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PUBLICATIONS OF THE UNIVERSITY OF MANCHESTER

BIOLOGICAL SERIES
No. II

THE QUANTITATIVE METHOD IN
BIOLOGY
Published by the University of Manchester at
THE UNIVERSITY PRESS (H. M. McKEcuHniIrE, Secretary)
12 Lime GROVE, OxFrorD Roap, MANCHESTER

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THE QUANTITATIVE
METHOD IN BIOLOGY

BY

JuLius MacLeEop, Dr Nar. Sc.
Professor of Botany in the University of Ghent

WITH 27 FIGURES

MANCHESTER :

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PUBLICATIONS OF THE UNIVERSITY OF MANCHESTER
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PREFACE

In Physics, Chemistry and Mineralogy the properties of the
objects are measured and expressed by means of figures called
constants. A constant is independent of any theory: it is the
exact expression of a fact. The constants are in reality the
material by means of which theories are built up, the explana-
tion of the observed facts is found and the road opened for
new discoveries.

In Botany and Zoology, on the contrary, the properties
(characters) of the living things are usually described by means
of terms. We say that a given object is long or short, broad
or narrow, oblong or oval, etc. Much progress would be
rendered possible if such terms as long, broad, short, etc., were
replaced by figures. This would be simple enough if the
properties of animals and plants were invariable. Unfortunately
these properties are almost always variable, not only within
the limits of one species, but also among the children of the
same parents and even among the progeny of one parent.
Variability has been hitherto the great obstacle which has
rendered impossible the general use of quantitative data (figures)
in Biological Sciences.

The object of the present book is to describe a method by
which biological constants may be established.

In the first two chapters I have expounded certain theoretical
views about the notion of species and variation. Those views
afford us a guide for the discovery of the przmordza (simple or
elementary properties or characters) which are to be measured
in order to find constants. The constants themselves are,
however, entirely independent of any theory and of any

* Parthenogenesis, apogamy, asexual multiplication in animals and plants.
v
vi PREFACE

calculation whatsoever. Each constant is a direct expression
of an observed fact.

I have been asked several times in what way the described
method was to be applied to the investigation of certain given
properties of certain animals or plants. My answer is that in
each peculiar case a preliminary investigation is required in
order to find the primordia which are to be measured and the
way in which the measurements are to be carried out. This
preliminary work may be a long one.

For example, I began in December 1914 the study of the
British species of the genus Mnium (Acrocarpic Mosses). 1
spent two months on the preparatory work before I had found
a dozen of the primordia and established their exact definition
and the method of measuring them. In a similar way it took
me in 1916 about three months to determine exactly twenty-five
primordia of the fertile stem of the Grasses. In 1907 I began
the measurement of thirty-eight primordia of the species of the
genus Carabus after a preparatory investigation of the simple
properties of the Coleoptera and other insects which lasted
several years. Such work is, IJ think, an excellent school for
the biologist, because he becomes aware of the vagueness of
many of our notions. As soon as we require to make measure-
ments, we feel again and again compelled to replace approxi-
mations by exact definitions. It may be hoped that the
preparatory work under consideration will become easier in
proportion as the number of examples investigated becomes
greater.

The work needed for the measurement of the primordia of
animals and plants is rather lengthy, but biologists ought not
to shrink from the idea of undertaking such a laborious task.
It may be recalled that the physicists, the chemists and the
mineralogists have already collected hundreds of thousands
of constants at the cost of tremendous toil. They have per-
severed in spite of numerous difficulties. For example, in
order to establish exactly the constants (atomic weight, specific
gravity, melting-point, etc.) of a given metal, a pure specimen
PREFACE vil

must be provided, and the preparation of a pure specimen may
last several months. Moreover, many figures obtained by the
measurement of inorganic objects are variable according to
the external conditions, in the same way as the dimensions
and other properties of living beings. For instance, the density
of a given substance varies according to temperature ; pressure
has an influence on the boiling-point ; etc. Therefore, in order
to establish constants, certain conventions have been made;
this renders the task still more laborious and delicate. Biologists
should not allow themselves to be discouraged by the prospect
of “such lengthy work”; they should always remember what
the students of inorganic nature have already carried out.

When an index of refraction, a coefficient of expansion or a
given angle of a crystal has been exactly measured, work and
perseverance find their reward, because a precise notion has
been acquired once for all. In Biology, on the contrary,
especially in the descriptive (systematic) part of Zoology and
Botany,} numerous objects have been described again and
again as new ; contradiction and hesitation prevail everywhere ;
an enormous amount of labour has been wasted. We should
follow the example given by physicists, chemists and mineralo-
gists. Otherwise it may be feared that the work, like that of
Penelope, will go on indefinitely.

It may be remarked that the present book is NOT in reality
a treatise on mathematical biology: mathematical notions
(Part VI.) are used only in order to find the primordia and the
methods of measuring them. We may hope that when a
sufficient number of constants have been collected the power-
ful machinery of mathematical science will become applicable
to biological problems.

I have, in conclusion, the pleasant duty of acknowledging the
assistance received from various friends.

To Professor F. E. Weiss, who has kindly read through
the manuscript and has made numerous corrections in the
language, and to Professor W. H. Lang, in whose laboratory

1 See on Embryology, § 50.
Vili PREFACE

I have been working for more than three years, I am indebted
for the most cordial assistance. Both of them have given me
bibliographical information of a most useful character.

I beg Professor G. Unwin, who kindly helped me with
the language, to accept my most sincere thanks.

To Professor Niels Bohr, Copenhagen, I am indebted for
useful remarks about the mathematical part.

Finally, I have to express my great obligation to Mr W. D.
Evans, M.A., who has read through the manuscript and
proofs of the mathematical part and who has assisted me in
various ways.

JuLtius MACLEOD.

THE UNIVERSITY,
MANCHESTER. 21st December 1918.
CONTENTS

PREFACE . . : ; ‘ : a . ‘ sae
LIST OF ILLUSTRATIONS 4 . ; 3 é . xii
PART I
THE NOTION OF SPECIES IS A CHEMICAL NOTION . z I

The Living Substance of each Specific Form is a Mixture of a Number
of Chemical Entities—Each Specific Mixture differs from all others by
at least one Entity—Chemical Classification of Plants and Animals—
Groups and Series of Chemical Entities—Glycerides—Proteins—Natural
Mixtures—Bioproteins—Biotic and Abiotic Chemical Properties—
Heredity—Individual Variation—Mutation—Lamarckism

PART II

THE OBSERVABLE PROPERTIES OF EACH SPECIES ARE
PRODUCED BY REACTIONS OF ITS LIVING SUB-
STANCE. . : : . 9

Possible and Observable Properties—Range of Possibilities—Plasticity—
Variants—Complexity—Monotypic and Complex Species—Subspecies
—Pure Lines—Bud-Variation—Bud-Species—Continuous and Dis-
continuous Variation—Adaptation—Accommodation—Variation under
Cultivation—Latent Properties

PART III

QUANTITATIVE METHOD AND PRIMORDIA . ‘i ‘ ‘ 25

Summary of Parts I. and II.—Use of the Quantitative Method in the
Description and Classification of Species—Linnzus—Latreille—Bertil-
lonage — Biometry — Quantitative Variation — Quetelet — Variation
Curves—Galton—Weldon—Pearson— Davenport—Biometrika—A ppli-
cation of the Quantitative Method on the Study of Hybridization—
Mendel—The Mendelian Experiments in Relation to the Notion of
Species—Simple and Compound Properties—Primordia—Observable
Properties and Hereditary Factors—Segregation (Dissociation) of
Compound Properties into Primordia by Hybridization, Plasticity,
Gradation and in the Course of Individual Development—The Mendelian
Method of describing Hybrids is applicable on the Description of
Species — Phyllotaxis — Quantitative Investigation of Physiological
Functions

ix
x CONTENTS
PART IV

PAGE
THE PRIMORDIA . e : : ; : ; . 8I

The Adult State is a State of Equilibrium—Each Primordium repre-
sents a State of Equilibrium—Individual Adaptation (Accommodation)
is Equilibrium—Classification of the Primordia with reference to their
Development—Sensitive Period—Correlation—Independence of the
Primordia—Pzedogenesis—Measurement of a State of Equilibrium—
Curves of Development—Leading Property—Variation in Embryology

PART V
ATTEMPT AT A CLASSIFICATION OF THE PRIMORDIA 66

Numerous Primordia mentioned in existing Descriptive Literature—
Classification of the Primordia (Bateson)—Spirogyra (Primordia,
Sensitive Period)—Uniaxial System—Radial System— Pediastrum—
Morphological Homology and Mechanical Concordance— Volvox,
Hydrodictyon—Systems of Segmentation derived from the Uniaxial
System—Ramification— Psexdochete—Complicated Cases — Primordia
of Trees, Cuttings, Grafts, etc.—The Notion of Individual—Series of
Subordinate Biological Units—Secondary Segmentation—Rectangular
Biaxial System (Chess-board System)—Alterations of the Chess-board
System—Intermediate Units—Vexillary Marks—Gradation—Differ-
entiation—Simple and Compound Axes—Curved Axes—Disorder—
False (Oblique) Axes—Second Secondary Segmentation: Rectangular
Triaxial System—Shell of the Molluscs

PART VI

THE MEASUREMENT OF VARIABLE PROPERTIES OF ANIMALS
AND PLANTS. SIMPLE NOTIONS OF PROBABILITY
(FREQUENCY). : :

Position of Equilibrium of a Sphere on a Horizontal Plane—Chance—
Specific Energy— One Coin (Head or Tail)—A System of Two Coins—
Three Coins—An Unlimited Number of Coins—An Urn containing
Two Sorts of Balls, Three Sorts of Balls—One Die, Two Dice—Co-
existence of Simple Events—Various Ways in which they may be
combined into Compound Events—Diversity of the Effects

Application of the Principles of Frequency on the Hereditary Trans-
mission of Primordia in the Mendelian Hybrids—Segregation

Measurement of the Density of a Solid Body—Curve of Errors—
Measurement of a given Weight of a certain Substance—A Mixture of
Two Volumes of Water—A Mixture of an Acid and an Alkaline Liquid
—Continuous and Discontinuous Variation—Unilateral Variation—
Influence of Growth—Embryological Curves

An Urn containing Two Sorts of Prisms—Variation Curve—Ex-
treme Values and Mean Value—Experiments with Cards—Biological
and Inorganic Variation Curves—Conditions of Existence—Components
of Chance—Optimal Values—Values m-o-4/—Significance of a Mean
Value—The Highest Value of a Variable Primordium is a Specific
Constant—Minimal Value—Conventions—Usefulness of Mean Values
for Comparing Two or More Series of Measurements

115
CONTENTS xi

PART VII
PAGE
VARIATION STEPS . ; ‘ , é : - 178

Examples—Diverse Series of Variation Steps—Variation Steps of the
First, Second and Third Degree—Symmetry and Variation Steps—
Relation between Mean Value and Variation Steps—Transformation
of a Monomorphic Curve into a Dimorphic or a Polymorphic one by
External Causes—Influence of Selection upon Variation Steps—Dis-
continuous Variation, Variation Steps and Specific Difference—Rela-
tion between Variation Steps and Phyllotaxis—Methods for the
Discovery of Variation Steps—Embryological Series—Parallel Varia-
tion: Mechanical Concordance, Embryological Parallelism, Parallel
Variation Steps

PART VIII
GRADATION 7 7 : 7 é , 2 » 198

Comparison between Living Beings and Crystals—The Axes of the
Crystals are Lines of Stability—The Axes of the Living Beings are also
Lines of Stability—Difference between both Sorts of Axes—Examples
of Gradation—Independence of the Primordia in Respect of Gradation
—Comparison between Gradation Curves and Embryological Curves—
The Axes of the Living Beings are Lines of Equilibrium, Ordonnance,
Gradation, Segmentation and Differentiation — Various Effects of
Gradation

PART IX

APPLICATION OF THE QUANTITATIVE METHOD — THE
DESCRIPTION OF SPECIES : : . : . 207

Various Applications of the Quantitative Method—Breach of Continuity
in the Development of Biological Science—Vagueness and Incomplete-
ness of Specific and Generic Descriptions—Importance of Systematics
—Comparative Method—Morphology—Palzontology—Importance of
Collections—Minute Details—The Notion of Species—Independence
of Species—Quantitative Description and Identification of Graminea—
Constants of Alopecurus pratensis—Tables of Constants—Examples—
Methods for using Tables of Identification—Bertillonage

INDEX : é 3 : : é 2 3 (1223
LIST OF ILLUSTRATIONS

FIGURE BASE
1. Variation Curve of the Disc-breadth of Opkiocoma nigra. ‘ 29
2. Uniaxial System ‘ q - ‘ : : : 73
3. Euastropsis, Pediastrum . . : a . . 79
4. Pseudochate gracilis . s A . 2 84
5. A Hair consisting of Four Cells aivwteine snaritess 5 : 87
6. Prasiola parietina 3 $ 3 j p . : 93
7. Pleurococcus vulgarées : ‘ Fi . . . 94
8. Regular Chess-board System . : Fi ‘ 3 5 94
9. Epidermis (Ad/ium cepa) a ‘ ‘ ‘ . ; 96

10. /lea . j F : 7 . 7 : e 97
11. Prasiola ‘ 5 4 s z 2 é 98
12, Human Epidermis . ' : . ‘ ; 99
13. (1) Regular Chess-board ee p ; , é 100
13. (2) Effects of Gradation in a Chess-board Spstent é - i IOI
14. Allium porrum: Epidermis . ‘ ‘ 3 "i 103
15. Chess-board System in Leaves of —— a ‘ : 106
16. Mnium punctatum : Cells of the Leaf 3 . . 7 108
17. Bryum argenteum: Cells of the Leaf ‘ ‘ . ‘ 109
18. Curve of Errors (a +4)” ‘ _ ; 3 146
19. Curve of Committed Errors; Curve of Siew Effects : 5 152
20. Curve of Growth - 2 . ‘i : . ‘ 155
21. Curve of Growth 3 ‘5 : ‘ ‘ 3 156
22. Curve of Development: Red, Hesitation, Blue : a . 157
23. Curves of Development of Three Primordia . . . 158
24. Symmetrical Variation Curve 2 : 7 . : 161
25. Relation between Temperature and Growth . F : Z 168
26. Gradation Curve : : . e 7 : 201
27. Gradation Curves of Four eenatats : : 3 : : 203

xii
THE QUANTITATIVE METHOD
IN BIOLOGY

PARI I]
THE NOTION OF SPECIES IS A CHEMICAL NOTION

§ 1—Each animal and vegetable species differs strictly
from all others by the chemical composition of its living
substance.

§ 2.—The so-called characteristics of each species are the
product of reactions, in which there intervene on the one hand
the external causes which affect the individuals during their
development and on the other hand the living substance of the
species under consideration.

§ 8.—Our knowledge of the chemical composition of living
substance is too incomplete to found a RATIONAL classifica-
tion of plants and animals based upon differences of chemical
constitution. In the present state of science our classifications
are founded merely on differences in observable characteristics
(properties).

In our study of living beings we find ourselves in much the
same position as a mineralogist would be if he were ignorant of
the chemical constitution of the minerals, and were thus limited
to the study of their properties, such as crystalline form, optical
properties, density, hardness, colour, etc., and were to try to
found on those data a classification of the mineral species.”
Fortunately, we dispose of a larger number of facts than our

1 The term species is used here in its most general significance (specific form)
—that is tosay, in the sense of a form of life (species properly so called, elemen-
tary species, race, etc.) characterized by hereditary properties.

?See Sir HENRY ALEXANDER MIERS, F.R.S., The Old and the New
Mineralogy, in Trans. Chemical Society, 1918, vol. cxviii., pp. 364-386. In this
interesting paper the author has recorded that, in former times, the characters
of minerals which were used for the purpose of discriminating between species
and of classifying them were the external or natural history properties (specific
gravity, colour, crystalline form, etc.). Later on (DANA, 1850) a new classifi-
cation of the minerals, based upon their chemical composition, was adopted.

A I
2 THE QUANTITATIVE METHOD IN BIOLOGY

supposed mineralogist : we may investigate the transmission
of the properties (characteristics) by inheritance, the order
in which they appear during individual development and, in
many cases at least, the order in which species and groups of
species have appeared during the geological ages. We may
also modify the properties of a given species and bring about
the appearance or disappearance of some of them by modifying
the conditions of existence (external causes). In spite of all
this, however, our classifications are of an empirical nature.

§ 4.—At first sight it seems impossible to accept the sugges-
tion that a sufficient diversity exists in the chemical com-
position of the living substance to explain the existence of
millions of animal and vegetable species. This difficulty dis-
appears when we look upon the living substance of each species
as consisting of a mixture of a rather small number of chemical
entities—the components being very probably proteins (or
substances related to the proteins) and each specific mixture
differing from all others by at least one component.

If we suppose that the components of all the existing species
are ¢hivty in number and that ¢wenty of them occur in each
species, we realize the possibility of an enormous number of
specific mixtures differing from each other by one, two or
more components.1 If we suppose, moreover, that in certain
species twenty, in others nineteen, eighteen, etc., components
occur, the number of possible mixtures becomes practically
unlimited, just as is the case with the number of living and
fossil species.

§ 5.-In the present state of science it is impossible to verify
the above suggestion. It is, however, made admissible by the
following facts :—

(x) A large number of the combinations of carbon may be
brought into natural growps, each group consisting of one or
several series, each series including several terms.

EXAMPLE: one of the most important groups consists of
the glycerides of the fatty acids (fixed oils and fats). In this
group we find numerous series ; for instance, the glycerides of
the acids of the

acetic series (C,,H,,0,),

acrylic (oleic) series (C,Hon..O,),
linolic series (C,H on. 4Oo),
linolenic series (C,Hy.,0.), etc.”

1 The number of such specific mixtures differing by one component at least
is 30,045,015.

?In EDWARD THORPE, A Dictionary of Applied Chemistry, vol. iii. (1912),
Pp. 744, nine series are mentioned.
THE NOTION OF SPECIES 3

Each series includes a certain number of terms (entities)
which differ from each other by the value of ; for instance,
to the acetic series belong the glycerides of

acetic acid (C,H,0O,),

butyric acid (C,H,O,),

caproic acid (C,H,,0.),
lignoceric acid (C,,H,,0.), etc. ;

to the acrylic series belong the glycerides of

tiglic acid (C;H,O,),
oleic acid (C,,H;,0,),
erucic acid (C,,H,4,0,), etc., etc.

Between the terms of each series and also between the series
of a given group evident analogies exist, not only with regard
to the chemical constitution, but also in the facies and physical
properties.

(2) The PROTEINS 2 seem to be polypeptides which are
formed by the conjugation of a large number of amino acids.
Altogether more than fifty proteins are known to occur natur-
ally in animals and plants, which differ from one another in
physical and chemical properties. They may be brought into
classes and groups in the following way 3 :—

Class A: Simple Proteins.
Group 1: Protamines.
Histones.
: Albumins.
: Globulins.
: Prolamins (Gliadins).
: Glutelins.
‘ Scleroproteins.
Class B: Goaiteated Proteins.
Group 8: Nucleoproteins.
4 g: Glycoproteins.
» 10: Hemoglobins.
» 11: Phosphoproteins.
12: Lipoproteins.
Class C: Derived Proteins.
Group 13: Proteans (Metaproteins).
» 14: Coagulated Proteins.
» 15: Proteoses.
» 16: Peptones.
« if Peptides.

IF

”

”

”?

”

oe) AuBW ND

THORPE, loc. cit., vol. iii., p. 744. 2 [bid., vol. iv. (1913), Pp. 407.
° The classification here given is adopted by American physiologists and
chemists. See Thorpe, Joc. cit., vol. iv.
4 THE QUANTITATIVE METHOD IN BIOLOGY

In each group we find a certain number of substances ; for
instance : ay

In Group 3 (Albumins) : Legumelin, Leucosine, Ricin. |

In Group 4 (Globulins): Amandin, Avenalin, Castanin,
Conglutin, Corylin, Edestin, Excelsin, Globulin, Myosin, Ovo-
globin, Fibrinogen, etc.

Since the way in which the highly complicated molecules of
the proteins are built up is very incompletely known, their
classification is more or less of an empirical nature. There
exist, however, between those substances physical and
chemical analogies enough to justify the conclusion that they
are related to each other, at least to a certain degree, in a
similar way as the glycerides.

(3) We find in the body of living beings, independently of the
living substance, numerous so-called substances the composi-
tion of which is more or less completely known. Many of
those substances are mixtures of several distinct chemical
entities. It is, from a biological standpoint, a very important
fact that such natural mixtures consist in the main almost
always of components which belong to the same chemical
family.

The natural oils and fats which are distributed throughout
the vegetable and animal kingdoms afford us numerous
instances of mixtures.

EXAMPLES: (a) Avachis Oil (seed of Arachis hypogea)
contains glycerides of stearic, arachidic, lignoceric, oleic, hypo-
geic, linolic acids, etc.?

(6) In Linseed O1l (seed of Linum usitatissimum), the com-
position of which is not yet fully known, glycerides of palmitic,
arachidic, linolenic, oleic acids have already been discovered.?

(c) In Cow Butter glycerides of the following acids occur :—
butyric, caproic, caprylic, capric, lauric, myristic, palmitic,
stearic, oleic.?

Microscopical observation does not give us the slightest idea
of the complicate composition of the natural mixtures which
we call arachis oil, linseed oil and cow butter.

It may be remarked that the same glyceride very often
occurs among the components of several oils and fats (for
instance, oleic acid is found in the three above examples
and many others; arachis oil and linseed oil have two com-
ponents in common, although they are found in plants which
belong to different families).

ANOTHER EXAMPLE: There are in opium (latex of
Papaver somniferum) neutral compounds, acids and some
twenty alkaloids, the most important of which is Morphine.‘

a THORPE, loc. cit., vol. i. (1912), p. 286. ® Tbid., vol. iii. (1912), p. 324.
3 Tbid., vol. i. (1912), P- 577- ‘ Ibid., vol. iv. (1913), p. 19.
THE NOTION OF SPECIES 5

§ 6.—The facts stated in the preceding paragraph may be
summarized in the following way :—a large number of natural
substances are mixtures, consisting in the main of chemical
entities which belong to one chemical family ; the components
are associated in a different way in each species and each com-
ponent may occur in a certain number of specific mixtures.
On the other hand, the proteins may be looked upon as belong-
ing to a single chemical family.

We may therefore accept the suggestion that living substance
(the /tving contents of the cell) follows the ordinary rule and is
a mixture, and since many well-known facts point to a chemical
relation between living substance and proteins, we may admit
that the components of the former are proteins—or substances
which are related to the already known proteins and which
might be called Bioproteins.

The properties ! of living substance are, indeed, so character-
istic that we are, as it were, compelled to think that its com-
ponents are not merely proteins properly so called. It may be
suggested that these components are proteins of a peculiar
kind, which deserve to be distinguished under the name bio-
proteins.

It may be further surmised that the molecules of the bio-
proteins are more complex than those of the proteins, and are
formed by the conjugation of a larger number of amino acids,’
the proteins properly so called being hydrolitic degradation
products of the bioproteins. According to this, a special class,
under the name of bioproteins, ought perhaps to be added to
the three classes mentioned in the classification adopted in § 5.

§ 7.—The living mixture which is found in a cell or a plas-
modium does not consist entirely of a homogeneous association
of components. Certain components are permanently or
temporarily separated from the others, being localized among
the living mass * and differentiated in the form of nucleus,
chromosomes, centrosomes, protoplasmic granulations and, in
general, plastids. The differentiated parts may be themselves
mixtures of several bioproteins. It is quite possible that
a chromosome, for instance, is a complicated mixture of a
number of bioproteic entities. A minute globule of cow butter,

1 Contractility; semipermeability; division of nucleus and_ plastids;
irritability, etc.

2 Or by the conjugation of two or several already discovered proteins.

* Example: Nucleoproteins (see p. 3, Group 8), which are compounds of
the strongly basic protamines (p. 3, Group 1) with nucleic acid, seem to
be localized in the cell nucleus (rhorpe, loc. cit., vol. iv., p. 411). I do not
look upon nucleoproteins as being bioproteins. Certain bioproteins, how-
ever, may be localized in certain parts of the cell in the same way as nucleo-
proteins.
6 THE QUANTITATIVE METHOD IN BIOLOGY

observed in a drop of milk by means of the most powerful
microscope, seems to be a homogeneous mass, although it con-
sists of nine different kinds of glycerides. It is therefore quite
conceivable that a chromosome, a centrosome, the living
stroma of a chloroplast, etc., contain a number of bioproteic
components. =

By the investigation of the differentiated parts of the living
substance we may acquire very valuable knowledge of numer-
ous observable properties and functions of the cells, yet we are
not enabled to probe to the actual bottom of the subject. A
biologist is sometimes induced to believe that it is possible, by
proceeding along this path of study, to attain the limits of our
science with regard to the explanation of the facts of heredity,
variation and origin of species. Feeling themselves deceived,
after many years of work, certain biologists seek for an explana-
tion in a so-called vital force, which is a matter of belief and not
susceptible of scientific analysis.

We must always bear in mind that all the differentiations
and functions of the living substance, and also its physical
constitution, after all is said and done, depend on the way in
which the molecules of its components are built up. As soon
as we want to look further, we leave the field of exact science.

§ 8—BIOTIC AND ABIOTIC CHEMICAL PROPERTIES.
—A living mixture may include and probably always includes
substances which do not belong to its tntvinsical components.
Such substances might be called abiotic ; they may be absorbed
from without (examples: food, oxygen and eventually any
substance for which the living mixture is permeable), or pro-
duced within the living mixture and used for various physio-
logical purposes (glucose and more respiratory combustibles),
or excreted (carbonic acid) or stored (starch, proteins in the form
of aleuron, etc.), etc.

The abiotic substances which are included in the living
mixture (and also, of course, in the vacuolar liquid and the cell-
walls) are exceedingly numerous, and many of them are
characteristic of certain species or groups of species.

EXAMPLES: Morphine in Papaver, nicotine in Nicotiana,
dipsacine and dipsacotine in many Dipsacee; colouring and
odorous substances in numerous plants and animals; for
instance, in Phallus impudicus, Chara, Cicindela, Coccinella,
bugs, etc.

The so-called chemical charactertstics of a species, which
depend on the presence of abiotic substances, are to be strictly
distinguished from the bzotzc chemical properties of the specific
living mixture. This mixture is the laboratory in which the
alysarine of Rubia tinctorum, the coumarine of Asperula
THE NOTION OF SPECIES 7

odorata, the roseal substance of Cicindela, the S(NH,), of
Phallus and other chemical characteristics are produced.

§ 8Aa—HEREDITY. INDIVIDUAL VARIATION. MU-
TATION.—Let us venture to proceed one step further along
the way of suggestion.

Almost all the properties of living beings are variable within
the limits of each species. The abiotic chemical properties
follow the ordinary rule. We know, for instance, that the
composition of opium and many other animal and vegetable
chemical products is variable according to external causes
(conditions of existence; for instance, climate). It is therefore
possible and even probable that the living mixture of each
species is also subjected to variation. It may be suggested
that two kinds of variation occur :

(1) Individual variation (variation properly so called) pro-
duced by the diversity of the conditions of existence (external
causes). In this form of variation it may be supposed that the
individuals differ guantitatively—t.e. in the proportions in which
the biotic components of the living substance are mixed, the
qualitative composition (that is to say, the nature of the com-
ponents) of the specific mixture being invariable in the species.

The qualitative composition of each specific mixture is trans-
mitted by inheritance, and therefore the possibility of producing
the reactions which result in specific properties (characters) is
also hereditary. (This does not exclude segregation among the
components of the living mixture of a hybrid, in which the
components of both parents are brought together into one
mixture.) It is also admissible that the quantitative com-
position of each individual is hereditary to a certain degree,
and, moreover, that quantitative individual peculiarities may
be accumulated (increased) under the influence of selection }
so often as the same conditions of existence prevail for two or
several generations, the increase alluded to being confined
within certain limits which are characteristic of each species
(see § 9). A complete discussion of this question lies outside
the scope of the present book. (See § 129.)

(2) Certain causes, which are probably diverse (§ 105), may
produce, in the qualitative composition of the living mixture
of certain individuals of a species, a modification which is
hereditary and called sport, saltation or mutation. If one of the
components disappears, or is transformed into a new chemical
entity (for instance, into an isomer), or if o7e new component is
added to those previously existing, a slight mutation takes
place, the new living form being, for instance, a pure line (§ 19)
or a subspecies (elementary species) little different from the

1T am alluding here especially to experimental (artificial) selection.
8 THE QUANTITATIVE METHOD IN BIOLOGY

original form. We may, for instance, look upon the trans-
formation of blue flax into white flax (or vice versa), of
Solanum nigrum with black fruits into Sol. nigr. with green
fruits, etc., as being the result of a qualitative transformation
of the living mixture with regard to one of its components.

We may also imagine two, three or more components to be
simultaneously transformed, the consequence of which would
be the appearance by saltation (mutation) of a new species
quite different from the original one, and even of a new genus,
anew family. (See bud-variation, § 20.) 1

§ 9—MUTATION. LAMARCKISM.—Among the possible
causes of mutation alluded to in § 8A, the influence of external
factors deserves a special mention. (See §§ 35 and 105.)

A change in the conditions of life of certain specimens of a
species may result divectly in a mutation.

It is also conceivable that a quantitative modification of a
living mixture produced by external causes may become im-
portant enough to bring about indirectly a qualitative modifica-
tion—z.e.a mutation. We know that the reactions which take
place in a mixture of chemical entities depend, in certain cases
and to a certain degree, on the proportions in which the entities
are mixed. Therefore it is conceivable that a change in the
proportions of a living mixture (quantitative modification)
might produce a new reaction resulting in a mutation.

If we adopt the suggestion that mutations may be brought
about, directly or indirectly, by external causes, there is no
longer any incompatibility between

The principle of mutation (saltation), according to which a
new species may appear at once, and

The Lamarckian principle, according to which new species
are produced by new conditions of existence.?

Both principles being combined,? the transformation of a
species into a new one, without transitory or transitional forms
between both, becomes quite intelligible.

1 According to the above a fundamental distinction ought to be made
between two kinds of heredity :

(a) The hereditary transmission of quantitative modifications of the living
mixture of a species; by this, no new species can be produced.

(0) The hereditary transmission of qualitative modifications of the living
mixture of a species ; this gives birth to a new species.

? Without selection.

* That is to say, the production of mutations by external causes being
admitted.
PART i

THE OBSERVABLE PROPERTIES OF EACH SPECIES
ARE PRODUCED BY REACTIONS OF ITS LIVING
SUBSTANCE

§ 10.—POSSIBLE AND OBSERVABLE PROPERTIES.—
The living mixture of each species is able to produce numerous
reactions which bring about the observable properties (so-
called characteristics). In each reaction internal (specific)
causes, which depend on the composition of the living mixture,
and external causes, which depend on the environment (con-
ditions of existence), play a part. The possible properties of
each species are very numerous; each individual exhibits only
a part of them, according to the conditions of existence under
which it has been developed, the other properties being Jatent.
What we usually call the characteristics of a species are those
properties which become observable under ordinary circum-
stances of life. It is in this sense that the descriptions in the
floras and the faunas and also in anatomical and morpho-
logical literature are to be understood. If the conditions are
modified, some of the described characteristics become latent
and other properties appear.

Therefore, if we wish to discover all the possibilities (potenti-
alities, possible properties) of a species, we must collect and
examine specimens developed under all the different external
conditions under which the life of the species is possible.

§ 11—RANGE OF POSSIBILITIES. PLASTICITY.—
The range of possibilities is very different in one species from
what it is in another. I take as first example three species
which are characteristic of the alpine flora: Soldanella alpina,
Rhododendron ferrugineum and Leontopodium alpinum. When
these plants are cultivated in the plains (for instance, in the
Botanic Garden at Ghent), where the conditions are different
from those which prevail in high altitudes, they behave in
quite a different way. Soldanedia is not at all or hardly modi-
fied, but it dies down after a certain time: the limits of external
conditions under which its existence is possible are rather
narrow.! Rhododendron may be kept in the plains for an

1 This seems to be the case with many vegetable species (for instance, several
very rare terrestrial orchids) which are only found on certain spots where
peculiar conditions prevail.

9
10 THE QUANTITATIVE METHOD IN BIOLOGY

unlimited number of years without any important change in its
observable properties. Leontopodium is suitable for cultiva-
tion in the plains, yet its properties (facies) are so deeply modi-
fied that it becomes hardly recognizable ; in other words, this
species is very PLASTIC (modifiable, facilis). (See § 14.)

§ 12—EXAMPLES OF PLASTICITY.—Polygonum am-
phibium is a good example of a species with a living sub-
stance capable of numerous reactions according to the condi-
tions of existence, which bring about an astonishing diversity
in its observable properties. This species occurs (for instance,
in Flanders) in three distinct forms (VARIANTS). The Zer-
vestrial form or variant is (in Flanders) a common and rather
noxious weed in cultivated fields. Its stem is erect and rather
robust, 50 cm. to 1 m. high, with numerous spreading leaves.
The aguatic form or variant is common in ponds and watery
ditches. The stems are longer (2 m. and more), flexible, float-
ing; the leaves are few, rather thick, spreading on the surface
of the water and differing considerably from the leaves of
the terrestial form by their facies and anatomical structure.
The xerophytic variant is not uncommon on rather arid, sandy
soil. Here the stems are more or less creeping, the leaves
being more like those of the terrestrial form but smaller.
Transitions between the three mentioned types frequently
occur; for instance, in shallow or dried-up ponds, muddy
ditches, etc. The types are so very different from one another
by their facies and internal structure that one can hardly
realize that there is no hereditary difference between them (in
other words, that the living mixture is the same in each and
all). This is, however, beyond any doubt, for it is possible to
obtain the three types (variants) by bringing parts (with buds)
of one specimen under the various conditions of existence
mentioned above.

Another remarkable example of plasticity is Ranunculus
sceleratus. In the terrestyial variant, which is common on
rather wet soil, the stem is erect, the leaves are comparatively
small, spread out and divided into segments. In the aquatic
variant the leaves are thicker, larger, less divided and spread
on the surface of the water. Their facies is so characteristic
that they may be discerned at first sight from any other sort of
floating leaves of our flora. Limiting ourselves to the study
of the terrestrial variant, we would neither suspect the possi-
bility nor guess at the properties of the floating leaves. These
are produced by reactions which take place only in water.

The two preceding species are examples of what we call
ordinarily variable or polymorphic species. Here polymorphism

1In a number of floras the floating leaves are passed over in silence.
OBSERVABLE PROPERTIES OF EACH SPECIES 11

is a consequence of plasticity and depends entirely on the
conditions of life. In both examples plasticity is prominent,
yet every living species is plastic to a certain degree.

Other well-known examples of remarkable plasticity are
the so-called light and shade leaves of many plants (for in-
stance, Fagus sylvatica) ; the variation in the leaves of several
thistles according as they are developed in a dry or in a moist
atmosphere ; remarkable variations in the colours of a number
of butterflies 1 produced by external influences (temperature,
food) affecting the caterpillar or the chrysalis, etc.

It seems as if many biologists did not pay much attention
to the above facts. They continue to give us descriptions of
species and anatomical contrivances as if plasticity did not
exist. Plasticity, however, is in itself a very important pheno-
menon, which deserves to be investigated quite independently
of the question whether the observed variations may become
hereditary or not.

§ 13.—COMPLEXITY.—In certain species, which are also
called variable or polymorphic, the observed variation is inde-
pendent of external causes and depends on the fact that the
species under consideration consists of two or several distinct
hereditary forms or subspecies (elementary species) which are
brought together under one name. EXAMPLE: Solanum
nigrum is variable with regard to the colour of the ripe fruit.
In many localities (on the Continent) specimens with black
berries and others with green berries are found side by side
under the same conditions of existence. We know, on the
other hand, that each of the colours mentioned is transmitted
by inheritance (DE VRIES).? We may conclude, therefore,
that S. nigrum is a COMPLEX species, including two sub-
species (melanocarpum and chlorocarpum). Very probably
S. nigrum includes more than two sub-species. We see, indeed,
in BENTHAM’S Handbook of the British Flora (1866) that

“in Britain, the stem . . . is usually glabrous or nearly so,
but on the Continent often hairy or rough at the angles,”

that the

“berries . . . are . . . usually black, but sometimes,
especially on the Continent, green, yellow or dingy red,”

and further, that the species is

‘varying so much in warmer regions as to have been
described under more than forty names ”’ (loc. cit., p. 332).

It is only by means of experiments that we can hope to

1Certain of the variations alluded to have been observed fortuitously in
the state of nature and described as very rare varieties. ;

?HUGO DE VRIES, die Autationstheorie (Leipzig, Veit und Co.), vol. ii.
(1903), pp. 156 and 170-171.
12 THE QUANTITATIVE METHOD IN BIOLOGY

discover whether the mentioned polymorphism, with regard to
certain properties, depends on the existence of several sub-
species differing from each other by their living substance, or
is a consequence of plasticity with regard to other properties.
As far as I know, we have exact information only with reference
to the colours black and green. In the meantime it is advisable
to collect facts and material without encumbering the botanical
nomenclature with more names.

§ 14—PLASTICITY (continued). SENECIO AND CHRYS-
ANTHEMUM.—It may happen that certain species are very
plastic with regard to a certain property, whereas in other
species, which belong to the same systematic group, this same
property seems to be independent of the conditions of existence.

EXAMPLE: In certain species of Senecio the number of
marginal florets varies very little. In S. jacob@a, for instance,
this number is 13.1 On the other hand, in other Com-
posite, this property is very variable. In Chrysanthemum
carinatum, for instance, the extremes are about 3 and 30 or
still more. In this plant the number of marginal florets may
be augmented or diminished by modifying the conditions of
existence: the highest figures are obtained (according to my
experiments) when the plants are grown under favourable
conditions (in good soil, at sufficient distances from each other),
whereas lower figures are observed when the conditions are
rather poor; for instance, when the plants grow close together
or when the soil is poor (§ 128).

The difference between the living mixture of S. jacobea and
that of C. carinatum is disclosed not only by the reactions
which produce the so-called characteristics of each species, but
also by the fact that C. carinatum is very plastic with reference
to the above-mentioned property, whereas S. jacobe@a is very
slightly plastic.

The degree of plasticity is a specific property in itself. (See § 11.)

§ 15. — PLASTICITY (continued). PHILODENDRON
PERTUSUM.—In certain cases a property described as being
in a high degree characteristic of a given species disappears
(becomes latent) under the influence of certain external causes.

EXAMPLE: Philodendron pertusum bears large leaves
pierced with round holes, which give to this plant the name
of pertusum (perforated). In the Botanical Garden in Ghent
several specimens of this species were cultivated for many years
in a greenhouse which was rather cool and dry. The holes were

1In Flanders, I have counted the marginal florets of thousands of flower-
heads in many localities, under very different conditions of existence. I

always found 13, except in three or four flower-heads in which the figure
was 12 OF 14.
OBSERVABLE PROPERTIES OF EACH SPECIES 13

rare: it happened sometimes that it was impossible to find one
single perforation in all the leaves of a specimen. The plants
were, in every other respect, quite healthy. In 1903 they were
brought into a new greenhouse which was warmer and moister.
After a few months the new leaves were abundantly perforated,
and from that time on the plant was again deserving of its
name (J. V. BURVENICH).

§ 16. — PLASTICITY (continued), PRIMULA, CAM-
PANULA, CRIMSON RAMBLER.—In the preceding ex-
amples external causes brought about differences between
specimens of the same species. Inversely, specific differences
may disappear under the influence of unusual conditions of life.

EXAMPLES: In some subspecies of Primula sinensis the
corolla is white, in others it is pink. Under ordinary circum-
stances, the temperature being 10° to 20° C., the colour is quite
characteristic of each form. But if a certain pink subspecies
is cultivated at a temperature of 30° C., the pink colour dis-
appears: the corolla becomes white and can no longer be
distinguished from that of a white subspecies.

Similar facts have been observed in Campanula. Some
species of this genus include blue and white subspecies. A
certain subspecies with a blue corolla, when grown at a high
temperature, is transformed into a white form (variant) which
resembles a white subspecies.

The crimson rambler rose is cultivated at Ghent 1 in many
gardens. The flowers are comparatively small, very numerous
on each flowering branch and crimson in colour. When an
inflorescence (corymb) is crooked before the buds have reached
their full size, the flowers of this branch, when expanded, are
quite healthy, but white. The crimson rambler is, as it were,
transformed into a white rambler.”

§ 17.— PLASTICITY (continued). CALLITRICHE. — In
two examples mentioned in § 16 a difference between two
(sub)species disappears under conditions which are unusual or
even abnormal. Inversely it is probable that, in numerous
cases, two specific forms which are hardly different under
ordinary conditions of life become distinctly different under
unusual circumstances.

EXAMPLE: In togir (in Flanders) the summer was hot
and very dry. In dried-up ditches I observed repeatedly
the terrestrial form (variant) = Callitriche. The stems were

1 Probably introduced from Englan

? This fact was observed by Mr COLLUMBIEN, SENIOR, horticultural
teacher at Ghent. I repeated the experiment several times with success. I

tried to obtain in the same way a similar transformation with two other
sorts of roses with pink flowers, but without any effect.
14 THE QUANTITATIVE METHOD IN BIOLOGY

ordinarily rooting at their base, the ascending part being about
5 cm. high, with numerous leaves. In one ditch (between
Beernem and Ruyselede, in West Flanders) I found a form
with a creeping stem, distant, comparatively narrow leaves, the
extremity of the stem not being erect. The difference between
the two forms was striking and much more apparent than
between the numerous specimens of the aquatic form which
I have observed in many localities in Flanders. Therefore I
surmise that the two terrestrial forms belong to two subspecies
which can hardly be distinguished in their ordinary aquatic
form.

REMARK : When we want to ascertain whether two plants
belong to the same species (or subspecies) or not, we often
cultivate specimens of both side by side under ordinary con-
ditions. Ifa distinct difference is observed, we conclude that
there exists a specific difference between them. If the speci-
mens show the same properties, we are tempted to believe that
they belong to the same species. The latter conclusion, how-
ever, may at times be erroneous. It is possible that certain
reactions of the living mixture and the corresponding visible
differences are only observed under unusual conditions. A
better method would be to have comparative cultures under
conditions as various as possible (soil of diverse composition ;
dry or wet; shady or sunny position, etc.). In this way we
may hope that latent differential characteristics will become
visible, which have not yet been observed. The principle of
this method is, mutatis mutandis, adopted for the investigation
of lower fungi, bacteria, etc. It might render good services
to the study of crztzcal species of phanerogams, mosses, etc.

§ 18—MONOTYPIC AND COMPLEX = SPECIES.
SPECIES AND SUBSPECIES.—To sum up, the so-called
variability (variation, polymorphism) of a species may depend
on two quite distinct causes (compare § 8a):

(1) The living mixture of a species is capable of reacting in
various ways according to differences in the external condi-
tions. I call this plasticity.

(2) A species may be (and many species are) a complex con-
sisting of two or several subspecies differing from one another
by the qualitative composition of their living mixture! (each
subspecies being, of course, plastic). I call this complexity.

The distinction between plasticity and complexity is well
known. It may, however, be useful to recall it, because we
often apply the terms variability, variation and polymorphism
to both. This confusion occurs again and again in zoological

1 The chemical difference between two subspecies is smaller than between
two species. (See § 84.)
OBSERVABLE PROPERTIES OF EACH SPECIES 15

and botanical systematic literature. Although it is often rather
difficult to discriminate between plasticity and complexity with-
out having recourse to experiment (see § 17, Remark), we must
always bear in mind the fundamental difference between these
two kinds of variation.

REMARK I.: The term variety is used with different
meanings and has therefore no longer any exact significance.
Certain authors have given a definition of it which they seem
soon to have forgotten, since they use the term with various
meanings, quite different from their own definition. In the
floras and the faunas the term variety is often used as a
synonym of subspecies, but unfortunately certain forms
(variants) which depend on plasticity are also called varieties.

REMARK II.: I use the term subspecies in the sense of
elementary species or petite espéce, because it is shorter and
clearer than the latter expressions. [ call variant any form of
a species or subspecies which is brought about by plasticity.
Variants are not to be designated by Latin names. (Examples
of variants are given in §§ 12, 15, 16, 17.)

REMARK III.: A species which includes only one sub-
species may be called a monotypic species, whereas a complex
species includes two or several subspecies.

§ 19—PURE LINES.—It is very probable that many sub-
species (and monotypic species) consist of two or more pure
lines (JOHANSEN), separated from one another by qualitative
chemical differences of their living mixture which are slighter
than those which exist between subspecies (§ 8A), each pure line
being plastic. In the present state of science the discovery of
pure lines is only possible by means of delicate experiments.
As well-established facts are up to now not numerous, our
knowledge of this very interesting subject is still slight. There-
fore I limit myself to this brief mention of pure lines.

§ 20—BUD-VARIATION.—It has often been observed
that in a bud of a given plant a certain change takes place the
nature of which is hitherto unknown, but the consequences of
which are visible : the new parts (branches, leaves, flowers, etc.)
produced by the modified bud react in a new way and exhibit
properties (characters) by which they differ from the original
plant. This peculiar form of variation is called bud-variation.

Numerous examples of bud-variation have been mentioned
by several authors, among whom DARWIN must be cited in
the first place.

In many cases the new parts produced by a bud-variation

1CHARLES DARWIN, The Variation of Animals and Plants under
Domestication (second edition, 1875), vol. i.
16 THE QUANTITATIVE METHOD IN BIOLOGY

have been propagated by means of cuttings, layers, tubers and
other methods of vegetative propagation. It is possible to
obtain in this way an unlimited number of specimens which are
all characterized by the new properties and seem to belong to
a peculiar species or subspecies. Many so-called horticultural
species have their origin in a bud-variation.

EXAMPLES: Mr KNIGHT states that a tree of the yellow magnum
bonum plum, forty years old, which had always borne ordinary fruit, produced
a branch which yielded red magnum bonums (Darwin, Joc. cit., p. 399). The
black or purple Frontignan (grape) in one case produced during two successive
years (and no doubt permanently) spurs which bore white Frontignan grapes
(DARWIN, Joc. cét., p. 399). Kemp’s potato is properly white, but a plant
in Lancashire produced two tubers which were red and two which were white.
The red kind was propagated in the usual manner by eyes, and kept true to its
new colour, and, being found a more productive variety, soon became widely
known under the name of Taylor’s fortyfold (DARWIN, loc. cit., p. 410).

The pseudo-species produced by bud-variation (we may call
them bud-species or bud-subspecies) differ from the true species
(seed-species) because their characteristic properties are not
true to seed, which means that they are not transmissible by
sexual reproduction: as a rule, the seeds of the bud-species
produce specimens in which the mew properties have dis-
appeared. The bud-species are plastic just as the seed-species.

It may be suggested that a bud-species is produced by a
qualitative change of the living mixture (§ 8a) localized in
a bud and transmissible only by vegetative multiplication. In
other words, a bud-variation might be looked upon as being a
non seed-fixed ? mutation.

In a hybrid specimen we observe, in general, a combination of a number of
properties (characters) borrowed from the parents. This combination is
ordinarily transmitted only to a part of the children (seedlings): the seminal
offspring of a given hybrid is very variable, the properties under consideration
being combined in various ways among the children (as a consequence of the
principle of segregation). The hereditary transmission of the characteristic
combination of a given hybrid by sexual reproduction is therefore impossible
in horticultural practice, especially in those cases in which the combined
properties are numerous—for instance, when the hybrid is a complex one,
produced by successive crossings between several species. ?

It is, however, possible to obtain from a hybrid an unlimited number of
specimens similar to the parent by means of vegetative multiplication, the
characteristic combination being transmitted in this way. Many so-called
horticultural species consist in reality of the vegetative offspring of one hybrid
specimen.

Between bud-species and hybrids a certain analogy exists in respect to
heredity: in both cases the characters vanish by seminal reproduction and
are transmitted by vegetative multiplication.

Concerning constant hybrids, see § 105.

REMARK: It is possible that bud-species (or subspecies)
exist in the state of nature. A bud-variation might easily be

1 This is the translation of the Dutch word zaadvast (zaad=seed and vast =
fixed).

2 See, for instance, the complex hybrids in the genus Gladiolus mentioned by
DE VRIES (Mutationstheorie).
OBSERVABLE PROPERTIES OF EACH SPECIES 17

multiplied in the very numerous species (Ficaria ranunculoides,
Ajuga reptans, Potentilla anserina, etc., etc.) which ordinarily
multiply by vegetative means.1 If natural bud-species really
occur, it would be impossible to distinguish them from seed-
species without experiment. One would expect to find eventu-
ally numerous specimens of them in narrowly limited localities.

§ 21—CONTINUOUS AND DISCONTINUOUS VARIA-
TION.—Confusion exists in the use of the terms continuous
and discontinuous variation.

The variation of a property is called continuous when all
possible transitions exist between the extremes. When we
measure, for instance, the length of the spike of a number of
specimens of one subspecies (so-called vace) of the rye, and set
them in order into a series according to their length, we see
that the measured property increases gradually from the
shortest to the longest one: there are neither gaps nor jumps
in the series (Dr C. DE BRUYKER).

If, on the contrary, a gap is observed in the series, by which
the measured specimens can be divided into two groups, the
variation is called discontinuous.

In a similar way we say that discontinuity exists when two
groups of specimens differ from one another in a pair of
properties which are distinctly different. EXAMPLE: In
Lychnis diurna (Melandryum roseum) the petals are pink. In
Lychntis vespertina (Melandryum album) the petals are white.

Those two kinds of discontinuity must be distinguished from
one another. This subject is expounded more completely in
§ 130. (See also § 112.) In the present paragraph I content
myself with calling attention to the very important fact that
discontinuity (in the values of one property) sometimes occurs
in a group of specimens between which no specific difference
whatever exists, and that, on the other hand, continuity is
often observed although the specimens under consideration
belong to two (or even more) distinctly different specific forms.

§ 22.—ADAPTATION. ACCOMMODATION.—There is a
relation between variation and so-called adaptation. A strict
distinction ought to be made between individual adaptation
(accommodation), which is the consequence of plasticity, and
the HYPOTHETICAL adaptation of the species, which is
supposed to be produced by natural selection (Darwinism)
or by the hereditary transmission and fixation of individual
adaptation (Neo-Lamarckism). (See on this subject §§ 44-45.)

§ 28.—VARIATION UNDER CULTIVATION OR DO-
MESTICATION AND IN THE STATE OF NATURE.—The

1A rather large number of indigenous species rarely bear seed.
B
18 THE QUANTITATIVE METHOD IN BIOLOGY

idea that plants and animals are more variable under cultiva-
tion and domestication than in the state of nature is adopted
by almost every biologist. ; ;

It may be asked, however, whether there is not a certain
exaggeration in that belief. :

When a plant species, taken from the state of nature, is
cultivated in a garden, we ordinarily grow a large number of
specimens side by side. We pay much attention to our plants,
looking at them again and again, and comparing them with one
another. In this way we discover numerous and often un-
expected individual differences. In the state of nature, on the
contrary, the specimens of a given species are ordinarily more
isolated from each other and therefore we have less opportunity
to make comparisons. It happens very rarely that we observe
carefully more than half-a-dozen specimens: this brings about
the impression that there is less variation than among the
cultivated plants.

If we compare a large number of specimens growing wild we
are often compelled to collect them from a rather large area.
A botanist who has collected two hundred specimens of a
given species from an area of a hundred square miles, who has
studied attentively the variation of the collected material and
compared this with the variability of an equal number of culti-
vated specimens of the same species, belongs to a varissima
species.

If we only take the necessary trouble we shall see that varia-
tion (it may be complexity or plasticity) in the state of nature
is greater than we fancied. In July and August, 1916, I com-
pared several hundreds of specimens of Dactylis glomerata
collected between Withington and Alderley Edge (near Man-
chester), along the roads, on meadows, on waste ground and on
the heath. Although shady and distinctly wet places were
purposely excluded, the plants were very variable with regard
to the length of the internodes, the dimensions of the leaves,
the number and the length of the branches of the panicle and
the density of the clusters of spikelets. When the extreme
forms were placed side by side it seemed at first sight as if they
belonged to different species. Phleum pratense was observed in
the same way in the same district : in this species the variation
was on the whole less marked, although notable in the length
of the spike-like panicle (from 8 to 166 mm.).!_ I have made
similar observations in Flanders, observing the variation of
several properties of Centaurea nigra, Calluna vulgaris, Stellaria
holostea, Stellaria media, Stellaria uliginosa, Primula elatior,

1 Holcus mollis is exceedingly variable (plastic) in the Manchester district.
The herbarium of the University of Manchester contains an unlabelled
specimen of Ph. pratense the inflorescence of which has a length of 194 mm.
OBSERVABLE PROPERTIES OF EACH SPECIES 19

Hypericum perforatum, etc. I was again and again brought
to the conclusion that the species under natural conditions
are on the whole more variable than we are tempted to
believe.

Among wild animals examples of astonishing variation are
found as soon as attention is paid to a large number of speci-
mens. EXAMPLES (observed in Flanders): Rana tempo-
varia is very variable with regard to its colour. This is also the
case with A phrophora,' Eristalis tenax,? Neritina fluviatilis, etc.
On the dunes near the Flemish coast (Ostend, Blankenberghe,
etc.), on certain hot summer days, Coccinella novemdecim-
punctata is found in millions of specimens. If one collects
several hundreds of them, places them side by side and observes
them with a glass, one is astonished by their diversity. It is,
however, very difficult to accept the suggestion that com-
plexity is here in play.

The above examples of variation among animals are rather
exceptional. It is incontestable, however, that even in ordinary
cases we overlook variation in the state of nature because we
almost never compare a sufficient number of specimens.

The conclusion is that the influence of cultivation and
domestication on variation is on the whole less important than
we have been told. Many years ago, at a time when our know-
ledge of variation was incomplete, attention was called to the
variation of cultivated and domesticated species (DARWIN).
Ever since, numerous new observations have been made, but
the fundamental distinction between complexity and plasticity
has been continually overlooked. Preconceived theories
(Darwinism, Neo-Lamarckism), combined with the obsession
of adaptation, have prevailed too much in the minds of many
observers.

§ 24._VARIATION UNDER CULTIVATION (continued).
PLASTICITY OF MONOTYPIC SPECIES.—When we bring
a plant species under cultivation the conditions of existence are
more or less modified. They may be less favourable? than in
the state of nature, or they. may be on the whole better, the
plants being grown in a manured soil, at sufficient distances
from one another, and watered, and protected against the pre-
judicial influence of weeds. The gardener often succeeds, after
several fruitless attempts, in finding the best possible conditions.

1 Here variation depends probably to a considerable extent on the fact that
the larve of Aphr. spumaria live on various species of plants.

2 This species was formerly exceedingly common in Flanders, the larve
being injurious to flax in the rettories (retting-ponds). It has been, like
many other flower-visiting insects, almost completely destroyed by the cool,
rainy summers of 1909-1910. In 1911 it was rather a rarity.

3 That is to say, less appropriate to the needs of the species.
20 THE QUANTITATIVE METHOD IN BIOLOGY

This is the ordinary rule in nurseries... What is the influence
of the new state of things on plasticity, the material being
monotypic (a monotypic species or a subspecies) ? .

Under the new conditions certain reactions of the living
substance of the species are modified ; certain properties and
even the facies are altered. In the successive experiments
various alterations occur. We say that the species varies or is
beginning to vary under cultivation. This ts a misuse of terms.
The faculty of varying, which depends on the specific living
mixture, is not modified; only the visible properties are
deviating from their previous state. ;

EXAMPLE: In the state of nature the length of the in-
florescence (spike-like panicle) of Phieum pratense, for instance,
varies ordinarily between 2 and 10 cm. (proportion, 1:5;
mean length, 6 cm.), the extremes being uncommon. In a
given garden the limits are, for instance, 3 and 15 cm. (propor-
tion, 1:5; mean length, 9 cm.), the extreme values being
easily found, since numerous specimens are growing on a small
area. The absolute value of the difference between the limits
is increased, and therefore we may have the impression that
the species is more inclined to vary, although the degree of
plasticity, considered as a specific property, 1s not modified.”
(It is moreover possible to find under natural conditions speci-
mens the inflorescence of which has a length equal or even
superior to that of the longest inflorescence observed under
cultivation.)

§ 25.—VARIATION UNDER CULTIVATION. MONO-
TYPIC SPECIES (continued). NEW PROPERTIES.—Under
given conditions certain possible reactions of a species do not
take place, the corresponding properties being latent (§ ro). I
take as example the fasciation of the stem. Suppose that a
species in which fasciation has never been observed under
natural conditions is cultivated in a garden. It may happen
that a number of stems become more or less fasciated. In this
case it seems to be unquestionable that variability has been
augmented by cultivation,? for a new property has appeared,

1 Tf it seems impossible to obtain healthy, vigorous (commercial) plants, the
experiment is abandoned. Failures are very rarely published or even men-
oe and we are told nothing about variation under unfavourable con-

ons.

* The possibility that altered conditions of existence may really modify
temporarily the degree of plasticity (by altering the quantitative composition
of the living mixture ; see § 8a) is not excluded a priori, but we have no
exact information about this. It is only by delicate experiments and by the
aia of the quantitative method that an answer to this question can be
ound.

* Using a well-known expression, we might say that the species has gone
mad (Vespéce est affolée).
OBSERVABLE PROPERTIES OF EACH SPECIES 21

and this property is variable.1 Nothing, however, is changed
in the specific plasticity. The property fasciation becomes
visible, in the same way in which the floating leaves of Ranun-
culus sceleratus (see § 12) become visible when this species is
developed in water.

§ 26—VARIATION UNDER CULTIVATION (continued).
COMPLEX SPECIES.—Suppose now that the species which is
brought under cultivation is a complex one, consisting, for in-
stance, of two subspecies. If these coexist in the same locality
(which is very often the case), hybrids may occur. Many hybrid
specimens resemble one of the parents, although one (or several)
properties of the other parent are latent in them. If one of the
seeds collected in the state of nature is a hybrid, we may obtain
in the garden, in the first or in the second cultivated generation,
specimens of two kinds (regression, MENDEL), and according
to the principle of segregation (MENDEL. See § 33), it may
happen that even more than two kinds of plants appear,
and this may be repeated in several successive cultivated
generations.”

Numerous species which are looked upon as being mono-
typic are actually complex. Some of their subspecies, being
rather rare, are overlooked or looked upon as being occasional
deviations, monstrosities, anomalies and, in general, curios-
ities. On the other hand, many of them have been described
as varieties or species properly so called.4 It may therefore be
surmised that many species which have afforded examples of
new properties when brought under cultivation were actually
complex species. If we don’t know that a cultivated species
is complex, we may be tempted to believe that variation has

1In the given example (observed in my private garden with Cnothera
biennis ; seeds collected at Deurel, near Ghent) the differences between the
cultivated specimens with regard to fasciation depend on differences in the
conditions of existence. These conditions are always different from one
specimen to another, even when all possible precautions to avoid them are
taken by the gardener. Ifthe plants, for instance, are sown in a seed-pan and
afterwards transplanted one by one, a slight difference in the manipulation
of two specimens (roots more or less disturbed, young stems more or less
pressed between the fingers, etc.) may have an important influence upon their
further development.

2 In this way new forms (new combinations of properties), which have never
been observed before, may be obtained.

3 EXAMPLE: In Flanders, Centaurea cyanus includes, as far as I know, three
subspecies : (1) blue flowers, very common ; (2) white flowers, uncommon ;
(3) purplish flowers, rare. Many seed-fixed subspecies of Centaurea cyanus
are found in seedsmen’s catalogues (see, for instance, the price list of HAAGE
and SCHMIDT, Erfurt). See also Solanum nigrum, § 13.

4Innumerable species of Mentha, Salicornia, Evythrea and many other
polymorphic genera have been described. Although the great majority of these
so-called species are simply based upon variants (variations produced by con-
ditions of existence), there are certainly a number of subspecies among them.
22 THE QUANTITATIVE METHOD IN BIOLOGY

been increased by cultivation, although the observed facts are
simply a consequence of the laws of hybridization.

§ 27. VARIATION UNDER CULTIVATION (continued).
COMPLEX SPECIES. LATENT PROPERTIES.—It may
happen that a species which is in fact complex has been
hitherto considered monotypic, because the characteristic
properties of one or several of its subspecies are practically
always latent under natural conditions.1 HUGO DE VRIES
has demonstrated, by means of numerous admirable experi-
ments, that a number of so-called monstrosities (anomalies)
are peculiar subspecies (DE VRIES calls them races). Certain
of them are exceedingly rare in the state of nature, but in a
garden they are obtained in numerous specimens when culti-
vated under very favourable conditions. In the same garden
their characteristics become again latent whenever the condi-
tions (manure, etc.) become less favourable. : ;

I take as an example Dipsacus silvestris. Although this species
is common in Europe, very few botanists have seen a specimen
of subspecies torsus DE VRIES, characterised by a twisted
stem; it has probably never been mentioned in any flora.?
HUGO DE VRIES, starting from the seed of one specimen,
cultivated this plant for years and succeeded in obtaining an
unlimited number of specimens as often as the conditions of
existence were very favourable. In the most favourable cases
about 30 per cent. of the cultivated specimens were twisted.?

Suppose now that a sample of seed taken at random from
ordinary specimens (which do not exhibit any visible trace of the
properties of subspecies torvsus) was used to start a culture, and
that we were quite ignorant of the experiments of DE VRIES
and even of the existence of twisted stems. If one of the
parental plants happened to be a éorsus with latent properties,
or if one seed was fertilized by a pollen grain from a latent
torsus, it might happen that in the garden, in the first or ina
subsequent generation, one or several specimens would exhibit

1 Compare § 25 (latent properties of a monotypic species).

2 T have observed thousands of specimens of D. stlvestyis in Flanders (Nieu-
port, Ostend, Blankenberghe, Ter Neuzen, etc., on clayey soil without lime-
stone) and in the valley of the Meuse (between Huy and Namur, on rather
clayey soil, limestone district). I did not succeed in finding a single specimen
of the handsome subspecies torsus, although its characteristics are very
apparent.

3 Some years ago Prof. H. DE VRIES kindly sent me some seeds of his
D. silv.torsus. Thirty-one plants were obtained and carefully cultivated on a
bed in the Botanic Garden at Ghent by the head gardener, J. V. BURVENICH.
Unfortunately the spaces between the plants were too small. This is very
probably the reason why only one twisted specimen appeared. It grew at a
comer of the bed, under better conditions than the others, because it there
found plenty of space for its development. Seed was collected by Mr J. V.

BURVENICH, who unfortunately fellill and died soon afterwards. After his
death the seed was not found.
OBSERVABLE PROPERTIES OF EACH SPECIES 23

the characteristics of torsus. One might think that a very re-
markable variation has been brought about by cultivation,
the more so because the twisted stems would be hereditary by
further cultivation under favourable conditions. Many horti-
cultural species which have been found in a seed-plot have
probably a similar origin. In reality, in such cases, no new
form is produced, the property of plasticity is not modified, but
unusual external causes have brought about unusual reactions
of the living mixture, which are no longer observed as soon as the
unusual causes have ceased to prevail.

Among the subspecies (races) which have been investigated
by H. DE VRIES in the same way as D. silv. torsus, with
similar results, several subspecies with fasciated stems, ascidi-
form leaves, three cotyledons, etc., may be mentioned.

§ 28—VARIATION UNDER CULTIVATION (continued).
REMARKS.—I think that the great majority of the examples
of variation under cultivation, which are mentioned in bio-
logical literature may be brought into the four following
groups :—

(xt) Greater variation under cultivation is simply a delusive
appearance, a consequence of incomplete information about
plasticity in the state of nature (§§ 23, 24).

(2) Certain properties which are. always or almost always
latent under natural conditions become observable under the
unusual conditions which prevail in a garden (§ 25).

(3) When the cultivated material is regarded as being mono-
typic, although it is complex, the properties of certain of its
monotypic components may become visible under cultivation
because certain specimens are hybrids (§ 26).

(4) When the cultivated material is looked upon as being
monotypic, although it is complex, the properties of certain of
its monotypic components which are latent or very rarely
observable in the state of nature may become visible under
the new conditions which prevail under cultivation (§ 27).

It is easily realized that several of the possibilities alluded to
may coexist and bring about various and intricate combina-
tions in one group of cultivated plants.

In short, it seems as if our ignorance about complexity and
plasticity among plants and animals under natural conditions
were the origin of the belief that variability is increased by
cultivation or domestication. (A restriction is made in note 2
on p. 20; see further the present paragraph.)

Botanists and zoologists who are collectors may make much
progress by observing and collecting specimens which exhibit
unusual properties, inscribing on the labels exact information
about the conditions of existence and about certain properties
24 THE QUANTITATIVE METHOD IN BIOLOGY

(colours, etc.) which often disappear in the collections after a
certain time. This method has been followed by Mr PH.
DAUTZENBERG (Paris), in whose princely collection of
shells the variation of numerous species is represented by
unrivalled series of specimens.

It is, however, possible that the unusual conditions of life
which prevail under cultivation may result in a quantitative
modification of the living substance of certain specimens (note 2,
p. 20), or may produce, directly or indirectly, a qualitative
change—that is to say, a mutation. (See §§ 8A and 9.)

It would be safer to have recourse to those hypotheses and
to use the terms sport, saltation or mutation only after we have
tried in vain to find another explanation.
PART III

QUANTITATIVE METHOD AND PRIMORDIA

§ 29—SUMMARY OF PARTS I. AND II. (§§ 1-28).—The
living substance of each monotypic species (or subspecies) is a
mixture of a certain number of chemical entities (bioproteins ?),
each specific mixture differing from all others at least by one
component. When the qualitative composition of a specific
mixture is altered, a new specific form (sport, saltation or
mutation) is produced.

Each observable property of a species is produced by a
reaction in which its living mixture as well as external causes
(conditions of existence) play a part. In each species the
number of possible reactions and therefore of possible pro-
perties is very large. In a given specimen a part only of the
possible properties is observable, the others being latent.
External causes (temperature, light, food, etc.), which are, of
course, very variable, determine which properties are observ-
able and which are latent in each specimen. This produces
variation (plasticity ; variants) within the limits of each species
without any qualitative alteration of its living mixture.

External causes may produce a quantitative alteration of
a specific mixture. This alteration (and the corresponding
alterations of the observable properties) may be transmitted
by inheritance and augmented by (artificial) selection (but
never beyond the specific limits as long as the external causes
do not bring about a saltation).

Another form of variation depends on complexity. A
species is complex when it consists of two or more subspecies
which differ from each other by qualitative differences in the
constitution of their living mixture slighter than the specific
differences. Each subspecies is plastic just as is the species.

In both plasticity and complexity the variation of a given
observable property may be continuous or discontinuous
(§ 21).

In Part II. I have mentioned a number of facts which
prove that plasticity is greater than is actually realized by
most biologists.

When we say that the (observable) properties of a species
are hereditary, we must add the proviso that they are trans-
mitted only when the external causes remain the same in the

25
26 THE QUANTITATIVE METHOD IN BIOLOGY

successive generations. It is more accurate to say that
THE POSSIBILITIES ARE HEREDITARY.

To discover all the possibilities of a species, we ought to
observe it under all possible conditions of existence. ;

A classification of the living species based upon their
observable properties is of an empirical nature. A rational
classification based upon differences of chemical constitution 1s
impossible in the present state of science. Our classifications
are founded on the postulate that specimens in which the
same possibilities are hereditary are identical (or similar) with
regard to the constitution of their living substance and belong
therefore to the same specific form or systematic group (pure
line ? ; subspecies, species, etc.). ; .

We are still ignorant of the mechanical relations which exist
between a given property of a species and its chemical constitu-
tion. In spite of this, certain hypotheses about the chemical
constitution of the living substance (hereditary factors, etc.)
may have a heuristic value and render good services.

§ 30—QUANTITATIVE DESCRIPTION OF THE PRO-
PERTIES.—The properties (characteristics) of animals and
plants are ordinarily described by means of terms. This
method is unsatisfactory ; terms are vague, and the descrip-
tions in faunas and floras leave us often in doubt as to the
identification of a given specimen. Is it possible to give a
quantitative description of the living individuals and species,
expressing the individual and specific properties by measure-
ment ?

The quantitative method has been already used along five
different lines—viz.

(t) In the description and classification of species. (LIN-
NUS, LATREILLE, etc. See § 31.)

(2) In biometry properly socalled. (QUETELET, GALTON,
PEARSON, WELDON, etc. See § 32.)

(3) In the study of hybridization. (MENDEL. See § 33.)

(4) In phyllotaxis, including floral diagrams. (See § 40.)

(5) In the measurement of certain physiological functions
and corresponding properties. (See § 41.)

1In a similar way the state of equilibrium of a chemical entity (species)
which is called its crystalline form depends on aspecific possibility which takes
the form of an observable property under certain conditions. In chemistry
and mineralogy a confusion between the terms possibility and property is of
no consequence, any ambiguity being precluded by our knowledge of the
chemical structure of the entities. In a living species properties appear and
disappear and are altered without any alteration of the possibilities, but the
chemical constitution on which the latter depend is up to the present time
unknown. Therefore, if we want to avoid ambiguity, we must always bear
in mind that the state of equilibrium (see § 43) which we call a property is
the temporary realization of a possibility (potentiality) of the species.
QUANTITATIVE METHOD AND PRIMORDIA 27

§ 81—THE USE OF THE QUANTITATIVE METHOD
IN THE DESCRIPTION AND CLASSIFICATION OF
SPECIES.—LINNEUS adopted a classification of the vege-
table kingdom founded to a large extent on the number of
stamens and pistils. For instance, the classes I. to X. of the
Linnean system included plants with one, two... ten
stamens. Each class was divided in its turn into orders
according to the number of pistils, etc. This system has been
severely criticized and even violently attacked. It is certainly
unnatural, but botanists have overlooked the creative power
of the principle upon which it is based.

In the description of the mammalia we use the dental
formula which indicates the number of incisors, canines, etc.,
in each species.

The ichthyologists find important specific characteristics in
the number of dorsal and anal fins, in the number of their rays
and also in the number of scales.

In the description of articulate animals much importance is
attached to the number of segments (somites, articles) of the
body, the legs, etc., the number of eyes, and even the number
of certain kinds of hairs. LATREILLE is the author of a
classification of the coleoptera based upon the number of seg-
ments of the tarses (Pentamera, Heteromera, Tetramera, etc.)
which has rendered and is still rendering good services.

The mosses have been classified according to the number of
teeth of the peristome.

One of the first applications of the quantitative method has
been the measurement of the facial angle. An interesting
application is the so-called bertillonage. This is the description
of a person by means of a combination of figures, obtained by
measuring certain properties.

We see from the above examples that the quantitative
method has already been used to a large extent.

Most biologists, however, look upon the use of quantitative
data as being something artificial They overlook their
PRACTICAL importance for the identification and the exact
description of living beings—in general, for the exact descrip-
tion and comparison of biological facts—whatever may be their
value as a base of classification and independently of any
theory.

§ 82—THE MEASUREMENT OF VARIABLE PRO-
PERTIES. BIOMETRY.— The use of the quantitative
method has been hitherto almost entirely confined to the
measurement (including counting) of properties which are 7n-
variable or almost invariable. Its application is more difficult
when we want to investigate variable properties. Every
28 THE QUANTITATIVE METHOD IN BIOLOGY

species is variable in respect of almost all its properties: we
realize this better when we have recourse to measurement than
when we content ourselves with mere observation.?

EXAMPLES OF QUANTITATIVE VARIATION IN
PLANTS: In Mnium serratum (an acrocarpic moss) I have
measured the length of the leaves of a number of fertile stems.
In one stem this length varied between 1-02 and 4-71 mm. In
the same species the number of cells of the leaves of the fertile
stem (counted in the transversal direction, at the place of the
greatest breadth of the leaf, excluding the differentiated border
and the nerve) varied between 20 and 57.

In an allied species (Mn. subglobosum) the limits were:
length of the leaves, 1-02 to 7-34 mm.; number of cells, 23
to 106.

EXAMPLES OF QUANTITATIVE VARIATION IN
ANIMALS : In twenty-eight specimens of Scturvus carolinensis
four properties were measured by J. A. ALLEN.? The
extreme values were: length of the body, 8-25 to 10-20 inches ;
length of the tail, 6-75 to 8-75 inches. In the fore-foot the
range of variation was less and in the head smaller still.

In Pseudoclytia pentata (a hydromedusa) the radial canals
were counted by A. G. MAYER ®#?: the extreme values were
2and8. (See also Fig. 1.)

Whatever may be the measured property, the figures seem
at first sight to be capricious and independent of any rule
whatever. The majority of biologists have been discouraged by
the disconcerting variation which is almost always observed,
and look therefore upon dimensions and numbers as being of
accessory importance.

More than seventy years ago QUETELET ‘ initiated a new
method for the quantitative study of variable properties.
According to this method a given property is measured in a
large number of specimens of the same species (one of the
examples studied by QUETELET was the height of soldiers).
The distance between the limits (extreme values) is divided
into a certain number of equal intervals; the specimens are
distributed among the intervals according to their value
(individual figure). In this way a variation curve of the

1 Properties which are really invariable are exceedingly rare. Forinstance,
the number of fingers in man seems to be invariable. Examples of (hereditary )
polydactyly are, however, not so rare as one is tempted to believe. Even
examples of cyclopism (one eye on the median line) have been observed.

2 Bull. Mus. Comp. Zodlogy, Harvard, 1871. Quoted according to
H. M. VERNON, Variation in Animals and Plants (Internat. Scient. Series,
London, 1903), p. 4.

‘ 3 Science Bull. Brooklyn Museum, vol. i. Quoted according to VERNON,
0c. cit., P. 90.

4 QUETELET, Lettres sur la Théorie des Probabilités, Brussels, 1846. An-

thropométrie, 1870. QUETELET was born at Ghent in 1805.
QUANTITATIVE METHOD AND PRIMORDIA 29

measured property is obtained, which may be represented by a
table of figures, or plotted out in the form of a diagram, in
which the intervals are represented by equal segments of a
horizontal line and the number of specimens in each interval
by the length of a corresponding vertical ordinate erected in the
middle of the interval.

EXAMPLE: D. C. M‘INTOSH has measured the disc-
breadth of 1000 specimens of Ophiocoma nigra. The following
curve was obtained (in millimetres) :—

Disc-breadth 4 § © 9% 8 9 10 mm.

Specimens 6 I7 34 59 109 137 195
Disc-breadth II 12 13 134 15 16 I7 mm.

Specimens 174 141 90 26 g9 I 2

The arithmetical mean of all the measurements (10,106 mm. :

 

ee

 

T T T T —T T T T : ve

Fic. 1.—Variation Curve of the Disc-Breadth of Ophiocoma Nigra.
14 Intervals

1000) is 10-11 mm. The most frequently occurring measure-
ment is one of Io mm.

We remark (1) that there is a heaping up of the measure-
ments (specimens) in the region of the mean value; (2) that
measurements deviating from the mean (hump of the curve)
occur less and less frequently in a vough proportion to their
degree of deviation; (3) that the measured property varies
between certain limits (4 and 17 mm.); (4) that the distribu-
tion of the measurements follows approximately the law of
frequency of error and is therefore ruled by chance (see § 108) ;
(5) that two factors are taken into account: the absolute value and
the frequency of each measurement. (Example: the frequency of
the specimens the disc-breadth of which is 7 mm. is 59 : 1000.)

Using the method of which the above example gives some

1D. C. M‘INTOSH, “Variation in Ophiocoma Nigra,’’ Biometrika, vol. ti.
(1902-1903), PP. 463-473.
30 THE QUANTITATIVE METHOD IN BIOLOGY

idea, the variation of a large number of properties of numerous
species has already been investigated. According to QUETE-
LET, the mean value may be taken as a measure of the property
under consideration.

By means of a variation curve we may calculate not only the
mean value, but also the probable error. ,

This may be represented in the following way (according to
GALTON) :—Suppose that a given property has been measured
in 2 specimens ! (for instance, the height of soldiers taken at
random in a certain district, or the length of the spike of the
main stem of specimens of rye taken at random from a field).”
When all the specimens are placed side by side, in the order of
their individual lengths, the smallest one being N®r and the
largest one being N°», the specimen M, which is in the middle

(at the place ), represents very approximately the mean
value. The difference D between the figure of M and that of
the specimen Q, which is at the place ” is the negative mean

deviation. In the same way the difference D! between M and
the figure of the specimen Q, which is at the place o is the
positive mean deviation. In a perfectly normal (symmetrical)
curve D and D? are equal in value, but as no experimental
result is perfect, they usually differ slightly in amount. A
mean between the two is therefore taken: this mean is the

D+D)

probable error = =
EXAMPLE: I put down x=1000. The mean between the
specimens 500 and 501 (these specimens differ very little or not
at all in amount) is the measure of M. In the same way the

 

mean between the specimens 250 and 251 (place ? is Q, and the

mean between the specimens 750 and 751 (place 3”) is Q».

‘The probable error is a measure of the degree of spread of the
curve ; it is an index of the variability of the property under
consideration.?

1n being a large number ; for instance, 1000.

2 The latter example (rye) was studied in the Botanic Garden at Ghent by
Dr C. DE BRUYKER.

3 That is to say that 50 per cent. of all the measurements fall below it in
magnitude and 50 per cent. above it.

“The quotient probable error : mean value is the relative probable ervor. By
means of the latter value the degree of variability of two or several series of
observations (differing by their mean values) may be compared.

Another method of expressing the variability of a property is to calculate
the arithmetical mean error,
QUANTITATIVE METHOD AND PRIMORDIA © 31

The importance of the ingenious statistical method initiated
by QUETELET was not realized for many years. His work
has been scorned and ridiculed by certain biologists.

WALLACE has done perhaps more than any other scholar
to call attention to the method of QUETELET, by giving in
his widely distributed book on Darwinism 1a series of diagrams
illustrating the variation of certain properties in several animal
species.

QUETELET'’S results have been confirmed and extended by
FRANCIS GALTON,’ who ultimately introduced the statistical
method into biological science.

Among the numerous statistical researches which have
already been published, the experiments of JOHANSEN on the
pure lines (see § 19) deserve a special mention, not only because
the notion of pure lines is important in itself, but because this
author has called attention to the importance of the extreme
values and also to the fact that two or several distinct curves
may produce by their association one regular variation curve, in
which it is impossible to discover (without experiment) or even
to suspect the heterogeneity of the material.

In Igor a special review, Biometrika,® devoted to biostatis-
tical researches, was founded by WELDON, PEARSON and
DAVENPORT, and this part of biological science has been
called Biometry. A large amount of valuable material has
already been collected. The biometrical researches, however,
have been hitherto rather fragmentary.

The biometricians have constructed numerous variation
curves and skilful calculations have been made, but the in-
vestigated properties have been taken a good deal at random,
from species which belong to very different groups of the zoo-
logical and botanical kingdoms. Although numerous examples
of correlation have been studied, there exist on the whole neither
morphological nor physiological relations between the pro-
perties which have been the object of measurement, and there
is no systematic relation between the species of which pro-
perties have been measured. Therefore descriptive natural]
science has only in exceptional cases found any help from the
results of biometrical work, however important this work may
be in itself.

There seem to be, moreover, two weak points in biometry :
FIRSTLY, the exaggerated importance ascribed to the mean
value. A mean value is not always the quantitative expression
of a fact, of a reality; it is often a rather artificial result of

1ALFRED RUSSEL WALLACE, Darwinism. London, Macmillan, 1890.

2F, GALTON, Natural Inheritance. London, Macmillan, 1880.

3 Biometrika, a Journal for the Statistical Study of Biological Problems, edited

in consultation with FRANCIS GALTON by W. F. R. WELDON, KARL
PEARSON, C. B. DAVENPORT, Cambridge University Press,
32 THE QUANTITATIVE METHOD IN BIOLOGY

calculation. There is often a complicated relation between a
given mean value and the thing which it is regarded to express.*
This relation is very diverse, according to the case under con- :
sideration, and it is sometimes very difficult or even impossible
to make it clear. When the significance of a mean value is
vague, any figure deduced from it is still more vague (this
question is expounded in Part VI., especially in §§ 109, 110, 116).

In biometrical literature some examples of a SECOND weak
point are found. When we have collected a series of figures
by measuring a property in a number of specimens, we are
tempted to believe that the observed differences depend on
chance (according to the principle laid down by QUETELET) and
our calculations are based upon this belief. This is, however, not
always the case. There are sometimes between the collected
figures certain relations which are not governed by the laws of
chance (probability), but by the laws of gradation. If chance
and gradation are not distinguished, confusion is inevitable.
This difficulty has not always been avoided. (See Part VIII.
See also variation steps, § 127.)

§ 88. — APPLICATION OF THE QUANTITATIVE
METHOD ON THE STUDY OF HYBRIDIZATION.
MENDELISM.—The use of the quantitative method in bio-
logical science has been initiated along a third line by
GREGORIUS MENDEL in 1865-1866.2, This author chose
Pisum sativum for his subject. Varieties (subspecies) in culti-
vation are distinguished by striking characters recognizable
without trouble. The plants are habitually self-fertilized.
Following his idea that the heredity of each character (property)
must be separately investigated, he chose a number of pairs
of properties, and made crosses between subspecies differing
markedly in respect of one pair of properties. MENDEL took,
for instance, two subspecies of which one was tall, being 6-7
feet high, and the other was dwarf, 3 to 14 feet (the pair of
properties is here tallness-dwarfness).

These two were crossed together. The cross-bred seeds
thus produced grew into plants which were always tall, having
a height not sensibly different from that of the pure tall sub-
species. I call these plants F, (first filial generation). The

1In other words, a mean value is often am indirect expression, not the direct
expression of a reality.

* See W. BATESON, Mendel’s Principles of Hevedity (Cambridge University
Press, 1909); Xiv.+396 pp., with three portraits of MENDEL, 6 coloured plates
and 33 figures. This book contains a very instructive and complete account
of the subject, a biography of MENDEL and a translation of his memoir,
which was published in Verhandl. Naturf. Ver. in Briinn (Abhandlungen, vi.
1865) and appeared in 1866.

The short and simplified account given in the present paragraph is borrowed
from BATESON (pp. 8-11) and MENDEL (BATESON, loc. cit., pp. 332-335)-
QUANTITATIVE METHOD AND PRIMORDIA — 33

property tallness, which appears in F, to the exclusion of the
opposite property, was called by MENDEL a dominant char-
acter ; dwarfness, which disappears in Fy, he called recessive.

The tall cross-bred F, in its turn bore seeds by self-fertiliza-
tion. These are the next generation F, (second filial genera-
tion). When grown up they proved to be mixed, many being
tall, some being short, like the tall and the short grandparents
respectively. Here the quantitative method was applied.
Upon counting the members of this F, generation it was dis-
covered that the proportion of talls to shorts exhibited a certain
constancy, averaging about three talls to one short, or, in other
words, 75 per cent. dominants to 25 per cent. recessives.

These F, plants were again allowed to fertilize themselves
and the offspring F, of each specimen was separately sown. It
was then found that the offspring F, of the recessives (F,
dwarfs) consisted entirely of recessives. Further generations
bred from the recessives again produced recessives only, and
therefore the recessives which appeared in F, are seen to be
pure to the recessive property (dwarfness). But the tall F,
plants (dominants) when tested by the study of their offspring
F;, instead of being all alike, proved to be of two kinds—viz.

(a) Plants a which gave a mixed F, consisting of both talls
and dwarfs, the proportion showing (just as in F,) an average
of three talls to one dwarf (75 : 25).

(0) Plants 6 which gave talls only and are thus pure to tallness.

The ratio of the impure plants a to the pure plants b was
as 2:1. The whole F, generation therefore consists of three
kinds of plants, although, by external appearance (visible
properties), it seems to consist only of two kinds. There are,
in fact, in F, two kinds of dominants (a and 6)—-viz.

 

25° D ; 50a a 25°lo
pure dominants impure dominants recessives
° = ; ,
3 dominants I recessive

The result is exactly what would be expected if both male
and female germ-cells of the cross-bred F, were in equal number
bearers of ether the dominant (D) or the recessive (A) property,
but not both. If this were so, and if the union of the male and
female germ-cells occurred at random, the result would be an F,
family made up of (supposing 100 seeds to be taken) #

25 DD+25 DR+25 RD+25 RR

1In each pair of letters the first letter represents a § and the second a?
germ cell.

If the union occurred at random, the four possible combinations Dé x D@,
D& xR, RS xD? and Rs xR? would occur in equal numbers, because
there exists no reason why one sort of combination would be more favoured
than any other.

Cc
384 THE QUANTITATIVE METHOD IN BIOLOGY

But, as the first cross (between two subspecies) showed, when
D meets R in fertilization the resulting individual (F,) is in
appearance D (the property R being latent); therefore F,
appears as 3D: 1R (the property R being concealed in DR and
RD). The results observed in the F, generation are in exact
agreement with this suggestion, for the RR plants (in F,) give
an offspring with the property R only, and of the plants in
which D is visible one-third (DD) give D only, while two-thirds
(DR+RD) give the same mixture (3D +1) which was pro-
duced by F,.

Now since the fertilized F, ovum, formed by the original
cross, was made by the union (Df x RQ or Rf xD) of two
germ-cells bearing respectively tallness and dwarfness, both
these elements (possibilities) entered into the composition of
the generation F,; but if the germ-cells which that genera-
tion eventually forms are bearers of either tallness or dwarfness,
there must at some stage in the process of germ formation be a
separation of the two properties (possibilities). This pheno-
menon, the dissociation of properties (possibilities) from each
other in the course of the formation of the male and female
germs, we speak of as segregation.

In the above-described experiment plants were used which
differed only in one essential property. MENDEL crossed
also subspecies of Pisum sativum which differed in two pro-
perties—for instance, a subspecies a with round seeds (property
D) and yellow ‘“‘albumen”’ (property d) crossed with a sub-
species 6 the seeds of which were wrinkled (property R) and
the “albumen”’ green (property 7). The produced seeds F,
appeared Dd like those of the parent a. In each pair of pro-
perties (D, R and d, r) there was thus a dominant (D, d) anda
recessive (R, 7). The cross-bred F, bore seeds F, by self-
fertilization. The F, generation proved to consist (with
regard to the visible properties) of four kinds ! of seeds—viz.

(2) Dd (round, yellow)
(6) Rd (wrinkled, yellow)
(y) Dr (round, green)
(8) Rr (wrinkled, green)

‘In fact, nine combinations occur among the F, plants. This may be cal-
culated by working out
(D+R)?x (d+r/?

The obtained terms are :

(a) D°d?+2DRd*+2D%dr+4DRdr?+

(8) d*R?+2dyR?+

(y) D?v?+2DRr2+

(8) R27?
_ Ineach combination in which R meets D the property Ris latent (concealed);
in the same way 7 is latent when meeting d. Therefore, as is easily seen, the
nine combinations are reduced to four groups, a, 8, y and 4, with reference to
the visible properties. (See, on the use of formulas, §§ 104-106.)
QUANTITATIVE METHOD AND PRIMORDIA — 35

The segregation of each pair of properties has taken place as
if the other pair did not exist. In respect to the pair D, R the
plants are divided into two groups D and R; in each of these
the plants are divided in their turn into two groups d and r—viz.

FP,
—oOCOCO
D R
‘Gr aloo
d rv d v
Visible propertie : . Dd Dr Rd Rr
Groups. ‘ ‘ . a y B 5

In another experiment MENDEL crossed two subspecies
which differed in three properties of the ripe seeds—viz.

Subspecies a: seeds round (D), albumen yellow (d), seed-
coat grey-brown (8).

Subspecies 6: seeds wrinkled (R), albumen green (7), seed-
coat white (p).

In the F, generation eight sorts of seeds were obtained:
Dds, Ddp, Drs, Drp, Rd3, Rdp, Rvs, Rrp. All the results were
governed by the same rules as the two first experiments.
(Complete explanation is given in § 106.)

In a similar way as QUETELET’S work, the discovery of
MENDEL passed unnoticed for a long time. Even the famous
NAGELI failed altogether to realize the importance of it.!
About 1900 MENDEL’S paper was discovered almost simul-
taneously by three botanists, CORRENS, TSCHERMAK and
DE VRIES. These three repeated independently from each
other MENDEL’S experiments and confirmed his results.

Since then numerous researches along the lines initiated by
MENDEL have been carried out. A number of experiments
have given results similar to those arrived at by MENDEL.
In other cases the results of hybridization are more complicated.
Several of these, however, have already been elucidated.

MENDEL has added to biological science a new branch
(Mendelism) which is remarkable by the rigour of its reasoning
and the exactitude of its conclusions. Both qualities are the
result of the use of the quantitative method, based here upon
counting in each generation the specimens in which the pro-
perties of the crossed subspecies are visible, latent or vanished,
and comparing the figures.’

MENDEL not only devised a magnificent method for the

1See BATESON, loc. cit., p. 314. QUETELET and MENDEL met the
same fate as MARIOTTE, KOELREUTER, CHR. K. SPRENGEL and
several other botanists whose fundamental discoveries were overlooked for
many years.

2This method of investigation is quite independent of MENDEL’S skilful
suggestions about dominant or recessive properties and segregation.
36 THE QUANTITATIVE METHOD IN BIOLOGY

investigation of heredity; Mendelism teaches us more than
this.

§ 84-—MENDELISM (continued). THE NOTION OF
SPECIES.—From MENDEL’S experiments and the numerous
experiments carried out by his successors we are allowed to
draw the conclusion that the groups of specimens which we call
species (or subspecies) are distinctly different from one another.
The belief that intermediates (transitions) between the species
exist is an unavoidable consequence of the proposition that sub-
species, species, etc., arise through the transformation of masses
of individuals by the selective accumulation of minute differ-
ences (impalpable changes).!_ As often as intermediates (trans-
itions) are proved not to exist, the above proposition about
the origin of species * cannot be accepted.

In fact, there is ambiguity in the use of the term tntermedzate.
A distinction ought to be made between intermediate with regard
to the properties and intermediate with regard to the possibilities.
(See § 21.)

Intermediate forms (individuals) in respect to one or several
observable properties are very common and this has brought
about a misconception. Those intermediate forms are, in the
state of nature (hybridization being excluded), a result of plas-
ticity (§ 84). They appear and disappear again and again as
often as the conditions of existence are altered. (See, on the
fugitiveness of observable properties, the examples mentioned
in § 12.)

In other words, two species, observed under certain condi-
tions of existence, may be seemingly connected by specimens
with intermediate properties. Between both, however, a
GAP exists with regard to their possibilities (which depend
on qualitative differences in the composition of their living
mixture). Although the gap may be narrow, it is permanent:
there is no continuity.

This view, drawn from the study of innumerable examples of
plasticity, and from the study of systematic natural science, is
supported by numerous facts discovered by MENDEL and his
successors. The distinction between properties and possibilities
becomes evident by the observation of hybrids.

EXAMPLE: When two species (subspecies) are crossed
which differ in one pair of properties D (dominant) and R
(recessive) a new living mixture is produced and two possi-
bilities exist in the offspring. In the first hybrid generation

+“ Once for all, that burden so gratuitously undertaken in ignorance of genetic
physiology by the evolutionists of the last century may be cast into oblivion.”
BATESON, loc. cit., p. 289.

_? Just as any other theory explaining the origin of species by the accumula-
tion of impalpable changes.
QUANTITATIVE METHOD AND PRIMORDIA 37

(F, plants) the possibility D produces a reaction by which the
property D becomes observable. The property R is latent,
although the possibility R exists. In the offspring F, of any
specimen whatever of F, the possibility R awakens and the
property R becomes visible in 25 per cent. of the children. In
a similar way the transmission of the possibilities D and R
may be traced through the F;, F, . . . generations (although
the property R may be concealed in an unlimited lineage of
successive seed-bearers) because the possibility R is permanent
in the impure plants (true hybrids ; heterozygots) DR.

REMARKS: (x) There is no difference in the observable
properties between the DD and the DR plants, although a
difference in the possibilities exists.

(2) The appearance of the property R (which is only possible
in the RR plants) indicates the disappearance of the possibility
D

(3) The possibilities D and R may exist simultaneously (they
are not incompatible) although the properties D and R are
exclusive of each other.

The facts alluded to in the present paragraph are inconsist-
ent with the notion that transitory or transitional forms (con-
tinuity) exist between the crossed species.

§ 85—MENDELISM. THE NOTION OF SPECIES (con-
tinued). EXCEPTIONS WITH REGARD TO THE PRO-
PERTIES.—In certain cases an intermediate property between
the properties D and R is observed in the offspring F, of a
cross.

EXAMPLE: In Hyoscyamus niger subsp. annuus (this is
the ordinary form) the corolla is brown. In H. niger subsp.
pallidus it is pale (the brown colour does not exist). The cross
gives F, plants with flowers of an intermediate tint, almost
exactly as if one part of the brown colour of annuus had
been diluted by addition of one part of the pale colour of
pallidus.

BATESON has given a very interesting discussion of this
subject (intermediates and exceptions, oc. czt., pp. 235-244 and
245-265). He divides the examples of intermediate properties
and other exceptions on the rules laid down by MENDEL into
several classes. On the whole, we may conclude from the facts
mentioned by BATESON that in many examples it is possible
to prove that a so-called intermediate form exists only with
regard to a pair of observable properties, while the possibilities
are distinct and transmitted according to the principle of
segregation.

1CORRENS, “‘ Ueber die dominierenden Merkmele der Bastarde.”’ Ber. deut.
bot. Geselisch. (1903), xxi., p. 133. Quoted according to BATESON, loc. cit.
38 THE QUANTITATIVE METHOD IN BIOLOGY

In some examples the existence of intermediate properties
depends obviously on environmental influences. (BATESON,
loc. cit., p. 243.) For instance, the cotyledons of many sub-
species of peas are in all ripe seeds a full yellow, while those of
many others are a full green. The contrast between the pro-
perties yellow and green in F, (after segregation) may be
perfectly sharp and clear. Some subspecies, however, have many
seeds which are in various degrees partly yellow and partly
green. I have observed that it is sometimes possible to bring
a number of seeds into a series from about fudl yellow to about
full green in such a way that the difference between two succes-
sive seeds is very slight. In such a case, if we overlook the
fundamental distinction between possibility and property,’ the
existence of a gradual passage between the extremes seems to
be incontestable. BATESON, after experimenting with such
kinds, found that the parti-coloured appearance was caused by
exposure to sun and weather. Plasticity is here in play, but
no intermediates exist with regard to the possibilities, although
the latter may coexist in the hybrids.

In other cases an intermediate property is observed in the
hybrids F, and transmitted to the generations F,, F,;.. .
without segregation.

EXAMPLE: The subsequent generations raised from the
hybrids Gnothera muricata x G@. biennis showed no definite
departure from the F, type.’

If this and other similar examples are not susceptible of any
other explanation, the suggestion may be accepted that here a
new, quite distinct living mixture H has been brought into
existence and that therefore a new property H has appeared,
the new mixture differing from the ordinary hybrid mixture
because it finds itself in a state of stable equilibrium which is
permanent and transmissible by heredity.? (Constant hybrid.)

In other words, according to this view, a new subspecies H

1In other words, between chemical constitution and observable reaction.

? HUGO DE VRIES, die Mutationstheorie (Leipzig, Veit & Co., 1901), vol. i.,
p. 67. In several successive generations the hybrid alluded to was constant,
on the whole differing little from C. biennis. The middle radical leaves
of the hybrid were similar to those of G@. biennis and distinctly different from
those of @. muricata by their length, breadth, form, border and nerves. (See
also BATESON, loc. cit., pp. 249-250.)

* This may be rendered more intelligible by the following comparison :—
when a fixed oil is mixed with water the mixture is in a state of unstable
equilibrium : after a certain time segregation takes place and both components
are separated. This corresponds to an ordinary hybrid mixture. When a
fixed oil is mixed with ether the mixture becomes a solution, which is in a
state of stable equilibrium and therefore permanent, without segregation.
This is comparable to the supposed mixture H and also to any ordinary
specific (not hybrid) mixture. It is conceivable that a similar principle finds
eueeaieen in the living mixtures, although these mixtures are very com-
plicated.
QUANTITATIVE METHOD AND PRIMORDIA _ 39

has been produced.’ This subspecies is strictly distinct from
its parents by the seed-fixed possibility H even if the corre-
sponding property H were variable, inclining (goneoclinous)
sometimes toward one of the parents or towards the other,
according to the principle of plasticity. (Compare the variable
colour of the peas, p. 38.)

We might be tempted to call the new subspecies H an inter-
mediate between the parents. The term intermediate implies,
at least in biological language, the idea of transition, gradual
passage, continuity. Since the subspecies 4 is strictly distinct
from both parental species (in spite of the possible variability
of the property H), it is not a transitory form. Therefore I
think it is preferable to call it an interposed subspecies. (See
§ 105.)

The difference between ‘ransitory and interposed may be easily realized by
means of acomparison. The two parental species may be compared to two
terms a and ¢ of a chemical series, for instance—the acrylic series (§ 5), in which
the atoms of carbon are m and ~+2 in number. Between the chemical species
aand c certain differences exist in the observable properties—for instance, in
the temperature of fusion. The subspecies H is comparable to the term }
in which the number of atoms of carbon is +1. The term b is separated
from a and c by two distinct gaps with regard to the constitution of its mole-

cule and also by its melting-point.2, There is no continuity between a,b and c.
The term 0 is not transitory, but interposed between a and b.

The number of facts which are ruled by the principle of
segregation is very large, and the examples which at first sight
seemed to be exceptions, but were later on proved to follow the
Mendelian rule, are already numerous. Even if exceptions
really exist, it is impossible not to accept the principle of
segregation in point of fact as a biological rule.

Perhaps we may again have recourse to a comparison. Every
biologist accepts as a rule the proposition that the develop-
ment of a female germ is impossible without fertilization,
although numerous examples of parthenogenesis are known.

It is also accepted as a vue that flower-visiting insects (bees,
etc.) play an important part in the fertilization of flowers.
The number of species which are partially or completely sterile
when deprived of the aid of insects is so large that any doubt
about the reality of the mentioned rule is excluded, although
many examples of self-fertile plants are known, and although
in a number of flowers which are visited by crowds of insects
attracted by honey and perfumes seeds are produced by
apogamy.

1This conclusion was adopted by JANCZEWSKI with reference to the
hybrid Anemone silvestris x magellanica. (Bateson, loc. cit., pp. 250-251.)

If this suggestion were proved to be exact we would find in hybridization
one of the possible causes of mutation. (In § 9 another possible cause is men-
tioned. See also § 105.)

2 Although this temperature is variable according to external influences,
such as pressure, for instance.
40 THE QUANTITATIVE METHOD IN BIOLOGY

In a similar way the principle of segregation ought to be
looked upon as being a biological rule,! in spite of possible
exceptions. Therefore the conclusion expressed in the first
phrase of § 34 is justified.

§ 86—MENDELISM (continued). SIMPLE AND COM-
POUND PROPERTIES.—A very important result of the
Mendelian experiments is the conception that each property is
in itself something definite, in a certain sense a unit which has
a proper existence. By hybridization it is possible to trans-
plant a given property from one species to another, as if the
living individuals were the soil, the substratum on which the
property grows.

We may express this conception in a different way by saying
that a reaction which results in a certain property may be-
come possible in a species a in which it never occurred before
when the composition of the living substance of a is altered by
hybridization.

From a number of Mendelian experiments it may be con-
cluded that the observable properties ought to be brought into
two classes :

(xr) Simple properties (so-called elementary characters °),
which it is impossible to decompose into more properties. A
simple property might be called a PRIMORDIUM.?

(2) Compound properties, which at first sight seem to be
simple, but depend on the coexistence of two or more simple
properties. In other words, a compound property is a com-
bination of primordia.

This distinction is of the highest importance for the study of
many biological problems, especially in descriptive natural
science, in which simple and compound properties are con-
tinually confounded.

A simple property is seen to be an entity. A compound
property may be decomposed into its components in several
ways, especially by Mendelian segregation. (See § 38.)

EXAMPLES: In numerous cases a given colour of a species
is a primordium, depending on the presence of one colouring
substance. When the coloured species is crossed with a
colourless one, segregation produces in the second hybrid
generation (F,) two sorts of specimens: coloured and colour-

1] avoid purposely the term Jaw. See, on the distinction between law and
tule, my lecture on “The Place of Science in History.” Mem. and Proceed.
Manchester Liter. and Philos. Soc., vol. lix., Part III. (1914-1915), p. 35-

*T avoid the term elementary. This term has various significances (see the
dictionaries) and is therefore one of the rather numerous linguistic nuisances
which embroil our notions and bring confusion to the mind of the biologist.

* This term is used by Lucretius in the sense of chemical element, thus in the
sense of a simple something.
QUANTITATIVE METHOD AND PRIMORDIA 41

less (yellow and white endosperm in maize. See BATESON,
loc. cit., p. 41).

In other cases a colour Z, which seems to be a primordium of
a species s, depends on the coexistence of two colouring sub-
stances a and 6. When the coloured species s is crossed with a
colourless one, since each colouring substance 1s submitted to
segregation independently from the other (see § 33, p. 35), the two
components a and 6 (both dominant when they meet white) are
ied among the F, plants according to the following
scheme :—

 

Coloured species x Colourless species
(Colour Z=a +b) | (Colour white)
one Z)
Fa
all a white ee
oe Hu“é—_éuY OO
b white b white

(colour Z) (colour a) (colour b) (colour white)

In this way two primordia a and 6 which existed but were
not discernible 1 in one of the parental species become visible
in two groups of the F, generation. It seems as if two new
properties had been produced by hybridization.

§ 37—MENDELISM (continued). OBSERVABLE PRO-
PERTIES AND HEREDITARY FACTORS.—In this book
a property is looked upon as being a something which exists in
itself. I content myself with the general notion that a pro-
perty is the product of a reaction of the living mixture, the
observable symptom of a certain possibility, without more.
The scholars of the Mendelian School go further: they try to
analyse the possibilities.

They start from the hypothesis that in each species certain
hereditary factors (determiners) exist which bring about
certain reactions by which the properties are produced. In the
successive generations F,, F, . . . produced by a hybridization,
the factors of the parental species are brought together or
separated from one another according to the rule of segregation.
In other words, the principle of segregation is no longer applied
to the observable properties, but to hypothetical hereditary
factors.

The Mendelians accept further the view that certain pro-
perties depend on the presence of one factor, while others are

1Certain persons who are endowed with a highly developed colour-sense

may be able to discern the colours a and b in the mixture Z of the coloured
species s (for instance, in certain subspecies of Matthiola).
(

42 THE QUANTITATIVE METHOD IN BIOLOGY

produced by the coexistence of two or more factors—that, for
instance, a certain factor C is able to produce a property a as
often as a certain factor A is also present, and another property
b when it meets a certain factor B, but that neither C nor A
nor B are able to produce any observable property when they
are isolated.?

A factor is a hypothetical something which is to be found in
the living mixture. It may be surmised that a factor corre-
sponds to a certain bioprotein, or to a certain abiotic substance
(enzym, chromogen, etc.) 2 produced by the living mixture.
Although it is impossible to reach the actual bottom of the
problem because of our ignorance of the chemical composi-
tion of the living mixture, I think that the theory of the
hereditary factors may be further developed by a more
complete investigation of the primordia 7m a series of species ®
according to the method expounded in the present work.
(See Part IX.)

Whatever it may be, by means of the ingenious but rather
complicated theory of the hereditary factors 4 it has already
been possible to classify and to explain numerous facts which
seemed to be capricious and inscrutable.

It may be remarked once more that this very important part
of natural science is based upon the use of the quantitative
method initiated by MENDEL, counting the specimens which
exhibit a given property and applying the method of calculation
alluded to in the note on p. 34 and completely expounded in
§§ 104-106.

Unfortunately the theory of hereditary factors is hitherto
only applicable in those cases in which hybridization and culti-
vation of the hybrids are possible. When we deal, for instance,
with mosses, ferns and many other living organisms with which
hybridization cannot be carried out with certainty, or with
fossil species, we shall need another method.

Therefore, in order to answer the needs of descriptive science,
I leave the hereditary factors out of account in the present
work, limiting myself to the <tudy of the primordia. I try
. to discern and to express the latter by measurement and to
collect in this way exact notions, by means of which it may be
possible to bring the inventory of living nature into a more
useful form, and to throw more light upon the problems of
heredity and the origin of species. I avail myself as often

as possible of the information collected by the Mendelian
School.

1In other words, the property uw is produced by the coexistence of both
factors 4 and C, the property b by the coexistence of B and C.

2See BATESON, loc. cit., p. 98.

° For instance, in all the species of a genus, a family, etc.

4‘ This subject is expounded in BATESON, loc. cit., passim.
QUANTITATIVE METHOD AND PRIMORDIA 43

§ 88—MENDELISM (continued). SEGREGATION OF
COMPOUND PROPERTIES INTO THEIR COMPONENTS.
COMPARISON BETWEEN MENDELIAN DISSOCIATION
AND SEGREGATION PRODUCED BY PLASTICITY AND
GRADATION AND IN THE COURSE OF INDIVIDUAL
DEVELOPMENT. Cause dissimiles, similes effectus —When
two parental species differing in one pair of primordia D and R
are crossed, both possibilities exist simultaneously in the first
hybrid generation F, and the property R is latent. In the next
generation F, (in the typical cases) the property D is visible
in certain specimens and the property R in others, according to
the Mendelian rule of segregation (dissociation). For instance,
He cross blue flax x white flax gives in F, blue, in F, white and

lue.

Segregation produced by plasticity.—On the other hand, when
we take the offspring of a certain blue Campanula and cultivate
some specimens D at ordinary temperature (15° to 20° C.) and
other specimens R about a temperature of 30° C., the D speci-
mens are blue, the R specimens white. In the offspring under
consideration plasticity has brought about segregation. The
result is the same, with regard to the visible properties, as if
a blue Campanula had been crossed with a white one (§ 16).

When we divide one specimen of Philodendron pertusum
(characterized by perforated leaves) into two parts P and 4,
and bring P into a warm, damp greenhouse and # into a green-
house which is cool and dry, the new leaves of P are perforated,
but in the new leaves of # the characteristic perforations are not
(or hardly) observed. Here, again, segregation is a consequence
of plasticity. The plants P and # differ in an observable
property, just as two specimens of the F, generation produced
by a (supposed) cross between Philodendron pertusum and a
Philodendron with non-perforated leaves.

The species Fagus silvatica includes two subspecies: the
ordinary green beech (leaves green) and the copper beech,
the leaves of which are reddish. When a copper beech is
grown in deep shade its leaves are green; the reaction which
produces the red colour is only possible under the influence of
light.1 Between two specimens taken from a shady and a
sunny place the same difference exists with regard to the colour
as between two specimens of the F, generation produced by a
(supposed) cross green beech x copper beech. In this example
of segregation produced by plasticity all possible transitory
colours are observed between the extremes green and reddish,
according to the variations in degree of light and shade, in the
same way as in certain examples of hybridization continuous

11 call shade and light the whole of the conditions of life which prevail
in a shady or a sunny place.
44 THE QUANTITATIVE METHOD IN BIOLOGY

variation in the conditions of existence results in a series of
transitions between the parental species (with regard to the
observable properties) (§ 35, p. 38).

In the preceding examples! segregation (produced by plasticity)
brings about differences between specimens. It may also happen
that segregation results in a difference between two parts of
one specimen. This occurs in a certain sense in the case of
Philodendron, in which the specimens P and # are, in fact, parts
of one plant. Ina similar way, when the crown of a copper
beech becomes large enough, the leaves which are developed
in the shady central part of the crown are green, while the
peripheral leaves of the same crown, being exposed to sun-
shine, are red.

Some sorts of apples are green or greenish when ripe; other
sorts arered. It often happens that in a fruit of a red sort the
side which is exposed to light becomes red, while the opposite
side is green. Both parts of the apple differ in the properties
red and green, in the same way as two plants of the F, genera-
tion after a (supposed) cross between a seed-fixed red sort and
a seed-fixed green sort. Similar differences between two parts
of one specimen are observed in certain hybrids: among the
hybrids produced by a cross between the ordinary Antirrhinum
majus with personate flowers and the subspecies with peloric
flowers certain specimens bear simultaneously personate and
peloric flowers.

Sometimes plasticity causes segregation in more than two
groups of specimens. In Polygonum amphibium we observe :
(I) a terrestrial form (stem erect, etc.); (2) an aquatic form
(stem flexible, etc.); (3) a xerophytic form (stem creeping,
etc.) (See § 12.)

Decomposition of a Compound Property into Primordia by
Plasticity. We have seen in § 36 that a compound property
may be dissociated into simple properties by hybridization.
Plasticity may produce a similar effect. The colour of the
leaves of the copper beech is a compound property ; we call it
red or reddish, but in reality it is produced by the coexistence
of red and green. In the shade the primordium red becomes
latent and the green colour is isolated.

Another interesting example is afforded by Deschampsia
(Aiva) cespitosa. According to the floras, this species grows
in moist, shady places and its spikelets are silvery-grey or
purplish. I have observed (Gatley, Wilmslow, Hazel Grove;
near Manchester, August, 1916) two forms which differ by
their facies. In moist, sunny places the spikelets are shiny,
purplish (or rather purplish-brown), the grey colour of the
glumes being concealed by a purplish-brown pigment. In

1 These examples are taken from among a large number of similar cases.
QUANTITATIVE METHOD AND PRIMORDIA 45

shady places (in woods) the pigment does not exist and the grey
colour is visible. The spikelets are therefore shiny grey; in
other words, sélvery-grey.

Numerous similar examples will be undoubtedly observed as
soon as the attention of the describing naturalists is called to
this subject, and the descriptions will become more accurate.

Dissociation by Gradation.\—I call gradation the variation of
a given property along a given axis. This subject is ex-
pounded in Part VIII. In this paragraph I content myself
with one example.

In Holcus lanatus (fam. Graminee) the sheaths of all the
leaves of a fertile stem are clothed with down. Holcus mollis
is described as being uot generally so downy. In the latter
species, according to my observations (numerous specimens in
the neighbourhood of Manchester, August-October, 1916), the
primordium downy is variable along the fertile stem, which is
here the axis of gradation. Comparing the successive leaves
from below upwards to the (terminal) panicle, we observe that
the sheath of the lowest leaf is downy”; proceeding upwards
we see that the down gradually diminishes on the successive
sheaths. The sheath of the upper leaf is always deprived of
down (or hardly downy at its base). In this way in Holcus
mollis the property downy is distinctly segregated from the
property glabrous (absence of down) when the upper leaf and
the lower leaf are compared.

If the sheaths of the successive leaves of one fertile stem of
H. mollis are placed in order into a series according to their
position along the axis, the variation of the primordium downy
is the same as it would be among the hybrids produced by a
cross between H. lanatus and a glabrous species of Holcus,
supposing that among these hybrids the extremes (parental
properties) downy and glabrous were connected by a series of
transition forms.* (See § 35.)

According to the above, the difference between both species
may be described in the following way 4 :—

H. lanatus: sheath of the upper leaf of the fertile stem
downy.

H. mollis: sheath of the upper leaf of the fertile stem
glabrous (rarely downy at its base).

1Compare: ‘Segregation of the Parental Characters in Seminal Hybrids
by Bud-Variation.” DARWIN, The Variation of Animals and Plants under
Domestication (second edition, 1875), vol.i., p. 425.

2 The down is still visible during the flowering period, although the sheath
is already fading.

3It would be interesting to know whether a Holcus with glabrous sheaths
exists, and to cross it with H. lanatus. :

4 The description here given is applicable to the specimens observed in the

Manchester district. It would be interesting to repeat my observations in
other districts or countries.
Missing Page
Missing Page
48 THE QUANTITATIVE METHOD IN BIOLOGY

sideration among all the indigenous and cultivated plants of
Central Europe.?

In a similar way, limiting ourselves to the British flora, the
combination leaves angulinerve, perianth of 5 segments, 6-8
stamens, I ovary, 3 styles is found only in the genus Polygonum.

Holcus lanatus is characterized among all the British grasses
by the following combination :—

Property a: each spikelet two-flowered.
a 6: glume of the upper flower of each spikelet awned.
4 c: glume of the lowest flower of each spikelet awnless.
% ad: axis of the spikelet glabrous.
a5 é: sheath of the upper leaf of the fertile stem downy.

Holcus mollis is characterized by the following combination :—
a, 6, c, d and
Property f : sheath of the upper leaf of the fertile stem glabrous.

The combinations abcde and abcdf represent respectively
Hi. lanatus and H. mollis as exactly as the combinations KNOOO
and NaNOOO represent respectively potash-salpetre and soda-
salpetre.

It is ordinarily impossible to find the characteristic combina-
tion of a species without investigating a sufficient number of
primordia in all the species of the genus, the family, etc., to
which it belongs, plasticity, gradation and even (in certain
cases) the succession in the course of the individual develop-
ment being taken into account.

In the floras and the faunas a mere enumeration of properties
of each species is given. The reader, in other words, the un-
fortunate biologist, who wants to identify a plant or an animal
is requested to discover by himself the characteristic combina-
tions.

§ 40.—PHYLLOTAXIS. (See § 30 (4)).—This part of botany,
which is the study of the relative position of the cauloms and
the phylloms, is entirely based upon quantitative data. It
might be called geometrical botany. It includes, among other
things, the knowledge of the floral diagrams, which is of high
importance for descriptive botany. The fundamental principles
of phyllotaxis are expounded in the classic text-books ; therefore
I content myself with this short reference to it.

§ 41—THE QUANTITATIVE METHOD APPLIED TO
PHYSIOLOGICAL FUNCTIONS AND PROPERTIES. (See
§ 30 (5)).—In the physiology of animals and also, to a certain
degree, in the physiology of plants much progress has been
made by the use of the quantitative method. By the measure-

1A combination of properties is comparable to a word, which represents
an exact notion, although each isolated letter is deprived of any significance.
QUANTITATIVE METHOD AND PRIMORDIA = 49

ment of certain vital functions several parts of physiology have
reached a degree of accuracy hardly inferior to the exactitude
prevalent in physical and chemical sciences. I content myself
with a few examples.

The measurement of the so-called personal equation and of
the duration of a sensation produced by a luminous impression
upon our eye (JOSEF PLATEAU) have been the origin of the
modern physiology of the nervous system and the sense organs,
which includes experimental psychology. In this part of
biological science a new world of facts and phenomena has been
disclosed by means of measurement. The relations between
stimuli and the physiological reactions which they produce,
the physiology and the optical contrivances of the human eye,
belong to the most admirable conquests of modern science.
Here INVESTIGATION IS MEASUREMENT and almost
every conclusion is drawn from a comparison of figures.
Similarly the quantitative method has been introduced in
physiology by the application of physics and chemistry to the
study of physiological functions. Our knowledge of aerobic
and anaerobic respiration, the conception of respiration in
general, our knowledge of the osmotic properties of cell-sap
(DE VRIES) and other liquids contained in the body of living
beings (HAMBURGER) have been built up by means of
methods borrowed from physics and chemistry, which are
themselves governed by the quantitative method.

DARWIN’S remarkable experimental investigation of self-
and cross-fertilization is based upon the measurement of the
dimensions and the fertility of self- and cross-fertilized speci-
mens. This line of experimental research is in close relation
with the study of heredity. It is full of promise, although it is
for the time being somewhat overlooked.

In the present state of biological science there is a rather
disconcerting discordance between physiology, which is the
investigation of the functions of the living beings, and descrip-
tive biology, which is the study of the living objects themselves.
In physiology quantitative investigation is already prepon-
derant. In anatomy, morphology, embryology and in the
description of species we still follow almost entirely the quali-
tative method. Physiology would say, for instance, that a
certain thing a is 1-13 times as long as 0}; descriptive biology
would say that a is rather longer than 6. On the one hand an
exact description is used ; on the other hand, vague terms.

§ 41a—Among the students of descriptive biology a pre-
judicial misconception seems to prevail. Many of them seem
to believe that the use of the quantitative method is very easy
and simple when applied to physics, chemistry and physiology.

D
50 THE QUANTITATIVE METHOD IN BIOLOGY

On the other hand, they look upon this method as being an
impossibility in descriptive science, or a fearful something
because of the long labour required for the measurement of the
properties of animals and plants. It seems as if they did not
realize that, for instance, the determination of the duration ! of
the three periods of the contraction of a muscle and the measure-
ment of the relations between fatigue, temperature, intensity
of the stimulus, etc., and these periods require very long and
exceedingly delicate work, and that numerous experiments are
needed to establish one figure.

The aim of the quantitative method in descriptive science is
not only to describe exactly the properties of the species and to
make an inventory of the forms of life. This 1s tmportant enough
in itself, but there is more. It is difficult to obtain exact data
about the development and the anatomy of animals and plants
as long as the observed facts are described by means of mere
terms. It is still more difficult to discover the origin of species
and their phyletic relations without an exact knowledge of the
investigated species. This can only be obtained by comparing
their characteristic figures with the figures of other species.
The object of the quantitative method is, in general, the exact
description of the living objects.

The HAECKELIAN method has been, for more than forty
years, an important instrument of progress. It is, however,
open to certain criticism. (See §50.) Among other things, it has
diverted attention from the quantitative investigation initiated
by QUETELET, MENDEL and also by DARWIN. There-
fore the HAECKELIAN method, in spite of its high merits,
does not enable us to get to the bottom of the biological prob-
lems. It cannot advance our knowledge beyond a certain
limit.

1 Expressed, for instance, in hundredths of a second.
PART IV

THE PRIMORDIA

§ 42—THE ADULT STATE IS A STATE OF EQUI-
LIBRIUM.—Every living being is at the beginning of its
development} in a state of unstable equilibrium. It passes
through a series of transformations, brought about by reactions,
till there is no longer any force (cause) by which a new reaction
might be produced. In this way the individual is brought into
a state of stable equilibrium which we call the adult state.

§ 483—EACH PRIMORDIUM REPRESENTS A STATE
OF EQUILIBRIUM.—As long as we are using the ordinary
biological language we may content ourselves with the notion
that a given individual is adult. This is, however, a complex
notion. When we want to apply the quantitative method we
are compelled to decompose the notion adult individual into
simple concepts representing measurable things. This is
possible by considering each primordium (simple property)
separately.

In the course of the individual development the primordia
appear in a certain order. (DARWIN. See § 38, p. 46.) Each
primordium is the product of a reaction? which begins at a
certain moment and continues till there is no longer any force
(cause) by which further continuation might be produced. At
that moment the material parts which participated in the
reaction have reached a state of stable equilibrium: the pri-
mordium 1s adult.

This brings us to a mechanical definition of the term pri-
mordium: a primordium is the expression of a state of equi-
librium, or, in short, a primordium is a state of equilibrium.

The expression adult individual may be used in its ordinary,
vague sense. In reality an individual is never adult, because
the development of certain of its primordia continues till it has
ceased to live.

§ 44—INDIVIDUAL ADAPTATION (ACCOMMODA-
TION) IS EQUILIBRIUM. (See § 22).—In any reaction (or

1 The beginning of the individual development is very often preceded by a
period of rest. :
2 Or a series of reactions.

51
52 THE QUANTITATIVE METHOD IN BIOLOGY

series of reactions) which results in the production of an adult
primordium, two sets of causes may be discerned (§§ 10 and 18):
on the one hand, internal or specific causes, which depend on the
chemical composition of the living mixture; on the other hand,
external causes, which depend on the environment. The in-
ternal causes may be looked upon as being the same in all the
specimens of a given species, but the external causes are vari-
able from one individual to another. According to this, each
adult primordium is a priori variable in a given species, because
it is, in each individual, in equilibrium with a particular com-
bination of external forces. This equilibrium is called sdi-
vidual adaptation or accommodation. Since all the properties
of a given individual are accommodated in this way, we may
say that the individual, considered as a whole, is accommodated
to (in equilibrium with) its conditions of life. An individual
is accommodated to its environment, not 1” order to obtain
certain physiological advantages, but because it cannot be
otherwise.

§ 45.—EXAMPLES OF INDIVIDUAL ADAPTATION.
—Several examples of individual adaptations (Polygonum
amphibium, Primula sinensis, etc.) are mentioned in §§ 12 and
14-17. I call plasticity the variation produced by individual
adaptation.

In the following example one single primordium is taken into
account. Suppose that an adult petal a of a given species has
a length of 12 mm.: in the course of its development the length
has been successively I, 2... 9, 10, 11, 12mm. When the length
I2 mm. was reached the primordium /ength was in equilibrium
with the environment. Suppose now a second adult petal 0 of
the same species the length of which is 10 mm. The petal b
has been subjected to different influences! during its develop-
ment. It passed also through the series of values I, 2... 9,
ro mm., but it was in equilibrium with its environment when
its length had reached 10 mm.

Both petals have been accommodated to their respective
conditions of existence: the difference between them may be
expressed by measurement.

REMARK: Although the shorter petal d is adult, just as
the longer one a, we may say that 0 is in an infantile (juvenile,
pedogenetic) state with regard to the primordium length
because its growth has been stopped in a younger state.

§ 46—CLASSIFICATION OF THE PRIMORDIA WITH
REGARD TO THEIR DEVELOPMENT.—In the course of
the development of a living individual each of its primordia

1 Temperature, light, food, water, etc. (See § 119.)
THE PRIMORDIA 53

passes through a series of values till a maximum is reached, just
as the length of a petal taken as example in § 45. When we
investigate the evolution of an individual! we may follow
the development of each primordium separately. We may
compare the evolution of several primordia in order to obtain
a view of the whole. We may also compare the develop-
ment of a given simple property in several individuals or
species.

In order to make such comparisons easier I give here an
attempt to classify the primordia with respect to their develop-
ment. Considering first the primordia at the beginning of their
development, I bring them into three groups :

(1) The original primordia, which appear (or exist) at the
beginning of the embryonic life of the individual (or of the
part of the individual to which they belong). Examples: Ina
specimen of Spivogyra the total length and the number of cells
are original properties: they are both already discernible and
measurable at the beginning, when the specimen consists of
one cell (zygospore).2. In a pluricellular simple hair of a plant
the total length and the number of cells are both original with
regard to the hair considered as a unit. The length and the
nee ae of a petal are original primordia with reference to the
petal.

(2) The metamorphic primordia, which are produced by a
transformation of a previously existing property. Examples:
A colouring substance, which appears at a certain moment in
a petal by a transformation of a chromogen. The presence of
hairs on a leaf (primordium hairy or downy) is a metamorphic
property, because each hair has its origin in a transformation
of an epidermal cell. In higher animals and plants the meta-
morphic properties are exceedingly numerous.

(3) The awakening primordia, which are latent for a certain
time, and appear at a certain moment, independently of any
previously existing primordium. Awakening properties seem
to be rare. Example: The initial cell (zygospore) of a Spzro-
gyra is more or less oblong. After the second cell division two
of the four cells are cylindrical. The primordium cylindrical
appears at once: it is an awakening primordium. (See §§ 54
and 58.) It is sometimes difficult to determine whether a
given primordium is metamorphic or awakening.

Considering the primordia at the end of their development
(independently of their origin), I divide them into two groups :

10r of a part of an individual; for instance, petal, a leaf, an antenna of
an insect, a scale of a lizard, etc. : .

2 Here the value of the property ¢otal length is obtained by measuring the
length of the zygospore; the value of the property number of cells is one.
The value of each property increases till the definitive (adult) valueis reached.
54 THE QUANTITATIVE METHOD IN BIOLOGY

A. The arrested primordia, the growth (development) of
which is arrested when they have reached a certain value, with-
out any further increase or modification. Examples: The total
length of a Spivogyra or of a petal. The number of scales of a
hibernaculum, etc.

B. The transitory primordia, which are transformed at
a certain moment into a new (metamorphic) primordium.
Examples: In the limb of the corolla of Myosotis palustris
three colours appear successively: white, rose, blue. The
primordium white is original (with regard to the corolla) and
transitory. The primordium rose, being very probably pro-
duced by a transformation of a chromogen which is already
existing during the white period, is metamorphic; it is also
transitory, because it is transformed into the primordium blue.
The primordium ddue is therefore metamorphic and also arrested,
because the blue colour, when it has reached a certain intensity,
is not subjected to any further modification. Such is the
succession of the colours in the ordinary blue subspecies of
Myosotis palusivis. In the vose subspecies the blue colour does
not appear; the property vose is therefore arrested. In the
white subspecies the property white is arrested.!

The arrested properties in their turn may be divided into two
groups :

Aa. The persistent properties, which are preserved till the end
of the life of the individual (or part) in which they are observed.
Example: The blue colour in Myosotis palustris.

Ab. The caducous properties, which disappear at a certain
moment. Their disappearance is often a direct consequence of
the fact that the parts (segments, organs) to which they belong
are caducous. Example: The leaves of many plants are
clothed with hairs which fall off at a certain moment: all the
primordia of the hairs and the primordium hairy itself dis-
appear with the hairs. In a similar way all the primordia of
the scales of a hibernaculum disappear when the scales fall off
in the spring. In the course of the development of almost
all (perhaps all) higher animals a number of primordia are
caducous,” owing to the resorption (degeneration, phagocytosis,
etc.) of certain organs.

A primordium which disappears gradually may be called
deciduous.

1 With regard to the colour (all other properties being excluded), the white
subspecies is infantile compared with the rose, and the rose is infantile com-
pared with the blue. (See § 45.) ao

The succession of the colours in the blue subspecies is an example of segrega-
tion of three primordia. (See §38.) About the transformation of red into blue,
see § 133.

a i a property is, of course, something quite different from a
transitory property.
THE PRIMORDIA 55
All the mentioned groups of primordia are set out in order in
the following table :—

Classification of the Primordia (Simple Properties) according
to their Development *

persistent
original ie caducous (or deciduous)
transitory
arrested oe
Primordia metamorphic | caducous (or deciduous)
transitory
arrested persistent
? awakening caducous (or deciduous)
transitory

§ 47 —CLASSIFICATION OF THE PRIMORDIA WITH
REFERENCE TO THEIR DEVELOPMENT (continued).
EXAMPLES.—FIRST EXAMPLE: In § 161 have mentioned
a subspecies of Primula sinensis the corolla of which is red at
ordinary temperature and white if the plant is cultivated at a
temperature of about 30°. In this corolla (limiting ourselves
to the limb) we observe the primordia length and breadth, which
are both original, arrested and persistent. During the first
period of its development the corolla is white*: it contains
very probably a chromogen, which is transformed at ordinary
temperature into a red substance. The intensity of the red
colour increases gradually till a maximum is reached. The
property white is original and transitory; the property red is
metamorphic, arrested and persistent.

If we look upon the primordia white and red as being two
terms of one series, we see that three properties white-red, length
and breadth follow in their development three separate lines
(the velocity of increase of length and breadth is not the same).
Along each of these lines the value of the corresponding
property is continually varying, the variation of each property
being governed by a peculiar law. At a given moment, for
instance, after ” hours, a certain combination of values is found
to exist; after 2x hours a new combination is observed, etc.
The so-called adult state corresponds to a certain combination.
In other words, there exists a certain harmony * between the
three properties with regard to the progress of their develop-
ment. The above facts may be brought into the form of

1On accrescent properties, see § 47, second example.

2 It may be that the young corolla contains chlorophyl at a certain moment.
This is of no importance for the subject under consideration. _

3 The term harmony is used here in the meaning in which it was used by
LEIBNITZ, the author of Monadologia and Harmonia prestabilita. LEIBNITZ
was a mathematician.
56 THE QUANTITATIVE METHOD IN BIOLOGY

exact knowledge by means of the quantitative method,! the
properties being measured after , 2, 37 .. . hours, the figures
being plotted down in the form of curves. (See, on the use ofa
leading property, § 49.)

Let us now consider the corolla of the same species when
grown at a temperature of 30° C. The properties length and
breadth behave on the whole in the same way as in the preced-
ing case. The primordium white is original. Since the reaction
which produces the primordium ved does not take place, white
is arrested (its value is invariable and may be represented by
O=no colouring substance) and persistent (instead of transitory).

In the preceding example only three primordia (colour,
length, breadth) have been considered. It is, of course, possible
to devote attention to a larger number of primordia at the same
time ; for instance, the number of epidermal cells and their
dimensions, the number of stomata and the dimensions of
their cells, etc.

SECOND EXAMPLE (ACCRESCENT PRIMORDIUM) :
In a leaf of a tree we may distinguish, among other primordia
(limiting ourselves to the limb) : (x) the length (measured along
the mid-nerve) ; (2) the breadth (at the place of the greatest
breadth) ; (3) the number of palissade cells (counted in the
transverse direction at the place of the greatest breadth) ; (4)
the breadth of the palissade cells (calculated by dividing the
breadth by the number of cells).

The primordium nwmbey of cells increases from the beginning
till the maximum is reached : it is original, arrested, persistent.
During this first period of the development of the leaf (period
of cell-division) the breadth of the cells may be looked upon as
being constant. At (or about) the end of this period the cells
begin to grow, and this process goes on till they have reached
their full size. The primordium breadth of the cells is original,
arrested and persistent. Since the increase of this primordium
is continued after the primordium number has been arrested, it
might be called ACCRESCENT in comparison to the primor-
dium number. The primordia length and breadth of the limb
are both original, arrested and persistent.

SECOND EXAMPLE (continued). SENSITIVE PERIOD,
CORRELATION. The period of development of the leaves of
any of our indigenous trees (for instance, Fagus silvatica) is.
divided by the winter rest into two parts: (x) the bud period
(intragemmal period), which corresponds to the summer (July-
September) of the first year; (2) the spring period (vernal
period), which begins when the bud expands, and extends (in

1Length and breadth may be easily measured. The measurement of
colours is possible in several ways (scale of colours, chemical analysis,
spectroscope).
THE PRIMORDIA 57

Fagus silvatica) in ordinary years (in Flanders) from about the
end of April to about the middle of May. The period of cell-
division is included within the bud period; therefore the
plasticity of the primordium number of cells depends on external
causes (temperature, etc.) which are acting in July, August,
September, but this primordium is, of course, not affected by
the external influences which prevail in the spring. The bud
period is therefore the sensitive period (mobilis @tas) of the
primordium under consideration.!

On the other hand, the plasticity of the primordium breadth
of the palissade cells depends almost entirely on the external
conditions which prevail in the spring. Its sensitive period
corresponds, therefore, to the vernal period.

The properties length and breadth of the leaf-blade may be
looked upon as being primordia. They are, however, in reality
compound properties, which depend on the number of cells and
on their dimensions. As a consequence of this the sensitive
period of the mentioned properties extends over both parts of
the period of development of the leaf.’

The knowledge of the sensitive period of the primordia is
important for embryology in general, and especially for the
investigation of plasticity, adaptation and correlation between
plastic properties.

A curious example of modified correlation in relation with the
sensitive period has been described by DE VRIES. In Papaver
somniferum, subsp. polycephalum, the central (normal) pistil is
surrounded by a number of smaller supplementary pistils. In
ordinary specimens an evident correlation exists between the
dimension of the central pistil and the degree of development of
the supplementary pistils, a large central pistil coinciding
with well-developed supplementary ones, and vice versa. The
sensitive period of the property supplementary pistils coincides
with the early period of the life of the individual, whereas the
sensitive period of the property dimension of the central pistil
coincides with a later part of the individual life. Ifa specimen
is brought under unfavourable conditions of existence (poor
food) during the first weeks, the supplementary pistils are
hampered in their development. If the same specimen is
brought (at the age of about six weeks) under better condi-
tions, a large central pistil may still be obtained. In this way a
large central pistil coincides with incompletely developed
supplementary pistils, the ordinary correlation being entirely

1 The sensitive period idea has been introduced in botanical science by DE
VRIES.

4The sensitive period of several properties of the leaves of Fagus silvatica
with reference to the influence of light and shadow has been investigated by
Dr DE BOIS (Botanic Garden at Ghent).
58 THE QUANTITATIVE METHOD IN BIOLOGY

disturbed. The ordinary correlation is, of course, a consequence
of the fact that the conditions of existence are ordinarily favour-
able or unfavourable through the whole life (a few months) of
each specimen.

I have observed in Chrysanthemum cavinatum remarkable modifications,
the explanation of which is found in the sensitive period. Dr C. DE BRUYKER
(Ghent) has observed similar facts.

This calls for reflection, especially with regard to the methods
of studying correlation. Little attention has hitherto been
paid to this interesting question.

THIRD EXAMPLE: In the ordinary blue subspecies of
Centaurea cyanus (observed in Flanders) I consider two prim-
ordia of the marginal florets: length and colour. In a young
bud the colour is white: this primordium is original and
transitory. The second period of the development (within the
bud) begins with the appearance of a very pale rose-purplish
colour, which is very probably produced by a transformation
of a previously existing colourless chromogen. The intensity
of the new colour increases up to a certain limit which I call
pale rose-purplish. This primordium is metamorphic and
transitory. The third period is initiated (still within the bud)
by a transformation of the pale rose-purplish into blue. The
intensity of the blue colour increases till the flower-head is
expanded. The primordium O/ue is metamorphic, arrested
and caducous (strictly speaking, it is deciduous, since it vanishes
by degrees during the post-floration). While the three terms of
the property colour follow each other, the primordium length
increases continuously till the maximum is reached (this
happens a short time after the expansion of the bud). The
primordium length is original, arrested and persistent.?

THIRD EXAMPLE (continued). PLASTICITY.—I have
cultivated the blue Centaurea cyanus under very poor conditions
of existence (about seventy specimens in a seed-pan, the diameter
of which was about 30 cm. and which contained only sand).
The plants were dwarf; most of them produced only one
terminal flower-head. The corolla of the marginal florets was
distinctly shorter, the blue colour hardly paler than under
ordinary conditions. We observe here a new example of the
independence of the primordia: a modification of the condi-
tions of life has here an important influence on the value of
the primordium length and an almost negligible influence on
the primordium colour.? (In Primula sinensis the reverse was

1In the development of the colours mentioned an interesting example of
gradation is observed. (See § 133.) The succession of the colours is an example
of segregation. (Compare Viola, § 38, p. 46, and Myozotis, § 46, p. 54.)

2In the experiment mentioned, under unfavourable conditions, the adult

marginal florets were distinctly infantile with regard to the length, hardly
infantile with regard to the colour.
THE PRIMORDIA 59

observed, the colour being affected, the length hardly or not at
all. See this paragraph, first example, p. 55.)

FOURTH EXAMPLE: A rose-purplish subspecies of
Centaurea cyanus (one specimen in a rye field, June, rg11);
marginal florets—The property length behaves exactly as in
the above-mentioned blue subspecies; it is original, arrested
and persistent. The development of the colour follows the
same line as in the blue subspecies during the two first periods,
the succession being white and rose-purplish. But when the
latter colour has reached the value fale (which coincides with
the end of the second period in the blue subspecies) the trans-
formation into blue does not take place and a third period is not
initiated. The second period is protracted, the intensity of the
vose-purplish colour increasing gradually till the value intense
rose-purplish is reached. This happens when the flower-head
is expanded. The primordium rose-purplish is here meta-
morphic and arrested.1

REMARK I.: The above example is interesting with regard
to the significance of the term infantile (juvenile, pedogenetic).
We might be tempted to say that the rose-purplish subspecies
is infantile in comparison with the blue. Used in that way, the
term infantile does not express an exact notion. The rose-
purplish subspecies is deprived of the blue colour and therefore
infantile with regard to the property blue. But in the blue sub-
species the property rose-purplish is arrested in its development
when it has reached the value fale; therefore the blue sub-
species is infantile with regard to the colour rose-purplish.

In other words, each subspecies being considered as a whole,
neither of them is infantile. In both the development of the
colour follows the same line till the value fale rose-purplish is
reached. After that the development continues along two
diverging lines. We see, from this very simple example, that
the term infantile (juventle, pedogenetic) ought to be used with
regard to each property separately, but is not strictly applic-
able to a species, a subspecies (or even an individual) considered
as a whole.

REMARK II.: In a similar way the terms progressive and
vetrogressive are ambiguous when applied to the phylogenic
relations of specific forms. It might be said, for instance, that
the rose-purplish subspecies has been produced by a progres-
sive mutation of the blue subspecies with regard to the property
rose-purplish ; but one might say also that the rose-purplish
subspecies is the result of a retrogression with regard to the
property blue. The above remarks are not merely linguistic
subtleties. In complicated cases, when a number of properties

*I don’t remember whether it is persistent or deciduous. See about
gradation in Centaurea, § 133.
60 THE QUANTITATIVE METHOD IN BIOLOGY

are in play, the indiscriminate use of the above-mentioned
terms may result (and has resulted) in inexact conceptions.
For instance, in the comparative study of male and female
individuals of the same species, clearer views would certainly
be obtained if the terms infantile (juvenile), progression and
vetrogression were used for each property separately. The
investigation of this important subject, which is in close rela-
tion with the secondary sexual characters, has been initiated by
DARWIN. It has been considerably spoiled by the obsession
of adaptation and other preconceived ideas, and it is rather
overlooked by many biologists.

§ 48.-THE MEASUREMENT OF A STATE OF EQUI-
LIBRIUM.—In § 43 a primordium (simple property) is defined
as a state of equilibrium. This is further explained in § 44,
and in § 45 the property Jength of a petal is given as example.
Just as the latter property, the primordia mentioned in §§ 46-
47, during their period of development are passing through a
series of values till a certain state of equilibrium is reached.

This view is based upon a mechanical conception. It may
be asked how it is possible to express a state of equilibrium by
measurement.

A state of equilibrium coincides with the simultaneous action
of a certain number of forces. Strictly speaking, it ought to be
expressed by an equation in terms of the forces. In the
present state of biological science it is impossible to enumerate
and to measure the forces which are at play. Therefore we
must have recourse to an indirect method, measuring the
material parts which are maintained in equilibrium by the
acting forces. We may count the similar parts (organs, seg-
ments, etc.) which are in equilibrium, measure their dimensions,
their form (any form may be expressed in terms of dimensions),
their relative position (angles of divergence, etc. See, on
phyllotaxis, § 40), their physical properties (elasticity, etc.), etc.
The chemical properties properly so called, which depend on
the presence of certain abiotic substances or mixtures (§ 8), are
quantitatively known as soon as we know the chemical con-
stitution and the quantity of the substances under considera-
tion.! In many cases the abiotic chemical properties may be
measured indirectly (scale of colours, transparence, etc.). But
whatever may be the object of the measurement, it must always
be borne in mind that we are measuring something which coin-
cides with a state of equilibrium.

The principles upon which the measurement of the primordia
of the living beings is based are expounded in Part VI. (prob-
ability), Part VII. (variation steps) and Part VIII. (gradation).

1 This may be discovered by chemical research.
THE PRIMORDIA 61

§ 49—THE QUANTITATIVE METHOD APPLIED ON
EMBRYOLOGY. CURVES OF DEVELOPMENT. LEAD-
ING PROPERTIES.—In § 47 I have given a short account of
the development of certain properties of plants. The examples
given are very simple and the facts mentioned may be observed
without complicated technique, but the principles of the method
are applicable to the study of any embryological subject.
These principles may be summarized in the following way :—

(x) In the study of the development of a living individual (or
part, segment, organ, etc.) we want to discover a certain number
of simple properties (primordia).

(2) Since the primordia are on the whole independent of
each other, the development of each primordium ought to
be studied separately, by measuring its value at successive
moments of the period of development.

(3) The primordia of a species are very numerous, in higher
animals and plants practically unlimited in number. There-
fore it is advisable to concentrate our attention upon the
development of a small number of well-chosen properties.

(4) The successive values of each property ought to be set out
in order in a chronological series. They may be represented by
ordinates, by means of which a curve of development may be
drawn.

(5) The moment at which a transitory property is trans-
formed into a metamorphic one ought to be determined and
indicated in the curve of development. In a similar way
the moment at which a (caducous) property disappears or a
(awakening) property appears ought to be determined and
indicated in the curve.

(6) The curves (or series of figures) of all the investigated
properties ought to be brought together into one table or one
diagram (§ 47, first example). By means of an embryological
table, or diagram constructed in that way, we may compare
exactly the lines of development of several properties ; we may
find which is, at any given moment, the existing combination
of values!; we may obtain a clear notion of the way in which
a given state proceeds from the preceding state and gives birth
to the next one; we may obtain valuable information about
the segregation of the properties, for instance, with reference
to the developmental continuity or discontinuity between two
properties, and we may compare several individuals, species,
etc., by comparing their tables or curves of development.

(The gradation curves mentioned in Part VIII. are constructed
on the whole according to the above principles. See Fig. 27.)

In the third and fourth examples described in § 47 I have

1In other words (using the ordinary language), we may find which are the
characteristics of a given embryo at any moment of its development.
62 THE QUANTITATIVE METHOD IN BIOLOGY

contented myself with a mere estimation of the successive values
of the primordia. This method was applicable because it was
Possible to bring side by side into a series and to compare a
number of specimens (florets of Centaurea cyanus) in various
states of development. But in order to obtain exact results
Measurement is, of course, indispensable.

An important question is to determine at which moment
the measurements ought to be made. Two general methods
(followed in embryology) may be adopted:

(1) We may divide the time (hours, days, etc.) between the
beginning and the end of the development into a certain
number of intervals, measuring the properties at the end of
each interval. This method is applicable in certain cases ; for
instance, for the development of a bird or a fish within the egg,
all the eggs developing under the same conditions. But this is
rather exceptional. The rapidity of development often varies
considerably according to external influences (temperature,
etc.). Therefore two embryos of the same age may be in a very
different state of development. It is, moreover, often impossible
to know the exact age of an embryo.

(2) According to the second method, one property is taken as
a standard or leading property, the development of the others
being investigated in comparison with the standard. The
choice of a leading property is, of course, arbitrary, and depends
in each peculiar case on the investigated subject. In the
development of a fish, a leaf, a petal, etc., the total length of
the object is ordinarily a convenient leading property.

I have adopted the method of the leading property in the
investigation of gradation along the stem of grasses and acrocar-
pic mosses (Part VIII.). (Compare § 114, Fig. 23.) See § 133.

§ 50.—VARIATION IN EMBRYOLOGY.—Many embry-
ologists believe that variation does not exist or hardly exists in
the early period of development of higher animals and plants.
Conclusions drawn from the study of one or two specimens are
regarded as being applicable to the species and also (according
to the Haeckelian principles) to a whole genus and even to a
family or a class. For instance, a paper in which two embryos
of a tortoise are described is called a Memoir on the Embryology
of the Chelonide., etc.

We know, on the other hand, that adult specimens are
variable in their internal anatomy just as in their external
properties. I have investigated by measurement thirty-eight
properties in about ninety species and twenty-five so-called
varieties of the genera Cavabus and Calosoma.1 I have found a

11 have carried out about 250,000 measurements (September 1907 to July
IgI4).
THE PRIMORDIA 63

large amount of variation within the limits of each species and
even of each “variety,” and, moreover, numerous specific
differences which have never been mentioned and probably
never suvmised. The differences between the genera Carabus
and Calosoma are described in the classical books in a few
words ; they are, in reality, very numerous.

According to the Haeckelian School, embryos in an early
state of development are to be compared to lower animals
and plants. We know that the latter are variable just as the
higher forms of life. For instance, a number of alge and
fungi are exceedingly plastic, even in properties upon which
classification has been based.

We may ask the question, Why should embryos be less vari-
able than adult specimens or lower animals and plants? It is
difficult to find any serious reason why embryos should be, as it
were, sheltered from the influence of plasticity.

In certain groups, such as Mammalia and Birds, the condi-
tions of existence of the embryos! seem to be little variable,
and therefore it may be expected that plasticity is rather small.
Even here, however, the influence of complexity exists. It may
be remarked that an important part of our knowledge of the
embryology of mammalha and birds has been collected by
the investigation of such animals as the dog, the rabbit and the
chicken, three species which include numerous subspecies (so-
called races), innumerable specimens being hybrids of very
complex origin. In the books and memoirs in which the em-
bryology of these species has been described again and again
one finds hardly ever any information about the subspecies to
which the described specimens belong. Variation produced by
hybridization has been simply ignored.

It often happens that two scholars, endowed with an equal
talent for observation and an equal mastery of technique, do
not agree with one another, and that a third embryologist, in-
vestigating the same subject, causes still more confusion by
publishing new discoveries. It may be supposed that com-
plexity is here at play and that different subspecies (and
hybrids) have been confounded under the name dog, or rabbit,
or chicken.

The application of the quantitative method to embryology would
enable us to reduce the complicated notion of DEVELOPMENT
to terms of the simple notion of GROWTH of the primordia. It
would enable us to investigate the influence of external con-
ditions upon the development (growth) of one or several given
primordia. Since the simple properties are, on the whole, in-
dependent of each other, it may beanticipated that the line (curve)
of growth of each primordium may be modified separately

1 For instance, temperature, light, food, etc.
64 THE QUANTITATIVE METHOD IN BIOLOGY

by external causes; that the characteristics (combination of
primordia) of an embryo in a given state may be therefore
modified, bringing about a new starting-point, and that the
further development may be modified in its turn.

We have seen, for instance (§ 47, p. 56) that in Primula
sinensis an original transitory primordium (white) is trans-
formed by unusual temperature into an original arrested per-
sistent primordium, a second primordium (red) being sup-
pressed altogether, while a third primordium (length) is hardly or
not altered. There is, a frtovt, no reason why similar changes
should not occur in the course of the individual develop-
ment in any species whatever. It is only by means of the
quantitative method (curves of development) that it is possible
to investigate accurately such phenomena. (Compare Part
VIII., gradation curves.)

§ 51.— REMARK: The quantitative method in embry-
ology ought to be established by degrees by the investigation
of not too complicated examples. This method is still very
incomplete ; its period of trial is not yet over. It is only
by CARRYING OUT NUMEROUS MEASUREMENTS that
serious progress is to be expected.

It is possible to investigate the development of many objects,
in which only a few properties have to be taken into considera-
tion and from which it is possible to collect numerous figures
without serious practical difficulties.

EXAMPLES: The development of a phyllom, a trichom;
a Spirogyra and other similar plants. In the animal kingdom,
the development of the legs, antennz, wings, etc., of articulate
animals (Arachnids, Crustacea, Hemiptera, Orthoptera, etc.),
the shell of Bivalve Mollusca, etc.

The development of such comparatively simple objects is
governed by the same mechanical laws as that of a rabbit, a
chicken or a frog, because the individual evolution consists, in
each and all, of the passage of one state of equilibrium to another.

When we want to discover laws of nature the best method
is, of course, to proceed from simplicity to complexity. This
logical line has been followed and is still followed in those
sciences which investigate inorganic nature. The founders of
modern chemistry (LAVOISIER, PRIESTLEY) began with
the study of very simple substances, such as water, carbon
dioxide, sulphur dioxide, mercuric oxide, etc. If they had tried,
at the end of the eighteenth century, to discover the constitu-
tion of complicated silicates, indigo or alkaloids, their efforts
would have been fruitless. HAUY has drawn up the funda-
mental laws of crystallography from the study of beautiful,
regular crystals; later on he attacked complicated and
THE PRIMORDIA 65

irregular objects. MENDEL discovered very important
principles of heredity by the investigation of a few compara-
tively simple facts. The rules which he laid down are to-day
a guiding principle among the diversity of the phenomena of
hybridization.

There seems to exist, in the mind of many biologists, a pro-
pensity to study problems which are INSOLUBLE in the present
state of science. Our methods ave not adequate for these dtffi-
culties.

In the present state of our knowledge the application of the
quantitative method to complicated embryological subjects
would be premature and result very probably in waste of
labour and disappointment.
PART V

ATTEMPT AT A CLASSIFICATION OF THE
PRIMORDIA

§ 52. PRELIMINARY REMARK: NUMEROUS PRI-
MORDIA ARE MENTIONED IN THE EXISTING DESCRIP-
TIVE LITERATURE.—When we intend to apply the quanti-
tative method to the study of any species, we must first of all
discover a certain number of its primordia. Very often we
find the wanted information, at least to a considerable extent,
by consulting a flora or a fauna in which the species is described.
The amount of material accumulated in descriptive literature
is inexhaustible and opens up, when adequately used, a wide field
for quantitative investigation, not only with regard to the
quantitative description of subspecies, species, genera, etc., but
also for the study of the individual development. (See §§ 46
and 49-50.)

Many specific characters are in reality measurable primordia.
Other characters may be brought into the form of measurable
primordia. Certain characters are compound properties which
may be decomposed into their primordial components. (See
§ 38, segregation, p. 43.)

A property, mentioned as a character, may, by analogy, lead
to the discovery of other similar properties which have never
been mentioned nor investigated before.

It very often happens that a character, which exists in a large
number of species of a genus, a family, etc., is described in one
of them and not mentioned in all the others. In such cases it
is possible to investigate quantitatively the property under
consideration through a long series of species. By the applica-
tion of this method unexpected analogies and differences are
discovered and many interesting comparisons are rendered
possible. This affords an unlimited field for investigation.

The principle of the primordia and the quantitative method

1A renowned embryologist of the modern school told me one day that it
was a waste of time to identify the animal species of which I was studying
the development ; he said also, expressing his contempt by a jest, that entomol-
ogy is the art of counting hairs on the coccyx of beetles. By counting the joints
of the tarsus of innumerable species of Coleoptera, however, LATREILLE
found the base of classification of these insects. By counting the teeth and
the vertebre, through the whole series of mammalia, most important results
have been attained (CUVIER, R.OWEN). Etc.

66
CLASSIFICATION OF THE PRIMORDIA 67

throw new light upon the innumerable details recorded in
descriptive literature.

FIRST EXAMPLE: In the description of Anagallis tenella
we find, among other things: segments of the calyx pointed
but short; corolla deeply 5-cleft1 We recognize here four
measurable primordia: (x) length of the calyx; (2) id. of its
segments ; (3) length of the corolla; (4) id. of its segments.
The curve of development of each of these properties may be
established by the study of flower buds.?. The same primordia
may be investigated in the same way through the whole family
of the Primulacee.

SECOND EXAMPLE: British species of genus Genista 3:

Genista: seeds several.

G. tinctoria : leaves sessile, from narrow lanceolate to broadly
elliptical or nearly ovate. Pod nearly an inch long.

G. pilosa: leaves shortly obovate or lanceolate, obtuse.
Pod rather shorter and broader than in G. tinctoria.

G. anglica: leaves small, lanceolate or ovate. Pods about
six lines long, broad.

The characters mentioned have been observed accurately,
but the descriptions are rather vague. Seven measurable
properties may be taken into account in each species: (1)
length of the petiole 4; (2) id. of the blade ; (3) breadth of the
blade ; (4) distance between the greatest breadth of the blade
and its summit; (5) length of the ripe pod; (6) breadth id. ;
(7) number of seeds.*

As long as we confine ourselves to the British flora it seems
to be superfluous to examine thoroughly the above-mentioned
primordia, because the three British species are easily dis-
tinguished by their thorns and hairs. But the quantitative
investigation of the leaves, the pods and the seeds would
render good service for the description of the xumerous species
(about seventy) of Genista which are found in other countries
and eventually of their subspecies. And, moreover, a descrip-
tion ought to be something more than a short diagnosis.

THIRD EXAMPLE: In certain genera of the family of the
Carabid@ the labrum bears two hairs ; in other genera the hairs
are four in number. In the description of the species of the
genus Carabus these hairs are not mentioned, probably because
they are numerous and their number variable in each species of
this genus. I have counted the hairs under consideration in
numerous species of Cavabus, taking at least six $ and six ¢ of

1 HOOKER, British Flora, 1866, p. 306.

2 The turgor being suppressed in one or another way.

> HOOKER, British Flora, 1866, pp. 108-109.

4 When the leaves are sessile, the length of the petiole=o.
5 See, on the measurement of variable properties, Part VI.
68 THE QUANTITATIVE METHOD IN BIOLOGY

each species. This work has not been a waste of time.
Although the figures of one species, taken separately, are of
little importance, from the whole set of specific figures interest-
ing conclusions may be drawn. At first is appears that the
number of hairs is not very variable in certain species, whereas
it is very variable in the majority of them. Secondly, all the
species (ninety in number) being arranged in a series according
to the value of the property under consideration, a gradual
transition is observed from the lowest figure to the highest. In
this series certain species which are (with regard to other prop-
erties) very different from each other are placed side by side,
and certain species which are looked upon as being allied with
one another are separated by a considerable distance. Thirdly,
the species which are at both extremities of the series are dis-
tinctly different by their figures, in spite of variation. There-
fore the extremes are easily distinguished by the primordium
number of hatrs of the labrum, without regard to any other
property.?

FOURTH EXAMPLE (INTER-SPECIFIC CORRELA-
TION): We find in a classic book, which contains the descrip-
tion of about thirty-five species of the genus Cavabus, that in
one of these species the ultimate joint of the maxillary palp is
shorter than the penultimate. For all the other species no
information is given about the relative length of the joints
mentioned. We are also told that the ultimate joint of the
maxillary and labial palps is broad in certain species and
narrow in others,’ but for the majority of the species this char-
acteristic is passed over in silence. In order to replace this
fragmentary information, which is rather irritating by its
vagueness and incompleteness, by more useful notions, I have
measured in ninety species five properties—viz. (I) length of
the ultimate joint of the maxillary palp; (2) breadth id. ;
(3) length of the penultimate joint zd. ; (4) length of the ultimate
joint of the labial palp ; (5) breadth zd. All the figures being
arranged in order in the same way as in the third example, the
conclusions are similar with regard to each of the five properties.
Such material is exceedingly interesting with reference to the
correlation between several properties in a series of species.
This form of correlation might be called inter-specific. It is
something quite different from the correlation between proper-
ties of one species.

FIFTH EXAMPLE: In the classical descriptions of the
leaves of the mosses, the length and the breadth of the leaves

‘T intend to give a complete account of these and many other similar facts
in a work on Cavabus and Calosoma which I hope to publish later on.

* The significance of the terms broad and narrow is, of course, an enigma
which ought to be guessed by the unfortunate reader.
CLASSIFICATION OF THE PRIMORDIA 69

are given for certain species but not for others. We are in-
formed that the leaves are very narrow at their base in certain
species and narrow or broad in others, but for many species
the property breadth at the base is not mentioned. Here three
properties may be measured : (1) length ; (2) greatest breadth ;
(3) breadth at the base. I have carried out this work for ten
British species of the genus Mnium,! replacing the terms Jong,
short, large, small, broad, narrow, very narrow, etc., by three
figures for each species. This subject is rather complicated
because gradation comes into play here. (See Part VIII.)

§ 538.—CLASSIFICATION OF THE PRIMORDIA.—In the
present work a number of primordia have already been men-
tioned—for instance, the length, the breadth and the number
of cells of certain organs; the dimensions of the cells; the
presence or absence of hairs; the number of hairs on the
labrum of an insect ; certain colours; the number of seeds in
a pod, etc. Between those properties no relations exist ; they
have been taken at random, as examples. When we consult
a flora or a fauna in order to find primordia (§ 52) we are pro-
ceeding at a venture. We behave as if an indefinite number
of properties (so-called characters) existed in each species; in
each peculiar case we pick out and investigate some of them,
but the choice we make is arbitrary. Similar remarks are
applicable on the mass of different properties which have been
investigated by the Mendelian School and by the biometricians.

We need a method enabling us to compile an inventory of the
primordia of each species: such a method ought to be based
upon a classification of the primordia. In § 46 I have attempted
to classify the simple properties (primordia) into nine groups
according to their development. This classification may
render service in embryology but is inadequate when we want
to make up a list of the properties of a species.

W. BATESON? has divided the phenomena of variation
into two groups: variations in the processes of division and
variations in the nature of the substances divided (loc cit.
chapter ii., p. 31). This classification of the variations is in
reality equivalent to what I call a classification of the primordia.
BATESON calls meristic variations the variations in the pro-
cesses of division and substantive variations the changes in
actual composition of material. He also uses the terms

1See my paper: ‘Quantitative Description of Ten British Species of the
genus Mnium.” Linnean Society’s Journal—Botany, vol. xliv., November,
1917. (Communicated by Prof. F. E. WEISS, D.Sc., F.L.S. Read ist June
1916.) 58 pages, 9 text-figures. : :

2-wW. BATESON, Problems of Genetics (New Haven, Yale University Press.
London, Humphrey Milford. Oxford, University Press). 1913.
70 THE QUANTITATIVE METHOD IN BIOLOGY

mechanical and chemical.1 With regard to cell-division (which
is the simplest case of division), BATESON divides the
mechanical variations in their turn into two groups: (x) the
division properly so called and (2) the differentiation which
brings about differences between the parts produced by a
division.

It is possible to go further along the line indicated by BATE-
SON. I want to expound this subject by means of examples.
In the present work I limit myself almost entirely to the vege-
table kingdom because at the time being the notes about the
properties of animals, which I have collected for years, are not
within my reach.

The researches the results of which are partly expounded in this book have
occupied about thirty-five years. I began with measuring various objects
taken at random among animals and plants, following the ordinary statistical
method initiated by QUETELET. I submitted my first results (asymmetrical
and multi-humped curves) to several biologists and mathematicians, who told
me that QUETELET’S attempts were foolish and I was wasting my time.

Later I limited myself almost entirely to the measurement of various proper-
ties of numerous species of shells, and I spent several years before I could
find in a satisfactory way a sufficient number of primordia. I abandoned this
exceedingly interesting work because of the difficulty of obtaining the material
(numerous specimens of each species) I wanted for further methodical investi-
gation. (See § 89, third example.) :

After that I began the study of insects, and after a preliminary work which
lasted again several years I began in October, 1907, the methodical investiga-
tion of the species of the genus Cavabus (including Calosoma). This work was
continued till July, 1914, and interrupted by the war.

§ 54—FIRST EXAMPLE: SPIROGYRA—I take as
example a specimen of Spirogyra (or Zygnema, or any other
alga consisting of a series of cells without branches) the
structure of which is very simple. This plant consists at the
beginning of one cell (zygospore, egg). By its form this young
individual resembles more or less an ellipsoid. Since we have
no exact information about its form, we call it oblong or use
another rather vague term. Two simple visible properties may
be discerned here: length and breadth.” Both ought to be
measured according to two rectangular axes: longitudinal and
transverse.

At a certain moment the egg is divided into two cells: the
(imaginary) straight line which joins the centres of both new
cells is the line or axis of division (segmentation) ; this axis
coincides with the longitudinal axis of the egg.

The two cells (unicellular individuals) remain connected to

1BATESON, using the terms actual composition of material (chemical
variations), does not make any distinction between two notions which I look
upon as being different: (1) the composition of the living mixture; (2) the
chemical properties properly so called (abiotic chemical properties). (See § 8.)

2 These properties are variable, just as almost all the further mentioned
properties. See, on the measurement of variable properties, Part VI.
CLASSIFICATION OF THE PRIMORDIA 71

each other and are divided in their turn into 2,4 . . . 2* cells.1
All the successive divisions take place according to the already
mentioned axis of segmentation and all the cells remain adher-
ent. In this way an adult specimen of Sfirogyra is produced.
This is a uniaxial system of segments (Fig. 2).

I call this object a specimen. It may be called an individual.
Unfortunately the latter term is used in different senses; it
may be applied to the egg, to the adult pluricellular specimen
and to each of its cells.2 The pluricellular specimen may be
‘looked upon as being an individual of a certain order x. Tak-
ing this individual as starting-point, I call each of its unicellular
segments (which are all equivalent) an individual of the order
x+1. In the present example we may put down x=1; accord-
ing to this, the pluricellular specimen is an individual of the
first order and each cell an individual of the second order.®
I don’t go further, looking (in the present work) upon each cell
as being an individual (unit) of the last (simplest) order.

Generally speaking, I call individual of the order x or indi-
vidual x any specimen, individual, segment, organ or part
whatsoever * of which I want to investigate or to describe the
constitution. An individual x may be divided by segmenta-
tion into individuals x+1; these may consist in their turn of
individuals x +2, etc.

REMARK: The above definitions are based upon the
principle that the notion of individual is a relative one. The
definition of the term individual involves a convention. In
biology we use this term in the sense of unit; the definition of
any unit is a matter of convention. Examples: the metre is
the unit of length in the metric system. Since we know that
an error has been committed in the original measurement of
the metre, this unit is conventional. Moreover, we have been
compelled to adopt a series of other units of length; for in-
stance, the micron, the millimetre, the centimetre (C.G.S.
system), the kilometre, etc., the standard being the metre. If
the founders of the metric system had been pure logicians they
might have taken the metric ton (1000 kilogrammes) as the

1Certain particularities, which are of no importance for our subject, are
passed over in silence in this description. See about the first cell-divisions in
Zygnema: N. WILLE, in ENGLER and PRANTL, Natiirl. Pflanzenfam.,
Theil I, Abt. 2, Fig. 11. See about Spirogyra: G. S. WEST, British Fresh-
water Alge (Cambridge, 1904), Fig. 49.

2Jt happens under certain conditions that the cells separate from each
other and become really independent individuals.

3 It might be more logical to call each cell an individual of the first order,
and the pluricellular specimen an individual of the second order, but in com-
plicated cases it is very difficult or even impossible to adopt this notation.
See note 1, p. 72.

4 A tree, a moss, a leaf, a hair, a Spirogyra, an insect, an antenna, etc.,
and by further extension a shell of a mollusc, the shell of an egg of a bird, etc.
72 THE QUANTITATIVE METHOD IN BIOLOGY

fundamental unit of weight, but they have wisely adapted the
new system to the needs of practical application and therefore
they have chosen the gramme. Nowadays we use the series
milligramme, centigramme, gramme (C.G.S. system), kilo-
gramme, metric ton, the gramme being the standard.

In physics and chemistry the molecules and atoms are in a
certain sense individuals or units of a certain order. For many
years the atom has been the ultimate term, in fact the
standard. In the new chemistry the atom is divided in its
turn into smaller units; the classic system of units has been
completed, but neither aliered nor disturbed by this innovation.

In a similar way we may express in biology the notion of unit
or individual by means of one (or several) series of terms, the
cell being the standard and (provisionally) the simplest term.
The first series of units (see a second series in § 70) is based upon
the principle of segmentation and includes the terms x, «+1,
%4+2...x+4%m. If necessary we may ascribe to x a definite
value according to the case under consideration. If we want,
for one reason or another, to proceed from the unicellular units
to the more complex individuals, we may call the cell an indi-
vidual (x+), the next (pluricellular) term being (x +7)-1,
etc.

I do not attach much importance to the adopted notation of
the successive units. More important is the principle of the
adaptation of a series of biological untts of successive order, a unit
of a given order being a component of a unit of the preceding
order and including several units of the next order.

I hope that the proposed system is elastic enough to render
possible various applications. If we were compelled to divide
the cell itself into smaller units, the system would be com-
pleted but not altered, x +m remaining x +7.

§55.—FIRST EXAMPLE: SPIROGYRA (continued).—
An individual x (adult specimen) of Sfirogyra consists of a
number of individuals x+1 (cells). This number is a primor-
dium of the individual x. We may look upon all the cells as
being cylindric, except both terminal cells, which are cylindric
and rounded at their distal (external) extremity.2 We find
here a very simple example of differentiation: the individuals
x +1 (cells) are indeed of two kinds, terminal and intermediate.

1In Spirogyra n=1. Ina leaf of an elm, in the salivary gland of a horse,
the value of x is practically unknown. In these and similar complicated cases
a given cell is called (y+). This means that it is the /ast term of a series,
the number of terms +1 and the value of the most complicated term # being
unknown. The value (+7) is therefore undetermined, but the value of
(¥+n)—1 is determined with regard to the cell.

2 We must content ourselves with the term rounded because of our ignorance
of the exact form of the extremity.
CLASSIFICATION OF THE PRIMORDIA 73

In this example it is useless to complicate the question by
numbering the cells; this becomes necessary in certain more
complicated cases.

Since the two kinds of cells (units x + 1) have the same origin
(the egg), they are identical with regard to their hereditary
possibilities (§ 29). The observed differences
ought therefore to be ascribed to plasticity— i
that is to say, to causes external with regard
to each cell. We may look upon the individual
x as being a society of individuals x +1 (cells).
Each member of the society undergoes the
influence of two sorts of external causes:
(1) EXTERNAL causes properly so called,
such as temperature, light, etc. ; (2) SOCIAL
causes which emanate from other members of
the society or from the society taken as a
whole. In other words, each member (cell)
lives in a social environment: the differences
brought about by the influence of this en-
vironment are SOCIAL differences (see below,
Remark).

According to this, it is obvious that the
difference between the intermediate and the
terminal cells of Spirogyra is a social difference.
It may be remarked that the longitudinal line
(axis) of segmentation is also a line of differentia-
tion. Indeed, following this line from one end to
another, we observe the variation produced by woe. 2.— Uniaxial
differentiation. The line of segmentation and system (Spirogyra
differentiation is already found in the egg: Zygnema, etc.), dia-
it is the longitudinal axis. te

The principles, the application of which one finds in
Spirogyra in a very simple form, govern the distribution of the
properties in all organisms, from the simplest to the most
complicated.

REMARK : The terms social cause, social environment and
social difference may render good service in biology.

A very simple example of social differentiation is found in
the pseudo-bulb of Phajus grandiflorus. The members (cells) of
this society (individual x) which are near the surface are green
because their so-called amyloplasts are impregnated with
chlorophyll. At a certain distance from the surface the
amyloplasts are colourless and the cells are white, because they
are deprived of the influence of light by the presence of the
external cells. Here the combined (simultaneous) action of an
external cause (light) and a social cause is obvious : the obser-.ed
difference is a social difference.

 

 

 

 

 

 

 

 

 
74 THE QUANTITATIVE METHOD IN BIOLOGY

In the body of a vertebrate animal we find cells of various
kinds; for instance, nervous, glandular, epidermal, muscular,
cartilaginous, ciliate cells, etc. The differences between these
cells are strongly marked: if they were Protozoa, they would
be classified into different genera, families, etc. Between them
there are, however, no hereditary differences (the possibilities
are the same in each and all), since they all belong to the off-
spring of one egg; in each of them certain peculiar reactions
have resulted in peculiar properties according to the social in-
fluences. This example illustrates, perhaps better than any
other, the fundamental distinction between hereditary posst-
bilities and observable properties. Every biologist knows these
facts, but only few realise the importance of the consequences
which may be drawn from them.

§ 56.—FIRST EXAMPLE: SPIROGYRA (continued).—In
each cell of a Spfivogyra two primordia may be recognized:
length and breadth. ‘They are easily measurable, the measure-
ments being carried out in the direction of two axes (longi-
tudinal and transverse).+

§ 57.—FIRST EXAMPLE: SPIROGYRA  (continued).—
The primordia which we have already discerned in a Spirogyra
(or a similar plant) may be brought into five groups:

(rt) Number of axes (of segmentation and differentiation) :
one.

(2) Number of segments (cells=individuals x +1).

(3) Number of sorts of segments: two (terminal and inter-
mediate).

(4) Form of the two sorts of segments (cylindrical and
cylindrical with one rounded extremity).

(5) Dimensions of the segments (length and breadth).

All these primordia are measurable (the term cylindrical
represents a strictly geometrical notion) except the rounded
extremity. (This is not a difficulty from a theoretical stand-
point ; it merely depends on our ignorance.)

We may add to the above list the length and the breadth of
the egg (fifth group: dimensions).

It is possible to go further and to distinguish a number of
primordia within the cells ; for instance, the number of chromo-
phores, the dimensions of the nucleus, the number of chromo-
somes, the physical properties (optical axes, etc. STEIN-
BRINK) of the cell-walls, certain chemical properties (presence
of tanin in the vacuoles), etc. From a theoretical point of view

1It would be interesting to ascertain whether any difference exists between
the terminal and the intermediate cells with regard to their length and eventu-
ally whether the difference is the same in all the species.
CLASSIFICATION OF THE PRIMORDIA 75

all these properties may be expressed by measurement. In the
present work the internal properties of the cells are passed over
in silence ; therefore I content myself with a simple mention.
(See §§ 60, 72, 73.)

§ 58.—FIRST EXAMPLE: SPIROGYRA (continued).—
The mentioned primordia of an adult Sfivogyra (or a similar
plant) may be classitied with reference to their development in
the following way (see § 46) :—

(x) The properties (1), (2) and (5) are original, arrested and
persistent.

(2) The property (3) (differentiation) is arrested and persistent.
It may be looked upon as being an awakening property ; it does
not exist as long as the cells are only two in number (both being
terminal) and it is not produced by a transformation of a
previously existing property.

(3) The property (4) (form) is arrested and persistent for all
the cells. It may be looked upon as being awakening. (I don’t
take into account certain peculiarities of Spirogyra.)

§59.—FIRST EXAMPLE: SPIROGYRA (continued).
SENSITIVE PERIOD.—With regard to their sensitive period
(see § 47, second example), the mentioned properties of a
Spirogyra (including the egg) may be classified in the following
way :-—

(t) The properties length and breadth of the egg (first state of
each specimen) reach their final equilibrium (see § 45) within a
cell of the mother plant. Their development and, of course,
their sensitive period, are arrested when the egg is ripe. Later
on they are independent from any external cause (temperature,
light, etc.) whatsoever.

(2) A certain time (period of rest) after the sensitive period
of the above properties the sensitive period of the property
number of cells is initiated by the first cell-division. The value
of this property depends on the number of cell-divisions. If
we suppose that the divisions follow each other regularly, taking
place simultaneously in all the cells of a specimen, the property
number would pass through the series of values 1, 2, 4, 8, 16,
32... 2". The state of equilibrium (definitive number) may
be reached sooner or later (in a given species) according to the
external agencies which may augment or diminish the number
of divisions. Although we have little information about this
subject, it may be considered certain that temperature, food
and light have an influence. If the cell-divisions are arrested
(for instance, by falling off of temperature) in a given specimen
when the number 24=16 is reached and in a second specimen
of the same species when the cells are 2°=32 in number, a
76 THE QUANTITATIVE METHOD IN BIOLOGY

difference 1:2 will exist between both; but if we take the
number of divisions into account, the difference is only 4:5
or I: 1-25. There seems, at first sight, to exist a complete
disproportion between cause and effect.1 When the last cell-
division has taken place the sensitive period of the property
number of cells is over. (Compare § 66.)

(3) When the specimen has reached its equilibrium in
respect of the number of cells, the latter have not yet attained
their full size. This is certainly the case with their length, the
further increase of which may be considerable and is certainly
influenced by external causes. The sensitive period of the
property length of the cells begins really after the last cell-
division and is therefore limited to the last part of the period
of development (growth) of the specimen.

(4) The property number of axes is (as far as we know) inde-
pendent from the conditions of existence.

(5) The properties number of sorts and form of the cells seem
to be also independent from external influences, except if the
number of cells did not exceed two, which is thinkable (if so,
cylindric intermediate cells would not exist).

We see from the above that the sensitive periods of three
groups of properties of Spirogyra (length and breadth of the
egg, number of cells, length of the cells) do not coincide. There-
fore the three groups are independent from each other with
regard to plasticity. It is, for instance, a priorz, possible that
a small egg produces a specimen with numerous short cells,
that a big egg produces a specimen with few long cells, etc.,
etc. This must be taken into account whenever we wish to
investigate any form of correlation between the mentioned
properties.

These principles are, of course, applicable on any animal or
vegetable species. (See § 47, p. 56.)

§ 60.—FIRST EXAMPLE: SPIROGYRA (continued).—In
Spirogyra a longitudinal axis really exists. I have also sup-
posed the existence of a transverse axis in the egg and in each
cell, but this axis remains in reality latent till sexual reproduc-
tion takes place. When the moment of reproduction approaches,
two specimens of Spirogyra place themselves side by side, the
cells facing each other by pairs. Each cell produces a tubular
outgrowth which meets the corresponding outgrowth of the
opposite cell. The axis of each outgrowth clearly indicates the
position of the transverse axis of the cell. Since all the out-
growths of each specimen seem to be in the same plane, we may

1Compare the law of Weber.
2 TI have no information about the further increase of the breadth.
CLASSIFICATION OF THE PRIMORDIA 77

conclude that the transverse axes of all the cells are probably
in one plane.?

The conjugating processes have (apart from their position)
certain simple measurable properties (length, diameter) which
belong to the fifth group (dimensions) in § 57. The existence
of the sexual outgrowths is a result of a differentiation within
the limits of one cell and ought therefore to be brought into a
sixth group of properties. (Compare the five groups in § 57.)
The properties of the outgrowths are awakening, arrested and
rather caducous or deciduous. Their sensitive period very
probably begins after that of all the other properties.

§ 61—THE UNIAXIAL SYSTEM IS A PRIMARY
SYSTEM.—Since the segments (cells) of a Spirogyra follow
each other according to one axis, I call an adult specimen of
this plant a uniaxial system. This is the simplest system of
segmentation ; it is observed again and again in the animal
and in the vegetable kingdom? It is a primary system from
which several other systems are derived.

Since the properties of the living beings are ordered with
reference to their axes, the determination of the axes is of high
importance for the exact definition and the measurement of
each property.

The study of the uniaxial system and its derivatives is con-
tinued in § 69. In §§ 62-68 I mention four special systems of
segmentation which have merely indirect relations (if any
relation at all) to the uniaxial system and about which I have
incomplete information.

§ 62—SPECIAL SYSTEMS OF SEGMENTATION. I.
RADIAL SYSTEM.—Under this name several different
systems are confounded. A radial system is observed in
Polyps. The radial system of the Echinoderms has a different
origin. ; ;

The radial system of the spiral and pseudo-cyclic flowers pro-
ceeds indirectly from the uniaxial system, and is, on the other
hand, in relation with the sectorial symmetry which prevails in
the true cyclic flowers.

See also Pedtastrum tetras, § 64, Fig. 3.

1The egg e has probably, within its mother-cell, a definite position with
regard to the transverse axis b of the latter. On the other hand, the position
of the transverse axes b} of the cells of the specimen produced by e is probably
already determined in the egge. It would be interesting to know the relative
position of 6 and 5b}. ;

2 Examples: The hairs of innumerable plants (here the segments are uni-
cellular), the antenna of an insect (here the segments are so-called joints), etc.
In the simplest case a uniaxial system includes only two segments ; for instance,
the teleutospores of Puccinia, the first pair of cells produced by the segmenta-
tion of the egg in animals and plants, etc.
78 THE QUANTITATIVE METHOD IN BIOLOGY

§ 68—SPECIAL SYSTEMS OF SEGMENTATION (con-
tinued). Il. THE TETRAHEDRAL SYSTEM.—This well-
known system of segmentation is observed in the pollen of a
number of Phanerogams (Evica, Rhododendron, etc.), in the
spores of many Cryptogams (Selaginella, Saccharomyces, etc.),
etc. This system is a primary system from which more com-
plicated systems are derived. Interesting examples of such
complications are observed in the pollen of Mimosa and certain
Orchids.

§ 64—SPECIAL SYSTEMS OF SEGMENTATION (con-
tinued). III. PEDIASTRUM, EUASTROPSIS.—Among the
algz we find several peculiar dispositions of the segments, some
of which are remarkable by their singularity and elegance.1

A specimen (cenobium, individual x) of Pediastrum? con-
sists of a certain number of cells (individuals x +1) which are
united into a regular discus. The constituent cells of a given
discus are produced by successive divisions of one cell, just as
the cells of a Spirogyra; but in Pediastrum the cells do not
remain attached to each other after each division ; they separ-
ate and become for a certain time independent, swimming
within a vesicle which proceeds from the mother-cell. At a
given moment the hitherto isolated cells are united by juxta-
position ; they become adherent and constitute a disciform
society called cenobium (specimen, individual x).

This discus is, in the full sense of the word, a society of cells
which find themselves in a state of equilibrium. We discern
here (as in Spivogyra) a differentiation into two sorts of cells ;
the marginal cells are of different form from those in the centre
and they are furnished with a pair of diverging processes.®
This differentiation is brought about by social causes (§ 55), for
all the cells are alike (without processes) as long as they are
independent. The number of cells is 4, 8, 16, 32... asina
typical Spirogyra.

In the genus Euastropsis (allied to Pediastrum) the develop-
ment proceeds on the whole as in Pediastrum, but the individual
x (cenobium) consists of two cells.

Our information about the relative disposition of the cells
in Pediastrum and Euastropsis is somewhat incomplete. A

1See the classic illustrated works on fresh-water alge; for instance, G. S.
WEST, A Treatise on the British Fresh-water Alge (Cambridge University
Press, 1904).

* Ibid., p. 209.

3 These processes are an example of differentiation within the limits of one
cell. (Compare the sexual outgrowths in Spirogyra, § 60.) Certain cells in
certain mosses (marginal cells of the leaves of Tortula ruralis) are furnished
with processes which recall those of the marginal cells of Pediastrum. Com-
pare also several Desmids,
CLASSIFICATION OF THE PRIMORDIA 79

bicellular specimen of Ewastropsis is more or less comparable
with a uniaxial system with two segments. In Pediastrum tetras
the cells are ordinarily four in number, united into a rect-
angular cross (radial system? rectangular biaxial system ?).
In other species of Pediastrum certain specimens consist of
eight cells, one of which is central and the seven others
marginal. This disposition in (more or less distinct) concentric

Z 3

Fic. 3.—1. Euastropsis. 2. Pediastrum tetras. 3. Pediastrum
consisting of sixteen cells. (Schematic, after WEST)

rings is also observed when the cells are more numerous.
According to NAEGELI,! the following dispositions are the
commonest :—

Specimen of 8 cells 1+7 .
” » 16 4, I+5+10 (Fig. 3, 3)
” » 32 4, I+5+10+16

Although these regular arrangements are not always observed,
it is incontestable that a remarkable plan of structure exists in
these alge. This calls for reflection.

§ 65—SPECIAL SYSTEMS OF SEGMENTATION. III.
PEDIASTRUM AND EUASTROPSIS (continued). FRUIT
OF MYXOMYCETES AND GASTEROMYCETES. POLYP-
IFORM ANIMALS AND OTHER EXAMPLES. MORPHO-
LOGICAL HOMOLOGY AND MECHANICAL CONCORD-
ANCE.—The classical morphology is based upon embryological
investigation. We try to explain the structure of a given adult
organism by the knowledge of its development. Starting from
the initial cell and proceeding step by step, we look upon each
state of development as being produced by a transformation of

1 Quoted after G.S. WEST, Joc. cit., p. 209.
80 THE QUANTITATIVE METHOD IN BIOLOGY

a previous state. This ontogenetic method had an enormous
influence upon the progress of morphological science, apart
from any theory about the origin and phylogenetic relations
of species. The results obtained by the comparative method
which was formerly used alone (Comparative Anatomy of
CUVIER), and which is based upon the comparison of adult
specimens, have been explained, verified and often corrected by
embryological investigation.

It may be asked, however, whether the universal use of the
embryological method does not divert our attention from
certain aspects of the morphological problems.

In the example of Pedzastrum the curious structure of the
adult specimen is quite independent of any previous state. It
appears suddenly, by the juxtaposition of parts (cells) between
which there was previously no relation at all. Since our
morphological (embryological) method does not afford any
explanation of the structure produced in this way, Pediastrum
is put apart as a curiosity.

Pediastrum is not an isolated case. It is impossible to find
any embryological explanation of the regular disposition of the
cells in an adult specimen of Volvox, Hydrodictyon, etc. (See
§ 68.) Other interesting examples are found among the Myxo-
mycetes. In the numerous species of this group a certain
number of isolated cells (amebo-spores, etc.) are produced by
successive divisions of one initial cell (spore). These cells
wander about within the substratum ; after a certain time two
cells meet each other and are united into a plasmodium, which
becomes a centre of attraction: more cells join this centre. In
the plasmodium no definite morphological structure exists
because the relative position of the cells (represented by their
nuclei) is continually modified by amzboid movements. At a
certain moment the movements are stopped and the society of
cells is brought into a state of stable equilibrium ; it becomes
transformed into a so-called fruit.

In numerous Myxomycetes the fruit has a vegulay form which
is characteristic of each species. Since it is impossible to find
any relation between this form and the preceding state, morphol-
ogy based on embryology gives us little help when we want to
investigate the structure of the fruits of the Myxomycetes.
Here a morphology of a peculiar kind ought to be created. The
primordia of the objects under consideration ought to be deter-
mined and measured in order to find a base for comparison.
Each primordium represents a state of equilibrium or, in other
words, a part of a system which is in equilibrium. An exact

1A similar method is applied in historical science; for instance, in paleog-
raphy, philology, numismatics (see the works of LELEWELL, SERRURE

and others), economic history, etc.
CLASSIFICATION OF THE PRIMORDIA 81

quantitative knowledge of the parts may enable us to analyse
the whole system. In this way a Morphology of the states of
equilibrium may be built up: this is, of course, only possible
by comparing numerous species.

The resemblances which exist between the fruits of several
Myxomycetes may be brought under the principle of mechanical
concordance, in order to distinguish them from the morpho-
logical homologies.

It may be expected that a morphology of the states of equi-
librium, based upon the quantitative investigation of the
primordia, may throw new light not only upon the structure of
the above-mentioned plants, but also upon numerous resem-
blances to which the morphologists have hitherto paid little
attention.

EXAMPLES: A remarkable resemblance exists between the fruits of certain
Myxomycetes and that of certain Gasteromycetes (Lycoperdon, Tulostoma,
etc.). Both groups of objects are widely different in their phylogenetic origin,
their individual development and their morphological significance. For the
Gasteromycetes we may follow the embryological method, starting from an
initial cell and proceeding step by step till the adult state is reached. This
method, however, does not afford a complete elucidation of the final state of
equilibrium. The resemblance with the Myxomycetes remains unexplained,
because the embryological method is not applicable on the latter plants. As
long as we are influenced by the idea that morphological facts are merely
an expression of genealogical relations and may be completely elucidated by
embryology, the resemblances alluded to are a remarkable something, without
further significance. But when we look vpon the objects mentioned as being
states of equilibrium, a new basis of comparison may possibly be obtained.

Let us recall the striking similarity between certain Polyps (Campanulavia,
Sertularia, etc.) and certain plants with regard to the relative position of the
branches; the resemblance between the epidermic scales of many reptiles,
the dermic scales of many fishes and even the cuticular scales of butterflies
with regard to their relative position ; the astonishing resemblance between the
seeds of Drosera and those of many orchids ; the well-known so-called analogy
between the fore-legs of Gryllotalpa and Talpa, between the eye-shaped spots
which adorn the feathers of certain birds, the wings of certain butterflies and
the skin of certain fishes, etc., etc.

In all similar cases, we try to explain the observed facts by means of the
principle of converging adaptation (which is based, at least in part, upon
physiological analogy). This principle involves a number of hypotheses.
Adopting the theory of natural selection, we are compelled to accept that :

(1) The observed similarities have been brought about gradually, by the
accumulation of a long series of impalpable variations in each of the com-
pared species.

(2) These variations have been hereditary.

(3) Each successive step has been the cause of certain advantages in the
struggle for existence, important enough to bring about the selection (survival)
of the varying specimens. ett:

(4) The successive changes have been accumulated along the same line in
forms of life which differ from each other as deeply as a Myxomycet from a
Gasteromycet, a butterfly from a fish, etc.

If we adopt the neo-Lamarckian theory, we must suppose that : :

(1) Each of the observed resemblances is the result of individual adaptations
(accommodations) to similar physiological functions or conditions of existence.

(2) The variations produced by accommodation (in widely different species)
have been fixed by heredity. :

All the above hypotheses require verification. As long as this has not been

F
82. THE QUANTITATIVE METHOD IN BIOLOGY

carried out in a satisfactory way, the term convergent adaptation is a delusive
screen behind which we conceal the problems which ought to be solved. And
moreover, even if convergent adaptation were proved to be a reality, it would
give us merely a physiological explanation, the morphological aspect of each
example being simply overlooked.

I think it is preferable to adopt the method of the mineralogists. We
know many examples of substances, completely different by their chemical
constitution, which occur in the same crystalline form. The mineralogists,
looking upon each crystal as being a system of molecules which are in equili-
brium, have built up a morphology of the crystals which is an exact science
quite independent of any theory about the origin and the transformations of
the crystallized substances. This has been rendered possible by discerning
and measuring the simple properties of the crystals.

Two different substances, both of which crystallize in the form of a regular
octahedral or a pentagonal dodecahedral are in the same state of equilibrium.
In a similar way, a ripe fruit of a given Myoxmycet and a ripe fruit of a Lyco-
perdon are in a comparable state of equilibrium: they are, as it were,
crystallized in the same system.1 I express this by saying that mechanical
concordance exists between them. Similarly, an adult Pedzastyum, an adult
Spirogyra, the fore-legs of Gryllotalpa and Talpa, etc., are systems of material
parts which are in equilibrium, for a very simple reason: if they were not in
equilibrium they would be modified (further developed) till a state of equili-
brium is reached. (See § 45.)

We are tempted to consider that the above-mentioned objects are known
when they have been described in a few lines by means of vague terms (long,
short, broad, narrow, convex, oboval, etc.). In reality, such descriptions,
piled up in thousands of volumes, are incomplete. In a similar way, the term
octahedral gives incomplete information about a crystal, because a number of
different octahedrals exist which can only be distinguished by the measurement
of their angles and internal properties. The quantitative investigation of the
primordia of animals and plants would not only enable us to describe and to
identify them more exactly than by the ordinary method: we may expect
to find in the collected data (figures!) material for a morphology of the states
of equilibrium—which might be, in a certain sense, a crystallography of the
organisms, quite independent of any theory about their origin and genealogy.

Between the suggested line of investigation and classic morphology there
is neither discordance nor contradiction. Following the method based upon
the measurement of the primordia, we want to avail ourselves of the information
already collected by systematic natural history, embryology, classic morphology
and also physiology *—trying to complete and to perfect this information by
investigating the facts from a different standpoint.

See on PARALLEL VARIATION, § 135.

§ 66—SPECIAL SYSTEMS OF SEGMENTATION. III.
PEDIASTRUM AND EUASTROPSIS (continued). SENSI-
TIVE PERIOD.—Two specimens of Pedzastrum which differ
by the number of cells may be looked upon as being of different
age with reference to the primordium umber. In the course
of the development of each specimen this number passes
through the values (compare § 50): 3, 2, 4, 8... 2", which
coincide with 0, I, 2,3 .. . # cell-divisions.

In a specimen 6 consisting, for instance, of 2° = 32 cells, each
cell considered separately has been after the fifth division in a

1 At least with reference to a part of their properties.
2 T am using here the term physiology in its broadest sense, including biology
roperly so-called (pollination of flowers, dissemination of seeds, symbiosis,
etc.), heredity (Mendelism, etc.), etc.
CLASSIFICATION OF THE PRIMORDIA 83

state of equilibrium of such a kind as to suppress any cause
which might bring about a new division.!. In a specimen a
consisting of 2*= 16 cells, the same state has been reached after
the fourth division. Therefore it may be said that a is younger
than 6 in respect of the property under consideration. (This
remark is also applicable on Spirogyra, § 59.)

As soon as the cells are connected with one another the sensi-
tive period of the property nwmber is over. Since the cells have
not yet reached their definitive dimensions, the sensitive period
of the primordium dimensions (size) begins about that moment.
The sensitive periods of number and size being independent,
both properties are also independent with regard to their
plasticity. (Compare Spirogyra, § 59.) An adult specimen with
small cells is younger than a specimen with large cells in respect
of the property size, whatever may be the number of cells. A
given difference between two adult specimens which belong to
the same species depends on plasticity; the same difference
between two specimens which belong to distinct species de-
pends on a difference in their living mixture if the conditions
of existence have been the same through the whole duration
of their development.

§ 67—VARIATION STEPS IN PEDIASTRUM.—See on
VARIATION STEPS, Part VII.

§ 68—SPECIAL SYSTEMS OF SEGMENTATION (con-
tinued). IV. VOLVOX, HYDRODICTYON.—In these Alge
the cells are united into a very characteristic system of equi-
librium (society) ,? which is, as far as I know, distinctly different
from any other system in the animal and vegetable kingdoms.

As in Pediastrvum, the initial cell undergoes a certain number
of successive divisions, the produced cells separating after each
division. When the definitive number is reached, all the hitherto
independent cells unite at once into a ccenobium, which is an
elegant hollow sphere or utricle. There is thus no morpho-
logical relation between the relative position of the segments
(cells) in an adult specimen and the preceding states of develop-
ment. (Compare Pediastrum, § 64,and the Myxomycetes, § 65.)

§ 69 (continued from § 61, p. 77)—SYSTEMS OF SEG-
MENTATION DERIVED FROM THE UNIAXIAL SYSTEM.
RAMIFICATION AND CLEAVAGE.—We have seen, in § 61,
that the uniaxial system is a primary system, from which
several other systems are derired.

1The equilibrium alluded to is, of course, distinct from the equilibrium

which exists between the cells when they have met one another.
2See G. S. WEST, loc. cit., pp. 195, 207.
84 THE QUANTITATIVE METHOD IN BIOLOGY

The uniaxial system may produce more complicated systems
along two different lines: (1) by ramification ; (2) by cleavage
—t.e. a secondary segmentation in the direction of a new axis.
(See § 77.)

§ 70—RAMIFICATION OF THE UNIAXIAL SYSTEM.
FIRST EXAMPLE: PSEUDOCHETE.—Among the Alge
we find a number of simple examples of ramification of the

uniaxial system. I take as
| example Pseudochete gracilis
(allied to Herposteivon), which
i ; occurs as an epiphyte on aquatic
plants.1_ A specimen x consists,
at first, of one row of cells united
into a uniaxial system similar to
Spirogyra. Irepresent this prim-
ary filament (pluricellular in-
dividual) and its axis by xA or
A. The individual (stem) A
creeping on the surface of an
aquatic plant, its axis may be
called horizontal.

Certain cells of A produce a
lateral erect branch B (or xB),
the axis of which is vertical?
In each branch B a certain
number of segments (cells) are
produced by segmentation (cell-
Fic Pseudochate gracilis (Sche Gays): B'Decomyes ml skis Way

4 che : a Sart
eee after WEST, loc. cit., Fig. 30) in hgdee ie gre eee
adopted in § 54, each constituent segment (cell) of an individual
(stem) A is called A +1 (or xA +1) ; each cell of an individual
Bis called B+1x (or x6 +1).

One might be tempted to believe that I am bringing useless
complications into the subject. I am, in fact, facing complica-
tions which really exist, and which must not be overlooked if
we want to apply the quantitative method. 413

In Pseudochete gracilis a fully developed specimen or indi-
vidual x is, indeed, a society constituted by one individual xA
(or A), and several individuals xB (or B), which consist them-
selves of simple individuals (cells) 4+1z and B+z1. All the
cells have been produced by successive divisions of one initial

1G. S. WEST, loc. cit., p. 88.

2 Between a branch B and one of the reproductive branches (outgrowths)
of Spirogyra (§ 60) mechanical concordance very probably exists. It may be
recalled that mechanical concordance may be independent of any physiological
analogy and of any morphological homology.

 

 

 

 

 

 

 

 
CLASSIFICATION OF THE PRIMORDIA 85

cell: therefore the possible reactions (hereditary possibilities,
latent properties) are the same in each and all. The observ-
able properties of a specimen x (mentioned in our books) depend
on the possibilities of its cells, but all these properties are not
observable in each cell: they are distributed among the cells
according to certain laws. In a given cell, certain reactions
have produced certain primordia (or a certain value of a given
primordium) ; in’ another cell other primordia (or another
value) have become observable because different reactions have
taken place. (Compare §55. Remark, p. 74.)

The differences between the unicellular individuals (cells) and
between the pluricellular individuals A and B depend on social
causes (§55. Remark, p. 73) and are governed by social laws.
Therefore, when we want to compare several specimens x
(societies of individuals, Fig. 4) by measuring a primordium
~ in each and all, we must give an exact definition of the
segments (branches, cells and, in general, individuals) in which
p is measured.

In § 54 (Remark, p. 71) I have adopted a series of biological
units (individuals) x, x+1I, +2... subordinated to each
other according to the principle of segmentation, x +2 being pro-
duced by segmentation of x+1, and «+1 by segmentation of x.
Here I adopt a second series of units, A, B, C,. . . based upon
the principle of ramification, C being produced by ramification
of B, and B by ramification of A, etc. (In Pseudochete A and
B exist.)

In Pseudochete gracilis both series of units ought to be dis-
tinguished: B (or xB) is any individual (branch) produced by
a ramification of an individual A (or xA). Any primordium
of an xB (for instance, its length, measured along its axis) is
comparable with the same primordium in any other xB what-
ever. B+1 (or xB+1) is a unit (in our example a cell of an
erect branch) produced by segmentation of a unit B, which is
itself a branch of a unit A. A primordium of a unit B+Tis
comparable with the same property in any other unit B+1.
(See § 72, p. 87.)

It may be expected that a further development of the
quantitative method will render the adoption of a notation in-
dispensable. I have used, in § 54 and in this paragraph, a
notation in order to express the notion of series of subordinated
units in a GENERAL FORM, which renders application
possible in any case whatever. In the present state of things,
however, it is possible to use terms. Example: I calla certain
individual the fst B + x (numbering the cells or individuals B + 1
along the axis. B from its proximal to its distal extremity).
The same individual may be called the basal cell of an erect
branch.
86 THE QUANTITATIVE METHOD IN BIOLOGY

§ 71—RAMIFICATION OF THE UNIAXIAL SYSTEM.
FIRST EXAMPLE: PSEUDOCHAETE GRACILIS (con-
tinued). GRADATION. HAIRS. IMPORTANCE OF THE
AXES.—The five groups of primordia which I have distin-
guished in an adult Sfivogyra (§§ 57 and 60) are found in
Pseudochate gracilis. Here they are, of course, to be measured
separately in the creeping stems (units A) and in the erect
branches B. In this way, it is possible to bring the description
of a given specimen x into the form of about a dozen of notions
(primordia) expressed by measurement.

In the erect branches B we observe a very simple example
of gradation. Each of these branches has the form of a cone
which is very narrow in proportion to its height (length). The
constituent cells are (as in Spirogyra) of two sorts (differentia-
tion) : the terminal cell is conical; each of the other cells has
the form of a truncated cone. The diameter of the cells
(expressed, for instance, by the diameter y of their proximal
base c) decreases regularly from the base (proximal extremity)
to the summit (distal extremity) of the conic branch.

I call GRADATION the variation of a given primordium
along a given axis. (See §38 and Part VIII.) Here the varying
property is the diameter y. In a given cell, the value y! of the
diameter measured at its base c depends on the distance x!
between c and the origin (base) of the axis (branch). In other
words, in general, y is a function of x. In the given example the
relation between y and x is very simple (the gradation curve
being a straight line, oblique in respect of the axis).

The axis of an erect branch of Pseudochete gracilis is: (1) an
axis of segmentation (§ 54); (2) an axis of di*ferentiation
(§ 55); (3) an axis of gradation. This is applicable in general
on any axis whatever.!

The great importance of the axes is brought into prominence
by the fact that an axis is always a line of segmentation, differ-
entiation and gradation. All the segments (individuals, units)
of a living being ave arranged according to the direction of its axes
and all its properties ave arranged with reference to these axes.
Each property ought to be measured in the direction of an axis,
or in a direction which is definite with regard to an axis.

In an erect branch of Ps. gracilis we may measure the degree
of gradation; this may be roughly expressed by the ratio
between the diameter of the base of the basal cell and the length
of the branch. This ratio, being a quotient obtained by divid-
ing a primordium with a second one, is a compound property.

1In an egg of Spirogyra, for instance (§ 54), the longitudinal axis is the axis
of segmentation and differentiation of the adult specimen. Since the trans-
verse diameter of the egg is variable along the mentioned axis, the latter is

also an axis of gradation.
CLASSIFICATION OF THE PRIMORDIA 87

In many plants we find hairs consisting of one row of cells,
which are similar to an erect branch of Ps. gracilis, the terminal
cell being different from the others in one or
another way. In such a hair the same
primordia as in an individual B of Ps.
gracilis are found. The mechanical concord-
ance between both objects is obvious. (Compare
Fig. 5 with the erect branches in Fig. +4.)

§ 72.—RAMIFICATION OF THE UNI-
AXIAL SYSTEM. FIRST EXAMPLE:
PSEUDOCHTE GRACILIS — (continued),
CLASSIFICATION OF THE PRIMORDIA .—
The primordia of Pseudochete gracilis! may be
classified according to the following scheme
(compare §§ 57, 60) :—

(z) Stem and branches (axes): two sorts (4
and 8B).

(2) Number of each sort.

(3) Relative position of the axes 4 and B.
This is a phyllotaxic property.

(4) Number of axes of segmentation in stem
and branches (one axis in A and in B).

(5) Number of segments (cells) in A and B.

(6) Form of the segments (cells) in A and B
(cone, truncated cone, etc.).

(7) Dimensions of the segments (cells) in 4
and B.

(8) Total length of the stem A and the
branches B.

(9) Gradation (branches B): «, with refer-
ence to the breadth (conical form); 6, with
reference to the variation of the length of the
successive cells. (In the creeping stems A
gradation is, I think, imperceptible.)

(10) Degree of gradation in the branches
B (compound property).

Since several branches B occur, we may
content ourselves with measuring the properties
5, 6, 7, 8, 9 and Io only in the longest branch. ek
With regard to 7 (dimensions of the cells in pyg 5 4 haircon-
the branches B) we may limit ourselves to the sisting of four
basal and the terminal cell of the longest erect cells. (Petiole of
Beant. Evodium moscha-

‘ 5 : tum)

The above scheme is applicable to any object

similar to Ps. gracilis in its structural plan. Most of the

1 The contents of the cells being excluded.

 

 

 

 
88 THE QUANTITATIVE METHOD IN BIOLOGY

mentioned properties are variable within the limits of a given
species: the method of measuring variable properties is ex-
pounded in Part VI.

§ 73.—RAMIFICATION OF THE UNIAXIAL SYSTEM.
COMPLICATED CASES.—In Pseudochete gracilis the ramifica-
tion of the uniaxial system is very simple: the whole plant x con-
sists of one uniaxial individual (creeping stem) A of the frst
order or generation and several individuals (erect branches) B of
the second order or generation.

The system of ramification of innumerable plants, belonging
to various systematic groups, is based upon the same principles
as that of Ps. gracilis.

EXAMPLE: A young tree (for instance, Fagus or Quercus)
x consists the first year of a simple stem A (uniaxial individual
of the first order or generation) divided into several segments or
internodes + which are segments or individuals A+1. The
stem A produces by ramification uniaxial individuals (branches)
B of the second generation, divided in their turn into internodes
B+1. When this state is reached the young tree x is compar-
able to a Ps. gracilis (each internode taken as a whole being
‘comparable to a cell).

The branches B may produce in their turn individuals
(branches) C, and soon. Along each branch (axis) the branches
of the next generation and the internodes may be numbered
from the base to the summit. Whatever may be the number
of generations, branches and internodes, each individual (stem,
branch, internode) has a definite place in the society of sub-
ordinate individuals which is called a tree.

The differences between the individuals (stems, branches, inter-
nodes) which are associated in a given tree * depend on their
position—that is ta say, on social causes. I leave out of account
the differences brought about by external causes—for instance,
temperature, rainfall, light, shade, etc., which influence the
primordia of each segment during their sensitive period.

(See, on this subject, §§ 59 and 66.)

In any ramified plant we find a large number of simple
properties, which may be distinguished and classified according
to the scheme in § 72.

The ramification of a uniaxial system does not only produce
branches properly so called, but cauloms and phylloms of various
kinds (leaves, phyllodes, cladodes, scales, glumes, sepals, petals,

1An exact definition of the limit between two intemodes is a rather subtle
morphological question. With regard to the application of the quantitative
method, the usual empiric and somewhat conventional definition of this limit
may be adopted.

2Tn other words, the individual variation within the limits of one specimen
CLASSIFICATION OF THE PRIMORDIA 89

etc.). All these individuals, whatever may be their nature,
have a definite position. Each of them may be regarded as a
uniaxial system in which several primordia may be discerned.
Moreover, the leaves, petals, stamens, etc., may be ramified in
their turn (leaves of Trifolium, petals of Reseda, stamens of
Fumaria, etc.). In all the segments produced in this way
primordia may be discerned according to the scheme in § 72.
Similar principles are applicable on the trichomes (hairs, glands,
etc.). (See §§ 57, 60.)

Certain primordia are not mentioned in § 72. Some of them
are important, for instance :

(x) Certain segments (individuals) may be united. In a
gamopetalous corolla (or gamosepalous calyx) the parts are
united into a cup, tube or ring. The stipules are detached
from the leaf or adhering to the leafstalk or united into a ring
or sheath round the stem, etc.

All such properties? are mentioned or described in the floras: they are
almost always easily measurable. Examples: In a gamophyllous corolla
or calyx we may measure the length of the tube, the length and the breadth
of the free portions (segments, lobes. teeth). In a leaf of a rose, we may
measure the total length of the stipules and the length of their free portion.

(2) The colours: each colour is measurable by means of a
scale of colours or by a chemical or spectroscopical analysis.

§ 74.— RAMIFICATION OF THE UNIAXIAL SYSTEM.
COMPLICATED CASES (continued) —The different sorts of
units (cauloms, phylloms and trichoms) which constitute a
ramified system, their relative position and the forms of rami-
fication are described in the classic literature on morphology
and phyllotaxis (including the floral diagrams).

Let us now compare two specimens, a and 8, with regard to
a given property ; for instance, the length of the leaves. This
property is almost always very variable within the limits of each
specimen ; the differences depend for a part on social causes
(place of the leaves).? For a comparison between a and 6 the
social differences ought to be eliminated. When a leaf « has
been measured in a we want to find and to measure in 0 a leaf

1The differences between the individuals alluded to are comparable to the
differences between different sorts of specialized individuals observed in certain
polypoid animals.

2? Whatever may be their morphological significance.

° All the leaves of a specimen (for instance, a tree) are individuals of a certain
sort which belong to one society (just as certain specialized individuals in
certain polypoid animals). The variation of each of their primordia (for
instance, their length) is in part a consequence of plasticity (external causes);
for another very important part a consequence of social causes (gradation,
Part VIII.).
90 THE QUANTITATIVE METHOD IN BIOLOGY

which has been developed under the same social conditions as
a.1 This problem is solved by determining the position of «
with regard to the system of axes of a and by finding in 0 a leaf
Pennell has the same position with regard to the axial system
of 8.

The method is applicable as often as the system of axes is not
too complicate.

EXAMPLE: We want to compare two or several specimens
of Quercus rvobur pedunculata with regard to the primordia
length of the leaf and number of leaves. The question is com-
paratively simple if we take young specimens; for instance, in
their third year. The main stem A may be #ractically looked
upon as consisting of three segments (successive annual shoots)
A +1 coinciding with the three years. Each segment A +1 is
divided into internodes A+2. The leaves may be counted, for
instance, in the third A +1 (terminal shoot of the main stem).
The lowest (first) leaf of this segment (=the first leaf of the
third yearly shoot) may be taken for the measurement of
the primordium /Jenglh.2 The mentioned leaf being measured
and the leaves being counted in all the specimens, social
variation is eliminated and the figures are comparable, just
as if we had measured, for instance, the breadth of the third
cervical vertebra in a number of specimens of one species of
mammalia.

The above method, applied on a series of species of one genus
(or on the indigenous trees and shrubs) would give very inter-
esting results; many characteristic features, many unsus-
pected similarities and differences would be discovered. For
such a comparison of different species it would be, of course,
necessary to take a number of specimens? of each species,
because individual variation ought to be taken into account
(Part VI.).

§ 75— RAMIFICATION OF THE UNIAXIAL SYSTEM.
COMPLICATED CASES (continued). INDIVIDUAL DE-
VELOPMENT. PRIMORDIA OF THE SUCCESSIVE
UNITS OF ONE SPECIMEN. PRIMORDIA OF CUTTINGS
AND GRAFTS.—Suppose we want to study the embryology
of the leaf of Quercus pedunculata. If we take at random a
certain number of leaves in successive stages of development
and compare them, the observed differences certainly depend for
a part on the social differences between the investigated leaves
(which are individuals). If we want to obtain exact results, the

1In other words, the leaf 8 ought to be a social equivalent of a.

2In reality it would be preferable to measure the longest leaf of the terminal
shoot. (See Gradation, Part VIII.)

3 Material (seedlings) of many species may be obtained at a rather low price
from any well-equipped free nursery.
CLASSIFICATION OF THE PRIMORDIA 91

method expounded in § 74 ought to be followed. Leaves between
which social equivalence exists ought to be taken in successive
states; and, moreover, the method of the curves of develop-
ment ought to be applied. (See § 49.) We may investigate ina
similar way the embryology of the internodes, the scales, the
trichoms, etc.

We might be tempted to say, for instance, that the terminal
shoot of the main stem produced in the course of the fourth
year represents a further state of development of a tree than
the terminal shoot produced in the course of the third year.
This would be, in reality, inexact. The successive yearly seg-
ments do not coincide with successive stages of development.
These segments (shoots) are individuals of a certain order
(1+1;3 see § 74), which are produced successively by means of
buds; we may call them bud-generations. The successive bud-
generations are superposed, as if they were grafted on each
other; this results in social relations. Therefore the differ-
ences between the successive yearly (terminal) shoots of a main
stem! are not embryological but social differences. (See
gradation, Part VIII.)

Cuttings: We may take, for instance, the terminal shoot
of a main stem as a cutting and cultivate it separately; the
social relations with the main stem being suppressed, the next
bud-generation produced by the cutting is more or less different
from the bud-generation which would have been produced if the
previous relations had been preserved.” In certain cases the
produced modification is very distinct.

Grafts: In a similar way a terminal (or any other) shoot
A+z1 of a specimen x may be grafted upon another specimen
x1; new social relations are brought about and in the next bud-
generation produced by A +1 the properties may be modified.
If the material is strictly monotypic—in other words, if there is
no specific difference between the specimens x and x!—the
observed modifications are a consequence of the social changes.
But if x and x! belong to different species ® the observed changes
depend not only on social causes, but also on a specific influ-

1 Such differences always exist. In many species they are very apparent ;
for instance, with reference to the properties of the leaves (Cecropia, Morus
nigra, Symphoricarpus racemosa, many Leguminose with compound leaves,
ae — the cutting is the terminal shoot of a main stem developed in the
course of the tenth year. It may happen that the next shoot (produced by
the cutting ) has leaves similar to those produced by the tree in its first, second
or third year. Starting from the erroneous idea that the tenth year represents
a further state of development than the first, second or third years, and from
the principle that the successive yearly shoots coincide with successive states
of the phylogenetic evolution, we are tempted to say that the cutting shows
a reversion to an ancestral state. We are deceived, I think, by an illusory

appearance.
* Example: Pyrus cydonia grafted upon Crategus monogyna.
92. THE QUANTITATIVE METHOD IN BIOLOGY

ence of x1 upon A +1, certain properties of x being eventually
transmitted to A +1.!

The quantitative investigation of the primordia of the species
x and x' and of allied species, and a similar investigation of the
individuals (cauloms, phylloms and trichoms) produced by the
graft might bring us nearer the elucidation of the complicated
problems alluded to.

§ 76.— RAMIFICATION OF THE UNIAXIAL SYSTEM.
COMPLICATED CASES (continued). ANNUALS, PEREN-
NIALS, BULBOUS PLANTS, SHRUBS, TREES.—The
quantitative investigation of annuals, perennials and bulbous
plants (Orchis, many Liliacee, Amaryllidacee, etc.), the rami-
fication of which is comparatively simple, may be carried out
according to the principles expounded in §§ 73-75. But as
often as a large number of bud-generations are united into one
specimen a complete analysis of the whole is very difficult,
although the theoretical possibility always exists. In such
cases we may make a choice among the numerous parts (indi-
viduals) which are united into one society (specimen) according
to certain CONVENTIONS.

All the herbaceous perennials and suffrutescent plants pro-
duce every year (in our climate) new fertile stems which die
after flowering (Solidago, Iris, many Gramineae, etc.). For a
quantitative description of the species we may limit ourselves
to these stems. If two or several stems are produced by one
specimen (stock or woody base), it is advisable to take the
first stem which is ordinarily (not always) more vigorous than
the others and flowers earlier than these.

In the shrubs and the trees it is somewhat difficult to find com-
parable material for the specific description of the primordia
of the vegetative parts. More or less satisfactory results
may be obtained by taking (if possible) terminal segments
(shoots) ¢ at the extremity of main stems, ten or more years old,
or terminal segments #1 of lateral branches consisting of succes-
sive terminal shoots produced for a period of zen or more
years. It may be admitted that such segments ¢ (respectively
t+) have developed under social conditions which are approxt-
mately the same for each and all. In several species a distinc-
tion ought to be made between short shoots (spurs, Kurztriebe)
and long shoots (Langtriebe).2 Segments developed at the

1 The specific influence and the possible transmission alluded to are quite
independent of the question whether the transmitted properties are fixed in
the seeds produced by the graft A +1.

2 An exact definition of short and long shoots and exact information about
the social conditions under which they are produced may be expected from
quantitative investigation. :

Certain branches having produced typical short shoots for a number of
CLASSIFICATION OF THE PRIMORDIA 93

periphery of the crown (sunshine) ought to be distinguished from
segments developed in the central parts of the crown (shade).
Adventitious branches proceeding from the main trunk or
from its base ought to be excluded (or to be investigated
separately).

This subject is exceedingly complicated. Since the quan-
titative method is still incompletely established, it is advisable
to limit ourselves, for the quantitative specific description of
the properties of the vegetative parts, to the study of young trees
and shrubs raised from seed (p. 90).

We may have recourse, however, to the quantitative in-
vestigation of the fertile parts; for
instance, inflorescences, bracts, flowers, =
fruits, seeds. These parts, indeed, are
brought into existence under certain [|
definite social conditions in each species
and are therefore comparable, at least
approximately. In these parts we find
a number of primordia large enough to
render possible, in a satisfactory way,
a quantitative description of all the
species.

§ 77. RECTANGULAR BIAXIAL
SYSTEM, PRODUCED BY SECOND-
ARY SEGMENTATION OR CLEAV-
AGE OF THE UNIAXIAL SYSTEM 4 9
(continued from § 69, p. 84).—An adult he A= Ss eee
specimen (individual x) of Spirogyra is “"(Schematic. after WEST.
divided by segmentation intoa number Fig. 36.) (1) young speci-
of segments or individuals (cells) x+ 1, 2 flee ae (2)
which follow each other in the direction biasial systeun ) ea
of oneaxis. I call this axis the principal
or primary axis, or axis North-Soulh (NS). If each segment
(cell) is divided in its turn into two segments in the direction
of a secondary axis East-West (EW) perpendicular on NS, a
new system, represented in Fig. 6, 2, is obtained. This is a
rectangular biaxial system. I call segmentation or principal
segmentation (primary segmentation, segmentation NS) the division
in the direction of the primary axis NS and secondary segmenta-
tion or cleavage (segmentation EW) the division according to the
secondary axis EW.

If the segmentation NS has been limited to the production
of two segments (cells), and if each of the latter has produced
only two segments by cleavage EW, a system of four segments

 

 

 

 

FETT)

 

 

 

 

 

 

 

 

years begin to produce long shoots at a certain moment (for instance, in Sorbus
aucuparia).
94 THE QUANTITATIVE METHOD IN BIOLOGY

is obtained. This is often (not always) observed in Pleuro-
coccus vulgaris (Fig. 7).1 In the segments of a rectangular
system (for instance, Fig. 7, 5) a number of successive divisions
may take place. If divisions NS and EW occur in all the

segments (cells), the

segmentations NS

() and EW alternating

regularly, a_ rect-

4 angular system is
3

obtained, in which
all the segments are
regularly placed in
rows NS and rows
EW, as the squares of

a chess-board. I call
} this a_ chess -board
system.
Regular or almost
regular examples of
4 5 e

the chess - board

Fic. 7.— Pleurococcus vulgavis. (Schematic.) en ma found in
(1-5) Successive states. (6) Irregular specimen Certain Alge (for in-
stance, certain Ulva-

cee), in the leaves of certain mosses (disposition of the cells), in
the disposition of the scales on the wings of numerous butterflies,
in the elytre of a number of Coleoptera, in many shells, etc.
Examples of the chess-board system, more or less altered, are
innumerable. The knowledge of
this system is important for the
investigation of the primordia of
plants. It is of the highest im-
portance in the animal kingdom.

 

§78.—PRIMORDIA IN A
RECTANGULAR BIAXIAL
SYSTEM (CHESS-BOARD
SYSTEM).—In a regular chess-
board system four primordia may
be distinguished: (x) the number
of segments in the longitudinal |
direction iv S; (2) the number of Fic. 8.— Part of a regular chess-
segments in the transversal direc- board system. (Schematic)
tion EW; (3) the dimension of
the segments in the direction NS (length); (4) the dimension of

 

 

 

 

 

1 The system represented in Fig. 7, 5; is, of course; quite different by its origin
from the quadricellular ceenobium represented in Fig. 3; p. 79. Between both
mechanical concordance probably exists.
CLASSIFICATION OF THE PRIMORDIA 95

the segments in the direction EW (breadth). These very simple
notions are applicable, for instance, on the quantitative investi-
gation of the scales on the wings of the butterflies, taking
socially equivalent segments in the wings of all the spieces of
a genus or a family.

§79 —ALTERATIONS OF THE CHESS-BOARD SYSTEM.
—The typical chess-board system (Fig. 8) may be modified along
several lines. This results in numerous deviations and com-
plications, many of which have been described as isolated facts,
or regarded as adaptations or mere curiosities! All these
modifications, however various and complicated they may be,
ought to be looked upon as states of equilibrium. Adopting
this view, we may regard them all from one standpoint—in a
similar way, as the mineralogists have brought together into a
whole the various deviations and complications of innumerable
crystals.

In order that we might be able to analyse the primordia of a
given chess-board system, we want, above all, to know the direc-
tion of the axes. This is almost always easily found: we may
take as axis NS the longitudinal axis of the object under con-
sideration. Sometimes it is more convenient to take an anti-
clinal (radial) or a periclinal (tangential) direction as axis NS.
In certain cases, the choice of the primary axis is arbitrary
for instance, in Pleurococcus (Fig. 7, 5), in which it is impossible
to discover any difference between the axes NS and EW.

I want to recall that any axis whatever is a line of equilib-
rium, segmentation (or cleavage), differentiation and gradation:
therefore the axes are the lines of orientation (ovdonnance) of
all the primordia of a biaxial system.

In general, the primordia of a chess-board system may be
classified according to the scheme in § 72 (supplement in § 73,
p. 89). (See also §§ 57, 60.)

Taking the above principles into account and starting from
the regular chess-board system (Fig. 8, p. 94), the alterations of
this system may be classified in the following way 2 :—

I. A chess-board system (segment, unit or individual x) may
be divided into groups of cells which are individuals or units
*x+1 intermediate between the whole system x and its simple
components or cells x+2. In a similar way the pluricellular
units «+ 1 may be divided into pluricellular units «+ 2, the cells
being ++ 3, etc. (See § 80.)

1 Numerous examples are found in the specific descriptions of shells, insects;
fishes, reptiles, etc.

2 The following classification is probably incomplete : it ought to be regarded
as being a first attempt to set in order a number of facts which have been
hitherto overlooked or described in a fragmentary way.
96 THE QUANTITATIVE METHOD IN BIOLOGY

II. In a chess-board system x gradation may be observed in
one of the directions NS or EW, or in both directions at the
same time (§ 82.)

II]. In a similar way gradation may be
observed in the intermediate units (seg-
ments) x+1,%+2,... alludedto. (Sub. I)

_IV. In a chess-board system differentia-
tion may occur. (§ 83.)

V. In a similar way differentiation may
be observed within the limits of the inter-
mediate units x+ 1, x+ 2, etc.

VI. In a chess-board system one axis or
both axes may be curved lines. (In reality,
a curved axis consists of a succession of very
short, straight axes.) (§ 84.)

VII. A chess-board system may become
irregular, its constituent segments being in
disorder. (§ 85.)

VIII. A rectangular chess-board system
may be altered by the existence of oblique
ie85 aa axes?) in the plane NS-EW.
§ 86.

§80—ALTERATIONS OF THE
CHESS - BOARD SYSTEM (continued).
INTERMEDIATE UNITS.—The epidermis
of the interior surface of a scale of an onion
bulb (Allcum cepa) consists of one layer of
cells, which are united into a chess-board
system x. We observe a segmentation into
a number of segments x+1 following each
other in the direction EW (transverse direc-
tion). Each segment x+1 (longitudinal
row) is segmented in its turn into unicellular
segments x+2 according to the direction
NS. The longitudinal rows x+1 are indi-
viduals intermediate between the epidermis
considered as a whole and the cells. In
each longitudinal row the /imits between
the cells are independent by their position
of those in the adjacent rows—in other

 

Fic.g. — Allium cepa.
Epidermis x of the i
interior surface of a words, each row has its own independent

scale ofabulb. Four segmentation. The cells are almost always

longitudinal

rows
(segments x + 1) longer than broad.

In this example the properties are dis-
tributed in a different way according to both axes. This
difference is, moreover, expressed by the fact that the resist-
CLASSIFICATION OF THE PRIMORDIA 97

ance to traction of the epidermis is greater in the direction
NS than in the direction EW.

It may happen that the division into intermediate segments
occurs in the direction of both axes; this is observed in certain
Algz; for instance, I/ea. (See N. WILLE in ENGLER und
PRANTL.) Here the segments x+1 consist of four cells each,
and follow each other in both directions in the same way, being
united into a regular checker-work.!

A more complicated segmentation isfound in the genus
Prasiola. (See N. WILLE in ENGLER und PRANTL.) Here
a specimen x is segmented into units x+1, which follow one
another according to both axes, NS and EW. Each unit
x+1 consists of four units, *+2. —- ae
Each unit «+2 consists of four | [ | |
units (cells), «+3 (Fig. 11).

In the three above examples
(onion, Jlea and Prastola) the
individuals intermediate between | aa
x and the cells are very small and
consist of a few cells. Very often
the segments are larger, the laws |
of segmentation being the same. =]

The (epidermal) scales of :the

lizards and other (not all) reptiles a
are segments (individuals, units) (__
of a certain order produced by a Fic. 10.— Zea. (Schematic)
segmentation of the epidermis.
In the tail of a lizard, for instance, the epidermis x is divided
into transversal (annular) segments x+1, which follow each
other in the (longitudinal) direction NS.? Each segment «+1
is divided in its turn into multicellular units, x+2 (scales),
which follow each other according to an axis EW. (This dis-
Position is in a certain sense inverse of that observed in the
onion, in which the segments x+1 are longitudinal.)

In the elytra of the Coleoptera we find innumerable examples
of chess-board systems, altered in the most various ways, which
all consist of multicellular units. One of the finest examples is
observed in Calosoma sycophanta (and other species of the same

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

1A similar segmentation is observed in certain forms of Pleurococcus vulgaris,
but here the society of cells has an ephemeral existence: the cells isolate
themselves after a certain time. ° : :

*The segmentation of the epidermis of the tail of a lizard into annular
segments +1 is independent of the segmentation of the interior parts,
which finds its expression in the vertebral column (vertebre), the muscular
system, etc. The conception that the body of a vertebrate animal is divided
into segments is chiefly based upon the skeleton. In reality, two or even
several (more or less concentric) independently segmented systems exist. In
a similar way, two or more independent systems exist in the body of the
Articulates, the Annelids, etc. (See Triaxial System, § 88.)

G
98 THE QUANTITATIVE METHOD IN BIOLOGY

genus). An elytrum of this handsome beetle is divided into a
number of units (longitudinal ribs), which follow each other in
the direction EW. Each rib is segmented in its turn into
multicellular quadrangular segments x+2, which follow each
other according to an axis NS.1_ On the whole, the disposition
of the segments recalls that of the cells in the epidermis of an
onion (Fig. 9). (Mechanical concordance.)
er ara Anunlimited number
‘ | i of various examples are
4 observed in the shells
| 1 of the molluscs.

 

A

 

 

 

 

, These objects have been
% hitherto described in a rather
4 4 empirical way. When they are
: ! i looked upon as being chess-
7 : board systems, governed
pe ain Sv Sabie Sth ich Re a sige amie’ by the principles expounded
* in this book, they afford a
very interesting and fascin-
ating subject of investigation
and measurement.? In order
to realize the importance of
the shells, which have been
rather neglected by the mor-
__§ phologists (and disdained by
‘ many biologists), one may
\ consider their importance
a si : a for the study of plasticity
Fic. 11.— Prasiola. (Schematic) (influence of the conditions
of existence), zoological
geography, oceanography, paleontology (here investigation is limited to the
shells) and geology. (See § 89.)

§ 81—LIMITS OF THE SEGMENTS. VEXILLARY
MARKS.—In the preceding examples the limits between the
segments are distinct. These limits, however, may get more or
less obliterated or disappear completely. Even in such cases
it is often possible to discover the disposition of the segments
and to count them by means of certain vexillary marks.

FIRST EXAMPLE: In certain parts of the human skin,
for instance on the palm of the hand, we observe a number of
parallel (somewhat curved and irregular) furrows,* separated by
intervals of about one half-millimetre. Each ribbon-like seg-
ment between two furrows is an individual «+1 (the epidermis
being x) comparable to the longitudinal segments *+1 in
Fig. 9 and to the annular segments of the tail of a lizard. In

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

1In this description, only the part of the elytrum comprised between its
proximal border (sutura) and the so-called series umbilicata (vaphe) is taken
into account. A number of details are passed over in silence.

2T have measured a number of primordia in many species. My notes are
not within my reach. See further.

3 These furrows are easily distinguishable from the very variable oblique
wrinkles of the skin.
CLASSIFICATION OF THE PRIMORDIA 99

certain places we observe (on the hands of certain persons)
tibbon-like segments, which are divided themselves by slight
transverse furrows ' into square segments or scales, x + 2, which
correspond (mechanical concordance) to the scales of a lizard
or the unicellular segments v+2 in Fig. 9. When it happens
that two or three adjacent ribbon-like segments are divided
into square segments, the chess-board system becomes evident :
one might say that the epidermis consists of scales.2 In the
centre of each scale the opening of one gland is visible.
Ordinarily, however, the slight transversal furrows are
obsolete, but the pores (openings of the glands) remain always
distinct, as vexillary marks which indicate the latent segmenta-
tion: they may be counted (for instance, at
the finger-ends) and from their number we
know the number of amalgamated scales.
SECOND EXAMPLE: It may happen
that the limits between the segments of a
chess-board system are obsolete, but that the |
segments differ from each other by one or
another property. In such cases the seg-
ments may be counted and their limits are
more or less (although indirectly) discernible.
The shell of many molluscs (for instance,
Cassis tessellata) is adorned with a regular
system of coloured spots in longitudinal and
transverse rows. These spots are vexillary Fic. 12—Portion of
marks which point to the existence of a human __ epidermis
chess-board system in one of the layers of givided info scales.
the shell. scale a gland
THIRD EXAMPLE: The curious square
spots which form a sort of checker-work in the epidermis of
the perianth of certain flowers (Fritillaria meleagris, certain
Colchicacea, Vanda cerulea, etc.) have perhaps a similar

significance.

REMARK: Between the examples mentioned or alluded to in §§ 80-81,
neither morphological homology nor physiological analogy, nor phylogenetic
relations exist. They are all governed by the general principle of mechanical
concordance—just as deeply different chemical entities which crystallize in
the same system.

 

 

1 To discern these slight furrows I have used a power of x 16.

2 After desquamation, by which the corneous layer of the epidermis is carried
off, the longitudinal and the slight transversal furrows are reformed in the new
corneous layer exactly as they were before. From this it may be concluded that
the existence of the scales depends on a segmentation of the meristematic layer
(vete mucosum) of the epidermis.

3 Periclinal (EW) and anticlinal (NS) rows. These terms are used here with
reference to the margin (border) of the aperture of the shell. With regard to
the shell taken as a whole periclinal = longitudinal and anticlinal = transverse
(spiral), See p. 113.
100 THE QUANTITATIVE METHOD IN BIOLOGY

§82.—ALTERATIONS OF THE CHESS-BOARD SYSTEM
(continued from § 80). GRADATION IN A CHESS-BOARD
SYSTEM x OR IN THE SYSTEMS x+1, «+2, ETC.—In the
examples mentioned in §§ 80-81, gradation (Part VIII.) has been
purposely overlooked. In reality, however, it is very difficult
to find a chess-board system in which gradation does not exist.
Here I content myself with a schematic example.

I start from the regular system x represented in Fig. 13, 1.
I suppose (Fig. 13, 2): (1) that x is divided in the direction
EW into two segments, «+1, the limit sy-sy being a plan of
symmetry; (2) that each segment *+1 is divided into three
longitudinal segments x+2 (a, b,c; c, b, a); (3) that each
longitudinal segment x + 2 is divided into a series of segments

7 x+3 following one
3 4 5 s ; eel another in the direction
NS; (4) that each seg-

ment *+3 is adorned
° ° ° o | With a central spot.
Taking each  prim-

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

“| ordium ~ separately, I

° ° ° 0 9 o | suppose (5) that the
i _| breadth of the segments

7 x+2 (a, 6, c; ©, 8, a)
. : 2 2 ® s decreases regularly in
a both directions (east-
‘ ys . 4 é 9 | ward and_ westward)
from the plan of sym-

metry to the lateral

° ° oO ° ° o | borders; (6) that in
i | each longitudinal seg-

Fic. 13, 1. System x ment x+2 the length of

the segments ¥+3 de-
creases from the base to the summit, the decrease being less
rapid in c,c than in 8, 8, and in 8, 0 less rapid than in 4, a;
(7) that the gradation of the breadth of the spots is governed
by the same law as the gradation of the segments in the direction
EW; (8) that the gradation of the length of the spots (dimen-
sion NS) is governed by the same law as the gradation of
the length of the segments (of each longitudinal row) in the
direction NS (the spots disappear at the extremity N of the
segments a, a, because their length becomes 0).

In this way we obtain the system represented in Fig. 13, 2.
This example gives us an idea of the endless variety of the
derivatives of the biaxial system produced by gradation (In
the direction of each axis segregation may be observed See
§ 38, p. 45.) However complicated the derivatives may be,
it is possible to analyse them by measuring each priraordium
CLASSIFICATION OF THE PRIMORDIA 101

separately in the direction of both axes. By the application
of this method to the description of shells and insects, of the
epidermis of plants, etc., an exact quantitative description of
the species will be rendered possible. It may be anticipated,
moreover, that inter- es sy Xs

=

esting similarities and ;- \

 

mechanical laws will
be discovered.

 

 

 

 

§ 88.— ALTERA-
TIONS OF THE
CHESS-BOARD SYS- | =
TEM (continued).
DIFFERENTIA-
TION. — Differentia- | ©
tion may be brought
about by various causes
and occurs in all pos-
sible degrees.

When a segment of
any system (uniaxial
or biaxial) is different
from the other seg-
ments by one or several
properties, we call it
differentiated.1

For instance, in the
epidermis (chess-board
system) of numerous (

 

 

 

 

 

|

 

0

 

 

)

 

 

 

 

 

 

 

|

See
lo Olle

ce

 

[D]o]{ofolofojo

 

Or Ore

 

 

 

 

 

plants and insects cer-
tain cells are different
from the others because

they are transformed

into hairs or glands, or “Ol b c Sy Be ze 2 '

because they contain a
colouring substance or
a cystolith. It seems often as if the position of such a
differentiated unicellular segment (idioblast) was accidental.

In many cases, however, a differentiation may be regarded
es a result of a gradation of a peculiar kind, and it may even be
surmised that this is a general rule.

‘Tn a typical example of gradation the variation of a property
p along an axis is gradual, without any sudden jump. I call

1Segmentation and differentiation, which are quite distinct notions, are
sometimes confounded under the term differentiation.

Instead of saying, for instance, that an antenna of a certain insect is differ-

entiated into twelve joints, we ought to say ... segmented...or...
divided. .

Oo
)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Fic. 13, 2.—sy-sy, plane of symmetry
102 THE QUANTITATIVE METHOD IN BIOLOGY

this continuous gradation. In the conical hair represented in
Fig. 5 (p. 87), for instance, the gradation of the primordium
breadth of the cells is continuous along the axis.

When, on the contrary, a sudden change is observed in the
value of p at a certain level of the axis, gradation is discon-
tinuous and produces differentiation.

EXAMPLE: An antenna of Cavabus is (with regard to the
exoskeleton (=cuticula)) a uniaxial system divided into eleven
segments (articles).1_ The gradation of the primordium length
of the segments may be described (in the majority of the species)
in the following way :—

Joint x: long.

” Zs short.
» 3: long.
» 4: Short.

» 5-11: length decreasing gradually from 5 to 11.

Here joint 2 is differentiated from 1 and 3. Between 3 and
4 the differentiation is very distinct in certain species, less
distinct in others. From 5 to 11 the gradation is almost always
continuous.

Between typical continuous gradation and typical discon-
tinuous gradation (differentiation) all possible transitions
exist.

In a chess-board system continuous gradation (Fig. 13, 2),
typical differentiation and all possible transitions between both
may be observed in the direction of one or both axes and in
various primordia.

EXAMPLE: The epidermis of a young leaf of Allium
porrum is divided in the direction EW into a number of seg-
ments, each of which consists of one longitudinal row of cells,
in the same way as the epidermis of an onion scale (Fig. 9,
p. 96). In each cell we may distinguish an extremity S
(proximal) and an extremity N (distal); a latent cause of
gradation according to the axis NS exists in each cell. At a
given moment of the development each cell (unit «+ 2) is
divided into a northern cell 6 and a southern cell a, and now
gradation finds its visible expression, the N-cell 6 being much
shorter than the S-cell a. Since the difference in length
between a and 0 is very distinct, we may say that gradation
results here in differentiation.

Later on a second difference between a and 6 becomes app< 1-
ent (Fig. 14): a develops into an ordinary epidermal Gell,
whereas 6 is divided (in the direction EW) into two cells
which form a stomate. In this way the curious differentiattion
of the units (longitudinal rows) x+1 into alternative stormatic

1In reality, the segments are twelve in number, the first segment be ing very
small and concealed.
I

CLASSIFICATION OF THE PRIMORDIA 103
segments and epidermal segments properly so called may be

regarded as a consequence of
gradation.

In the S-cells a latent gradation
exists ; it finds often its expres-
sion in a division into a N-cell a”
and a S-cell a’, the cell a” being
shorter than a’. (See Part VIIT.)

§ 84. — ALTERATIONS OF
THE CHESS-BOARD SYSTEM
(continued). SIMPLE AND
COMPOUND AXES. CURVED
AXES.—An axis, in its simplest
form, is the imaginary line which
joins the centres of two cells
produced by a division?; it is
therefore a straight line. Such an
original axis may be called a
simple axis. In the hitherto men-
tioned examples I have looked
upon the axes of the objects
under consideration as being
straight lines. Those axes are
indeed simple axes (teleuto-spores
of Puccinia, § 61, p. 77; the axis
EW of a stomate, Fig. 14, etc.),
ot compound axes consisting of a
number of successive simple axes
following each other in the direc-
tionof one straight line (Spirogyra,
§ 54, Fig. 2).

It happens, however, very often
that a compound axis is curved.
The curvature of a compound
axis ought to be regarded as a
secondary modification, which
may depend on various causes.
In each peculiar case the cause
ought to be discovered.

I place in a FIRST GROUP
those numerous examples of
curvature which are due to ex-
ternal causes, such as gravity,
wind, accidental mechanical
causes, etc. EXAMPLES: The

 

 

 

 

a,

 

 

 

ye TRS me ee

Ses

 

 

Q
ee

 

i

Fic. 14.—Allium porrum.  Epi-
dermis. NS, North-South. a, a,

a’, a”, epidermal cells.—b, 6,
stomates

axis of the flower stalk of many plants is straight; later on it is
1Or, more generally, of two adjacent cells. See Euastropsis, § 64.
104 THE QUANTITATIVE METHOD IN BIOLOGY

gradually curved in proportion as the weight of the fruit in-
creases. The flowering stems of a number of Graminee (and
many other plants) are more or less curved (drooping) under the
influence of gravity, the degree (and the plan) of curvature
being variable according to the intensity (and the direction) of
the wind.

SECOND GROUP: More interesting are the cases in which
the curvature, depending on internal causes, is fixed and
constitutes a characteristic feature of the object.

FIRST EXAMPLE: An oblong or oval leaf of a moss
(Mnium, Bryum, Tortula, Catharinea, etc.) is limited on both
sides by a curved line (margin), the median nerve being straight.
This object is a more or less modified chess-board system, con-
sisting of numerous unicellular segments, the axes being NS
(longitudinal) and EW (transverse). How can it be ex-
plained that the axis NS is straight in the middle and curved
along both margins? Two factors are here at play.

The fist factor depends on gradation. When the cells are
counted in the tvansverse direction at successive levels from the
base to the summit (from S to N) it is seen that their number
increases till the place of the greatest breadth of the leaf is
reached. Here we find the maximum. Further towards the
summit the number gradually decreases. The property
number oj cells is thus variable all along the axis NS.
consequence of this gradation is a displacement of the marginal
cells,t which do not any longer form a straight longitudinal
row. Two successive marginal cells, taken at random, are
joined by a straight simple axis; the successive simple axes
follow one another in the form of a broken line, which is a
compound axis.

The second factor depends on the flexibility and elasticity of
the cell walls. Since all the successive marginal cells are united
by their walls, they form a continuous whole, the margin, which
is brought into a new state of equilibrium: the margin is
curved over its whole length and assumes the form of a con-
tinuous curve (the angles between the simple axes being as it
were, smoothed out). The form of the curved (marginal) axis
depends thus (1) on the relative position and the direction
of the simple axes, which direction and relative position depend
themselves on gradation ; (2) on the flexibility and elasticity
of the cell-walls.

The cells which form one longitudinal row (or several parallel
rows) in the middle of the leaf are not displaced: here all the
successive simple axes form one straight compound axis. Ina
leaf considered as a whole the direction of the middle nerve

1 And, of course, of all the longitudinalzrows of cells, in proportion as they
are at a greater distance from the nerve.
CLASSIFICATION OF THE PRIMORDIA 105

may be taken as the axis NS. If we want to study the parts
near the margin (for instance, the cells of the differentiated
border) it is in general more convenient to take the tangential
(periclinal) direction as the axis N’S and the radial (anticlinal)
direction as the axis EW. (At the place of the greatest
breadth of the leaf the periclinal axis is, of course, parallel to
the nerve.)

SECOND EXAMPLE: It may happen that in a chess-board
system (Fig. 13, 1) the primordium nzmber of cells in the
successive longitudinal rows (counted in each row in the direc-
tion NS) augments gradually in the transversal direction ;
for instance, from W to E (the dimensions of all the cells being
supposed to be the same). As a consequence of this gradation
the whole system will be bent in such a way that the margin W
will become concave and the margin E convex. Just as in the
first example, the curvature depends here on gradation, and
each margin forms a continuous curve, the explanation being
the same as for a leaf of a moss. A similar curvature may be
produced by a gradation of the primordium length of the cells
(from W to £) according to the axis EW. If the primordium
number of cells is at play, the sensitive period of the curvature
coincides with the period of cell-division; if the curvature
depends on the primordium length of the cells its sensitive period
comes later, coinciding with the period of increase of the cells.
Concave-convex curvatures are very common; for instance,
in the mandibles of almost all the insects, in many fruits
(Medicago, etc.), etc. For the investigation of such objects,
we may limit ourselves to the epidermis, which is a biaxial
system.

§ 85 ALTERATIONS OF THE CHESS-BOARD SYSTEM
(continued). DISORDER.—The segments of a chess-board
system are often in disorder, forming an irregular mosaic-work
in which it is sometimes difficult to discern the prmiitive dis-
position and the direction of the axes. In the leaves of the
mosses we observe all possible transitions between a regular
or almost regular checker-work in which the direction of the
axes is distinct and complete disorder. In the epidermis of
the leaves of the Monocotyledons the checker-work is ordinarily
regular ; in the majority of the Dicotyledons the epidermic cells
of the leaves are in disorder.

Several causes may produce disorder ; in each peculiar case
the cause ought to be investigated. I content myself with
mentioning three causes of disorder :

(x) If the cells were disposed regularly into longitudinal and
transverse rows as the divisions of a chess-board they would be
quadrangular, and four cell-walls would meet each other at
106 THE QUANTITATIVE METHOD IN BIOLOGY

each corner of each cell. This is a mechanical impossibility,
because the cell-walls always meet each other three by three.
Therefore a supplementary (more or less curved) facet is always

3

x.

Fic. 15.—Chess-board system in leaves of mosses.—1. Catharinea
undulata, almost regular. 2. Jd.,id., slight disorder. 3. Mnium
undulatum, disorder. Ad naturam

interposed at each corner: an alteration of the form of the
cells and a certain degree of disorder are unavoidable con-
sequences of this interposition. The cause of disorder is
universal, but its effects are ordinarily rather unimportant.
(Fig. 8.)
CLASSIFICATION OF THE PRIMORDIA 107

(2) Disorder may be a consequence of gradation. We have
seen, for instance (§ 84, first example), that in a leaf of a moss
gradation produces a displacement of the cells and a curvature
of certain axes: it is obvious that disorder may be brought
about at the same time.

(3) In a chess-board system each segment (for instance, each
cell) is an individual which is more or less independent of the
adjacent individuals.1_ All the individuals are plastic (as any
living individual whatever). Therefore diversity in the con-
ditions of development (see below) brings about variation, for
instance, with regard to size and form, and this is a cause of
displacement and disorder.

The development of the segments is influenced in various
ways by external causes within the limits of one system. For
instance, a small object may cover a part of the surface of a
system (a leaf of a moss, the epidermis of an animal or a
plant, etc.) and modify locally temperature and light ; certain
segments may be affected by a shock or by temporary contact
with any object, etc. Such causes, acting during the sensitive
period, may favour or thwart cell-division in certain segments
(Fig. 15), accelerate or slacken the growth of certain units, a
consequence of such local modifications being disorder.

When comparable parts are investigated in several species
in respect of disorder it is often seen that regularity prevails
in certain species and disorder in others. Therefore disorder
seems to be, in a certain degree, a property of certain species.
(Compare, for instance, the dorsal surface of the pronotum,
which is a chess-board system, in a series of species of
Carabus.)

It may be surmised that regularity prevails in the majority
of those cases in which the system or its segments are elongated
according to one of the axes (NS or EW), whereas disorder
is ordinarily observed when the system or its segments are
rather isodiametric. EXAMPLE: The epidermal cells of

1This physiological independence may be easily demonstrated. In the
epidermis of an onion bulb, for instance, certain cells which are weakened by
one or another cause (a shock, a short contact with a hot or a very cold object,
etc.) may be killed by a certain poison, whereas the adjacent healthy cells are
not visibly influenced. If the poison is a plasmolysing substance (for instance,
KNO, at 10 per cent.), the healthy cells are plasmolysed; in the weakened
cells only the wall of the vacuole (tonoplast) is plasmolysed and separated
from the exterior part of the protoplasma Gaenicine the nucleus) which is
killed. In cells which are still more weakened the whole of the living con-
tents of the cell is killed at once by the mentioned poison without any trace
of plasmolysis.

f a small quantity of eosine (puvissima) is added to the plasmolysing
solution the above differences between adjacent cells become still more evident,
since the killed parts are stained, the living (plasmolysed) parts being colour-
less (E. VERSCHAFFELT). This question has been thoroughly investigated
by A. J. J. VANDEVELDE.
108 THE QUANTITATIVE METHOD IN BIOLOGY

plants have ordinarily a regular position when elongated
and are rather in disorder when isodiametric.

It happens that the limits between the segments of a chess-
board system are obsolete, each segment being represented by a
vexillary mark (§ 81). If disorder exists at the same time, the
chess-board-like disposition may be at first sight indiscernible
because of the irregular position of the marks. EXAMPLE:
Disorder often prevails in the disposition of the hairs with

which the epidermis of
many insects and plants
is clothed, each hair
representing one seg-
ment.
The plan of structure
is, however, often recog-
N nizable by comparing
several species (some of
them being regular), or
by investigating accur-
ately the object in order
to discover traces of the
limits, and perhaps by
studying its embryonal
development.

Disorder is certainly
the most important
cause owing to which
the universal distribu-
N_ tron of the biaxial system

in animals and plants
has been hitherto over-
looked. I regret that I
have not been able to
find any method to

Fic. 16.—Munium punctatum. Cells of the leafs measure the degree of
N-N, nerve. Ad naturam disorder.

 

§ 86. ALTERATIONS OF THE CHESS-BOARD SYSTEM
(continued). OBLIQUE AXES IN THE PLANE NS-EW
(FALSE AXES ?).—In a number of biaxial systems the dis-
position of the segments points to the existence of oblique axes.
This is observed, for instance, in the leaves of certain mosses.
In Mnium punctatum the cells are often placed in longitudinal
and oblique rows, the latter being directed from the nerve
towards the margin and from the base towards the summit
of the leaf (Fig. 16). This is described as a character of the
species.
CLASSIFICATION OF THE PRIMORDIA 109

It is rather difficult to find an explanation of obliquity. A
priort three possibilities exist :

(1) The observed obliquity is merely an illusion due to a
quincunxial disposition of the segments.

(2) Obliquity is a consequence of an oblique position of the
cell-walls in each longitudinal row. In certain leaves of
Bryum argenteun I have observed that several longitudinal
rows are sometimes regular and parallel, the transversal cell-
walls being oblique (Fig. 17). Each row resembles a ladder
with oblique rounds. This curious disposition being limited to
a small part of the leaf, it may be supposed that obliquity is
here secondary, the cell-walls being oblique, the simple axes
being rectangular.

(3) It is conceivable that an obliquangular system really
exists. This would be obtained if the divisions were succeed-
ing each other alternately, for instance, in the directions NS
and SE-NW. In this case the axes
of both kinds would be in reality
lines of segmentation, gradation and
differentiation. I could not find
any example of this supposed
obliquangular biaxial system. The
determination of the exact direction
of the nuclear spindles might throw
some light upon this question.

Curious examples of obliquity are
observed in the shells of certain "Si, W7noRye” ae:
Mollusca and are mentioned as
specific characteristics ; for instance, in certain species of Tellina
(LT. fabula), Pecten, etc. (In these shells a rectangular system is
ordinarily predominant, the axes being anticlinal and periclinal.)

§ 87—REMARKS ON THE BIAXIAL SYSTEM (CHESS-
BOARD SYSTEM, §8§ 77-86). SIMPLE PROPERTIES.—
When we want to discern and to measure the primordia of a
given biaxial system we ought before all to establish the direc-
tion of the axes and the existing alterations ought to be deter-
mined. After this preliminary work the primordia (simple
properties) are measured in the direction of each axis, as if each
of both axes existed alone. In other words, the whole system
ought to be regarded as a compound of two independent uniaxial
systems. The primordia of each system may be enumerated
and classified according to the scheme in § 57 (see also §§ 60,
72, 73, 78), each primordium being measured separately.

It happens very often that two or more alterations exist simul-
taneously in a given system. Since the possible alterations
may coexist in the most various ways, numerous combinations
110 THE QUANTITATIVE METHOD IN BIOLOGY

are possible and are really observed. In each system the
primordia themselves ave combined (coexist) in a certain way,
which varies from one case to another, and the value of each
primordium is variable according to the species investigated.
Therefore the diversity of the chess-board system is practically
unlimited, although the fundamental plan of structure is always
the same.

By the application of the principles expounded in §§ 77-86 it
is possible, I think, to disentangle even very complicated cases,
to bring innumerable facts, which seem to be accidental and
capricious, under general rules, and to establish comparable
figures for long series of specific forms.

The investigation of a certain number of examples is indis-
pensable for the further development of the quantitative
method. It is advisable to begin this work with examples
which are not too complicated and to have recourse again and
again to the comparative method. Investigation of a certain
number of primordia in a series of well-known species of the
same genus (or allied genera) is, I think, the most profitable
way.

§ 88. — SECOND SECONDARY SEGMENTATION
(SECOND CLEAVAGE) IN THE BIAXIAL SYSTEM.
RECTANGULAR TRIAXIAL SYSTEM. (See § 69, p. 83,
and § 77, p. 93).—A rectangular biaxial system is produced by
primary segmentation NS and first secondary segmentation
or first cleavage EW. In such a system each segment may
be divided in its turn into individuals (segments) by a second
secondary segmentation or second cleavage according to an axis
ZN. Since this axis is perpendicular to the plane of the axes
NS and EW, I call it the axis Zenith-Nadir (ZN). It is the
second secondary axis or axis of the second cleavage.

In this way a rectangular iviaxial system is produced. In
a biaxial system the segments are united into one layer. A
triaxial system consists of two or several superposed layers of
segments, each layer being a biaxial system.’

In the simplest case a triaxial system has the form of a
rectangular, straight prism, consisting of several superposed
chess-board systems. This form is observed, for instance, in
Sarcina, in certain specimens of which it is remarkably regular.

In a triaxial system three planes may be distinguished (just
as in a triaxial crystal)—viz. ciacd

(1) The plane NS-EW, the position of which is determined
by the axes NS and EW (horizontal plane).

(2) The plane NS-ZN, determined by the axes NS and ZN
(longitudinal plane).

1 The choice of the axes NS; EW and ZN is arbitrary. See§ 79, p. 95.
CLASSIFICATION OF THE PRIMORDIA 111

(3) The plane EW-ZN determined by the axes EW and ZN
(transverse plane).

EXAMPLE: In a number of Phanerogams (Asclepiadacee,
Apocynacea, etc.) the epidermis consists of two layers of cells
and is therefore a very simple triaxial system. If we take, for
instance, in a leaf the plane which is parallel to the surface of
the epidermis as NS-EW, a longitudinal section (parallel to the
middle nerve and perpendicular to the epidermis) represents
the plane NS-ZN, and a_ transverse section (perpendicu-
lar to the middle nerve and therefore to the surface) repre-
sents the plane EW-ZN. When we take the plane NS-EW
(parallel to the surface) as base, in each of the superposed
systems (two layers), which follow each other in the direction
ZN, we may find all the alterations and properties which may
exist in any biaxial system (§§ 77-87). Since the superposed
layers are more or less independent of each other, differences
may be observed between them. The whole triaxial system
may be investigated by starting from one of the three planes,
for instance, NS-EW, and comparing the layers which are
superposed according to the axis ZN, by studying and measur-
ing their primordia on sections exactly parallel to the planes
NS-ZN and EW-ZN (longitudinal and transverse sections).

In the triaxial systems the alterations and the primordia of
each layer (biaxial system), combined with the differences
between the layers, bring about an endless diversity and
various complications, which reach the highest degree in the
massive parts of the higher animals and plants.?

By the application of the above principles it is theoretically
possible to analyse the most difficult objects and to express
their properties by measurement. In many cases, however,
the structure is so intricate that the difficulties seem to be
practically insurmountable as long as the quantitative method
is not better established. The impossibility of making sections
of one object according to three different planes is a serious
obstacle. Therefore, when we need to compare quantitatively
several specimens, a choice between the three planes ought to
be made, the properties being measured in the same plane in all
the specimens.

A large amount of information has already been collected,
especially by histologists and embryologists, about the internal
structure of animals and plants. Unfortunately the observed
facts have been rarely measured in a convenient way (if
measured at all), and the fundamental distinction between
simple and compound properties has been overlooked. Much
attention has been paid to morphological homologies, but

1Complication is often increased by obliquity (see § 86) and also by the
curvature of certain axes (see § 84) and by disorder (§ 85).
112 THE QUANTITATIVE METHOD IN BIOLOGY

mechanical concordance and social equivalence have been often
lost out of sight, and even physiological analogy has been rather
neglected, especially by the zoologists. In spite of all this, the
knowledge already gathered affords a guide for the quantitative
investigation of the primordia in the triaxial systems.

§ 89—RECTANGULAR TRIAXIAL SYSTEM (continued).
EXAMPLES.—According to the general scientific method,
which consists in proceeding from the simple to the intricate,
we ought to begin the quantitative investigation of the triaxial
system with the study of simple examples, limiting ourselves
to some easily measurable primordia. I give here four
examples :

FIRST EXAMPLE: The root of many Phanerogams before
the secondary growth is initiated. This organ may be regarded
as a triaxial system, the axes being longitudinal (NS), peri-
clinal (tangential, EW) and anticlinal (radial, ZN).1 On a
transverse section of the root (plane EW-ZN) the following
ten primordia may be measured (the list is incomplete) :—

(1) The number of cells of the cortex in the radial (anticlinal,
ZN) direction. In each root these cells ought to be counted
according to three or four or even more radii, the mean value
being taken as the figure of the root.

(2-4) The number of cells of the endodermis and their radial
and tangential dimensions.

(5) The number of radial rays of the xylem. ;

(6) The mean number (or, in each root, the minimal and
maximal number) of ligneous vessels in one ray. ; ;

(7-10) In the phloem bundles the number and the dimensions
of the cells in the vadzal and the tangential direction (investigat-
ing three or four bundles and taking the mean values” as the
figures of the root). als

It would be very interesting to study in this way the root of
a series of species of one genus (for instance, of Allium, Its,
Narcissus, Poa, etc.). Of course roots of several specimens of
each species ought to be studied, terymenal branches of the root
system (social equivalence, see §§ 74-75) being taken and the
sections being made at a given distance from the summit in
each and all. ; ; ;

A monograph of a genus being obtained, it would be interesting
to cultivate certain species under different conditions (in sand,
clay, peat; moist and dry, etc.), and to study quantitatively
the plasticity of the primordia above mentioned. By means of

1Considering any cell whatever, its simple axes are NS, EW and ZN.
Its simple axis NS belongs to the longitudinal axis which passes through its
centre. Similarly its simple axis ZN is a part of a radial axis and its simple
axis EW is a part of a curved (circular) periclin axis. (See, on the curved

axes, § 84.) .
2 Or the minimal and the maximal values.
CLASSIFICATION OF THE PRIMORDIA 118

a series of successive sections from the summit towards the
base it would be possible to construct the developmental curve
of each primordium.

A number of subjects of research may be found along this
line of investigation.

SECOND EXAMPLE: The siphon of the Pelecypods.

THIRD EXAMPLE: The shell of the Molluscs. This shell
consists of two or several superposed layers. Each layer may
be looked upon as being a chess-board system, the axes of which
are periclinal and anticlinal. In each layer (system) all possible
alterations (§ 79) may exist and are combined in various ways.
The successive layers are superposed according to an axis ZN
(normal to the surface of the shell). They are more or less
independent of each other. It happens, for instance, that in
the external system (superficial layer) the segmentation in the
direction of the anticlinal axis! is predominant, whereas the
segmentation according to the periclinal axis (division into
spirally curved resp. radiair segments) prevailsin the second layer.
In other cases the same segmentation (anticlinal or periclinal)
is equally predominant in both layers. In certain species the
second layer is completely concealed by the exterior one, the
properties of the latter being visible at the surface of the shell.
In other species the exterior layer is moulded upon the second
layer in such a way that the former bears the impression of
certain properties of the latter, the external characteristics of the
shell being a combination of the properties of both layers. In
many shells the coloured lines, spots, etc., are vexillary marks
(see § 81). In certain species oblique axes are observed (see
§ 86, p. 109). Very often segmentation is obsolete, except at
or near the margin, where it is indicated by teeth (Donax
anatina, etc.), coloured spots (species of Cassis, etc.), etc.

All the mentioned properties may be studied and measured
according to the method indicated for the biaxial system, each
layer being investigated separately.

More properties of the shells are easily measurable, for instance: (1) in
the spiral shells, the height of the shell and its diameter at the place of the
greatest breadth; (2) in the conic shells (Patella, etc.), the height, the length
and the breadth; (3) in the Bivalves, the length and the breadth of the
valves and the transverse diameter (the valves being closed and taken as
a whole).

The properties mentioned above are, of course, compound properties. For

 

1 In the majority of the Gasteropods and Cephalopods (Ammonites, Nautilus,
etc.) the shell has a spiralform. Here the anticlinal axis NS, crossing the free
margin of the aperture of the shell at right angles, is a spirally curved line
as the shell itself. The periclinal axis EW is tangent to the margin. In
Patella, Ancylus and other similar Gasteropods and also in the Pelecypods,
the periclinal axis is concentric (tangent) and the anticlinal axis is radial with
tegard to the shell considered as a whole.

A
114 THE QUANTITATIVE METHOD IN BIOLOGY

the description of the species, they may be regarded without inconvenience
as simple.

Several authors have tried to find in the dimensions of the shells (for instance,
the ratio breadth : length, etc.) characters of the species. This method has met
hitherto with little success, because the majority of the authors did not know
in which way variable properties ought to be measured (see Part VI.).!

In § 80, p. 98, I have called attention to the importance of
the study of the shells. Since the notes and the materia! which
T have collected for years are not within my reach, I must con-
tent myself with the above very incomplete indications.

FOURTH EXAMPLE: The retina of the vertebrate animals
is a triaxial system, the structure of which is complicated but
comparatively regular. I think that it is practically possible
to measure certain of its primordia.” A comparative investi-
gation of the retina of several allied species would be here, as
for many other subjects, the best method.

1See HENRY EDWARD CRAMPTON (Professor of Zoology, Barnard
College, Columbia University), Studies on the Variation, Distribution and
Evolution of the Genus Partula (the species inhabiting Tahiti). 314 pages,
34 +19 (very beautiful) plates and numerous diagrams and tables. (Carnegie
Institution of Washington. (Publication No. 228.4°. Issued 2oth January 1917.)

In this interesting work (with which I became acquainted through the
kindness of Prof. S. J. HICKSON, Manchester University) four properties
(length and width of the shell, id. id. of the aperture) are measured in numerous
specimens of a number of species and local races.

2 Dimensions of the cones, rods, pigmentary cells, etc.
PART VI

THE MEASUREMENT OF VARIABLE PROPERTIES OF
ANIMALS AND PLANTS. SIMPLE NOTIONS OF
PROBABILITY (FREQUENCY).

§ 90—The application of the quantitative method to the
study of animals and plants is almost entirely based upon the
theory of probability (theory of chance). This theory has been
applied to biological problems along two different lines: by
QUETELET (1846) and his followers (see § 32) to the measure-
ment of variable properties and by MENDEL (1866) to the
study of heredity (see § 33).

The knowledge of the principles of this part of mathematical
science is indispensable to any biologist who wants to investi-
gate quantitatively the properties of living beings. In the
works in which the theory of probability is expounded we find
a large amount of mathematical knowledge, whereas facts and
realities are mentioned in a few words only and looked upon as
being of secondary importance. Such works do not answer
the needs of the biologist ; they are beyond his reach. This is a
fact . . . a reality by which the progress of biology is seriously
hampered.

The path followed by the theory of probability is slippery
ground. From a biological standpoint the theory of chance
(frequency) ought to be built up by continual association
of observation, measurement, comparison, experiment and
mathematical deduction. A conclusion, drawn from exact
figures by means of an irreproachable mathematical argu-
ment may be delusive! Therefore any conclusion ought to be
VERIFIED by the quantitative observation of more facts.

Many biologists seem to believe that the quantitative method
is in relation with certain theoretical views about heredity,
variation, selection, origin of species, etc.; that the object of
the method is to DEMONSTRATE the reality of certain
principles. This conception of the question is erroneous! I
want to emphasize once more that the object of the quantita-
tive method is not to demonstrate something, but to DIS-
COVER facts and realities which it is impossible to discover in

1The same mathematical principles have been applied by MENDEL to

the study of the hybrids and by QUETELET to the measurement of the
stature of man.

115
116 THE QUANTITATIVE METHOD IN BIOLOGY

any other way, and to find an exact expression for the dis-
covered facts. This is independent of any biological theory.

In Part VI. I wish to expound some principles of the theory
of chance (frequency) in a simple form by means of a series of
examples. The following pages are written for biologists, who
prefer concrete facts to abstract considerations.

§ 91—FIRST EXAMPLE: THE POSITION OF EQUI-
LIBRIUM OF A SPHERE ON A HORIZONTAL PLANE.—
Let us suppose that a ball (for instance, a billiard ball), exactly
spherical and homogeneous, is thrown at random and falls
upon a horizontal plane surface . After a certain time all
motion ceases; the ball is then at rest on the plane. Its state
of equilibrium is characterized by two measurable values:
(x) the direction of the straight line which joins the centre (of
gravity) G of the ball and the point of contact P (this line is
vertical) ; (2) the distance GP (radius of the ball).

Which are, in this experiment, the relations between cause
and effect ?

The cause is, in reality, a combination or resultant of an
enormous number of forces or factors, such as the direction in
which the ball has been thrown, its initial velocity, the initial
rotatory motion, its successive positions while rolling over the
plane before it came to rest, etc. Since it is practically im-
possible to determine or even to enumerate the factors which
are in play, the cause is called chance: we may call it a com-
bined cause. If the above experiment is repeated several
times the cause is, of course, different from one throw to another,
for a given combination of factors practically never occurs a
second time. In each experiment the cause may be called
accidental or fortuitous. E

The effect, on the other hand, is always the same; it is the
above described state of (indifferent) equilibrium of the ball.
This effect is invariable, because it depends on certain prop-
erties of the object. If the ball were an animal or a plant, we
should say that 7 always reacts in the same way, according to its
specific energy, and that its primordia (direction of GP and
length of GP) are invariable. ; a _

In this example chance, in spite of its unlimited variation,
produces an invariable effect. (Compare § 104.)

§ 92.—SECOND EXAMPLE : THE POSITIONS OF EQUI-
LIBRIUM OF A COIN. HEAD OR TAIL. In the above
experiment (§ 91) the spherical ball may be replaced by any
other object, all the conditions being the same. Let us throw,
for instance, a very thin disc (practically a thin coin), one of its
sides being called head or a and the other side tai or 6. Here
MEASUREMENT OF VARIABLE PROPERTIES 117

two states of equilibrium are possible—viz. a and b; in other
words, two events a and b may be observed.!' The cause is
chance (combined cause), just as in the example of the ball.
The variation of this cause is unlimited, but it has only two
different effects: a or b. This depends on certain properties
of the coin; in other words, on its specific energy. (If the
coin were a living being, we should say that there is alternative
variation with regard to a pair of primordia a and 6.)?

The two events a and 0 are equally possible, because one
cannot discover any cause (factor) by which one of both would
be more easily realized than the other.®

Let us now have recourse to experiment. If several series
of experiments are made, each series consisting of a rather
small number of tosses (for instance, twenty), the order of
succession of the events a and 6 is quite irregular in each series
and the ratio in which a and 6 are observed is very variable
from one series to another. It seems as if there were no rule
whatever. But if we persevere, repeating the experiment, for
instance, 500, I000, 1500... times, we observe that the
number of events a and the number of events 6 approach more
and more to equality, in proportion as the total number of
experiments (tosses) is increased. If this number is, for in-
stance, 10,000, each of the events a and b occurs about 5000
times.

In general, if the number of tosses is » (a large number), the
event a (head) occurs approximately % times.

We call probability (frequency) of the event a the ratio
between the number of tosses in which a is observed and the
total number of observations (tosses); thus 4:n=4. The
same value is, of course, the approximate expression of the
frequency of 0.

The above expression of frequency is drawn from experience :
the value } means that in a second series of »’ tosses (’ being a
large number) the event a will be observed approximately 2!
times (”’ x the frequency of a).

On the other hand, the probability (frequency) may be

1In reality a third state of equilibrium (event) is possible, in which the coin
would be in a vertical position, resting on the plane by one point of its border.
This event practically never occurs and may Tncieiore be left out of account.

? When the coin has reached its final state of equilibrium (adult state !)
three primordia may be discerned (G =centre of gravity; P=centre of the
side of the coin on which it is resting): (1) the length GP (invariable) ;
(2) the direction of GP (always vertical); (3) the sign of GP (head =a= +and
tail=b=—). Alternative variation exists here in respect of the primordium
sign.

° The two states of equilibrium a and b are equally stable.

_ ‘Contrary to the belief of many gamblers, the order of succession is always
irregular, however great the number of tosses may be, because a given toss
has no influence upon the next one.
118 THE QUANTITATIVE METHOD IN BIOLOGY

calculated a priori in the following way :—in the example under
consideration (one coin) the number of possible cases is two ;
both cases are equally possible!; one case is favourable for
the event a and one for the event b. The probability (frequency)
of a given event is obtained by dividing the number of favourable
cases by the number of possible cases®; thus for a and for 0 the
probability is 4.

The term probability is used here in a definite sense ; it is
a quotient. Since this term has, in the ordinary language, a
rather vague significance, it is a serious cause of misunderstand-
ing. Therefore it is preferable to replace it as often as possible
by the term frequency.

It must be borne in mind, once for all, that the notion of
frequency represents an approximation, and that it has very’
little practical significance, if any significance at all, when the
number of observations is too small.

§ 98.—EXPERIMENTAL VERIFICATION: EXPERI-
MENTS WITH ONE COIN.—I have tossed a coin (a British
penny) 3000 times. In 150 series of 20 successive tosses the
events a and b were observed 3:

In 1 series: a times; b 15 times | In 17 series: a 11 times; 0 9 times

5

I GC ge Rea as yg ES ie. ae BS gE Sa Bh cas
5p HO! gy) Se BF cas Ba EBL Be ES 3 ae ee ee
SOBs iyap Rae eis Oe | Gass Bhg gle A 98 i Bs sed ay Go a0” ae
BR aig Rap IOD. ee SF ape” was Bh By wt ae SF ak os
HBO gp) Br av d® b 39 EO — 55

Taking the event a (head), we see that its observed frequency
is variable within very wide limits—viz. 3, and 444 and that
in 120 out of the 150 series a deviation from the calculated
frequency (which is 3%) exists. Therefore we are in danger of
being seriously deluded if we draw any conclusion from one
series of 20 tosses.

In 30 series of 100 successive tosses the event a (head) was
observed :

In 1 series : 43 times In 1 series : 50 times

£3. cox PAA us v9 Oo ag FSI

side ogi BASE ay ga An oe 252) ay

ee ga BOT op a SP Be SSE cas
By YE ws se gy EST ids

2B om 4S eo a. SOD at

ae 49 5, MoE ag HOO

The calculated frequency is 74%. The observed frequency is
variable between 3/2, and %,;. The concordance between the

 

1 Both states of equilibrium are equally stable.

2 Possible states of equilibrium of equal stability.

3] have used a penny which was worn flat on both sides.
4 The possible limits are .% and 3.
MEASUREMENT OF VARIABLE PROPERTIES 119

series is thus more satisfactory than between the series of 20
tosses. One series of 100 observations (tosses) with one coin
gives, therefore, more or less reliable information.

In 6 series of 500 successive tosses the event a was observed

235, 239, 248, 248, 262, 262

times. The calculated frequency is 25%. Here the concordance
is still more satisfactory than between the series of 100 tosses.
The 3000 tosses being brought together into one series, the
observed frequencies were : heads 1494 times ; tails, 1506 times.
The observed ratio is 0-996: 1.
The calculated ratio is 1500 : 1500 =I: I.
The observed figures are as satisfactory as might be expected
from similar experiments. (Compare §§ 95 and 103.)

§ 94—THIRD EXAMPLE: THE POSITIONS OF EQUI-
LIBRIUM OF A SYSTEM OF TWO COINS. Let us toss
successively two coins I. and II. Under the influence of chance
the first coin I. may give the events a (head) or 6 (tail), which
we call from henceforth simple events. We ascribe to the letters
a and b, which represent the simple events, the numerical
value of their respective frequencies ; thus (according to § 92)
a= and d=} (or 0-50 and 0-50).

In a similar way the second coin II. may give the simple events
a or 6 (frequencies: a@=$=0:50 and b=}=0:50). By the
combination of the simple events two by two (the number of
coins is two), four compound events may be brought about—viz.

a (coin I.) followed by a (coin II.) : compound event aa
b .

a ” ” ” a” > ” ” ab
b »” ” ” a ” : ” ” ba
b ” ” » b » : 29) ” bb

Since four possibilities (states of equilibrium, compound
events) exist, and since they are equally possible (stable), the
frequency of each compound event (calculated a priori) is 1: 4.
(See § 92.) This is expressed by the numerical value of each
of the monomials which represent the compound events—viz.
aa=+; ab=t, etc.

In general, the frequency of any compound event is the product
of the frequencies of the simple events of which tt consists.

We have hitherto taken the order of succession of the simple
events into account. We may, however, neglect this order
and consider only the final result, as 7f both coins were tossed
at the same time. (By adopting this standpoint we do not
alter the facts.) We see then that there is no longer any dif-
ference between ab (head-tail) and ba (tail-head); both are
120 THE QUANTITATIVE METHOD IN BIOLOGY

confounded, and only three different compound events ought to
be distinguished—viz.

aa ab +ba bb
or

a® + 2ab +b?

These three compound events have not the same frequency.
Each of the events a? and 0? is produced in one way ; its fre-
quency is 7. The event ab may be produced in two ways (ab
or ba), each of which has the frequency }. The frequency of
ab is the sum of the frequencies of these two ways—viz. }+}=1.

The trinomial a? +2ab +0 affords us complete information
about the events which may occur when two coins are tossed
once—viz.

(1) Each letter represents a simple event (two simple events
are in play).

(2) The numerical value of each letter represents the fre-
quency of the corresponding simple event (a =} and b =}).

(3) From the number of terms we know how many sorts of
compound events are possible (three).

(4) The numerical value of each term represents the fre-
quency of the corresponding compound event (for instance, the
frequency of ab is zab=3?=4).

(5) The sum of all the coefficients 1 is the number of possible
compound events, the order of succession being taken into
account (I+2+I=4).

(6) The letters of each term represent the constitution
(simple events) of the corresponding compound event.

(7) The coefficient of each term indicates in how many ways
the corresponding compound event may be brought about (for
instance, ab in two ways: ab and 6a).

All the above information may be obtained in the following
way -—

The binomial a+0 or (a+6)} (in which a=b=4) represents
the events which may be observed when one coin is tossed.
When two coins are tossed we obtain a complete representation
of all the events by multiplying the binomials of both coins into
one another—viz.

(a+b) x (a+6) =(a+ 0)? =a? +2ab+ 0?

All the above may be verified approximately by observation,
under the condition that the number of experiments (tosses) is
large enough. Example: If two coins are tossed 3037 times,
the event ab may be expected approximately 1518-5 times
(1518 or 1519 times), and each of the events a* or b? approxim-

ately 759°25 (759) times.

1Or the denominator of the numerical value of any term.
MEASUREMENT OF VARIABLE PROPERTIES 121

REMARK: In the examples hitherto mentioned we have
at our disposal two methods for discovering the effects of the
variable combined cause which is called chance : (1) calculation
a priori, based upon the properties (specific energy) of the
objects under consideration (coins) ; (2) observation of facts
in sufficient number.

§ 95—FOURTH EXAMPLE: THE POSITIONS OF
EQUILIBRIUM OF THREE COINS.—Three coins being
tossed swccessively, the possible compound events are eight in
number—viz. :

aaa aab abb bbb
aba bab
baa bba

The order of succession being neglected (the coins being
tossed simultaneously), the eight compound events are reduced
to four. Taking the binomial of each coin (in which a=b=}),
complete information is obtained in the following way :—

(a+b) x (a+) x (a+b) =(a+ b=
=a5+ 30°) + 3ab7 + 53
From this polynomial we obtain similar information to that
found in the trinomial in the third example (p. 120, (I)-(7)).
Experimental verification: I have tossed three coins (British
pennies) simultaneously 1000 times. Result :

FirsT SERIES : 500 SUCCESSIVE TOSSES

 

 

Compound Observed Calculated
Events Frequency Frequency
a3 65 500 x t= 62°5
a’b 200 500 x 3=187'5
ab? 181 500 x $=187'5
63 54 500 x k= 62°5

 

SECOND SERIES: 500 SUCCESSIVE TOSSES

 

 

Compound Observed Calculated

Events Frequency Frequency
as 47 500 x}= 62°5
ab 175 500 x 3=187°5
ab? 216 500 x $= 187'5

 

bs 62 500 x$= 62°5

 

 
122 THE QUANTITATIVE METHOD IN BIOLOGY
FIRST AND SECOND SERIES: 1000 TOSSES

 

 

Compound Observed Calculated
Events Frequency Frequency
ae I12 1000 x }=125
a*b 375 1000 x 3=375
ab® 397 1000 x be 375
68 116 1000 x $= 125

 

According to the above figures, the simple event
a (head) has beén observed 1483 times
OCA. ay a ¥ 1517 ww
The observed ratio is heads : tails=0'978:1, the calculated
ratio being 1:1. In § 93 (3000 tosses) the observed ratio was
heads : tatls=0'996: 1. (See § 103.)

§ 96 —FIFTH EXAMPLE: POSITIONS OF EQUI-
LIBRIUM OF A SYSTEM OF » COINS.—Whatever may be
the number of coins, complete information about all the possible
events is obtained by means of the expression (a + 0)", in which

(x) aand b represent the simple events (a=head and 6= tail) ;

(2) a=b=} (frequency of the simple events) ;

(3) =number of coins (number of simple events which are

combined into compound events).

Let us suppose that six coins, I., IL, I1., IV., V. and VI., are
tossed. The order of succession being taken into account,
sixty-four compound events are equally possible (stable)—viz.

aaaaaa\ aaaaab \ aaaabb | aaabbb | bbbbaa | bbbbba | bbbbbd
aaaaba | aaabab | aababb | bbbaba | bbbbab
aaabaa | aaabba | aabbab | bbbaab | bbbabb
aabaaa | aabaab | aabbba | bbabba | bbabbb
abaaaa | aababa | abaabb \ bbabab | babbbb
baaaaa | aabbaa | ababab | bbaabb | abbbbb
abaaab | ababba | babbba
abaaba | abbaab | babbab
ababaa | abbaba | bababb
abbaaa | abbbaa | baabbb
baaaab | baaabb | abbbba
baaaba | baabab | abbbab
baabaa | baabba | abbabb
babaaa | babaab | ababbb
bbaaaa | bababa | aabbbb
babbaa
bbaaab
bbaaba
bbabaa
bbbaaa

 

 

 

 

 

 
MEASUREMENT OF VARIABLE PROPERTIES = 123

The order of succession being neglected, the sixty-four events
are reduced to seven, which are represented by the terms
obtained by expanding (a+ b)°, in which a=b =4—viz.

(a+ b)® =a® + 645d + 15a4b? + 2003 + 15a2b4 + 6ab* + b°

About the information given by these terms, see p. 120,
(r)-(7), and compare with the above table.

eee J.: Which is the frequency of the event a‘b? (four heads and
two tails) ?

Answer: 15:64 (= 0°234).

QUESTION II.: In a series of x tosses the event ab’ has been observed
300 times. How many times did the event ab‘ occur ?

Answer : Approximately 750. times.

QUESTION III. : Which is in Question II. the value of # ?

Answer: Ap oximately 3200 tosses.

QUESTION TV. : The number of tosses being 200, how many times will the
event a® be observed ?

Answer: Approximately three times (this answer has hardly any practical
value, because the number of tosses is too small).

QUESTION V.: The number of tosses being 6000, in how many tosses will
the number of events a (heads) be an even number ?

Answer : Approximately 2906 times.

§ 97—REMARKS ABOUT THE PRECEDING EX-
AMPLES.—Chance is a vague something which is continually
varying. At first sight the effects of chance seem to be
capricious, as if they were independent of any rule whatever.

In the example of the spherical ball (§ 91), however, all the
possible effects of chance are reduced to one simple event, the
occurrence of which is certain.

Tossing one coin (§92), we have reduced all the possible effects
of chance to two simple events aand b. The frequency of each
of them is 4. The sum of their frequencies (probabilities) is I.
The figure 1 1s the expression of certitude. If we consider one
toss, we may foretell with certitude that a or } will be observed,
but we do not know at all which of both will happen: the notion
of frequency (probability) is in this case a pure fiction. But
in proportion as the tosses become more numerous the exist-
ence of a rule becomes more apparent. We learn from EX-
PERIENCE that the frequencies of a and b approach more and
more to equality, which is represented by their frequencies
(4 and 4) calculated a priort.

The events a and 0 afford us a fixed starting-point for further
investigation. We look upon them as being simple causes (or
forces) the combinations of which produce combined causes
(resultants). We have succeeded in discovering certain rules
by which the combined causes and their effects are governed—
whatever may be the number » of simple causes (simple events)
which are combined.

The rules discovered are rules (or laws) of chance. The
124 THE QUANTITATIVE METHOD IN BIOLOGY

cause which we call chance is indeed a combined cause which
consists of an unlimited (unknown) number of simple causes.

§ 98—SIXTH EXAMPLE: AN URN CONTAINING 100
WHITE AND 100 BLACK BALLS.—When one ball is ex-
tracted at random from the urn, two simple events are possible :
white=a or black=b. Since the number of cases (possibilities)
favourable for a is 100 and the total number of possible cases
200, the frequency of a is 100:200=}. The frequency of b
has, of course, the same value. The conditions are thus
exactly the same as in the example of one coin (§ 92). If the
balls are extracted by series of 2,3 .. . m, taking them one by
one and putting each ball back into the urn after the colour has
been ascertained,! the same compound events (combinations)
will occur as when 2,3... ” coins are tossed.

If the balls are extracted (one by one), for instance, in series
of eight, all the possible combinations and the frequency of
each of them may be calculated a priori by expanding (a+ 6)*,
in which a=b=}—viz.

(a+ b)§=a® + 8a7b + 28050? + 565d? + 70a*h* + 56050 + 284708 +
8ab? + 68 =1 (certitude).*

QUESTION I.: What is the frequency of the compound event 6 white
(a) and 2 black (0) balls ?

Answer: Approximately 28 : 256 (=0'109).

QUESTION II.: Which is the frequency of aababbab ?

Answer: Approximately 1 : 256 =0'004.

§ 99—SEVENTH EXAMPLE: AN URN CONTAINING
200 WHITE AND 100 BLACK BALLS.—When one ball is
extracted the frequency of a (white) is 33% (number of favour-
able cases divided by number of possible cases) or 3, and the
frequency of b (black) is 4. All possible information 1s obtained
by expanding (a+6)", in which 7 is the number of extracted
balls (taken one by one; see the note, p. 124), a=% and b=}.

(See (I)-(7), p. 120.)

QUESTION I.: Six balls being extracted, which is the frequency of the
compound event two white and four black balls? (See (a+6)®, p. 123.)

Answer: Approximately 60 : 729 (=0'082). .

QUESTION II. : 15,000 series of eight balls being extracted, how many
times has the combination seven white and one black ball been obtained ? (See
(a+b), p. 124.)

Answer : 15,000 X 8a%b =15,000 X 338 = approximately 2341 times.

 

1lf the ball were not put back into the urn after each extraction, the fre-
quency of the simple oS a be continually modified and the calculations.
me more complicated. :
ae canna that the first extracted ball isa. When a second ball is
taken, the frequency of the event a is no longer 38, but .28,, and the fre-
quency of the event b is 199, etc.
2 Sum of the coefficients = 2°=256.
MEASUREMENT OF VARIABLE PROPERTIES 125

§ 100—EIGHTH EXAMPLE: AN URN CONTAINING
100 WHITE, roo BLACK AND 100 RED BALLS.—When one
ball is extracted three simple events are equally possible :
a (white), b (black) and c (red). The frequency of each of them
is 188=4. This is represented by the trinomial a+b+c, or
444441 (certitude).

When two balls are extracted successively the possible events
with regard to the second ball are similarly represented by
a+b+c. Since the simple events are combined two by two,
nine compound events are (equally) possible—viz.

aa bb cc ab ac bc
ba ca cb

The frequency of each compound event is 4x 4=}.

The order of succession being neglected, the nine events are
reduced to six. The expression of these six compound events
is obtained by multiplying into one another the trinomials
representing the simple events which are combined (see § 94,
p. 120)—viz.

(a+ b+c)x(at+b+c)=(a+b+c)?=
a+0? +c? +4+2ab+ 2ac+2be=3=1

The frequency of each compound event is expressed by the
numerical value of its term.

Complete information about all the possible compound events
when series of 3, 4... balls are extracted is obtained by
expanding (a + 6+)”, in which x is the number of simple events
(extracted balls of one series) and a=b=c=%. (Continued in

§ 115.)

§101—NINTH EXAMPLE: ONE DIE, TWO DICE.—In
the preceding examples the effects of chance are limited to a
definite number of simple events. In each event a certain
simple property (head, tail; colour) of the objects is rendered
visible. The simple events and properties are combined (co-
exist) in various ways, according to the rules of chance.

Between the above-mentioned simple properties (primordia,
see § 92, p. I17, note 2) no quantitative relations exist.
Each primordium is distinctly different from the others; it
is present or absent, visible or latent (concealed), without
more.

It may happen, however, that the properties under con-
sideration are measurable, each simple event coinciding with
a certain value. In this case the rules of chance are un-
altered, but chance has certain effects which we have not yet
alluded to.

One ordinary die being cast, six states of equilibrium or
simple events are equally possible: in each event one of the
126 THE QUANTITATIVE METHOD IN BIOLOGY

faces of the die becomes visible. The frequency of each event
(face) is 3. If we represent the faces by six letters, a, b,c, d, e, f,
and ascribe to each letter the value of its frequency, which is 3
for each, the possibilities are expressed by the polynomial

a+b+c+d+e+f=%=1 (certitude)!

Two dice being cast successively, the simple events are com-
bined two by two, and thirty-six compound events are equall
possible, according to the expression (a+b+c+d+e+f)®. (See
§ 100.) These thirty-six events are represented by aa, ab...
ba, bb. . . etc. The frequency is 3, for each.

If the order of succession is neglected, the thirty-six events
are reduced to twenty-one (see § 100)—viz.

(a+b+c+dtetf=

TABLE a

a’ + 2ab+ 2ac + 2ad + 2ae + 2af + 2bf + 2cf + 2df + 2ef +f?
+ 6+26c4+ 2bd +2be + 2ce + 2ed + €?
+ C4+2cd+ @

It is possible to go further. Since each letter represents one
of the faces of a die, we may ascribe to each letter two distinct
values: (1) the value of the frequency of the corresponding
simple event, which is 4 for each letter; (2) the value of the
corresponding face of the die (@=1, b=2,c=3,d=4, e=5, f=6).
This jacial value is quite independent of the frequency.

In Table « each monomial is the expression of a compound
event. The arithmetical sum of the letters of each monomial is
the facial value of the corresponding compound event; for
instance :

@=a+a=1+I=2
ab=1+2=3
ac=1+3=4
6? =b64+6=24+2=4

Pi af+f =6+6=12

When only the facial values are taken into account, the twenty-
one events in Table « are reduced to eleven, characterized by
the values

2, 3, 4, 5, 6, 7, 8, 9, 10, II, 12

(In Table «a the monomials are arranged in such a way that
they have the same facial value in each vertical column.)

1 This polynomial is also the expression of the six possible events when one
ball is taken from an urn containing six sorts of balls in equal number, (See
§ roo.)
MEASUREMENT OF VARIABLE PROPERTIES 127

TABLE 6
A Tek | 2.2) £23 | Bod | ores) 2.6 C
2.0) Qe | 2.3 | 2.4 | 2.5 | 2.6
3.1 | 3.2 |] 3.3 | 3.4 | 3.5 | 3.6
Ae | 2.8 | dae 1 goa | Qe | a. 8
5-2 | Se | O25 | Be4 | Bes: | Sx8
© | G.F | 6.2) 6.5 | Gia | 6.5 1 6.6) DB

In Table 8 the thirty-six compound events are represented
by their facial values ; in each pair of figures the first figure
represents the first die. In each of the eleven oblique rows
parallel to the diagonal BC the compound events have the same
facial value.

The frequency of the eleven facial values is expressed by the
sum of the arithmetical values of the monomials which belong
to the same vertical column in Table «. For instance, the fre-
quency of 4 (4 dots with 2 dice) is 2ac+ b?=3.4+,=3,.1

In Table y the eleven facial values are given with their
respective frequencies :

 

TABLE y
Fac. value 2 3 4 5 6 7 8 g 10 Ir 12
Frequency 35 gs vs vs ss os oe vs os oe oy

The frequency increases regularly from 2 to 7 and decreases
further till 12. (Compare Table £8.) This regular result
(which may be verified by experiment ; see § 103) is brought
about by chance! The variation of the facial values is zn-
cluded between two limits: 2 and 12.

If 1 dice are cast the frequency and the facial value of all the
possible events may be obtained by expanding (a+ b+c+d+
e+ 7)”.

the same method is applicable, of course, whatever may be
the number of faces of the dice (tetrahedral, octahedral,
dodecahedral, icosahedral dice, etc.) and the number of dice in
each cast. A coin may be looked upon as being a die with two
faces. In the experiments with coins (§ 94; see also § 98) all
the possibilities are Jatent in the expression (a+ 6)": this is a
peculiar case of the general method expounded in the present

paragraph.

§ 102.—TENTH EXAMPLE: ONE CAST WITH TWO
DICE: DIVERSITY OF THE EFFECTS.—In the preceding
example we consider a first series of six events (first die) which
coincide with the facial values 1 to 6, and a second similar series

1In other words, the facial value 4 is obtained in three different ways, each
of which has a frequency j. (See Table 8.)
128 THE QUANTITATIVE METHOD IN BIOLOGY

of six events (second die). In each of the thirty-six possible
combinations one event of the first series coexists with one event
of the second series. The two figures (facial values) of each
combination may be looked upon as being-two causes or forces,
which may work together in order to produce a certain effect.
This is easily realized if we suppose that each cast with two dice
indicates, by the swm of both figures (facial value of the com-
pound event), for instance, a number of kilograms which
ought to be raised, of kilometres which ought to be travelled
over, of shillings which ought to be paid, etc.

In the simplest case the effect (resultant) of the two co-
existing causes is expressed by the sum of their facial values
and may be calculated by means of a simple addition: in this
way the thirty-six possible compound events are reduced to
eleven (§ ror), the frequencies of which are given in Table y
(p. 127). Two coexisting causes (forces), however, may be
associated into one resultant in an unlimited number of ways ;
the effect may depend not only on their sum, but, for instance,
on their difference, their product, their quotient; on the
diagonal of a rectangle the length and the breadth of which
are indicated by the two coexisting figures; on the volume of a
cone determined by these figures, etc.

Whatever may be the way in which two simple causes (the
coexistence of which depends on chance) work together, all the
possible effects and the frequency of each of them may be
calculated a priort.

Starting from one cast with two dice (Table 8, p. 127), I
take the following four examples :—

EXAMPLE (A): By means of the thirty-six pairs of figures
in Table 6 we may construct thirty-six rectangles, the surface
of each being the product of the figures of the corresponding
pair. With reference to the resulting products, the thirty-six
possibilities are reduced to eighteen, because a number of those
products are realized in more than one way—viz.

Surface 1 realized in I way Surface 15 realized in 2 ways
, 2 a 2 ways ~ 26 si lap
x 3 ” 2 a” »”? 17 a 0 ”)
”? 4 ” 3 ae a? 18 a” 2 a2
a”? 5 sw 2 »” ae 19 oF 0 a”
a” 6 »” 4 ”) se 20 a 2 ”
” 7 wD. oO a? oP 21-23 ” 0 ”
EF 8 IF 2 ” 2? 24 a? 2 ”?
»” 9 ” I ” ” 25 ” I 2 3
a. oe ss a cits 1, 29-29 si Oe ay
35 II 7 Os ” 39 ” 2
” IZ ” 4 ” ” 31-35 ” Os»
oe a o 0 » » 30 Ps Ei
” 14 ” 0 ”

 
MEASUREMENT OF VARIABLE PROPERTIES 129

Between the limits 1 and 36 several irregular gaps exist ;
the distribution of the frequencies is also very irregular. It
seems as if the above figures were accidental, independent of
any rule whatever. They are, however, governed by definite
rules, which are rules of chance. I have verified the above
calculated figures by experiment. (See § 103.)

EXAMPLE (B): Let us suppose that the figures of each pair
in Table 8 (p. 127) express the length and the breadth of thirty-
six leaves of a certain species, and let us calculate the ratio
breadth: length of each of them (in each pair of figures in Table 8
the a figure expresses the breadth). The following result is
obtained :—

TABLE 6 (COMPARE TABLE f, p. 127)
A 1°00 0°50 0°33 0°25 0°20 0°17 C
2°00 r'00 0°67 0°50 0°40 0°33
3°00 I'50 I'00 0°75 0°60 0°50
4°00 2°00 1°33 I'00 0°80 0°67
5°00 2°50 1°67 I'25 100 0°83
B 6°00 3°00 2°00 1°50 I'20 r'00 D
If the thirty-six figures in Table 5 had been obtained from
the measurement of thirty-six leaves, we might be tempted to
bring them into the form of a variation curve (see p. 29 and
§ 108)—viz.

Ratio breadth : length : 0 - 0 - g9=15 leaves
” » ” II: 99 =12 ”
” ” ” 2-2 ‘9Qg=4 ”»
” a” 2” 3-3°99=2 ”
” ”» ” 4-4: 99=1 ”
” ” a 5-5°99=1 v4
O= 6 4 «= 7

” oe a”?

A certain regularity is observed in this curve: it recalls
certain unilateral curves which have been actually obtained
and described. (See experimental verification in § 103.)

Remark about the preceding examples (dice): Starting from the thirty-six pairs
of figures in Table f (p. 127), and taking successively the sum (Table y, p. 127)
the product (p. 128) and the quotient (Table 6, p. 129) of the figures of each
pair, we have obtained three different results : in two cases (sum and quotient)
the distribution of the frequencies is regular or fairly regular; in one case
(product) it seems to be capricious. In the three cases, the cause of the
observed facts is chance oni tae cause). In each cast chance brings about
certain reactions which are going on till a certain state of equilibrium exists
and the corresponding values of the dice (dots) become visible. The two
values (one of each die) which become visible at the same time are the ex-
pression of forces which may work together in various ways. In other words,
orces which depend on the specific energy of the dice are brought as it were
into action by chance. The system of two dice is a sort of machinery, through
which chance is acting. In the three given examples the effects depend on
the machinery, the cause CHANCE being exactly the same in each.

I
130 THE QUANTITATIVE METHOD IN BIOLOGY

EXAMPLE (C): I suppose two dice the six faces of which are
coloured with six pure spectral colours—viz.

fed Sr St orange=0=2 yellow=y=3
green =g=4 blue =b=5 violet =v=6
The dice being cast, the thirty-six possible events (combina-

tions of colours) may be found by means of the expression
(y+o+y+g+b+v)* (compare Table 8, p. 127)—viz. :

TABLE ¢
A Y-7 7.0 r.y r.g rb rev Cc
oO.” 0.0 0.¥ 0.g 0.b O.v
yer y.O yey y.2 ue y.v
g.7 g.o g.¥y gg g. g.v
b.7 b.0 b.y b.¢g 6.6 b.v
B v.47 v.0 vey v.g v.b v.v D

When both terms of each pair are added (in one or another
way) the following colours are perceived :—

(r) The pairs in which both terms are alike give a pure
spectral colour (see the diagonal row AD) ; this occurs six times.

(2) The pairs which consist of two complementary colours
(red+ green, yellow+ blue, orange+ violet) give white; this
occurs six times (rg, ov, yb, gr, v0, by).

(3) The pairs which consist of different (not complementary)
colours give a mixed colour ; this occurs twenty-four times.

The respective frequencies are thus :

mixed : white : pure=24:6:6=4:1:1

(See experimental verification in § 103.)

EXAMPLE (D): I suppose that the figures on the faces of the
first die represent a corresponding number of cubic centimetres
of an acid liquid and that the figures of the second die represent
in the same way an alkaline liquid, both liquids being prepared
in such a way that I cubic centimetre of the first neutralizes
exactly I cubic centimetre of the second. The two dice being
cast, the thirty-six possible events are given in Table f (p. 127).
If thirty-six mixtures are made in the proportions (volumes)
indicated by the figures of each pair, it is seen that : :

(t) The pairs in which the first figure is predominant give an
acid mixture ; this occurs fifteen times.

(2) The pairs in which the second figure is predominant give
an alkaline mixture ; this happens also fifteen times.

(3) The pairs in which both figures are equal give a neutral
mixture; this occurs six times.

The respective frequencies are thus:

acid: alkaline: neutral=15:15:6=5:5:2
(See experimental verification in § 103.)
MEASUREMENT OF VARIABLE PROPERTIES 131

§ 108—ONE CAST WITH TWO DICE. EXPERI-
MENTAL VERIFICATION OF THE EXAMPLES IN §§ ror-
102. I have cast two dice 3600 times. Result :

TABLE ¢ (COMPARE TABLE 8, p. 127): 3600 CASTS WITH
2 DICE: OBSERVED FREQUENCIES

 

Die II: 1| Die II: 2] Die II: 3] Die II: 4] Die II: 5|DieII:6] Total

 

97 | I00 | 120 | IIg | 102 99 | 637
103 | 99 go | 98 98 96 | 584
a 114 go 84 116 oI 97 592

Die I: 1

2

: 3
snk 96 99 96 oI 102 102 586

= 3

6

a”

84 87 100 102 108 105 586
107 99 104 84 103 r18 615

a”

”

 

Total 601 574 | 504 | 610 | 604 617

 

 

 

 

 

 

 

 

According to calculation, the figure 100 was expected in each
of the thirty-six divisions. In twenty cases the difference
between the observed and the calculated value does not exceed
004 of the latter. Although the number of casts is rather
small (no less than thirty-six compound events are compared)
the concordance is not unsatisfactory.

In the horizontal rows and in the vertical columns the
deviations from the calculated figure (600) are small; in the
most unfavourable case it reaches hardly 0'062 of the latter.

Looking upon the 3600 casts as being 7200 casts with one die,
taking the figures of each die separately and calculating how
many times even and uneven figures were obtained (equality is
expected), we find :

DieI Die II
even (2, 4, 6 dots): 1785 1801
uneven (I, 3, 5 dots): 1815 1799

Both dice together (expected 3600 : 3600) :
even: 3586 uneven: 3614

Deviation from the expected figures: 0°004. The observed
ratio is even : uneven=0'992 ‘I.

Compare this very satisfactory result with the irregularity
of the series of I00.

Compare the series of 100, 500 and 3000 in § 93 (p. 118) and
the series of 3000 in § 95 (p. 122).

When we take in each of the thirty-six compound events in
Table 6 the sum of the facial values of both dice, the thirty-six
132. THE QUANTITATIVE METHOD IN BIOLOGY

events are reduced to eleven, the calculated relative frequencies
of which are (according to Table y, p. 127) :

Facial values . » 2 8 4 5 6 7 8
Relative frequencies I 2 3 4 5 6 5
Facial values . - 9 10 11 #22

Relative frequencies 4 3 2 #4

From the figures in Table ¢ (p. 131) we may easily deduce
the observed relative frequencies in our series of 3600 casts—viz.

TABLE 7: 3600 CasTS WITH 2 DICE

Facial values ‘ : 2 3 4 5 6
Calculated frequencies . I00 200 300 400 4500
Observed ¥8 . 97 203 «333. 395 467
Facial values ; 7 8 9 10 11 12
Calculated frequencies 600 500 400 300 200 100
Observed % 603 477° 405 294 208 118

In Example (A) (§ 102, p. 128) the frequencies of the eighteen
values of the rectangles constructed by means of the thirty-six

TABLE 9 (SURFACE OF RECTANGLES)

 

 

 

 

 

Frequencies Frequencies
Surfaces |Calculated| Observed] Surfaces |Calculated| Observed
I 100 97 Ig — —
2, 200 203 20 200 185
3 200 234 2 _—
4 300 314 22 — _—
5 200 186 23 — —
6 400 386 24 200 | -186
7 — — 25 100 108
8 200 197 26 — _—
9 r00 84 27 — =
10 200 185 28 — —
II — — 29 — —
12 400 407 30 200 208
13 — — 31 _— _—
14 — — 32 —_ _—
15 200 Ig 33 — _—
16 100 gl 34 — —_
17 7 iam 35 med me
18 200 201 36 100 118

 

 

 

 

 

 
MEASUREMENT OF VARIABLE PROPERTIES 133

pairs of facial values have been calculated a priori. From
Table ¢ (p. 131) the observed frequencies may be deduced.

., In Table 9 (p. 132) both series of relative frequencies are
compared :

Although the above concordance is hardly satisfactory
(because the casts are not numerous enough), it is sufficient to
prove that the calculated figures, however capricious they seem
to be, are the expression of really existing rules of chance.

In Example (B) (§ 102, p. 129) the first figure of each pair has
been divided by the second. The thirty-six quotients have
been brought into seven groups and the frequency of each group
has been calculated. The calculated and the observed fre-
quencies (deduced from Table ¢) are compared in Table «:

TABLE + (QUOTIENTS)

 

 

 

 

Frequencies
Quotients Calculated Observed
0-0 99 1500 1535
I-I 99 1200 1172
2-2 99 400 393
3-3 99 200 213
4-4 99 100 96
5-5 99 100 84
6 100 107

 

 

With regard to the colours mentioned in Example (C) (§ 102,
p. 130) a comparison between the calculated and the observed
values (deduced from Table ¢) is given in Table «:

TABLE «x (COLOURS)

 

 

 

Frequencies
Calculated Observed
Mixed colour. 2400 2402
Pure colour. 600 507
White... ‘ 600 601

 

 

Here the concordance is as satisfactory as possible.
In Example (D) (§ 102, p. 130) the frequencies of the three
134 THE QUANTITATIVE METHOD IN BIOLOGY

reactions, acid, alkaline, neutral, have been calculated a priori.
In Table A they are compared with the observed frequencies
(deduced from Table ¢) :

TABLE » (REACTIONS)

 

 

 

Frequencies
Calculated Observed
Acid. 3 1500 1468
Alkaline. 1500 1535
Neutral ‘ 600 597

 

 

§ 104—ELEVENTH EXAMPLE: APPLICATION OF
THE PRINCIPLES OF PROBABILITY (FREQUENCY)
TO THE HEREDITARY TRANSMISSION OF PRIMORDIA
IN MENDELIAN HYBRIDS.—In § 33 (p. 32) I have given a
short account of MENDEL’S experiments and principles. Let
us now consider this subject from the standpoint of the rules
of chance.

In one of his classic experiments with the edible pea
MENDEL crossed a variety (subspecies) 6 with round seeds
(primordium D) with a variety p with wrinkled seeds (pri-
mordium R). In this cross each egg or seed (hybrid of the F,
generation) is made by the union of a germ cell D taken from
the parent 5 and containing a certain cause or factor corre-
sponding to the primordium D, and a germ cell R taken from p
and containing a factor corresponding to the property R. Both
germ cells are, of course, taken at random; their union is a
compound event. One possibility exists (compare § 91): the
production of an egg or seed DR in which the causes D and R
meet each other.!_ The coexistence of both factors brings about
a reaction by which the dominant primordium (state of equi-
librium) D becomes visible, whereas R is concealed or latent
(compare Example (D), p. 130) : all the seeds are round.

From the seeds DR (F, generation) plants F , are raised which
give birth to g and ¢ germ cells. According to the principle
of segregation, the germ cells are of two sorts, D and R, both
sorts being in equal number among the # just as among the ¢.
The plants are fertilized with their own pollen, the ¢ and the ¢
germ cells being united according to the rules of chance. If we
suppose that, for instance, the ¢ germ cells are 500 D+ 500 R

1It is supposed that the ¢ and the ? germ cells are equivalent with regard
to the hereditary transmission of the primordia.
MEASUREMENT OF VARIABLE PROPERTIES 135

and the ? germ cells also 500 D+500 Rin number,! the 500 D

$ being united at random with 500 2,250 D $ meet 250 D @
and 250D f$ meet 250 R §, and ina similar way 250 R f meet
250 D 2 and 250 R f meet 250 R Q. Four sorts of com-
pound events are equally possible, and therefore four sorts of
seeds (F, generation) are produced in equal numbers—viz.

250 D f x 250 D 2 = 250 seeds DD
(250 D $x 250R 2=250 ,, DR
(250 R f x 250 D 2 = 250 _ ,, RDY

250R gx 250R Q=250 ,, RR

All the events under consideration are the same as if a very
large number of white balls D and an equal number of black
balls R were brought into an urn and taken one by one in 1000
series of two, the first ball of each series being 3 and the second
ball?. All the possible events are expressed by the trinomial
obtained by working out (D+ R)*, in which D= R=} (see § 98)
—viz.

(D+ R)?=D?+2DR+ R?

This trinomial gives us complete information about the
hereditary possibilities and visible properties of the 1000 seeds
of the F, generation and about the frequency of each sort of
seeds (compare § 94, (1)-(7), p. 120) :

(1) Each letter represents a simple event; in other words, a
germ cell (f or $) containing a factor D or R.

(2) The numerical value of each letter is the expression of the
frequency of the corresponding simple event ; in other words,
of the relative number of existing germ cells of each sort
(D=R=0'50 of the total number).

(3) From the number of terms we know how many sorts of
compound events are possible (the order of succession of the
simple events being neglected) *; in other words, how many
sorts of seeds are produced. Three sorts exist, but as often as
a germ cell D meets a germ cell R the coexisting simple events
(factors) produce a resultant by which the primordium D becomes
visible and R latent. Therefore it is impossible to distinguish
D? from DR (or RD) and (with regard to the visible properties)
only two sorts of seeds (round or wrinkled) exist. (Compare
examples (C) and (D) in § 102, p. 130.)

(4) The numerical value of each term represents the fre-
quency of the corresponding compound event; in other
words, the relative number of seeds of the corresponding sort.

1 The figure 500 is taken arbitrarily instead of x.
2 This means the sexual difference being overlooked : the first simple event
of each pair (first ball or germ cell) is supposed to be ¢, the second ?.
186 THE QUANTITATIVE METHOD IN BIOLOGY

With reference to the visible properties, two sorts of seeds exist
(see (3)): round seeds represented by D?+2DR (=3+2=3),
and wrinkled seeds represented by R? (=3). The ratio is
round : wrinkled = 3:1.

In MENDEL’S experiment 7324 seeds were obtained ;
among them 5474 were round or roundish and 1850 angular
wrinkled. Therefrom the (observed) ratio 2-96 to x is de-
duced.1

With reference to the hereditary possibilities, two sorts of
round seeds exist: a first sort represented by the term D?
(numeric value 4), which is able to produce round seeds only,
and a second sort represented by the term 2DR (value 4),
which contains the factors D and R and may therefore produce
round and wrinkled seeds. Therefrom (among the plants raised
from round seeds) the ratio plants ytelding x sort of seeds: plants
yielding 2 sorts of seeds=1:2=1: 2.

In MENDEL’S experiment, among 565 plants which were
raised from round seeds 193 yielded round seeds only; 372,
however, gave both round and wrinkled seeds. Therefrom the
(observed) ratio x : 1-93 is deduced.”

(5) The sum of the three coefficients (I+ 2+1=4) expresses
the number of sorts of possible compound events (sorts of
seeds), the order of succession of the simple events (dis-
tinction between g$ and ? germ cells) being taken into
account.

(6) The letters of each term indicate the constitution of the
corresponding compound event ; in other words, the hereditary
causes or factors contained in the corresponding sort of seeds.
See (4).
if) tbe coefficient of each term indicates inhow many ways
the corresponding compound event may be brought about ;
in other words, in how many ways the corresponding seeds may
be produced. The seeds D? (coefficient 1) and R? (coefficient 1)
are produced each in one way (D $x D2; RZxR ®).
The seeds 2DR are produced in two ways (D fx R 2 or
D@xR-s).

Each coefficient indicates, moreover, how many sorts of
seeds (F,; generation) may be yielded by the corresponding
plants. (See (4).) The plants raised from the seeds D? will
produce one sort of germ cells (D) and therefore one sort
of seeds (just as the parent 6). For the same reason the
plants raised from the seeds Kk? will yield one sort of seeds
(as the parent p). The plants raised from the seeds 2DR will
produce two sorts of germ cells and (with regard to the visible
properties) two sorts of seeds, as the plants (DR) of the F,
generation—viz.

1See MENDEL, in BATESON, Joc. cit., p. 326. 2 Ibid., p. 329.
MEASUREMENT OF VARIABLE PROPERTIES 137

Parents. . . . . .. . dxp
|
Hybrids F, . . . .. . DR
|
—————
Hybrids F, . . D?+ ...2DR+... R
. ae
Hybrids F; . . D?...D®+2DR+R?...R?

§ 105 ELEVENTH EXAMPLE (continued).—In a second
experiment MENDEL crossed a variety or subspecies (pea) a
with round seeds (D) and yellow albumen (d) with a variety }
with wrinkled seeds (R) and green albumen (7). Here each egg
(or seed) of the F, generation is made by the union of a germ cell
(taken from a) containing two factors D and d and a germ cell
taken from 6 and containing the factors R and 7. One
possibility exists: the production of a seed DdRr (D and d
dominant ; R and 7 recessive).

From the F, seeds Ddky plants are raised which give birth to
four sorts of germ cells. With regard to the pair of primordia
D, R, the germ cells are segregated into two groups D and R,
which are in equal numbers among the f and among the ? —
let us suppose 250 D $,250D 2, 250R $,250R 2. With
regard to the pair d and 7, a similar segregation occurs, 7nde-
pendently of the first one, in such a way that each of the four
above groups is segregated into two equally numerous groups.
Eight groups of germ cells are obtained—viz.

125 Dd §,125 Dr $,125 Rd f, 125 Rr $
125 Dd 2,125 Dr 2,125 Rd 2,125 Rr &

The germ cells of any given ¢ group being distributed at
random among the four groups of ? germ cells, since the latter
groups are equally numerous, the frequency of each of the four
possible sorts of compound events is}. The $ groups being
four in number and equally numerous, the frequency of each
sort of g¢ germ cells is }. Each of these 4 groups giving 4
compound events, the total number of possible compound events
(seeds) is 16, the frequency of each being } x }= 75 —viz.

 

Dd é Dr & Rd & Rr $

 

Dd § Dd. Dd Dr .Dd Rd. Dd Rr .Dd
Dr §& Dd. Dr Dr .Dr Rd. Dr Rr . Dr
Rd ¢ Dd.Rd Dr .Rd Rd.Rd Rr .Rd
Rr $ Dd .Ryr Dr . Rr Rd. Rr Rr . Rr

 

 

 

 

 

 
1388 THE QUANTITATIVE METHOD IN BIOLOGY

Complete expression of the events under consideration (seeds)
may be obtained in the following way :—

Each pair of primordia (factors) is taken separately. Wi
regard to the first pair, the four a aoe events 1s obtained! =
expanding (D+R)*. (See § 104.) With regard to the second
pair, the four possible events are obtained by expanding (d+ n)?.
Since the four compound events of both groups are combined
two by two, the sixteen possible combinations are obtained by
multiplying (D+ R)* with (d+7)? (see §§ 94, 95)—viz.

(D+ R)? x (d+7)2=
D?d? + 2DRd? + 4DdRr +
D7? + 2D%dy +
@R* +2DRP +
Ry? + 2drR?

In this way, the difference between f and being neglected,
the 16 sorts of seeds are reduced to g sorts. (Compare

§ 95-)

Remark : The 16 possible events (sorts of seeds) are comparable to the 16
events which may take place when two dice with four faces, for instance, two
regulary tetrahedra (triangular pyramids) I. and II., are cast successively, I. being
é and II. being ¢, the faces of I. being marked Dd, Dr, Rd, Rr, the faces of II.
bearing the same marks. According to § 101, the possible events are cal-
culated a priori by expanding (Dd+Dv+4Rd+Ry)?.1 If both tetrahedra are
cast simultaneously, the distinction between I. and II. (sex) disappears and the
possible events are 9 in number. The result is the same as with the first
method.”

From a biological standpoint the example of the tetrahedra contains perhaps
(? 2?) something more than a method of calculation. In that example I suppose
that only two sorts of germ cells exist, one ¢ sort and one ? sort, each sort
containing all the primordia of both parents and being thus completely
hybrid. According to the classic hypothesis, eight sorts of germ cells (four 3
sorts and four @ sorts) exist. On the other hand, we know (see § 38) that
a combination of properties may be segregated into primordia in several ways
without dissociation among the germ cells. In the above example of the
tetrahedra we may find perhaps a starting-point for a new explanation of the
Mendelian facts...?  -

One feels that there is in the Mendelian hypothesis of segregation, however
ingenious and useful it may be, something artificial which is rather incon-
sistent with the ways of nature.

From the nine terms of the above polynomial (p. 138) we
obtain the same information as from the trinomial in the first
experiment. It is useless to repeat here the explanations given
on p. 120, (1)-(7). I limit myself to the following examples :—

(Compare (3), p. 120.) From the number of terms we know
how many sorts of seeds are found in the F, generation: nine

1 Remarvk : The faces Dd, Dr, Rd, Rv represent compound events, the simple
events D, R, d, y corresponding to causes or factors (§ 97). The compound
events are combined in their turn two by two when the tetrahedra are cast.

2 This may be easily demonstrated in the following way :—

(D+R} x (d+rP=[(D+R) (4+”fP
[(D+R) (d+r)P=(Dd+Dr+Rd+ kr)?
MEASUREMENT OF VARIABLE PROPERTIES 139

sorts exist, but as often as a germ cell D meets an R, the
property FR is latent; and in a similar way 7 is latent when d
meets y. Therefore the 9 sorts are reduced to 4—Vviz.

The seeds D?d? are Dd (round, ek,

ee 2DRG* » Dd 45 ”

“s 2D*dr_ ,, Dad( ,, al

9 4DdRr ” Dd ( ” ” )

a R’d? ,, Rd (wrinkled, yellow)
3 2drR? ,, Rd(_,, in
i D*y?_,, Dr (round, green)

” 2DRr? »” Dr ( ” ”

hss Ry? ,, Rr (wrinkled, green)

(Compare (4), p. 120.) The numerical value of each term is
the frequency of the corresponding sort of seeds—viz.

Round, yellow (Dd): 1+242+4=

Wrinkled, yellow (Rd): 445

bole Sh cle

to

4 16
Round, green (Dr): is
Wrinkled, green (Rv): ys = rs

or 9:3: 3:1 (relative frequencies).
In MENDEL’S experiment (556 seeds yielded by 15 F,
plants) the figures were !:

 

Observed | Calculated ?
Ry (wrinkled, green) 32 seeds 556x j;= 35 seeds
Dr (round, green) 108 _s,, 550x7%;=104 ,,
Rd (wrinkled, yellow) IoI ,, 5560 x 35=104 __,,
Dd (round, yellow) 315 556 x Ys =313

Considering the four above groups with reference to their
hereditary possibilities, we discern :—

Among the plants raised from round, yellow seeds :

(2) Plants raised from seeds D?d*, which are expected to
yield 1 sort of seeds (round, yellow); this is expressed by the
coefficient of the term, which is I.

(6) Plants raised from 2DRd?; coefficient 2; 2 sorts of
seeds (round, yellow; wrinkled, yellow).

(y) Plants raised from 2D%dr; coefficient 2; 2 sorts of
seeds (round, yellow ; round, green).

(8) Plants raised from 4DRadr ; coefficient 4; 4 sorts of seeds
(round, yellow; round, green; wrinkled, yellow; wrinkled,

green).

1MENDEL, in BATESON, Joc. cit., p. 333. Compare the method of cal-
culation adopted by Mendel and the method followed here.

* These experimental results are very satisfactory. Compare the figures
obtained by tossing 500 times one coin, p. 119.
140 THE QUANTITATIVE METHOD IN BIOLOGY

Since 301 fertile plants were raised from 315 seeds, the
numerical values of the four terms under consideration no
longer represent the frequencies of the four groups in respect of
the total number of seeds (which is 556), but their relative fre-
quencies in respect of the number of plants, which is 301. The
numerical values are o=,,; B= 4%; y= 3, and s=4. The
relative frequencies are I, 2, 2, 4; the expected figures are
30I1x$; 301” $3; 301 x 2, and 301 x 4.

In MENDEL’S experiment the figures were ?:

 

Observed Calculated
(2) Plants bearing Dd seeds . ‘ 38 30Lx2= 33
3 Dd and Rd seeds 60 301 x2= 67
x) F Dd and Dr seeds 65 301x2= 67
(°) . Dd, Dr, Rd and
Ry seeds ; 138 301 x $= 134

Among the plants raised from wrinkled, yellow seeds we can
fiefs

(«) plants raised from seeds R?d?; coefficient 1; x sort of
seeds (wrinkled, yellow).

(Q Plants raised from 2drR?; coefficient 2; 2 sorts of seeds.
(wrinkled, yellow; wrinkled, green).

From Io1 wrinkled, yellow seeds 96 fertile plants were ob-
tained. The numerical values of the terms are «=3;, (=75.
The relative frequencies are therefore 1, 2; the expected

are 96 x 4 and 96x 8.
In MENDEL’S experiment the figures were :

Observed Calculated

 

(e) Plants bearing Rd seeds . ‘ 28 96 x $= 32
(9) 4 Rd and Rr seeds 68 96 x $= 64

Among the plants raised from round, green seeds we can dis-
tinguish :
(n) Plants raised from D*v2; coefficient 1; 1 sort of seeds
(round, green). :
(9) Plants raised from 2DRr* ; coefficient 2 ; 2 sorts of seeds
(round, green ; wrinkled, green). :
From 108 round, green seeds 102 fertile plants were obtained.
The numerical values of the terms are 7=7;, 9= 7. The
relative frequencies are therefore 1, 2; the expected figures
are 102 x3 and I02 x §.

1 Compare MENDEL’S calculation in BATESON, loc. cit., p. 334.
MEASUREMENT OF VARIABLE PROPERTIES 141
In MENDEL’S experiment the figures were :

Observed Calculated

(7) Plants bearing Dr seeds . 35 102 x 4=34
(8) 9 Dr and Ry seeds 67 102 x = 68

The plants raised from wrinkled green seeds—that is to say,
from : k?y*—were expected to bear one sort of seeds (wrinkled,
green).

In MENDEL’S experiment 30 fertile plants raised from 32
seeds yielded seeds Rr.1

§ 106—ELEVENTH EXAMPLE (continued).—In a third
experiment MENDEL crossed two varieties (subspecies) of the
edible pea differing in three primordia—viz.

Parent a Parent B
Seed round (A) Seed wrinkled (a)
Albumen yellow (B) Albumen green (5)

Seed-coat grey-brown (C) Seed-coat white (c)

The seeds (first hybrid generation F,) are ABC as the parent
a, the primordia A, B, C being dominant.

The plants raised from these seeds yielded (by self-fertiliza-
tion) numerous sorts of seeds. In order to calculate all the
possible compound events (sorts of seeds), the method indicated
for the second experiment (p. 138) may be followed—viz.

For the three pairs of primordia all the possible combinations
of the germ cells are obtained by working out—

(A + a)? x (B+ b)? x (C+)?

1The plants raised from seeds Ry yield in their turn seeds Rr and so on in all
the subsequent generations. All these plants are similar to the parent b. In
many crosses between two species a and b differing in two pairs of properties,
the recessive property R belongs to a and 7 belongs to b. In all such cases the
plants Rr are characterized by a NEW combination of two properties which
do not coexist in any of the parental species. Since the new combination Ry
is transmitted without any variation to all the successive generations it may
be said that a new specific form (constant hybrid) has been produced. A
similar remark is applicable to the combination abc in § 106 and to any com-
bination of recessive properties.

It may be recalled that a new specific form may be produced in four different
ways—viz.

cr) By a saltation (mutation) which is a direct result of a change in the con-
ditions of life (§§ 8a and 9). ’ : a

(2) By a saltation which is an indirect result of a change in the conditions of
life a

a 2 a cross between two specific forms, the new form being interposed
between the parental species § 35). 2 :

(4) By a cross between two specific forms, the new form being characterized
by a new combination of properties.
142 THE QUANTITATIVE METHOD IN BIOLOGY

the value (frequency) of each letter (simple event) being }. In
this way 27 terms (sorts of seeds) are obtained (see below).

Remark (compare Remark, p. 138): According to the principle of segrega-
tion, 8 sorts of germ cells of each sex are produced by the plants raised from
the F, seeds—viz. ABC, aBC, AbC, ABc, Abc, aBc, abC, abc.

The ¢ germ cells being united at vandom with the ? germ cells, the result is
the same as if two dice I. and IT. with eight faces each (for instance, two regular
octahedra) were cast successively, the 8 sorts of germ cells being marked on the
faces of each die (Die I. being $ and Die II. being ?). All the possible events
are found by working out +

(ABC +aBC+AbC+ABc+Abe+aBc+ abC + abc)*

the value (frequency) of each term being (4)* =}.
We obtain in this way 64 terms, which are reduced to 27. The latter are

the same as those obtained by working out
(4 +a)? x (B+6)? x (C +0)? ?

The 27 terms are:

A?B2C2 2AaB?C? 4A aBbC? 8AaBbCc
A*Bc? 2A*BbC? 4AaB?Cc  walwes
A*b?C? 2A?B?Cc 4A?BbCc “ee
a* BC? 2AaBc? 4AaBbc?

Abc? 2A?Bbc? 4Aab?Cc

 

 

a? Bc? 2Aab?2C?2 4a?BbCc
ee CAO) Fo ae
obec? 2a2BbC2 sum: 24
ae | eee
Sunly se oAabee?
2Bbc2 sum of the 27 terms=§{=

Dee I (certitude)
sum = 24

From these 27 terms (F, seeds) we may draw the same in-
formation as from the 3 terms in the first experiment ((1)-(7),
p. 120) and from the 9 terms in the second experiment (p. 138).
By analysing the 27 terms successively the reader may easily
find in each of them the information alluded to. Therefore I
limit myself to the following remarks :-—

FIRST REMARK : Since the factors A, B and C are domi-
nant, in all the terms in which one of them coexists with the
recessive of the same pair, the recessive property is latent.

1 Fach octahedral die represents a germ cell (¢é or ?) in which the 8 com-
binations of all the factors of both parents a and #8, and thus the factors
themselves, coexist. In this way, instead of 16 sorts of germ cells (8 of each
sex), only 2 sorts (1 sort of each sex) are needed. Compare the tetrahedra,

p. 138, Remark. ; .
2 This may be easily demonstrated in the following way :—

(A +4)? x (B+b)? x (C+6)?=[(A +4) (B+b) (C40)?
[(4 +a) (B+b) (Cte) =(4BC +aBC +AbC +ABc+ Abc+aBe+abC + abc)?
MEASUREMENT OF VARIABLE PROPERTIES 143

Therefore the 27 sorts of seeds are reduced to 8 sorts with regard
to their visible properties —viz.

I. The seeds A2B?C?, 2AaB?C*, 2A?BbC?, 2A2B?Cc, 4A?BbCc,
4AaB*Cc, 4AaBbC?, 8AaBbCc are ABC (round, albumen yellow,
coat grey-brown). The sum of the frequencies (numerical values
of the 9 terms, the value of each letter being 4) is 27 : 64.

TI. The seeds a?B?C?, 2a®BbC*, 2a®B*Cc, 4a®BbCc are aBC
(wrinkled, albumen yellow, coat grey-brown) ; frequency 9 : 64.

III. The seeds A*v2C?, 2Aab?C2, 2A°b2Cc, 4A ab?Cc are AbC
(round, albumen green, coat grey-brown) ; frequency 9 : 64.

IV. The seeds A?B%c2, 2AaB%c?, 2A*Bbc®, 4AaBbc® are ABc
(round, albumen yellow, coat white) ; frequency 9 : 64.

V. The seeds A*b?c?, 2A.ab’c? are Abc (round, albumen green,
coat white) ; frequency 3 : 64.

VI. The seeds a?B%c?, 2a?Bbc? are aBc (wrinkled, albumen
yellow, coat white); frequency 3: 64.

VII. The seeds a2b2C2, 2a2b?Cc are abC (wrinkled, albumen
green, coat grey-brown) ; frequency 3: 64.

VIII. The seeds a22c? are abc (wrinkled, albumen green, coat
white) ; frequency 1 : 64.2

The relative frequencies of the 8 sorts of seeds are thus:
27,9,9, 9, 3,3,3,1- (Compare p.139. Compare also the pro-
portions, p. 130.)

These curious relations are calculated a prio; they have
been verified by MENDEL. In his third experiment, from
24 F, plants 687 seeds were obtained in all. From these in
the following year 639 fertile plants were raised, and there were
among them (according to the seeds they yielded)—

Observed Calculated
Plants raised from seeds ABC. 269 639 x 24=270
a os ABc : 98) 5 639 x z= 90
i + AbC ; ae 639 x Zr= 90
4 5 aBC. 88) & 639 x r= 90
a is Abc 5 27) 2, 639 x 2 = 30
is . aBc 34/8 639 x ¢r= 30
- i abot 30] § 639 x ez= 30
”? ” abc : 7 639 x vr= Io

1 These 8 sorts are indicated by the 8 terms the coefficient of which is 1.
In those terms A and a cannot exist together, nor B and 6, nor C and c: the
number of sorts of seeds is equal to the number of terms which are free from
products (4a, Bb, Cc) and composed only of squares.

2 The seeds in which 3 dominants exist (Group I.) have the frequency 27 : 64.
Each of the groups II, III. and IV. in which 2 dominants exist has the fre-
quency 9:64. Each of the groups V., VI. and VII. with 1 dominant has the
frequency 3:64. Group VIIL., without any dominant, has the frequency 1 : 64.
The relative frequencies are :

Dominants . - Oo I 2 3
3

Frequency . - ir 3 3? s
144 THE QUANTITATIVE METHOD IN BIOLOGY

SECOND REMARK: The number of sorts of
coat! + os pe raised from any of the en
may bear is indicate the coefficient of i
ee According to thie Ses eee
ach of the 8 terms with coefficient 1 will vi

gee total frequency 8 : 64. Sere
ach of the 12 terms with coefficient 2 will vi

seeds ; total frequency 24 : 64. eer cen

Each of the 6 terms with coefficient 4 will yield 4 sorts of
seeds; total frequency 24 : 64.

The term with coefficient 8 will yield 8 sorts of seeds:
frequency 8 : 64.

In MENDEL'’S experiment 639 F, plants fruited and there
were among them—

 

Observed Calculated
Plants yielding 1 sort of seeds . : 77 639 x= 80
‘if 2 sorts of seeds. 3 228 639 x 24=240
8 4 i - + | 256 | 639 x #4=240
3 8 3 : ‘ 78 639x2&= 80

_ THIRD REMARK: The coefficient of each term indicates
in how many ways the corresponding seeds have been pro-
duced. Examples: The seeds A®B2C? are produced in one
way: ABC $ x ABC ¢. The seeds 4A4aBbC? are produced in
four ways: ABC g xabC?,abC f x ABC 3, AbC f xaBC 2,
aBC ~ xAbC 3. Etc.

§ 107—THE METHOD OF QUETELET FOR THE
MEASUREMENT OF THE VARIABLE PROPERTIES OF
LIVING BEINGS. MEAN VALUE.—In § 32 I have briefly
expounded the method initiated by QUETELET for the
measurement of the variable properties of animals and
plants.

This method is based upon the principle that the variation
of a given primordium within the limits of a given species de-
pends on chance (variable combined cause) and is therefore
governed by the rules of probability (frequency). QUETELET
and his followers measure a given primordium in a large number
of specimens of the same species (§ 32); they construct the
variation curve and calculate the mean value.

I think that the importance of the latter has been exagger-
ated. Before I expatiate on this subject I am going to expound
briefly, by means of examples, the way in which the method of
QUETELET is used for the measurement of the properties of
inanimate objects—in general, for the determination of magni-
tudes (constants, etc.), in inorganic nature.
MEASUREMENT OF VARIABLE PROPERTIES 145

§ 108—TWELFTH EXAMPLE: THE MEASUREMENT
OF THE DENSITY OF A SOLID BODY a.—In order to
obtain the required value as exactly as possible, the density
of a (for instance, a metal) is determined a number of times.
We observe (this is a matter of fact) that the successively obtained
values are more or less different from each other. We find,
for instance, the following figures, each of them being obtained
several times :—

4°84, 4°85, 4°86, 4°87, 4°88, 4°89, 4°90, 4°91, 4°92, 4°93) 4°94, 4°95
4°90, 4°97, 4°98, 4°99, 5°00, 5°0T, 5°02, 5°03, 5°04, 5°05, 5°06, 5°07,
508, 5°09, 5°10, 5°II, 5°12, 5°13, 5°14, 5°15, 5°16

Which is in reality the density of a? In order to answer
this question we add up all the figures and divide the sum by
the number of observations: the quotient is the avithmetic
mean or mean value. I suppose that the mean value is 5'00:
this figure is, among all the observed figures, the most probable
value of the density of a.

Most of the observed figures deviate from the mean, because
of errors committed in the determinations. These errors
depend on numerous causes (forces, factors), certain of which
tend to produce a positive error, whereas others result in a
negative one. In each determination these causes (or certain of
them) act simultaneously: their combination (resultant) brings
about a more or less important positive or negative error.
This is expressed by saying that each error depends on
chance.

We may construct in the following way the curve of errors,
or, using biological language, the varzation curve of the measure-
ments. The distance between the extremes (4°84 and 5°16) is
divided arbitrarily into a certain number of equal intervals,
for instance, I1—viz.

4°84-4°86, 4°87-4°89, 4°90-4°92, 4°93-4°95, 4°96-4'98, 4°99-5'01,
5'02-5'04, 5'05-5'07, 5°08-5°10, 511-513, 5°14-5°16

The observed figures included in each interval are counted.
A horizontal line is divided into 11 equal segments, each of
which corresponds to an interval. From the middle of each
segment a vertical ordinate is erected, proportionate to the
number of figures (measurements) in the corresponding interval.
The extremities of the ordinates are joined by straight lines
(Fig. 18). The curve of errors obtained in this way is a diagram-
matic representation of facts, without any calculation.

We SEE that the observations (measurements) which deviate
the least from the mean (interval VI.) are the most numerous :

1 Compare with the second example (one toss with one coin), § 92, p. 116.
K
146 THE QUANTITATIVE METHOD IN BIOLOGY

the central ordinate m1 is, indeed, the highest one: it corre-
sponds to the so-called summit or hump of the curve. The
successive ordinates become shorter in proportion as they are
farther from the centre. In other words, the positive as well
as the negative errors (deviations from the mean value) become
less numerous in proportion as they are greater. The curve
is symmetrical: the positive and negative errors are equally
numerous.

Each error, considered in isolation, depends on chance, and
may be looked upon as being accidental. When we consider,

77tL

\

 

 

 

+

 

  

Vi

Fic. 18.—Curve of errors (a+)

however, all the errors at the same time as a whole, we see that
their distribution (among the eleven groups) is governed by a
definite rule. According to experience, the length of the succes-
sive ordinates is approximately proportionate to the} numerical
values of the terms obtained by expanding (a+b), in which
a=b=}. If we suppose »=10, we obtain 11 terms—viz.

a9 + r0a% + 45a%b? + 12007)? + 210a°t + 252a°b* +
210d + 1200207 + 45a2b8 + 10ab? + 51°

The numerical value of each term is given by its coefficient
divided by 21°=1024, thus yor, ziSa, etc.

1 The length of the central ordinate represents the number of measurements
from 4'99 to 5°01. The mean 1s 5°00.

 
MEASUREMENT OF VARIABLE PROPERTIES 147

If we suppose that the number of observations has been 10,240
(or in general x), we would expect to find approximately —

In interval I.: ro figures (=x x pez)
oe II.: t00) 4, | (=%x 733s)
3 TII.: 450 4, (=%x765;)

etc., the approximation being more and more close the greater
the number of observations (x).

REMARKS: (1) The above polynomial represents all the
possible events and their frequencies when Io coins (dice with
two faces) are tossed (a=head, b=tail). (See § 96.)

(2) The rr terms of the above polynomial represent the
relative frequencies of the evvors (deviations) in each of the
II groups, but they are independent of the absolute values
of the measurements.

(3) In this example two groups of causes (forces, factors)
have an influence upon each determination of the density
of a.

In the first group I put one cause or force, which is the density
we want to discover. This density is a definite, invariable
property of a. It is an invariable force, a constant. The mean
value is the measure of this constant.

The second group includes a number of accidental causes
(chance), the combination (resultant) of which varies continu-
ally and produces in each determination an error (or deviation).
Each observed figure is the constant + an error.

(4) Here the importance of the mean value is preponderant :
it represents a definite something the existence of which ts
independent of chance. The extreme errors are of very little
importance because they are indefinite. When the operator is
skilled and disposes of good instruments, the extreme errors
come nearer the mean and nearer each other than when the
operator is inexperienced and the instruments mediocre. And,
moreover, the possibility always exists that, in a new deter-
mination, an error may be committed greater than the greatest
one previously committed. In other words, in the given
example, the range of deviation is unlimited.2, We will see below
that this is not always the case.

1In reality, the arithmetical method followed here is not quite accurate :
a curve of errors is governed by a more complicated mathematical expression
deduced by GAUSS. The series of values (terms) obtained by expanding
(a+6)” approximates more and more closely to the probability curve of Gauss
the greater the value of . If m-=2zo the error is not very important, and for
a greater value of n the error (difference between the arithmetical curve and
the curve of Gauss) becomes rapidly smaller and smaller. I take n =10 (which
is too small) in order to avoid an exaggerated number of terms. The arith-
metical method is sufficient for the object of the present work.

? This finds its expression in the curve of Gauss.
148 THE QUANTITATIVE METHOD IN BIOLOGY

§109.— THIRTEENTH EXAMPLE: THE MEASURE-
MENT OF A GIVEN WEIGHT OF A CERTAIN SUBSTANCE.
—I want a certain number of portions of sand, each weighing
200 gr. A first operator A, inexperienced and disposing
of a mediocre balance, is trusted with the necessary work.
A weight of 200 gr. being placed in one of the scales of his
balance, he weighs successively a 1st, a 2nd... . a xth portion
of sand, each portion being kept separately. A second skilled
operator B, disposing of a good balance, is trusted with the veri-
fication of the work of A. Let us suppose that B does not
commit any error. He will find that almost all or all the portions
of sand weigh more or less than 200 gr. The figures observed
by B are comparable to those observed in the preceding
example (density, § 108). If we construct the curve of the
errors (variation curve of the portions of sand) committed by A
and discovered by B, we see that they are distributed accord-
ing to the rule expressed by (a+ 6)", just as in the preceding
example, the mean value being (approximately) 200 gr. (and
the extreme errors being indefinite).

Here again we discern :

(1) One simple cause, which is measured by the mean (200 gr.).

(2) Chance, which is variable and brings about errors
(deviations).

From a mathematical standpoint both examples (§§ 108 and
109) are identical. For the naturalist, however, they are dis-
similar because the mean value does not represent the same thing
in both.

In the first example we have discovered a certain property
(density) of a measured by the mean value. In the second
example the mean value represents something quite distinct
from any property of the sand. It represents, indeed, a cause
or force (the weight of 200 gr. in one scale of the balance) external
with regard to the substance sand and acting continually and
uniformly through the whole time during which the successive
portions (¢ndividuals) of sand were taking birth.

Using biological language, we might say that the mean
value (200 gr.) and the variation curve discovered by the verifier
B express the conditions of existence which prevailed while
the individuals (portions) of the species sand were developing.
These conditions are: (r) one simple cause ; (2) chance (variable
combined cause).

§ 110—FOURTEENTH EXAMPLE: A MIXTURE OF
TWO VOLUMES OF WATER.—We dispose of two pipettes
A and B. The pipette A is narrow, exactly graduated, each

1 More strictly, while the primordium weight of the individuals was reach-
ing its state of final equilibrium (adult state). (See § 45.)
MEASUREMENT OF VARIABLE PROPERTIES 149

division being 0-01 c.c._ The pipette B is wider, graduated in
such a way that each division is o-1 c.c. It is supposed that
it is possible to measure exactly a certain volume of water by
means of A, whereas errors are unavoidable when B is used.

By means of A we measure exactly a volume of water of
Io c.c., and an equal volume is measured rather inexactly by
means of B. Both volumes are united into one portion. The
same operation is repeated a number of times, each portion
being kept separately.

Thereafter all the portions are measured exactly. From the
collected figures we may calculate the mean volume (approxi-
mately 20 c.c.). We may construct the curve of errors (varia-
tion curve of the individuals) ; the limits of error are indefinite.

On the whole, this example recalls the preceding one (sand,
§ zog). There is, however, a difference between both with
regard to the significance of the mean value. In the case of
the sand, the mean value represents one simple invariable cause
(200 gr.) ; in the case of the water the mean (20 c.c.) represents
the resultant * of two simple causes, which have acted in each
of the successive operations. pee of these causes (pipette A)
is invariable ; the other cause (pipette B) is also invariable, but
its effects have been continually augmented or diminished by
chance.

Looking upon the portions of water as being specimens of
the species water of which we have measured one variable
property (volume), we may say that the observed values re-
present the conditions of existence under which the specimens
have been developed. The mean value and the variation curve
are independent of any property whatever of the water.

In the previously discussed examples, in which there is
question of a sphere, coins, balls in an urn, dice, and in the example
of the typical Mendelian hybrids, chance produces a limited
number of simple events (heads or tails, seeds round or wrinkled,
etc.). Chance is acting through a machinery which may be
brought into a limited number of states of equilibrium. The
observed effects depend on certain properties (specific energy)
of the objects under consideration. In the two last examples,
in which the machinery consists of sand or water, the observed
and measured facts are independent of the machinery through
which chance is acting. Each figure is a direct effect of external
causes. The variation is unlimited, because it depends merely
on the variation of chance, which has no limits.

§ 111—FIFTEENTH EXAMPLE: A MIXTURE OF AN
ACID AND AN ALKALINE LIQUID.—We dispose of two

1In this example, the resultant is simply the arithmetical sum of both causes
under consideration (10 +10).
150 THE QUANTITATIVE METHOD IN BIOLOGY

watery solutions, containing respectively an acid and an alkaline
substance. The solutions are prepared in such a way that roc.c.
of the acid neutralize exactly ro c.c. of the alkali. By means of
the (exact) pipette A of the preceding example (§ 110) Io c.c.
of the acid are taken; by means of the (imperfect) pipette B
we take rather inexactly 10 c.c. of the alkaline solution. Both
volumes being mixed into one portion, we add one drop of turn-
sol, by which the reaction (acid red, alkaline blue) is indicated.

A number of portions being obtained, we see that the red
and the blue portions are (about) equally numerous. How
can this result be explained ?

All the operations have been carried out exactly as in the
preceding example (§ 110). Since the acid has been measured
by means of A, the volume acid is exactly 10 c.c. in all the
portions. The alkaline solution has been measured by means
of B, which is imperfect, and therefore the alkaline volume is
variable from one portion to another. In all the portions in
which the alkal. vol.<10 c.c., the colour is red (acid pre-
dominant), whereas the portions in which alkal. vol.>10 c.c.
are blue.?

We know from the example in § 108 (density) that the errors
depend on chance. A curve of errors (Fig. 18, p. 146) is sym-
metrical, positive and negative errors being equally numerous.
Since each positive error (alkal. vol.>10) produces blue and each
negative error (alkal. vol. <10) red, both colours are observed an
equal number of times.

In this example the variation produced by chance (the
colours only being taken into account) is not expressed by
means of figures. Chance may produce only two events (states
of equilibrium) : ved or blue. When chance is alone at play,
red and blue are equally frequent. (If, however, a simple cause
interfered, augmenting, for instance, slightly the acid volume
in each portion, the frequency of the event ved would increase,
and vice versa.)

§ 112—REMARKS ON THE PRECEDING EXAMPLES:
CONTINUOUS AND DISCONTINUOUS VARIATION.—In
the examples mentioned in §§ 108-110 (density, sand, two
volumes of water) the variation of the observed values is con-
tinuous : it is expressed by a series of figures in which no gaps
occur, the transition from one value to the next one being
gradual (see the figures, p. 145)? and the frequency of the

1It is thinkable that the reactions of certain portions were neutral, both
constituent volumes being strictly equal. The probability (frequency) of

this event is exceedingly small, and therefore it may be practically excluded.

Compare the possible states of equilibrium of a coin, § 92, p. 117.
2 ta the mentioned series of observed values (p. 145) the difference between
two successive figures is not an existing gap: its value depends on the used
MEASUREMENT OF VARIABLE PROPERTIES 151

successive figures varying gradually. In the last example

'’ (acid + alkali, § 111), on the contrary, discontinuous variation
exists in the effects of chance ; there is, indeed, a distinct gap
between ved and blue.

The above phenomena recall respectively the continuous
and discontinuous variation observed in animals and plants.?
(See § 21.)

A comparison between the fourteenth and the fifteenth
examples is interesting for the biologist. In both cases
(volume and colour) all the conditions are the same, the opera-
tions are the same, the causes are the same. The effects, how-
ever, are quite different : continuous in one case, discontinuous
in the other. It might even be possible to observe both effects
(volume and colour) at the same time in each portion (speci-
men), if it is supposed that the chemical reaction has no
influence upon the total volume.

This being admitted, each portion acid+alkali may be
looked upon as being an ‘individual of a certain species of which
we have investigated two primordia, volume and colour. With
regard to the volume, continuous variation is observed, the
variation curve being regular, as in Fig. 18; with regard to the
colour, variation is discontinuous. We might be tempted to
ascribe the difference to a difference in the causes.2 We know,
however, that the very same causes have produced dissimilar
effects because each property has its own specific energy
which produces its characteristic states of equilibrium.? (Com-
pare Centaurea, § 47, p. 58.)

§ 118—SIXTEENTH EXAMPLE: UNILATERAL VARI-
ATION (UNILATERAL VARIATION CURVE).—We dispose
of two watery solutions containing respectively two salts a
and 6. The solutions are prepared in such a way that ro c.c.
of a precipitate exactly 10 c.c. of 0, the weight of the precipitate
being I gr.=1000 mgr.

By means of pipette A (§ 110) we measure exacily 10 c.c. of a ;
by means of pipette B (which is imperfect) we measure Io c.c.
of 6. Both volumes are mixed. A number of mixtures being

unit. On p. 145 the unit is o’o1 of the density of water. If we take, for
instance, o’oo1 as unit, the difference under consideration is ten times smaller
than when o’or is taken, etc. However small the adopted unit may be, perfect
continuity is never obtained, owing to the necessity of using ciphers for the
expression of the measurements.

1 The form of variation observed in the last example (red-blue) is often called
alternative variation. It may be looked upon as being discontinuous variation
with two terms.

2 For instance, to the existence of different determiners, factors, pangenes, etc.

3 The same cause has produced two kinds of variation, in one case con-
tinuous, in the other case discontinuous; but there is a connection between
the two kinds—e.g. if a is a blue specimen and § a red, then vol. of a >
vol. of 8 and this rule is invariable.
152

THE QUANTITATIVE METHOD IN BIOLOGY

prepared in this way, we determine exactly the weight of the

   

ce

 

 

 

 

- a

 

+—

(symmetrical).
(unilateral)

Fic. 19— ABCDEFGHIJK, curve of committed e
ABCDEL, curve of observed effects

TTOTS

precipitate in each
mixture. The value
of this weight de-
pends on twocauses,
one of which (pipette
A) is invariable, the
second one (pipette
B) consisting of an
invariable cause + a
variable cause which
ischance. Thevaria-
tion (errors) of the
weight precip. is
therefore governed
by the rules of
chance, but here
the effects of chance
are of a peculiar
kind.

Suppose that the
greatest errors (with
regard tothe volume)
committed by using
pipette B have been
+016 and —o-16
c.c. Between these
extremes all the
errorsare distributed
according to a curve
similar to Fig. 18,
the negative errors
being equal in num-
ber to the positive
ones.

Since the volume
of a is exactly 10 c.c.
in all the mixtures,
each negative error
results in a diminu-
tion of the weight
precip. Forinstance,
the greatest nega-
tive error, which
amounts to 0-016 of

Io C.c., corresponds to 984 mgr. of precipitate instead of 1000,

etc.

The positive errors, on the contrary, don’t produce any
MEASUREMENT OF VARIABLE PROPERTIES 153

increase of the weight precip., since this cannot exceed 1000
mer.
Therefore the variation curve of the weight precip. does not
coincide with the curve of the committed errors. The series
of committed errors (from 9-84 to 10-16 c.c.) being divided into
eleven groups (intervals; compare p. 145), and the relative
number of mixtures of each group being represented by a
vertical ordinate, a symmetrical curve of errors (Fig. 19) is
obtained similar to Fig. 18, p. 146. In the six groups A, B, C,
D, E, F the weight precip. increases from A to F. In F it
reaches the value of 1000 mgr. In the groupsG, H,/, J, K the
maximal value 1000 mgr. is invariable. Therefore if the varia-
tion curve of the weight precip. (observed effects) is constructed, the
frequencies G, H, J, J, K are added to the frequency F, and the
curve ABCDEL (Fig. 19) is obtained (FL=G+H+I+J+K).

The causes which have produced in the present example a
unilateral variation curve LEDCBA are exactly the same as
those which resulted in a symmetrical curve (ABCDEFGHI]/K,
Fig. 19) in the fourteenth example (10+ 10 c.c. water, § 110).
The difference between the two curves does not depend on a
difference in the causes, but merely on a difference in the
specific energy of the measured properties (volume ; precipitate)
of the mixtures.

REMARK : Comparing the fourteenth, fifteenth and sixteenth examples,
we see that the same causes may produce : (1) continuous variation, expressed

by a symmetrical curve ; (2) discontinuous variation ; (3) continuous variation
expressed by a unilateral curve.

In the sixteenth example the maximal value (weight precip.
1000 mgr.) has a preponderant importance ; it is, as it were, a
measure of the resultant of the two simple causes (10 c.c.
solution a +10 c.c. solution b) which have acted simultaneously.
The minimal limit, on the contrary, is indefinite. From all the
observed figures a mean value may be easily calculated, and it
might be possible to find a mathematical expression of the
(rather complicated) relation between this mean value and the
maximum. The significance of the mean value is, however,
rather a fictitious one, at least for the naturalist.

We see from this example that a unilateral variation curve
may be simply a product of chance acting through a certain
machinery, without the intervention of any peculiar cause.
(Compare § 102, Example (B), p. 129.)

§ 114—THE FOURTEENTH, FIFTEENTH AND SIXx-
TEENTH EXAMPLES MODIFIED BY A UNIFORM
INCREASE OF PIPETTE B.—In the mentioned examples
(§§ 110, 111 and 113) there is question of a mixture of two
liquids a and 6, 10 c.c. of each being measured respectively by
154 THE QUANTITATIVE METHOD IN BIOLOGY

means of an exact pipette 4 and an imperfect pipette B.
(See p. 148.) The three series of experiments may be repeated
under the following conditions :—

(1) The successive mixtures are prepared at equal intervals
of ten minutes each and marked with a number indicating their
order of succession.

(2) Pipette B is supposed to zncrease regularly (unknown to
the operator) through the whole duration of each series of
experiments,’ with such a velocity that the volume indicated
by degree ro is increasing by 0-01 c.c. in the course of each
interval of ten minutes. I ascribe here to pipette B a property
of the living beings—namely, growth.

(3) At the beginning of each of the three series degree 10 of
pipette B coincides (unknown to the operator) with a volume
of 9 c.c. instead of 10.

Suppose that in each series 200 portions (mixtures) are pre-
pared. In all the portions the already mentioned properties
are measured or observed—viz.

ist Series (fourteenth example): water+water: property
volume.

2nd Series (fifteenth example) : acid+alkali: property colour
(red or blue).

3rd Series (sixteenth example): salt a+salt 0: property
weight of the precipitate.

1st. Series —If no errors were committed, volume 1 (first
portion) ? would be 10+g=19 c.c. Ina similar way—

Volume 2 would be 19-01 c.c.
» 3 ” 19:02 ”

” 30 ” 19:29 ”
” 31 ” 19°30 ”

is go 4 19°89 ,,
»” gr ” 19:90 ”

” 100 ” 19°99 ”
” IorI 5 2-000 ,,
oh IIO nO 20:09 ,,
» II Re 2010 ,,
» 200 » 20°99 >,

1 For instance, by an increase of its diameter unperceived by the operator.
2 Volume 1 is prepared at the moment o.
MEASUREMENT OF VARIABLE PROPERTIES 155

But since errors are committed with pipette B, the effects of
the cause (volume) B are continually varying according to the
law of errors (§ 108) and the increase of the volume given by B
is no longer regular, but varying continually. If the greatest

20199 cub epn.|_..| sane | eke 54
gio
ff
ie
Leet
ar
18 e
pigs t atau CRs elec age Piet sch eta 19 cub|om

 

 

 

 

 

 

 

 

 

 

 

 

GO] 2 it IN VW VI VIE mM Xe

Fic. 20.— The distance between each small dot and of is supposed to
represent the volume of a portion. The thick dots represent the

curve of growth (see text); of, time; 0, origin

errors are supposed to be +0-10 and —o-I0o c.c., irregularities
may occur in the following way :—the volume of portion 30
(for instance) is expected to be (without error) 19-29 c.c. ; if the
error is, for instance, +0-06, the observed volume becomes
19:35. The volume of portion 31 is expected to be 19:30; if
the error is —o-10, the volume is reduced to 19:20. More or
156 THE QUANTITATIVE METHOD IN BIOLOGY

less important errors being continually committed, the effects
of the vegular increase of pipette B (the effects of growth) are
disordered according to the rules of chance.

The 200 portions may be represented by 200 small dots
(Fig. 20), the distance between each dot and a horizontal line of
representing the volume of the corresponding portion.

Fig. 20 represents the observed growth of the property
volume (during a period of 199 x 10=1990 minutes) deduced

ff yo

1000 es REISS ye eee abisks s30°° BeBe ve oD eajooGoe lo -@-a

Pee dazed ee ac secede iS fede tate goolmg.

 

 

 

 

 

 

 

 

 

 

 

 

O01 H Wm W V Vi Vil VN IX XE

Fic. 21.— The distance between each small dot and of is supposed to
represent the weight of the precipitate in a portion. The thick dots
represent the curve of growth (see text); ot, time ; 0, origin

from the measurement of 200 specimens of successive ages, the
last specimen (last small dot) being 199 x I0=1990 minutes
older than the first one. This total duration may be divided,
for instance, into ro equal intervals, I., IT., ... X. For each
interval the mean volume of the corresponding specimens (small
dots) may be calculated. Since each interval includes twenty
specimens, the positive and negative errors are counterbalanc-
ing one another 7m a certain degree.1_ The ten mean values being
plotted out in the form of thick dots, it is seen that the latter are
situated approximately on a straight line which is the curve of

1 The result would be, of course, better if the portions were more numerous.
(See, on the conclusion drawn from a series of twenty observations, § 93, p. 118.)
MEASUREMENT OF VARIABLE PROPERTIES 157

growth? and represents the mean growth. On both sides of this
line the specimens (small dots) are distributed (according to the
law of errors) within a zone, which is limited by the greatest
errors (+0-1 and —o'1). This zone is the variation zone of the
curve of growth.

and Series.—See below, p 157.

3rd Series.—The weight of the precipitate is determined in
the 200 portions and the curve of growth is constructed in the
same way as for the first series (Fig. 21).

In the intervals I.-IV. everything happens as in the first
series, the curve of growth (thick dots) being, on the whole,
an obliquely ascending straight line. As soon as portion g1 is
reached (in the middle of interval V.; see Table, p. 154) the
weight of the precipitate cannot exceed 1000 mer, even if the
greatest possible positive error (+0-10 c.c., which coincides
with +10 mgr. of precipitate) iscommitted. When portion 101
is reached the maximal value of the weight precip. (1000 mgr.)
is reached if no error is committed. (See Table, p. 154.) This
weight may be diminished by a negative error, but it cannot be
augmented by any positive error whatever. From portion 111
to the last one the value 1000 mgr. is certainly invariable ; it
cannot be modified even by the greatest negative error. There-
fore in the intervals VI.-X. all the small dots (with the possible
exception of the portions ro0I-110) are situated exactly on a
horizontal straight line (second part of the curve of growth),
and here a zone of variation does not longer exist.

Remark : The property weight precip. may be compared to an arrested pey-
sistent property. (See § 46.)

and Series—Here we find an example of discontinuous
variation (red, blue) which gives rise to a curve or line of growth
of a peculiar kind. In the intervals I.-IV. the acid is predomi-
nant whatever may be the errors, and the colour is always red.
When portion 92 is reached pipette B is expected to give 9-9
c.c. of alkali, but if a maximal error (+0-I) is committed the
volume B may reach 10-01, and since the volume 4 is 10-00,
the colour of the mixture is blue. From portion 92 to III
errors may produce an irregular alternation of red and blue.

. rvvvvvvvvvvovvbybrbrbybrbrbrbrbbybbbbbbbbbbbbbbbbbb .. . .
92

111 200
Fic. 22.— Development of the colours : 7, red; b, blue. (See text.)

1

In all the portions 112-200 the alkali is predominant in spite
of any error whatever and the colour is always blue. In the
development of the property colour we can therefore distinguish
three periods (Fig. 22)—viz. red; hesitation between red and
blue (alternative variation) ; blue.

1 This curve is an embryological curve. (See § 49.)
158 THE QUANTITATIVE METHOD IN BIOLOGY

Remark I.: In Fig. 22 the letters represent specimens of successive
age.

OS esis II.: The primordium ved is original, arrested, transitory; the
primordium blue is metamorphic, arrested, persistent. (See § 46.)

Remark IIl.: The primordia ved and biue are two terms of an embryo-
logical series. (See § 133.) ; ,

Remark IV.: The possibility of investigating the three primordia (volume,
weight precip., colour) in the same mixture is conceivable. This would be
realized if we disposed of an acid solution @ and an alkaline solution 6 pro-
ducing a precipitate when mixed, in such a way that every excess of a would
be indicated by red and vice versa, supposing, moreover, that the total volume
of the mixture were not modified
by the occurring chemical reactions.
A chemist could perhaps indicate
two substances which would satisfy
the required conditions.

However it may be, the above
possibility being admitted, we may
look upon the 200 portions (mix-
tures) as being specimens of different
age of the same species. The three
primordia being observed and
measured in all the specimens and
their curves being constructed, a
diagram similar to Fig. 23 would
be obtained.

Since the causes (pipettes A and
b B) are exactly the same for the

 

three primordia, the curve of each
J $$ AY] Soprimordium depends on its specific
energy.

Remark V.: Each of the three
curves in Fig. 23, considered separ-
ately, does not represent the develop-
Oo E ment of a specimen considered as
Fic. 23 Curves of development of three a whole. This development is a

primordia of a mixture of two liquids complex something, the exact in-

(see text)—v, curve of growth of the vestigation of which is possible by

total volume; #, curve of growth of measuring the growth of each

the weight of the precipitate ; 7b, curve primordium separately. In the
of development of the colour: 7, red leaves of the mosses and other
period; 6, blue period—between both objects I have observed facts which

a period of hesitation ; of, duration of recall the above example (gradation

the development ; 0, origin curves, Part VIII.). (Compare § 49 :

application of the quantitative method
on embryology. In Fig. 23 the volume is the most convenient leading

property.)

§ 115—SEVENTEENTH EXAMPLE: AN URN CON-
TAINING too PRISMS a AND 100 PRISMS 06 (continued
from § 100).—An urn contains :

(1) 100 right prisms a, the base of each being a square of
side r cm., the height 2 cm.

(2) 100 prisms 6 differing from the prisms a only by their
height, which is 3 cm.

It is obvious that the conditions are the same as if the urn
contained 100 white and 100 black balls (see this example in
§ 98). When the prisms are taken one by one in series of n
prisms (each prism being put again into the urn after its height

 

 

 
MEASUREMENT OF VARIABLE PROPERTIES 159

has been observed ; see § 98) ! all the possible compound events
and their frequencies may be calculated a priori by expanding
(a+ 6)”, in which a=b=199=}.

The prisms being extracted, for instance, in series of 10, and
this operation being repeated, for instance, 102,400 times,” all
the events (combinations of 10 prisms) are represented by—

(a+ 6)?9= a? + 10a°b + 45a*b? + 120a7b3 + 210a%b4 + 252055 +
210a4b® + 120a°b7 + 45a2b8 + roab®+ bl! =1

The denominator of all the terms is 2!°9=1024. The fre-
quency of each term is z,5:7 multiplied by its coefficient.

Example. The frequency of the combination a?b® (2 prisms
a+8 prisms b) is 7$5;; since we have extracted 1024 x 100
series, a?b® occurs approximately 45 x 100 times.

T ascribe to the letters a and b two values :

(1) The value 4, which is the frequency of the corresponding
simple events.

(2) A second value (facial value), which is quite independent
of the frequency and represents the measure of the correspond-
ing simple events (§ IoI, p. 126)—1.e. a=2 cm. and )=3 cm.
In this way the sum of the letters of each term is the total
height of the ro prisms of the corresponding combination
(resultant of the simple causes).

Example: The term 1oab® represents 1 prism a+g prisms 8,
the total height of which is (2 x 1) + (3 x 9) =29 cm.

By a very simple calculation one finds that the total heights
increase regularly from the first to the last term, the values
being :

20, 21... 29, 30 cm.

We construct now a large number of new prisms of eleven
sorts, the respective heights of which are given by the above
values (20 to 30 cm.), the number of each sort being propor-
tional to the frequency (numerical value) of the corresponding
term.

(The base of all the prisms is 1 cm?.)

Examples: The term a!°= 5,4, represents the frequency
of the combination the total height of which is 20 cm.
We construct, for instance, 1000 prisms of 20 cm. The term
10a =732; represents the frequency of the prisms of 21 cm.
According to this, we construct 10,000 prisms of this sort, etc.
The total number of prisms is 1,024,000.

All the prisms (each within a case) are mingled and put

1 Each prism is supposed to be enclosed within a case, in such a way that
it is impossible to distinguish an a from a b without opening the case.

2 102,400 =2'!x100. I take this figure in order to simplify the calculations
below.
160 THE QUANTITATIVE METHOD IN BIOLOGY

into an urn. One case being extracted, the probability (fre
quency) of each sort of prisms is given by (a + 6)!°—viz.

 

Height Frequency

20 cm. : I,000: I1,024,000= 1: 1024= 0-098 %
BX 3, é 10,000 : x = 10: , = 008 ,,
22 5, . 45,000 : 2” = 45: ” = 4°39 ;,
rae . 120,000: » =120: , =II7 ,,
BA, os . 210,000: » =210: ,, =2051 ,,
25. 53 . 252,000: J =252: , =2460  ,,
26 ,, - 210,000: on =210: ,, =2051 ,,
De 5 . 120,000: » =120: , =I1I97 ,,
2B og » 45,000 : of ASS wy = AO as
29, : 10,000 : os = 10: , = 098 ,,
30, : 1,000 : » = I: 4 = 0098 ,,

When a large number of prisms, for instance, 102,400, are
extracted one by one, we may expect approximately the
following result :—

Height of the

prisms ‘ 20 21 22 23 24 25
Number of

prisms ; 100 I000 4500 12,000 21,000 25,200
Height of the

prisms ‘ 26 27 28 29 30
Number of

prisms . 21,000 12,000 4500 1000 I00

The eleven sorts of prisms are, as it were, specimens of a
certain species, a variable property of which (height) has been
measured. The above figures represent the variation curve,
which is governed by chance (Fig. 24.)

§ 116—SEVENTEENTH EXAMPLE (continued)—Let us
now suppose that we find in the state of nature an unlimited
number of specimens of a given species varying with regard to
the property stature (height), the extremes being 20 and 30 cm.
A large number of specimens taken at random being measured,
a variation curve is obtained. It happens often (not always),
especially in the animal kingdom, that the successive values
are distributed approximately according to the rules of chance
(expressed by ($+ 4)”; see note, p. 147), just as in the above
variation curve of the species prism. The latter (in which n = 10)
being taken as example and plotted out in the form of a diagram,
the obtained figure (Fig. 24) is the same as the curve of errors
mentioned in § 108. (See Fig. 18, p. 146, density of a solid

 
MEASUREMENT OF VARIABLE PROPERTIES 161

body.) From this similitude QUETELET has deduced that
variation in the living beings 1s governed by chance (law of
errors). (See §§ 32 and 118.)

From a mathematical standpoint, a curve of errors obtained
by measuring a density (§ 108) and a typical variation curve
(height of the prisms, § 115 ) are similar. From the standpoint
of the naturalist, however, two fundamental differences exist
between them.

A first difference exists with regard to the significance of the
mean value. When the density of a solid a is determined by
means of a series of measurements, two groups of causes

77

\

 

 

 

ggg ak
VI

Fic. 24.—Symmetrical variation curve (a+b)?

7
S

 

(forces) are at play: (1) a definite simple cause, the density of
a; (2) a variable combined cause (chance). The mean value
represents a definite something : it is the measure of a property
of a—i.e. a physical constant (§ 108); the errors (deviations
from the mean) are produced by chance.! In the example of
the prisms it is possible to calculate a mean (its value is 25 cm.),
but this does not represent a definite constant, a property of
the objects (compound prisms) under consideration. Here the
mean is produced by the variable combined cause (chance).
Its value depends (1) on the simple causes which have been
combined (a=2 cm.; b=3 cm.; see § 115); (2) on the fre-
quency of those causes (a=4; b=); (3) on the number of
causes (simple events) which have been combined (; in the
1In other words, each observed value consists of the constant + an error.

L
162 THE QUANTITATIVE METHOD IN BIOLOGY

given example n=10). The mean represents therefore a very
complex something. In order to realize its significance in
general we are compelled to have recourse to a rather compli-
cated argument (expounded in § 115), starting from (a+6)"+
In each peculiar case, we must know the numerical value of
the data a, 6 and 7.

It is, however, possible to give a definition of the mean value
by saying that—

The mean value is the arithmetical mean of all the observed
figures (this definition is, for the naturalist, a fictitious some-
thing),

Or—

The mean value is the most frequent resultant of the combined
causes ; in other words, the most frequently observed (the most
probable) value.

Although the latter definition is more satisfactory than the
former, we don’t find in it the notion of a directly measurable
simple thing (a constant).

Moreover, the arithmetical mean and the most frequent value
do not always coincide. This coincidence exists in the typical
symmetrical variation curves ; for instance, in the example of the
prisms (§ 115, p. 160). In this case we start from an urn con-
taining simple prisms a and 6 in equal numbers. Since the
frequencies of the simple events are equal, the variation of the
compound prisms is expressed by a symmetrical curve, and
the mean (25 cm:) coincides with the central ordinate (the
most frequent value ; hump of the curve).

If it is supposed that the first urn contains 100 prisms @
(2 cm.) and 200 prisms 6 (3 cm.), the variation curve of the
compound prisms would be obtained by expanding (a+ 0),?
the frequencies being a=38¢=4 and 6=383= (compare the
balls in § 99)—viz. (59,049 compound prisms being extracted) :

Height of the

prisms 3 20 21 22 23 24 25
Number of

prisms : I 20 180 960 3360 8064
Height of the

prisms A 26 27 28 29 30
Number of

prisms - 13,440 15,360 11,520 5120 10243

This curve is asymmetrical. The most frequent value

1Tt is impossible to distinguish in each of the eleven observed values @
constant + an error.

2 See the eleven terms, p. 159. The numerical values are : a1°=(1)=.,175;
10a% =10(3)9 (2) =sa%53 ete.

si The denominator of the eleven terms obtained by expanding (1+) is
31°=59,049.
MEASUREMENT OF VARIABLE PROPERTIES 163

(highest ordinate) is 27 cm. The arithmetical mean is

1,574,640 : 59,049 =263 cm. This does not represent any
existing prism. For the naturalist the second definition of the
mean is not applicable.

A second difference exists between a curve of errors (§ 108) and
the variation curve of the prisms (§ 115) with reference to the
significance of the extreme values (limits). In a curve of errors
the limits are indefinite and of secondary importance, because
it is always possible that a mew error exceeds the greatest error
previously committed.? In the variation curve of the com-
pound prisms, on the contrary, the extreme values are strictly
definite. The minimum is a’ (20 cm.) and the maximum 6°
(30cm.). If one succeeds in finding these values by observation
(extracting prisms from the urn), they are determined once for
all. it is impossible to find in the urn any prism <20 or>30 cm.

In the example of the prisms and in all similar cases the
extreme values may be defined as being the direct measure
of the maximum and the minimum effects produced by the
acting combined causes. In other words, using biological
language, the maximum corresponds to the optzmal conditions
of growth of the species (compound prism), whereas the minimum
corresponds to the most unfavourable conditions—the pessimal
conditions. Both extreme values are constants, between which
variation fluctuates.

We shall see below (§ 118-119) that the extremes (especially
the maximum) deserve still better the name of constants when
variable properties of animals and plants are measured. The
method which I propose for the measurement of constants, the
description of species and the identification of specimens is
based upon the determination of the extreme values.

REMARK: In § ror (Table y, p. 127), we have seen that in
the series of facial values obtained by casting two dice the extreme
values (2 and 12) are definite. Other examples of definite ex-
tremes are mentioned in § 102, examples (A) (p. 128) and (B)
(p. 129) ; experimental verification in §103. In § 113, Fig. 109,
the maximal value is definite.

§117._EIGHTEENTH EXAMPLE: EXPERIMENTS
WITH CARDS. MEAN VALUE AND EXTREME VALUES.
. —First Experiment: I ascribe to each card of an ordinary pack

1 The value 1,574,640 cm. is the total length of the 59,049 prisms.

2In the example in § 108 (measurement of a density) I have put down

n=10, Eye that the combined causes were 10 in number. This is
arbitrary was compelled to adopt a definite value for 2 because I am using
the arithmetical method. By doing so I have arbitrarily fixed two limits
of error (a° and b’°). In reality, m is an indefinite number. Instead of being
combined 10 by 10, the causes which bring about errors may be combined
Il by 11, 12 by 12, ..., 100 by 100, etc. (See note, p. 147.)
164 THE QUANTITATIVE METHOD IN BIOLOGY

(52 cards, 4 suits) the following facial values (without dis-
tinguishing the suits) :—whole numbers 1 to 10; Knave=11 ;
Queen=12; King =13.

Drawing from a complete pack 4 cards simultaneously at
random, I ascertain the sum of their facial values (example :
ace+7+9+queen=29). This experiment is repeated a
number of times. (After each drawing the 4 cards are put
back into the pack and this is shuffled before the next
drawing.)

If we take only the compound facial values into account
(the suits being overlooked), all the possible compound events
(combinations of 4 cards) are reduced to 49 events, measured
by the whole numbers from 4 (4 aces) to 52 (4 kings). Each
of both extreme values may be realized only in one way.

The 49 different values may be looked upon as representing
49 kinds of specimens of a certain species, variable in a certain
property, which is measured in each specimen (4 cards) by
the facial value. The variation curve is symmetrical: its
hump (most frequent value) coincides with 28, which is also
the arithmetical mean.

In this example the range of variation is very wide and the
probability of discovering the extremes by a series of measure-
ments (drawings) is small. Therefore the experimental dis-
covery of the extremes is more difficult, I think, than in the
majority of the living subspecies or monotypic species. I
have carried out 1200 drawings of 4 cards divided into three
series of 400 successive drawings each. Result (facial values) :

 

Ist Series | 2nd Series | 3rd Series
Drawings . ‘ : I-400 401-800 | 801-1200
Minimum . : ‘ 7 9 II
Mean ‘ , : 27°50 28 60 27°83
Maximum . ‘ : 48 47 45

Ist + 2nd + 3rd series (1200 drawings) :

Minimum: Observed 7 Calculated 4
Mean : s) 27°08 s 28
Maximum : 15 48 5 52

Sccond Experiment: Similar to the first, the cards 1, 2, 12 and
13 of each suit being suppressed. The cards are drawn simul-
taneously 4 by 4. The extreme facial values (4 cards) are 12
(4x3) and 44 (4 knaves). Curve symmetrical. Arithmetical
mean, 28. Result:
MEASUREMENT OF VARIABLE PROPERTIES 165

 

4th Series 5th Series 6th Series
Drawings . ; : 1201-1600 | 1601-2000 | 2001-2400
Minimum . : ‘ I5 I4 I4
Mean ‘i . é 28-16 28 83 27-69
Maximum . ‘i ‘ 43 42 42

4th + 5th + 6th series (1200 drawings) :

Minimum: Observed 14 Calculated 12
Mean : i 28-23 + 28
Maximum : By 43 as 44

Third Experiment: Similar to the first, with 13 cards of one
suit. Cards drawn simultaneously 4 by 4. The extreme facial
values are 10 (=1+2+3+4) and 46 (10+II+12+13). Curve
symmetrical. Arithmetical mean, 28. Result (facial values) :

 

7th Series | 8th Series | oth Series
Drawings . ‘ . | 2401-2800 | 2801-3200 | 3201-3600
Minimum . ‘ ¥ II Io Io
Mean ‘ ; : 27-62 27°42 28-04
Maximum . . : 46 44 44

7th + 8th + gth series (1200 drawings) :

Minimum: Observed 10 Calculated 10
Mean: 5 27-69 28
Maximum : 74 46 2 46

REMARKS: In each series of 1200 drawings and even in
almost all the series of 400 drawings the mean value has been
discovered in a satisfactory way.

With regard to the extreme values, the result is unsatisfactory
in the first experiment (this was expected, the frequency of the
extremes being very small) ; the approximation is closer in the
second experiment. In the third experiment both extremes
have been found exactly. The exceptional wide range of
variation in the first experiment being taken into account, we
may conclude from the above result that the discovery of the
extreme values, with a sufficient degree of approximation, is
practically within the reach of observation.

§ 118.—NINETEENTH EXAMPLE. VARIATION
CURVE OF A PROPERTY OF A LIVING SPECIES (BIO-
LOGICAL VARIATION CURVE).—Starting from a very
simple example (sphere, § gI) in which all the possible effects
of chance are reduced to one event, we have been brought step
166 THE QUANTITATIVE METHOD IN BIOLOGY

by step to very complicated cases, in which chance brings about
a large number of events, the diversity of which is expressed
by a curve of errors (Fig. 18, p. 146), or by a variation curve
(dice, § 101; prisms, § 115; cards, § 117).

Let us now suppose that we have measured a variable pri-
mordium in numerous specimens belonging to a subspecies or a
monotypic species ; for instance, the length of the adult spike of
a certain race (subspecies) of rye.

Each observed figure is the measure of an object (individual,
spike) which is in a state of equilibrium. The equilibrium is
brought about by a series of reactions which take place in the
course of the development of the measured object. (See § 45,
growth of a petal.) In these reactions two groups of causes
are operative : (1) specific causes, which depend on the living
substance of the species under consideration; (2) : external
causes, which are numerous; for instance, temperature, light,
water, food, etc. (See § 119.) Each cause has an influence
upon the observed values. The causes are combined in many
different ways according to the laws of chance ; their resultant
is different from one specimen to another. The figures of the
measured property, considered as a whole, are represented by a
variation curve which is governed by chance.

It has often (not always) been observed that the curve
obtained is one humped and symmetrical (or nearly so), corre-
sponding to the expression (4 + 4)” (see note, p. 147) and similar
to the variation curve of the prisms in § 115 and the curve of
errors in § 108. (See QUETELET, § 116, p. 161.)

What is the significance of the mean value and the extremes
in a variation curve of a property of a living species—in other
words, in a BIOLOGICAL variation curve ?

We have seen in § 108 that in a curve of errors the mean
value is the measure of something independent of chance. If
the combined causes (chance) were not operative while we are
determining the specific weight of a solid (§ 108), no errors
would be committed and in each determination a value would
be obtained equal to the mean. In an inorganic variation
curve (for instance, the curve of the compound prisms, § 115),
on the contrary, each specimen is brought into existence by the
very same causes which result in variation by their various
combinations. If these causes (components of chance) were
not operative,! no mean value would be obtained, for the simple
reason that no specimens (compound prisms) would exist.
Therefore the mean value is an indirect expression of a com-
plicated something. (Compare § 116, p. 162.)

A mean value calculated from a biological variation curve

1 The causes alluded to were acting and varying continually while we were
extracting the simple prisms from the first urn.
MEASUREMENT OF VARIABLE PROPERTIES 167

seems to have the same significance as in an inorganic variation
curve. The length of the adult spike of the rye being taken
as example, the external causes (temperature, water, food, etc.)
which bring about variation by their combinations are in
reality the causes of the development of the spike.1 Without
heat, water, food, etc., no spike would come into existence,
and no mean value would exist.

There is, however, between both cases (inorganic and bio-
logical) a fundamental difference.

§ 119.—BIOLOGICAL AND INORGANIC VARIATION
CURVES (continwed):—Among the external causes (factors)
which have (or may have) an influence upon the development
of the living beings, the following may be mentioned :—

(x) Temperature.

(2) Light (source of energy and stimulant).

(3) Water.

Food, which consists of a number of substances; for
instance, (4)-(15) :

Carbon (tension of CO?).

Nitrogen.

Phosphorus.

Sulphur,

Chlorine — (Br., I.).

Potassium.

) Sodium.

) Calcium.

) Magnesium,

) Iron.

) Oxygen (food and respiratory comburant ; tension of

oxygen in the atmosphere).

Silica,

Radio-activity.
So-called catalysts (manganese, lead, uranium, etc.).

(1g) Other living beings (parasitism, symbiosis properly so
called, etc.).

(20) The space available for the development of the indi-
vidual.

Each of the mentioned causes (the list is rather incomplete)
has its proper influence upon each living specimen considered
as a whole and upon each of its primordia. These causes are
the CONDITIONS OF EXISTENCE.

In the course of the development of a living specimen the

1 Without the external factors the (internal) specific causes would not be
operative.

)
) Electricity.
)
)
168 THE QUANTITATIVE METHOD IN BIOLOGY

above-mentioned factors are continually varying ; their vari-
able values are combined in an unlimited number of ways:
— they are the COMPONENTS OF
Se CHANCE. The prevailing com-
‘v2 bination is different for all the
oe specimens of a given species.

I take the influence of tempera-
ture upon a given primordium (for
instance, the length \ of the spike
of a given subspecies of rye) as
example. We know from experience
that the growth of any living object
whatever is possible only within two
limits of temperature. I call the
lowest limit ¢° and the highest limit
T°. Let us suppose that, in the
case of the spike, #= +5° C. and
T° =35° C. (or thereabout). Be-
tween ¢° and T° every variation of
temperature results in a variation
of the intensity of growth and
therefore of the value A. Starting
from 2°, every increase of tempera-
ture brings about an increase of »
till a certain temperature 6° (I
suppose 15° C.) is reached. Every
; further increase from & to T° re-
sults on the contrary in a decrease
of A. The temperature 6° (inter-
mediate between ¢° and T°) is the
optimal temperature, which coin-
cides with the maximal effect.

The relation between cause and
effect is roughly represented by Fig.
; 25. Belowé° andabove T° thelength
4 =0, for the simple reason that no
ce spike may come into existence.

<P

%
a

  
  

 

 

x
u

a= The limits ¢° and T° are, of course,
; critical temperatures. Therefore I
proninct ermeaien’erastrek: fake, in Fig. 25, limits which are a
tion between temperature ({°-T°) little below ¢° and a little above T°.
and length A of the spike; ¥, Suppose that a series of speci-
maximal length of the spike; @°, mens have been cultivated at all
optimal temperature. (See text.) Doccible temperatures between 2°
and T°, the other conditions of development being the same
for each and all. The adult spikes being measured, a series
of values A,, As, As... Aw is obtained. The highest value
MEASUREMENT OF VARIABLE PROPERTIES 169

dp coincides with the optimal temperature 6°. It is impossible
to obtain a spike longer than Ay, whatever may be the
temperature (the other conditions of existence being the same).
Therefore A» is a constant. If we compare two or several
subspecies of rye, each of them has its own value Ap.

The maximal value of a primordium is the exact expression of
a constant property of each species (specific form), just as the
density of a given substance is the exact expression of a con-
stant property of that substance.

REMARK: The influence of temperature upon the pri-
mordium under consideration is comparable to the influence
of temperature upon the density of water. The existence of
liquid water is possible between ¢° (=o0° C. ) and T° (=100° C.).
If a series of specimens of water were taken at all possible
temperatures between the limits ¢° and T°, and if their density
were measured, a series of values d,, d,... d» would be
obtained. The highest value dy would coincide with + 4° C.,
which is 6°. This value du has been adopted as a funda-
mental physical constant.

§ 120—BIOLOGICAL AND INORGANIC VARIATION
CURVES (continued).—I suppose that we find, in the state of
nature, an unlimited number of specimens which have been
developed at all possible temperatures between two limits
(which are not necessarily 7° and T°): a large number—for
instance, 1024 adult spikes—are measured.’ The temperature
of development of each specimen depends on a combination
(resultant) of a number of natural accidental causes. The
frequencies of these combinations are governed by the laws of
chance, and therefore the frequencies of the various observed
values of A (length of the spike) are governed by the same laws.

The variation curve (curve of frequency) of temperature
being represented by (4 + 4)?° (see Fig. 18, p. 146), what will be
the variation curve of A?

I take two eventualities as examples and expound the
subject by means of figures, supposing that all other condi-
tions of existence are the same for all the specimens. (The
following Tables and calculations are merely approximate,
owing to the use of the arithmetical method.)

First Eventuality: The most frequent temperature is 6°
(optimum). Suppose the limits of temperature have been 10°
and 20°, the optimum (6°) being 15°. The following Table
[(a + 6)!°] gives the curve of frequency of temperature expressed

1In order to eliminate the variation produced by gradation (see Part VIII.)
in each plant only the spike of the first bud generation is measured. This is,
in the case of the rye, ordinarily the longest spike of each plant.
170 THE QUANTITATIVE METHOD IN BIOLOGY

by the number of measured specimens developed at each
temperature :—

Temperature . - ro° re 2° 43° 4% 15°
Frequency! . a IO 45 120 210 252
Groups . . a ie b c a € i
Temperature . . I a” wa’ 29” 20°
Frequency? . . 210 120 45 10 I

Groups . 5 a: §2 h 2 7] k

Suppose, on the other hand, that the relation between the
jength A and temperature (between 10° and 20° C.) is expressed
by the following table 2 :—

Length 4, (for instance, a cm.) coincides with 10° and 20° C.

ced A, ( ” ” ) ”? 11° ” 19° C.
” rg ( » ” ) ” 12° a”? is” C.
a” Ag ( ” 7s ” ) ” 13° ” 17° C.
a” Axo ( 2» 14 ” ) a” 14° ” 16° C.
” Aq ( ” I5 ” ) ” I5° (= 6°)

From the above figures the following variation curve (curve
of frequency) of 4 is deduced :—

Length Groups Frequency
A, (lIocm.) a+k= 1+ I= 2
A, (IZ ,,) &+7= IO+ IO= 20
Ag (12 4) C+t= 45+ 45= go
Ag (13. ,,) @&+h=1204+120= 240
Ay (14.4, ) @€+¢=210+2I0= 420
(Au =) Au (15 ” ) j= 252

Total 1024=21° specimens

This curve is asymmetrical: the most frequent value 4,,
(14 cm.) is the length of the spikes which have been developed
either at 14° or at 16°C. The arithmetical mean of 4 is 13-77
cm. It may be possible to express (in a rather complicated
way) the relations between the mean value and the data. The
latter are: (xz) the variation curve of temperature (absolute
values and frequencies) ; (2) the values A,, 4, ... and the
curve which expresses the relation between these values and
the temperatures between 10° and 20° C.

In the present state of biological science, however, the
problem is insoluble, because we have no exact information

1 Number of specimens (total 1024).

? Proceeding in Fig. 25 from both limits #° and T° towards the highest ordi-
nate, we meet on each side successively the values Ay, A, .. . Ay. The
length A, (practically 0) coincides with the critical temperatures 2° and T°.

The length \, coincides with two temperatures (see Fig. 25) which are nearer
the optimum (6°), etc. The length \,, (=A) coincides with 6°.
MEASUREMENT OF VARIABLE PROPERTIES 171

about the data. The figures which I have taken are more or
less approaching to reality; they are, however, arbitrary. In
any case, the arithmetical mean is here, for the biologist, an
empirical value.

Second Eventuality ; The limits of temperature are supposed
to be 11° and 21° C. (6° =15°). The frequencies of temperature
are given by the following curve (according to (4 + $)*°) :—

Temperature . ~ TE’ rt <3? a4? 15° 6"
Frequency? . 3 -£ 10 45 120 210 252
Groups . i . Ob c ad G } g
Temperature . . I7° 8° Ig? 20° az”
Frequency! . . 210 120 45 10 I
Groups . ‘ _ ih t ] k l

The variation curve of the primordium » is given by the
following Table (the relation between 4 and temperature being
the same as in the first contingency, and the length of the
spike at 21° being 4;=9 cm.) :—

Length Groups Frequency
A, (9cm.) l= I
A, (10 ,, ) k= Io
A, (Ir ,,) B+7= I+ 45 46
Ag (12 ,,) ¢+t= 10+120 130
Ay (13 ,,) d@t+h= 454210 255
Aw (14 5) €+¢=1204252 372
Aw(=Aqy) (15, ) {= 210

Total 1024 =2!° specimens

The curve is asymmetrical, yet distinctly different from the
preceding one. Arithmetical mean of A=13-52 cm.

The remarks about the mean value in the first eventuality
are also applicable here.

It is easily seen that an unlimited number of eventualities
are possible, since the most frequent temperature and the
extremes may coincide, in each peculiar case, with various
temperatures between the limits #? and T°. The form of the
variation curve of X (hump, mean value, etc.) depends, in each
series of measurements, on the prevailing conditions.2. The
observed figures (values of 4), and also the mean value, are an
indirect expression of the conditions of development (tempera-
ture), One single figure is invariable: this is the maximal
value of (I have supposed A»=15 cm.).3 This value will be

1 Number of specimens (total 1024).
2 In certain cases a unilateral curve might be obtained.
* About the minimal value of X, see below.
172 THE QUANTITATIVE METHOD IN BIOLOGY

discovered as often as the conditions under which the measure-
ments are made are various enough to include . It is a
constant of the race.

I have taken temperature as example. The same rule holds,
in general, for the various factors mentioned in the list, p. 167.
For each factor there are two limits and an optimum. We
know from experience, for instance, for the substances nitrogen,
phosphorus, potassium, etc., that the development of an
organism is impossible when they are not available in sufficient
quantity and that, on the other hand, too high a dose becomes
detrimental and even poisonous. Every gardener knows that
the development of many species (for instance, a number of
ferns) is impossible in a sunny place or in a place which is too
dry, and also when the intensity of light is too weak or the
watering too abundant; etc., etc.

The absolute values of the minimum, optimum and maxi-
mum (values m-o-M) of each factor (with reference to each
primordium and to the individual considered as a whole) are the
expression of properties of each living species. They are, how-
ever, variable within the limits of one species. The chief
cause of ¢hzs variability is the fact that the values m-o-M of
each factor are more or less modified by the variation of other
factors.

We know, for instance, that the optimal value of the tension
of carbon dioxide in the atmosphere depends on the intensity of
light. The m-o-M of temperature are modified (in an intricate
way) by the available quantity of water. Potassium, calcium,
phosphorus, etc., are absorbed by each species in certain pro-
portions: if the available quantity of one substance a (for
instance, potassium) is modified, the absorption of the others

b,c . . . 1s modified in its turn, and one would therefore expect
that any variation of a would result in a variation of the m-o-M
of 6,c. . . . Although our knowledge of the relations alluded to

is still incomplete, we may assume that they are very numerous
and intricate. Therefore the exact experimental determination
of the values m-o-M of a given cause (factor) with regard to a
given primordium of a given species is an exceedingly com-
plicated problem.?

In each specimen the numerous factors enumerated (p. 167)
are combined in a certain way. The diversity of the combina-
tions brings about variation of the primordia, each primordium
being variable according to its specific energy.

1 Perhaps with certain restrictions, which are unimportant for our subject.

? Physicists and astronomers are faced with questions which are almost
as involved as the biological problems alluded to. I recall the numerous
corrections which have to be made in order to deduce from the height of the

mercury in a barometer the exact pressure of the atmosphere. This is a
comparatively simple example.
MEASUREMENT OF VARIABLE PROPERTIES 173

We know that when a Jarge number of causes (factors) are
combined under the influence of chance, the intensity of each
factor being variable according to the law of chance (see tem-
perature, p. 170),1 and when no cause is predominant, the fre-
quency of the combinations is, when all is said and done,
governed by the law of chance which also governs the errors
of observation and finds its expression in the curve of errors
(Fig. 18, p. 146).

When a certain primordium is measured in a number of
specimens of a given species taken at random in the state of
nature, each figure is the expression (the measure, as it were)
of a certain combination (resultant) of ALL the factors which
are the components of the conditions of development. It may
therefore be expected that the observed variation would be
expressed by a one-humped symmetrical curve similar to a
curve of errors (or the variation of the prisms, Fig. 24, p. 161).
This is actually often (not always) the case.?

In a biological variation curve (whatever its form may be)
the arithmetical mean is not a constant of the species. It is,
just as any of the observed individual values, a physiological
measure of a certain combination of factors. It is not the
expression of a simple something. It is impossible to decom-
pose each observed value into a constant + an error. The very
same causes which produce variation bring the measured pri-
mordium into existence. (Compare § 108, p. 147, and § 116,
p. 162.)

It is, moreover, impossible to determine exactly the MEAN
VALUE of a variable property of a species. I take as example
Poa annua and suppose that I wish to determine the mean
length of the axis of its panicle. If a number of specimens are
collected from a dry, waste place, a wood (shadow), the banks
of a stream (humid and sunny), walls or rocks, etc., a different
mean value is obtained from each series. A comparison
between the mean values is simply a comparison between the
conditions of existence in the mentioned localities. If an
arithmetical mean were calculated from all the series con-
sidered as a whole, the obtained figure would depend, of course,
on the number of specimens of each series; it would be an
arbitrary and undecipherable something which would be modi-
fied by each new observation.

The MAXIMAL VALUE is, on the contrary, a strictly deter-

1In the case of living beings each factor is not only variable from one
specimen to another, but also continually varying through the whole period
of development of each specimen.

2 Asymmetrical curves in which the mean does not coincide at all with the
hump are common. When certain values of the measured primordium are
more easily realized than others because of a certain specific energy, the varia-
tion curve deviates from the typical form. (See Part VII., variation steps.)
174 THE QUANTITATIVE METHOD IN BIOLOGY

mined specific constant. Suppose the panicles of a number of
specimens, collected from various places, have been measured,
and that the longest one has a length of 119 mm.!_ This value
is the measure of the greatest possible length which the living
mixture of Poa annua is able to produce when the combination
of all the external factors is as favourable as possible ; in other
words, when the resultant of the combined factors is optimal.
Since the maximal effect of each factor (considered separately)
does not coincide with its maximal value, but with its optimum,
the effect of any combination whatever cannot exceed a certain
determined maximum.

This conclusion is confirmed by daily observation.

We know from experience that a given property of a given species never
exceeds a certain value. The length of a leaf of Quercus pedunculata, the
number of marginal teeth of a leaf of Castanea vesca, the number of cells of a
hair on the leaves of Primula sinensis, the length of the tibia of a horse or the
tail of a cow, the weight of a potato, the breadth of a petal of Ranunculus acris
never exceed a certain figure, however favourable the conditions of existence
may be, whatever may be the efforts of the gardener or the breeder.

When a vegetable species is brought under CULTIVATION
it often happens that the new combination of external factors
is, on the whole, nearer the optimum (with regard to a given
property) * than the combination which is the most frequent in
the state of nature. The mean value may therefore be aug-
mented, and it is also possible that the highest observed value
becomes greater. I think, however, that if numerous wild
specimens collected from a wide area and developed under
various conditions had been measured, the obtained maximum
would be hardly or not inferior to the maximum which might
be obtained from cultivated specimens. In this question, any
conclusion drawn from a mere impression must be distrusted :
it is only by measuring each primordium separately that exact
information can be obtained. (Compare § 23.)

When the maximum of a primordium has been determined
by the measurement of numerous (wild and eventually culti-
vated) specimens, it is possible that a higher maximum is found
by more observations. In this occurrence the specific constant
is to be corrected, and this may be repeated several times.
Many physical and chemical constants have also been corrected
step by step. After each correction of a biological constant
we ave brought nearer exactitude, and the probability of a new
correction and its probable importance become smaller. At

1 This is the figure I have found. According to J. D. HOOKER, the maxi-
mum is 3 in-=76 mm.

2It is possible, of course, that the reverse happens if the conditions of
existence are less favourable under cultivation than in the state of nature.

’ Because we are approaching more and more the extremity of the curve
of frequency (Fig. 24).
MEASUREMENT OF VARIABLE PROPERTIES 175

the end the error will be as small as the unavoidable errors of
measurement.

In order to discover the extreme values (maximum and
minimum) of a primordium it is not always necessary to
measure very numerous specimens. The value of many pri-
mordia may be roughly estimated without any instrument. In
all such cases we may content ourselves with collecting and
measuring, among a large number of individuals (in each
locality or spot), the specimens which approach the limits.

§ 120a—MINIMAL VALUES.—The minimal value of a
primordium may be looked upon, with certain restrictions, as
being a constant of the species. The lowest value of a pri-
mordium # coincides with the most unfavourable (pessimal)
combination of external factors under which its existence is
possible. The resultant of the pessimal combination is, of
course, a critical value, just as the limits of each factor con-
sidered separately. (See p. 168.) On the other hand, the
value of # at the beginning of its development is ordinarily
very small, practically not different from zero. If the prevail-
ing combination of factors is only a little better than the pessi-
mum, the growth of # is stopped in a very early state, when its
value hardly exceeds 0. If the combination of factors is more
unfavourable than the pessimum, # does not come into exist-
ence, which is expressed by the value 0. In both cases the
value of ~ is practically 0. This value being the same for very
numerous primordia of innumerable species, the minimal
value of a primordium is, ix general (no restrictions being
made), deprived of any specific significance.

This conclusion is confirmed by the observation of facts.
I take as FIRST EXAMPLE the length of the limb of the
leaf in Castanea vesca, Fagus silvatica and Betula alba. The
maximal values are distinctly different and characteristic of
each species. In the three mentioned species the limb of the
smallest leaves is very short, and since the three minimal values
converge towards the same limit (which is 0), these values are
not characteristic.1

I take the height /# of the stem of the rye as SECOND
EXAMPLE. In the ripe seed / is, as it were, infinitely small
(compared with its maximal value, which is 2 metres or there-
about). In the course of the germination and later on & in-
creases, passing through a series of successive values hy, hy, hg.
. . . Its growth may be stopped in any state whatever of its
development, when the value f,, or hy, or hg . . . is reached.
Since many (practically all) other Graminee@ (for instance, Poa

1 The smallest leaves are to be looked for a short time after the buds have
expanded because they often disappear later on.
176 THE QUANTITATIVE METHOD IN BIOLOGY

annua, Phleum avenariunt, etc.) behave in the same way, the
minimal value of # converges towards the same limit (practic-
ally o) in each and all, just as in the above example of the
leaves. Therefore the terms minimal height of the stem, without
more, represent an indeterminate notion.

Remark : The facts alluded to may be actually observed as often as a limited
area is crowded with seeds of the same species. The growth of the young
plants is stopped when their stems are still very short (and sterile). The same
experiment being carried out with several species (each of them separately),

no perceptible ‘difference is observed with regard to the minimal value of h.
I have carried out the experiment with rye, Poa annua and Phleum avenarium.

Certain CONVENTIONS (restrictions) being made, however,
the minimal value of a primordium may be looked upon as
being a characteristic specific constant.

The aspect of the question is changed, indeed, if we take a
given primordium under certain definite conditions; for in-
stance, the height Af of the ferizle stem of a grass. The exis-
tence of a fertile stem is only possible when the variation of the
conditions of existence (combined factors) is included within
certain limits which are different according to the species, and
narrower than the limits between which the development of a
stem i general is possible. Therefore the minimum of Af is
not the minimal height of a stem im general, but the peculiar
minimum which may occur when the conditions of fertility of
the species are prevailing. Therefore the minimum of Af is a
specific constant.

In a similar way the minimal values of various primordia of
animals and plants are specific constants.

Examples: The length, breadth and other primordia of the longest leaf of
a fevtile stem of an acrocarpic moss; the length and other primordia of the
longest petal of a flower ; the number of flowers of an inflorescence ; the length
of an antenna, a wing and other parts (segments) of an insect; the primordia

of an animal or a vegetable embryo in a state of development coinciding with
a given value of the leading property (see § 49), etc.

§ 1208.—RELATION BETWEEN MEAN VALUE AND
VARIATION STEPS.—The arithmetical mean of a series of
measurements has, in general, only an empirical significance.
It may happen, however, that a mean value coincides with one
of the terms of a series of variation steps. In this case the
mean value is the expression of a characteristic state of equi-
librium, and is really a constant of a peculiar kind. (See Part
VII., especially § 127.)

§ 121—USEFULNESS OF MEAN VALUES FOR COM-
PARING TWO OR MORE SERIES OF MEASUREMENTS.—
One single mean value, taken alone, is a rather vague piece of
information; if we ascribe to it a definite significance we
MEASUREMENT OF VARIABLE PROPERTIES 177

are in danger of being deceived. In certain cases, however,
a comparison between two or several mean values obtained
under definite conditions may render good service.

Example: Wheat is cultivated on two fields A and B, all the
conditions of existence being as exactly as possible the same for
both 1—in such a way that the variation curve of any given
property of the wheat would be the same on A and B. A
certain quantity of potash manure is added to B. When the
wheat is ripe, one of its properties—for instance, the length of
the spike—is measured. If any difference exists between the
mean values of A and B it may be considered as an indirect
measure of the influence of the added potash.

In general, it may be said that a comparison between two or
several mean values gives useful information as often as the
series of measurements have been collected under conditions
which were different only with regard to one factor.

According to this principle, I use the mean values for the in-
vestigation of the gradation curves, the varying factor being
here a social cause. (See Part VIII.) Ina similar way I have
used mean values for the investigation of the growth of certain
properties of a mixture (§ 114, pp. 155 and 157), the varying
factor being here the age of the measured specimens.

1In other words, the same series of combinations of factors with the same
frequencies prevailing on both fields.
PART VI

VARIATION STEPS

§ 122—EXAMPLES OF VARIATION STEPS: PEDI-
ASTRUM, PERISTOME OF MOSSES.—In Pediastrum (§ 64)
the segments (cells) of an adult specimen (cenobium, Fig. 3,
p. 79) are 2, 4, 8... 2% in number. The same series of
values is observed in the number of teeth of the peristome of the
mosses. These values are the expression of certain states of
equilibrium (see, for instance, § 66), which are more probable
(more stable?) than the intermediate values. I call them
variation steps.

Although attention has been repeatedly called to this subject,
especially by LUDWIG and also, among others, by DE
BRUYKER, WASTEELS, DE VRIES, VERSCHAFFELT
and myself, its importance has not yet been realized by the
great majority of the biologists,

In general, when a given property passes through a series of
values, if certain values a’, a”, a’ are observed more frequently
than the intermediate values, the terms a’, a’, a’ . are
variation steps. Between the values a’, a”, a’” . certain
arithmetical relations exist.

§ 123—DIVERSE SERIES OF VARIATION STEPS.—
Several series of variation steps have already been discovered.
I limit myself to five examples ?!:

(1) The Fibonacci series (discovered and thoroughly investi-
gated by LUDWIG), which consists of the terms 1, 2, 3, 5, 8, 13,
21, 34. . . . Each term is the sum of the two preceding terms,
the first terms being 1 and 2. Examples are very numerous ;
for instance, the number of marginal florets in many species of
Corymbiferous Composite. This series seems to exist also in
the animal kingdom (LUDWIG); for instance, in certain
properties of the shells of many Mollusca (Pecten, VAN DER
GUCHT ; Scalavria, MACLEOD and WASTEELS, etc.).

(2) The sertes 3, 5, 7... (uneven numbers). Example:
the number of leaflets of digitate leaves in many plants; for
instance, in Trifolium pratense quinquefolium (discovered by
DE VRIES).

(3) The sevtes 5, 10, 15... (multiples of 5). Example :

1 My notes are not within my reach.

178
VARIATION STEPS 179

the number of styles in a race of Geranium with numerous styles
(discovered by DE VRIES). (See § 131.)

(4) The serves 3, 6, 9 (multiples of 3). Example: the number
of stamens in many Monocotyledons; for instance: I7is, 3;
Lilium, 6; Butomus, 9. The valuesi,2...4,5...7, 8

... 10, II... are uncommon, rare or very rare in the
androecium of the Monocotyledons.
(5) The series 2, 4, 8, 16, 32 . . . (powers of 2). Examples:

number of cells in Pediastrum; number of teeth of the peri-
stome of the Mosses.

REMARK: Certain values belong to more than one series; for instance -
the value 3 belongs to the series 1, 2 and 4; the value 5 belongs to the series
I, 2 and 3; the value 8 belongs to the series 1 and 5. (See § 126.)

§ 124—_VARIATION STEPS OF THE FIRST, THE
SECOND AND THE THIRD DEGREE.—Several degrees are
observed in the frequency of the characteristic terms of a given
series of variation steps compared with the frequency of the
intermediate values. I discern three degrees of frequency,
between which all possible transitions exist :

Variation steps of the first degree—The characteristic terms
of the series under consideration exist alone, the intermediate
values being very rare (or practically never observed). Ex-
ample: genus Senecio. In Senecio nemorensis, subspecies (?)
pentaglossa (ordinary form, province Luxemburg, Belgium),
the marginal florets are 5 in number. In a subspecies (?) which
I have found in Belgium, and which might be called Sen. nem.,
subsp. triglossa (if not yet described), the number is 3.4_ In
Sen. nem., subsp. (?) octoglossa (mentioned in Switzerland) the
number is 8. In Senecio jacobea (Flanders) the number is 13.
In these examples the observed figures (3, 5, 8, 13) belong to the
Fibonacci series. According to my (very numerous) observa-
tions, the_above-mentioned figures 3, 5 and 13 are almost in-
variable in each of the corresponding specific forms, and,
according to floristic data this is also the case with figure 8 in
subsp. octoglossa.* The figures 2, 4, 8, 16... in the peri-
stome of the Mosses, the step values 3, 6, 9 im’ the andreecium
of many Monocotyledons are probably almost always of the
first degree. (That is to say, invariable or almost invariable
in a given specific form.)

Variation steps of the second degree—The transitory values

1 This subspecies is very abundant in a wood about 1 kilom. north from the
station Poix St Hubert (province Luxemburg), east from the railway.

2 In the British Islands, the number of marginal florets varies in S. nemorensis
between 5 and 8 (seldom more than 6 or 7). (BENTHAM, British Flora, 1866,
PP. 254-256.) According to LUDWIG (Botan. Centralblatt, vol. lxiv., 1895,
Pp. 100) the typical values in the mentioned species are 3 and 5, the figure 5
being predominant.
180 THE QUANTITATIVE METHOD IN BIOLOGY

between the variation steps are rather common, but distinctly
less frequent than the characteristic step values. Examples:
number of leaflets in Trifolium pratense quinquefolium: the
figures 3, 5,7. . . are predominant ; leaves with 4, 6,8, ...
leaflets being less numerous, although not uncommon (DE
VRIES). In Chrysanthemum segetum (number of marginal
florets) the Fibonacci terms 13 and 21 are much more frequent
than the transitory values (DE VRIES). This is also the case
with the number of marginal florets in many other Composite
(LUDWIG). For instance, in Chrysanthemum carinatum the
terms 5, 8, 13 and 21 are distinctly predominant (DE
BRUYKER and myself).

Variation steps of the third degree—Here the limits of varia-
tion coincide more or less exactly with two characteristic terms
of a series, the most frequent value being one of the transitory
values. Example: the number of marginal florets in the
terminal flower-head of Centaurea cyanus}: the most frequent
value is about Io or 11 (under ordinary conditions of existence).
Starting from this maximum the frequency of the flower-heads
decreases in the positive and in the negative sense till the values
8 and 13 are reached. Below and above these limits there is a
sudden decrease in the frequency: flower-heads with >13
marg. florets are uncommon and such with <8 marg. florets
are rare. The variation of the property under consideration
oscillates, as it were, between two limits which coincide with two
variation steps. I think that numerous examples of the third
degree will be discovered as soon as more attention is paid to
this subject.

§ 125—SYMMETRY AND VARIATION STEPS.—Many
biologists look upon the Fibonacci terms and the other series
mentioned in § 123 as being merely the expression of certain
states of symmetry. (This view is not a sufficient reason to
overlook the whole subject.)

In the case of Pediastrum and Euastropsis (number of cells:
series 2, 4,8... 2" See §65) the observed figures are not a
consequence of symmetry, since they are determined before the
cells meet one another, thus before any symmetry exists with
regard to their relative position. In a bicellular specimen of
Euastropsis the bilateral symmetry is a state of equilibrium
which depends on the fact that two independent cells meet each
other. Similarly in Pediastrum tetras, the radial symmetry
depends on the fact that four cells meet each other and are
united into a system of equilibrium which has the form of a

1 Specimens with blue flowers collected in ryefields in Flanders. Specimens
with blue and specimens with purplish flowers (subspecies atropurpurea)
raised from seed which was obtained from HAAGE and SCHMIDT in Erfurt.
VARIATION STEPS 181

rectangular cross. In these examples, the observed symmetry
is secondary, the number of segments is primary. }

Between symmetry and variation steps certain relations may
exist and probably really exist. In certain examples symmetry
may be the cause of the variation steps; in other examples
symmetry is rather the effect, the variation steps being the
cause. It is impossible to express the relations alluded to in
one short sentence. .

This subject is in relation with very delicate morphological
problems. Morphological homology, mechanical concordance
(§ 65) and variation under the influence of external causes
(plasticity) ought to be taken into account; the distinction
between hereditary possibilities and observable properties must
be borne in mind.

§ 126—THE SIGNIFICANCE OF AN OBSERVED VALUE
DEPENDS ON THE SERIES TO WHICH IT BELONGS.—
In Senecio nemorensis, subsp. octoglossa, the marginal florets are
8 in number. Here the number 8 is a term of the Fibonacci
series, for other terms of this series are observed in other species
of Senecio (§ 124) and in other Composite. In Epilobium and
Fuchsia 8 stamens exist; here the number 8 is a term of the
series 2, 4,8 . . . 2”, for this series is observed among the Ona-
gracee (Circea, Lopezia, 2 stamens; Eucharidium, Isnardia,
4 stamens; Hauya, Clarkia, Gnothera, Epilobium, Fuchsia,
8 stamens). From these examples (see also § 123, Remark) it
may be concluded that the significance of a given value depends
on the series to which it belongs, as often as variation steps are
at play.

In other words, the series of steps through which the value
of a given property passes is the quantitative expression of
a certain specific energy of this property. Therefore the value
8 is the expression of different specific energies in Epilobium
and Senecio.

This is of the highest importance with regard to the study of
heredity and variation. (See§131.) See, in § 132, the methods
for discovering the series of variation steps to which a given
value belongs.

§ 127—A MEAN VALUE WHICH COINCIDES WITH A
VARIATION STEP MAY BE LOOKED UPON AS BEING
A CONSTANT.—In a biological curve a mean value which does
not coincide with a variation step has not the significance of a
constant. It is not the measure of something which has an
independent existence, and it is therefore quite different from
the mean value of a curve of errors. (See § 108.) Such a
biological mean is merely an indirect measure of the conditions
182 THE QUANTITATIVE METHOD IN BIOLOGY

of development of the measured specimens. A comparison
between two mean values is, in reality, a comparison between
the conditions of existence of two groups of specimens. (See
§ 120.)

EXAMPLE: In Mnium hornum the length of the longest leaf of the fertile
stem varies between 5°17 and 8:06 mm. These figures are specific constants.
If a certain number of specimens collected from one spot are measured, the
extremes may be, for instance, 5°50 and 7:00, the mean being 6:25 mm. A
second series of specimens, collected from a second spot (even in the same
locality) may give : extremes 6 and 7'50, the mean being 6°75 mm., etc. Since
no variation steps exist in the property under consideration, the mean values
obtained (and also the extremes in each series) depend on the conditions of
existence. These conditions are more or less variable from one spot to
another.

When, on the contrary, a biological mean coincides with a
variation step, it is really the measure of a definite something,
of a specific energy which exists in the measured property,
independently of any external cause. Such a mean value is
(for the naturalist) comparable with the mean of a curve of
errors: it is a constant.

EXAMPLES: Variation steps of the first degree. In Senecio jacobea
the number of marginal florets is almost always 13 (Fibonacci term) ; the
figures 12 and 14 are very rare. Series of specimens collected from various
spots and various localities always give the mean 13. This mean is a con-
stant. It may be surmised that many properties of animals and plants, which
are practically constant in a species or a genus, are in reality variation steps
of the first degree of a certain series.

Variation steps of the second degree. I have cultivated Chrysanthemum
cavinatum in several series under various conditions of existence. In one of
the series, the variation curve was comparatively symmetrical, the most
frequent value (hump of the curve) being 21 (Fibonacci term). The mean
value was, approximately, 21. Such a coincidence between the mean and a
variation step is rather rare when the steps are of the second degree.
Ordinarily the mean coincides approximately with one of the transitory values
between two steps. In Chrysanthemum segetum, DE VRIES obtained the
ae variation curve (number of marginal florets of the terminal flower-

ead 1) :

Florets . » 12 13 14 15 16 17 18 I9 20 21 22
Specimens . 1 14 13 4 6 9 7 10 312 20 1

The arithmetical mean is 17°5. The curve is two-humped (dimorphic) :
the humps coincide with the variation steps 13 and 21 and represent there-
fore ci whereas the mean has no definite significance. (See also
§ 129.

Variation steps of the thivd degree. In Centaurea cyanus (under ordinary
conditions of existence) the variation curve of the number of marginal florets
of the terminal flower-head is one-humped, the hump coinciding with the
values 10 or 11, the mean coinciding almost exactly with the hump. In
reality, the mean is intermediate between two variation steps 8 and 13, which
are indicated by a sudden falling of the curve between 7 and 8 and between
13 and 14. The mean does not represent a constant: it is, however, influ-

 

1 Archiv fiir Entwickelungsmechanik, Bd. Il., p. 52, 1896. (Quoted after
VERNON, loc. cit., p. 50.) I have obtained several similar curves for Chry-
santhemum carinatum. Unfortunately the figures are not at my disposal.
VARIATION STEPS 183

enced in acertain degree by the existence of the variation steps. The curve is
governed not only by the laws of chance; it is also under the influence of the
specific energy which finds its expression in the variation steps.

If we compare the examples given in this paragraph, we see
that in the case of Mnium the mean is merely a product of
chance ; in Senecio the influence of a specific energy is quite
predominant ; in Chrysanthemum the latter influence is less
important ; in Cevtaurea? it is still more in the background.
It is, moreover, quite thinkable that variation steps might
be still more concealed than in the case of Centaurea, their
influence upon the mean and upon the form of the curve being
still smaller. In the present state of science, we must content
ourselves with a rough estimation of the influence alluded to.
We may, however, anticipate the possibility of calculating it
exactly.

However skilful and subtle the mathematical methods used
in biometry may be, biological errors may be committed in the
interpretation of a mean value if the eventual existence of
variation steps is not taken into account.

OTHER EXAMPLES: Professor PEARSON counted the number of
stigmatic bands on the 4443 seed capsules obtained from 176 Shirley poppies

growing in a single garden, and found the following frequencies (Pearson,
Grammar of Science, 2nd Ed., p. 443. Quoted after Vernon, p. 89) :—

Bands. : 5 6 7 8 9 10 Ir 12
Frequency : I II 32 56 148 363 628 925
Bands. ‘ 13 14 15 16 17 #18 19
Frequency - 954 709 397 155 51 12 1

Professor PEARSON counted the segments on 3212 fruits of Negella
hispanica, and found the following frequencies (loc. cit.) : —

Segments ‘ 2 3 4 5 6 a 8 9 10
Frequency . 10 7 20 303 412 534 1552 223 59
Segments II 12 13 14 15 16 ry 18 19; 20.
Frequency 35 43 6 —- — 6 —- — — 2

In both curves the material is not homogeneous. Terminal fruits and
lateral fruits of successive order being brought together, the influence of
gradation (social cause, see § 128) has been overlooked. In other words,
there is no social equivalence among the material.

In spite of that, the most common form coincides in each curve with a
variation step (respectively 13 and 8) which belongs here to the Fibonacci
series. Therefore the hump of each curve may be looked upon as being a
constant.

The mean values (12°51 and 7°46) coincide approximately with the most
frequent values. In reality, however, the mean values (if not compared with
the humps) are here a vague expression of the conditions of existence of the
examined plants. According to my observations, the number of stigmatic
bands in Papavey (poppy) is very variable according to the conditions of life,
and this is undoubtedly also the case in Nigella.

§ 128. — RELATION BETWEEN THE VARIATION
STEPS AND THE CONDITIONS OF EXISTENCE. TRANS-
1 By counting the ribs of the shell of Scalavia communis (more than 1000

specimens, Flemish coast) a variation curve was obtained more or less similar
to that of Centaurea cyanus (MACLEOD and WASTEELS).
184 THE QUANTITATIVE METHOD IN BIOLOGY

FORMATION OF A MONOMORPHIC CURVE INTO A
DIMORPHIC OR A POLYMORPHIC ONE BY EXTERNAL
CAUSES.—When variation steps exist in the series of possible
values of a certain property #, it may happen that a
monomorphic (one-humped) curve is obtained under certain
conditions of existence, whereas the curve is dimorphic or
polymorphic under other conditions without any change in
the hereditary properties.

EXAMPLE: I have cultivated Chrysanthemum carinatum
in several groups, the conditions of existence being more and
more unfavourable from the first group to the last one!: the
first group under ordinary conditions in a garden, the intervals
between the specimens being rather large; the second group
in the same soil, the intervals being too small to allow a full
development of each specimen, etc.

The marginal florets of the ¢eyminal flower-head were counted
in all the specimens.” In the first group the variation curve
was somewhat regular, with a distinct hump coinciding with
the value 21. In the second group the hump coincided with 13 ;
in the next groups the summit passed through the values 8, 5.

. In certain groups two humps (belonging to the series 3, 5,
8, 13...) were observed, with a depression between both.
In this experiment the variation of the measured property and
the succession of the steps (Fibonacci terms) was, of course, a
consequence of plasticity. There was no specific hereditary
difference between the groups.

The specimens of the first group produced a number of
flowering branches; flowers were abundant for a period of
about ten weeks. About a fortnight after the terminal flower-
heads had been investigated, a second group of flower-heads
produced by lateral branches were observed in their turn, and
so on, several successive groups of flower-heads being taken
with intervals of about a fortnight. The successive curves
were different from each other in the same way as the curves
of the teyminal flower-heads of the groups cultivated under
different conditions. The successive summits coincided with
the Fibonacci terms, the order of decrease being 21 (terminal
heads), 13, 8, 5, 3 from the beginning to the end of the flower-
ing period. In certain curves two humps coinciding with two
successive terms were observed. The successive appearance
of the Fibonacci humps depends here on a social cause—1.e.
gradation. (See Part VIII.)

1 This experiment was carried out in the Botanic Garden at Ghent with
the collaboration of J. V. BURVENICH. The seeds were obtained from
HAAGE and SCHMIDT, Erfurt. The subspecies cultivated was characterized
by simple flower-heads; marginal florets white, central florets brownish.

? The property mentioned here is of the second degree.
VARIATION STEPS 185

Similar experiments were carried out by DE BRUYKER, on
the whole with similar results. :

In the Corymbiferous Composite the number of marginal
florets may pass through a long series of values, let us say from
o to 100 (and still more). When the variation of this property
is observed :

(x) Within the limits of a complex species (Senecio nemor-
ensis, § 124) or a genus (Senecio, § 124);

(2) In one monotypic species under the influence of plasticity ;

(3) In one monotypic species under the influence of gradation,
the rule is always the same. The Fibonacci terms are always
predominant (if they are of the first or the second degree),
coinciding with the humps of the curves.

Adopting the view that any value whatever of the property
under consideration corresponds to a state of equilibrium (§ 43)
I conclude that the Fibonacci terms are the expression of states
of equilibrium which are more stable ! than those expressed by
other values. The Fibonacci terms are, therefore, the expres-
sion of a certain mechanical predisposition which is a specific
energy of the property. This conclusion is applicable on any
series of variation steps whatever. (See § 123.)

Two more conclusions may be drawn from the above obser-
vations :

(1) The existence of a two- (or more) humped variation curve
does not give proof of the existence of different subspecies
(races) in the material (§ 130). In other words, dimorphism or
polymorphism of a curve may depend on the existence of varia-
tion steps without any complexity. This remark is applicable
on certain curves, from which the coexistence of different sub-
species or races has been deduced, without any information
about the specific energies of the measured property.

(2) A monomorphic (one-humped) vatiation curve may be
transformed into a dimorphic (or polymorphic) one by a simple
change in the conditions of existence—if variation steps are at
play. Therefore, when the variation curve of a given property
of a given species is one-humped in a first country (or locality),
and two-humped in a second country (or locality), we are not
allowed to conclude without more information that the species is
monotypic in the first case and complex in the second case.

In Primula elatior the number of flowers of the so-called
umbel is very variable, with distinct variation steps which coin-
cide with the terms 3, 5, 8 . . . (Fibonacci series). Dr DE
BRUYKER has observed that specimens collected from dry
spots give a variation curve in which the lower terms (3 or 5, or
both) are predominant, whereas specimens collected from wet
spots in the same locality show a distinct predominance of the

1 T discern three degrees of stability (§ 124).
186 THE QUANTITATIVE METHOD IN BIOLOGY

higher values (5 or 8, or both). Here the influence of the con-
ditions of existence is as indubitable as in the above-mentioned
experiments with Chrysanthemum carinatum.

LUDWIG! has studied the variation of the number of
marginal florets in Chrysanthemum leucanthemum. Series of
specimens collected from certain localities showed the 13-floret
form to be the commonest, whereas the 34-floret form was
predominant in other localities. It would be premature to
conclude from these facts, without more information, that two
different subspecies (hereditary races) exist among the material
collected by LUDWIG (§ 130).

§ 129. — INFLUENCE OF SELECTION UPON THE
VARIATION STEPS IN CHRYSANTHEMUM SEGETUM.
—DE VRIES sowed the mixed seed of Chrysanthemum segetum
obtained from twenty different botanic gardens. The terminal
flower-heads of each of the ninety-seven healthy plants obtained
were examined, and were found to contain the following numbers
of marginal florets 2 :—

Florets . . 12 13 34 15 16 17 18 Ig 20 21 22
Specimens . I I4 13 4 6 9 7 IO I2 20 I

This two-humped curve (Fibonacci series of the second degree)
resembles certain two-humped curves of Chr. carinatum
obtained under unfavourable conditions or by examining
flower-heads of lateral branches. According to DE VRIES,
the observed discontinuity indicated the presence of two forms,
a 13-ray form and a 21-ray form. The seeds from 12- and 13-
Tay specimens were collected and sown next year, the terminal
flower-heads obtained therefrom having the following numbers
of florets * :—

Florets .. ‘ . . 8 9g IO It 32 13 14 15
Specimens. ‘ : - 2 FT 0 F 13 904 25 7
Florets ‘ : » 16 17 28 2G Zo 21 Be
Specimens . : ; , & T 2 O@ 3 oO oO

“ That is to say, all trace of the 21-ray form had been elimin-
ated and a nearly pure 13-ray form obtained. That this was so
was proved by sowing the seed of some of the 12-rayed plants
obtained on this occasion in the following year. It was then
found that the frequencies of occurrence of flowers with various

1 Quoted after H. M. VERNON, loc. cit., p. 47.

* Archiv fir Entwickelungsmechanik, Bd. II., p. 52, 1896. (Quoted after
VERNON, loc. cit., p. 50.)

It is worth noting that in this curve the limits coincide approximately with
two variation steps, just as in Centaurea cyanus. (See § 127, p. 182.)

° Here the limits coincide once more almost exactly with two variation steps.
VARIATION STEPS : 187

numbers of rays remained practically unchanged”’ (VERNON,
loc. cit., p. 51).7 . :

On the other hand, DE VRIES, “starting in 1896 with
plants which had 21-ray florets occurring most frequently in
their capitula, and none of which had more than 23 florets,
picked out each year the two or three plants richest in florets
for breeding with, and sowed their seed the following year. In
1897 a single flower was obtained, having 34 florets, but the
21-floret form was still the commonest. In 1898 one of the
flowers had 48 florets, the commonest flowers now having 26
or 34 florets. In 1899 one had 67 florets, the commonest form
having 26 or 33 to 35 florets, and in 1900 one had ror florets,
the commonest form having 47 florets.” (VERNON, loc. cit.,

. 63.

I nk it would be premature to conclude from the above
very important experiments that two hereditary forms (sub-
species ?, pure lines ?) were mixed in the original group of 97
specimens. It may be surmised that the results of selection
have been influenced by the existence of variation steps—?.e. by
a specific energy of the examined property.

The differences between the 97 original specimens were
probably produced by two groups of factors: (1) differences in
the conditions of existence (of the specimens) which are un-
avoidable (plasticity) ; (2) differences in the quantitative com-
position of the living mixture (§ 8A).?

Selection being carried out, specimens of different quantzta-
tive composition have been picked out and isolated, the differ-
ences being increased (within certain limits) by continued
selection. The progress (in respect of the observable property),
instead of being gradual (by impalpable changes) has been very
vapid, proceeding, as it were, by jumps, because of the existence
of variation steps.

In other words, in this example each of the figures 13, 21, 34,
etc., considered in itself is not an hereditary property of the
species or of one or another subspecies (race, form, etc.), but
what is transmitted by inheritance is the specific energy,
expressed by a Fibonacci series of the second degree.

§ 180 —VARIATION STEPS, DISCONTINUOUS VARIA-
TION AND SPECIFIC DIFFERENCE.—Two given species
(subspecies, etc.) are always strictly different by the qualita-
tive composition of their living mixture and therefore by their

1 Taking ONLY the figures into account, it may be remarked that selection
has resulted here in a change of the curve similar to the changes produced in
Chr. carinatum by modified conditions of existence or by gradation (§ 128).

? The latter differences being themselves a consequence of differences in the
conditions of life of the parents, for the seeds were obtained from twenty
botanic gardens, thus from various countries.
188 THE QUANTITATIVE METHOD IN BIOLOGY

hereditary possibilities (possible primordia). In the variation
of a given primordium continuity or discontinuity may exist
within the limits of a complex group of specimens (including
two or more specific forms), just as within the limits of a mono-
typic group (including one specific form only). In § 21 I have
called attention to this fact. (See also § 128.)

Here a distinction must be made between primordia with
variation steps and primordia in which no variation steps exist.

I take as first example the length of the longest leaf of the fertile
stem in Mnium serratum, spinosum and undulatum. These
three species (Acrocarpic Mosses) are distinctly different and
easily recognizable. I have measured the mentioned prim-
ordium in a number of specimens collected from several
localities. No trace of variation steps could be discovered.
The limits of variation were (in mm.) :

Minimal Maximal
length length
Serratum ‘ : . . 2:49 4-71
Spinosum . ‘ 5 . 5:05 8-I0
Undulatum . ; : . 6:93 15°58

According to these figures, which are specific constants,!
absolute discontinuity exists probably between serratum and.
spinosum (the difference between 4-71 and 5-01 is, however, too
small to be decisive) and certainly between serratum and
undulatum. Between spinosum and undulatum continuity
exists, for 6-93 <8-I0.

The aspect of the question is completely changed when we
limit the comparison to series of specimens collected from
given localities.

We may find, for instance, in a locality A, for spinosum:
limits 5-20 and 7-60, mean 6-40; for undulatum: limits 9 and
13, mean 11. Between both variation curves discontinuity is
absolute.

In a second locality, B, we might possibly find, for spinosum
limits 6-93 and 8-10, mean 7-52; for undulatum the same
figures. Here both curves are identical.

Between identity and absolute discontinuity all possible
transitions may occur.

Ina third locality, C, indeed, the figures may be, for spinosum :
limits 5-50 and 8, mean 6-75 ; for undulatum : limits 7 and 10,
mean 8:50. Here transgressive variation exists ; in other words,
both curves overlap one another. This results in partial dis-
continuity.

In a fourth locality, D, we may find for spinosum : limits 6-30

1It is possible that these constants will be corrected later on, but this is
of no importance for our subject.
VARIATION STEPS 189

and 8-10, mean 7:20; for wndulatum: limits 6-93 and 9-Io,
mean 8-02. Here the difference between both curves is small.

Suppose now that the two species under consideration were
doubtful (critical) species, and that for each locality the collected
specimens were confused in one series of measurements, the
result would be: in A, two separate curves; in C,a two-humped
curve; in D, a one-humped asymmetrical curve; and in Ba
regular, symmetrical one-humped curve. If we limit ourselves
to one series collected from one locality, we are in danger of
being completely deluded: the curves obtained from the
localities B and D point to the existence of one species, whereas
the existence of two specific forms seems to be demonstrated by
the figures obtained from AandC. If the curves obtained from
the four localities were compared, we might perhaps be tempted
to believe that transitory forms between two species exist.

In reality, the differences between the four localities depend
merely on differences in the conditions of existence. Compare
Mnium hornum in § 127, p. 182.

From the above examples (and many others which may
easily be found) it may be concluded that continuity and dis-
continuity in various degrees may be observed in the variation
of any primordium whatever in a given group of specimens,
and that any conclusion about the existence of one or several
species among the observed material is questionable, if not
verified by other methods.

When variation steps exist in the investigated primordium
we are still move in danger of being deceived if we draw any
conclusion from a supposed relation between continuous varia-
tion and specific identity or between discontinuous variation
and specific difference, for a monomorphic (one-humped) curve
may be easily transformed into a dimorphic or a polymorphic
one by a simple change in the conditions of existence or under
the influence of gradation. See the examples of Chrysanthe-
mum and Primula in § 128, pp. 184 and 185.

Many attempts have been made in order to discover, by
means of the biometrical method, whether a given critical
species consists of one or several specific forms, and also in
order to find characteristic differences between two or more
allied critical species or between specimens of a given species
collected from various countries or localities. In the researches
alluded to much importance has been ascribed to the mean
values, the correlation constants and the form of the variation
curves.! Several authors are tempted to believe that a suffi-
cient degree of discontinuity in the variation curve of a given

‘This subject is expounded and illustrated by a number of examples in

VERNON, Joc. cit., chaps. ii. and x. Examples are also found in the review
Biometrika, passim.
190 THE QUANTITATIVE METHOD IN BIOLOGY

primordium indicates the existence of two specific forms.
Unfortunately, little attention, if any attention at all, has been
paid to the variation steps and the specific limits of variation
(minimal and maximal values).

I think that the application of the followed method to the
difficult problems under consideration is fruitless or at least
premature. ; ;

Scientific progress is obtained by proceeding from the simple
to the complicated. Very numerous specific forms of animals
and plants are easily recognizable : it is possible to investigate
them quantitatively, determining the constants (limits of
variation) and eventually the variation steps of numerous
properties for series of (not critical) allied forms ; for instance,
for series of species of one genus or allied genera.

In the higher forms of life, numerous measurable properties exist which
have been hitherto completely or almost completely overlooked. Examples :
Dr FRIEDRICH HEINCKE! has examined a number of so-called local
races of the herring in respect of about 25 different characters, and some in
respect of over 50 characters. I have measured 38 properties (characters)
in 90 species of Carabus and Calosoma—a dozen of properties of the leaves
of the mosses of the genus Mnium (see Part IX.)—and more than 25 properties

of the fertile stem, the leaves and the flowers of more than 25 species of
Graminee. (See Part IX.)

A complete and exact description of the species which are
DISTINCTLY CHARACTERIZED is, in the present state of
science, an attainable object of the quantitative method. It
may be expected that the description of a few hundreds of
species by means of figures will be sufficient to demonstrate the
value of the quantitative method for descriptive science. The
collected data will afford a base of comparison for the investiga-
tion of the critical species, the local races, etc. We will be,
however, very often compelled to have recourse for critical
specific forms to the experimental method (see § 17), the results
of the experiments being expressed by measurement.

§ 181.—RELATION BETWEEN THE VARIATION
STEPS AND CERTAIN QUESTIONS OF PHYLLOTAXIS.
PRIMULA OFFICINALIS, MYOSOTIS, GERANIUM,
ROSACEA .—In § 126 I have called attention to the fact that
the significance of a given value depends on the series of varia-
tion steps to which it belongs. In certain cases exact informa-
tion about the variation steps might perhaps throw any light
upon certain phyllotaxic and other morphological problems.

In Primula and Myosotis the corolla consists of five petals
and is ordinarily looked upon as being cyclic (verticillate). In
Geranium the gynecium is also pentamerous and described
as cyclic.

1 Quoted after VERNON, loc. cit., p. 322.
VARIATION STEPS 191

Let us see what information may be obtained from the
variation steps. ;

LUDWIG has counted the petals of 1170 flowers of Primula
officinalis which were all obtained from a single meadow (near
Wieda).1 The number varies from 1 to 22. The variation
curve has five humps, corresponding to 3, 5 (predominant), 8,
10 (5 x2?) and 13; the superior limit coincides almost exactly
with 21. From these observations it may be concluded that
the number 5, which is practically constant in the species, is
here a term of the Fibonacci series, and it may therefore be
surmised that the corolla of Primula is, in reality, spiral, the
divergence being ordinarily 2/5.

REMARK : For the observed facts three explanations are a priori possible :
(1) In the meadow where the flowers were collected certain peculiar conditions
of existence prevail by which a number of unusual reactions (expressed by the
humps of the curve) have been produced instead of the ordinary reaction
which results in the number 5—thus a modification similar to the changes
which I have observed in Chrysanthemum carinatum (§ 128, p. 184)—and
in general, similar to modifications produced by cultivation. It may be
surmised, moreover, that not only the number of petals, but also the angle of
divergence has been modified. (2) In the locality mentioned a peculiar sub-
species exists, characterized by the fact that the Fibonacci series of the first
degree observed in the ordinary form (the term 5 being invariable just as in
Senecio jacobea) has been transformed into a series of the second degree
(comparable to Chrysanthemum carinatum and many other Composite).
(3) In the mentioned meadow a mixture of several subspecies (pure lines ?,
taces) occurs. I look upon the latter explanation as being very improbable,
because it implies about half-a-dozen mutations in a single property.

In a certain species of Myosotis * a form exists which has
more than 5 petals ; the number is variable, the figure 8 being
predominant. Since 8 is a Fibonacci term we may conclude
that the ordinary figure 5 is also a Fibonacci term, and it may
be surmised that the corolla of Myosotis is spiral (divergence 2/5).

REMARK: The form of Myosotis alluded to may be looked upon as being
probably a subspecies because its characteristic feature is hereditary, even
when the plants are cultivated in a country very distant from their original
locality.

In a certain form of Geranium examined by DE VRIES, the
number of pistils was very variable : the predominant numbers
were 5, 10,15 . . . (multiples of 5). It may therefore be sur-
mised that the gynecium of Geranium is really cyclic, the
deviating specimens having two, three or more pentamer
cycles of pistils.

Number of stamens in the Rosacee : in this property, a series
of variation steps coinciding with the multiples of 5 exists. In

1 Ber. deut. Bot. Gesellsch., xiv., 1896, p. 204. (Quoted according to VERNON,
loc. cit., p. 48.)

21 think M. alpestris. The seeds (from which plants were raised in the

Botanic Garden at Ghent) were obtained from Germany. I don’t remember
the name of the tradesman. (My notes are not within my reach.)
192 THE QUANTITATIVE METHOD IN BIOLOGY

Prunus spinosa, for instance, the number 20 prevails. In the
neighbourhood of Leipzig, DIETEL found in this species a
variation curve in which the figure 21 was predominant (LUD-
WIG).! In Crategus coccinea LUDWIG found a variation
curve with a distinct hump coinciding with the value 8.
According to LUDWIG it may be surmised that in the men-
tioned examples the ordinary cyclic disposition of the stamens
is transformed into a spiral one.

By the above examples an interesting line of research is
indicated.

§ 182—METHODS FOR THE DISCOVERY OF VARIA-
TION STEPS.—Several methods for the discovery of variation
steps may be followed. I give here six methods and I suggest
a seventh one.

FIRST METHOD: When a two-humped (dimorphic) or
multi-humped (polymorphic) variation curve is obtained, it
may happen that the humps coincide with variation steps.
This may be considered as very probable if a certain arzth-
metical velation exists between the values which coincide with
the humps. Insuch a case it is advisable to verify the obtained
conclusion by carrying out a second series of measurements or
by applying another method. (See below.)

SECOND METHOD: In a one-humped (monomorphic)
curve the existence of variation steps may be surmised, as often
as a sudden decrease of the ordinates (frequencies) coincides
with two values between which certain arithmetical relations
exist, and also when arithmetical relations exist between both
extreme values, or between the most frequent value (hump of
the ar, and one of the extreme values or both extreme
values. In such cases verification is, of course, necessary.
(Example : Centaurea cyanus, § 124, p. 180.)

THIRD METHOD: Variation steps may be discovered by
comparing the value of a property in several subspecies, species,
genera, etc.; in other words, by examining the variation of a
given property through a long series of specific forms. From
the predominance of certain figures the existence of variation
steps may be deduced. (Examples: the predominance of the
figures 3, 6, g in the number of stamens of the Monocotyledons—
the predominance of the Fibonacci terms in the number of rays
of the umbella of the Umbellifere, etc.)

FOURTH METHOD: Variation steps may be rendered
observable by cultivating plants (or breeding animals) under
conditions of existence as various as possible, or by observing
them in the state of nature under different conditions. EX-

1 Prof. Dr F. LUDWIG, Ueber Variationskurven und Vartationsflachen der
Pflanzen. Botan. Centralblatt, 1895, vol. lxiv., Pp. 103-105.
VARIATION STEPS 193

AMPLES: Chrysanthemum carinatum, p. 184. In the number
of flowers of the inflorescence of Primula elatior a Fibonacci
series of the second degree is observed. According to DE
BRUYKER, in the state of nature, the predominance of a
given term depends on the conditions of life (for instance, on
the quantity of water in the soil).

FIFTH METHOD: Variation steps may be discovered by
observing the variation produced by gradation. (See Part
VIII.) EXAMPLE: the Fibonacci terms are rendered observ-
able in Chrysanthemum carinatum by comparing the flower-
heads of the successive lateral branches. (See p. 184.)

SIXTH METHOD: SELECTION. In certain cases the
successive terms of a series of variation steps have been brought
into evidence by selection. DE VRIES, starting with two
specimens of Trifolium pratense, which had a few leaves with
4 leaflets, obtained by selection a form with numerous leaflets,
the most frequent values being 3, 5,7 . . . (series of the un-
even numbers). (See also the example of Chrysanthemum
segetum, § 129.)

From this method the discovery of new series of variation
steps and the elucidation of the true significance of certain
values (§§ 126, 131) may be expected.

SEVENTH METHOD: CURVES OF DEVELOPMENT.
In the course of the individual development many primordia
pass through successive values till the definitive value is
reached. Ordinarily the increase seems to be gradual (con-
tinuous). It may be expected, however, that in the develop-
ment (growth) of a primordium in which variation steps exist,
jumps may occur, the passage from a term (step) to the next
one taking place suddenly, or more rapidly than the passage
between two transitory values.

It may be anticipated that in such cases the variation steps
might be indicated by abrupt changes in the direction of the
curve of development (see § 49), these turning points of the
curve being more or less distinct according as the series of steps
under consideration belongs to the first, the second or the third
degree. (See § 124.) Therefore the use of curves of develop-
ment for the discovery of variation steps may be suggested.

§ 183.—SERIATION OF THE PRIMORDIA ACCORDING
TO THEIR DEVELOPMENT. EMBRYOLOGICAL SERIES.
—Since each term of a series of variation steps represents one
of the states of equilibrium of a primordium, the arithmetical
relations between the terms of a series correspond to more or
less complicated mechanical relations, and very probably in
many cases to morphological relations, and also to embryo-
logical relations. (See § 132, Seventh Method.)

N
194 THE QUANTITATIVE METHOD IN BIOLOGY

It happens very often that distinctly different primordia
follow one another in the course of the individual development
according toa certain order a, b, c. . . the primordium c being
produced by a metamorphosis of }, and b by a metamorphosis
of a. The primordia a, 6,c . . . may then be looked upon as
being successive terms of a series, which I call an embryological
series. Certain series of variation steps very probably represent
successive states of development ; but between a series of steps
by which the successive states of one primordium are repre-
sented, and an embryological series, which indicates the
developmental relations between several different primordia, a
fundamental difference exists.

In Myosotis palustris the colours white, rose, blue (§ 46, p. 54)
are the terms of an embryological series which is observed in
many Boraginacee. In the blue Centaurea cyanus a similar
series exists, consisting of the terms white, rose-purplish and
blue (§ 47). . ’

In Myosotis versicolor the terms are white, yellow, blue. This
series recalls the embryological series of colours observed in the
subspecies of Viola tricolor mentioned in § 38.

The transformation of a given term of an embryological
series into the next one may take place in different ways. In
Myosotis palustvis the metamorphosis of rose into blue proceeds
in such a way that irregular blue spots appear on the rose-
coloured petals. These spots (the limits of which are rather
vague) coalesce more and more till the petal is blue. In
Centaurea cyanus, on the contrary, the metamorphosis of rose-
purplish into blue begins at the extremity of the petals and
proceeds gradually and regularly towards their base (gradation ;
see Part VIII.).

The available information about the relations alluded to
in the present paragraph is hitherto fragmentary. Further
investigation of this subject is desirable. A more complete
acquaintance with the developmental relations between differ-
ent primordia and between the different values (variation steps)
of a given primordium might throw some light upon the rela-
tions between the terms of a given pair of properties in the
hybrids,* and upon other biological problems.

§ 184—THE DIFFERENCES BETWEEN THE TERMS
OF AN EMBRYOLOGICAL SERIES MAY BE EXPRESSED
QUANTITATIVELY.—In Myosotis palustris the primordia
white, rose and blue being chemical properties, they may be
represented by chemical formule, which are the expression of
quantitative notions.

Strict segregation or transitory values (goneoclinie); dominant and
recessive, etc.
VARIATION STEPS 195

From another standpoint the differences between the prim-
ordia under consideration may be expressed by measurement.
The rose colour appears at a certain moment, let us say after
hours ; the blue colour after x’ hours. A petal stopped in its
development before the moment 7 is white ; if stopped before
the moment »’ it is rose ; if stopped in its development after 7’
it is blue. The curve of development being constructed, the
differences may be reduced to the terms of time.

§ 185-—PARALLEL VARIATION.—The term analogous
or parallel variation has been used by DARWIN to indicate
that similar properties occasionally make their appearance in
several ‘‘ varieties’’ or ‘‘races’’ descended from the same
species and more rarely in the offspring of widely distinct
species. DARWIN points out that the majority of the observed
cases (occasional appearance of black wing bars in the various
breeds of pigeon, and of stripes on the legs of the ass and of
various races of the horse, etc.) are evidently due to reversion.
Other examples are regarded by many biologists (for instance,
by H. M. VERNON, Joc. cit., p. 96) as being probably mere
coincidences and of no scientific value.

EXAMPLES (mentioned by DARWIN) ?: many trees be-
longing to quite different orders have produced pendulous and
fastigiate varieties. A multitude of plants have yielded
varieties with deeply cut leaves. Several varieties of melon
resemble other species in important properties. Thus one
variety has fruit so like, both externally and internally, the
fruit of the cucumber, as hardly to be distinguished fromit. In
animals we find feather-footed races of the fowl, pigeon and
canary bird. Horses of the most different races present the
same range of colour. Many “sub-varieties” of the pigeon
have reversed and somewhat lengthened feathers on the back
parts of their heads, and sub-varieties of the fowl, turkey, canary,
duck and goose all have either top-knots or reversed feathers
on their heads. It is a common circumstance to find certain
coloured marks persistently characterizing all the species of a
genus, but differing much in tint. The nectarine is the off-
spring of the peach, and the varieties of peaches and nectarines
offer a remarkable parallelism in the fruit being white, red or
yellow fleshed; in being cling-stones or freestones; in the
flowers being large or small; in the leaves being serrated or
crenated, furnished with globose or reniform glands, or quite
destitute of glands.

At least three different groups of facts are confounded under

1Or to the terms of the value of a leading property (§ 49).

2See CH. DARWIN, The Variation of Animals and Plants undey Domestica-
tion, second edition, 1875, vol. ii., p. 340. See also VERNON, loc. cit., p. 96.
196 THE QUANTITATIVE METHOD IN BIOLOGY

the term parallel variation and are therefore confounded in our
mind,

I place in a first group the cases in which two or more sub-
species, species, genera, etc., resemble one another in certain
properties, without more. Examples: fasciated and twisted
stems, ascidiform leaves, eye-shaped spots on the wings of
butterflies and the feathers of birds. In certain Comfere
(Pinus silvestris, etc.) certain insects (Chermes) bring about
cecidia, which resemble a strobilus by certain properties, etc.
Such resemblances are the expression of similar states of equi-
librium: they ought to be called mechanical concordances.
They are comparable to the examples given in § 65, in which
this subject is expounded.

In other cases a SERIES of primordia, observed in a species
(genus, etc.) A is met with again in a second species (genus,
etc.) B. Examples: the above-mentioned horses of different
races which present the same range of colour.

If there is no relation between the properties which belong to
such a series,! the term parallel variation ought to be avoided :
the resemblances under consideration are mechanical concord-
ances and belong to the first group.

Second Group—It may happen, however, that the pro-
perties under consideration are terms of an embryological series
(§ 133). I bring such cases in a second group under the name
embryological parallelism. Example: in the species Myosotis
palustris three subspecies exist: white, rose, blue. In other
species of Myosotis and in several species of other genera of the
same family (Echium vulgare, etc.) a similar series of subspecies
exists. The primordia white, vose and blue are terms of an
embryological series: therefore we may say that embryological
parallelism * exists between the different series of white-rose-
blue subspecies.

In a third group of so-called parallel variations, the properties
under consideration correspond to determined values, a, 0, c

. of one primordium and coincide with variation steps.
Here the existence of the termsa, b,c . . . inseveral subspecies,
species, genera, families, etc., depends on a mechanical con-
cordance of a peculiar kind which I designate by the term
parallel variation steps. Examples: the series 2,4... 2” is
repeated in Pediastrum (number of cells, § 122), the Onagracee
(number of stamens, § 126), the Mosses (teeth of the peristome,
§ 122). The Fibonacci series is found in many Composite
(number of marginal florets) and Umbellifere (number of rays

‘ 1] don’t know whether any relation exists between the colours of the
orses.
?The term embryological parallelism is based upon the constatation of a

fact and quite independent of the phylogenetic relations between the sub-
species alluded to.
VARIATION STEPS 197

of the umbella, LUDWIG), in Primula and Myosotis (number
of petals ?, § 131) and very probably in certain properties of
Mollusca and other animals. Etc.

Examples of mechanical concordance, embryological parallel-
ism and parallel variation steps are innumerable. It is by dis-
cerning and measuring the primordia—in the adult state and
in the course of the individual development—that it may
become possible to classify the facts and to establish their
biological significance.

In this subject, as in many others, DARWIN has been the
pioneer. If, however, we go on talking continually and indis-
criminately about analogous or parallel variation, reversion,
ancestral characteristics, convergent adaptation (see § 65, p. 81),
etc., further progress will be rather slow.
PART VItl

GRADATION

§ 186—COMPARISON BETWEEN LIVING BEINGS
AND CRYSTALS.—Attempts to establish a comparison
between living beings and crystals have been made repeatedly
and often discussed in biological literature. The remarkable
regularity of a number of forms of life 1 has probably been the
origin of such attempts. Along this line, however, no results
of any real value have been hitherto attained, because the
attempted comparisons have been merely based upon simili-
tudes of the exterior forms. The real nature of the crystals,
which depends on their internal constitution rather than on
their external aspect, has been overlooked, and this has
rendered fruitless the attempts under consideration. More-
over, the universal occurrence in the living beings of curved
lines which are never observed in crystals seemed until now to
be an insuperable obstacle, and no attention has been paid to
gradation, which is the key to the whole subject (§ 139).

In the comparison which I advance in the following para-
graphs, there is no question of external similitudes.

§ 187—THE AXES OF THE CRYSTALS ARE LINES
OF STABILITY.—A crystal is a system of material parts
which are in a certain state of stability. In each crystal we
discern a certain number of imaginary straight lines or axes
(ordinarily three, sometimes four) which may be called lines of
stability or equilibrium. The constitutive parts or units
(molecules, particles) of a given crystal are all alike and arranged
in a certain way according to the axes. All the successive
points of a given axis are identical. The value of any property
whatever of a crystal is invariable along each of its axes.

I take, for instance, an orthorectangular prism ?: in such a
crystal we discern three axes, a, b and c, each of which is per-
pendicular to the plane of the two others. The crystal may
be compared to a society of individuals (units) associated into
a rectangular triaxial system. (See § 88.) If we divide the
crystal into successive slices (sections) parallel to the plane bc

1 Diatoms, polyhedric cells in many animals and plants, tetrads, prismatic
stems; Echinids, etc.

* A straight prism, the base of which is a rectangle.

198
GRADATION 199

and following each other in the direction of the axis a, and if we
measure in those sections any physical property (dilatability,
conductibility, compressibility, refraction, specific gravity, etc.)
we obtain the same value for each and all. The same con-
stancy is observed along the axes b (slices parallel to the plane
ac) and c (slices parallel to the plane ab).

All the crystals are governed by the same law.

§ 188—THE AXES OF THE LIVING BEINGS ARE
ALSO LINES OF STABILITY.—I consider now a living
being, limiting myself to the pluricellular animals and plants.
Here we also distinguish axes which are lines of stability.
Each pluricellular specimen is a society consisting of a certain
number of individuals (segments or biological units; cells, etc.
See § 54) associated into a certain state of equilibrium and
ordered according to the axes. ;

When the axes of the living beings are looked upon as being
lines of stability and ordonnance, they are no longer arbitrary
or abstract conceptions. They acquire the same mechanical
significance as the axes of a crystal, and a comparison between
both is founded upon real analogy.

§ 189 —DIFFERENCE BETWEEN THE AXES OF THE
LIVING BEINGS AND THOSE OF THE CRYSTALS.
GRADATION.—A fundamental difference between the axes
of the living beings and those of the crystals depends on Grada-
tion. In a plant or an animal the value of a given property,
measured successively at different places along a given axis, is
variable instead of being constant as in the crystals! Its varia-
tion is regular; that is to say, ruled by a geometrical law, which is
to be discovered by measurement in each peculiar case and may
be represented by a gradation curve.?

§ 140—EXAMPLES OF GRADATION. FIRST EX-
AMPLE: THE FERTILE STEM OF POA TRIVIALIS (A
GRASS).—I call this stem a specimen or individual of the first
order; it is a uniaxial system. It consists of two segments
(individuals or units) of the second order—viz.: (1) the basal
(proximal) segment or stem properly so called ; (2) the terminal
(distal) segment or inflorescence (panicle, the lateral branches
of which are neglected here). Both segments are distinctly
different by a number of properties (differentiation).

1 See on the different systems of axes which are observed in the living beings
(uni-, bi-, triaxial systems, etc.), §§ 54, 77, 88.

See on the axes of unicellular beings, § 60 (egg of Spirogyra). See on curved
axes, which consist of a succession of straight simple axes, § 84.
_ 7 In the crystals, the gradation curve of any property is always a straight
line parallel to the axis. Therefore we may say that gradation does not exist.

‘
200 THE QUANTITATIVE METHOD IN BIOLOGY

Each of the above segments consists in its turn of a number
of units of the third order called internodes. All the segments
or units (of the second and the third order) follow each other in
the direction of one straight line, which is the axis. The whole
system (specimen) is therefore a uniaxial system. _

The axis isa line of ordonnance. It is characterized by three
facts: it is a line of: (x) segmentation; (2) differentiation ;
(3) gradation. ;

With reference to the latter point I measured the primordium
(simple property) length of the successive internodes from the
base to the summit (the terminal spikelet being excluded) of
two flowering stems taken at random."

The figures are given in the folloving Table:

Length of the successive internodes of two flowering stems of Poa trivialis.
The terminal spikelet is excluded. The internodes are numbered (I.,
II... .) from the base to the summit. The limit between the stem
properly so called and the inflorescence is indicated for each stem by ] [.
Length in mm.

Internodes . 5 I Il iit IV Vv VI VII VIII
Length ist stem . G 16 27 33 36 62 126 = 187]
Length 2nd stem . 5 10 25 39 31 44 60 102
Internodes . . %IX xX XI XII XIII XIV XvV_ XVI
Length 1st stem . [32 23 18 15 15 10 65 5
Length 2nd stem . 178] [23 17 14 1I 9 6 45
Internodes . . XVII XVIII XIX XX XXI

Length ist stem . 3 35 I 2 12

Length 2nd stem . 4 22 2 v8 2'2

Each of the above series of figures represents an individual
gradation curve (specimen curve). By means of the figures of
each series (I take the first stem as example),we may draw the
curve (Fig. 26), in which the axis (stem) is represented by a
horizontal line, the length of the successive internodes being
represented by equidistant vertical ordinates. Such a curve is
merely a graphic representation of facts without any calculation.

It is seen that in both stems the value of the primordium
under consideration increases from the base® till a maximum
is reached and further diminishes towards the summit. The
curve has thus an ascending-descending form. The slight
irregularities which occur at several places (for instance, 2nd
stem, internode IV.) are brought about by accidental causes
(chance) .®

_1 It happened that the total number of internodes was the same in both—
viz. 21. This is not always the case.
_ ?The value y of any ordinate depends on the distance comprised between
its base and the origin 7. In other words y =fx.
_ >A number of similar curves have been described by PERCY GROOM
in his interesting paper on “ Longitudinal Symmetry in Phanerogamia,”
Phil. Trans. Roy. Soc., London, ser. B., vol. cc. (1908), pp. 57-115, with numer-
ous figures,
GRADATION 201

There is a distinct breach of continuity (discontinuous
gradation) in each of the above curves between the longest
ordinate and the next one. This breach is a quantitative
expression of the differentiation of the stem (individual of 1st
order) into two segments (individuals of 2nd order: vegetative
part of the stem and panicle). The longest internode is the
upper internode of the basal part; the next one is the first
internode of the panicle. I have measured the length of the
internodes of numerous stems belonging to a number of species
of Graminee : the general (ascending-descending) form of the
gradation curve is the same in each and all. An exact com-
parison between two given stems,! in respect of the primordia

r 200
L

+ 100

 

 

 

I Vv X XV XX

Fic. 26.—Poa trivialis. Gradation Curve of the length of the internodes
of one fertile stem. J, Base of the stem; J, I’, . . . successive internodes.
Scale in mm. See the figures, p. 200, 1st stem.

(length, etc.) of their internodes is easily obtained by compar-
ing the longest internode and the first internode of the panicle
of both stems. The compared internodes are socially equiva-
lent and they represent the maximal value of the length in each
of the segments of 2nd order.”

SECOND EXAMPLE: THE FERTILE STEM OF HOL-
CUS MOLLIS (A GRASS).—This object has the same con-
stitution as the first example. I have measured the following
primordia, which are all ordered along the longitudinal axis of
the stem :

(1) The length of the internodes from the base to the summit
(the terminal spikelet being excluded) ;

1 Belonging to the same or different species.

2 It may be remarked that each of the above series of figures is a bertillonage—
that is to say, a quantitative description of a specimen complete enough to enable
us to distinguish it from any other fertile stem of any grass whatever, because
the same combination of figures practically never occurs a second time.
202 THE QUANTITATIVE METHOD IN BIOLOGY

(2) The length of the sheath of the successive leaves taken in
the same order ; ;

(3) The length of the blade (lamina); and ;

(4) The breadth of the blade of the successive leaves
(measured at the place of their greatest breadth).

The figures are given in the following Table:

Gradation in a flowering stem of Holcus mollis. Four primordia have been meas-
ured: length of the internodes, length of the sheaths, length and breadth
of the blades of the leaves. The internodes are numbered (I., II., . . .) from
the base to the summit. The figures of each leaf are in the same vertical
column as the figures of the internode at the base of which it is inserted.
The limit between the stem and the inflorescence is indicated by ][. The
lowest leaves were faded and could not be measured exactly. Dimensions

in mm.
Internodes . 2 of II WI Iv VoeovI vif vill IX
Length internodes . 15 12 8 7 7 3 7 15 30
Length sheaths —- -—- =— _ _ — 44 58 68
Length blades SES SS —_ = _ 52 90 121
Breadth blades - -—- — — — _— v8 24 32
Internodes - MX XI XII XII XIV XV XVI XVII
Length internodes 45 52 44 41 43 49 146] [7-4
Length sheaths 19 72 55 45 36 35 72
Length blades - 132 139 142 116 gt 75 15
Breadth blades $ 4 5 62 74 8 64 2°6
Internodes . - XVIII XIX XX XXI XXII
Length internodes . 9 8 7 55 5
Internodes. - XXITI XXIV XXV_ XXXVI
Length internodes . 2°9 371 21 3

With regard to the length of the internodes the remarks made
about Poa (first example) are also applicable to Holcus. Here,
however, the humps observed in the internodes II. and XI.
seem to be something more than fortuitous deviations. We
know that the internodes I.-XVI. (stem properly so called)
have been formed successively in acropetal order ; therefore
they represent a period of growth. In the course of this period
something has happened by which the regular progress of
growth has been disturbed two times: this has produced two
secondary humps (internodes II. and XI.) in the gradation
curve. In other words, several secondary waves of growth
have followed each other.

I have observed similar facts in the fertile stems of certain
Mosses.” In Mnium subglobosum and Mn. punctatum, two
waves occur rather frequently in the ascending portion of the
gradation curves (length and breadth of the leaves). Here the
limit between the waves is more conspicuous than in the above
bertilloned® stem of Holcus; it is really a distinct breach of

> A similar example is given in my paper on Mnium, p. 14, Fig. 3.
* See p. 33 in my paper on Muium mentioned in the present book on p. 69.
* From the French verb bevtilloner. See note 2, Pp. 201.
GRADATION 208

continuity by which two successive periods (waves) of gradation
are disjointed. = si
The existence of secondary humps (or breaches of continuity)
in a gradation curve of a given specimen depends probably very
often on a temporary change in the external conditions (tem-
perature ? supply of water ? etc.) in the course of the period of
growth. In certain species, however, the existence of more
than one period is observed in all the specimens ' and is there-
fore characteristic of the species. This is the case with the
gradation of the primordia length and breadth of the leaves of the
fertile stem in Cinclidium stygium Sw. (a moss allied to Mneum).

[150

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Fic. 27.—The curves represent the figures on p. 202. a, length of the inter-
nodes ; 0, length of the sheaths; c, length of the blades; d, breadth of the
blades; J, V, . . . successive internodes. Scale in millimetres °

Further investigation (by measurement !) of this subject may
bring, I think, an explanation of a number of facts in the
structure of living beings which have been hitherto overlooked
or looked upon as being mere curiosities.

In the gradation curve of the length of the sheath (Holcus) one
observes a distinct maximum (hump) in the upper leaf (inter-
node XVI.) and a secondary hump in internode X. The latter
did not exist or was hardly perceptible in other stems of the
same species. The gradation curves of the primordia length
and breadth of the blade have a rather regular ascending-

descending form, their summits coinciding respectively with
the ordinates XII. and XIV.

?The gradation curve of the property under consideration being simple
(one-humped) in allied species.
204 THE QUANTITATIVE METHOD IN BIOLOGY

Comparing the four curves in Fig. 27, it may be concluded
that the gradation of each primordium is independent of the
gradation of the others. The study of several examples of
gradation in other Phanerogamia (internodes and leaves in
Ilex, Ulmus, etc.) and in animals (shells of Molluscs, etc.) has
brought me to the same conclusion. In my paper on Mnium
referred to above I have given the gradation curves of a dozen
of primordia of the leaves along the axis of the fertile stem in
ten British species of that genus: here, also, the curves were
found to be in general independent of each other, although
in certain cases two curves have the same form or thereabout.

The independence of the gradation curves of different
primordia along a given axis seems, therefore, to be a general
rule.

THIRD EXAMPLE: GRADATION IN A LEAF.—The
blade of a leaf (in preference an entire oblong, lanceolate, oval
or oboval leaf) is an individual (unit) of a certain order (order «),
the longitudinal axis (axis NS) of which is indicated by the mid-
nerve. We know that the successive parts (I do not use here
the term segments) which follow one another along the axis
have been developed successively, ordinarily in basipetal order.
If we measure the breadth of the blade at a certain number of
equidistant places from the base to the summit of the leaf we
obtain a series of figures which represent a gradation curve.

The margin of a leaf is, on each side, a curve of the gradation
of the primordium breadth! drawn by nature itself. Very
often, even in leaves which seem to be exactly symmetrical, a
difference between both margins (right and left) is discovered
by measurement.

In certain leaves (or other phylloms), which are narrowed
about their middle, two periods (waves) of gradation exist
(marginal curve two-humped). (See my paper on Mnium,
P. 33.)

The margin of a leaf is curved; it consists of a series of
successive, straight, simple axes. The curvature is a secondary
form brought about by gradation (§ 84).

§ 141—COMPARISON BETWEEN GRADATION CURVES
AND EMBRYOLOGICAL CURVES. INDEPENDENCE
OF THE PRIMORDIA.—When we compare the different
values of a given primordium along a given axis, each value
coincides with a certain state of development in which the
growth of the primordium has been stopped. (See length of a
petal, § 45.) For instance, in the first stem of Poa trivialis,
mentioned p. 200, internode V. has been stopped in its growth

1The dimension of one-half of the leaf in the direction of the transversal
axis (axis EW).
GRADATION 205

(has reached its final state of equilibrium) with reference to the
primordium length when the latter was 36 mm., whereas the
growth of the length of internode VII. has been stopped when
the value 126 mm. was reached. Therefore a gradation curve
may be compared to a curve of development. Especially in
those numerous gradation-curves in which the increase is con-
tinuous from one extremity to the other (without waves or
secondary humps), the successive ordinates represent, as it were,
a series of individuals (segments) measured in successive states
of development (example : internodes I.-VIII., first stem, p. 200).

The above comparison is, of course, only applicable when each
primordium is taken separately, as an zndependent something.
The aspect of the question is completely changed if we consider
each individual (specimen or segment) as a whole. When we
compare, for instance, in Holcus mollis (p. 202), leaf VIII. with
leaf XIII., we see that XIII. is comparatively juvenile (in an
embryonal state) in respect of the length of the sheath, whereas the
same leaf XIII. is further advanced in its development (com-
paratively senile) in respect of the length and the breadth of the
blade. (Compare colour and length of the corolla in Centaurea
cyanus, p. 58; see also p. 52.) One may find numerous
similar examples in my paper on Mnium.

In the study of gradation, as well as in the study of embry-
ology, each primordium must be measured at first separately in
order to obtain EXACT information. The gradation curves of
several primordia being plotted down into the form of one dia-
gram (Fig. 23, p. 158, and Fig. 27, p. 203), exact notions about
each individual taken as a whole become attainable.

The notion of pedogenesis and the terms pedogenetic form,
juvenile state, embryonal form, etc., when applied on individuals,
have been often the expression of vague conceptions... When
applied on species, genera, families, etc., those conceptions have
been the cause of erroneous conclusions and many contradic-
tions. The fruit of laborious phylogenetic researches, carried
out for half-a-century, has been partly spoiled because we
have overlooked the FUNDAMENTAL PRINCIPLE OF THE
INDEPENDENCE OF THE PRIMORDIA. (See § 33:
MENDEL.)

§ 142._In the present book attention has been repeatedly
called to the importance of gradation, and several curious and
even unexpected consequences of gradation have been men-
tioned. In this paragraph I wish to recall the most important
passages in which gradation is alluded to:

(1) § 38 (p. 43): Segregation of properties produced by

: 1 For instance, with reference to the comparison between male and female
individuals of the same species (sexual and secondary sexual characters),
206 THE QUANTITATIVE METHOD IN BIOLOGY

gradation. Comparison between the effects of Mendelian dis-
sociation, plasticity, gradation and individual development.
Example of segregation by gradation : the primordium downy
in the sheaths of the leaves of Holcus (p. 45). A similar
example is described in my paper on Mnium, p. 20, Remark IV.

(2) § 49 (6) (p. 61): Comparison of the curves of develop-
ment of several primordia according to the method foliowed
(§ 140, second example, and § 141) for the comparison of grada-
tion curves.

(3) § 52 (fifth example, p. 68): Influence of gradation on
certain properties of the leaves of Mosses. (See also my paper
on Mnzium.) :

(4) § 71 (p. 86) : Any axis is a line of segmentation, differ-
entiation and gradation. Gradation in the erect branches of
Pseudochate gracilis, in an egg of Spirogyra, in a hair.

(5) § 79 (p. 96): Alteration of a chess-board system by
gradation.

(6) § 82 (p. 100): Gradation in a chess-board system in the
direction of the axes NS and EW; complicated effects (Fig. 13,
p. Ioz).

(7) § 83 (p. Ior): Continuous and discontinuous gradation
(differentiation). Antenna of Carabus. Epidermis of Allium
porrum.

(8) §84(p. 104) : Curvature of compound axes a consequence
of gradation.

(9) § 85 (p. 107): Gradation a cause of disorder in biaxial
systems.
PART IX

APPLICATION OF THE QUANTITATIVE METHOD—
THE DESCRIPTION OF SPECIES

§ 1483—VARIOUS APPLICATIONS OF THE QUAN-
TITATIVE METHOD.—In this book I have pointed to a
number of possible applications of the quantitative method—
for instance :

(1) The construction of embryological curves, based upon
the measurement of a sufficient number of primordia in succes-
sive states of development.

(2) The investigation of the structure of animals and plants
by means of gradation curves based upon the measurement of
primordia along the axes.

(3) The quantitative investigation of the influence of external
conditions of existence (plasticity).

(4) The quantitative description of the results of experiments.

(5) The quantitative description of species.

(6) And, in general, the determination of constants, by which
it becomes possible to replace terms by figures in aivy descrip-
tion whatever and to obtain exact expression of observed facts.

In my paper on Mnium (mentioned, p. 69) I have applied the
method to the description of species and also to the description
(bertillonage) and the identification of specimens, replacing the
classic dichotomous tables by tables of constants. I have
taken as example ten British species of the genus Mnium. I
have applied the same method on the species of the genus
Carabus and on the GRAMINEZ& of the Manchester district.
From the fact that the adopted method gives satisfactory
results in each of those three widely different groups of living
beings, one may conclude that it is applicable to all animals
and plants. In certain cases, however, measurements are
rendered difficult by practical obstacles—for instance, by the
contractility of certain animals (Polypes, Bryozoa, Molluscs,
etc.), by the astonishing plasticity of certain plants (many lower
Fungi, etc.), a.s.o. It may be hoped that such technical diffi-
culties will be surmounted one after another.

§ 144—BREACH OF CONTINUITY IN THE DEVELOP-
MENT OF BIOLOGICAL SCIENCE.—I wish to emphasize

1 The total number of measurements which I have hitherto carried i
the three mentioned groups may be estimated at more than 300,000. —s

207
208 THE QUANTITATIVE METHOD IN BIOLOGY

that the quantitative description of specific forms is only one of
the numerous possible applications of the method described in
this book, because many biologists take little interest in the
systematic part of their science. From the fact that I have
applied the quantitative method especially to systematics, they
might be tempted to conclude that this method is good for
specific description only and is of no importance for other
subjects.

There has been a breach of continuity in the historical de-
velopment of Biological Science. The classical work of LIN-
NUS, the DE JUSSIEUS, LAMARCK, LATREILLE, R.
BROWN, the DE CANDOLLES, DESHAYES, LINDLEY,
BERKELEY, REICHENBACH, VON MARTIUS, W. and
J. D. HOOKER and other masters of descriptive science, who
tried to inventory and to classify the specific forms, has made
hardly any substantial progress for half-a-century. It has been,
as it were, interrupted when the doctrine of the constancy of
species was replaced by the idea that specific forms are trans-
formed one into another by the accumulation of impalpable
changes (DARWIN). It is true, many new species (or so-called
species) have been discovered and described, but the new
material has been studied almost entirely according to old-
fashioned methods. The specific and generic descriptions
of Vertebrate and Articulate animals, Molluscs (recent and
fossil shells), Phanerogams, etc., which are published every
year in a number of memoirs and books, are on the whole
drawn up in the same way as half-a-century or even a century
ago.?

"On the other hand, scientific research along new lines has
obtained more prominent positions: much progress has been
achieved in anatomy, cytology, embryology, physiology,
hybridization, heredity, variation, biology properly so called—
that is to say, in those parts of zoology and botany which might
be called laboratory science.

Unfortunately systematic science, being almost entirely con-
fined to museums and private collections, did not avail itself of
the progress of laboratory science. On the other hand, numer-
ous biologists, who are working in laboratories or experimental
gardens, have almost forgotten the existence of systematics.
They limit themselves to a rather small number of forms, which
are, on the whole, nearly the same in all the universities and
laboratories of Europe. They no longer realize the astonishing

1Compare, for instance, the Flora of the Pavis District, edited in 1857 by
COSSON AND GERMAIN, or GEORGE BENTHAM’S Handbook of the

British Flora (New edition, 1866) with the new floras which have been
published in Europe and other parts of the world in the last twenty years.

As fav as the method ts concerned, several of the new works are rather inferi
to COSSON AND GERMAIN os BENTHAM. Paneer
APPLICATION OF THE QUANTITATIVE METHOD 209

diversity of the forms of life ; they become rather indifferent to
the splendour of living nature.

When they are told that in a certain collection 5000 species of birds are
brought together, they do not realize what that means. They know the
anatomy and the embryology of the chicken ; they have an idea of the duck
and the pigeon; they know the peculiarities of the skeleton of the ostrich.
Is that not enough ? Why should they waste theiy time with 5000 variants of
the type bird? When the laboratory botanist reads in a book that in Greece,
Italy and Spain, thousands of Phanerogams are found which are unknown
in Central Europe, his curiosity is not awakened. He knows the most im-
portant forms of temperate Europe; why should he bother about their
Mediterranean representatives ? I was myself in that state of mind for years.

The majority of the biologists of the modern school take from
an unlimited forest a few branches which they investigate
thoroughly, but they hardly know the trees the branches of
which they are studying, and they have not a clear idea of the
immensity of the forest, although they believe they have. The
systematists walk and travel through the forest, but they do
not know what is found within a branch.

Such a state of things is detrimental to the progress of our
science. It is not with impunity that we have disunited the
right and the left hand. The one-handed method has given us,
on the whole, what it possibly could give. On many sides our
science seems to be at a standstill, because we are faced with
fundamental problems which will remain insoluble as long as
we do not combine the use of both hands.

§ 145—VAGUENESS AND INCOMPLETENESS OF
SPECIFIC AND GENERIC DESCRIPTIONS.—The living
beings are described in our floras and faunas by means of terms.
Unfortunately the terms are often vague ; there is even some-
thing mysterious in their use. We are told, for instance, in one
of our best floras, that the leaves of Deschampsia flexuosa (a
grass) are short, with a long sheath. According to my measure-
ments the length of the leaf (blade) varies in this species between
8 and 112 mm., and the limits of variation of the length of the
sheath are 37 and 175 mm.!_ What is Jong and what is short ?
According to the book a sheath of 50 mm. is long and a blade of
100 mm. is short. The imperfection of the descriptive method
is obvious.

When figures are given they are often hardly approximate,
or quite inexact. We find in a classic book that in Phleum
pratense the length of the inflorescence varies between 25
and 100 mm. (1-4 inches) ; the limits I have found are 8 and
194 mm.! We are told in the same book that in Triodiu
decumbens the upper empty glume is 3-nerved. This is given

11 have limited myself to the upper leaf of the fertile stem.
oO
210 THE QUANTITATIVE METHOD IN BIOLOGY

as a characteristic of the genus. I have found the following
variation curve :—

Number of nerves: 3 4
IO

5 6 7 8 9
», glumes : 23 11 21

a” I

It is seen that the primordium under consideration is very
variable ; that the figures 5 and 6 are predominant, and that
3 1S a rarity !

Similar examples are found in UNLIMITED NUMBER in
the best systematic works in which Phanerogams, Fungi, Alge,
Fishes, Birds, Articulate animals, Shells, etc., are described.*
As soon as we measure a few primordia in a sufficient number of
specimens of a species ® and compare the result with the in-
formation given in a flora or a fauna, we discover vagueness,
inexactitude and even manifest errors. (See § 52.)

I point out here a serious evil which seems to have been
hitherto overlooked.? The systematists, confined in an anti-
quated routine, are the first victims of their deplorable method.
Since the great majority of the existing specific and even generic
descriptions are superficial and unfinished to such a degree that
the exact identification of a specimen is simply impossible, the
systematists discover continually and describe under new names
so-called new species, which have already been described either
once or even several times. The result is a complicated
synonymy and a discouraging disorder. When anyone tries
to make a catalogue of the flora or fauna of a given area, he is
faced with inextricable difficulties. If he takes the pains of
travelling from one museum and private collection to another
in order to examine and to compare the tyes, he discovers
that numerous descriptions have been based upon one or two
specimens, or even upon a fragment, and he is again and again
disappointed.

Moreover, the existing descriptions are ordinarily very in-
complete. Only a few characters are mentioned, according to
a sort of conventional scheme, which would possibly have been
sufficient (or thereabout) a century ago, when the number of
known species was comparatively small, but which does not
answer the needs of modern science. The fruits and the seeds

1 See other examples in my paper on Mnium.

* Taking a species the identification of which is beyond any doubt.

®See C. G. LLOYD, The Myths of Mycology, Part I. Cincinnati, O.
(December, 1917). 16 pages.”

The author of this paper has illustrated, by a number of examples, the
almost incredible imperfection of many well-known works on fungi and
or deplorable disorder which prevails in this department of descriptive

otany.

*T repeat here in a few words what I was told by TH. DURAND, one of
the authors of Conspectus Flore A fricane.
APPLICATION OF THE QUANTITATIVE METHOD 211

of many plants are simply ignored or hardly mentioned. As
a consequence of the spirit of routine, microscopical characters
are still almost entirely excluded from the systematic descrip-
tion of Phanerogams, Vertebrate animals, shells, etc. Although
microscopes of modern type were brought into general use
between 1830 and 1840, at the time being many entomologists
have not yet realized that the descriptive work they are carry-
ing out without the microscope will have to be done over again.

By means of the method expounded in this book, it becomes
possible to describe exactly any primordium whatever, however
variable it may be. Using the microscope for the discovery and
the measurement of primordia we are enabled to go far beyond
the usual scheme. For the description of the higher forms of
life * there are practically no limits to the number of primordia
which may be used. (See p.1go.) Following the variation of
a given primordium through a long series of specific forms, inter-
esting and unsurmised resemblances and differences are dis-
covered. (See p. 68.) By means of tables of constants the
innumerable observed facts may be set in order. (See my paper
on Mnium.) Following this method we grow accustomed to
exactitude and we learn to use the ¢eyms with more accuracy.
Moreover, we find now and then that a given peculiarity, which
was quite unknown and seems to be a futile detail, is a char-
acteristic feature of one species, with the consequence that a
decisive diagnosis of that species may be reduced to five or six
words with one or two numbers.

§ 146—IMPORTANCE OF SYSTEMATICS.—It would be
a mistake to disdain the work of the classic school. The talent
of observation of the masters of systematic science is marvellous.
They had exactly distinguished and classified an enormous
number of species with poor technical means, at a time when
optical instruments and laboratory science had not yet emerged
from childhood. They have been the pioneers of our science.
They were almost all enthusiastic collectors. Their collections
of objects have been collections of ideas: let us follow their
example. They were chiefly guided by a sort of instinct, which
enabled them to distinguish and to recognize the species by
their habitus (facies). The high value of that instinct, acquired
and developed by experience, should be impressed upon the
mind of many modern biologists, who cannot realize how it is
possible, for instance, to recognize thirty or forty horticultural
sorts of Azalea indica by a glance at the plants without flowers.

1The study of the fruits and the seeds of exotic Angiosperms, and even of
many European species, is for the investigator an unlimited field full of promise.

2 And even for the description of many Thallophytes and lower animals.

° See my paper on Mnium, Table XXXIX. More examples will be given in
a paper on Grasses which I hope to edit later on.
212 THE QUANTITATIVE METHOD IN BIOLOGY

Unfortunately the methods of description which came down
to us from the past do not enable us to make a useful inventory
of the forms of life. It may be hoped that the quantitative
method will render possible further development of the work
of the pioneers.

§ 147—SYSTEMATICS AND COMPARATIVE METHOD ;
MORPHOLOGY AND PALHONTOLOGY. IMPORTANCE
OF COLLECTIONS.—The Comparative Anatomy of CUVIER
is the real fundament of modern morphology : it has been built
up by the comparison of numerous species. This would have
been impossible without collections. CUVIER and his con-
temporaries were, in a certain sense, one-handed : they limited
themselves to the comparison of adult specimens. They could
not do otherwise; embryology was almost entirely beyond
their reach, because there were neither microtomes nor good
microscopes. We are also one-handed: in morphological
science we have universally adopted the embryological method,
but we are not concerned with collections and we overlook the
importance of the comparative method. We have forgotten
that our science has been created by the latter and has taken
birth in museums.

Why do not we combine both methods? Because of the
breach of continuity I have already alluded to. Comparison
is, in reality, impossible without systematics and collections.
Both are disdained by many modern morphologists, because
they have been too often disappointed by the imperfection of
the antiquated methods still followed by the collectors and in
the museums.

Numerous biologists overlook the importance of paleon-
tology. Here embryology is of little use; it is only by the com-
parative method that we can investigate the majority of the
fossil plants and the innumerable fossil animals. The bulk
of the palzontological material consists of shells, carapaces
(Echinids, etc.), polypiers, teeth, leaves, etc., which are, as a
rule, disdained by the laboratory biologists. Since there is a
gap between museum and laboratory, between the compara-
tive and the embryological methods, paleontology is hampered
in its progress. Fossil Molluscs, Echinids, polypiers, etc., are,
as a Tule, still investigated according to the methods of DES-
HAYES, D’ORBIGNY and other pioneers of the past.*

The quantitative method, applied on systematics, enables us

1GEORGE HICKLING, D.Sc., F.G.S., “The Variation of Planorbis multi-
formis Bronn,” in Memoivs and Proceedings of the Manchester Literary and
Philosophical Society, vol. lvii., Part TII.; 24 pages with 2 plates and 6 figures
(1913). This interesting memoir is an exception to the ordinary rule: the

author has applied the modern biometrical method to the study of the varia-
tion of the fossil species mentioned in the title.
APPLICATION OF THE QUANTITATIVE METHOD 218

to discover in the shells and the carapaces numerous unsus-
pected peculiarities, which may afford new, wider means of
comparison between fossil and recent species. (See § 148.)

§ 148—IMPORTANCE OF MINUTE DETAILS.—The
tables of constants given in my paper on Mnium, the tables
which are given below (§ 150), and many examples mentioned
in the present book, might bring about the impression that I
am concerned with unimportant details.

In Biological Science there are no unimportant subjects.
MENDEL and his followers have taken a certain number of
simple things or primordia and studied their hereditary trans-
mission. They have discovered a new world by the investiga-
tion of colours, wrinkles, hairs, prickliness and smoothness of
fruits, presence or absence of glands on the leaves, branching
or unbranched habit, presence of starch or sugar in the albumen,
dimensions (tallness or dwarfness) and other details which are
ordinarily considered unimportant.

The intricate problems of heredity have been brought nearer
their solution by dividing them into simple components.

The most intricate morphological structures consist of a
combination of primordia, each primordium being a simple
something, a detail. Comparing compound structures, the
morphologists try to discover the relations between large groups
(orders, classes, families) of living beings, but they are less con-
cerned with the relations between smaller groups, such as
genera, species, subspecies. Here the relations are simpler,
because the differences depend on a smaller number of pri-
mordia, but the fundamental morphological laws are the same.
In the simple, as well as in the complicated cases, everything
Sia on the primordia and on the specific energy of each of

em,

We should bear in mind that the best method is to proceed
from the simple to the complex. It would be profitable, I
think, to pay more attention to the relations between genera,
species and subspecies : this would pave the way for the study
of more intricate relations. When we apply the quantitative
method on systematics, investigating, for instance, a number of
primordia in a series of species of Carabus, Mnium or Graminee,
we are studying minutie, it is true, but we may hope to dis-
cover general rules which govern the more complex com-
binations of primordia. A consequence of our disdain for
systematics is that we sometimes attack insoluble problems,
putting the cart before the horse.

In the shells, carapaces, polypiers and other similar objects,
we also discern a number of primordia. Here the combinations

1 See, on the primordia of the shells, p. 113.
214 THE QUANTITATIVE METHOD IN BIOLOGY

are comparatively simple, and we enjoy the inestimable advant-
age of having at our disposal not only recent species but numer-
ous series and innumerable specimens of fossil species from all
the geological periods. By means of tables of constants the
facts may be set in order. Here we must, of course, begin with
the investigation of the recent forms, in order to pave the way
for the study of their fossil analogues.’ ;

The history of the progress of physics and chemistry teaches
us an important lesson : here the quantitative method has been
applied more and more to the study of minutiz. The con-
structors of instruments have been asked continually for
more perfection in their balances, thermometers, goniometers,
galvanometers, thermostats and other implements, in order to
penetrate deeper into the quantitative knowledge of small things
which were previously neglected. Along this road marvellous
discoveries have been made. In a similar way much progress
may be achieved in biology by the measurement of minutiz
which are primordia. By the work of the Mendelian School
and by the application of the quantitative method to system-
atics, the road is opened.

§ 149-—-THE NOTION OF SPECIES.—This notion is in
reality the corner-stone of biological science. In Part I. I have
expounded a hypothesis according to which the notion of species
is a chemical notion, and each species is strictly different from all
others. Adopting the latter principle, I deviate from the Dar-
winian doctrine of the continuity of the forms of life which is
still accepted by the great majority of the biologists. I am,
however, not alone.

It may be remarked, at first, that DARWIN himself,
especially in some of his later works, has repeatedly pointed
to the occurrence of sudden variations or sports, by which a
specific form might possibly be transformed into a new one
(saltation).

“. . . GALTON (1889) is of the opinion that the aberrant
or discontinuous variations generally known as sports may be
of considerable significance in evolution. Because evolution
may proceed by minute steps, he considers that it does not by
any means follow that it must so proceed.

“ Again, within recent years the orthodox view (continuity)
has been ably combated by BATESON in his book on variation

1 For instance, the study of the fossil Brachyopods, Pectens, Cardiums or
Echinids should be preceded by the quantitative investigation of the primordia
of the recent species of the same groups, because it is possible to obtain about
the latter information in respect of individual development (embryological
Series, see p. 194 ; embryological curves, see p. 61 and 158), conditions of exist-
ence (plasticity) and even hybridization. Beginning with the fossils, we would,
Iam afraid, put once more the cart before the horse. :
APPLICATION OF THE QUANTITATIVE METHOD 215

(1894). In this work he has collected a very large number of
instances of discontinuous variation, or variations in respect of
certain organs or parts, which have suddenly arisen in a com-
plete and perfect state, without, as a rule, the occurrence of
any intermediate stages. If, therefore, argues BATESON, such
instances of discontinuous variation undoubtedly occur, 1s it
not possible that the discontinuity of species which is so
striking a fact among living organisms is a consequence and
expression of this discontinuity of Variation ? ” 1 ;

In his theory of mutation HUGO DE VRIES has emphasized
the principle of discontinuity of species; he promulgated the
view that one species arises from another by a distinct step or
jump (mutation ; saltation).

Many facts discovered by the MENDELIAN SCHOOL
seem to be inconsistent with any theory (Darwinian or Neo-
Lamarckian) about the origin of species based upon the principle
of continuous transformation. Ina number of examples, indeed,
primordia (characteristics) are transmitted independently from
one another, being in turns observable or latent through succes-
sive generations, without intermediate forms (plasticity being
taken into account).

And moreover, as far as I know, it has been hitherto im-
possible, by means of ARTIFICIAL SELECTION, to modify
a species beyond a certain limit and to obtain the gradual trans-
formation of a species into another one.

The doctrine of the constancy of species, which prevailed in
pre-Darwinian times, can no longer be accepted. There are,
however, very serious reasons to adopt the principle of the
independence of species, which has the same significance for
practical purposes, although it is different from a theoretical
standpoint.

Suppose that we wish to study the numerous indigenous
species of Ranunculus, Vicia, Veronica or Graminee. We
collect specimens and try to identify them by means of the best
modern floras: in those books the given information is vague,
often hardly approximate, or even erroneous.2. Since we are
continually hesitating we are tempted to believe that a species
is really an artificial something and that all our Veronicas or
Vicias are simply variants of one type. One day perhaps a
friend may identify our specimens. We persevere ; we look at
the specimens rather than at the books. Observing the plants
under various conditions of existence, we become aware of the
importance of plasticity. We acquire step by step a certain
degree of instinct, and the result is that we become capable of

1See H. M. VERNON, Variation in Animals and Plants (London, 1903),
Pp. 52. See also, in the present book, p. 36, note 1.
2 See § 145.
216 THE QUANTITATIVE METHOD IN BIOLOGY

distinguishing the species, recognizing them at first sight. Now
we realize that the authors of the floras knew the species and
even certain subspecies! on the whole very exactly. We
believe that the initial difficulties have been a result of our
ignorance. Do we realize that they were, above all, a con-
sequence of the hopeless insufficiency of the descriptions ?

In certain critical genera, such as Rosa, Rubus, Hieracium,
and also Salix, Carex and others, it is true, the difficulties seem
to be insuperable. Here the notion of species seems to be really
artificial. Let us try to discover the origin of that state of
things.

The prevailing disorder has taken birth in former times, when
the disentanglement of the specific forms of the mentioned
genera was an insoluble problem. Here the instinct was not a
sufficient guide because of the extreme variability. Our pre-
decessors had no clear notions about the different sorts of varia-
tion. They have described indiscriminately species, subspecies,
variants,” hybrids and bud-variations.’ Since the descriptions
were drawn up in the ordinary defective way, it is impossible to
find in their writings the exact expression of the observed facts.
In more modern times, the same method being still followed,
the disorder has been continually augmented by the publication
of more memoirs, monographs, and critical revisions. It be-
came still more fearful when we began to talk about Jordanian
species: the sluice gates were opened more widely than ever
before.4 The subject has been spoiled.

A similar disconcerting result would be attained if a number of miner-
alogists, ignorant of the MODERN METHODS of investigation of their science,
began to write memoirs on the composition of all sorts of sand collected from
various parts of the world.

The investigation of the critical genera of animals and plants should be
started afresh. The existing literature should be provisionally thrown aside,
the best floras and faunas being used, however, for general orientation and for
the discovery of primordia (§ 52). A sufficient number of primordia should

 

1Certain forms, described as varieties, are simply variants. (See p. 11.)

* Numerous species of Cavex and Salix are more or less amphibious: it is
well known that amphibious species are in general very plastic.

* Hybrids and bud-variations may be multiplied indefinitely by asexuai
propagation. (See § 20, p. 16.) The latter is widely spread in the genera under
consideration.

FR. CREPIN, who devoted more than thirty years of his life to the study
of the genus Rosa, has called attention to the fact that many so-called species
of that genus have been based upon one specimen, or upon one bush (buisson)
consisting of specimens which were all produced by vegetative propagation of
a single one. — Such species are represented in numerous herbaria by branches,
which were distributed by exchange clubs or exsiccata. CREPIN called this
method buissonomanie.

A similar method has been probably applied on Rubus, Salix, Carex, etc.

‘Investigation of the Jordanian species ought to be carried out by means

of the quantitative method initiated by JOHANSEN for the pure lines in his
experiments with beans.
APPLICATION OF THE QUANTITATIVE METHOD 217

be exactly determined and measured, gradation being taken into account.
Seedlings and cuttings should be compared and cultivated under various con-
ditions of existence, and we should have recourse as often as possible to
hybridization.

In this way, it may be hoped that light will be thrown upon that foggy
department of systematic science.

Whatever the theory may be, it isa matter of fact that critical
species are a small minority and that the independence of species
is the ordinary rule among living organisms. One may ask
whether the belief that the notion of species is artificial has not
its origin rather in the vagueness of the existing descriptions than
in the living objects. :

The quantitative method is independent of any theory: it
may be applied immediately to the description of the very
numerous species of animals and plants which are, in fact,
independent, whatever the explanation of that independence
may be. And, moreover, the constants of those complex
species which include critical subspecies may be established,
each species being taken as a whole. The constants of the sub-
species may be eventually determined later on. Since they
are, of course, included within the limits of the species, their
determination does not affect the latter."

§ 150—EXAMPLE OF APPLICATION: THE QUANTI-
TATIVE DESCRIPTION AND IDENTIFICATION OF
GRAMINE#.—In my memoir on Mnium I have given a first
example of application of the method to systematics. Here I
give a second example.

I have applied the method to the Graminee of the Manchester
district. Since the number of primordia (characters) is practic-
ally unlimited in those plants, a choice must be made. I have
measured about 25 primordia of the fertile stem (including
inflorescence, spikelets and flowers). For each primordium in
each species I have determined the limits of variation—that is
to say, the lowest and the highest value, which are specific
constants.

In order that we might find the limits without being com-
pelled to measure an excessive number of specimens, the
MATERIAL IS COLLECTED in the following way :—I try to
find specimens of a given species under conditions of existence
as various as possible : on dry and wet, sunny and shady spots,
on rich and poor soil, on walls and rocks and on the banks of
rivers and streams, in forests and gardens and on cultivated

1In the memoir on Graminee which I intend to publish later on, I hope to
discuss the notion of species (and subspecies) in relation with specific con-
stants, and also to suggest an explanation of the so-called adaptation of the
RACE #o the conditions of existence, independent of the direct influence of the
surroundings and without the intervention of natural selection.
218 THE QUANTITATIVE METHOD IN BIOLOGY

fields, on the heath, in waste places, in meadows, etc. From
each spot I collect the largest and the smallest specimens ” and
measure them. In this way the work required for the discovery
of the limits is reduced to a minimum.?

The description of a species consists of a table in which the
constants of each primordium are given.

Remark: Those constants are something quite different from the limits
of variation represented by the extremities of a variation curve constructed
by the measurement of a series of specimens collected (according to the
ordinary biometrical method) at random on one spot or in one locality. See
Pp. 182, 188.

EXAMPLE (here I content myself with nine primordia) :

Specific description of Alopecurus pratensis L. :

. Length of the upper internode of the fertile stem: 129-678 mm.
. Length of the blade of the upper leaf of the fertile stem : 12-253 mm.
Length of the inflorescence : 24-183 mm.
Length of the first empty glume: 3°86-6°42 mm.
Breadth of the first empty glume: 1°38-2°20 mm.
. Number of nerves of the first empty glume: 3-3.
. Number of nerves of the second empty glume: 3-3.
. Length of the (first) flowering glume: 3°44-5°97 mm.
. Length of the awn of the (first) flowering glume : 4:73-9:99 mm.
The ratio (length first empty glume): (length first flowering glume) varies
between 0:94 and 1°17.

© ONY DNA W DH

In the above table I give an example of a ratio, which is, of
course, not a primordium but an empirical value calculated
arbitrarily from two primordia. We might also take arbitrarily
the sum, the product, the square root of the product, etc.
(§ 102). Such empirical values may render in certain cases
good services, although their biological or mechanical signifi-
cance is very vague. The constants of the primordia are, on
the contrary, figures which have been obtained by direct
measurement without any calculation. They are the expres-
sion of observed facts.

TABLES OF IDENTIFICATION are constructed in the
following way, limiting myself in one or another way. I take,
for instance, all the species of a genus, or the species of a family
which are indigenous in a given country or district, etc. For
each primordium a table is drawn up in which the minimal and
maximal values of each species are given. In the following
example I content myself with four primordia, one ratio and six

1The possible conditions of life are very varied for the majority of the
species, although many of them are ordinarily found under certain definite
conditions. In LEO GRINDON‘S Flora of Manchester (1857) the ordinary
surroundings of each species are exactly indicated.

* And, as much as possible, those specimens which are conspicuous by one
or another peculiarity, for instance by very long or short leaves, very large
or small spikelets, etc.

ss a it may be added that many interesting observations are made in the
eld.
APPLICATION OF THE QUANTITATIVE METHOD) 219

species of grasses. This is enough to give an idea of the method.
I take Agrostis alba as a whole, and bring under this name A.
alba L., A. vulgaris With. and their so-called varieties, adopting
provisionally the view of BENTHAM (Handbook of the British
Flora, 1866, p. 533). Dimensions in millimetres :

TABLE I
Length of the blade of the upper leaf of the fertile stem
Minimum Maximum
Alopecurus pratensis 12 Melica uniflora 175
Agrostis alba 17 Glyceria fluitans 203
Glyceria fluitans 27 Agrostis alba 224
Festuca pratensis Huds. 33 Alopecurus pratensis 253
Melica uniflora 33 Festuca pratensis Huds. 264
Bromus asper 125 Bromus asper 416
TABLE IT
Length of the first empty glumé (awn excluded)
Minimum Maximum
Glyceria fluitans 16 Agrostis alba 3:2
Agrostis alba 18 Glyceria fluitans 40
Festuca pratensis Huds. 2-0 Festuca pratensis Huds. 4:3
Melica uniflora 27 Melica uniflora 55
Alopecurus pratensis 38 Alopecurus pratensis 6°5
Bromus asper 40 Bromus asper 7-6
TABLE III
Length of the first flowering glume (awn excluded)
Minimum Maximum
Agrostis alba 14 Agrostis alba 23
Melica uniflora 3:2 Melica uniflora 50
Alopecurus pratensis 3°4 Alopecurus pratensis 6-0
Glycerta fluitans 4°0 Glyceria fluitans ‘0
Festuca pratensis Huds. 4°7 Festuca pratensis Huds. 7°6
Bromus asper 8-7 Bromus asper 130
TABLE IV
Length of the awn of the first flowering glume
Minimum Maximum
Glyceria fluitans 0 Glyceria fluitans oO
Melica uniflora 0 Melica uniflora 0
Festuca pratensis Huds. 0 Festuca pratensis Huds. 2°0
Agrostis alba 0°04 = Agrostis alba 28
Bromus asper 4'0 Bromus asper 6'0

Alopecurus pratensis 4°7 Alopecurus pratensis 10°'0
220 THE QUANTITATIVE METHOD IN BIOLOGY

TABLE V
Ratio (length rst empty glume): (length rst flowering glume)

Minimum Maximum
Glyceria fluitans 0°39 Glyceria fluttans 0°55
Festuca pratensis Huds. 0°39 Bromus asper 0°64
Bromus asper 0°50 Festuca pratensis Huds. 0°65
Melica uniflora 0°82 Alopecurus pratensts Er7
Alopecurus pratensis 0°94 Melica uniflora I'Ig
Agrostis alba 108 Agrostis alba I'5r

USE OF THE TABLES OF IDENTIFICATION : Suppose
that we want to identify a Grass x with one or several fertile
stems, and that we have no other information than that it be-
longs to one of the species mentioned in the Tables I.-V. The
THREE METHODS of using the tables which I have given in
my paper on Mnium are also applicable to the Grasses.

According to the FIRST METHOD I measure the primordia
of one stem and of one spikelet of zts inflorescence. The figures
are (this example is taken at random) :

SPECIMEN *
Length blade upper leaf : ; : .- 7O mm.
59 first empty glume . . : a 49 5,
oa », Howering glume : ; 5 5I »

», _ awn first flowering glume _ 75»

Ratio length (rst empty) : (rst flowering) glume O07 ,,

I begin with Table I.: minimum, Bromus is excluded; maxi-
mum, no species excluded.

Table IJ.: minimum, no species excluded; maximum,
Agrostis, Glyceria and probably Festuca excluded. (Since the
constants are not definitively established, the difference between
4°3 and 4’9 is rather too small to be decisive.)

Table III.: minimum, exclusion of Bromus confirmed ;
maximum, exclusion of Agvostis confirmed, Melica probably
excluded.

Table IV. gives a decisive answer: minimum, no species
excluded; maximum, all the species excluded except
Alopecurus. Were, however, the exclusion of Bromus is only
probable (for the above given reason), but Byvomus has already
been excluded.

It may be concluded that x is Alopecurus pratensis.

I measure in a similar way the primordia of one stem and one
spikelet of a Grass y. The figures are :
APPLICATION OF THE QUANTITATIVE METHOD 221

SPECIMEN y
Length blade upper leaf : : i . 155 mm.
»  firstempty glume . 3 : : SF a
45 », flowering glume : ; ; 4 Or ung

» | awn first flowering glume if
Ratio length (1st empty) : (Ist flowering) glume a 93»

The order in which the tables are used being arbitrary, I
begin this time with :

Table V. : minimum, A grostis probably excluded ; maximum,
Glyceria, Bromus and Festuca excluded [here the practical utility
of an empirical value (ratio) is obvious].

Table [V.: minimum, Agrostis again probably excluded ;
maximum, exclusion of Bromus confirmed, Alopecurus excluded.

Table III.: minimum, exclusion of Bromus and Festuca con-
firmed ; maximum, exclusion of Agrostis confirmed.

Since five species have been excluded, y is Melica uniflora.

I try now a third Grass z and measure the primordia (one stem,
one spikelet). The figures are :

SPECIMEN z
Length blade upper leaf : P s - 327° mm.
fs first empty glume. : ; : 32 45
Ps », flowering glume : : ; Bie a5
36 awn first flowering glume ‘ Tg Os,

Ratio length (1st empty) : (rst flowering) glume 0°62

I begin with Table I.: minimum, no species excluded ;
maximum, Melica, Glyceria, Agrostis, Alopecurus and Festuca
excluded.

Table II.: minimum, Bromus excluded.

All the species being excluded, it may be concluded that z
does not belong to any of our six species. In order to verify
this deduction, I take the tables in the reverse order, and begin
with :

Table V.: minimum, Agrostis and Alopecurus excluded,
Melica very probably excluded ; maximum, Glyceria probably
excluded.

Table IV.: minimum, Bvomus excluded, exclusion of
Alopecurus confirmed; maximum, exclusion of Melica and
Glyceria confirmed.

Table III.: minimum, exclusion of Bromus confirmed ;
maximum, exclusion of A grostis confirmed.

Table II.: no more species excluded.

Table I. : minimum, no species excluded ; maximum, exclu-
sion of Melica, Glyceria, Agrostis and Alopecurus confirmed,
Festuca excluded.

”
222 THE QUANTITATIVE METHOD IN BIOLOGY

The above deduction is verified. The Grass z is, indeed,
a specimen (taken at random) of Dactylis glomerata. This
example gives us an idea of the way in which it may be dis-
covered whether a given species is new for the flora of a certain
area or even new for science, if we have tables of constants at
our disposal. ;

The SECOND METHOD is applicable as often as it is possible
to measure the same primordia in two or several specimens
which belong with certainty to the same species (in the case of
the Grasses two or several stems of one plant or one patch).
Example: I take (at random) three fertile stems of one patch
of Alopecurus pratensis and measure the length of the blade of
the upper leaf. The figures are 153, 132 and 47 mm. Taking
Table I., the values 153 and 132 do not give us any information,
but by means of the figure 47 Bromus asper is excluded. Etc.
See my paper on Mnium.

The THIRD METHOD is applicable if one specimen (in the
case of the Grasses one inflorescence) affords opportunity of
measuring certain primordia two or several times. Example :
I measure in one inflorescence, u, the length of the awn of the
first flowering glume of several spikelets. Among the examples
which I have collected I choose one in which the figures were
57,62 and 82mm. Taking Table IV., the figures 5-7 and 6-2
do not give decisive information, but from the value 8:2 it may
be deduced that u is Alopecurus pratensis.

In the above examples it has been possible to identify a speci-
men by means of a few figures. This happens more frequently
than one would think. It is, of course, often necessary to
measure a rather large number of primordia, especially when
we want to make a choice between numerous species. (An ex-
ample is given in my paper on Munium, Table XX XIX.)

DESCRIPTION OF ONE SPECIMEN. BERTILLONAGE.
—One figure, representing the value of one primordium of one
specimen, has rarely any value as long as it is taken isolatedly.
When a sufficient number of primordia of one specimen are
measured, the combination of figures obtained is a bertillonage :
it is a quantitative diagnosis of the specimen (compare § 140).
A bertillonage has been hitherto looked upon as being useful
only for the identification of an individual among all the speci-
mens of the same species, A bertillonage has, however, a much
higher significance. The species itself is included in the com-
bination of figures. (See the combinations of x, y and z, pp.
220-221.) I have tried a very large number of examples taken
at random among species of Carabus, Mnium and Graminec.
I never found an exception.

See my paper on Mnium, § 18: the value of bertillonage
for descriptive botany and zoology.
INDEX

A

ABIOTIC substances and properties, 6,
70

Accommodation, 17, 51

Adaptation, individual, 17, 51; of the
race, 217; specific, 17

Adult, individual, 51 ; primordium, 51

Agrostis, 219

Aa, 44

Ajuga, 17

Alkaloids, 4

Allen, J. A., 28

Allium, 96, 102, 112

Alopecurus, 218, 219

Alternative variation, 117

Alysarine, 6

Amaryllidacee, 92

Ammonites, 113

Anagallis, 67

Ancylus, 113

Anemone, constant hybrid, 39

Annelids, 97

Annuals, 92

Aphrophora, 19

Apocynacee, 111

Apple, 44.

Arachis (oil), 4

Articulates, 97

Asclepiadace@, 111

A sperula, 6

Ass, 195

Axes, 86, 93, 95; compound, 103 ; of
crystals, 198; curved, 103; of

living beings, 199; oblique (false),
108; optical, 74; simple, 103; uni-
axial system, 71

B

BALLS in an urn, 124, 125

Bateson, W., 32, 37> 38, 39, 42, 69, 214
Beech, 43. See Fagus

Bentham, I1, 208, 219

Bertillonage, 27, 201, 222

Betula, 175

Biaxial system, 93 ;

Binomium (a+b), 120; (a+b)", 146
Biology, breach of continuity in, 207
Biometrika, 31

Biometry, 27, 31

Bioproteins, 5

223

Bivalves, 113

Bohr, Niels, viii

Bois, Dr De, 57
Bovaginacee, 194

Bromus, 219

Bruyker, Dr de, 17, 58, 178, 185
Bud-generations, 91
Bud-species, 16
Bud-subspecies, 16
Bud-variation, 15

Bugs, 6

Buissonomanie, 216

Bulbous plants, 92
Burvenich, J. V., 13, 22, 184
Butomus, 179

Butter, 4, 5

Butterflies, 11 ; scales, 81

Cc

Callitriche, 13

Calluna, 18

Calosoma, 62, 68, 97, 190

Campanula, 13, 43

Campanularia, 81

Canary bird, 195

Carabus, 62, 67, 102, 107, 190

Cards, experiments with, 163

Carex, 216

Cassis, 99, 113

Castanea, 175

Cecropia, 91

Centaurea, 18, 21, 58, 180, 182, 194

Cephalopods, 113

Certitude, expression of, 123

Chara, ©

Characteristics (chemical), 6, 70

Chelonide, 62

Chemical characteristics, 6, 70

Chemical variations, 70

Chermes, 196

Chess-board system, 94; alterations,
95; differentiation, 101; disorder,
105; gradation, 100

Chrysanthemum, 12, 58, 180, 182, 184,
186

Cicindela, 6, 7

Cinclidium, 203

Circea, 181

Clarkia, 181

Classification, 1

Cleavage, 93, [10

Coccinella, 6, 19
224

Coefficient (equation), personal, 49

Ccenobium, 178

Coins, equilibrium of, 116, 119, 121, 122

Colchicacee, 99

Coleoptera, 97

Collections, importance Gf, 212

Collumbien, 13

Complex species, 14

Complexity, 11, 14 ;

Compound properties, 40 ; decomposi-
tion of: in the course of individual
development, 46; by gradation, 45;
by hybridization, 40; by plasticity,

43

Concordance, mechanical, 79

Conifere, 196

Constants, biological, 174, 181 ; tables
of, 218

Copper-beech, 43

Correlation, 56

Correns, 35, 37

Cortex, 112

Cosson, 208

Crampton, H. E., 114

Crataegus, 91, 192

Crépin, Fr., 216

Crimson Rambler (Rose), 13

Cucumber, 195

Cultivation, 17, 174

Curve, biological variation, 28, 165
167; dimorphic, 185; polymorphic,
185 ; of errors, 145; of growth, 153-
158; inorganic variation, 158-167 ;
unilateral variation, I5I. See
Embryological, Embryology

Cuttings, 90

Cuvier, 66, 80, 212

D

DactTYLis, 18, 222

Darwin, 15, 16, 19, 45, 46, 49, 51, 60,
195, 197, 208, 214

Darwinism, 17

Dautzenberg, Ph., 24

Davenport, C. B., 31

Deschampsia, 44, 209

Description of species, quantitative,
207, 218; vague and inexact, 209,
216, 217

Details, importance of, 213

Determiners, 41

Die, equilibrium of a, 125, 127

Dietel, 192

Differentiation, 72, 101, 201

Dipsacee, 6

Dipsacine, 6

Dipsacotine, 6

Dipsacus silvestris torsus, 22

Disorder, 105

Dissociation,
Segregation

in hybrids, 34. See

INDEX

Dominant character, 33
Donax, 113

Drosera, 81

Duck, 195

Durand, Th., 210

E

ECHINODERMS, 77

Echium, 196

Elementary species, 7, 11

Embryological curves, 153-158, 193,
204; series, 193, 196; parallelism,

TQ!

Embryology: curves of development,
61; variation in, 62; method, 50,
80, 212

Endodermis, 112

Epidermis, 98, 111

Epilobium, 181

Equation, personal, 49

Equilibrium, 51

Erica, 78

Evistalis, 19

Evodium, 87

Errors of observation, 145

Erythrea, 21

Euastropsis, 78, 180

Eucharidium, 181

Evans, W. D., viii

Existence, conditions of, 167

Experiments (investigation of critical
specific forms by), 14, 216; with
cards, 163

External factors, 167

Eye, 49

Eye-shaped spots, 196

F

Factors, hereditary, 41
Fagus, t1, 43, 56, 88, 175
Fasciation, 20

Fats, 2

Fertilization, self and cross, 49
Festuca, 219

Fibonacci numbers, 178
Ficavia, 17

Fossils, 212, 214

Fowl, 195

Frequency, 118
Fritillaria, 99
Frontignan (grape), 16
Fuchsia, 181

Fumaria, 89

G

GALTON, FRANCIS, 30, 31, 214
Gamophyllous corolla, calyx, 89
INDEX

Gasteromycetes, 79

Gauss, 147

Genista, 67

Geranium, 179, 191

Germain, 208

Gladiolus, 16

Glyceria, 219

Glycerides, 2

Goose, 195

Gradation, 100, 198, 205 ; discontinuous,
201, 203 ; ima leaf, 204, 205

Grafts, 90

Graminee, 92, 217

Grape, 16

Grasses, 217

Grindon, Leo, 218

Growth, 154

Gryllotalpa, 81

Gucht, van der, 178

H

HAECKEL, 50

Hamburger, 49

Hauy, 64

Hauya, 181

Head or tail, 116

Heincke, Dr Fr., 190

Heredity, 7; two kinds of, 8

Herpostetron, 84

Herring, 190

Hickling, Geo., 212

Hickson, S. J., 114

Hieracium, 216

Holcus, 18, 45, 48, 201, 205

Homology, 79

Hooker, J. D., 67, 174

Horse, 195

Horticultural species, 16 .

Hybridization, 32,134. See Hybrids

Hybrids, 21; constant, 38, 39, 141;
dissociation, 34; dominant char-
acters, 33; intermediate, 37, 38;
Mendelism, 32; Cnothera, 38; re-
cessive characters, 33; segregation,
34; vegetative multiplication, 16

Hydrodictyon, 83

Alyoscyamus, 37

Hypericum, 19

I
IDENTIFICATION, tables of, 218
Llea, 97
Ilex, 204

Independence, of adjacent cells, 107;
of the species, 215 ; of the primordia,
204 .

Individuals of successive order, 71.
See Units

P

225

Infantile state, 52, 59, 205

Intermediate, 36; units, 96; specific
forms, 39

Interposed specific forms, 39

Iris, 92, 112, 179

Isnarvdta, 181

J

JANCZEWSKI, 39
Johansen, 15, 31, 216
Jordanian species, 216
Juvenile state, 52, 59, 205

K

KNIGHT, 16
Koelreuter, 35

L

LaxBoraTory science, 208
Lamarckism, 8, 17, 81

Lang, W. H., vii

Latreille, 27, 66

Lavoisier, 64

Law, rule, 40

Leading property, 61

Leaf, gradation in a, 204, 205
Legumtinose, 91

Leibnitz, 55

Lelewell, 80

Leontopodium, 9

Ligneous vessels, 112

Liliacee, 92

Lilium, 179

Lines, pure, 15, 31

Linneus, 27

Linseed (oil), 4

Linum, 4, 8, 47 .
Living substance, 2, 70; variation of,

7
Lizard, 97
Lloyd, C. G., 210
Lopezia, 181
Ludwig, 178, 179, 186, 191, 192, 197
Lythnis, 17
Lycoperdon, 81

M

m-o-M values, 172
MacIntosh, D. C., 29
MacLeod, 40, 69, 178, 183
Mariotte, 35

Maximal value, 173
Mayer, A. G., 28

Mean deviation, 30
226

Mean error, 30 :

Mean value, 29, 147, 161, 166, 173;
use of, 176; relation with variation
steps, 176, 181

Mechanical concordance, 196

Melandrium, 17

Melica, 219

Melon, 195

Mendel, Gregorius, 21, 32, 65, 115, 134,

139
Mendelism, 134, 215
Mentha, 21
Meristic variations, 69
Miers, Sir Henry Alexander, 1
Mimosa, 78
Minimal value, 175
Mixtures, 4
Mnium, variation in, e8, 69, 182, 188,

Ig0, 202
Mobilis etas, 57
Monocotyledons, 179
Monotypic species, 14
Morus, 91
Mosses, 104, 106, 108, 109, 178
Muscle, contraction of a, 50
Mutation, 7, 8, 16, 141, 215
Mycology, 210
Myosotis, 191, 194, 196
Myxomycetes, 79

N

NAEGELI, 35, 79
Narcissus, 112
Nautilus, 113
Nectarine, 195
Nicottana, 6
Nigella, 183
Nucleus, 5

oO

OBLIQUANGULAR system, 109

Oblique (false) axes, 108

Gnothera biennis, 21,
hybrid, 38

Oils (fixed), 2

Onagraceez, 181

Ophiocama, 29

Opium, 4

Optimum, 168

Orchids, 78, 81, 92

Owen, R., 66

38; constant

P

P2DOGENESIS, 205
Paedogenetic state, 52, 59, 205
Palzontology, 212

Papaver, 4, 57, 183

Partula, 114

Patella, 113

Pea, 32, 134

INDEX

Peach, 195

Pearson, Karl, 31, 183

Pecten, 109, 178

Pediastrum, 78, 178, 180

Pelecypods, 113

Percy Groom, 200

Perennials, 92

Personal equation (coefficient), 49

Phajus, 73

Phallus, 6, 7

Philodendron, 12, 43

Phleum, 18, 20, 176, 209

Phloem, 112

Phyllotaxis, 48, 190

Pigeon, 195

Pinus, 196

Pisum, 32

Planorbis, 212

Plasticity, 9, 52, 58

Plastids, 5

Plateau, Josef, 49

Pleurococcus, 94, 97

Plum, 16

Poa, 112, 175, 199, 204

Polygonum, 10, 44, 48

Polyps, 77, 79, 81

Poppy, 183

Possibilities, 9, 26, 36

Potato, 16

Potentialities, 9, 26, 36

Potentilla, 17

Prasiola, 97

Priestley, 64

Primordia, 40; classification, 66, 69,
74, 87, 89; classified according to
their development, 55; accrescent,
56; arrested, 54; awakening, 53;
caducous, 54; deciduous, 54; meta-
morphic, 53; original, 53; transi-
tory, 54; independence of, 204;
leading, 61

Primula, 13, 18, 55, 185, 191

Primulacee, 67

Probability, 118

Probable error, 30

Progressive mutation, 59

Properties, combination (co-existence)
of, 47; possible and observable, 9,
26; simple and compound, 40.
See Primordia

Proteins, 3, 5

Prunus, 16, 192

Pseudochete, 84

Pseudoclytia, 28

Puccinia, 103

Pure lines, 15, 31, 216

Pyrus, gi

Q

QuanTITATIVE method, 26, 115, 144;
various applications, 207
INDEX

Quercus, 88, 90
Quetelet, 28, 31, 70, 115

R

Race, adaptation of the, 217
Radial system, 77
Ramification, 89

Rana, 19

Ranunculus, 10, 21
Recessive character, 33
Reptiles, scales, 81
Reseda, 89

Retina, 114

Retrogressive mutation, 59
Rhododendron, 9, 78
Root, primordia, 112

Rosa, 13, 216

Rosacegz, 191

Rubia, 6

Rubus, 216

Rule, law, 40

Rye, 17

S

Saccharomyces, 78

Salicornia, 21

Salix, 216

Saltation. See Mutation

Scalaria, 178, 183

Sciurus, 28

Secale, 17, 175

Seed rarely produced in many species,

17

Seed-fixed properties, 16

Seed-species, 16

Segregation, 34, 38; in hybrids, 34,
35, 40; by gradation, 45; in the
course of individual development,
46; by plasticity, 43

Selaginella, 78

Selection, 7, 81, 215, 217

Senecio, 12, 179, 181, 182

Sensations, duration of, 49

Sensitive period, 56, 75, 82

Serrure, 80

Sertularia, 81

Sexual characters, 205 ; secondary, 60

Shells, collection of Ph. Dautzenberg,
24; of molluscs, 98, 113

Shrubs, 92

Simple properties, 40

Skin, human, 98

Social: cause, difference, environ-
ment, 73; equivalence, 91; rela-
tions, 91

Solanum, nigrum, 8, 11 ; potato, 16
Soldanella, 9
Solidago, 92

227

Species, constancy of, 215; descrip-
tion of, 207, 209, 217 ; independence
of, 215; Jordanian, 216; notion of,
I, 214; monotypic, 14; complex,
14; horticultural, 16; bud-, 16;
seed-, 16; origin of, 141

Specific, energy, 116, 129, 181, 187;
constants, 174, 176, 218

Specimen, 71

Sphere, equilibrium on a plane, 116

Spirogyra, 70

Sport, 7, 8

Sprengel, Chr. K., 35

Spurs, 92

Steinbrink, 74

Stellavia, 18

Stomates, 102

Subspecies, 7, 11, 14

Substantive variation, 69

Symmetry, relation with variation
steps, 180

Symphoricarpus, 91

Systematics, importance of, 211

T

TABLES, of constants, 218; of identi-
fication, 218

Tail (head or), 116

Talpa, 81

Teleutospores, 77, 103

Tellina, 109

Tetrahedral system, 78

Thistles, 11

Thorpe, Edward, 2, 3, 4

Trees, 88, 92

Triaxial system, 110

Trifolium, 89, 178, 180, 193

Triodia, 209

Tschermak, 35

Tulostoma, 81

Turkey, 195

Types (specimens), 210

U
Ulmus, 204 i :
Units, biological, 71, 84; intermediate,
96
Unwin, G., viii
Vv

m-o-M, 172;
See

VALUE, maximal, 173;
minimal, 175; optimal, 168.
Mean Value

Vanda, 99

Vandevelde, A. J. J., 107

Variants, 10

Variation curves, 29, 160, 165
228

Variation: alternative, I51; com-
plexity, 11; continuous, discontinu-
ous, 17, 150, 153, 185, 187; index
of, 30; meristic, 69; parallel, 195 ;
plasticity, 9; substantive, 69;
under cultivation or domestication,

17

Variation steps, 178; gradation, 184;
methods for the discovery of, 192 ;
parallel, 196; plasticity, 184; re-
lation with mean value, 176, 181;
relation with phyllotaxis, 190; re-
lation with symmetry, 180; selec-
tion, 186; specific difference, 187

Varieties, 11, 15

Vernon, 28, 182, 186, 195, 215

Verschaffelt, E., 107, 178

Vertebrates, 97

Vexillary marks, 98, 108

Viola, 46, 194

Vitis, 16

Volvox, 83

INDEX

Vries, Hugo de, 11, 16, 22, 35, 38, 49,
57, 178, 182, 186

w

WALLACE, 31

Wasteels, 178, 183
Weiss, F. E., vii. 69
Weldon, W. F. R., 31
West, G. S.; 78, 83, 84, 93

Wheat, 177
Wille, N.; 97

Xx
XYLEM, 112

Z

ZENITH-NADIR, IIO
Zygnema, 79

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