The Future of Systematics: Tree Thinking without the Tree


The Future of Systematics: Tree Thinking without the Tree
Author(s): Joel D. Velasco
Source: Philosophy of Science, Vol. 79, No. 5 (December 2012), pp. 624-636
Published by: The University of Chicago Press on behalf of the Philosophy of Science Association
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The Future of Systematics:

Tree Thinking without the Tree
Joel D. Velasco*y
Phylogenetic trees are meant to represent the genealogical history of life and apparently
derive their justification from the existence of the tree of life and the fact that evolutionary
processes are treelike. However, there are a number of problems for these assumptions.
Here it is argued that once we understand the important role that phylogenetic trees play
as models that contain idealizations, we can accept these criticisms and deny the reality of
the tree while justifying the continued use of trees in phylogenetic theory and preserving
nearly all of what defenders of trees have called the “importance of tree thinking.”

1. Introduction to Phylogenetic Trees. Evolutionary biology is a histori-
cal science. Phylogenetic trees represent the history of lineages and lineage
splits through time. Constructing trees is the starting point for nearly every
study in evolutionary biology today. Trees provide the historical information
that is used as the essential background framing for explanations, recon-
structing events in the past, and understanding trends through time. It is not
surprising that a common paraphrase of Dobzhansky’s famous dictum about
evolution is that “nothing makes sense except in the light of phylogeny.”

The ability to properly read and understand trees is what Robert O’Hara
(1988) memorably termed “tree thinking.” As he later put it, “Just as begin-
ning students in geography need to be taught how to read maps, so beginning
students in biology should be taught how to read trees and to understand
what trees communicate” (O’Hara 1997). This is especially important given
our common tendencies toward group (class/kind) thinking and ladder think-
To contact the author, please write to: California Institute of Technology, Division of Hu-
anities and Social Sciences, MC 101-40, Pasadena, CA 91101; e-mail: joel@joelvelasco.net.

Thanks to audiences at the 2010 PSA meeting, the 2011 ISHPSSB meeting, Caltech, Ohio State,
ustavus Adolphus, and Texas Tech who heard parts of versions of this article and to Matt Barker,
enny Easwaran, Luke Glynn, Matt Haber, Matt Slater, and Elliott Sober who also provided com-
ents on this article.

hilosophy of Science, 79 (December 2012) pp. 624–636. 0031-8248/2012/7905-0027$10.00
opyright 2012 by the Philosophy of Science Association. All rights reserved.
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ing as well as the ubiquity of misleading diagrams of evolutionary history
(see Baum and Smith 2012).

Figure 1. Phylogenetic tree of some chordate groups with the origin of a few key
traits marked.

TREE THINKING WITHOUT THE TREE 625
It was Darwin in The Origin (1859) who first used trees to emphasize the
importance and explanatory power of common ancestry. For example, the
phenomenon of homology was well known before The Origin, but it was un-
clear why, for example, bats, birds, crocodiles, frogs, humans, and turtles
would have the same (homologous) bone structure in their limbs—a humerus
attached to a radius and ulna, attached to carpals, metacarpals, and phalanges,
and so on—despite the obviously different functions that these limbs per-
formed. We can see how Darwin explained homology by examining figure 1.

The tree represents the passage of time from left to right, with the tips of
the tree representing extant groups. The tetrapods—amphibians, reptiles,
mammals, and birds—all have four limbs with a common limb structure,
whereas all these except the amphibians have a watertight egg. Darwin’s ex-
planation of why these groups have the common tetrapod limb structure is
that it evolved once in the evolutionary past in one particular group and has
been transmitted down the branches to all the descendants of that group.
Similarly, the watertight egg evolved one time (on the amniote branch after
it split from the amphibian branch) and was passed down.

We can already see from this example the key features of the information
that trees convey. We assume that traits are passed downstream on a branch,
and we assume that they are not passed on to any nondownstream branches.
Lineage separation represents isolation.

Moving from the fact that homologous traits could possibly be explained
by common ancestry to the truth of the nested hierarchy and the branching
structure of the tree is not trivial. Perhaps other structures might also explain
homologous traits. On the special creation model, the tetrapod limb is simply
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a good design structure. It is not that hard to see why a creator might reuse a
design multiple times if it is simply a good design. On a ladder or great chain-

626 JOEL D. VELASCO
of-being picture, we can imagine that there is some kind of hierarchy of
traits, the lower creatures having the basic ones while the more advanced
creatures have more and more of the advanced traits until, finally, humans
are the only earthly species with the highest traits (like intelligence).

The easiest way to see the problem with the ladder is to think about mul-
tiple traits. On the ladder picture, a single trait can divide species into two
groups—those that have the trait in question and those that do not (hair di-
vides mammals from everything else). We could think of a linear ordering of
all of these groups with those that do not have the trait as more ancestral than
those that do. But when we look at a second trait (say feathers), it will group
different organisms into the ‘higher’ category (birds vs. nonbirds). So who is
higher on the evolutionary ladder, mammals or birds? The obvious answer is
that there are at least two ladders. And if we look at traits only found in turtles
(like the shell) it is obvious that neither birds nor mammals came from turtles;
rather, there is a third line leading to turtles, and so on. This reasoning leads to
a branching explanation of trait distribution, not a ladder explanation.

Of course naturalists were long aware of the distribution of traits, and
Lamarck’s ladder cannot be used to explain homology. Notice in figure 1 that
all of the groups that have a watertight egg also have four limbs. One group
is nested inside the other. However, there are no organisms with gizzards that
also have hair. Those groups are completely disjoint. If every trait evolved only
once, we could map the traits onto a tree and form a perfect group-within-
group structure that would be the phylogenetic tree of life. It would directly
give us our trait-based classification of groups in a nested hierarchy. Linnaeus
already had the hierarchical part of the tree structure, but he had no explana-
tion for this. The branching of genealogy explains the hierarchy of classifica-
tion, and nothing else does. This is why Darwin considered the evidence from
hierarchical classification to be the strongest evidence for his theory. Nesting
is logically consistent with special creation, but it is explained by a treelike
common ancestry.

This centrality of treelike ancestry manifests itself in the ubiquitous use of
phylogenetic trees across different problem areas. Treatments of many prob-
lems in systematics require the use of phylogenetic trees. Studying adap-
tation, biogeography, or comparative biology all requires the use of trees.
More general framework questions, such as to what extent there is a mo-
lecular clock, can only be answered once a phylogeny is in place. Testing
trends, such as whether mammals have increased in size over time, requires
the tree. Basically, for any questions that can only be answered in the light of
knowing the history of the group, the phylogenetic tree is the essential back-
ground information needed to get started answering such a question. More
generally, historical information is required for systematic studies. What I
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will call the realist defense of trees says why this is so: trees are essential pre-
cisely because they represent the real history.

TREE THINKING WITHOUT THE TREE 627
2. Worries for the Tree of Life. The centrality of phylogenetic trees ex-
tends to the construction of the universal tree of life. But there are serious
problems with that tree. Many biologists have claimed that there is no such
thing and that tree thinking can often constrain us and blind us to the truth.
For detailed arguments, see the special issues on the tree of life in Biology
and Philosophy (2010) and Biology Direct (2011). For brief overviews, see
O’Malley, Martin, and Dupré (2010) and Velasco (2013). Here, I will men-
tion only some of the most serious issues, which have an important feature
in common.

A natural way to think about individual phylogenetic trees is that they are
subtrees of the big, universal tree of life, which represents how all species are
connected (Velasco 2010). Some worries are specific to the universal tree of
life. For example, it is not clear that there is a single universal common an-
cestor at the root of the tree. But here, it must be pointed out that this is a
special problem for the universal tree and for deep time questions such as the
origin of cells. Even if in the end, we must give up the belief in the universal
tree, this has no direct consequences for the existence of trees at smaller
scales. If we are looking at a tree of Darwin’s finches, then as long as they do
in fact have a uniquely shared origin, there is no parallel problem with there
being a single rooted tree in this domain that serves exactly the same explan-
atory purposes and plays exactly the same inferential role as before. There is
no need to overgeneralize to all life in order to justify the use of particular
trees.

Perhaps the most dramatic problem with the tree is endosymbiosis. In en-
dosymbiosis, one organism comes to live inside another and eventually be-
comes an obligate symbiote. Over time, they are so tightly interconnected
that it is no longer appropriate to think of the situation as one organism living
inside another but, rather, as one integrated organism. Different understand-
ings of endosymbiosis will be more or less strict about what counts as a
new entity, but even on the most conservative understandings, the origins
of mitochondria and chloroplasts will count as two separate lineages merg-
ing into one, and the origin of the eukaryotic cell itself might be such an event
(O’Malley 2010). Endosymbiosis could hardly be more important to the his-
tory of life on this planet. But endosymbiosis involves the combination and
complete transformation of two lineages—sometimes as distantly related as
is possible on earth—and fuses them into a completely new lineage of a new
kind of organism.

As mentioned earlier, the tree typically represents genealogical connec-
tions between species, and thus separations of lineages represent the genetic
isolation of different species. But we know that organisms of different spe-
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cies can and do hybridize. Mallet (2005) surveys a variety of studies of hy-
brids and concludes that at least 25% of plant and 10% of animal species

628 JOEL D. VELASCO
form hybrids with other species in nature.
The most common way for different species to share genetic information

is via lateral gene transfer (LGT) in which genetic information is physically
transferred from one organism to another preexisting organism. LGT had
been conclusively shown in the 1940s to happen in the lab, and it was known
to be responsible for the spread of antibiotic resistance in the 1960s (Sapp
2009). But just how widespread LGTwas in nature was not known. It is now
known to be pervasive. Traits that are transferred from one lineage to another
via LGTshow that there is something wrong with our tree explanation of the
distribution of many homologous traits. It is not that there is some other ex-
planation for their nested group-within-group structure. Rather, for a great
many traits, they are not distributed in a group-within-group hierarchy in
the first place. LGT undermines central systematic concepts like phylogeny,
lineage, and species, and O’Malley and Boucher (2005) consider LGT to be
the major cause of an ongoing paradigm shift in microbiology beyond just its
role in systematics.

Endosymbiosis between lineages, hybridization between species, and
LGT between organisms all show that there are possible routes by which
changes on one lineage can have cross-stream, rather than just downstream,
effects on other lineages. Crucially, this is inconsistent with a branching tree
pattern. If we take seriously the realist idea that the tree of life represents the
genealogical pattern of evolutionary history, then the “tree” will not be a
phylogenetic tree but, rather, a complicated web or network of some sort.
Even very simplified drawings will look something like figure 2.

The empirical evidence is clear; there are a great many nontreelike pro-
cesses that produce nontreelike genealogical patterns in nature. The realist
is forced to become a realist about networks rather than trees.

3. Modeling and Idealization. These attacks on the reality of the tree struc-
ture in nature are not easily dismissed. Defenders of trees will often attempt
to minimize just how bad things are, by arguing that endosymbiosis and hy-
bridization are rare or that LGT happens only in prokaryotes (only in the vast
majority of life on earth?). A common response from those who attack the
use of trees is that these phenomena are much more widespread than com-
monlyappreciated. While I agree that the extent of suchphenomenais widely
underappreciated, such empirical questions can hardly matter to the realist
who is trying to insist that evolutionary history is accurately represented by
a single tree. It is not. Whether hybridization is rare or common, it is clearly
not nonexistent, and from the realist point of view, that is all that matters.

However, debates about the extent of these phenomena make perfect
sense if we think about trees as models. Here the relevant question is not
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whether the history is a tree but how good a model is that depicts history as a
tree (Franklin-Hall 2010). We can call the modeling defense of trees the view

Figure 2. Web of life that represents the history of lineages when we take into ac-
count various lateral transfers of genetic information as well as vertical reproduction.
Source: Doolittle (1999).

TREE THINKING WITHOUT THE TREE 629
that trees are useful because they are very good models. Models contain ideal-
izations. Roughly, idealizations deliberately simplify or alter something com-
plicated in order to better understand it or to better understand something else.
Philosophers of science have pointed to a number of different ways that ideal-
izations are used in scientific practice. Here I will follow Weisberg (2007) in
distinguishing three kinds of idealizations. While Weisberg’s particular tax-
onomy of idealizations is not essential to my project, it does provide a useful
expository strategy.

First, there are examples of minimalist idealizations. Here, the model con-
tains only the core causal factors that are relevant in the situation at hand.
Obviously, there are many aspects of genealogy that a tree does not repre-
sent. If we have a tree representing the great ape species, we know that traits
are actually inherited by individual organisms, not by species. But for at least
some uses of trees, these details are simply ignored as irrelevant to the prob-
lem at hand. We can treat character traits as being transmitted by lineages
along branches of the tree without any problems. This kind of idealization
has been called abstraction (e.g., Cartwright 1989) or Aristotelian idealiza-
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tion (Frigg and Hartmann 2012). It is easy to see how abstracting away from
details that do not matter could help us better understand and explain some

630 JOEL D. VELASCO
phenomenon like the particular distribution of traits.
While sometimes we can abstract away from irrelevant details, other

times we idealize away details that do make a difference. However, even in
some of those cases we are justified in thinking that the effects are small for
the purposes at hand and that, therefore, it is permissible to ignore them. For
example, tree models assume that once a lineage splits from another, changes
such as mutations on one lineage do not affect isolated lineages. Hybridiza-
tion and LGTshow this assumption to be false. Sometimes we simply ignore
these effects as real but small. Inferences that use trees will assume no such
effects, but as long as you are aware of these possibilities, you will reason
that you are just making a fallible inference when you infer that, for example,
a trait has evolved independently in two different lineages.

The systematics of the past is dominated by minimalist idealization. Those,
such as Darwin and Haeckel, who built the first trees were well aware of
hybridization. But often, they were attempting to capture broadscale features
of the history such as the connections between the different classes of verte-
brates or the different orders of birds. The messy details of speciation were
simply irrelevant for these purposes. In contrast, systematists of the late
twentieth century built trees at all scales, and here the details of hybridization
do matter. Yet often, these details were simply ignored.

We now know that simply ignoring lateral effects will not do. Here, the
empirical studies on the extent of LGT and hybridization really matter. In
these cases, there is also a particular kind of problem that arises from initially
just ignoring these lateral effects. If you do not bother looking for lateral
events, you will build a tree that is capable of fitting the data and may not
notice that anything has gone awry. Standard phylogenetic methods simply
assume that the data are generated from a tree process and then find the best
tree to fit the data. This is no way to detect whether a tree is the right kind of
structure in the first place (Sober 2008). You simply cannot detect lateral
events, unless you specifically look for them. And there is no way of know-
ing ahead of time whether you are working with a group in which lateral
events play an important causal and explanatory role.

Now that we know that lateral events can significantly affect our under-
standing of the history of particular groups, systematists today often attempt
to directly estimate the incidence and effects of lateral events such as gene
transfer or hybridization, as well as the effects from vertical transmission. In
these cases, a second type of idealization is often used. This is Galilean
idealization, the introduction and later removal of deliberate distortions. The
name is due to examples such as when Galileo assumes that the earth is flat
over a short distance or that a rolling ball is perfectly spherical (McMullin
1985). Sometimes the removal of the distortion will make a nonnegligible
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difference, but this difference can then be estimated, and we can still see that
the original idealization was an essential part of the overall inference process.

TREE THINKING WITHOUT THE TREE 631
Phylogenetic networks that contain lateral branches as well as horizontal
branches are sometimes constructed by first building the tree that best fits the
data. Then we look for anomalies in the data, by, for example, adding lateral
branches one at a time and checking to see whether the measure of fit (e.g., a
parsimony or likelihood score) is improved by a sufficient amount. If so, add
the branch and then look for more. While this is an improvement over ignor-
ing possible lateral effects, this procedure is analogous to doing a multiple
regression by examining one variable at a time, and there are well-known
methodological problems with all such greedy methods (Velasco and Sober
2010). Some kind of “find the best network all at once” approach is needed.

Most of the work that I described above still operates under the realist as-
sumption that we are trying to find and represent the one true history of the
group. This history is complicated, but in principle, it is what we want to
know if we are to make further inferences. Much of the best work in system-
atics today in fact does quite a good job of inferring very complicated histor-
ical structures and patterns. But after reflecting on the fact that trees and net-
works are simply models of the history, new possibilities are opened up. It is
here that I think the most exciting and ultimately the most fruitful work in
systematics will be done. Here, we acknowledge that we are building models
to use for inferences and that these models will contain idealizations that are
not entirely accurate. But we accept that there is no need to show that these
idealizations are harmless. In fact, they can be beneficial to our inferences
and explanations.

The third kind of idealization is multiple models idealization, which in-
volves “the practice of building multiple related but incompatible models,
each of which makes distinct claims about the nature and causal structure
giving rise to a phenomenon” (Weisberg 2007, 645). Here, we do not expect
a single best model to be the final product. Rather, each model involves
trade-offs of better representing some aspects of reality at the cost of a worse
representation of others. An obvious parallel is the case of maps. Some maps
of New York City focus on the layout of the streets and ignore topographical
features, others carefully note changes in altitude but would not help you if
you were lost trying to find the library (Toulmin 1953; Kitcher 2001). This
kind of trade-off is clear in the decision to represent a group by a tree or a
network. We can represent the history of lineages quite well with trees, but
this will ignore connections such as those due to LGT. But complicated net-
works that attempt to represent all such connections distort or even destroy
the history of the lineages and cellular reproduction events. In general, we
can imagine that different models of the phylogeny of the same groups ide-
alize different aspects of this genealogy in different ways. For specific pur-
poses, one model might be better than another. But in general, there is no
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reason to expect that a single model will fare better for answering a num-
ber of different questions about the groups in question, just as there is no best

632 JOEL D. VELASCO
map. For certain purposes such as phylogenomic inference (inferring the
function of a gene from phylogenetic information), a phylogenetic tree that
depicts three separate domains of life and some of the major clades within
them really is a valuable tool in understanding diversity (Brown and Sjölander
2006). But not representing the endosymbiotic events that resulted in the ori-
gins of the plastids, mitochondria, and possibly all of the eukaryotes would
be tremendously misleading if we wish to understand some of the most im-
portant innovations in the history of life on earth.

In a review of plastid evolution, Archibald (2009) uses a phylogenetic tree
as an inference tool to discover exactly where and when endosymbiotic
events occurred in the past. This single figure contains both a network and
a special tree contained within this network. In order to reconstruct some-
thing like figure 3, first, note that the gain of an internal symbiote and tran-
sition to a new kind of organism is simply one kind of change that gets passed
along to descendants along the branch. Now use the current distribution of
the symbiotes, together with information from other traits, to reconstruct an
incomplete tree of the host cells that can itself be used to reconstruct the his-
tory of the past acquisition of symbiotes.

Archibald’s reasoning exemplifies tree thinking without the tree. We
know that the history of these organisms has been heavily influenced by lat-
eral transfer events such as repeated endosymbiosis followed by the massive
sharing of genetic information between symbiote and host. But in order to
understand this history, we must recognize that bits of the history such as the
vertical descent of the host cells form a tree.

This also exemplifies multimodel inference because in order to under-
stand one aspect of the history, we need to downplay or distort the history
of other events. It would be a mistake to look at arbitrary gene trees to build
the host tree in the first place since many of these will not share the host’s
phylogeny. To represent the history of such genes in the same model as the
vertical inheritance of others would obscure the unique role of the host cell.
Here, the tree model and the network model idealize different things, and
there is a necessary trade-off in the representations. Which model is to be
preferred depends on what you are trying to do.

On the smaller scale, it is obvious that forcing the history of Darwin’s
finches or human populations into a tree structure ignores information about
migration and introgression between populations, which is essential to un-
derstanding their history. For example, it has been argued that there has been
so much admixture in human history that the concept of race makes no bio-
logical sense (Templeton 1998; but see Andreasen 2004). However, trees of
human populations are quite useful for understanding major ancestral migra-
tory events (Soares et al. 2009). Obviously there are migrations between hu-
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man populations. But whether the amount of migration is “sufficient” to be
best represented as collapsing the distinction between different lineages de-

634 JOEL D. VELASCO
pends on what aspects of the lineages we are focusing on. For different in-
ference purposes, different representations of genealogical history focusing
on different aspects of that history are appropriate. Looking at trees of popu-
lations at the subspecific level, such as those of humans, is common in the
growing field of phylogeography (Avise 2000). This is a clear example of
the superiority of the modeling defense of trees since if there were genetic
isolation between these lineages they would represent different species.

One might think that we could get everything we want by simply “repre-
senting everything” in one giant model. This is false, not only because it
would be computationally intractable, which of course it would be, but also
because models that focus on the right things are more explanatory than
models that have no focus. An important part of the future of systematics will
be recognizing how to take advantage of the fact that different models of the
same phenomena can be independently fruitful (and fruitfully combined as
well). Learning new and interesting things about past history will always
be important. But learning when it is okay to ignore things we know can be
equally important.

4. Conclusion. We have seen that phylogenetic trees are ubiquitous in
biology. The justification for the use of trees has traditionally been that evo-
lutionary processes are in fact treelike. This justification is faulty. Attempt-
ing to interpret phylogenetic trees in a literal way leads to the view that these
trees entail many falsities about evolutionary history. Attacks on the univer-
sal tree of life thus appear to be justified. The goal of this article is to argue
that these attacks are not in conflict with the continued and justified use of
trees and tree thinking in biology. The use of phylogenetic trees can often be
completely justified, even if they are not entirely accurate representations of
the world. Instead, these trees are models that contain idealizations. These
models are used to better understand the world. Sometimes, for some pur-
poses, a tree model is inappropriate. But often, trees are entirely appropriate
and perhaps even the best models we have.

Modeling and idealizations are widespread throughout the sciences. There
is no particular reason to think that systematics should be any different. Evo-
lutionary history is complicated. It is a sign of the advancement of the
science of systematics not only that we take advantage of standard modeling
practices from other disciplines but that we understand that this is what it is
that we are doing. It is true that belief in the existence of the tree of life as the
big, universal, grand unifying, scale-free representation of all of the history
of life should probably go away (if indeed biologists ever did believe there
was such a tree). Whether we can still talk about the tree of life as some mod-
ified version of this idea is, I think, an open question. Whether the problems
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with the universal tree extend to smaller trees as well will depend on the par-
ticular details of the case in question. But whatever the outcome of these de-

TREE THINKING WITHOUT THE TREE 635
bates, phylogenetic trees and the importance of tree thinking are here to stay.
The future of tree thinking is bright, as long as we can recognize the impor-
tance of tree thinking without the tree.

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