ST? 
 
 '5? 
 
 NATURAL HISTORY AND PROPAGATION OF 
 FRESH-WATER MUSSELS :::::::: 
 By R. E. Coker, A. F. Shira, H. W. Clark, and A. D. Howard 
 
 From BULLETIN OF THE BUREAU OF FISHERIES, Volume XXXVII, 1919-20 
 Document No. 893 : : : : : : : : : : : : : : : Issued May 2, igsi 
 
 PRICE, 25 CENTS 
 Sold onlir by the Superintendent of Documents, Government Printing Office, Wasliington, D. C. 
 
 WASHINGTON :::::: GOVERNMENT PRINTING OFFICE 
 
 I9U 
 
Rook. (L ^9 
 
/^ 
 
 NATURAL HISTORY AND PROPAGATION OF 
 FRESH-WATER MUSSELS :::::::: 
 By R. E. Coker, A. F. Shira, H. W. Clark, and A. D. Howard 
 
 From BULLETIN OF THE BUREAU OF FISHERIES, Volume XXXVII, 1919-20 
 Document No. 8gj : : : : : : : : : : : : : : : Issued May 2, ig2i 
 
 PRICE, 25 CENTS 
 Sold only by the Superintendent of Documents. Government Printing Office, Washington, D. C. 
 
 WASHINGTON : 
 
 : GOVERNMENT PRINTING OFFICE : 
 
 ; 1921 
 
6< 
 
 -UrfTiWili — -~ 
 
 LIBRARY OF CQNQRESS 
 
 MAY 6-1921 
 
 DOCUMBNT& LiiV.uklON 
 
A 
 
 CONTENTS. 
 
 Page. 
 
 Introduction 79 
 
 Part I . Natural history of fresh- water mussels 81 
 
 Habits 81 
 
 Conditions of existence 81 
 
 Locomotion 82 
 
 Density of population 84 
 
 Breeding 85 
 
 Winter habits 85 
 
 Feeding habits 86 
 
 Food of mussels 87 
 
 Significance of the problem 87 
 
 Observations of Franz Schrader on food of mussels 88 
 
 Species studied 88 
 
 Food content of waters 88 
 
 Food discrimination under normal conditions i'. 89 
 
 Utilization of food materials ;........ 89 
 
 Experiments in feeding vegetable matter 89 
 
 Experiments in feeding animal matter 90 
 
 General observations 90 
 
 Observations of H. Walton Clark on food of mussels 91 
 
 Observations of A. F. Shira on food of juvenile mussels 93 
 
 Habitat 94 
 
 Body of water 94 
 
 Streams 94 
 
 I<akes 97 
 
 Ponds, sloughs, marshes, and swamps lOo 
 
 Artificial ponds and canals 100 
 
 Bottom loi 
 
 Depth 107 
 
 Light no 
 
 Current in 
 
 Water content 113 
 
 Suspended matter 1 14 
 
 Minerals in solution 114 
 
 Dissolved gases 117 
 
 Vegetation 118 
 
 Animal associates 119 
 
 Parasites and enemies 121 
 
 Parasites 121 
 
 Enemies 122 
 
 Conditions unfavorable for mussels 123 
 
 Natiural conditions 123 
 
 Artificial conditions 124 
 
 Growth and fonnation of shell 125 
 
 Measurements of gro\vth 125 
 
 Presence of so-called growth rings 129 
 
 Mode of fonnation of shell 129 
 
 Significance of rings 132 
 
 Abnormalities in growth of shell 133 
 
 77 
 
78 CONTENTS. 
 
 Page. 
 
 Part 2. Life history and propagation of fresh-water mussels 135 
 
 Introduction ^ 135 
 
 Historical note 136 
 
 Age at which breeding begins 137 
 
 Ovulation and fertilization 138 
 
 Brood pouches or marsupia 138 
 
 Seasons of deposition of eggs 140 
 
 Seasons of incubation of eggs 140 
 
 Glochidium 143 
 
 Stage of parasitism 148 
 
 Hosts of fresh-water mussels 151 
 
 Parasitism and immimit}- 155 
 
 Metamorphosis without parasitism 156 
 
 Juvenile stage 157 
 
 Artificial propagation 160 
 
 Principle of operation 1 60 
 
 Methods 160 
 
 Mussel culture 1 63 
 
 Part 3. Structure of fresh-water mussels 1O7 
 
 Introduction 167 
 
 The shell 168 
 
 External features i68 
 
 Internal features 169 
 
 DiversitTi' in form 1 70 
 
 The soft body 171 
 
 Form and functions of the mantle 171 
 
 Other conspicuous organs 172 
 
 Internal structure 173 
 
 Stmctiu'e and functions of the gills 174 
 
 Bibliography 177 
 
NATURAL HISTORY AND PROPAGATION OF FRESH-WATER 
 
 MUSSELS. 
 
 By 
 
 R. E. COKER, Assistant in Charge Scientific Inquiry, 
 
 A. F. SHIRA, Lately Director Fisheries Biological Station, Fairport, Iowa, 
 
 H. WALTON CLARK, Scientific Assistant, and 
 
 A. D. HOWARD, Scientific Assistant. 
 
 INTRODUCTION. 
 
 Adult fresh-water mussels are free-living but sedentary in habit. Though attached 
 to nothing they remain for indefinite periods nearly as still as if their position were irre- 
 vocably fixed. They have powers of locomotion but only occasionally use them. A 
 snail is expected to be in travel, however slow, in the search for food; but when a mussel 
 is found in motion the observer is inclined to look for a special cause of this behavior. 
 
 If a living animal remains generally in one place without going after its food, it 
 must have some effective mechanism for bringing food to itself, and it must also depend 
 in part upon outside agencies to convey its food within reach. In the fresh-water mus- 
 sel, the mechanism employed for food gathering consists of hundreds of thousands of 
 active microscopic paddles covering the flaps that hang from the side of its body. These 
 paddles are exceedingly minute and all within the shell; each is weak and ineffective 
 alone, but the effect of their concurrent action is to keep a strong current of water passing 
 into the mussel and out again. The water is filtered in passing, and the food, of course, 
 consists of the fine materials suspended and perhaps in part dissolved in the water. 
 The food in the water that lies within the influence of its currents is thus available to 
 the mussels; the natural circulation of the outside water must do the rest. 
 
 A single animal that finds food brought within its reach might live the full period 
 of its life in one spot, but all animals of a species can not live in the same spot. It is 
 inevitable, therefore, that at some stage in the life history of such an animal as the 
 fresh-water mussel, there must be a period of movement or of distribution by outside 
 agencies. Through one of nature's nice adaptations, such a period of migration or dis- 
 tribution occurs in the life history of the mussel at the stage of infancy. Even then the 
 mussel shifts the burden of its distribution upon fish, as will be more fully told in the 
 section on life history. As inactive in youth as in old age, the fresh-water mussel, hav- 
 ing taken passage upon a fish, may then travel extensively to find a new home far removed 
 from the scene of its birth. Its living conveyance dispensed with, the mussel settles 
 down to a relatively immobile existence. 
 
 Peculiarly victims of circumstance at all stages of existence, the fresh-water mus- 
 sels under natural conditions yet throve abundantly and broadly in streams and lakes 
 
 79 
 
8o BULLETIN OF THE BUREAU OF FISHERIES. 
 
 of this country and in those of other countries, but more especially in the Mississippi and 
 Great Lakes drainages. For them, however, times changed with the discovery that their 
 shells formed a good material for the manufacture of a universal necessity — buttons. 
 Equal as they were to the vicissitudes of natural conditions, they were unable to with- 
 stand the unchecked ravages of commercial fishery. Thus there has arisen the necessity 
 for measures of conservation— propagation and protection. 
 
 It is the purpose of the present report to present such an account of the structure 
 and habits and relations of fresh-water mussels as will serve to diffuse knowledge of 
 fresh-water mussels and interest in them, as may promote intelligent measures for their 
 conservation and efficiency in propagation and as may stimulate investigation of the many 
 problems presented by thebehavior, distribution, and propagation of mussels. Directed as 
 it is both to the layman and to the scientist, the report must labor under the disadvantage 
 of embodying matter that may seem trite to the scientist and much that may seem 
 overtechnical to the layman. As far as possible, however, the more technical data are 
 omitted or embodied in tables which can be passed over by those who are not interested 
 in the details. 
 
 The first part, on the natural history of mussels or the relation to their environments, 
 embodies data from many sources, but more especially from the general experience of 
 the several authors. In the second part is comprised perhaps the greatest measure of 
 original data gained from experiments and investigations conducted at the U. S. Fish- 
 eries Biological Station, Fairport, Iowa, though there are incorporated also results of 
 the published investigations of Lefevre and Curtis and of others. The third part, pre- 
 senting a summarized account of the structure, does not pretend to offer new data, but 
 rather to afford a background of knowledge of the mussel as a complex living animal 
 with many functions and needs. It might have been placed first but that it seemed best 
 to begin with the subjects which constitute the essential purpose of the paper. 
 
Bull. U. vS. B. F., ioio-2c 
 
 Plate Y 
 
 Fig. 1. — Rear view of yellow sand-shell in natural position 
 in bottom under water, showing the two siphonal open- 
 ings, the gaping shell, and the apposed margins of the 
 mantle. 
 
 Fig. 2. — Rear view of Anodonta corPulenta showing 
 siphonal openings. Note the very smooth margins of 
 the upper exhalent opening and the fimbriae or "feel- 
 ers" protecting the lower or inhalent opening. 
 
 -Tracks of >ouug mussels iu crate 
 
 Change in the conditions uf the water had caused them to ' 
 normally. 
 
 audcr more than 
 
PART 1. NATURAL HISTORY OF FRESH- WATER MUSSELS. 
 
 HABITS. 
 
 CONDITIONS OF EXISTENCE. 
 
 A mussel, in natural position in a stream, is partly or almost entirely embedded 
 in the sand, mud, or gravel of the bottom (PI. V, fig. i). Almost invariably it will be 
 found to have an oblique position, the front end of the body being directed down into 
 the bottom and in a direction with the flow of the current, while the hinder end of the 
 shell is exposed and is directed upward and against the flow of the stream. Unless the 
 mussel has been disturbed, the shell will be slightly gaping, with the edges of the mantle 
 protruding through the opening and closing it everywhere except at the rear (upper) 
 end where it is so arranged as to form two neat funnel-like openings. The upper open- 
 ing is usually the smaller, and the edges of the mantle about it are smooth or crinkled. 
 The lower opening is generally much longer, and the border of the mantle here is com- 
 monly adorned with a number of delicate feelers, or water testers as these may be called 
 (PI. V, figs. I and 2). The significance of the two openings can be easily ascertained 
 if a small amount of some colored liquid, such as finely powdered carmine in water, is 
 placed near to the openings in a mussel which has been allowed to remain undisturbed 
 in a small aquarium or dish of water. The carmine may be seen to be expelled forcibly 
 from the upper smaller opening, while, if placed near the lower opening, it will be drawn 
 in. It becomes apparent that the water is continually drawn in through the lower 
 (inhalent) opening and passed out through the upper (exhalent). In view of the func- 
 tions of the gills and the mantle, described on page 174, it may be understood that this 
 stream of water not only serves the purpose of respiration but also that, as it is strained 
 through the minute pores in the surfaces of the gills, it must yield up the microscopic 
 materials that serve as food for the mussel. The position of the mussel, directed against 
 the flow of the river, not only insures a more effective resistance should the current of 
 the river be excessively strong, but it perhaps gives the mussel greater advantage in 
 collecting the food floating with the current. In lakes where no regular current pre- 
 vails mussels may lie with their axes in any direction, but the oblique position in the 
 bottom is virtually constant for those that are not in movement. 
 
 The advantages of rivers over lakes for the growth of mussels may readily be in- 
 ferred. The mussel can draw in and strain only the water that is close about it, and in 
 the quiet water of a lake or pond new supplies of food are brought to its vicinity only 
 by the comparatively slow forces that cause the intermingling of the waters of the lake. 
 In the steady current of a river, on the other hand, the same water is never strained 
 twice by the same mussel and, besides, the action of the current tends to stir up the 
 small organisms and nutritive sediment which abound in the surface scum of the bottom. 
 Observations by Clark indicate that mussels in lakes feed more largely upon plankton 
 than those in rivers, the latter of which contain in their stomachs chiefly detritus or 
 
 81 
 
82 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 finely divided nonliving organic materials. The rate of growth of mussels generally is 
 much higher and the size attained is greater in rivers than in lakes. Other factors 
 than currents, of course, enter into consideration, and these will be discussed in the 
 appropriate places. 
 
 A chief condition of rich growth of mussels is a plentiful food supply, and not all 
 rivers are alike in this regard. There are relatively fertile and relatively sterile rivers 
 and lakes, and the fertility of streams is likely to correspond in a rather general way 
 with the fertility of the lands from which the drainage is derived. Whatever materials 
 suitable for the construction of plant tissues are brought into the waters are likely ulti- 
 mately to be converted in great part into plant or animal life, and no little part of the 
 plant life that is formed is likely to be converted ultimately into animal life. 
 
 A primary condition for the formation of thick shells of good quality is the presence 
 in the water of suitable minerals, principally calcium, and all of the important mussel- 
 bearing streams are those whose tributaries flow from regions of limestone or other cal- 
 careous deposits. Consequently it is the Mississippi Basin which largely supports the 
 pearl-button industry, though shells of commercial value are also found in the Great 
 Lakes and Gulf of Mexico drainages, and some in the Red River of the North. The 
 streams of the Atlantic and Pacific slopes are almost or entirely barren of valuable 
 shells. 
 
 Many factors, indeed, enter into the suitability of waters for mussels, and of the 
 various species of mussels — more than 500 in the United States — each has its special 
 requirements; some will thrive where others will not. Much remains to be learned 
 concerning the relation of mussels to their environment, and the subject is particularly 
 complex because of the great number of species involved; but it will be attempted to 
 place the several phases of that subject in general review in a later section on habitat 
 (p. 94). It is the purpose of this section to give such a general account of the habit of life 
 and the conditions of existence as is necessary to establish the peculiar dependence of 
 fresh-water mussels upon the immediate environment. 
 
 LOCOMOTION. 
 
 As regards their place of abode, fresh-water mussels are very largely creatures of 
 circumstances. Since they are not frequently seen in motion it is probable that most 
 of them spend their lives after the period of infancy very near to the place where they 
 first settle down. Nevertheless they can and do move, and certain species, principally 
 the more elongate forms, manifest a condition of restlessness at times. 
 
 All mussels are sensitive to some stimuli; a splash of the water near them, a touch 
 on the edges of the mantle especially at the siphons, or the passing of a shadow over 
 them, will cause the siphons to be withdrawn and the shell to be tightly closed. There 
 are evidences to indicate that when the disturbance is severe, as when the mussel is 
 taken entirely out of the water, or is exposed to the sun by an unusually low stage of 
 water, or is affected by extreme cold, the withdrawal of the mantle is so extreme as to 
 break the living connection with the edge of the shell, and thus to cause, when growth 
 is resumed, an interruption line or plane in the shell which is present ever afterwards. 
 (See p. 132.) 
 
 The reaction to evident stimuli consists merely in closing up; there are times, 
 however, when a mussel is impelled to change its position. The inoverrjent may then be 
 
FRESH-WATER MUSSELS. 83 
 
 in a vertical direction, the mussel going down deeper into the bottom; rarely does it go 
 completely beneath the surface of the bottom; more frequently the mussel moves 
 horizontally, leaving a distinct path behind it, which reveals the direction and dis- 
 tance of travel. Locomotion is accomplished by thrusting the muscular foot forward 
 into the bottom, expanding the outer end, and then contracting special muscles so as 
 to draw the shell and body nearer to the end of the foot. Mussels that are most likely 
 to travel in this way are the yellow sand-shell, black sand-shell, and slough sand-shell, 
 species that are relatively long and narrow. Rotund forms, like most of the species of 
 Quadrula, are less likely to migrate, but, of the Ouadrulas, perhaps the most vagrant 
 form is the very elongate rabbit's-foot, Ouadrida cylindrica.'^ The pocketbook, Lamp- 
 silis ventricosa, and the pink heel-splitter, Lampsilis alaia, are also fairly active. Juvenile 
 mussels are more active than adults. (PI. V, fig. 3.) 
 
 The causes of movements from one location to another are not known and the 
 subject offers an interesting field of study. Change of pressure (depth), temperature, 
 or more probably light may be the governing factor. Yellow sand-shells move up on 
 the shoals or toward shallow water in times of flood, and return toward deeper water as 
 the stage of water recedes. It is a matter of common report that after high-flood stages 
 these mussels are sometimes found stranded in the swamps at some distance from the 
 ordinary channel of a river, but the authenticity of such reports is not established. 
 Headlee and Simonton (1904, p. 175) observed that fat muckets moved away from shore 
 during periods of high-wave action. 
 
 Isley (191 4) tagged and planted large numbers of mussels in comparatively shallow 
 natural waters and after several months recovered a considerable percentage of them, 
 finding very little evidence of migration. The Quadrulas placed in water over 3 feet 
 deep remained approximately where planted ; those placed in water as shallow as i foot 
 moved to deeper water, which was easily reached. The species of Lampsilis used in 
 the experiments showed more acti\aty, but none were discovered which had moved more 
 than a few yards. He concluded from his experiments and field obser\^ations that 
 mussels, especially the Quadrulas (heavy-shelled mussels) and related species, were 
 unable to help themselves if conditions became unfavorable, but that, on the other hand, 
 their power to endure unfavorable conditions was remarkable. 
 
 From observations in Lake Maxinkuckee, Ind., Evermann and Clark (1918, p. 256) 
 say: 
 
 The rau.ssels in shallow waters near the shore move into greater depths at the approach of cold 
 weather in late autumn or early winter and bury themselves more deeply in the sand. This movement 
 is rather irregular and was not observed every' year. It was strikingly manifest in the late autumn of 
 1913, when at one of the piers off Long Point a large number of furrows was observed heading straight 
 into deep water, with a mussel at the outer end of each. The return of the mussels to shore during 
 spring and summer was not observed. [These were mostly Lampsilis luteola, the fat mucket.] 
 
 It is evident from the available data that the locomotion of fresh-water mussels 
 can play little part in their distribution. Distribution is, in fact, effected principally 
 during the period of parasitism on fish, when it is governed by the migrations of the 
 hosts. When dropping from the fish, the little mussels are naturally subject to the 
 force of the current, and some that fall in unfavorable environments may be carried to 
 a more suitable place, while others falling upon good ground may drift into a less favor- 
 
 » Wilson and Clark (1914. pp. 35 and 59) have noted a particularly vagrant habit for Quadrula cylindrica. 
 
84 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 able situation. Distribution by currents presumably has little practical effect, except, 
 perhaps, in the case of such a thin-shelled species as ^4 yiodcmla imbecillis. 
 
 DENSITY OF POPULATION. 
 
 Strange stories are heard of the density of mussels in beds. It has been said that 
 the living mussels in certain beds were in a layer 2 feet deep. Such stories, persistent 
 among clammers, are, of course, based upon faulty reasoning. A bed is gone over 
 repeatedly with crowfoot bars, and with continuing success, but the fact is overlooked 
 that the appliance takes mussels only at random. A layer of mussels is not moved at 
 each drag. A particular bed in the Mississippi River, more than a quarter of a mile 
 long and 100 yards wide, was insistently described as being uniformly 2 feet deep in 
 mussels. Further inquiry elicited the information that the bed was virtually cleaned 
 up in a season and that about a half dozen carloads of shells were obtained. A simple 
 calculation showed that, had the bed been as described, at least 30 trains of 100 cars 
 each would have been required to move the shells obtained. Other stories relate to 
 such observations as the taking of mussels by suction dredges after excavating deep 
 holes in the bottom, no consideration being given to the possibility of a mussel falling 
 in with the caving sand from above. 
 
 In planting operations and in experiments involving the retention of mussels for 
 considerable periods, if normal health and growth are desired it is important to know 
 how closely mussels m.ay be crowded. The following observations are therefore offered. 
 
 The place of densest mussel growth observed by the senior author in the Grand 
 River, Mich., in 1909, yielded 52 living mussels of 6 species from a space 6 feet long by 
 3 feet wide, giving a density of about 3 mussels per square foot. Clark and Wilson 
 (191 2, p. 20) found a most favorable place for observations of density in the Feeder 
 Canal, near Fort Wayne, Ind., which had been recently drained. The bottom of the 
 canal had been abundantly populated with mussels and from i square meter they took 
 81 mussels of 8 species, or about 7^ per square foot. At the place of greatest observed 
 density in the Clinch River, Tenn., J. F. Boepple took 66 mussels of 10 species from an 
 area which he estimated to be 4 square feet; if his estimate was correct, the density 
 was 16K per square foot. 
 
 At all of these places mentioned, mussels occurred in such striking and unusual 
 abundance as to suggest to experienced observers the desirability of making actual 
 counts. It is fair to assume, then, that the natural occurrence of more than three or 
 four mussels per square foot over any considerable area is unusual and that plantings 
 of large mussels in greater density are warranted only where the conditions are shown 
 to be particularly favorable. 
 
 Very small juveniles may safely be planted more closely. Howard reared for a 
 season 217 juveniles in a floating crate iS by 24 inches, but the rate of growth among 
 them was very variable. (PI. V, fig. 3.) In other rearing experiments at Fairport (con- 
 ducted by F. H. Reuling) 2,006 juvenile sand-shells were obtained from a trough 14 
 feet long and i foot wide, a density of 143.3 per square foot. In another trough of the 
 same size, 3,016 juvenile Lake Pepin muckets were reared, a density of 215.4 P^r square 
 foot. It is not to be assumed, however, that the young mussels would have lived long 
 and grown normally while crowded so closely as were these. 
 
FRESH-WATER MUSSELS. 85 
 
 BREEDING. 
 
 The internal phenomena connected with reproduction are presented in connection 
 with the discussion of life history (Part 2, p. i38ff). Wehave to do here only with the very 
 few external manifestations which have been obser\'-ed as related to the breeding 
 activities. 
 
 The eggs are fertilized by sperm emitted into the water by males and taken in 
 with the inhalent current of the female. In a few species the females, when about to 
 spawn, are marked by a striking development of lurid colors and elongate flaps on the 
 margin of the mantle about the inhalent orifice. In addition to the bright colors there 
 are peculiar spasmodic movements of this part of the mantle. This peculiarity has been 
 observed in a good many pocketbooks, Lampsilis ventricosa, in a few fat muckets, 
 Lampsilis luteola, in some L. radiata, L. orhkulata, L. higginsii, and L. ovata (grandma), 
 and in nearly all of the L. multiradiala which have come under observ'ation. (See Clark 
 and Wilson, 1912, p. 54; Wilson and Clark, 1912, pp. 13, 14; and Evermann and 
 Clark, 1918, p. 284.) Ortmann (191 1, p. 319) has described such flaps in Lampsilis 
 ■ventricosa and L. multiradiala. He obser\^es that when the gravid females are undis- 
 turbed the marsupia are pushed outward, so that they project out through the inhalent 
 opening and even a little beyond the shell, as previously figured by Lea. The waving 
 flaps lie alongside the marsupia, and he attributes to them a function in promoting a 
 current of water over the marsupia. It seems more probable that these conspicuous 
 flaps, which sometimes suggest the appearance of small fish, may serve as a lure to fish, 
 bringing them into desirable proximity to spawners when the glochidia are ready for 
 extrusion, thus rendering the fish liable to infection and so increasing the chance of 
 survival of the glochidia. The following is quoted from Wilson and Clark (1912, pp. 
 13. 14): 
 
 The mussels were thickly scattered everywhere, with especially dense beds along the shore. The 
 small fish were again noticed playing about in the immediate vicinity of the spawning mussels. 
 
 L. veniricosus has a habit of moving its bright-yellow siphon fringes, which are much enlarged during 
 spawning, back and forth in the water. This undulatory motion seems to attract the small darters 
 and minnows, particularly Notropis blennius, which could be seen darting in toward the fringes 
 repeatedly. It also probably assists in furnishing fresh water for the respiration of the young mussels. 
 
 .\t intervals during the undulations small numbers of glochidia are discharged from the brood 
 chambers of the mussel .and carried out of the excurrent aperture. These glochidia are of the hookless 
 type, and must be taken into the mouth of the fish that is to carry them during their parasitic period. 
 We can thus understand the advanfcige of attracting these fish and keeping them in the immediate 
 vicinity during the discharge of the glochidia. 
 
 WINTER HABITS. 
 
 Very little is known of the habits of fresh-water mussels in winter. Observations 
 of rate of growth indicate that growth practically ceases during the very cold months. 
 (See Isely, 1914; and also p. 132.) Microscopic studies of sections of shell indicate that 
 there are numerous slight interruptions and resumptions of growth, corresponding to 
 each period of winter, and these are no doubt related to the fluctuations of temperature 
 in fall and spring. 
 
 According to clammers, mussels cease to "bite" with the approach of cold weather. 
 The observations of Evermann and Clark on the movement of certain mussels from the 
 very shallow waters near the shore of Eake Maxinkuckee in late fall have been previously 
 
86 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 quoted (p. 83). They do not generally migrate or bury themselves, however, but 
 simply become benumbed so that they respond very slowly if at all to such stimuli as 
 the touch of the clammer's hook. Evermann and Clark (19 18, pi 256) also observed that 
 mussels are not altogether inactive in midwinter : 
 
 Occasional mussels were observed moving about in midwinter, even in rather deep waters. During 
 the winter of 1900-1901 , an example of Lampsilis luteola, in rather deep water in the vicinity of Winfield 's, 
 wasobserved to have moved about 18 inches in a few days. Its track could distinctly be seen through 
 the clear ice. 
 
 FEEDING HABITS. 
 
 It has been previously noted that a mussel in normal condition on the bottom 
 keeps a stream of water continually passing in through one of two siphonal openings 
 and out through the other. The food is derived from this current as it passes through 
 the gills. The manner in which the food is collected and taken to the mouth has been 
 well described by Allen (i9i4,p. 128 ft) from studies conducted at the Indiana Universitj 
 Biological Station, Winona Lake, Ind. 
 
 The filaments of the gills are covered with cilia which intercept the particles contained in the water 
 and prevent their passing through the gills with the water. They become entangled in mucus, and 
 tlirough the action of these cilia such particles are wafted toward the mouth in streams. If they are of 
 a harmless nature or of food value, they are permitted to enter the alimentar)' tract. During the incuba- 
 tion of the glochidia, the female gives up a greater or less part of one or both of the gills for marsupial 
 purposes. At this period these parts are of little use for respiration or for the collection of food. 
 
 Cilia similar to those of the gills line the entire branchial chamber, cover all organs which come into 
 contact with the water, and also line the alimentary tract. They are, as is always true of cilia, in con- 
 stant motion during life; they act independently of nervous control and in a single plane. Their con- 
 certed action is in the fonn of waves — resembling in appearance the passing of a breeze over a field of 
 grain, or the movement of a bank of oars. The direction which these waves or streams take varies in 
 the several organs. But all of the streams taken together are coordinated to accomplish a certain common 
 end. * * * 
 
 The mouth of the Lamellibranch lies nearly as far as possible from the external openings, just 
 behind the anterior adductormuscle. It is thus well protected from the entrance of harmful substances. 
 It is flanked above and below by the thin narrow lips. The upper lip is continuous with the outer 
 labial palp on each side, while the lower lip is prolonged into the inner right and left palps. Most of the 
 ciliar\' currents of the contiguoiis faces of the palps and of the lips are directed forward to the mouth. 
 The outer or noncontiguous faces of both palps and lips as vrell as the edge of tlie inner face of the lips 
 bear cilia which arc directed backward and away from the mouth. Thus particles which find their way 
 between the palps are carried to the mouth. As will soon be seen, very little undesirable matter ever 
 reaches the mouth or palps, but even here Wallengren (1905) has pointed out how selection and rejection 
 may be made. 
 
 * * * The inner surface of the labial palps, except their outer margins, are made up of minute 
 
 vertical ridges, or furrows. These constitute a quite complex mechanism for the sorting of material. 
 » * -r, 
 
 Upon the ridges as elsewhere occurs a ciliated epithelium. But the ciliar>' currents are disposed 
 in a unicjue manner. Upon tlie anterior slope of each ridge they are directed backward while those 
 on the posterior slope lead foi-ward. This seeming conflict is not such in fact, because only one set 
 of cilia comes into action at a time. The position of the ridges determines which set shall function 
 at a given moment. Thus tlie after slopes are ordinarily brought uppermost, the ciliary currents leading 
 to the mouth are upon the surface, while the cilia which lead from the mouth lie somewhat underneath 
 the ridges. So long as no adverse stimuli are received, particles which lie between the palps are thought 
 to be passed on forward from one ridge to another, to the lips and mouth. 
 
 In the event that distasteful matter reaches the palps a reflex erection of the ridges brings upper- 
 most the cilia leading backward and such material is returned from summit to summit to the edge of 
 the palps and discharged into the mantle chamber. * * * 
 
fresh-water mussels. §7 
 
 The entire epithelium touching the brajichial chamber is abimdantly supplied with glands which 
 secrete a mucous substance. The mucus envelops and binds togetlier in strands the material to be 
 trans]X)rted by the cilia. This is particularly Uue of those particles which are of a very distasteful 
 nature. * * * 
 
 Observers have differed widely in their notions of the ability of the mussel to select its food. To 
 me it is evident that there are, to summarize, four points where such choice is exercised: 
 
 (i) The labial palps, at the upper margin. 
 
 (2) The labial palps, on the furrowed surfaces. 
 
 (3) The mouth. 
 
 (4) The incurrent siphon. 
 
 As to the last, it is surromided by a row of pointed, fleshy papillae, having a resemblance to plant 
 structures. These have two senson,' functions — tactile and gustator>' ; for upon being disturbed mechan- 
 ically they are withdrawn into the shell, while a continued teasing, or a strong chemical stimulus results 
 in the closing of the shell . 
 
 Allen conducted experiments the results of which indicated that a mussel siphons 
 a liter of water (about i quart) in approximately 42 minutes. From other observations 
 he was led to infer that mussels pass food through the digestive system somewhat auto- 
 matically or regardless of appetite, but that the secretion of digestive juices and the 
 utilization of the food ingested may be controlled according to the needs of the mussel. 
 
 Allen gives a list of diatoms, desmids and other algte, and miscellaneous food items, 
 but without quantitative data or appraisal of the relative values of the different sorts 
 of food and without reference to the presence of plant detritus in the stomachs. Seem- 
 ingly he supposed, as did many others before him, that mussels subsisted almost exclu- 
 sively upon living organisms. Data bearing on this question are presented in the 
 following section. 
 
 FOOD OF MUSSELS. 
 
 SIGNIFICANCE OF THE PROBLEM. 
 
 The fact that the rate of growth of mussels seems so directly proportionate to the 
 thickness of the shell (p. 129), or, speaking from a physiological point of view, to the 
 mineral requirements of the mussel — for the shell is chiefly mineral — leads naturally 
 to the supposition that the limiting factor of growth is not the organic food supply, 
 but the mineral food supply. This is a rather startling inference, since we are accustomed 
 to view animals in nature as engaged in a fierce competition for food, their numbers and 
 the luxuriance of grovvth being proportioned to the abundance of food available; and 
 the food we ordinarily think of is the organic (animal and vegetable) substance required 
 rather than the mineral matter. Yet, if it could be assumed that the food requirements 
 of a floater mussel are of the same nature as those of a pimple-back, then, since in the 
 same body of water the floater with its shell of paperlike thickness may attain a length 
 of 3^ inches in two seasons, while the pimple-back with thick shell may not in the same 
 period attain a length of more than about an inch, the conclusion would seem probable 
 that the thick-shelled species was restricted in growth, not for deficiency of organic 
 food, but for lack of the materials necessary for the formation of shell. The assumption 
 proposed, viz, that the food requirement of the different species is virtually identical, 
 although plausible and substantiated by some evidence, can not be accepted as finally 
 proved. 
 
 It becomes of importance to determine what is the food of fresh-water mussels, 
 whether the requirements of different species are the same, whether there is serious 
 competition for organic food between commercial and noncommercial species, and 
 
88 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 whether there is a sufficient food supply in water in whicli it is desired to promote an 
 abundant growth of mussels. 
 
 Three bodies of evidence bearing upon some of these questions are presented in 
 the following pages. One is a summary of the observations by H. Walton Clark, which 
 have been published elsewhere in part; another is a table embodying the results of 
 Shira's studies of the 60 juvenile mussels taken in Lake Pepin (Shira, unpublished 
 manuscript); the third comprises previously unpublished obser\'ations made in 1916 
 by Franz Schrader," formerly scientific assistant in the Bureau of Fisheries. The last 
 will be given first since the studies were directed more particularly at the questions 
 just presented. 
 
 OBSERVATIONS OF FRANZ SCHRADER ON FOOD OF MUSSELS. 
 
 SPECIES STUDIED. 
 
 Four species that were thought to be fairly representative were selected for investi- 
 gation: The river mucket, Lampsilts ligamentina, the Lake Pepin mucket, Lampsilis 
 luteola, the blue-point, Ouadrula plicafa, and the spike, Unio gibbosus. The first named 
 is a typical river mussel, and one of the most important of all from the button manu- 
 facturer's point of view — considering the quantity and quality of the shells together. 
 Lampsilis luteola, a shell of fine quality, is predominantly a mussel of standing bodies 
 of water, and is found to comprise 31.5 per cent of the entire shell output of Lake Pepin. 
 Qtiadrula plicaia, also a good button shell, is evidently equally at home in stagnant 
 and in flowing water. It is a member of a genus in general slow, ponderous, and heavy- 
 shelled. Finally, Unio gibbossus is a form of little commercial importance because 
 of its colored shell but is extremely common in some localities. Thus in Lake Pepin 
 13 per cent of the shells were found to be of this species, and it was thought that if 
 competition for food played an important part in mussel ecology, the presence of this 
 valueless form might be detrimental to the commercial species, especially when occurring 
 in such numbers as in Lake Pepin. 
 
 FOOD CONTENT OF WATERS. 
 
 The first step taken was to make a careful examination of the water. For this pur- 
 pose samples were taken from v>'ell-known mussel grounds. A water sampler operating 
 by means of valves that are closed through releasing the catch by a string was used. 
 The sample of water taken at from 2 to 4 inches from the bottom was treated with 
 formalin and the contents allowed to settle in the usual way. 
 
 The solid matter thus obtained may be roughly divided into three groups: (i) Min- 
 eral matter; (2) organic remains predominantly from plants (detritus); (3) plankton, 
 chiefly green algse and diatoms. The proportions of these were extremely variable, 
 varying not only with the season but also with changes in the river level. Plankton 
 varied from less than i to more than 20 per cent. The remaining material comprised 
 chiefly detritus, for, except after thaws or rains, the mineral matter seldom e:<ceeded 
 5 per cent of the total of solids. 
 
 Regarding the plankton, it may be said that relatively few forms made up the 
 greater bulk. Thus, among green alga there were Scenedesmus, Selenastrum, Pedi- 
 astrum, Cosmarium, and Volvox, the latter especially in the spring. In August greater 
 
 a Included with his consent. 
 
FRESH-WATER MUSSELS. 89 
 
 or lesser fragments of various thread algee, such as Spirogyra, increased in numbers 
 until they outranked all others in importance. The list of diatoms showed these forms 
 as important: Coscinodiscus, Synedra, Asterionella, and Navicula. In far smaller 
 quantities but generally present were Gyrosigma, Tabellaria, Gomphonema, Epithemia, 
 and a few others that are negligible for practical purposes. 
 
 In both quantitative and qualitative constitution no appreciable difference was 
 noticed between samples from Lake Pepin and those from the Mississippi River at 
 Homer, Minn. 
 
 FOOD DISCRIMINATION UNDER NORMAL CONDITIONS. 
 
 Having ascertained the materials available in the water as a possible source of 
 food, the next step was to determine whether the different mussels showed a preference 
 or dislike for any of these constituents. This necessitated an examination of the 
 stomach and intestinal contents of naturall}' feeding mussels. In every case the con- 
 stituents of the material obtained from the stomachs corresponded to those found in 
 a free state in the water. This refers not onl}' to the kind of material found but also to 
 the percentages, which were discovered always to correspond, at least roughly, to those 
 obtaining in the water at that period. Lastly, no difference was observed — ^in stomach 
 or intestinal contents — among any of the four fonns of mussels concerned. Thus, 
 under normal conditions no discernible degree of discrimination is e\inced. 
 
 UTILIZATION OF FOOD MATERIALS. 
 
 The question of the utilization of these materials was best solved by an examina- 
 tion of the feces. It was astonishing to note that only about one-half of the green algae 
 and diatoms were attacked to any degree by the digestive processes. In fact the 
 green algae, with their often delicate cell walls, on many occasions did not even lose 
 color. It was the detritus that underwent the greatest changes. The vegetable origin 
 of this material was easily discerned under the microscope before digestion had taken 
 place, but in the feces, after digestion, the substance was found almost always to have 
 undergone a radical change in appearance and in structure. It was evidently attacked 
 by the digestive processes to a much greater degree than the plankton. 
 
 These observations point to a comparatively unimportant role as played by algae 
 and diatoms in the food of mussels. Not only are these forms present in very much 
 smaller amounts than the dead-food materials but also they are not digested as well. 
 
 EXPERIMENTS IN FEEDING VEGETABLE MATTER. 
 
 Although under normal natural conditions no discrimination of food was observed, 
 conditions might easily arise which would bring about a radical change in the constit- 
 uents of this normal food supply. Feeding v/ith different materials was tried, therefore, 
 to determine any preference that the mussels might have. 
 
 The method used was to starve the mussels for four to five days and then feed 
 them with the material under investigation. In this way the intestine was first cleared 
 and the state of digestion of the fed material determined without any disturbing con- 
 tamination from substances previously present in the intestine. As starved mussels 
 may lose their sense of discrimination to a certain degree, an equal number of control 
 mussels feeding and living in a tank with a flow of river water were always experimented 
 on at the same time. The food was administered from a long pipette into the intak- 
 ing siphon. It is unnecessary to go into the details here, but it may be mentioned that 
 
9^ BULLETIN OF THE BUREAU OF FISHERIES. 
 
 the utmost care had to be employed so as not to feed particles of food exceeding a 
 certain size. A neglect of this caution invariably caused violent expulsion of the 
 whole dose of food, no matter what it was. 
 
 ThrBad Alg^. — These were accepted by all four species, but only in limited 
 quantities b)' the mucket, Lanipsilis Ugamentina. An examination of feces confinned 
 the previous observations that green algae are only very incompletely digested. 
 
 PalmellalES. — These soft, slimy, green algae gave no other result save that they 
 seemed somewhat better digested by the blue-point mussel. 
 
 Detritus. — This was artificially prepared by immersing the leaves and soft stalks 
 of plants that are generally found near the water in some water for a few days imtil 
 nitrogenization had set in. They were then macerated with mortar and pestle and the 
 resulting pulp strained through bolting cloth. All mussels took this artificial detritus 
 readily, and the feces showed the characteristic features of digested detritus. 
 
 Fresh Vegetable Material. — This was not so readily taken. 
 
 Vegetable Fat. — Olive oil in the form of an emulsion was accepted by the Lake 
 Pepin mucket and the river mucket. It was evidently thoroughly absorbed, as no 
 traces could be found after digestion. The blue-point and the spike were not tried with 
 this material. 
 
 experiments in feeding animal matter." 
 
 Fish Meat (heart of the wall-eyed pike, Stizostedion vitreum). — Two out of three 
 examples of the Lake Pepin mucket accepted this material readily, the third less so. 
 The control mussels vacillated, occasionally taking very small quantities. The other 
 three species evinced strong repulsion, expelling any of the substance taken in in from 
 I to 15 seconds. Abnonnal reddish feces. 
 
 Tails of Tadpoles (macerated). — These were refused or quickly expelled by 
 the river mucket and the Lake Pepin mucket. The other mussels were not tried with 
 this material. 
 
 Blood of Pickerel.— This was refused by all species, even when given in a state 
 of high dilution. 
 
 Animal Fat. — This was an emulsion of fat obtained from the sheepshead fish, 
 Aplodinotus grunniens. Extremely small doses at long intervals were taken and evi- 
 dently digested. 
 
 In all these cases the food matenal was generally readily taken (from i to 1 5 seconds) 
 into the siphon. After a varying period of time (a few seconds), the length of time 
 necessary for the substance fed to affect the taste organs, disagreeable food was always 
 expelled again. 
 
 The experiments do not point to any undoubted conclusion regarding animal food, 
 except that they seem to establish the fact that vegetable food is preferred to the animal 
 substances employed. Probably, under normal conditions, small quantities of the 
 latter are taken in with other substances, but it is hardly believed that it ever plays 
 a large role. 
 
 general observations. 
 
 Throughout the experiments it was noticed that the Lake Pepin mucket, Lamp- 
 silis luieola, was not so exact in its requirements as the river mucket, Lampsilis Uga- 
 mentina. The latter was indeed the most delicate feeder of the four species, and the 
 
 a Allen C1914, p. 138) fed mussels upon living Paramecia with apparent success. 
 
PRESH-WATER MUSSELS. 91 
 
 greatest care had to be taken in handling it, while just the opposite was true of its near 
 relative, the Lake Pepin mucket, which fed readily on most of the experimental material 
 and was not so fastidious regarding the physical state of the food; that is, the size of 
 food particles and the amount given at one time. This may explain to a certain degree 
 the success attending the culture of the latter species in ponds, but the question then 
 arises why the river mucket is not crowded out everywhere by this mussel, since one 
 species, judging from the shell structure, is as well adapted to live in moving water as 
 the other. As was observed above, however, Lant.l>siHs luteola is typically an inhab- 
 itant of water with little or no current, while Lampsilis ligamentina is a true river mussel. 
 The available data of shell structure and feeding habit evidently offer no explanation. 
 
 The blue-point and the spike take a midway position as regards their feeding 
 habits, although the former is perhaps less exacting than the latter. 
 
 Detritus undoubtedly forms the main bulk of the food of fresh-water mussels. 
 Dissolved substances may also play a part (Churchill, 191 5 and 191 6), but their role is 
 probably a comparatively unimportant one when compared with the solid food matter. 
 This must be especially true of streams with relatively pure water, in which mussels 
 have been found to thrive just as well or better than those carrying large quantities of 
 dissolved matter. 
 
 In view of the universal presence of plants in or near waters productive of mussels 
 there is little likelihood of a shortage of food, for detritus will always be forthcoming. 
 There can be only a very little competition among mussels as far as food is concerned, 
 and the noncommercial species are not objectionable from this standpoint. 
 
 OBSERVATIONS OF H. WALTON CLARK ON FOOD OF MUSSELS." 
 
 In general it may be said that the food of fresh- water mussels, as indicated by their 
 stomach contents, includes about everything obtainable and not positively harmful, 
 organic or inorganic substances, living or dead matter, if not too large or too active for 
 the mussels to take in. As the mussel has no means of mastication it can not use long 
 objects such as filaments of algse and the like. 
 
 In the course of general biological investigations and of mussel surveys opportunity 
 was had to study the stomach contents of mussels from widely separated areas and 
 under widely different conditions. One of the striking features of the case is that the 
 size and apparent health of mussels bear no direct relation to the apparent nutritive- 
 ness of the material in the stomach. Thickness of shell is partly a matter of heredity; 
 thick-shelled species of Lampsilis are found in fairly good currents where nutritious food 
 material is scarce; thin-shelled Anodontas are usually found in quiet places where the 
 food supply is rich. Moreover, generally speaking, Lampsilis of any species in a quiet 
 lake where food in the form of plankton is abundant, are thinner shelled and smaller 
 than those of rivers. 
 
 Although, generally speaking, thickness of shell seems to be almost always in 
 inverse ratio to richness of food, that relation itself may be partly accidental. In mus- 
 sels the secretion of shell is in relation to current or to mineral content of the water. 
 
 The stomach contents of some large heavy pocketbooks, Lampsilis ventricosa, 
 from the mussel beds in Yellow River, Ind., where this species reaches maximum size, 
 
 a For additional data see Clark and Wilson (igi2) and Evennann and Clark (1918). 
 
 9745°— 21— 2 
 
92 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 consisted chiefly of the yellow mud of the river bottom, with organisms of any sort few 
 and far between. In general, mud" is an abundant element in the stomachs of all mus- 
 sels; so much so that the color and general appearance of the mass of the stomach con- 
 tents of all river mussels examined was that of the bottom soil. In ponds full of dif- 
 fused plankton algse the plants may be present in sufficient quantities to at least fleck 
 the "ground color" with a pronounced green or blue green. Studies of the stomach 
 contents of the mussels in the reservoir of the Feeder Canal at Fort Wayne, in 1908, 
 revealed the presence of many flagellates, such as Trachelomonas and Phacus, together 
 with such minute plants as Scenedesmus, Pediastrum, Botryococcus, such diatoms as 
 Gomphonema, Na\'icula, and the like, a few desmids (Cosmarium), fragments of Cera- 
 tium hirundinella, casts of the rotifer Anuresa cochlearis, and small fragments of 
 confervoid algae. In the main current of the vSt. Joseph, St. Mary, and Maumee 
 Rivers there was much mud with about the same organisms scattered sparsely through 
 it. A mucket, Lampsilis ligamentina, taken in the Auglaize River, contained what 
 appeared to be bacteria. Mussels in Lake Amelia, near ,St. Paul, Minn., contained an 
 abundance of that peculiar organism Diiiobryon serlularia. The mussels of Lost Lake 
 and Lake Maxinkuckee, Ind., contained enough plankton organisms of all the minuter 
 sorts to give the stomach contents a greenish cast or to mottle it considerably with greenish 
 flecks. Not to enter into too great detail, the)' contained such organisms as Microcystis 
 (BTuginosa, Pediastrum boryanum, and P. duplex, Coelastrum microporum,, Botryococcus 
 braunii, Scenedesmus, Melosira crenulata, Coconenia cyrnbifornie., Navicula, Epithemia 
 argiis, Fragilaria, Cocconeis pedicidus, and Lyngbya tzstu-arii. Melosira and Spirulina 
 represented the longest filaments taken. Anurcea cochlearis was common but represented 
 only by lorica, and Chydorus was the largest and most active organism taken. 
 
 Observations believed to be of both interest and importance were made in the Mis- 
 sissippi in the late summer and autumn of 1919. The river had remained high and 
 swift until about the beginning of September, when it fell rapidly. With its fall the 
 great body of marginal water lost the velocit}' of its flow, and great areas behind wing 
 dams, lagoons, and mouths of sloughs became extensive areas of calm. In these a rich 
 and varied plankton, consisting chiefly of holophytic sorts (Euglena, Paudoriiia, rotifers, 
 Platydorina, and a bottom benthos of diatoms), rapidly developed in considerable quan- 
 tities. The stomachs of the mussels in the bottom of these areas of calm contained 
 numerous organisms of the plankton and benthos such as A nurcea cochlearis, Pandorina, 
 Mycrocystis, Scenedesmus, Phacus, and various diatoms; the stomach contents bore 
 general resemblance to those of the mussels of the Feeder Canal reservoir. 
 
 Opportunity was taken to examine the stomach contents of some young mussels 
 which were obtained at the same time. In a slough sand-shell, Lampsilis jallaciosa, 
 1 9. 1 mm. long, all that could be recognized was one colony of Clathrocystis. Another, 
 18.9 mm. long, contained chiefly brown, gritty mud in which were several Scetiedesmus 
 caudatiis, Pliacus plcuronectcs, i Coscinodiscus, a few x&xy minute Melosiras, and some 
 rough spherical cysts. A third example, 19.6 mm. long, contained much brown flocculent 
 organic mud, a large colony of Microcystis, i Scenedesmus caudatus, the diatom Cyclotella 
 compta, and many of the green rough cysts. 
 
 The stomachs of some very small Lampsilis anodonloides and L. luteola, reared in 
 troughs at Fairport and apparently thriving, contained only a fine brown flocculent 
 
 1 The mud is probably mixed with much decomposing organic matter. 
 
PRESH-WATER MUSSELS. 
 
 93 
 
 mud, with rarely an occasional diatom. A young L. anodontoides from Smiths Creek bar 
 in the Mississippi contained fragments of diatom shells indicating that it had been feeding 
 on them to an unusual extent. Although Pleurosigma covered the nmd of that region, 
 forming an almost unbroken brown scum, it is noteworthy that it was only rarely found in 
 the stomachs of the young mussels, it being apparently too large to enter the mouth. 
 
 As regards the entire subject of mussel food and feeding there are some general 
 obsei-vations it may be pertinent to make at this point. 
 
 At one time it was thought that extremely dense beds of mussels in the bottom of 
 lakes might act as reducers of an excessive accumulation of plankton. They might 
 indeed take care of many sunken and decaying plankton organisms, but under favor- 
 able conditions plankton can develop more rapidly than anything can eat it. 
 
 The finding of what appears to be bacteria in the stoniachs of mussels of the Auglaize 
 River and the observation made in tanks at the Biological Station at Fairport — that 
 turbid water in which there were mussels cleared up rapidly, the mussels collecting the 
 silt and other materials in suspension — raise the question as to whether mussel beds are 
 not or can not be of use in the purification and sanitation of rivers. If oysters grown 
 m polluted waters may harbor typhoid bacilli and so communicate the disease to those 
 who eat them, there seems to be no good reason why mussels, which are not eaten, may 
 not sen'e to arrest and devour those as well as other pathogenic organisms. 
 
 Since mussels are very inactive animals, the rate of metabolism may be expected 
 to be low and the food requirements correspondingly small. The problem of obtaining 
 nourishment for mussels is then one of the least of our troubles. Doubtless younger, 
 more active mussels require a richer diet, and the first problem of mussel propagation, 
 that of finding a suitable host, is fundamentally one of finding suitable nutrition for a 
 creature remarkable for its fastidiousness in this regard. It ma}- be that a critical 
 problem is the finding of suitable nourishment for the first month or so of free life, but 
 beyond this the only problem, so far as food supply is concerned, appears to be the 
 avoidance of actually poisonous or harmful substances. 
 
 OBSERVATIONS OF A. F. SHIRA ON FOOD OF JUVENILE MUSSELS. 
 
 The following table (i) embodies a record of the stomach contents of 60 juvenile 
 mussels, distributed among 6 species, taken in Lake Pepin during 1914. The material 
 v/as studied with the use of a rafter counting cell, but since only a very small quantity 
 of food could be obtained from each mussel the calculation of percentages can be only 
 approximate. 
 
 Table i. — Food of Six Species op Juvenilb Mussels Taken in Lake Pepin, September, October, 
 
 AND November, 1914. 
 
 Juveniles examined. 
 
 
 Length 
 
 of juvenile 
 
 meters). 
 
 s (milli- 
 
 
 Percentage of food . 
 
 
 Spedes. 
 
 Number. 
 
 Mini- 
 mum. 
 
 Maxi- 
 mum. 
 
 Average. 
 
 Organic 
 remains 
 (princi- 
 pally 
 vege- 
 table 
 matter). 
 
 In- 
 organic 
 remains 
 
 Csilt. 
 
 etc.). 
 
 Unicel- 
 lular 
 green 
 algse. 
 
 Diatomi 
 
 T.iiTnpQilis liitppla 
 
 13 
 10 
 
 8 
 10 
 
 8 
 12 
 
 5-0 
 4.8 
 8.2 
 6.6 
 6.4 
 6.2 
 
 IS- 4 
 13-4 
 21.5 
 19. 6 
 II. 
 19- 5 
 
 9-5 
 8-8 
 13- 7 
 '3- 5 
 
 r-4 
 
 12. 7 
 
 S9 
 90 
 96 
 05 
 96 
 91 
 
 6 
 5 
 
 I 
 
 X 
 
 Trace. 
 4 
 
 3 
 3 
 
 2 
 
 3 
 3 
 3 
 
 
 
 
 Lampsilis alata 
 
 
 
 
 Quadrula plicata 
 
 
 
 
 
 
94 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 HABITAT. 
 
 The pearly mussels, as inhabitants of fresh water, are found in diverse habitats, in 
 lakes and in rivers, in shallow and in deeper waters, in cold and in warm waters, in mud, 
 in sand, and among rocks. Yet they do not occur in all lakes and rivers, nor in all parts 
 of the lakes and rivers in which they do live; and the several species of mussels, when 
 living togetlier, are not always found in the same relative abundance. It may, therefore, 
 be supposed that fresh-water mussels, like other animals, are adapted rather definitely 
 to particular conditions of environment; that some find congenial environment in still 
 or sluggish water, while others thrive best in strong currents ; that a mud bottom supports 
 certain species, while a firmer soil is required by others. 
 
 Adult mussels in some cases thrive, or continue to live at least, in environments 
 where the young would perish, for delicately balanced conditions are required by very 
 young mussels of many species, and only where these conditions exist can a mussel bed 
 originate or perpetuate itself. On the degree of stability of the conditions favorable to 
 the growth of the young the permanency of the bed must depend, since, when replenish- 
 ment fails, the bed can continue only as long as the life of the adult mussels it contains. 
 As any mussel has rather limited powers of independent locomotion, the place where it 
 lives (or prematurely dies) is probably, as a general rule, near where it falls when it 
 drops from its fish host; yet the early juvenile can be carried by the current, and doubtless 
 this means of transportation may sometimes aid the young mussel in finding a suitable 
 habitat. An adult niggerhead mussel lived in apparently healthy condition in a balanced 
 aquarium at the Fairport station for nearly nine months; yet in nature this species is 
 found only in strong currents, the favored environment of its fish host, the river herring. 
 
 The relationship of fresh-water mussels to the environment may be treated with 
 reference to body of water, bottom, depth, light, current, water content, vegetation, 
 and animal associates. 
 
 BODY OF WATER. 
 
 The various geographic types of fresh water in which mussels occur are rivers, lakes, 
 ponds, sloughs, swamps, marshes, and canals. In so far as distinctive conditions char- 
 acterize these various types of waters, each may have its characteristic mussel fauna. 
 It may be said in general, that wherever conditions suitable for a particular species of 
 animal prevail, that species will be found, except as it may have been naturally excluded 
 through features of geologic history or other factors governing the distribution of animals; 
 in the case of fresh-water mussels, however, emphasis must be placed upon a qualifica- 
 tion of this general statement. Though all conditions in a body of water may be other- 
 wise suitable, mussels can not naturally occur where conditions do not permit the entry 
 and survival of the species of fish which serve as hosts. 
 
 STREAMS. 
 
 Mussels have undoubtedly reached their greatest development, as to numbers, both 
 of species and of individuals, in flowing water. From the commercial standpoint, also, 
 the quality of shells from streams is almost invariably superior. In general, where other 
 conditions are favorable to mussels, larger bodies of flowing water are more productive 
 than the smaller. Brooks do not usually contain mussels. Morphologically, mussels 
 adapted to life in strong currents are differentiated from those adapted to still water by 
 
Bull. U. S. B. F., 1919-20. 
 
 Plate VI. 
 
 Fig. I.— Upper waters of Grand River. Habitat of mussels in sliallow swift water. 
 
 
 
 
 
 ^ -JL>^ 
 
 ) JS^^^^^^ 
 
 in 
 
 
 1^ 
 
 
 i 
 
 
 
 '^^^^^^1 
 
 
 f 
 
 
 r 
 
 
 
 ^^BBB 
 
 
 w 
 
 
 
 .^0^ 
 
 
 Wr ' ■ '^4^^H 
 
 
 *"-• 
 
 
 
 --i« 
 
 w '-^^^H 
 
 ^H|E^~ -^^^^^^^^^^^B 
 
 Fig. 2.— Upper waters of Grand River. Habitat of mussels in sluggish water. 
 
Plate VII. 
 
 Fig. I. — Black Kult, Ark , a very productive mussel stream. 
 
 Fig. 2. — Red River, near Campti, L,a., a turbid stream with caviny banks and shifting bottom, quite unfavorable 
 
 for mussels. 
 
Bull. U. S. B. F., 1919-20. 
 
 Pi.ATK MIL 
 
 Tig. 
 
 -Lake Pepin, an expansion of the Mississippi River between Wisconsin and ^Minnesota, 
 a favorable habitat for fresh-water mussels. 
 
 -North Fork of Kentucky River, near Jackson. K^■.. with sand bottom and conditions unfa\-ora 
 
 ( r);illi,'l;ido I 
 
 )k' fur mussels, 
 
 -Tea Table shoals, another portion of the Kentucky- River; the shores indicate stabjlii> 
 moderately deep, and the environment is favorable for mussels. 
 
Bull. U. S. B. F., 1919-20. 
 
 Plate IX. 
 
 Fig. I. — An undredged portion of the Kankakee River where valuable mussels lluurisli. 
 
 ^Mi^^ 
 
 Fig. 2. — A dredged portion of the Kankakee River rendered (temporarily, at leastj unfit for fresh-water 
 
 mussels. 
 
Bull. U. S. B. F., 1919-20. 
 
 Plate X. 
 
 Fig. I.— Lower porlion of Grand River. Mich., where mussels thrive under natural conditions. 
 
 Fig. 2. — Lower portion of Grand River where conditions have been rendered unsuitable for mussels by 
 canalization in interest of navigation. 
 
BuLU U. S. B. F., 1919-20. 
 
 Plate XL 
 
 Fig. I. — Auiilaize River near Defiance. Ohio, showing 
 islets and pools coutaiumy dense beds ol mussels. 
 
 l'"ii.. _■ — M.iiinuc River, ru-fiaiice Olii... The river 
 heii a broad valley with limestone bottom, broken 
 into numerous pools and channels with little islands 
 — an excellent growth of fresh-water mussels. 
 
 Fig. 3.— The drunim m1 li:, 
 Wayne. Ind.. r'.'\Lalni a i 
 tion of fresh-water mussels 
 
 1'\t'iKt Canal near Fort 
 inarkab!>' dense popula- 
 
 FiG. 4. — Parts of the Miami and Erie Canal afford 
 excellent environments for mussels. 
 
 Fic 
 
 5. — Construction of wing dams in the upper Mississippi River often renders conditions unfavorable for mussels that 
 previously throve in such sections of the river. 
 
FRESH-WATER MUSSELS. 
 
 95 
 
 the stronger development of the hinge teeth which aid in keeping the two valves of the 
 shell in perfect apposition. 
 
 Since a river presents from source to mouth conditions of varying suitability for any 
 form of animal life, there will usually be found in some measure a longitudinal succession 
 of mussels. Shelford (1913, p. 122) gives a table showing the longitudinal sequence of 
 eight species of mussels in the Calumet Deep River. 
 
 If one goes down a river from its headwaters, making collections of mussels at 
 various points, many species may be found at each place, but some species first encoun- 
 tered may disappear before the upper waters are passed. Others appear here or there 
 and perhaps disappear as one proceeds still farther down. The mussel fauna of the 
 different sections of the stream are characteristic, although one or more species may be 
 so adaptable as to live throughout the entire course of the stream. 
 
 This longitudinal succession of species is well illustrated by Table 2, which shows 
 the distribution of mussels in the Grand River, Mich. 
 
 Table 2. — Longitudinal Distribution op Mussels in Grand River. Mich.<i 
 
 Scientific name. 
 
 1. Quadrula coccinea 
 
 2. Strophitus edentulus 
 
 3. Anodonta grandis . , 
 
 4. Lampsilis ventricosa 
 
 5. Quadrula rubiglnosa 
 
 6. Anodontoides ferussacianus. 
 
 7. Lampsilis iris 
 
 8. SymphiTiota compressa 
 
 g. Lampsilis luteola 
 
 10. Alasmidonta calceola 
 
 ir. Unio gibhosus 
 
 12. Symphynota costata 
 
 Lampsilis elHpsifonnis 
 
 14. Quadrula undulata 
 
 15. Lampsilis lipamentina 
 
 16. Alasmidonta marginata 
 
 17. Quadrula tuherculata 
 
 18. Lampsilis recta 
 
 19. Lampsilis alata 
 
 20. Quadrula pustulosa 
 
 21. Lampsilis gracilis 
 
 22. Obliquaria reflcxa 
 
 33. Obovaria ellipsis 
 
 24. Plagiola elegans 
 
 25. Quadrula lachrymosa 
 
 26. Symphynota complanata 
 
 13 
 
 Total. 
 
 Common name. 
 
 " Flat niggerhead ' 
 
 Squaw-foot 
 
 Floater 
 
 Pocketbook 
 
 Flat ni ggerhead . . . 
 
 Small floater 
 
 Rainbow-shell. . . . 
 
 Fat mucket . . 
 Slipper-shell. 
 
 Spike 
 
 Fluted shell, . 
 
 Three-ridge 
 
 Muckct 
 
 Elk-toe 
 
 Flat purple pimple-back 
 
 Black sand-shell 
 
 Hatchet-back, pink heel-splitter. 
 
 White wart y-back 
 
 Paper-shell 
 
 Three-homed warty-back 
 
 Hickory-nut 
 
 Deer-toe 
 
 Maple-leaf 
 
 White heel-splitter 
 
 Observations made at and below- 
 
 — 01 4^ 
 
 O 
 
 14 
 
 14 
 
 
 X I X 
 X I X 
 
 X 
 
 X X 
 
 . . . . X 
 
 16 
 
 o Observations by R. E. Coker in 1909. 
 
 Stjmmarv or Table. 
 
 Total species observed. 26 
 
 Other species occurriug above Portland 6 
 
 Species occurring throughout river 10 
 
 Species found only at or below Portland 10 
 
 Species not found below Grand Rapids 4 
 
 Species found only below Grand Rapids 6 
 
 It will be observed at once that a far greater number of species is found in the lower 
 part of the stream. Thus, while only to of the 26 species obser\'ed in the river were 
 found near the headwater lakes, 22 species were met in the section of the river between 
 
96 BULLETIN OF THE. BUREAU OF FISHERIES. 
 
 Grand Rapids and the mouth at Grand Haven. It might be thought that this was due 
 to the fact that there would be fewer obstacles to the passage of mussels downstream 
 than to their distribution in an upstream direction. It seems sufficient, however, to 
 assume that the unequal distribution is due rather to the greater variety of conditions of 
 depth and of fish associates presented in the lower portion of the river. Shallow water 
 only is found in the upper river, except as artificial pools have been formed in recent 
 years by the construction of dams, while in the lower river deep water prevails in its 
 channel and all lesser depths are found between the channel and the shores. The very 
 breadth of the lower part of the river affords also a greater area for fish and mussels. 
 
 A difference of up-river and down-river habitat is presented by the distribution of two 
 closely related species, the three-ridge, Qiiadrula undulata, and the blue-point, Quadrida 
 plicata; the former, a more compressed and rougher form, is found in the more rapid 
 waters of upstream habitats, while the latter, being thicker and less ridged, occurs in the 
 deeper waters of the lower parts of a river system." (See Clark and Wilson, 191 2, and 
 Wilson and Clark, 191 2.) 
 
 In some rivers mussels are almost entirely lacking for long distances, as in the main 
 course of the Missouri River for hundreds of miles above its mouth, where the absence 
 of mussels is apparently due to the rapidly shifting bottom of sand. The Red River, 
 with its heavy load of silt and its habit of suddenly cutting into its banks and changing 
 its course, is manifestly unsuited for mussels, and examination of its bottom in many 
 places by Isely (1914) and Howard revealed extremely few mussels (PI. VII, fig. 2). There 
 is also a virtual absence of mussels in the Mississippi River, except close alongshore, below 
 the mouth of the Missouri River. Examination of the Musselshell Ri\'er in Montana by 
 J. B. Southall in 1919 revealed the presence in numbers of only a single species of mussel, 
 and this a species {Lampsilis luteola) characteristic of lakes, which lived in the portions 
 of the river deep enough to remain as isolated pools during the periods of dry weather. 
 In the east fork of the Chicago River, Baker (1910) found only 3 species, and these were 
 mussels characteristic of pond habitats, which were able to survive the dry seasons in 
 the small ponds left isolated in the deeper parts of the river channel. 
 
 The James River, in North and South Dakota, though having very few fish, was found 
 to possess a comparatively varied and abundant mussel fauna in the still waters between 
 shallow riffles; but there was evidence that the mussels were derived from fish infected 
 in other waters, that ascended the stream iu times of flood (Coker and Southall, 1915). 
 
 The suitability of any section of a stream for the growth of mussels arises from a 
 diversity of causes, including the nature of the rock or soil through which the stream is 
 flowing, the character of the drainage waters entering the river at or above the section, 
 the gradient of the stream bed with its effect upon depth and currents, and the species 
 of fish which frequent the region. 
 
 Barriers in the course of a stream such as natural falls, or artificial dams, if impassa- 
 ble to fish, may have an effect upon the distribution of mussels. Wilson and Danglade 
 (1914) found no mussels of the genus Quadrula above the F'alls of St. Anthony in the 
 Mississippi River, although several species of this genus are very common in the river 
 
 n Ortmann (1920) has definitely shown, for certain species, that: "(i) The more obese (swollen) fonn is found farther down 
 in the large rivers, and passes gradually, in the upstream direction, into a less obese (compressed) form in the headwaters; (2) 
 with the decrease in obesity often an increase iu size (length) is correlated; (3) a few shells which have, in the larger rivers, a pe- 
 culiar sculpture of large tubercles, lose these tubercles in the headwaters." He ascertains also that these laws do not apply to all 
 species. 
 
FRESH-WATER MUSSELS. 
 
 9V 
 
 below that barrier. Wilson and Clark (1914) found only 4 species of mussels in the 
 Cumberland River above the Cumberland Falls (one of these probably planted), while 19 
 species were taken in the pool immediately below the falls, but in this case the conditions 
 prevailing in the river above the falls appeared distinctly unfavorable for fresh-water 
 mussels. An impassable dam formed after mussels were generally distributed throughout 
 a stream would have little significance with reference to the distribution of mussels tlie 
 hosts of which subsequently thrived both above and below the dam. The effect, how- 
 ever, of a dam in changing a region of rapids into a pool, might cause the mussel fauna of 
 swift waters to give place to a fauna of slack-water habitat. 
 
 Studies of rivers in cross section indicate that there may be quite definite distribu- 
 tion of life with reference to the banks. Shelford (191 3) has discussed a horizontal 
 arrangement of animals that is best illustrated in the cross sections of curves where there 
 is a horizontal gradation in rate of current and in size of material in the bed of the stream. 
 In the strong current only the coarsest materials are dropped, while the finest silt is 
 deposited where the flow is most retarded. The depth, of water is doubtless one factor 
 governing the hoi'izontal distribution of mussels, but the nature of the bottom material 
 is of first importance. Howard (Survey of Andalusia Chute, Mississippi River, report in 
 preparation) foimd in a branch, of the Mississippi, following a comparatively straight 
 course (not on rapids) and averaging 1,200 feet in width, that mussels were uniformly 
 restricted to a border 200 feet from the shore line. (See table below.) vSome mussels 
 vv'ere found almost anywhere along this border, but occurring in beds at points where the 
 channel touched the shore and where bottom conditions were favorable; depth seemed 
 to be a minor factor as affecting the distribution. 
 
 The following table (3) indicates the results of a sample series of unit hauls taken at 
 stated distances from the water's edge and so represents the distribution in a cross 
 section of the river. It is not typical because of the narrowness of the bed on the left 
 bank, but it illustrates in a general way the distribution found throughout the survey. 
 
 Table 3. — Distribution op Mussels in Andalusia Chute, Mississippi River. 
 
 
 
 From right bank. 
 
 
 Middle 
 
 of 
 river. 
 
 From left bank. 
 
 Distance, in feet, from water's edge. . 
 
 S5 
 
 13 
 
 8s 100 
 3 
 
 200 
 
 
 300 
 
 400 
 
 300 
 
 
 
 200 
 
 
 no 
 
 
 60 
 12 
 
 
 
 33 
 
 
 
 
 Where there arc rapids with bowlder or cobblestone bottom across a river of this 
 size, it is known that mussels are not limited to such a border but are found at all points 
 across the stream. 
 
 LAKES. 
 
 The mussels from some lakes are large and heavy-shelled, while in others thev are 
 small, thin-shelled, and stunted. These extremes represent the varied conditions 
 which lakes present in respect to mussel life. 
 
 Lakes that have a free circulation of water seem to be favorable; such are those 
 that are interposed in the course of a river. A favorable feature in such cases, no doubt, 
 is the direct and free connection witli streams that are well supplied with mussels. 
 Examples are Lakes Pepin and Pokegama, Minn., and the former is noteworthy for the 
 abundance of mussels produced. Though at first sight Lake Pepin might be considered 
 
98 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 no more than an expansion of the Mississippi River, further observation shows it to be 
 a true lake in many of its characters, as in clearness of the water, depth, growth of vege- 
 tation, and virtual absence of current. In both of the lakes mentioned, a characteristic 
 lacustrine species, the fat mucket, or Lake Pepin mucket, Lampsilis hileola, which is 
 thin-shelled and worthless in ordinary inclosed lakes, attains so fine a commercial quality 
 of shell as to appear almost as a distinct variety. Caddo Lake, La., which is interpolated 
 in the course of a stream, possesses a rich mussel fauna and has been the scene of active 
 pearl fishery (Shira, 1913). The small Rice Lake near La Crosse, Wis., which is, in 
 effect, an expansion of a thoroughfare connecting the Black River, near its mouth, with 
 the Mississippi River, also supports a varied and luxuriant mussel fauna. Where lakes 
 are freely connected with rivers, as are those first mentioned, or as are others with short 
 open outlets to the rivers, the lakes and rivers have many species of mussels in common. 
 
 In Lake Pepin, Shira (report in manuscript) found that the distribution of the mus- 
 sels is confined wholly to the shore line and the flats within a maximum depth of 25 feet; 
 no mussels at all were taken in the deep central part of the lake. In certain places the 
 mussels were quite densely distributed, forming very well-defined beds, but as these 
 beds were generally connected by areas of lesser population, a more or less continuous 
 mussel bed was found to occur on each side of the lake. The largest and most extensive 
 beds were located on a gravel bottom, or a mixture of gravel and sand. Several good 
 tliough less extensive beds occurred on bottoms containing a considerable percentage 
 of mud. 
 
 The upper end of the lake evidently serves as a settling basin for the silt poured in 
 from the river proper, and for a distance of about 2 miles below the entrance of the river 
 the lake is comparatively shallow with a soft oozy bottom. In this section of the lake 
 very few mussels are found. 
 
 Shira records 32 species of mussels (report in manuscript). Ten of the most abund- 
 ant species with the percentage of occurrence are given as follows: 
 
 Per cent. 
 
 Fat mucket, Lampsilis luieola 31-5 
 
 Spike, Unio gibbosus 13. o 
 
 Blue-point, Quadrula plicaia 12. 7 
 
 Pig-toe, Quadrula undala 10. o 
 
 Pink heel-splitter, Lampsilis alata 8. 3 
 
 Pocketbook, Lampsilis ventricosa 5. 6 
 
 Slop-bucket, Anodonia corpulenta 5. 5 
 
 Squaw-foot, Slrophitus cdcniulus 4-3 
 
 White heel-splitter, Symphynota complanala 2.3 
 
 Black sand-shell, Lampsilis recta 1.4 
 
 In small lakes of considerable depth and without circulation, except as effected by 
 winds and changes of temperature, animal life generally is absent or greatly restricted 
 in the deeper portions, and mussels, when present, are confined to zones near the shores 
 (Headlee and Simonton, 1 904) . Muttkowski ( 1 9 1 8) in Lake Mendota found the optimum 
 conditions for mussels at depths of 6 to 9 feet on sand bottom, but there was not an 
 extensive mussel population in the lake as a whole. 
 
 The restriction of mussels to the border zones is indeed generally characteristic 
 of the lakes of the Middle Western States, and even in this environment where the cir- 
 culation effects of wave action may be felt, the mussels are stunted in growth. In their 
 report on the mussel faiina of Lake Maxinkuckee, Evermann and Clark (1918, p. 251), 
 
FRESH-WATER MUSSELS. 
 
 99 
 
 summarize as follows the results of observations of mussels in lakes of Indiana and else- 
 where : 
 
 Generally speaking, lakes and ponds are not so well suited to tlie growth and development of mussels 
 as rivers are; the species of lake or pond mussels are comparatively few and the individuals usually 
 somewhat dwarfed. Of about 84 species of mussels reported for the State of Indiana, only about 24 are 
 found in lakes, and not all of these in any one lake, several of them bat rarely in any. Of the 24 species 
 occasionally found in Indiana lakes, but 5 are reported only in lakes, and only 3 or 4 of the species com- 
 mon to both lakes and rivers seem to prefer lakes. 
 
 Characteristic species of mussels of inclosed lakes of upper Central States are named 
 in the following table (4), and it may be remarked that the fat mucket and the floater 
 are easily predominant over all others. 
 
 Tabue 4. ^Characteristic Mussels op Lakes of Upper Central States. 
 
 Species. 
 
 Fat mucket, Lampsilis luteola 
 
 Floater, Anodonta trrandis 
 
 Pocketbook, Lampsilis veutricosa 
 
 Squaw-foot. Strophitus edentulus 
 
 Small floater. Anodontoides ferussacianus. . 
 
 Quadrula rubicinosa 
 
 Spike, Unio Eibbosus 
 
 Lampsilis subrostrata 
 
 Rainbow-shell. Lampsilis iris 
 
 Slop-bucket, Anodouta corpulenta 
 
 Paper shell, Anodonta imbeciUis 
 
 Paper-shell, Anodonta pepiniana 
 
 Michigan." 
 
 Minnesota.'' 
 
 Indiana c 
 
 " Cokcr. R. E. (unpublished notes). 
 
 f* Wilson and Danclade (1914). 
 
 c Clark and Wilson C1912); Wilson and Clark C1912); and Evermann and Clark C191S). 
 
 While, as has been previously indicated, the plains streams, such as the Red River 
 or the Missouri, with their ever-changing banks and bottoms and silt-laden currents, 
 present conditions entirely unfavorable to mussels, yet the oxbow or cut-off lakes adja- 
 cent to them may offer favorable habitats for several species of mussels (Isely, 1914, and 
 Howard, unpublished notes). 
 
 The sand shores of the Great Lakes to a depth of 8 feet are virtually barren of ani- 
 mal life (Shelford, 1918, p. 26). Fresh-water mussels are found in these lakes, chiefly, 
 it appears, in the shallower bays, where they sometimes manifest a vigorous growth. 
 They have not been used commercially to any extent, and probably few possess shells 
 of a size and quality rendering them suitable for button manufacture. 
 
 In a biological examination of Lake Michigan in the Traverse Bay region. Ward 
 (1896) encountered 9 species of mussels, all of species generally possessing relatively 
 thin shells, while Reighard (1894) reported 20 species and subspecies from Lake St. 
 Clair, of which the following 8 were described as abundant: 
 
 Pink heel-splitter, Lampsilis alata (Say). 
 Thin niggerhead, Quadrula coccinea (Conrad). 
 Spike, Unio gibbosus (Barnes). 
 Mucket, Lampsilis ligameniina (Lamarck). 
 
 Lampsilis nasutus (Say). 
 
 Black sand-shell, Lampsilis recta (Lamarck). 
 Pocketbook, Lampsilis veniricosa (Barnes). 
 Floater, A nodonta grandis (Say) . 
 
 A more extensive list of mussels from Lake Erie and the Detroit River is given by 
 Walker (191 3), the list including 39 species of 15 genera. Since the great majority of 
 the species named are those that normally possess thin and fragile shells, it may be 
 
lOO BULLETIN OF THE BUREAU OF FISHERIES. 
 
 supposed that the conditions in these waters are not favorable to the production of 
 good shells. Certain species are mentioned, however, which, in other regions at least, 
 possess shells of commercial quality. Principal among these are the following : 
 
 Maple-leaf, Quadrula lachrymosa (Lea). 
 Pimple-back, Quadrula ftustulosa (Lea). 
 Pig-toe, Quadrula undaia (Barnes). 
 
 Long solid, Quadrula subrotunda (Lea). 
 
 Hickory-nut, Obovaria ellipns (Lea). 
 
 Black sand-shell, Lampsilis recta sageri (Conrad). 
 
 Clark, collecting on the shores of Lake Erie at Put in Bay, found dead shells all 
 dwarfed in form but representing 14 species, of which the more common were as follows: 
 
 Three-ridge, Quadrula undulata. 
 Spike, Unio gibbosus. 
 Roimd hickory-nut, Obovaria circulus. 
 Paper-shell, Lampsilis gracilis. 
 
 Pink heel-splitter, Lampsilis alaia. 
 Black sand-shell, Lampsilis recta. 
 Fat mucket, Lampsilis luieola. 
 Pocketbook, Lampsilis vevtricosa. 
 
 PONDS, SLOUGHS, MARSHES, AND SWAMPS. 
 
 These types of environment are grouped together, since their mussel fauna is gener- 
 ally similar. The mussels are thin-shelled as a rule, since light weight is favorable for life 
 in mud or soft bottoms and mass is not essential in the absence of current. Some possess 
 narrow bodies and keel-like shells that fit them for locomotion through soft soil, and a 
 few of the narrow-bodied species, where other conditions are suitable, have relatively 
 heavy shells. Such are the pink heel -splitter, Lampsilis alaia, and the white heel- 
 splitter, Symphynota complanata. 
 
 The heavier mussels characteristic of rivers are sometimes found in sloughs, but in 
 these the characters of flowing and still water are in a measure combined, since strong 
 currents may prevail at seasons of high water. Sloughs, as parts of river systems and 
 subject to being stocked from them, have mussel fauna to a certain extent related to 
 that of the river; that is, the still-water species of the river are to be found in the sloughs. 
 Marshes and swamps may have mussels at places where they contain pond or streamlike 
 openings. In general the marsh and swamp environment is not favorable to mussels. 
 
 In ponds that are more or less isolated the thin-shelled mussels of the toothless 
 type, as Atwdonta grandis (floater) and Anodonioides ferussacianus, are characteristic. 
 Lampsilis parOa, one of the tiniest of fresh-water mussels, scarcely exceeding an inch 
 in lengfth, is sometimes found in such environments. A characteristic pond-dwelling 
 species is the mussel Unio tdralasmus, which will survive in ponds that become dry in 
 summer. Examples of this species of mussel have been found alive buried in the bottom 
 three months after the water had disappeared on the surface (Isely, 1914, p. 18). 
 
 ARTIFICIAL PONDS AND CANALS. 
 
 Artificial ponds may present a favorable en^iroinnent for many species of fresh- 
 water mussels if the water supply is suitable, and some species are likely to become 
 accidentally introduced with fish that are brought into the pond. The ponds of the 
 Fisheries Biological Station at Fairport, Iowa, are supplied with water pumped from 
 the Mississippi River. The first species of mussel to appear in the ponds was the large 
 thin-shelled slop-bucket, Anodonta corpidenta, some examples of which had attained a 
 length of 3 to 33^ inches when they were first discovered at the expiration of the second 
 season of the pond, 17 months (May, 1910, to October, 1911) after the date of introduc- 
 
FRESH- WATER MUSSELS. lOT 
 
 ing water and fish into the newly excavated pond. Eighteen species which have been 
 accidentally introduced are listed on page 165 below. 
 
 Few of these mussels are of commercial value, but it has been attempted to intro- 
 duce several useful species by artificial infection upon fish, and success has been at- 
 tained with the Lake Pepin mucket, a lacustrine mussel of high commercial value, 
 which thrives well in the ponds and has attained a size and quality of shell suitable for 
 commercial purposes at the age of 4X years. 
 
 In canals mussels frequently thrive (PI. XI, figs. 3 and 4). A mill race from a well- 
 stocked stream seems to present a favorable environment for them. Clark and Wilson 
 (1912, pp. 19-22) describe a luxuriant development of mussels in a canal at Fort 
 Wayne, Ind., as follows: 
 
 Toward the upper end of the canal , in a place where the bottom was 1 5 feet wide , the mussels were 
 counted for a stretch of 10 feet along the canal bed and the following species noted: Quadrula rubiginosa, 
 11, Q. cylindrica , i, Q. undulata, 86: Anodonta grandis, 6; Plyclwbranclms phaseolus, i; Lampsilis ligamen- 
 iina, 5; L. luleola, 6. The width taken was the total width of the bottom of the canal and was consider- 
 ably wider than the space occupied by the mussels. 
 
 About a mile farther down the canal a space of 10 feet square was measured off in the bottom of the 
 canal, and the following species were found: Quadrula rubiginosa, 6; Q. undulata, 60, all rather small; 
 Pleurobemaclava, i ; Alasmidonta Irurwata, 2; Symphynota complanata, 2; 5. costata, 5; Anodonta grandis, 
 1$; Obovaria circulus, 4; Lampsilis ligamentina, 5; L. luteola, i; L. veniricosa, 4. This gave a little over 
 one shell per square foot. In igo8, in a square meter of bottom near the Rod and Gun Club, the follow- 
 ing species were noted: Quadrula rubiginosa, 9; Q. undulata, 36; Symphynoia complanata, i; Anodonta 
 grandis, 17; Obovaria circulus , 11; Lampsilis iris, 2; L. ligamentina, 2; L. luteola, 3, giving a total of 81 
 per square meter. In addition to these shells there were many small Sphaeriums, the ground being 
 paved with them, 34 Carapelomas, and 33 Pleuroceras. The square meter referred to above repre- 
 sents, as nearly as could be judged, an average number rather than either extreme. 
 
 It would appear from a general comparison of the aspect of mussels in lakes, ponds, 
 and rivers that the effect of currents or circulation upon the growth of mussels is variable 
 according to the relative proportions of organic and mineral foods present. In rivers, 
 where the circulation of water is constant, mussels may grow to large size and possess 
 thick shells, but when circulation is reduced, as in inclosed bodies of water, the mussels 
 may be small and relatively thin-shelled, or they may attain a large size with thin shells 
 (suggesting relative deficiency of mineral food), or else, with heavier shells, they may be 
 dwarfed in size (suggesting a relative deficiency of organic food). 
 
 BOTTOM. 
 
 Most mussels are normally embedded in the bottom from one-half to three-quarters 
 of their bulk.'' That they ma^- thus establish themselves, a firm but not impenetrable 
 soil is required. The character of the bottom is, therefore, of especial significance to 
 fresh-water mussels, though it has important relations to all bottom-dwelling animals. 
 With regard to the bottom, consideration must be given both to its topography and 
 to the materials of which it is composed. Major inequalities in topography, such as 
 waterfalls and rapids, are discussed elsewhere. Minor inequalities are of importance 
 because of the effects upon currents, sedimentation, light conditions, growth of food, 
 
 <• The cases of deep embedding mentioned by Wilson and Dauglade (1913), where they give a depth of i foot or more lor living 
 mussel-sin Shell River (p. 15'), and the report of a fisherman of 2 to 3 feet at Lake Bemidji, seem to be cases of "digging in" because 
 cf drought. Unio telralasmus (Isely, 1914) and Qnadnita pticata (Howard, 1914) seem to have a remarkable power of resistance 
 under these conditions. 
 
I02 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 and protective conditions; stability of soil is important for the establishment of the 
 juveniles, for otherwise they will be overwhelmed. For some species objects for attach- 
 ment, to which the byssus of the juvenile may be fastened, may also be necessary. 
 Most of the varieties of bottom soil encountered are composed of one of the following 
 materials, or of mixtures of two or more of them: Silt, mud, marl, clay, sand, gravel, 
 pebbles, cobbles, bowlders, and ledge rock. 
 
 In rivers, sandy bottoms are regions of change comparable to sand-dune areas on 
 land where immobile forms are killed. Sand bottoms occur extensively in many rivers 
 and they may be veritable deserts. Rivers like the Missouri are devoid of mussels for 
 hundreds of miles partly because of a preponderance of bottom of shifting sand. Mussels 
 when found on sand bars in rivers are in transit seeking more stable conditions. Although 
 comprising regions of instability in rivers where decided currents prevail, bottoms of 
 sand may offer more favorable conditions in lakes where they furnish a permanent 
 habitat for mussels. 
 
 A greater variety of bottoms favorable for mussels, as well as a more indiscriminate ' 
 disposition of them, prevails in rivers than in the other bodies of water considered. In 
 many lakes there is a more definite sorting of materials, leading especially to a segregation 
 of the finest sediment in the deeper portions of the lake to form a bottom that is very 
 soft and generally unsuitable for the Unionidae; mussels possessing much mass would 
 sink too deeply and have the gills too much clogged with silt to survive (Headlee and 
 Simonton, 1904, p. 176). Where such conditions prevail the mussels are found near 
 shore. 
 
 Headlee (1906, p. 315) summarizes observations and experiments in certain lakes 
 of Indiana in the following words: 
 
 The work of 1903 and 1904 shows conclusively that the mussels of Winona, Pike, and Center Lakes 
 can not exist on the fine black mud bottom — they become choked with mud and apparently smother — 
 and that the light-weight forms and the forms exposing great surface in proportion to weight can rest 
 on top of comparatively soft mud and can, therefore, live farthest out on the deep-water edge of the 
 bed. Because the mussels can not occupy any region where the pure black mud is present, they are 
 confined by it to isolated beds and narrow bands of shore line. 
 
 I believe that the whole evidence of the distributional and experimental work of 1903 and 1904 
 pointsclearly to the character of the bottom as the great basal influence in the distribution of mussels in 
 small lakes generally. 
 
 The species he dealt with were the fat mucket, Lampsilis luteola, Lampsilis stib- 
 rostrata, Quadrula rubiginosa, Anodonta grandis, and other small species with light shells. 
 While his conclusion accords generally with the observations of the writers in other 
 waters, the exclusion of mussels from mud bottoms can not be taken as an invariable 
 rule. In the Grand River, at Grand Rapids, Mich., for example, one of the authors has 
 observed such a heavy-shelled mussel as the three-ridge, Quadrula utidiUafa, living in 
 considerable numbers along with the light floater (Anodonta) in very soft mud. Also, 
 in Mississippi Slough, in the Wisconsin lowlands along the Mississippi River opposite 
 Homer, Mirm., the blue-point, Quadrula plicala, the pimple-back, Q. pustulosa, and the 
 pig-toe, Q. undaia, have been found in considerable numbers on a soft-mud bottom 
 along with the heel-splitters, Symphynoia complanata and Lampsilis alaia, and the 
 slopbucket, Anodonta corpulenta. 
 
FRESH-WATER MUSSELS. I03 
 
 Baker (1918, p. 1 17) gives a summary of results of studies of mussels with reference 
 to bottom and depth in Oneida Lake, N. Y., in the following words: 
 
 The greatest number of individuals occurred on a clay or sandy-clay bottom. Twice as many 
 mussels occurred in water deeper than 6 feet than within the 6-foot contour. These features are 
 expressed in Table No. 27, the figures being averages per unit area of 9 square feet. 
 
 TABtB No. 27.— AvER.\GB NnMBER OF Mussels on Bottom. 
 
 Bowlder and gravel bottom 6. 14 
 
 Sand 6. 39 
 
 Clay and sandy clay 13- 00 
 
 Mud 10. 26 
 
 Within 6-foot contour. 7. 84 
 
 Outside 6-foot contour •_ 16. 85 
 
 The above table shows that mussels are more abundant on the mud bottom in deep water (S to 14 
 feet) than on sand, gravel, bowlder, or clay in shallow water (i to 6 feet). These are the only studies of 
 this character known to tne. 
 
 In that lake one species, Anodonia implicata, is reported from one kind of bottom 
 only, in sand between bowlders; while another species, Lampsilis luteola Lamarck, is 
 said to be common on all varieties of bottom, except gravel (Baker, 1918, pp. 161, 162). 
 
 Muttkowski (1918) found that sand bottoms marked the favored environments 
 of fresh-water mussels in Lake Mendota, Wis. 
 
 In Lake Pepin most of the adult mussels are found on a bottom of gravel or a 
 mixture of gravel and sand. Bottoms composed largely of mud but made firm by a 
 mixture of sand or gravel or both, yield a good supply of mussels; such areas are of 
 much less extent in the lake than bottoms of gravel or gravel and sand. Of 1,397 
 juvenile mussels comprising 16 species collected in Lake Pepin in 1914, practically 95 per 
 cent were taken on a sand bottom; about 4 per cent, principally Anodonta imbecillis, 
 were found on a mud bottom ; and the remaining i per cent on gravel or a mixture of 
 sand, gravel, and mud (Shira, report in manuscript). 
 
 In ponds and sloughs there is less choice of bottoms than in lakes, and mud bot- 
 toms usually prevail; for such conditions Lampsilis parva, Lampsilis subrostrata, the 
 light-shelled Anodontas, and similar species are especially adapted. 
 
 When we consider the relation between various mussel species and the bottom in 
 rivers, we find the matter complicated by several considerations. This much, however, 
 may be said definitely: No mussels can survive in a shifting bottom, nor upon a bottom 
 of solid bare rock. Between the extremes, beginning with clean sand or soft miry silt 
 and ending with coarse gravel and bowlders or stiff clay, there is a great variety of 
 bottoms utilized to a greater or less extent as habitats for various species of mussels. 
 
 There are, of course, more or less definite relations between bottom and other 
 features. Soft, muddy bottom is always associated with a current that is feeble at 
 least near the bottom, or with the checking of the current; gravel bottom is usually 
 associated with swift current; and clean sand or gravel is associated with clear water. 
 Certain of the "mud-loving" mussels, such as the Anodontas, may be really lovers of 
 quiet places and their association with mud rather an accident. Some of those supposed 
 to be partial to sandy or gravelly bottom may simply prefer clear to turbid water, or 
 mav thrive best in a swift current. 
 
I04 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 Several species, including most of the Anodontas, Symphynota complanata, Arcidens 
 confragosus , and others, are confined chiefly to one sort of bottom. A great many, 
 however, seem indifferent to the character of the bottom, provided other conditions are 
 favorable. Mussels may also apparently thrive where one would naturally think condi- 
 tions unfavorable and where they might not survive if artificially planted. Thus in the 
 crescent-shaped bayous along the Kankakee Quadrula undulata, and in sloughs of the 
 Mississippi a closely related mussel, both heavy-shelled species, are found thriving on the 
 top of deep, soft, silty mud which would not seem stiff enough to bear their weight. 
 
 In the Grand River, Mich., various species of mussels were found upon "clean" 
 sand bottoms, but always sparsely. Quadrula undulata and Lampsilis ellipsiforviis and 
 venlricosa seemed best adapted to life in accumulations of drift. In sewage and waste- 
 polluted waters at Lansing, Mich., Lampsilis ligamentina, venlricosa, and ellipsijormis, 
 Quadrula coccinea, Symphynota costala, and Alasmidonta marginata were found in appar- 
 ently healthy condition. The Lampsilis ellipsijormis obtained there, of especially large 
 size, bore innumerable (but worthless) small pearls. (Coker, unpublished notes.) 
 
 In the Mississippi River near Fairport, Iowa, bottoms of unmixed mud and pure 
 sand were found to be much less occupied by many of the species than mixtures of gravel 
 and sand or of sand and mud, which supported both a far greater number of individuals 
 and a somewhat greater variety of species. The preference for certain bottoms is most 
 conspicuous when the proportion of the total catch of mussels found on the favored 
 bottoms is viewed in connection -mth the proportions of these bottoms in the total area 
 sur\'eyed. Table 5 shows the total number of mussels taken from the different types of 
 bottom in a survey of Andalusia Chute, Mississippi River (Howard, report in preparation) : 
 
 Table 5.- 
 
 -Mussels Collected in Survey ov Andalusi.^ Chute, with Reference to Character 
 
 OF Bottom. 
 
 Composition of bottom. 
 
 Approxi- 
 mate per- 
 centage of 
 total area 
 of bottom. 
 
 Number oi 
 mussels. 
 
 Number oi 
 species. 
 
 Mud . . ■....-..^ 
 
 7 
 4 
 
 'A 
 
 71 
 
 9 
 
 2 
 
 2 
 
 I 
 
 2 
 
 44 
 158 
 
 17 
 
 87 
 289 
 
 29 
 5 
 
 34 
 
 17 
 
 
 Mild anH IpHgp rnr-lf ,, , . , , , 
 
 
 Sand ■,-.■.... .'/; .......if.. :.'-.; l'.; . 
 
 
 
 
 Sand and pebbles .....■.....'!.;... . . 
 
 
 
 3 
 14 
 
 
 
 Pebbles 
 
 
 
 Rock 
 
 
 
 
 
 
 The niggerhead mussel, Quadrula ebenus, in some streams, at least, is said to show a 
 decided preference for firm bottoms, as of gravel or blue clay, but few observations have 
 yet been made upon these mussels in streams having considerable areas of clay bottom. 
 In the Grand River, Mich., the pink heel-splitter, Lampsilis alata, was found living in a 
 ledge of very tough slippery blue clay (Coker, unpubHshed notes). So finn was the clay 
 that a mussel could be extricated from it only by the exertion of considerable muscular 
 efifort. Several other species of mussel were in the vicinity, but none were embedded in 
 
FRESH-WATER MUSSEI.S. I05 
 
 the clay except one example of the three-ridge, Quadrula undulata, and that was in a 
 spot where the clay was mixed with mud and was distinctly softer. Some spikes, Unio 
 gibbosus, were found lying on the blue clay but not embedded; it seemed evident that 
 they were unable to penetrate so tough a bottom. 
 
 The character of the soil has an effect upon the amount of materials carried in 
 suspension in the water. If the amount is too great, as over soft mud or over extremely 
 fine sand, under some conditions the mussel becomes smothered, or having no chance 
 to feed, is starved. Too much decomposing organic matter in the soil is said to cause 
 enough acidity to attack and erode the shell. For several reasons, therefore, areas of 
 rapid silt deposition, or soft-mud bottoms, are quite unfavorable to mussels. Mussels 
 are usually found in rivers in places where the bottom is swept clean by the current, 
 even though in flood time the water may be heavily laden with silt in suspension. 
 
 The selection by some species of bottoms of gravel, pebbles, and bowlders as most 
 favored habitats can readily be understood from the foregoing remarks; but there are 
 still other favorable features of rough bottoms. The very stability of the larger-sized 
 materials protects the bottom from washing, and may save the mussels from being 
 smothered or carried away. It is of advantage to mussels to be surrounded by numerous 
 other animals, especially by the smaller ones, which furnish attraction to fishes and thus 
 promote the reproduction of the mussel. Many of these small animals live attached to 
 stones, thus giving added value to gravelly and rocky bottom. In gravels, too, the 
 youngest mussels may be protected through inaccessibility to enemies, and as they 
 grow older the resemblance to small pieces of stone among which they lie may be the 
 cause of escape from enemies. As previously indicated (p. 97), where bowlder rock or 
 cobblestone bottoms occur in regions of rapids, mussels are commonly found abundantly 
 and occur over the entire river. 
 
 The following table (6) embodies the experience of several observers regarding the 
 preferences exhibited by 62 common species of fresh-water mussels for bottoms of differ- 
 ent characters. In view of the intergradation of the several types of bottom and the 
 almost unlimited variety of mixtures of sand, gravel, mud, and clay, the classification of 
 the bottoms for the purpose of a table must of necessity be rough, and the characterization 
 of mixed bottoms may in some cases be affected by the personal equation of the observer. 
 Young mussels may have bottom requirements somewhat different from those of adults. 
 
 EXPLANATION OF TABLE 6. 
 
 The letters refer to the experience of the several observers (including the present authors and three 
 previous writers), as follows: A, Baker (1898); B, Call (1900); C, Clark; D, Howard; E, Scammon (1906); 
 F, Shira; G, Coker. 
 
 The use of large capitals indicates that, according to the observer whose letter is in large capitals, 
 a certain type of bottom is preferred by the particular species of mussel. Wherever a small capital is 
 used, the observer corresponding to the letter has indicated the type of bottom as favorable for the 
 particular species of mussel, but not necessarily preferred to other favorable bottom. 
 
 The observations of Shira refer largely to lake conditions (Lake Pepin, Lake Pokegama, and Caddo 
 Lake). 
 
 The observations of Coker refer primarily to shallow rivers (Grand River, Mich.). 
 
 The habitats indicated by Howard are based chiefly on the observed preferences of juvenile mussels 
 in rivers, streams, ponds, and slues to the exclusion of true lakes. 
 
io6 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 Table 6. — Habitats of Certain Fresh-water Mussels, Classified According to Character 
 
 OF Bottom. 
 
 Scientific name. 
 
 Common name. 
 
 ■6 
 
 1 
 
 t 
 
 2 
 
 a 
 
 7j 
 
 •a 
 a 
 ca 
 
 c 
 
 C 
 ca 
 
 ■a 
 
 ■3 
 
 S 
 
 u 
 
 •a 
 
 ■§1 
 
 i 
 
 i 
 
 a 
 1 
 
 d 
 
 a 
 a 
 
 ■6 
 
 1 
 
 a 
 
 > 
 a 
 
 
 
 
 
 
 
 D 
 DG 
 
 
 G 
 
 D 
 
 
 
 A 
 A 
 
 FD 
 
 ABDE 
 
 AEF 
 
 BE 
 
 A 
 
 Bd 
 
 
 c 
 
 
 2. Alasmidonta marginata. . , 
 
 Elk-toe 
 
 G 
 
 BCo 
 
 
 c 
 C 
 
 
 3, Anodonta corpuleiita 
 
 Slop-bucket 
 
 
 V 
 
 c 
 
 CP 
 
 
 c 
 
 c 
 D 
 CD 
 
 c 
 
 
 
 
 Floater 
 
 
 
 
 
 
 
 
 Paper-shell 
 
 do 
 
 E 
 
 
 
 
 c 
 
 
 
 
 
 
 
 7. Anodontoides ferussacia- 
 
 nus. 
 
 8. Arcidens confragosus 
 
 
 G 
 
 GD 
 
 
 
 dgC 
 
 C 
 
 G 
 
 
 c 
 
 
 Rock pocketbook. 
 Fan-shell 
 
 D 
 C 
 
 c 
 
 BC 
 
 
 
 
 
 
 
 
 
 
 10. Dromiis dromas 
 
 Dromedary mussel 
 
 
 C 
 
 
 
 
 
 
 
 
 
 
 ABD 
 
 
 
 
 B 
 
 ABEf 
 
 ABEd 
 
 D 
 
 ae 
 
 DF 
 
 
 
 
 
 Pink heel-splitter. 
 Yellow sand-shell. 
 Pocketbook 
 
 F 
 
 EGD 
 C 
 G 
 
 CP 
 
 
 DP 
 
 nc 
 
 D 
 
 
 C 
 C 
 
 c 
 
 c 
 
 
 13. Lampsilis anodontoides.. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 Dg 
 
 DF 
 C 
 D 
 
 F 
 c 
 
 GD 
 
 
 
 
 c 
 
 c 
 
 
 16. Ldmpsilis fallaciosa 
 
 Slough sand-shell. 
 
 F 
 
 
 C 
 
 c 
 
 c 
 
 
 Paper-shell 
 
 Higgin'seye 
 
 Rainbow-shell.. . - 
 Paper-shell 
 
 efG 
 
 F 
 AG 
 EP 
 DGP 
 
 P 
 D 
 C 
 
 D 
 
 F 
 
 
 ABDEF 
 
 C 
 
 C 
 
 
 
 
 
 
 
 CG 
 
 DG 
 P 
 
 G 
 
 c 
 C 
 
 C 
 
 A 
 
 EF 
 ABd 
 
 
 
 
 CD 
 
 
 
 22. Lampsilis lij;amentina 
 
 23. Lampsilis ligamentina 
 
 gibba. 
 
 cfgD 
 C 
 
 CF 
 
 c 
 
 F 
 D 
 
 cFG 
 
 DG 
 
 c 
 
 
 Southern mucket . . 
 
 
 Fatmucket 
 
 CdFG 
 
 AC 
 D 
 
 F 
 
 GP 
 
 c 
 
 cFG 
 
 D 
 
 bdFG 
 
 CdfE 
 cfdE 
 
 CEGP 
 BDEP 
 
 DF 
 
 
 
 
 c 
 
 AEfd 
 A 
 
 adef 
 
 
 c 
 c 
 
 
 
 
 
 
 
 
 
 D 
 
 
 D 
 F 
 F 
 
 
 c 
 
 
 27. Lampsilis purpurata 
 
 Purply 
 
 E 
 
 c" 
 
 D 
 
 
 
 Black sand-shell . . 
 
 EFg 
 
 
 
 
 AE 
 BED 
 dAE 
 
 bd 
 Abd 
 
 D 
 
 Ade 
 Adef 
 
 B 
 
 d 
 
 c 
 c 
 
 r 
 
 
 
 
 
 30. Lampsilis ventricosa 
 
 31. Margar itaua monodonta . . 
 
 32. Obliquaria rcflexa 
 
 Pocketbook 
 
 Spectacle-case 
 
 Three-horned 
 
 warty-back. 
 Hickory-nut 
 
 Cgf 
 Cd 
 
 FD 
 CFD 
 
 Cdf 
 CDf 
 
 F 
 D 
 
 D 
 
 Be 
 bcdfE 
 
 cdF 
 
 cdF 
 
 CP 
 
 bdeCF 
 
 
 BD 
 
 Bd 
 
 D 
 
 DP 
 
 G 
 
 c 
 
 c 
 c 
 
 c 
 
 
 D 
 
 D 
 D 
 
 D 
 
 DP 
 
 
 C 
 
 c 
 
 c 
 
 
 
 
 
 
 
 
 
 
 D 
 
 
 c 
 C 
 
 
 c 
 
 c 
 C 
 
 C 
 
 
 37. Pleiirobema aesopus 
 
 Bullhead 
 
 
 
 
 
 
 
 
 
 
 lus. 
 
 39. Quadrula coccinea 
 
 40. Quadrula cylindraca 
 
 
 
 cdG 
 c 
 Dp 
 
 F 
 DP 
 
 D 
 DP 
 
 C 
 DP 
 
 DF 
 DG 
 
 Eg 
 
 C 
 
 FGd 
 
 F 
 
 GD 
 
 G 
 
 
 
 
 A 
 
 
 
 
 
 
 
 
 
 
 D 
 
 D 
 
 
 C 
 C 
 c 
 C 
 c 
 
 
 
 
 
 42. Quadrula granifera 
 
 Purple warty-back 
 
 
 
 
 
 
 
 
 F 
 DP 
 
 D 
 
 D 
 
 BDF 
 
 ABFb 
 
 Bd 
 
 
 
 r 
 
 44. Quadrula lachrymosa 
 
 45. Quadrula metanevra 
 
 46. Quadrula obliqua 
 
 
 AEG 
 
 E 
 bdCEF 
 
 C 
 D 
 
 
 c 
 
 
 
 
 Ohio River pig-toe 
 
 Blue-point 
 
 Pimple-back 
 
 do 
 
 p 
 
 CD 
 
 fG 
 bgG 
 
 
 C 
 
 
 
 F 
 c 
 
 CEF 
 B 
 
 D 
 BDG 
 
 DP 
 D 
 P 
 
 dE 
 
 G 
 
 C 
 
 c 
 C 
 c 
 
 AB 
 
 Bf 
 
 ABFdb 
 
 ABd 
 
 Fd 
 ABF 
 ABdp 
 
 Ad 
 Adef 
 
 ABDEF 
 
 cE 
 
 
 48. Quadrula pustulata 
 
 
 
 
 
 c 
 C 
 
 
 
 
 
 
 
 
 
 Purple warty-back 
 
 G 
 
 DP 
 
 G 
 
 CDGF 
 
 f 
 
 ■ ' DF ' 
 
 CG 
 
 GDP 
 
 F 
 
 G 
 CDGf 
 
 EP 
 C 
 
 bC 
 bdF 
 
 G 
 
 CDFG 
 
 F 
 
 
 
 
 c 
 C 
 
 
 
 
 
 D 
 G 
 G 
 
 D 
 
 D 
 
 DPG 
 
 F 
 
 
 CO 
 
 c" 
 
 D 
 
 c 
 
 c' 
 
 
 54. Quadrula undulata 
 
 55. Strophitus edentulus 
 
 Three-ridge 
 
 Squaw-foot 
 
 White heel-splitter 
 
 
 
 G 
 
 c 
 c 
 
 
 
 c 
 
 c 
 c 
 C 
 c 
 
 
 
 Fluted shell 
 
 GF 
 P 
 
 BCF 
 
 dep 
 
 D 
 
 G 
 P 
 
 
 
 Adp 
 BFde 
 
 
 
 
 C 
 
 
 60. Truncilla sulcata 
 
 Cat's paw 
 
 
 
 
 
 
 
 F 
 F 
 
 G 
 
 C 
 
 BF 
 
 AuEF 
 
 
 
 
 Lady-finger 
 
 DPG 
 
 GP 
 
 DFGe 
 
 
 
 
 
 
 
 
 It appears from this and the following table that the preferred bottom for the 
 majority of species is mud (but not deep, soft mud, to which type of bottom few species 
 are adapted) and gravel, including sand and gravel. Sand ranks next and clay last; 
 but few species of mussels exhibit a preference for sand or sandy clay, and only two are 
 
FRESH-WATER MUSSELS. 
 
 107 
 
 recoided (by one observer) as finding the most favorable environment in a bottom of 
 clay unmixed with sand. 
 
 Table 6 may be simplified by reducing the types of bottom to four general classes, 
 sand, gravel, mud, and clay, and by eliminating all but the leading commercial species. 
 The results are indicated in Table 7 following : 
 
 Table 7. — Preferred Habitats of Leading Economic Fresh-water Mussels, According to 
 
 Character of Bottom. 
 
 IX indicates preference as noted by majority and x by minority of observers.] 
 
 Scientific name. 
 
 Common name. 
 
 Sand.o 
 
 Gravel.ft 
 
 Mud.c 
 
 Clay.* 
 
 Lampsilis anodontoides 
 
 LampsiUs fallaciosa 
 
 Lampsilis recta , 
 
 Lampsilis ligamentina 
 
 Lampsilis lieamentina gibba. 
 
 Lampsilis luteola 
 
 Lampsilis ventricosa 
 
 Obovaria ellipsis 
 
 Plagiola securis 
 
 Quadrula coccinea 
 
 Quadrula ebenus 
 
 Quadrula heros 
 
 Quadrula lachrymosa , 
 
 Quadrula metanevra 
 
 Quadrula obliqua 
 
 Quadrula plicata , 
 
 Quadnda pustulosa , 
 
 Quadrula rubiginosa , 
 
 Quadrula undata 
 
 Quadrula undulata 
 
 Unio crassidens 
 
 Unio gibbosus 
 
 Yellow sand-shell . . 
 Slough sand-shell. . 
 Black sand -shell. . . 
 
 Mucket 
 
 Southern mucket. . 
 
 Fat mucket 
 
 Pocketbook 
 
 Hickory-nut 
 
 Butterfly 
 
 Flat niggerhead 
 
 Niggerhead 
 
 Washboard 
 
 Maple-leaf 
 
 Monkey-face 
 
 Ohio River pig-toe. 
 
 Blue-point 
 
 Pimple-back 
 
 X 
 X 
 X 
 
 X 
 
 X 
 X 
 
 X 
 X 
 
 X 
 X 
 
 X 
 
 X 
 
 X 
 
 Pig-toe 
 
 Three-ridge. . . . 
 Elephant's ear. 
 Lady-finger. . . 
 
 X 
 
 x" 
 
 X 
 
 x 
 
 X 
 X 
 
 a Sand alone. 
 
 t> Including sand and gravel, mud and gravel, and rocks. 
 
 ^ Mud alone. 
 
 ^ Including sand and clay, mud and clay. 
 
 DEPTH. 
 
 The distribution of many animdis of the water is known to be influenced by depth, 
 the effect of which may be felt, among other ways, through pressure, light, temperature, 
 dissolved gases, and freedom from wave action, or exposure thereto. In an indirect way, 
 too, the effect of depth is experienced by any animal through the influence of these 
 conditions upon food and enemies. 
 
 The increase of pressure is approximately i atmosphere for each lo meters (33 
 feet) in depth, but fresh-water mussels are, so far as known, restricted to shallow waters 
 where pressures must be insignificant. The Sphseriids are the only mollusks found 
 below the 25-meter line in Lake Michigan (Shelford, 1913). Maury (1916, p. 32), (see 
 Baker, 1918, p. 155), reporting the results of dredging in Cayuga Lake, N. Y., says: 
 "These dredgings proved conclusively that MoUusca after 25 feet become very scarce. 
 * * * In the greater depths no signs of Mollusca or of plants were found." In 
 clear water minor depths do not markedly affect the light, but if the water is turbid, a 
 common condition in the environment of fresh-water mussels, the penetration of light 
 is very much diminished (see p. 114), and mussels if affected by light may, therefore, 
 be expected to live at greater depths in clear lakes than in turbid streams. Temperature 
 changes due to depth alone are so inconsiderable for shallow water as doubtless to have 
 little effect upon the distribution of mussels, except where freezing to the bottom may 
 occur. 
 
 9745°— 21 3 
 
Io8 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 The depth of water below which waves would reach them is apparently a factor in 
 determining the habitat of many species of mussels in lakes (Headlee, 1906, p. 308 — 
 Winona Lake; Muttkowski, 1918 — Lake Mendota). In large bodies of water like Lake 
 Michigan the action of the waves is said to extend to 8 meters below the surface. The 
 zone of wave action is a region in lakes comparable to the rapids and riffles of streams, 
 where there is maximum circulation and aeration and a solid bottom suitable for 
 such mussels as can withstand the violent action of waves and undertow currents. 
 The species occupying this zone are given by Headlee for Winona Lake as the spike, 
 Unio gibbosus, and the fat mucket, L. luteola. Baker (1916) says of this habitat in 
 Oneida Lake : 
 
 The shore may be free from vegetation. It receives the full force of the winds and waves from the 
 open lake. The water is from i to 3 feet in depth and the bottom is heavily and thickly covered with 
 stones and bowlders, many of the latter being of large size. Animal life is abundant, the clams living 
 between the stones and on the sand between the stones. 
 
 The mussels he reported are as follows: Elliptio complanaius, common; LampsUis 
 luteola, rare; LampsUis radiata, common; LampsUis iris, rare; Margaritana m,argari- 
 tijera, rare; Anodonta caiaracta, common; Anodonta iviplicata, coramoia; Anodonta 
 grandis, common; Strophitus edentulus, rare. Some of these are very thin shelled and 
 doubtless survive the force of the waves only through the protection afforded by the 
 large rocks. No doubt the thorough aeration of the water, resulting from wave action, 
 is a favorable factor in this zone 
 
 On the shores of Lake Pepin one of the authors has often picked up live mussels 
 that had been thrown up by heavy wave action. The mussels thus most frequently 
 encountered were Unio gibbosus, LampsUis alata, Anodonta corpulenta, Strophitus eden- 
 tulus, LampsUis vcntricosa, and LampsUis luteola in about the order named. They were 
 usually immature examples. Occasionally after a stomi had subsided one could see 
 mussels that had not been entirely stranded on the beach near shore and in the act of 
 making their way back' again into deeper water. Headlee and Simonton (1904, p. 175) 
 recorded similar observations. 
 
 While the data available are sufficient only to suggest how depth may affect the 
 haoitat selection of mussels, it is of interest to note some of the observations on this 
 relation. A maximum depth of 22 feet for mussels in Winona Lake is given by Headlee 
 (1906), who ascribes the control of distribution to bottom characters chiefly. Baker 
 (191 8) found that in Oneida Lake twice as many mussels occurred in water deeper than 
 6 feet as within the 6-foot contour. (See quotation, p. 103, above.) He records three 
 species as limited to a depth of i K to 8 feet, three as living at varying depths between 
 i}4 and 18 feet, and one subspecies as occurring only between 8 and 18 feet, the greatest 
 depth which he explored. He reports an interesting case of bathymetric distribution of 
 two races, LampsUis radiata, occurring at i K to 3 feet, and a subspecies, LampsUis radiata 
 oneidensis, living only at 8 to 18 feet, the two forms showing a distinct difference in 
 habitat. For Lake Mendota the optimum depth for mussels of the genera Anodonta 
 and Lampsilis is given as from 2 to 3 meters (6 to 10 feet) (Muttkowski, 191 8, p. 477); 
 they were, however, found abundantly between 3 and 5 meters and rarely at greater 
 depths than 7 meters (23 feet). 
 
 Wilson and Dangiade (1914), in reporting a reconnoissance of mussel resources in 
 Minnesota waters, give depths of the lakes, but without detailed data on the distribution 
 
FRESH-WATER MUSSELS. IO9 
 
 of the mussels. In Lake Maxinkuckee, Evemiann and Clark (1918, p. 255) say: "Mussels 
 are to be found almost anywhere iii water 2 to 5 or 6 feet deep where the bottom is 
 more or less sandy or marly." Headlee (1906, p. 306) found that the mussel zone 
 generally extended from the shore line to where the bottom changes from sand, gravel, 
 or marl to very soft mud, a region in Winona Lake covered by from 4 inches to 9 feet 
 of water. He did find, however, some mussels on sandy bottom in 22 feet of water. 
 He made some experiments in retaining mussels at various depths and in a crate placed 
 in 85 feet of water; only i of 10 specimens died in six days of exposure. After 12 days 
 several specimens were found badly choked with mud. 
 
 In Lake Pepin mussels are plentifully found at depths ranging from 8 to 20 feet, 
 but the majority are taken at depths ranging from 12 to 1 8 feet. Relative to the juvenile 
 mussels, out of a total of 1,397 collected in 1914, 1,283, or 9i-8 per cent, were taken ata 
 depth of 3 to 8 feet; 2.6 per cent at 8 to 12 feet; 2.3 per cent at 12 to 16 feet; 0.4 per 
 cent at 1 6 to 20 feet ; and 2.9 per cent at 20 to 25 feet. A . imhecillis was the only juvenile 
 found in any abundance at a depth greater than 15 feet, and 41 of the 79 individuals of 
 this species collected were taken at 25 feet (Shira, report in manuscript). 
 
 A marked distribution with regard to depth has been observed in the artificial 
 ponds at Fairport, Iowa. Here the species, Lampsilis luleola, is seldom found below a 
 depth of 3 feet. When held in crates below this depth it does not thrive, although in its 
 natural habitat. Lake Pepin, this species is abundant at a depth of 8 to 20 feet and has 
 been taken at a depth of 25 feet. 
 
 In rivers and smaller streams mussels seem to be found commonly at lesser depths 
 than in lakes, but unfortunately we have very few reports of observations in the deeper 
 parts of large rivers. In the Illinois River, Danglade (191 4) mentions a small bed 2 to 3 
 acres in extent above the mouth of Spoon River, where the bottom was of mud, the 
 current about 2 miles per hour, and the depth of water 8 feet. At Chillicothe he found 
 a good bed at a depth of 1 2 to 1 5 feet. The survey of Andalusia Chute, Mississippi River 
 (Howard, report in preparation), carried on during relatively high-water stages in 1915, 
 revealed no mussels in the deeper portion of the river over 12 feet in depth, and the 
 greater number of mussels were found at depths less than 10 feet. Local informants at 
 Madison, Ark., stated that the niggerhead, Quadrida ebenus, was found in water 20 to 50 
 feet deep; it was also said that in flood season it was captured from a depth of 75 feet. 
 There has been no opportunity, however, to verify these statements. 
 
 With regard to a collection of 183 juveniles of the Quadrula group from 12 stations 
 in the Mississippi River, Howard (1914, p. 34) reported depths from o to 8 feet. Wilson 
 and Clark (191 4) reported a rich find (19 species) in the Rock Castle River off the Cum- 
 berland, in water having a maximum' depth of iK feet. In the Grand River, Mich., 
 the senior author has found mussels (muckets, Lampsilis ligamentina, three-ridge, 
 Quadrula undulata, and others) in conspicuous abundance in swift water less than a foot 
 in depth. Boepple (Boepple and Coker, 191 2) found mussels abundant and of fine 
 commercial quality in water from i to 3 feet in depth in the Holston and Clinch Rivers 
 of Tennessee. In Caddo Lake, Tex., Shira (1913) found an abundance of mussels in 
 4 to 8 inches of water, and in many places there was scarcely enough water to cover the 
 shells. This lake was very shallow over large areas. In fact, mussels are frequently 
 found in very shallow water where the conditions of the bed of the stream and other 
 
no BULLETIN OF THE BUREAU OF FISHERIES. 
 
 factors are favorable. In various parts of the country considerable commercial quan- 
 tities of mussels are collected by hand from shallow waters. At one such place, Lyons, 
 Mich., the mucket, Lampsilis ligamentina comprised 80 per cent of the collection, although 
 the three-ridge, Quadrula undiUala, the pocketbook, Lampsilis ventricosa, the spike, 
 Unio gihbosus, and the black sand-shell, Lampsilis recta, were quite common. Among 
 other species that were frequently found in very shallow water (i to 2 feet in depth) in 
 that stream were the following: Lampsilis luteola, iris, and ellipsijormis, Quadrula 
 coccinea and rubiginosa, Sirophitus edentulus, Symphynoia compressa and costata, Alasmi- 
 donta marginata, Anodontoides jerussacianus, and Anodonta grandis. In fact, the only 
 species that were not found in water less than 6 feet in depth in the Grand River were 
 the three-homed warty-back, Obliquaria reflexa, the hickory-nut, Obovaria ellipsis, the 
 deer-toe, Plagiola elegans, and the white heel-splitter, Symphynota complanata. 
 
 LIGHT. 
 
 The small floater, A nodonla imbecillis Say, in sunlight will draw in its siphons when 
 a shadow passes over. Wenrick (1916) has demonstrated experimentally mth measured 
 illumination, that a fresh-water mussel, Anodonta cataracta Say, is very sensitive to 
 decrease in intensity of light. Observations in the Washington laboratory indicate that 
 the yellow sand-shell, Lampsilis anodontoides, will close when a black cloth is placed 
 over the aquarium, but will open when exposed either to daylight or to the light of a 
 bright electric lamp. These reactions may be for protection of the animal from approach- 
 ing enemies, but it is probable also that the distribution of mussels is largely influenced 
 by light conditions. Mussels are seldom found in vegetation which is dense enough to 
 exclude the light to a great extent. This is especially true with regard to plants like the 
 water lily which have floating leaves. Some relations to vegetation are brought out 
 in a study of the habitats in Oneida Lake (Baker, 191 6). 
 
 An exceptional case is reported by Wilson and Danglade (191 4, p. 15) where the 
 mussels were found in densest aggregation submerged deeply in the bottom and below 
 a covering of vegetation. Their account is of sufficient interest to be quoted in full : 
 
 The bottom of the river where these shells are obtained is covered with algae and water weeds to the 
 depth of 12 to 18 inches, and the thicker the vegetation the more plentiful the mussels beneath it. Two 
 men were actively working the Shell River at Twin Lakes near Menahga at the time of our visit, and we 
 watched them rake off the algae and weeds and then dig into the underlying gravel and sand for the 
 mussels. The latter are often buried to the depth of a foot or more. This is, at the least, a novel con- 
 dition and one which, so far as is known, has not been reported from any other locality. 
 
 Certain species of mussels, the mucket, pocketbook, black sand-shell, and others 
 are sometimes pink-nacred and sometimes white-nacred, and with the two former, at 
 least, the outside covering of the shell has a reddish cast in pink-nacred examples. 
 With such species it is a matter of common observation that pink-nacred shells and 
 brightly colored exteriors are more frequently found in shallow clear water where the 
 mussels are exposed to bright light." Thus the black sand-shells of the upper part of the 
 Grand River, Mich., have a deep purple nacre, while white shells of the same species 
 predominate in the more turbid Mississippi. The spike, Unio gibbosus, is usually purple- 
 nacred, but uncommon examples that are nearly white are found in turbid rivers. Clark 
 
 " Grier (1920a) presents the result of an extensive study of the nacreous color of mussels. He notes a tendency to lighter of 
 bluish nacreous color in the lower portion of stream courses- He has evidence of some correlation between color and sex. 
 
FRESH- WATER MUSSELS. • III 
 
 and Wilson (191 2) describe the Maumee River as ratiier muddy most of the time, and it 
 is interesting to find that they report that two-thirds of the spikes, Unio gibbosus, in that 
 river were white-nacred and that the black sand-shells were usually white-nacred. 
 
 The reputed migration of certain mussels toward shore in time of flood may be an 
 accommodation to light conditions associated with turbidity of water under such con- 
 ditions. We have virtually no data on the distribution of mussels with respect to 
 permanently shaded areas or with regard to the reactions to daily changes in light. 
 
 CURRENT. 
 
 The luxuriant development of certain mussels in streams where the current is 
 strong, in contrast with their growth in sluggish portions of rivers and lakes, bears 
 witness to the significance of current as a favorable factor of environment for fresh- 
 water mussels. Current is a characteristic feature of streams, and the rate of flow is 
 largely determined by the gradient of the channel. Currents producing a circulation 
 of water occur also in lakes, where they are caused chiefly by wind and to a less extent 
 by changes of temperature. In some lakes the circulation extends from top to bottom, 
 but in small deep lakes only a partial surface circulation commonly prevails (Birge and 
 Juday, 191 1 ). Undertow currents are also developed where there is wave action, and 
 under some conditions convection currents must exist in natural bodies of water, but 
 we have little data on this. 
 
 Shelford (1913) emphasizes the relation of water animals to current as follows: 
 
 The distribution of dissolved salts and gases is dependent upon the circulation of the water, as 
 their diffusion is too slow to keep them evenly distributed. The water of streams has been found to 
 be supersaturated with oxygen [citing Birge and Juday, 1911]. Oxygen is taken up by water near the 
 surface. Nitrogen and carbon dioxide are produced especially near the bottom, and if the water did 
 not circulate they would be too abundant in some places and deficient in others for animals to live 
 (p. 60). * * » 
 
 The current in streams differs from that in lakes in that it is for the most part in one direction 
 while the lake currents often alternate. There are backward flows and eddies at various points in 
 streams in front of and behind every object encotintered in the current. As we pass across a stream 
 we find the current swiftest near the surface in the middle and least swift at the bottom near the sides 
 (p. 61). * * * 
 
 The factors of greatest importance in governing the distribution of animals in streams are current 
 and kind of bottom. They influence carbon dioxide, light, oxygen content, vegetation, etc. (p. 66). 
 
 Since mussels are bottom dwellers and largely stationary in habit, one can appreciate 
 how dependent they must be upon circulation of the water to bring renewed supplies 
 of organic food, mineral matter in solution, and oxygen, and to remove the poisonous 
 products of metabolism that are produced in their own bodies and in those of other 
 organisms living about. Mussels, of course, cause by their respirative currents cir- 
 culation of the water immediately about them, but this is not sufficient to prevent 
 an early exhaustion of food supply unless broader currents prevail. 
 
 It must be emphasized, too, that flowing water carries more matter in suspension 
 than still water. It has been seen (p. 91) that the food of mussels consists to a con- 
 siderable extent of the finely divided solid matter; but such materials, however abun- 
 dant on the bottom, are not available to the mussel imtil they are taken up in the water 
 and carried to the mussel. The effects of the current, then, both in lifting solid matter 
 from the bottom and in holding it in suspension play a foremost part in its relation 
 
112 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 to the welfare of mussels. The power of water to move solid matter on the bottom 
 increases very rapidly with the rate of flow. 
 
 The capacity of water to move solid matter from a condition of rest on the bottom of a stream 
 varies with the sixth power of the velocity of the stream. If the velocity is doubled, the increase 
 in the force which is capable of putting the particle in motion is multiplied 64 times. (New York 
 report of Metropolitan Sewerage Commission, 1912, p. 41.) 
 
 Fish frequent areas near the current but maintain themselves in eddies or in places 
 where the current is relatively slack, as at the bottom and near the shores (vShelford, 1913). 
 In view of the essential part that fish play in the distribution of mussels, the habits 
 of the fish may be a very significant factor in the distribution of mussels with reference 
 to current. It has been suggested by Evermann and Clark (1918, p. 252) that currents 
 may promote the reproduction of mussels by making fertilization of the egg more 
 certain and by decreasing the chance for inbreeding through the conveyance of sperm 
 from mussels farther upstream. In still waters the chance for fertilization of eggs 
 may be less favorable. 
 
 The relations of mussels to temperature have not been fully investigated, but it 
 seems certain that flowing water must protect mussels from excessively high tempera- 
 tures and thus permit many species to live in much shallower water in streams than 
 in ponds or lakes. 
 
 The tendency of mussels to locate apart from the main channel and nearer the 
 banks of the streams has previously been mentioned (p. 97). While this distribution 
 may be partly due to the fact that there the full force of the current is avoided while 
 many of its benefits are received, nevertheless it must not be overlooked that many 
 species of mussels thrive in rapid shallow streams and that such regions of swift water 
 in the Mississippi River, as the fomier "rapids" at Keokuk or the existing "rapids" 
 above Davenport, have been among the most prolific mussel grounds of the entire river. 
 In these circumstances, however, the rocky nature of the bottom affords the mussels 
 protection against some' effects of the current. Evidently the barrenness of the main 
 channel in most cases is due rather to the nature of the bottom combined with the force 
 of flow than to the strength of current alone. 
 
 On page 99 there have been listed the species of mussels which are characteristic 
 of lakes and ponds, regions of comparatively still water. The more common mussels 
 of rivers may be classified according to apparent adaptation to sluggish water, strong 
 current, and rapids (Table 8). These general comments should be made: In a firm 
 bottom, such as furnishes good anchorage, a mussel may dwell in a current swifter 
 than is characteristic of its common habitats; where rocks furnish shelter, mussels 
 below them may be in rather slow water despite the current around them; deep water 
 may be fairly sluggish under a swift surface current. 
 
 EXPLANATION OF TABLE 8. 
 
 The symbols are those used in Table 6, C representing Clark; D, Howard; F, Shira; and G, Coker. 
 The large capital denotes preference in the opinion of the observer, for a particular condition of current. 
 The small capital denotes that the condition is favorable but not, so far as is known, preferred to other 
 conditions. When no large capital occurs on a line, no preference is indicated; and when a particular 
 letter appears in small capital throughout a line, the observer denoted by the letter has no evidence 
 upon which to base an opinion of discrimination on the part of the particular mussel between the 
 different conditions of current regarded as favorable. 
 
FRESH-WATER MUSSElvS. II3 
 
 Table 8. — Classification of Common Fresh-water Mussels in Relation to Current. 
 
 Scientific name. 
 
 Common name. 
 
 Little or no 
 current. 
 
 Fair or good 
 current. 
 
 Stn»igor 
 swift cur- 
 rent. 
 
 Alasmidonta calceola 
 
 Alasmidonta raarginata 
 
 Anodonta corpulenta 
 
 Anodonta grandis 
 
 Anodonta imbecillis 
 
 Anodonta suborbiculata . . . . 
 Anodontoides ferussacianus. , 
 
 Arcidens confragosus 
 
 Cyprogenia irrorata 
 
 Dromiis dromas 
 
 Hemilastenia ambigua 
 
 Lampsilis alata. 
 
 Lampsilis anodontoides 
 
 Lampsilis capax 
 
 Lampsilis ellipsiforniis 
 
 Lampsilis fallaciosa 
 
 Lampsilis glans 
 
 Lampsilis gracilis ._ 
 
 Lampsilis hig&insii 
 
 Lampsilis iris 
 
 Lampsilis laevissima 
 
 Lampsilis liganieotiua . ._ 
 
 I^ampsilis ligamenlina gibba 
 
 Lampsilis luteola 
 
 Lampsilis muUiradiata 
 
 Lampsilis pan'a 
 
 Lampsilis purpurata 
 
 Lampsilis recta 
 
 Lampsilis subrostrata 
 
 Ivampsilis ventricosa 
 
 Margaritana monodonta 
 
 Obliquaria rcilexa 
 
 Obovana ellipsis' 
 
 Plagiola donaciformis 
 
 Plagiola elegans 
 
 Plagiola securis 
 
 Pleurobema aesopus 
 
 Plychobranchus phaseolus. . 
 
 Quadrula coccinea 
 
 Quadnila cylindrica 
 
 Quadnila cbemis 
 
 Quadrula granitera 
 
 Quadrula heros 
 
 Quadrula lachr>Tnosa 
 
 Quadrula metanevra 
 
 Quadrula ol^liqua 
 
 Quadrula plicata 
 
 Quadnila pustulata 
 
 Quadrula pustulosa 
 
 Quadrula rubijcinosa 
 
 Quadrula trapezoides 
 
 Quadrula tuberculata 
 
 Quadrula undata 
 
 Quadrula undulata 
 
 Strophitus edentulus 
 
 Symphynota complanata, . . 
 Symphynota coraprcssa. . . . 
 
 Symphynota costata 
 
 Tritogonia tuberculata 
 
 TrunciUa sulcata 
 
 Unio crassidens 
 
 Unio gibbosus 
 
 Slipper-shell. 
 
 Elk-toe 
 
 Slop-bucket . . 
 
 Floater 
 
 Paper-shell... 
 ....do 
 
 CDF. 
 CDF. 
 CDF. 
 CD... 
 
 Rock pocketbook . . . 
 
 Fan-shell 
 
 Dromedary mussel. 
 
 CG 
 
 CDF. 
 
 Pink heel-splitter. 
 Yellow sand-shell. 
 Fat pocketbook . . . 
 
 D 
 
 cDFG. 
 
 Slough sand-shell. 
 
 Paper-shell. 
 
 Higgin's eye 
 
 Rainbow-shell. . . . 
 
 Paper-shell 
 
 Mucket 
 
 Southern mucket. 
 Fat mucket 
 
 cD 
 
 CG 
 
 DF.... 
 
 CDFG.' 
 
 cgD.. 
 CDF. 
 
 CDFG. 
 
 Purply 
 
 Black sand-shell. 
 
 CDF. 
 cF... 
 
 Pocketbook 
 
 Spectacle-case 
 
 Three-homed warty-back. 
 Hickory-nut 
 
 CD... 
 
 CFGD. 
 
 Deer-toe 
 
 Butterfly 
 
 Bullhead 
 
 Kidney-shell 
 
 Flat niggerhead 
 
 Rabbit's-foot 
 
 Niggerhead 
 
 Purple warty-back. 
 
 Washboard 
 
 Maple-leaf 
 
 Monkey-face 
 
 Ohio River pig-toe. 
 
 Blue-point 
 
 Fimple-back 
 
 do 
 
 DP. . 
 
 DF. 
 F 
 
 Bank-climber 
 
 Purple warty-back. 
 
 Pig-toe 
 
 Three-ridge 
 
 Squaw-foot 
 
 Wliite heel-splitter. 
 
 cF. 
 
 DP.... 
 cgD... 
 cgDF. 
 CPG. . . 
 
 Fluted shell.... 
 
 Buckhom 
 
 Cat's paw 
 
 Elephant's ear. 
 Lady-finger 
 
 cdgF. 
 
 CG. 
 C... 
 ct.. 
 
 CG. . 
 
 CD... 
 CF 
 
 CDF. 
 C... 
 CG... 
 CF... 
 
 c 
 
 CDF.. 
 
 CDF. 
 CG... 
 
 F 
 
 CF... 
 
 C... 
 
 CFG. . 
 C 
 
 CP 
 
 CDFG. 
 
 c 
 
 CD KG. . 
 
 CD 
 
 CFGd.. 
 
 CDFG 
 
 CDF... 
 
 CFG... 
 
 CDF... 
 
 CDF... 
 
 C 
 
 CDg... 
 
 CF 
 
 CFd. . . 
 
 CD 
 
 CDF. . . 
 CFG. . . 
 CDF... 
 
 C 
 
 CDF... 
 CDF... 
 CFGd.. 
 CDG... 
 
 CF 
 
 CG 
 
 CFd... 
 CFGd.. 
 
 CDG . . . . 
 
 CDF... 
 
 CF... 
 CFd.. 
 C... 
 CDF. 
 
 CDG. . 
 
 DG 
 
 DG 
 c 
 
 dG 
 
 D 
 
 DG 
 
 Dg 
 
 WATER CONTENT. 
 
 The matter that is carried in all natural waters in varying quantities and proportions 
 consists of suspended matter, botli dead and living, minerals and other ordinarily solid 
 substances in solution, and dissolved gases. All of these classes of substances are utilized 
 by fresh-water mussels in one way or another, and the quantity of any of them in the 
 water has a direct bearing upon the suitability of waters for mussels. 
 
114 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 SUSPENDED MATTER. 
 
 The solids carried in suspension by water consist of mineral and organic substances. 
 The particles of mineral matter brought in by surface drainage or derived from bottom 
 and shores, apart from that which is in solution, range in size from coarse to very minute. 
 The carrying power of the water varies with the sixth power of the velocity, although 
 in the case of the most minutely divided substances other factors than rate of flow 
 come into play. 
 
 Mussels are afifected in various ways by the matter in suspension. It has been 
 reported that some mussels stop feeding when the water is excessively turbid, as after 
 a storm. In this way they would avoid taking into their stomachs large amounts of 
 indigestible mineral. They have, however, the power of ejecting undesirable matter; 
 this may enable them to continue feeding even though the water is moderately turbid 
 In streams like the Mississippi, mussels could hardly survdve without feeding during 
 the long periods of turbidity that prevail. Excessive precipitation of silt may smother 
 or even bury the mussel (Headlee and Simonton, 1904, p. 176). The turbidity of water 
 over deeper beds materially restricts the amount of light reaching the mussel, and it is 
 possible that this has an untoward effect. Data regarding the turbidity of several 
 streams are given in Table 9, page 116. The turbidity of representative mussel-producing 
 streams varies from 37 to 188, except that the Des Moines River at Keosauqua has a 
 turbidity rating of 542 — a striking exception. The Missouri and Red Rivers (non- 
 productive) and portions of the Mississippi River which do not yield commercial mussels 
 have turbidity ratings from 556 to 1,931. 
 
 Organic materials, both living and dead, are abundantly suspended in most natural 
 waters, and form a large part of the food of mussels. (See p. 91.) The living bodies 
 are the microscopic plants and animals which make up what is called the plankton. 
 The dead organic materials are the remains or fragments of plants and animals in a 
 state of decomposition, and such also form a part of the food supply. 
 
 Some of the plankton originates in the lake or stream in which the mussels are 
 living. Another and perhaps the greater part is brought in by the tributary streams. 
 Similar statements may be made regarding the dead organic matter, with the addition 
 that some of this may be brought in by surface drainage from the bordering lands. 
 
 MINERALS IN SOLUTION. 
 
 To what extent mussels derive the mineral matter necessary for the sustenance of 
 life and the formation of shells directly from the water or through the solid food con- 
 sumed can not be said, but even that part which is derived from solid food must have 
 been obtained by the smaller organism from the water or the soil. Churchill (191 5 and 
 1916), from experiments conducted at the Fairport Station, has shown that fresh-water 
 mussels possess the ability to make use of nutriment which is in solution in the water. 
 WhUe he demonstrated this for such nutritive substances as fat, protein, and starch, 
 there are yet wanting, as he has pointed out, analyses of the natural water in which 
 mussels live to prove that such organic substances are present in the waters in quantities 
 sufficient to play an important part in the nutrition of mussels. There are, however, 
 abundant analyses to prove the presence of dissolved minerals. 
 
 The requirements of mussels in mineral food may be ascertained by analysis of 
 the soft bodies and shells, Such analysis shows that while the shell is about 95 per cent 
 
FRESH- WATER MUSSELS. II5 
 
 calcium carbonate, and 3K per cent organic matter, it also contains other minerals in 
 very small proportions, less than i per cent each, such as silica, manganese, iron, alumi- 
 num, and phosphoric acid. It does not follow that because these minerals, other than 
 calcium, occur in minute proportions, they are any the less essential to the welfare of 
 the mussel; iron forms a very small proportion of the human body, but man can not 
 live without it. So these minerals may, then, be just as essential to the formation of 
 good shell as calcium, but with the possible exception of manganese it is probable that 
 all natural waters contain a sufficient quantity of the minerals to satisfy the needs of 
 mussels. Nevertheless an interesting and important problem may be found in a com- 
 parative study of the mineral content of different waters which yield shells of diverse 
 qualities. It is even possible that an excessive proportion of certain minerals in water 
 tends to the formation of shells that are brittle, discolored, or otherwise inferior. 
 
 The sundried meats of mussels from the Mississippi River when analyzed have 
 been found to contain, besides moisture (about 7.6 per cent), protein (calculated from 
 nitrogen), 44 per cent; glycogen, about 9 per cent, ether extract (presumably fats), 
 a little less than 3 per cent; and undetermined organic material, 13 per cent. The 
 remainder is mineral matter (chiefly phosphoric acid), 9 per cent; calcium (calcium 
 oxide), 8 per cent; silica, 3>^ per cent; manganese, about one-half of i per cent; and 
 such other minerals in small proportions as sodium, potassium, iron, and magnesium 
 (Coker, 191 9, p. 62, analysis by U. S. Bureau of Chemistry). 
 
 As previously indicated, nearly all natural waters, at least those fed largely with 
 surface drainage, probably contain certain quantities of the required minerals, but it 
 would be going beyond the bounds of present knowledge to say whether or not the 
 abundant growth of mussels in certain streams and the variable qualities of shells 
 produced in different streams are related to the proportions of minerals present other 
 than calcium. Certain it is that a deficiency of lime is very unfavorable. The soft 
 waters of the Atlantic slope support very few mussels and these are small in size and 
 possess thin shells which are usually badly eroded. The thinness of the shells is asso- 
 ciated with the deficiency of calcium in the water, and the erosion is an indirect result 
 of the same cause, since the free carbonic acid, which attacks and consumes the shells 
 wherever the protective horny covering has been broken by abrasion, would, in harder 
 waters, be combined with the calcium in solution to form the bicarbonate. 
 
 Circulation, of course, plays a great part in making available to mussels the dissolved 
 content of the water. It may be due not so much to low calcium content as to inadequate 
 circulation that small lakes and ponds in States of the Middle West generally yield 
 mussels with thin or dwarfed shells. 
 
 The waters of many streams of the United States have been subjected to analysis 
 by the United States Geological Survey (Dole, 1909). The summarized analyses for 
 several streams, or parts of streams, productive of mussel resources, and for 10 others 
 that are not productive of commercial shells, are given in Table 9 below. It appears 
 that, within broad limits, the variations in content of silica, iron, magnesium, sodium, 
 and potassium are not significant as affecting productiveness (unless, as may be the 
 case, the quality of the shell produced is affected) . Particular attention may be directed 
 to the columns of turbidity, calcium, carbonate radicle, and nitrate radicle. The 
 nonproductive streams, or parts of streams, listed are generally either very high in 
 turbidity or very low in calcium, bicarbonate, and nitrate. The Shenandoah, among 
 
ii6 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 nonproductive streams, is an interesting exception. So far as can be seen, its analysis 
 conforms essentially to the standard of productiveness in mussels as revealed by streams 
 of the Mississippi Basin. It is possible, then, that the Shenandoah, and perhaps a few 
 other streams of the Atlantic or Pacific slopes, might support fresh-water mussels of 
 commercial value should the proper species be introduced. 
 
 Table 9.- 
 
 -Contents of Waters op Certain Productive Mussel Streams and Other Nonpro- 
 ductive Streams." 
 
 PRODUCTIVIv RIVERS. 
 
 Wabash, Vincenues. Ind 
 
 lUinois, La Salic. Ill 
 
 niinois, Kamps\'ille, 111 
 
 Fox. Ottawa. HI 
 
 San^ramon. Springfield. Ill 
 
 Cumberland. Nashville, Tenn. . 
 
 Cumberland, Kuttawa. Ky 
 
 Des Moines, Keosauqua, Iowa. . 
 
 Grand, Grand Rapids, Mich 
 
 Cedar. Cedar Rapids. Iowa 
 
 Maumee. Toledo, Ohio 
 
 Mississippi, !Moline, 111 
 
 Mississippi, Quincy, 111 
 
 NOKPRODUCTIVE RIVER.S, 
 
 James, Richmond, Va 
 
 Potomac, Cimiberland, Md 
 
 Wateree, Camden, S. C 
 
 Shenandoah. MiUville, W, Va. . 
 
 Mississippi, Chester, 111 
 
 Mississippi, Memphis, Tenn 
 
 Red, Shrcveport, La 
 
 Missouri, Ruegs, Mo 
 
 Savannah, Augusta, Ga 
 
 Hudson. Hudson, N. Y 
 
 Cape Fear, Wilmington, N. C. . 
 
 Turbidity. 
 
 17a 
 159 
 188 
 94 
 74 
 136 
 176 
 54» 
 37 
 64 
 '43 
 117 
 173 
 
 90 
 
 23 
 
 359 
 
 31 
 
 858 
 
 5S6 
 
 790 
 
 1. 931 
 
 173 
 
 13 
 
 73 
 
 Suspended 
 matter. 
 
 193 
 ■36 
 14s 
 
 87 
 
 39 
 94 
 i6s 
 643 
 43 
 6r 
 
 113 
 
 106 
 119 
 
 71 
 29 
 
 314 
 
 39 
 634 
 519 
 870 
 ,890 
 143 
 16 
 
 Coeificient 
 of fineness. 
 
 .80 
 .80 
 1. 30 
 .80 
 
 •74 
 
 • 93 
 
 I.09 
 1. 61 
 
 -97 
 •95 
 
 .96 
 I. 59 
 
 •79 
 1.64 
 
 •97 
 
 •77 
 1.36 
 
 Total 
 iron (Fe) 
 
 SiUca 
 (SiOs). 
 
 Iron (Fe). 
 
 li.O 
 
 0. 34 
 
 IJ.O 
 
 . 21 
 
 13.0 
 
 •"7 
 
 II^O 
 
 .ao 
 
 16.0 
 
 ■i' 
 
 20.0 
 
 .43 
 
 18.0 
 
 .30 
 
 33.0 
 
 .36 
 
 14.0 
 
 •07 
 
 14.0 
 
 .09 
 
 17.0 
 
 .37 
 
 16.0 
 
 •59 
 
 18.0 
 
 .46 
 
 18.0 
 
 .5 
 
 8.3 
 
 .14 
 
 25.0 
 
 .38 
 
 iS^o 
 
 .08 
 
 33.0 
 
 •39 
 
 34.0 
 
 .61 
 
 30.0 
 
 1.1 
 
 39.0 
 
 .51 
 
 33- 
 
 .44 
 
 II. 
 
 ■IS 
 
 9.9 
 
 •78 
 
 Calcium 
 
 (Ca). 
 
 61.0 
 so.o 
 47-0 
 60.0 
 
 53.0 
 26.0 
 28.0 
 58.0 
 56.0 
 48.0 
 57.0 
 33-0 
 36-0 
 
 14.0 
 24.0 
 6.3 
 33.0 
 44.0 
 36.0 
 
 74- O 
 52-0 
 5-7 
 
 2I>0 
 S-O 
 
 Magne- 
 sium 
 (Mg). 
 
 23-0 
 22.0 
 20.0 
 33- O 
 24>0 
 3-6 
 
 4-3 
 
 21-0 
 
 19.0 
 16.0 
 
 16.0 
 
 13- o 
 
 16.0 
 
 3-0 
 4-6 
 
 16.0 
 12.0 
 
 3-8 
 
 Sodium 
 and potas- 
 sium 
 
 (Na-f-K). 
 
 Carbonate 
 
 radicle 
 (CO3). 
 
 Bicarbo- 
 nate radicle 
 {HCO3). 
 
 Sulphate 
 radicle 
 (SOO- 
 
 Nitrate 
 radicle 
 CNO3). 
 
 Chlorine 
 (CI). 
 
 ToUl 
 
 dissolved 
 
 solids. 
 
 PRODUCTIVE RIVERS. 
 
 Wabash, Vincennes, Ind 
 
 Illinois, La Salle, lU 
 
 Illinois, Kampsville, 111 
 
 Fox, Ottawa, 111 
 
 Sangamon, Springfield, 111 
 
 Cumberland, Nashville, Tenn... 
 
 Cumberland. Kuttawa, Ky 
 
 Des Moines, Keosauqua, Iowa . . 
 Grand, Grand Rapids, Mich. . . . 
 
 Cedar, Cedar Rapids, Iowa 
 
 Maumee, Toledo, Ohio 
 
 Mississippi, Moline, 111 
 
 Mississippi, Quincy. Ill 
 
 NONPRODUCTIVE RIVERS, 
 
 James, Richmond. Va 
 
 Potomac, Cumberland, Md 
 
 Wateree. Camden, S. C 
 
 Shenandoah, MiUville. W. Va. . . 
 
 Mississippi, Chester. Ill 
 
 Mississippi, Memphis, Tenn 
 
 Red, Shreveport, La 
 
 Missouri, Ruegg, Mo 
 
 Savannah, Augxista. Ga 
 
 Hudson, Hudson, N. Y 
 
 Cape Fear, Wilmington, N. C. . . 
 
 35-0 
 16.0 
 18.0 
 14.0 
 16.0 
 9.6 
 7.8 
 
 17-0 
 10. o 
 12.0 
 
 24>0 
 
 10. o 
 
 6.7 
 
 9-0 
 
 8.4 
 
 6.7 
 
 21.0 
 19.0 
 90.0 
 
 36-0 
 12.0 
 7-9 
 7.2 
 
 8.5 
 
 4.6 
 
 330 
 
 55^o 
 
 303 
 
 50.0 
 
 303 
 
 43.0 
 
 27s 
 
 61.0 
 
 347 
 
 37- 
 
 93 
 
 14.0 
 
 100 
 
 9-7 
 
 3l5 
 
 71. 
 
 314 
 
 33^o 
 
 309 
 
 30.0 
 
 173 
 
 48.0 
 
 IS3 
 
 34.0 
 
 175 
 
 35.0 
 
 60 
 
 7-1 
 
 36 
 
 s8.o 
 
 34 
 
 4.3 
 
 133 
 
 6.3 
 
 174 
 
 56.0 
 
 139 
 
 43^o 
 
 13 s 
 
 140^0 
 
 178 
 
 104^0 
 
 30 
 
 6.0 
 
 73 
 
 l6.o 
 
 25 
 
 3-' 
 
 6.4 
 
 36.0 
 
 6.6 
 
 130 
 
 4^3 
 
 15.0 
 
 4.9 
 
 7-9 
 
 3^4 
 
 7.5 
 
 I. 2 
 
 3. 1 
 
 1.8 
 
 3^o 
 
 33 
 
 4.8 
 
 2^3 
 
 7-7 
 
 31 
 
 3-4 
 
 4-5 
 
 40.0 
 
 1.8 
 
 3^7 
 
 2. 3 
 
 4.4 
 
 •3 
 
 3-3 
 
 •9 
 
 6.4 
 
 .4 
 
 2.S 
 
 3.6 
 
 3^0 
 
 2^7 
 
 9.8 
 
 1-7 
 
 8.6 
 
 •4 
 
 131. 
 
 2.g 
 
 12.0 
 
 .6 
 
 2. 1 
 
 .8 
 
 4.0 
 
 .3 
 
 5-8 
 
 336 
 278 
 267 
 
 33s 
 
 276 
 
 119 
 134 
 
 31-' 
 358 
 238 
 298 
 179 
 
 ao3 
 
 89 
 J30 
 
 73 
 140 
 369 
 303 
 561 
 346 
 
 60 
 108 
 
 57 
 
 o After U. S. Geological Survey. 
 
FRESH- WATER MUSSELS. II7 
 
 DISSOLVED GASES. 
 
 Air is inconspicuous, yet nothing is more important to man. Without it he dies; 
 and his comfort, health, and normal development depend upon the purity of the air 
 by which he is surrounded. This is because of the absolute necessity for oxygen, and 
 the deleterious efifect of too much carbonic-acid gas. The gases dissolved in water 
 are as invisible as air, but the mussels are as dependent upon the free oxygen in solution 
 in the water as man is dependent upon the oxygen of the air. The water of streams 
 and lakes dissolves air at the surface from the atmosphere and derives it from the 
 physiological action of plants in light. Cold water will hold more free oxygen than 
 warm, but the absorption of oxygen at the surface is favored by increased evaporation, 
 with warm dry air and the prevalence of winds (W. E. Adeney, in Report of the Metro- 
 politan Sewerage Commission of New York, 1912, p. 81). Falls, rapids, and swift 
 currents promote the absorption of oxygen, and circulation currents lead to its better 
 distribution into the deeper parts and throughout the whole body of water. Even 
 without the aid of circulation currents, a measure of distribution of oxygen dissolved 
 at the surface is effected by diffusion and "streaming" of the gas within the water 
 (W. E. Adeney, loc. cit., p. 82). 
 
 Carbon dioxide (COj), commonly called carbonic-acid gas, which is given off as a 
 waste product of mussels and other animals, and which is also formed by the decom- 
 position of animal and vegetable matter, is helpful in small quantities, but is poisonous 
 to animals when present in too great quantities (Shelford, 1913, p. 59; 1918, pp. 39, 40; 
 and 1919, p. 106). It is used up by green plants in sunlight and is also given off to the 
 atmosphere at the surface of the water. The same conditions that are favorable to the 
 absorption of oxygen are also favorable to the loss of COj. 
 
 Carbon dioxide is of especial significance sometimes because of its tendency to 
 unite with calcium carbonate to form the bicarbonate, which is soluble in water. Since 
 the shell of a fresh-water mussel is composed principally of calcium carbonate it is liable 
 to be attacked by free carbon dioxide in the water and taken up into solution. The 
 horny covering of the shell is a protection against the action of the gas, but if that 
 becomes broken or worn off in spots, as frequently occurs, the shell is exposed to the 
 destructive effect of the acid. This leads to little harm in hard waters where the CO, 
 may unite with the calcium carbonate derived from rocks or soils, but in soft waters, or 
 in any waters where there is an excess of gas over dissolved calcium, the shells are 
 partially or completely destroyed by corrosion. On many rivers "baldhead" shells 
 are commonly encountered, and sometimes the shells are full of pits or even eaten clean 
 through in the older parts. 
 
 Nitrogen, though an important element in the composition of mussels, can not be 
 used by them in the form of a gas, and its presence in water (unless in excess) is pre- 
 sumably a matter of indifference to them, just as the nitrogen which composes the 
 bulk of the atmosphere is uninjurious to men and not directly utilized by them (Shelford, 
 1918, p. 36). Other gases found in water are ammonia, methane (CH^) and other 
 hydrocarbons, and hydrogen sulphide (HjS), ^vhich are formed in certain processes 
 of decomposition (Needham and Lloyd, 1916, p. 47). These are of importance only 
 when occurring in sufficient quantity to be injurious. 
 
Il8 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 Mussels and olher animals grow more plentifully in regions of water where, with 
 
 other conditions favorable, there is a proper gas content — abundant free oxygen and 
 
 limited amounts of carbon dioxide. Such places are near zones of wave action in 
 
 lakes and in rapids in streams, where the influence of green plants is felt, and where water 
 
 circulation is good. 
 
 VEGETATION. 
 
 In many lakes and streams in protected locations rooted plants occur in more or 
 less abundance. If this vegetation is of open character, not producing a heavy shade, it 
 frequently harbors an extensive mussel fauna (Baker, 1916, pp. 94 and 95). This kind 
 of habitat is especially favorable to many fishes," and to this fact in part may be attrib- 
 uted the presence of mussels, since the young mussels upon leaving the fish, having 
 small power of locomotion, will remain where they fall if the habitat is at all suitable. 
 Since mussels are found in abundance where there is no vegetation, as in rivers like the 
 Mississippi, and generally are conspicuously absent from dense growths, it would seem 
 that the association with rooted plants is largely incidental. There is other direct 
 evidence to indicate that mussels of such habitats are those that are parasites upon 
 species of fish that have a preference for such an environment. 
 
 vShira's observations in Lake Pepin (unpublished manuscript) indicated a certain 
 association of juvenile mussels and vegetation, since 94 per cent of the juvenile mussels 
 taken in a survey conducted in 191 4 were taken in situations where more or less vegeta- 
 tion was encountered. On the other hand, he found juveniles at as many stations 
 without vegetation as with it. As the result of many observations he concluded that a 
 dense growth of vegetation was distinctly unfavorable to the survival of young mussels, 
 and«he suggests that the association of juvenile mussels with vegetation may be partly 
 due to the fact that environments marked by the presence of aquatic plants are attractive 
 to fish. He also observed that a given area of bottom supportive of mussels might 
 display a heavy growth of aquatic plants one year but be practically or entirely free 
 of them in another year. The same author has observed relatively dense growths of 
 vegetation on mussel beds in Lake Pokegama. 
 
 It has frequently been observed in lakes that mussels live abundantly in patches of 
 Chara, a low-growing green plant usually containing a considerable proportion of 
 calcium carbonate. In the Grand River, Mich., Coker noted that mussel collecting was 
 invariably poor in the midst of abundant rooted plants. The principal species found 
 in such localities were the floaters {Anodonta grandis), the fat mucket (LMmpsilis luteola), 
 and the pink heel-splitter {Lampsilis alata). The mucket (Lampsilis ligamentina) , and 
 other species were likely to be found in the vicinity of rooted aquatic plants. 
 
 As quoted on page no, above, Wilson and Danglade (1914, p. 15) described the 
 finding of mussels beneath layers of algae and weeds in Minnesota streams. 
 
 It must be remarked that rooted plants are not the only ones that contribute to the 
 oxygen supply and to the depletion of the carbon dioxide of the water. There are 
 thread algse and innumerable microscopic floating plants which play an important if 
 not the most important part in oxygenation of the water, and these are widely dis- 
 tributed in all zones to which sunlight penetrates. 
 
 o "Little fishes and the greater number of mature fishes keep more or less closely to the shelter of shores and vegetation" 
 (Needham and Lloyd, 1916, p. 23). 
 
FRESH-WATER MUSSELS. 1 19 
 
 ANIMAL ASSOCIATES. 
 
 In the previous discussion of the Naiades in relation to the physical environment, 
 there has been shown to be an adaptation by certain species to particular physiographic 
 situations, as to pond, lake, river, swift or quiet water, hard or soft bottom, etc. In 
 any habitat each mussel is in association with other mussels of the same or other species 
 and with animals and plants of various classes, all more or less adapted to the same 
 environment. Such an association of organisms forms a community, the members of 
 which interact more or less upon one another and upon their environment. The con- 
 sideration of these communities with reference to th^ir members and to the environment 
 often reveals important relations. Because of the mutual relations existing, a dis- 
 turbance or destruction of any one element, by affecting a balanced condition, may 
 cause a marked disturbance of the whole community. (See Shelford, 191 3, p. 17.) 
 Some of the relations between mussels and their associates may be described as com- 
 petition, symbiosis and commensalism, parasitism, and preying. A description of a 
 typical habitat with its inhabitants will illustrate the variety of life associated with 
 mussels. For Oneida Lake, N. Y., Baker (1916, p. 94) gives an account of a particular 
 sort of habitat which he designates the bulrush-waterwillow type, where there is not 
 great exposure to waves, where the bottom is more or less covered with stones and 
 bowlders, but with sandy spots here and there, where the depth varies from i to 4 
 feet, and where the vegetation consists of bulmshes, waterwillows, and pickerelweed. 
 
 The principal differences between this habitat and the bowlder type are the less exposed situation, 
 the density of the vegetation, the deeper water, and the sandier bottom. Such a habitat is particularly 
 favorable for black bass, sunfish, rock bass, and others, because of the hiding and breeding places 
 provided by the thick vegetation, the attachment for eggs by the roots and stems of plants, and the 
 excellent feeding ground, by the abundance of animal life, insect, crustacean, and molluscan. The 
 largest number of molluscan species, 39, occur in this type of habitat, including upwards of 15 which 
 are known to be eaten by bottom-feeding fish. [The following numbers of species are listed; Mussels, 
 ir, including several species of Anodonta and Lampsilis; univalves, 16; crustaceans, i (crayfish); 
 Sphaeriids, 10; leeches, 5; insects, 4.] 
 
 A typical association of mussels and other species in Andalusia Chute, Mississippi 
 River, near Fairport, Iowa, is as follows (Howard, unpublished notes) : 
 
 Bottom — gravel , rock , and sand . 
 
 Water — depth -5':^ to 7,'^ feet. Current at surface estimated 2 miles. 
 
 Haul — 250 feet in length, with crowfoot drag 10 feet wide and with dredge 18 inches wide. 
 
 Distance from edge of water — 20 feet. 
 
 Mussels — Lampsilis gracilis, 3; Plagiola elegans, i; P. donaciformis , 3; Quadrula ebenus, i; Q. 
 metanevra, 3; Q. pustulosa, i; Q. undata, 2; Strophiius edentulus, i; and Unio gibbosus, 3. Total, 18. 
 
 Bivalve — Musculium transversum Say, i. 
 
 Bryozoa — Plumaiella polymorpha Kraepelin, i colony. 
 
 Snail — Vivipara subpurpurea Say, 36; Plcurocera elevattim, Say i. 
 
 Flatworm — Planarian . 
 
 Leech — Placobdella parasitica Say. 
 
 Insects— Stonefly, Perla sp. (larvae); mayfly, Chirotenetes, i (larva); Heptagenia, 14 (larvse); 
 Polymitarcys, 2; dragonfl)', Gomphus externus, 5, Argia, 3 (larva), Neurocordulia, i; caddisfly. Hydro- 
 psyche, 70 (larvae); beetle, Pamids, 2 (adult). 
 
 Crustacea — Crayfish, Cambams. 
 
 In communities of animals and plants, as the individuals increase in numbers there 
 may develop the keen competition for food which has been designated as the struggle 
 
I20 BULLETIN OF THE BUREAU OK FISHERIES. 
 
 for existence of the animate world. Since mussels feed upon suspended matter, living 
 or dead, which they filter from the water, and since water once filtered must be less 
 richly supplied with food for other mussels, an actual competition for food undoubtedly 
 exists. Clark and Wilson (191 2, pp. 19-20) give an account of a measured area of i 
 square meter (10.76 square feet) in which they counted 81 mussels and 57 other mollusks, 
 making a total of 138 individuals, or about 13 per square foot; and there were present, 
 of course, many other animals, some of which took the same kind of food as the mussels. 
 This recorded determination of numbers per given area illustrates the possibilities of 
 competition. As'indicated on pages 91 and 93, above, a detrimental competition for 
 organic food probably does not occur ordinarily with mussels. 
 
 Symbiosis and commensalism exist in such communities. A few supposed instances 
 affecting mussels are afforded by small forms that live within the shells in the mantle 
 cavity of the mussel where they receive food and protection. A small bristle worm, 
 Chcetogaster limruEi, frequently observed in the mantle cavity of mussels, is supposed 
 by some to be merely a commensal, but it may be considered a predacious species since 
 it has been seen with juvenile mussels within its digestive tract (Howard, paper read at 
 meeting of American Fisheries Society, 1918). The leech, Placobdella montijem, enters 
 living mussels, but is not known to feed upon them (Moore, 1912, p. 89). 
 
 Bryozoa and other sessile forms are found attached to the exposed portions of 
 live-mussel shells. Doubtless there are many cases of commensalism to be revealed 
 by closer study of mussels in their natural habitat. 
 
 An interesting symbiotic relation exists between a mussel and the bitterling, a 
 small European fish, which lays eggs in the mantle cavity of a fresh-water mussel which 
 in turn infects the fish with glochidia (Olt, 1893). A different relation, which shows 
 some reciprocity, however, is that of the fresh-water drum {Aplodinotus grunniens) 
 of the Mississippi Basin, that eats fresh-water mussels but pays for the privilege, 
 in part at least, by nourishing the young of several species parasitically encysted 
 on its gills. (Surber, 1913, p. 105, and Howard, 1914, pp. 37 and 40.) The same is 
 true of other fish that eat mussels, as the catfishes. 
 
 Parasitism is a phenomenon of community relations, and it is of double significance 
 in the case of mussels, because not only have the mussels parasites to prey upon them, 
 but they with few exceptions depend for existence upon the opportunity to become 
 parasites of fish or, in one case, of an amphibian. A rather close relationship of fish 
 to the mussel community is essential, and there may be a particular interrelation of 
 given species of fish and of mussels. Questions arise as to when and how this special 
 and intimate relationship came about and to what extent the habits of host and 
 mussel interlock in such cases as the gar pikes and the sand-shells (Hovt^ard, 1914a), 
 the river herring and the niggerhead, the shovel-nose sturgeon and the hickory-nut, 
 the catfiches and the warty-back, the mud puppy and the little salamander mussel. 
 In the last-named case, the peculiar habit of the mussel which lives beneath flat stones 
 conforms evidently to the habits of the host, for the mud puppy is well known to 
 frequent such situations. 
 
 One feature of certain mussels that possibly serves to decoy fish is the elaborate 
 development of the mantle flap in gravid females of the pocketbook mussel, Lampsilis 
 ventricosa, and others. (See p. 85.) These flaps in their form and coloration, includ- 
 ing an eyespot, resemble a small fish, and the motion of these in the current still further 
 
FRESH- WATER MUSSELS. 121 
 
 enhances the resemblance. The enlarged marsupia distended with glochidia lie close 
 to these flaps, one on each side. It has been suggested that a fish darting at this 
 tempting bait may cause the extrusion of the glochidia and then become infected. 
 (See Wilson and Clark, 1912, pp. 13, 14.) The unwelcome members in the associations 
 to which mussels belong are discussed in the following section on "Parasites and 
 Enemies." 
 
 PARASITES AND ENEMIES. 
 
 PARASITES. 
 
 Long green algae are occasionally found attached to the exposed tips of the shells 
 of mussels, and these may cause some erosion of the shells. Marly concretions, com- 
 posed of intermingled low algae and lime often form knoblike lumps on shells in lakes. 
 
 Among the most common of mussel parasites are water mites which dwell in the 
 gill cavity and lay their eggs within the flesh of the mussel, in the inner surface of the 
 mantle, in the foot, or in the gills. These water mites, which belong to the genus Atax, 
 vary in size and color and to some extent in shape (Wolcott, 1899). One is black with 
 a white Y-like marking on its back; others may be reddish. The largest and most 
 degenerate is of a honey color with white treelike markings, but because of its incon- 
 spicuous coloration it is often overlooked. The different sjjecies of Ata.x are hard to 
 distinguish without special preparation and study. Under magnification these water 
 mites look somewhat like spiders. Small pearls are sometimes formed about Atax eggs. 
 
 Leeches are occasionally seen on the inner surface of the mantle of some mussels, 
 especially in Anodontas (floaters) in ponds. They probably feed on the mucus of the 
 mussel. 
 
 A small organism closely resembling a minute leech in general shape and appear- 
 ance is occasional in the axils of the gills of mussels in some lakes. This is Cotylaspis 
 insignis, one of the trematodes or flukes (Leidy, 1904, p. no). One mussel may 
 harbor a dozen or more of these parasites. Rather similar to Cotylaspis insignis but 
 considerably larger and pink instead of yellowish, is the trematode Aspidogaster con- 
 chicola. It is more complex than Cotylaspis insignis and is usually found in the peri- 
 cardial cavity of the host mussels, although in severe infection it may overflow into 
 other organs. 
 
 Distomids, both free and encysted, are found in mussels. The distomid occurs 
 in almost any muscular part of the body but most frequently in the foot or along the 
 edges of the mantle. Sometimes pearls are fonned around distomid cysts. The free 
 distomids are usually found on the mantle surface next to the shell; they are chiefly 
 confined to the flesh along the hinge line but may extend lower down. They are often 
 associated with small irregular pearls. Sporocysts of distomids are common, especially 
 in some Quadrulas. Many distomid parasites of mussels appear to be harmless, but 
 one, Bucephalus polymorphus, destroys their reproductive organs (Kelly, 1899, p. 407; 
 Wilson and Clark, 1912, pp. 69, 70; Lefevre and Curtis, 1912, p. 121). An ascarid 
 worm is occasionally found in the intestine of mussels. 
 
 A worm with peculiar hooks on its head was found encysted in the margin of the 
 mantle of some mussels in a pond near Fairport, Iowa. It was probably a trematode 
 but has been found only once and never identified. 
 
122 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 An oligochaete worm, Chcetogaster limtUBt, is occasionally found in mussels. It is 
 possibly a parasite of snails from which it now and then migrates to mussels. We have 
 some reason to believe that it devours the other mussel parasites. The crystalline 
 style, a long translucent gelatinous body which is formed by the mussel within its in- 
 testine, is often mistaken by clammers for a womi. 
 
 Certain protozoa, Conchopthirus curtus and Canchopthirui anodonUz, somewhat 
 resembling in general appearance the slipper animalcule, Paramoecium, are occasionally 
 met in the mucus of mussels. Attached protozoa, like \^orticella, are also occasionally 
 found on the edge of the mantle. 
 
 Occasionally larval Atax migrate into the space between the mantle and shell 
 and are covered by nacre, where they may form minute white tracks, or in some cases 
 apparently small raised "blisters" or pimples (Clark and Gillette, 191 1). One or 
 perhaps several species of distomid causes a brick-red or purplish discoloration of the 
 nacre, mostly in thin-shelled mussels (Anodonta and Strophitus) (Osbom, 1898; Kelly, 
 1899, p. 406; Wilson and Clark, 191 2, p. 66). The marginal cyst distomid sometimes 
 causes a steel-blue stain of the nacre near the margin (Wilson and Clark, 1912, p. 63). 
 
 ENEMIES. 
 
 Mussels have numerous enemies, among which may be mentioned the mink, the 
 muskrat, the raccoon, water birds, turtles, fishes, hogs, and man. 
 
 Of the depredation of many of these we know little. Water birds probably kill 
 but few mussels, and of fishes, catfish and the sheepshead, or fresh-water drum, are 
 the most noteworthy. These probably feed mainly on the thinner-shelled species. 
 Small mussels {Lampsilis parva) have been found in the intestines of the turtle, Mala- 
 clemmys lesueurii. 
 
 Besides man the muskrat is the most notorious enemy of mussels, and the shell 
 piles left by them are often conspicuous objects along the shores of lakes and rivers. 
 Conchologists sometimes rely upon the muskrat's shell piles to furnish them choice 
 and rare shells. Evermann and Clark (1918, p. 284) found not a few examples of 
 Micromya fabalis in muskrat shell piles on the banks of Lake Maxinkuckee, though 
 collecting in the lake during several seasons failed to reveal a single living specimen. 
 Clammers prospecting new rivers sometimes use the piles of shells left by the muskrat 
 as aids indicating where to dredge for shells. 
 
 Direct observations of the work of muskrats in Lake Maxinkuckee, Ind., were made 
 by Clark and reported in "The Unionidse of Lake Maxinkuckee" (Evermann and Clark, 
 1918, pp. 261, 262), as follows: 
 
 The greatest enemy of the lake mussels is the muskrat, and its depredations are for the most part 
 confined to the mussels near shore. The muskrat does not usually begin its mussel diet until rather 
 late in autumn, when much of the succulent vegetation upon which it feeds has been cut down by 
 the frost. Some autumns, however, they begin much earlier than others; a scarcity of vegetation or 
 an abundance of old muskrats may have much to do with this. The rodent usually chooses for its 
 feeding grounds some object projecting out above the water, such as a pier or the top of a fallen tree. 
 Near or under such objects one occasionally finds large piles of shells. The muskrat apparently has 
 no especial preference for one species of mussel above another but naturally subsists most freely on 
 the most abimdant species. These shell piles are excellent places to search for the rarer shells of the 
 lake. 
 
 In the winter after the lake is frozen, great cracks in the ice extend out from shore in various 
 directions, and this enables the muskrat to extend his depredations some distance from shore in defi- 
 
FRESH- WATER MUSSELS. 123 
 
 nite limited directions. During the winter of 1904 a muskrat was observed feeding on mussels along 
 the broad ice crack that extended from the end of Long Point northeastward across the lake. The 
 muskrat was about 50 feet from the shore. It repeatedly dived from the edge of the ice crack and 
 reappeared with a mussel in its mouth. Upon reaching the surface with its catch it sat down on its 
 haunches on the edge of the crack and, holding the mussel in its front feet, pried the valves apart 
 with its teeth and scooped or licked out the contents of the shell. Some of the larger mussels were 
 too strong for it to open, and a part of these were left lying on the ice. The bottom of the lake near 
 Long Point, and also over by Norris's, is well paved by shells that have been killed by muskrats. 
 Muskrats do not seem to relish the gills of gravid mussels; these parts are occasionally found untouched 
 where the animal had been feeding. 
 
 In spite of all these enemies mussels held their own and throve and flourished 
 imtil the appearance of man upon the scene, when depletion of the mussel beds became 
 noticeable. Man exterminates a good many mussel beds by sewage discharge, by 
 drainage, through which sand is washed do%vn over the beds, by dredging and construc- 
 tion of %ving dams for navigation, by pearling, but, most of all, by exhaustive clamming 
 for the shells. 
 
 CONDITIONS UNFAVORABLE FOR MUSSELS. 
 
 Since mussels are animals of generally sedentary habit, with limited powers of loco- 
 motion, they arc more helpless to escape from unfavorable conditions of environment 
 than are fish or other active creatures of the water. This relative helplessness does not 
 characterize the adult mussel alone, but is even exaggerated for the young stages. 
 From the time the larval mussel attaches itself to a fish until it is liberated it is entirely 
 dependent upon the movements of its host for its future home ; it may be dropped in a suit- 
 able environment or in a place wholly unfavorable to its survival. On the other hand, 
 adult mussels of many species can endure unfavorable conditions for a considerable 
 period of time. This is found to be especially true of several species of Quadrula. 
 
 NATURAL CONDITIONS. 
 
 Some natural conditions unfavorable to mussel life are shifting bottom, turbidity, 
 sedimentation, floods, and droughts. These conditions pertain usually to streams 
 rather than to lakes. They have received some consideration in various paragraphs 
 of this section on "Habitat"; therefore it is only necessary to summarize them in 
 this connection. 
 
 The paucity of mussels in the Missouri River, as well as in the greater part of the 
 Red River and other streams of the plains, is no doubt due to its exceedingly shifting 
 bottom. Similar conditions apply in lesser degree in the lower stretches of many 
 streams. In fact, all rivers, for some distances above their mouths, are as a rule very 
 deficient in mussels as compared with sections farther up where bottom and other con- 
 ditions are more favorable. Shifting bottoms not only prevent mussels from securing a 
 foothold, but may also entirely destroy established beds. 
 
 Interrelated with shifting bottom are turbidity and sedimentation. All three factors 
 and the extent to which they may be operative are largely dependent upon flood condi- 
 tions. In nearly all large rivers floods commonly plow new channels here and there in 
 the stream bed, cut away banks to a greater or less extent, and build new shoals or 
 change the form and dimensions of old ones. Such changes in navigable streams are 
 9745°— 21 i 
 
124 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 familiar to pilots who find it necessary to ' learn the nver " each season. Many of these 
 changes must be catastrophic to mussels in certain localities. 
 
 Excessive turbidity with consequent increased sedimentation, when of considerable 
 duration, is no doubt seriously unfavorable to the well-being of mussels. It has been 
 stated that mussels do not feed during periods of high turbidity, but no definite data 
 in support of this can be given. That mussels do not "bite" well on the crowfoot 
 hooks during a rising stage of water is a condition recognized by clammers. Whether 
 the fact that the shells are not generally open and the mussels feeding at this time is due 
 to the turbidity, or to other changing conditions incidental to the rising water, can not 
 be stated. If heavy deposits of sediment are unfavorable for adult mussels, they must 
 be more directly harmful to the young during the early stages of independent life, for 
 the tiny juveniles may be smothered by deposits that would have less disastrous effect 
 upon larger mussels. 
 
 The effects of droughts are ordinarily felt but little by the mussels of the larger 
 streams and lakes. The most unfavorable condition arises when, owing to a prolonged 
 dry season, the water is lowered to such an extent that the mussels fall easy prey both 
 to muskrats and to clammers and pearlers seeking them in the shallow water. Crows, 
 too, are known to pluck out and kill Anodontas when the water over them becomes low 
 and clear. 
 
 Inthesmallstreams, lakes, and sloughs, the mussels may be killed by the partial or 
 complete drying up of the water. Certain species of mussels are, of course, more resis- 
 tant to such condition than others. Isley (191 4) states that live specimens of Unto 
 tetralasmus were plowed up in a pond three months after it had become dry. The mus- 
 sels had burrowed down to zones of moisture. 
 
 ARTIFICIAL CONDITIONS. 
 
 Among the conditions imposed by man that may be detrimental to mussel life in 
 our streams may be mentioned the discharge of sewage, industrial wastes, dredging, 
 and the building of wing dams. (See Pis. IX, X, and XI.) 
 
 Disposition of the sev^age and wastes of large cities without harmful contamination 
 of the rivers presents an issue of growing importance. Portions of streams just below 
 important cities are sometimes veritable cesspools, unsuited to both mussel and fish life. 
 The Illinois River for a considerable distance below its origin is greatly influenced by 
 sewage pollution through the Des Plaines River and the drainage canal ; from the head 
 of the stream down to Starved Rock, 42 miles from the source, no mussels are found, 
 and a normal variety and abundance of fishes is not present above Henry, 77 miles from 
 its source (Forbes, 1913, p. 170; Forbes and Richardson, 1919, p. 148). Industrial 
 wastes from pulp and paper mills, tanneries, gas plants, etc., are injurious to fishes, 
 and no doubt harmful to mussels as well. Such unfavorable conditions as arise through 
 the depletion of oxygen supply by the decomposition of sewage are partially or com- 
 pletely corrected by the intervention of rapids or waterfalls. (See Shelford, 191 9, 
 p. Ill, and Baker, 1920.) 
 
 River improvement work, such as dredging and the building of wing dams, creates 
 conditions more or less unfavorable for mussels. Hydrauhc dredging may destroy 
 mussels, either directly by pumping them up, or by shifting the river channel so that 
 
FRESH- WATER MUSSELS. 1 25 
 
 ensuing changes cause new sand bars to form and to bury previously existing beds. 
 Wing dams constructed for improvement of the Mississippi River, built of rock and 
 brush and projecting from the shore to the channel, have far-reaching effects upon the 
 course of the current, upon sedimentation, and upon the formation of sand bars. The 
 area between the dams may fill up with sand, so that eventually willows are growing 
 where a mussel bed once flourished. Such changes have been observed in the Mississippi 
 River near Fairport, Iowa, and at Homer, Minn. 
 
 The effect of the construction of dams directly across the channel of a river, as for 
 water-power development, has been discussed on page 97. 
 
 Greater irregularity of stream flow resulting from the clearing of forests greatly 
 influences the life of mussels. The drying up of ponds inhabited by mussels and the 
 extreme low stages of water which allow clammers to obtain the mussels by wading, form 
 disastrous conditions to which mussel beds are occasionally exposed. Extreme low 
 stages of lakes and streams in summer may lead to mortality of mussels resulting from 
 high temperature of the water and diminished oxygen supply. (See Strode, 1891; 
 Sterki, 1892; Farrar, 1892.) 
 
 GROWTH AND FORMATION OF SHELL. 
 
 MEASUREMENTS OF GROWTH. 
 
 Methods of propagation, estimate of results, and measures for protection all depend 
 in a considerable degree upon knowledge of the rate of growth of mussels. It is impor- 
 tant to know how many years elapse before a mussel may attain a market size, as well 
 as at what age it may be expected to begin breeding. Furthermore, these questions 
 require answers for more than 40 economic species, even if consideration were not given 
 to the more than 500 additional American species of fresh-water mussel. The rate of 
 growth is not, however, easily ascertainable for most species. 
 
 Mussels of any species may be left under observation for a considerable period in 
 tanks or troughs, but experiments indicate that normal growth does not occur under 
 the conditions of life in tanks. Even large ponds do not offer the conditions required 
 by many species. The data to be offered on this subject are derived principally from 
 experiments conducted at the Fairport station. Further data on growth of mussels 
 will be found in Isley's paper (191 4). 
 
 Pocketbooks, Lampsilis ventricosa, reared in one of the ponds at the Fairport 
 station attained a length of 41 to 47 mm. (1.6 to 1.85 inches) in two growing seasons, 
 and about 65 mm. (2.56 inches) by August of the third season. Examples 45 to 47 
 mm. long (1.76 to 1.85 inches), and these evidently in the second year of free life, were 
 measured and planted in the Mississippi River by Lefevre and Curtis in June, 1908, 
 and recovered by the senior author of this paper in November, 1910, at the close of the 
 fourth year of growth (Lefevre and Curtis, 1912, p. 180 ff). They had attained lengths 
 of 81 to 85 mm. (3.18 to 3.35 inches). (See fig. 6, p. 133.) 
 
 It is evident, then, that pocketbook mussels under only ordinarily favorable con- 
 ditions may attain a marketable size by the end of the fourth season of independent 
 life (at 3K years of age from date of infection). The observations reported in the 
 following table (10) show that a nearly equal rate of growth applies to the Lake Pepin 
 mucket, Lampsilis luteola. 
 
126 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 Table io. — Average Length of Six Examples of the Lake Pepin Mucket, Lampsilis luteola, 
 
 Reared in Pond 3D at Fairport, Iowa. 
 
 Time of measurement. 
 
 Length. 
 
 
 
 MillinuteTS. 
 
 43-4 
 68.8 
 77.0 
 80.6 
 84.9 
 
 Inches. 
 
 I. 71 
 2.73 
 3.04 
 3.18 
 3-35 
 
 Close of third growing; season o 
 
 
 
 
 
 1 Tlie records of the original lot for the third year having been lost in the fire, there is substituted a corresponding record for 
 the third year of mussels of another lot recorded in Pond 8D. The mussels in Pond 3D were from a fall infection and those in 
 8D from a spring infection; therefore the former are sUghtly older. 
 
 Another species of pocketbook, Lampsilis (Propiera) capax, had attained a length 
 of 49 mm. (1.93 inches) at the end of the second season, indicating a slightly more 
 rapid growth for this species than for Lampsilis ventricosa. Thinner-shelled species of 
 the genus Lampsilis may grow more rapidly. Thus some examples of the paper-shell 
 Lampsilis (Propiera) Imvissima, known to be not over i6 months of age (in free life), 
 had attained lengths of 78 to 81 mm. (over 3 inches). An example of the paper-shell, 
 Lampsilis (Paraptera) gracilis, grew from 17.6 mm. (0.7 inch) to 107 mm. (4.2 inches) 
 in 2 years 9 months and 18 days, the rate of growth averaging about i}4 inches per 
 year. 
 
 The very thin-shelled mussels of the genus Anodonta grow even more rapidly. 
 Examples of the floater or slop-bucket, Anodonta corpulenia, taken from a pond at the 
 Fairport station 16 months after the ponds were constructed, varied in length from 
 66 to 88 mm. (2.59 to 3.46 inches). Examples of another paper-shell, Anodonta sub- 
 orhiculata, taken at the same time from another pond of the same age, but which may have 
 offered less favorable conditions, were 64 to 67 mm. in length (2.52 to 2.63 inches). 
 
 With regard to heavy-shelled mussels, such as the niggerhead, pimple-back, and 
 blue-point, there is much less satisfactory evidence as to growth. They undoubtedly grow 
 much more slowly than mussels possessing thin shells, yet the rates of growth secured 
 in such experiments as have been conducted can hardly be assumed to be representative 
 of the conditions prevailing in nature. The species are not \vell adapted to life in tanks 
 or ponds, and there are few places where measured specimens can be placed in rivers 
 with any assurance that they will remain undisturbed or may be recovered at a later 
 time. In Lefevre and Curtis's experiments (1912) an example of the hickory-nut, 
 Obovaria ellipsis, that was practically full-grown when first measured, gained 5 mm. (one- 
 fifth of an inch, 0.197) i^ ^ little less than 2K years. In the same period an example 
 of Quadrula solida, somewhat less mature, gained 10 ram. (two-fifths of an inch, 0.394). 
 
 In the following table (11) there are indicated sizes, at the close of the second year, 
 of certain mussels reared accidentally or intentionally in ponds at the Fairport station. 
 The short-term breeders, at least, were a little less than iK years of age. 
 
 Since these are all mussels of river habit, it can not be assumed that the growth 
 attained in ponds is representative of the rate of growth in a natural environment. 
 
FRESH-WATER MUSSELS. 
 
 127 
 
 Table h. — Sizes at Close of Second Year op Certain Mussels Reared in Ponds, 
 
 Station, Iowa. 
 
 Fairport 
 
 Sdentific name. 
 
 Common name. 
 
 lycngth. 
 
 Lampsilis Hgamentina. . . 
 
 Lampsilis anodontoides . 
 
 Obliquaria reflexa , 
 
 Obovaria ellipsis 
 
 Plagiola donaciformis . . . , 
 
 Quadrula plicata , 
 
 Quadrula pustulosa 
 
 Quadrula undata 
 
 Mucket a 
 
 Yellow sand-shell b 
 
 Three-homed warty-back. 
 Hickory-nut 
 
 Blue- point. . . , jiiiU. 
 
 Pimple-back. . .' 
 
 Pig-toe 
 
 Millimeters. 
 
 Inches. 
 
 20.0 
 
 
 
 41 
 16 
 
 
 
 
 z 
 
 II 
 
 20 
 
 4 
 
 
 
 »3 
 
 24 
 15 
 
 S 
 a 
 8 
 
 
 .79 
 .62 
 •63 
 
 •4S 
 -79 
 •S3 
 •69 
 .63 
 
 a Other observations indicate tiiat the mucket grows more rapidly in streams, 
 b The yellow sand-shell was only i year and 3 months of age. 
 
 Some medium-sized examples of several species of Quadrula were placed, after 
 measurement, in a crate which was anchored in the Mississippi River at Fairport, Sep- 
 tember 19, 1910. When the crate was recovered and the mussels remeasured, July 31 of 
 the following year, very little growth was apparent in most of the specimens. The data 
 for measurements of length in the several examples are given in the following table (12) : 
 
 Table 12. — Incrbase in Length of Mussei3 in Cage. 
 
 Scientific name. 
 
 Common name. 
 
 Length, 
 
 Length, 
 
 Sept. 19. 
 
 July 31, 
 
 1910. 
 
 1911. 
 
 Inches. 
 
 Inches. 
 
 1.92 
 
 1.98 
 
 1.74 
 
 ..85 
 
 I. 70 
 
 1.86 
 
 2.80 
 
 3- 02 
 
 ..4. 
 
 I. 74 
 
 Increase in 
 length. 
 
 Quadrula cbenus 
 
 Quadrula pustulosa, . 
 Quadrula metanevra. 
 Quadrula plicata . . . . . 
 Quadrula undata 
 
 Nigger head... 
 Pimple-back. 
 Monkey-face. 
 Blue-point. . . 
 
 Pig-toe 
 
 Inches. 
 
 o. 06 
 
 In another experiment 76 mussels, representing 19 species, principally the thick- 
 shelled forms, were placed in a crate with nine compartments which was anchored in the 
 river about 25 feet from shore. The crate was put out July 31, 191 1, and recovered No- 
 vember 14, 1913, when 36 of the original mussels, representing 13 species, were found to 
 be alive. These mussels generally manifested a higher rate of growth than marked some 
 of the mussels used in the experiment just described, although the increase in size was 
 disappointingly small. The period of time between the dates of measurements was 2 
 years 3 months and 14 days. The mussels were of medium size at the beginning of the 
 experiment, so that the growth to be expected was that which would characterize the 
 period of approaching maturity rather than that of early life. The mussels living at 
 the close of the experiment^ with the maximum and minimum gain in length and the 
 average for the species (when more than two examples were available), are shown in 
 the following table (13) : 
 
 Table 13. — Growth of 36 Mussels in Crate from July 31, 1911, to Nov. 14, 1913. 
 
 Scientific name. 
 
 Quadrula ebenus 
 
 Quadrula pustulosa 
 
 Quadrula pustulata 
 
 Quadrula metanevra. . . . 
 
 Quadrula plicata 
 
 Quadrula undata 
 
 Obovaria ellipsis 
 
 Obliquaria reflexa 
 
 Tritogonia tuberculata. , 
 Lampsilis ligamentina. . 
 
 Lampsilis recta 
 
 Strophitus edentulus. . . , 
 Unio gibbosus 
 
 Common name. 
 
 Niggerhead 
 
 Pimple-back 
 
 ....do 
 
 Monkey-face 
 
 Blue- point 
 
 Pig-toe 
 
 Hickory-nut 
 
 Three-horned warty-back. 
 
 Buckhorn 
 
 Mucket 
 
 Black sand-shell 
 
 Squaw-foot 
 
 Spike ; 
 
 Examples. 
 
 Number. 
 7 
 5 
 
 Increase in length. 
 
 Maximimi. 
 
 Minimum. 
 
 Average. 
 
 Inches. 
 0.64 
 •so 
 
 Inches. 
 
 0.38 
 . 20 
 
 Inches. 
 0.463 
 ■375 
 
 .46 
 
 .20 
 
 
 .80 
 
 •S17 
 
 .72 
 .18 
 
 • 4SS 
 
 .36 
 
 
 
 .84 
 
 .10 
 
 
 1.76 
 
 
 .66 
 
 •S6 
 
 
 •17 
 
 
128 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 It must be borne in mind that the conditions of life for mussels in an inclosed crate, 
 and relatively closely crowded together, are probably not nearly so favorable for growth 
 for the majority of mussels as are those of the natural river bottom, where the mussel 
 has a fair chance to assume its desired position and secures the full benefit of the food- 
 laden current. Doubtless the maximum rate of growth shown in the crate is more 
 nearly normal than the average rate. Our impression is that thick -shelled mussels, such 
 as the niggerheads, pig-toes, and pimple-backs, after they are half grown, increase 
 in size ordinarily at the rate of a quarter of an inch a year or less. If this be true, it 
 would require four years or more for a niggerhead mussel, under ordinarily favorable 
 conditions, to increase from a length of 2 inches to a length of 3 inches. Assuming that 
 the rate of growth is more rapid in early life, it may be inferred that niggerheads or 
 pimple-backs 3 inches in length are 10 or 12 years of age. Additional experiments 
 conducted under proper conditions are clearly wanted. 
 
 A marked contrast in rate of growth is thus afforded by the species of Quadrula (and 
 others having generally' similar character of shell), on the one hand, and those of Lamp- 
 sUis, on the other. This was strikingly shown, in connection with the last experiment 
 described, by two examples of the yellow sand-shell, Lampsilis anodontoides , which were 
 not put into the crate but which must have found their way in by chance v/hen still 
 small enough to pass through the screen wire of yi-mch. mesh. Although the crate was 
 out only a little over two years, these two sand-shells were respectively 3.30 and 4.12 
 inches in length. Being elongate in form, they may have entered the crate when a 
 little more than an inch in length. 
 
 Table 14 embodies the result of measurements of length and counts of rings on 
 yellow sand-shells, Lampsilis anodontoides , from the St. Francis River, at Madison, Ark. 
 
 Table 14. 
 
 -Classification of 40 Yellow Sand-Shells from St. Francis River, Ark., 
 TO Length and Age. 
 
 According 
 
 Length in 
 
 Num- 
 ber 
 each 
 leugth. 
 
 Age as indicated by interruption rings on 
 surface of sheU. 
 
 Length in 
 inches. 
 
 Num- 
 ber 
 each 
 length. 
 
 Age as indicated by interruption rings on 
 surface of shell. 
 
 inches. 
 
 Three 
 
 years. 
 
 V Four 
 years. 
 
 Five 
 
 years. 
 
 Six 
 years. 
 
 Older. 
 
 Three 
 years. 
 
 Four 
 years. 
 
 Five 
 years. 
 
 Six 
 years. 
 
 Older. 
 
 
 I 
 I 
 z 
 2 
 4 
 S 
 
 I 
 
 2 
 
 I 
 
 oi 
 
 
 
 
 4K 
 
 4^ 
 
 aH 
 
 6 
 3 
 9 
 
 S 
 
 
 s 
 i 
 
 2 
 
 I 
 
 
 
 3^.";::::::: 
 
 
 
 
 
 
 3K 
 
 2 
 2 
 6 
 
 
 
 
 S 
 
 t 
 
 I 
 2 
 
 
 3J4 
 
 
 
 
 
 ti/ 
 
 
 
 
 Total... 
 
 
 
 
 
 I 
 
 
 
 40 
 
 4 
 
 22 
 
 8 
 
 3 
 
 
 
 
 
 
 " shell with stunted appearance. 
 
 The observations indicate that mussels of this species in the St. Francis River attain 
 a length of 4 to 4K inches in 4 years, that they may attain a length of 4 inches in 3 years, 
 and that 6 years or more are ordinarily required to attaiin a length of 5 inches. 
 
 In summary, the rate of increase in length of fresh-water mussels varies from i K or 2 
 inches per year for paper-shells (as Lampsilis IcBvissima) to J4 inch (a little more or a little 
 less) per year for the niggerhead and related species, while an intermediate rate of J^^ or i 
 inch per year characterizes the muckets and pocketbooks, and a slightly more rapid rate 
 the sand-shells. In general the rate of growth is so directly proportioned (in inverse 
 
FRESH-WATER MUSSELS. 129 
 
 ratio) to the thickness of shell of the species as strongl}' to suggest that the limiting 
 factor of growlh ordinarily is not organic food, but the mineral content of the water 
 
 (p. 87). 
 
 PRESENCE OF SO-CALLED GROWTH RINGS. 
 
 The ages of animals may not infrequently be determined, at least approximately, by 
 the "rings of growth," on teeth, scales, scutes, or otoliths (ear stones), or other hard parts 
 of the body. A similar criterion of age determination is of course commonly applied to 
 trees. More recently the rings on the scutes of terrapin and those on the scales and 
 otoliths of fish have been used for the same purpose. 
 
 This method of determining age is generally based upon the belief that the cessation 
 or the slowing down of growth during the winter season may cause the formation of a 
 distinguishable line or band on a concentrically growing structure. By counting the 
 number of winter lines or bands the number of winters through which the animal has 
 passed is ascertained, or by counting the number of zones between such rings, beginning 
 with the center zone, the number of seasons of growth is discovered. It is one thing to 
 know that such rings are formed in winter, but quite another thing to learn just how or 
 why the rings are formed. It is also of primary importance to determine whether or not 
 similar rings may be formed upon any other occasion than the occurrence of a season of 
 winter. In the case of the fresh-water mussel shell, at least, these questions can be 
 answered by observations and experiments. (Coker, unpublished notes.) 
 
 Some years ago when collecting mussels in lakes in southern Michigan it was ob- 
 served that the shells of the fat muckets were all marked with several conspicuous rings 
 which were approximately equally spaced on all the mussels of a bed. It seemed a 
 natural inference that these dark rings represented winter periods and thus afforded a 
 means of age determination. At another time, upon examination of mussels which 
 had been measured and placed in crates in the river two years previously, it wasobsei^ved 
 that there were rings apparently corresponding to the two winters which had elapsed 
 since the date of original measurement, but that there was also another ring which 
 marked the exact size of the mussel when originally measured. (See text fig. 6.) 
 Subsequent observations showed that whenever a mussel was measured and replaced in 
 the water, a ring would be formed on the shell before growth in size was resumed. 
 
 These obser^^ations led to an effort by microscopic examination of sections of the 
 shell to determine the significance of rings which apparently could be formed either by a 
 season of cold weather or by the pi ocedure of taking a mussel from the water, applying a 
 caliper rule, and returning it to the water. To make clear what was learned from the 
 study of the sections it is necessary first to explain briefly the mode of formation of shell 
 which leads to gro\\i;h in size. 
 
 MODE OF FORMATION OF SHELL. 
 
 The shell is composed of four distinct layers (text figs. 1,2, and 3). The outer is the 
 homy covering called the periostracum." Immediately beneath this is a calcareous 
 layer composed of prisms of calcium carbonate set vertically to the surface. This pris- 
 matic layer is very thin, though thicker than the periostracum, and is likely to remain 
 
 •* The fact that the periostracum itself comprises 3 layers of separate origin, while very siguificailt in some respects, is imma- 
 terial in this comiectiou. 
 
130 
 
 BUI^LETIN OK THE BUREAU OK FISHERIES. 
 
 Fio. I. — ^Biagraimnatic and highly magnified camera lucida drawing of section of 
 margin of fresh-water mussel shell, Obovaria ellipsis (Lea), showing arrangement of 
 layers: A^ epidermis (double layer); B, prismatic layer; and C, nacreous layer. 
 Note the folds of epidermis which give the shell its "silky" appearance. 
 
 attaxihed to the periostracuni when that is peeled off. Beneath the prismatic layer and 
 composing nearly the entire body of the shell is the nacreous or mother-of-pearl layer, 
 
 w hich is made upof almost 
 innumerable thin laminae 
 lying one upon the other 
 and parallel to the inner 
 surface of the shell. 
 Through the nacre, inter- 
 secting its laminae, passes a 
 very thin fourth layer, the 
 hypostracum," secreted 
 by the muscles (p. 172). 
 
 Growth of shell in 
 thickness is accomplish- 
 ed by the laying down of 
 successive laminae, from 
 the entire surface of the 
 mantle. Layer after layer is added to the inner surface of the shell, each layer exceed- 
 ingly thin and generally a little larger than the preceding. Ring after ring is added 
 to the margin of the shell, but since growth is most 
 pronounced in the posterior (rear) direction, less 
 so in a ventral, and still less in the anterior 
 (forward) direction the rings must be widest be- 
 hind and narrowest in front. It will be noted 
 that any mussel shell is marked with innumerable 
 concentric lines. Superficially such lines suggest 
 the annual rings seen on the section of the trunk 
 of a tree, but the resemblance is entirely mislead- 
 ing. The shell is added to in layers, but a very 
 great number of layers are made in a year. 
 Pfund (191 7) has, by refined physical methods, 
 measured the thickness of the layers or laminae 
 and determined that the thickness in the examples 
 he studied lies between 0.4 /i and 0.6 /i. Transla- 
 ting these terms into ordinary language, there are 
 some 50,000 layers to an inch of thickness. A shell 
 one-quarter of an inch thick would have 1 2,500 lam- 
 inae; and if such a shell were 8 years old, more than 
 1,500 laminae would have been formed each year, 
 on the average. The outcropping edges of these 
 laminae on the surface of a polished niggerhead shell 
 have also been measured and found to be spaced at 
 the rate of about 9,000 to the inch. Such lines are of course not visible to the naked eye, 
 and therefore the fine rings in evidence on the surface of the shell can not represent these 
 
 Fig. 2. — Section through double-layered pert- 
 ostracum and prismatic layer. Nacreous layer 
 below not shown. 
 
 a Not shown in figures herewith. 
 
FRESH-WATER MUSSELS. 131 
 
 laminae but must have some other significance. They probably mean nothing more 
 than slight and frequent but irregular retractions of the margin of the mantle during 
 the process of shell formation, which have registered themselves in fine wrinkles on 
 the surface of the shell as it is built. The more conspicuous rings that mark some 
 shells still await our attention. 
 
 Fig. 3. — Sections through prismatic layer of Quadrula ehenus. The sections were made at different levels, the prisms being smaller 
 
 and more numerous in the outer portion. X 300. 
 
 Growth of the shell in length and breadth is accomphshed by the secretion of shell 
 substance of the three layers by cells at or near the margin of the mantle. There are 
 certain cells of a furrow in the margin of the mantle which form only periostracum, 
 and there is a certain portion of the mantle near the margin which forms only prismatic 
 shell substance, while the greater portion of the mantle surface normally forms only 
 nacre. Now, the important point for our present consideration is this: If, from any 
 cause, the margin of the mantle is made to withdraw within the shell to such an extent 
 as to break its continuity with the thin and flexible margin of the shell, then, as the 
 study of sections indicates, when the deposition of shell is resumed, the new layers 
 
 Fig. 4. — Section through the interruption ring on pocketbook mussel, caused by handling mussel 
 in summer. Simple duplication. 
 
 of prismatic substance and periostracum are not continuous with the old, end to end, 
 but are more or less overlapped by the old. In other words, growth does not begin 
 again exactly where it left off, but a little distance back therefrom, and the cause of this 
 is largely mechanical (text fig. 4). The amount of overlapping probably depends 
 upon the degree of disturbance and the extent to which the mantle has withdrawn 
 itself. The result is an unwonted duplication of layers. Counting inward from the 
 
132 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 outer surface we find not simply one series of periostracum, prismatic, and nacreous 
 layers, but periostracum and prismatic layers, then periostracum and prismatic again, 
 and finally the nacreous layer; the outer layers arc doubled up. 
 
 SIGNIFICANCE OF RINGS. 
 
 In a case such as has just been described, where the outer layers are doubled up 
 as a result of an extreme retraction of the mantle, the effect of seeing a second horny 
 layer through the outer periostracum and the fairly translucent prismatic layer gives 
 the appearance of a dark band on the shell. This is the so-called growth ring, which 
 would be better termed duplication ring or interruption ring," since its significance is 
 simply that the continuity of the outer layers is interrupted and the break is repaired 
 by overlapping. In other words, the periostracum and prismatic layers are "spliced" 
 at this point. A duplication of layers should easily be observable on shells having 
 fairly Hght-colored or translucent periostracum but not on shells having a very dark 
 or opaque covering, and this is found to be the case. Growth rings or interruption 
 rings are commonly seen on pocketbooks, fat muckets, yellow sand-shells, floaters, and 
 other shells of light or only medium dark colors, while they are distinguishable with diffi- 
 culty, if at all, on niggerheads, 
 pimple-backs, blue-points, and 
 other dark-colored shells. 
 
 If the winter rings are 
 formed in the same way, and 
 the breaking of the continuity 
 of the outer layers is due to 
 the withdrawal of the mantle 
 in cold weather, then it would 
 be expected that several duplications would occur for a single winter. For cold 
 weather does not ordinarily fall with one blow. Periods of cold and warm weather 
 alternate for a time before winter sets fairly in, and again in the spring periods of low 
 and high temperature alternate before winter is entirely passed. Such fluctuations 
 of temperature are, of course, not so frequent or noticeable in the water as in the air, 
 but they do occur. It might be expected that the mussel would react to the first sharp 
 touch of winter by closure and a sharp withdrawal of the mantle but that the deposition 
 of shell would be resumed after a time, while further interruptions and resumptions 
 of growth would occur before the full effect of winter was experienced. Again in the 
 spring there might be alternate interruptions and resumptions of growth. This, at 
 least, is the story which seems to be told by a section through a winter ring when 
 examined under the microscope. Text figure 5 shows such a section, where the alterna- 
 tion of periostracum and prismatic layers is repeated seven times, indicating six inter- 
 ruptions of growth. As virtually no increase in size occurs between the several inter- 
 ruptions, the duplicated or repeated layers are simply piled upon one another. 
 
 Interruption rings corresponding to seasons of winter differ from those corresponding 
 to a single severe disturbance of the mussel during the normal period of growth in that 
 the latter are rings of single duplication (text fig. 4), while the former show several repe- 
 titions (text fig. 5). The winter rings in shells that have been observed are, therefore, 
 darker, though they may or may not be broader (text fig. 6). 
 
 o See Isely. 19x4, p. 18. 
 
 Fig. s. — Section through interruption ring (winter ring) on shell of pocket- 
 book, Lampsilis ventricosa, showing repeated duplications of periostracum 
 and prismatic layers. 
 
FRESH-WATER MUSSELS. 
 
 133 
 
 ABNORMALITIES IN GROWTH OF SHELL. 
 
 Seriously malformed mussels are not infrequently found, and peculiar interest 
 attaches to these because shellers generally entertain the belief that a mussel with de- 
 formed shell is most likely to contain a pearl. It seems possible that this belief is not 
 without some foundation. Pearls probably occur more frequently in parasitized mus- 
 sels, and many of the observed malformations are undoubtedly due to parasites. 
 
 A few distomids upon the mantle of Anodontas along or near the dorsal fold evidently 
 cause rusty stains in the nacre, abnonnal growths on the inner surface of the shell, de- 
 formities of the hinge teeth, and dark or poorly formed pearls. Another parasite which 
 infests the reproductive or- 
 gans may almost completely 
 destroy the gonads of the fe- 
 male mussel, and in such case 
 the female may develop a 
 shell in the form of a male or 
 in a form intermediate be- 
 tween that of the male and 
 the female. There is evi- 
 dence that parasites found 
 encysted in the margin of the 
 mantle may give rise to stains 
 on the nacre at the margin of 
 the shell, that others cause 
 the not unfamiliar steely or 
 leaden-colored margins of 
 shells, while some produce a 
 pitting of the inner surface 
 of the shell. 
 
 One of the most common 
 and serious defects of other- 
 wise valuable commercial 
 shells is the presence of yel- 
 low and brown spots or bluish or greenish splotches in the nacre. Regardless of the 
 texture of the shell, the partially or wholly discolored buttons must be given a very low 
 grade. The spots are not always found upon the surface but may lie deep within the 
 nacre, to be brought out in the finished button by the processes of shaping and polishing. 
 Spotted shells are most common in certain rivers or parts of rivers, particularly where 
 the current is sluggish as in partly inclosed sloughs. Some of these discolorations are 
 often observed to be associated with a parasitized condition of the mussels, but it is 
 not probable that the spots are always due to parasites. The U. S. Bureau of Stand- 
 ards, in connection with an investigation of the bleaching of discolored shells, has found 
 that the dark-yellow and brown spots are mud fixed by the nitrogenous organic layer 
 which binds together the calcium carbonate, and that the pale-yellow color is apparently 
 due to an organic coloring matter in the organic layers. That bureau also reports that 
 the color of the pink shells is due to an organic coloring which is not confined to the 
 organic layer but permeates the whole shell. 
 
 Fig. 6. 
 
 A shell of the pocketbook, Lampsilis ventricosa, which was recovered after 
 having been measured and confined in a wire cage in the Mississippi River for 
 two years, four and a half months. The line a, an interruption ring, marks the 
 size at the time of measuring. The lines b and c evidently correspond to the two 
 periods of winter intervening. The inconspicuous sign of a winter interruption 
 prccci'.ing the date of measurement does not appear in the drawing. Natural 
 size. (After Lefevre and Curtis.) 
 
134 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 A Striking fonn of shell associated with the presence of parasites is that with abbre- 
 viated gaping anterior margins, the edges being much thickened and in appearance 
 rolled outward. The explanation appears to be simply that the parasites check the 
 peripheral growth of the forward portion of the mantle, or perhaps, as the result of irri- 
 tation, keep the mantle more or less retracted in this portion. The shell being controlled 
 in growth by that of the mantle, its forward extension is checked, while growth in thick- 
 ness continues. Meantime the valves of the shell, growing normally in other directions, 
 are gradually and naturally pushed apart as successive layers are added in the posterior 
 portions. In consequence, after a time the valves of the shell cease to meet anteriorly 
 when the posterior margins are apposed. The result is a shell of normal dimensions 
 behind and below but abbreviated in front, where the edges are disproportionately thick 
 and gaping. 
 
 A very familiar form of abnormality is shown by the shells in Plate XII. When a 
 single shell of this type is first seen one is inclined to suppose that the deformity is the 
 result of a mechanical injury; but when shells marked by almost identically the same 
 abnormality are repeatedly found in various places and in different kinds of bottom, it 
 becomes evident that the explanation of mechanical injury is not applicable. It is prob- 
 able that a parasite checked the growth of the mantle at a particular point, so that, while 
 growth of shell continued nonnally both before and behind, it was so retarded at that 
 point that a pennanently notched outline resulted. The subject of discolored and mal- 
 formed shells is not introduced, however, with the object of definitely explaining them, 
 but rather with a view to directing attention to the desirability of further investigations of 
 the parasites of mussels, as well as of certain features of the environment of mussels, as 
 regards their effects upon the form and quality of shells. 
 
Bull. U. S. B. F., 1919-20. 
 
 Plate XII. 
 
 ■«J 
 
 1 llustrating a peculiar abnormality of not infrequent occurrence among fresh-water mussels. 
 
Bull. U. S. B. F., 1919-20. 
 
 Plate XI 3 
 
 [See text, pape 139. and compare Plate XXI, fig. 1, 
 showing marsupium occupying outer gills only. 
 Figures after Lefevre and Curtis.] 
 
 -Three-homed warty-back, ObliQuaria refiexa; marsupium 
 occupying middle region of outer gills. 
 
 Fig. 4. — Dromedary mussel, 
 Dromus drotnas; marsupium 
 occupying only lower border 
 of outer gills. Anterior end of 
 gill not included iu niarsu- 
 pium but overhangs it. 
 
 Fig. 5. — Kidney-shell, PtyLhobmtichus pkaseolus; marsupium occupyiug entire lower 
 border of outer gills and much folded. 
 
PART 2. LIFE HISTORY AND PROPAGATION OF FRESH-WATER 
 
 MUSSELS. 
 
 INTRODUCTION. 
 
 The life histories of fresh-water mussels present features in striking contrast to those 
 of other familiar mollusks of our seas and rivers. The American oyster, the clam, the 
 quahaug, and the sea mussel cast the eggs out to undergo development while floating in 
 the water. The pearly mussels of rivers and lakes, on the contrary, deposit their eggs 
 in marsupial pouches which are really modified portions of the gills, and there they are 
 retained until an advanced stage of development is attained. This particular feature of 
 breeding habit is not, however, unique to mussels. There are clams in coastal waters 
 that incubate the eggs in the gills, and the common oyster of Europe displays a similar 
 habit; but with all these the larvae when released are prepared for independent life. 
 Such is not the case with fresh-water mussels. When the larval mussels are discharged 
 from the marsupial pouches, the mother has done all that she can for them, but they 
 still want the services of a nurse or foster parent, as it were. Lacking the structure and 
 appearance of young mussels, they display a peculiar form designated as glochidium, 
 and (with few exceptions) they will not continue to live unless they become attached to 
 some fish, upon which for a certain time they will remain in a condition of parasitism. 
 
 During the period of parasitic life the glochidium undergoes a change of internal 
 reorganization, or metamorphosis, with or without growing in size. After the change 
 is complete and a form somewhat similar to the adult is attained, the young mussel 
 leaves the fish to enter upon its independent existence. At this time, or soon thereafter, 
 some mussels, but not a great number, differ distinctly from the adult form in bearing a 
 long, adhesive, and elastic thread, or byssus, by which they attach to plants, rocks, or 
 other anchorage. 
 
 The life history, then, comprises the following five stages: (i) The fertilized and 
 developing egg retained in the marsupial pouches of the mother mussel; (2) the glochid- 
 ium, which, before liberation, is often retained for a considerable further period in the 
 gills; (3) the stage of parasitism on fish (or water dogs) ; (4) the juvenile stage, which may 
 or may not be marked by the possession of threads for attachment to foreign objects; 
 and (5) the mussel stage, with the usual periods of adolescence and maturity. 
 
 Such in brief is the typical story of the life of a pearly mussel. And yet each 
 species of mussel, and there are many, has its own characteristic story, which differs in 
 more or less important respects from those of other species. One kind of mussel will 
 pass through the stage of parasitism only upon a particular species of fish, while another 
 kind acquires the aid of certain other fish. The diversity in life histories also manifests 
 itself in such details as in the season of spawning, in the part of the gills in which the 
 glochidia are carried, in the duration of the incubation period, in the matter of growth 
 in size during parasitism, and in many other particulars. There are even some mussels 
 which, like exceptions that prove the rule, undergo complete development without being 
 parasites upon fish at any stage. It is advisable, therefore, to treat the several stages 
 
 13s 
 
136 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 of life history at greater length and with such detail as is necessary to establish an 
 understanding of the conditions necessary for the successful propagation of the various 
 useful rnussels and for the effective conservation of the mussel resources. 
 
 HISTORICAL NOTE. 
 
 It seems appropriate to remark that the considerable fund of knowledge which has 
 been gained in very recent years regarding the diversified life histories of fresh-water 
 mussels has been gained very largely as a result of scientific studies which have been 
 stimulated by the practical need of conserving an economic resource, and which have 
 been pursued preliminary to or in connection with the propagation of nmssels as a 
 measure of conservation. To put it in another way, the development of 'the fresh- 
 water pearl-button industry has furnished an effective stimulus to biological studies 
 of high scientific interest and importance, just as the application of science to studies of 
 commercial mussels has rendered a distinct economic service. 
 
 As early as 1695 at least, the glochidium (see text fig. 8, p. 143) was observed in the 
 gills of European mussels, and was understood to be the larval form of the mussel, although 
 it was not then called a glochidium. Of the further stages of life history, science, as well 
 as the public, remained in ignorance for a long time. So wide indeed was the gap of knowl- 
 edge that it became possible for a scientific writer in 1797 to advance the theory that 
 the little mollusks noted in the gill pouches were not young mussels, but were parasites 
 of mussels constituting a genus and species of their own, which the investigator designated 
 with the Latin name Glochidium parasiticum. This view, known as the Glochidium 
 theory, though it never won full acceptance, was strongly supported, and an exhaustive 
 inquiry and report upon the subject by a special committee of the Academy of Sciences 
 in Paris, completed in 1828, failed to effect its decisive defeat. When, however, in 
 1832, Carus was fortunate in observing the passage of the eggs from the ovary of the 
 mussel into the gill pouches, the false theory was definitely overthrown. The name 
 glochidium, suggested though it was by an erroneous assumption, has persisted ever 
 since, being now correctly understood to designate not a distinct animal but a typical 
 stage in the development of the mussels. 
 
 It stni remained to determine how and where this peculiar larva became trans- 
 formed into the familiar adult mussel, and this important gap was abridged by Leydig, 
 in 1866, when the glochidium was discovered in parasitic condition upon the fin of a fish. 
 
 The advance in knowledge of the life history of fresh-water mussels made in the 
 ensuing decades was slow and inconspicuous, and textbooks, both American and foreign, 
 continued to reproduce accounts based upon the inadequate observations of the life 
 histories of European mussels. A period of distinct progress came with the extensive 
 and admirable investigations conducted by Lefevre and Curtis (1910, 1910a, and 1912) 
 in association with the Bureau of Fisheries during the years 1905 to 191 1. These inves- 
 tigations served to reveal not only some of the distinctive features of the breeding 
 habits and life histories of the American mussels as contrasted with the European 
 species but also the great diversity existing among the many American species, in breed- 
 ing season, period of incubation, and form of glochidia. The results of the investiga- 
 tions aggregated a mass of original observation on various phases of the propagation 
 and life history of fresh-water mussels. Other investigations, notably Ortmann's (191 1, 
 1 91 2, etc.), have contributed materially to knowledge of the breeding characters and 
 
FRESH-WATER MUSSELS. I37 
 
 habits and the development of mussels, while Simpson (1899, 1900, 1914, etc.), Walker 
 (1913, 1918, etc.), Ortmann (1911, 1912, 1913, etc.), and others have greatly extended 
 our information regarding classification, distribution, and structure. 
 
 With the establishment of the Fisheries Biological Station at Fairport, Iowa, and 
 the beginning of its scientific work in 1908, the studies pursued by the scientific staff 
 of that station, in connection with the propagation of mussels, made still further advances. 
 Chief among the results of the studies conducted at this station may be mentioned the 
 discovery that particular species of mussels are restricted in parasitism to one or a few 
 species of fish, the rearing of 3'oung mussels in quantity from artificial infections upon 
 fish, the demonstration that the glochidia of certain species of mussels may grow mate- 
 rially in size during the period of life on the fish (being, therefore, true parasites) , and the 
 obser\ration that one noncommercial species of fresh-water mussel normally completes 
 its life history without a stage of parasitic life." 
 
 Finally it should be remarked that one of the most difficult of all gaps to bridge 
 was the rearing of young mussels after they leave the fish. Strange as it may seem, 
 all attempts to keep alive and to rear the young mussels under conditions of control 
 failed of result. Lefevre and Curtis (191 2, pp. 182, 183) recorded the rearing from an 
 artificial infection of a single young mussel which attained a size of 41 by 30 mm. In 
 1914, however, Howard was successful in rearing over 200 Lake Pepin muckets from 
 an artificial infection, when the infected fish were retained in a small floating basket in 
 the Mississippi River (Howard, 1915). These mussels attained a maximum size of 3.2 
 cm. in the first season; and in subsequent years many of them were reared to maturity, 
 the glochidia developed from their eggs were infected upon fish, and a second generation 
 was reared to an advanced stage. In that year (1914), too, Shira, using watch glasses 
 and balanced aquaria, reared a few mussels from an artificial infection to a maximum 
 size of 0.44 cm. in 291 days. In the same year, though from an experiment initiated 
 by the senior author in the fall of 191 3, young mussels were reared in a pond, from an 
 artificial infection of fish liberated in the pond, to a maximum size in the first season of 
 3.5 cm. Some of these mussels at the age of 4 years had attained sizes suitable for 
 commercial use in the manufacture of buttons. The same species, Lampsilis luteola 
 (Lamarck), known as the Lake Pepin mucket, was used in all of these experiments. 
 Subsequent experiments on a larger scale conducted both at Fairport and in Lake 
 Pepin are mentioned on a later page. 
 
 AGE AT WHICH BREEDING BEGINS. 
 
 The age at which mussels begin to breed varies with tlie species. There is reason 
 to believe that the paper-shell, Lampsilis (Proptcra) Icsvissima, breeds in the same sum- 
 mer during which it leaves its host or when just i year of age from the egg. Anodonta 
 imbccillis and Plagiola donacijormis apparently breed in the second summer. The small- 
 est breeding Ouadrula observed was a pig-toe, Quadrula undata, 30 mm. (about 1.2 
 inches) in length, and 4 or 5 years of age as evidenced by the interruption rings. The 
 smallest washboard, Quadrula heros, observed in breeding condition was 91 mm. (3.58 
 
 o Lefevre and Curtis (191 1 ) had previously observed and reported the fully developed iuveuile mussels in the gills of Strophitus 
 edenlidus. Later, Howard (1914) while showing that the glochidia of that species will become parasitic on fish and undergo devel- 
 opment under the usual conditions, discovered that another species, Anodonta imbecUlis. normally develops without the aid of 
 fish. (See p. 156, below.) 
 
138 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 inches) in length and of an estimated age of 8 years. Females of the Lake Pepin mucket, 
 Lampsilis luteola, reared at the U. S. Fisheries Biological Station, Fairport, Iowa, were 
 found with mature glochidia in the third season of growth, a period of slightly more 
 than two years after dropping from the fish. Undoubtedly not all species breed at 
 such an early age, and it perhaps takes the heavier Ouadrulas 6 or 8 years to reach the 
 
 breeding age. 
 
 OVULATION AND FERTILIZATION. 
 
 With a few exceptions," the sexes are separate in American species of fresh-water 
 mussels. The discharge of eggs (ovulation) has been observed in some instances (Latter, 
 1891; Ortmann, 1911, p. 298; and Howard, 1914, p. 35). The eggs pass from the 
 ovaries by way of the oviduct, through the small genital aperture into the cloaca and 
 suprabranchial chambers, and then into the portions of the gills which are to sei-ve as 
 brood pouches. The sperm which has been thrown out into the water by one or more 
 male mussels, doubtless those in the near vicinity of the female, is taken in by the female 
 with the respiratory current, but whether the eggs are fertilized while on the way to 
 the brood pouches or after reaching them is unknown, since the process of fertilization 
 in nature has never been observed. We have no clue either as to the nature of the 
 stimulus which may excite ovulation or as to how it may be timed so as to take place 
 when a supply of living sperm is available in the water for the fertilization of the eggs. 
 Certain it is that the eggs are usually fertilized, although in the brood pouches of any 
 gravid mussel that may be examined there are found a good many eggs that have failed 
 to develop, presumably because they have escaped fertilization. 
 
 The discharge of sperm in great quantities may not infrequently be observed when 
 male mussels are retained in aquaria. The writers have obser\^ed in a large tank at the 
 Fairport station a male mussel discharging sperm. During the process it traveled exten- 
 sively over the bottom, leaving in the sand a long winding furrow which was filled with 
 a white cloud of sperm. Perhaps the discharge oi sperm and its introduction with the 
 respiratory current into the female constitute the exciting cause of ovulation. Exper- 
 iments are clearly wanted to determine this question. The arrangement of the eggs 
 in the several chambers of the brood pouches varies according to the character of the 
 pouch, and will therefore be more conveniently described in the following section. 
 
 BROOD POUCHES OR MARSUPIA. 
 
 The gills of mussels, as of other lamellibranch moUusks, are thin flaps that hang 
 like curtains from each side of the body, a pair on each side. As explained in another 
 place (p. 175) each gill, thin as it may appear, is really a double structure, or more cor- 
 rectly is a sheet folded upon itself just as a map, larger than the page of a book in which 
 it is bound, is folded on itself. There is this difference; the map may be unfolded at 
 will, but the gill may not, because the two sections are attached together by many par- 
 allel partitions which divide the narrow space between the sheets into a lot of long 
 slender tubes. It is into these tubes that the eggs are deposited, and when filled with 
 eggs or glochidia the several tubes are greatly distended (text fig. 7). The entire gills 
 or the parts of the gills bearing the eggs then appear not as thin sheets but as thick 
 
 " The known exceptions are. occasionally, Quadrula rubiginosa and pyramidata, and Lampsilis parva, and. usually, Anodonta 
 imbedtlisand henryana (Sterki, 1898), and Sympkyncta compressa and Tiiridts (Ortmann, 1911. p. 308). 
 
FRESH-WATER MUSSEI^S 
 
 139 
 
 nc. 
 
 pads. In this condition the marsupial pouches might be compared to pods filled with 
 closely packed beans, the individual beans representing not single eggs but separate 
 masses of eggs. 
 
 When the tubes of a mature female mussel are empty the gills may be as flat as 
 those of the males, or they may appear as sacks with thin translucent walls. The lat- 
 ter condition generally characterizes the long-term breeders, in which the portions of 
 the gill intended to receive the eggs are permanently enlarged. 
 
 The marsupia are conspicuously colored in some species, but in different species 
 the coloration is not necessarily attributable to the same cause. In the niggerhead, 
 Quadrula ebcnus, the pig-toe, Qiiadrula undata, and other species, the bright-red appear- 
 ance of the marsupia is due to the deeply colored eggs showing through the thin walls 
 of the marsupia. In the yellow sand-shell, Lampsilis 
 anodontoidcs , the pocketbook, Lampsilis vcnincosa, 
 and the Lake Pepin muckct, Lampsilis luteola, the 
 pigment lying in the outer walls of the ovisacs takes 
 the form of dark bands on the lower portion of the 
 marsupium, the pigmentation becoming more dense 
 and conspicuous when the mussels are gravid. In the 
 young Lampsilis cllipsijormis that we have seen the 
 pigmentation is more intense and more general, ex- 
 tending even to the upper portion of the marsupia, 
 but there restricted to the partitions separating the 
 ovisacs. The color in the black sand-shell, Lampsilis 
 recta, and the Missouri niggerhead, Ohovaria ellipsis, is 
 white or cream, in contrast to the yellowish color of 
 the remainder of the ovisacs. 
 
 The extent to which the gills are specialized or 
 modified to receive and retain the eggs while they are 
 developing into the glochidia has been largely utilized 
 in the classification of mussels. All of the North 
 American species belong to the groups in which the 
 
 brood pouch or marsupium comprises either all four gills or only the outer gills. 
 This group, in turn, is divided into the following seven divisions, according to the spe- 
 cializations involved (Simpson, 1900, p. 514): 
 
 1. Marsupium occupying all four gills, as in the niggerhead mussel, Quadrula ebenus, and perhaps 
 all Quadrulas (PI. XIII, fig. i). 
 
 2. Marsupium occupying the entire outer gills, as in tlie heel-splitter, Symphynota complanala (PI. 
 XXI, fig. i). 
 
 3. Marsupium occupying the entire outer gills, but differing from the second in that the egg masses 
 lie transversely in the gills, as in the squaw-foot, Sirophitus edentulus. 
 
 4. Marsupium occupying only the posterior end of the outer gills, as in the black sand-shell, Lamp- 
 silis recta, etc. (PI. XIII, fig. 2). 
 
 5. Marsupium occupying a specialized portion in the middle region of the outer gills, as in the 
 three-homed warty-back, Obliquaria reflexa (PI. XIII, fig. 3). 
 
 6. Marsupium occupying the entire lower border of the outer gills in the form of peculiar folds, as 
 in the kidney-shell, Ptychohranchus phaseolus (PI. XIII, fig. 5). 
 
 7. Marsupium occupying the lower border only of the outer gills, Ijut not folded, as in the drome- 
 dary mussel. Dromus dramas (PI. XIII, fig. 4). 
 
 Most of the commercial species belong to the first and fotirth types. 
 9745°— 21 5 
 
 r.c. 
 
 Fig 
 
 Horizontal section of a water tube of a 
 
 gravid marsupium, showing respiratory canals 
 (a. I.), and marsupial space (m. s.), containing 
 glochidia. (After I.,efevre and Curtis.) 
 
140 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 With such species as have all four gills, or the entire outer gills serving as marsupia, 
 the sexes are scarcely, if at all, distinguishable from an examination of the shell; but 
 when a distinct portion of the outer gill is used as a brood pouch there is usually a pro- 
 nounced inflation of the shell over the region of the marsupia, so that the female mussel 
 is clearly marked on the exterior. (See also Grier, 1920.) 
 
 It is to be remarked that the eggs packed into the water tubes or marsupial cham- 
 bers do not usually remain free of each other, but become either attached together by 
 their adhesive membranes or else embedded in a common mucilaginous substance. When 
 the eggs or glochidia are removed from the gills they do not separate from one another 
 unless fully ripe, but remain in large masses which conform to the shape of the tubes 
 from which they have been removed ° (PI. XIV, figs. 8-1 1). It occurs frequently 
 when gravid mussels are disturbed that the eggs, in whatever stage of development they 
 may be, arc aborted or discharged into the water. This not infrequently happens in 
 aquaria, and doubtless may occur in nature. Abortion is presumed to be due to a de- 
 ficiency of dissolved oxygen in the water; the mussel, beginning to suffocate, discharges 
 the eggs in order to employ its gills more effectively for respiration. 
 
 SEASONS OF DEPOSITION OF EGGS. 
 
 We must distinguish with fresh-water mussels the seasons when eggs are matured, 
 passed out of the body, and deposited in the marsupial pouches from the season when 
 the developed glochidia are cast out into the water. The tenn "spawning season" 
 might be misleading, because it is commonly used to refer to the occasion when the 
 glochidia are discharged to the exterior, and this may be weeks, months, or some- 
 times nearly a year after the eggs are actually extruded from the reproductive organs 
 and the young are launched into existence. In general, the deposition of eggs — the 
 actual spawning process, scientifically speaking — occurs with the long-term breeding 
 class (see below) in the latter part of the summer or early fall. In the short-term 
 breeding class spawning usually takes place in June, July, or August, although in one 
 or two species it is known to occur as early as April. One mussel, the washboard, 
 deposits eggs only in the late summer and early fall, August to October. 
 
 It is the experience of the Fisheries Biological Station at Fairport that the spawn- 
 ing seasons of mussels fluctuate to some degree in different years, no doubt because the 
 ripening of mussels is affected by varying conditions of water temperature. There are 
 also, of course, some differences of breeding season corresponding to differing climatic 
 conditions in more northern or more southern waters. 
 
 SEASONS OF INCUBATION OF EGGS. 
 
 Generally speaking, fresh-water mussels may be divided into two classes with re- 
 spect to their breeding seasons — the long-term breeders and the short-term breeders. 
 
 In the case of the long-term breeders the eggs are fertilized during the middle or 
 latter part of the summer and, passing into the brood pouches, develop into glochidia, 
 which are usually matured by fall or early winter. The glochidia may pass the entire 
 winter in the brood pouches, to be expelled during the following spring and early summer. 
 As might be expected, there is some overlapping of successive breeding seasons; females 
 
 a Exceptions to this rule are noted by Ortmann (1911. p. 299). In such cases (the genera Anodonta, Anodontoides, Sym- 
 phynota, and Alasmidonta) the eggs or glochidia are entirely separate from one another and flow out freely when the ovisac is 
 opened. 
 
FRESH-WATER MUSSELS. 
 
 141 
 
 that have discharged the glochidia quite early in the summer may already have the 
 brood pouches filled with eggs for the next season, while other mussels of the same spe- 
 cies are still retaining the glochidia developed from eggs of the past year. This fact is 
 obviously favorable to the work of artificial propagation, rendering it possible to obtain 
 glochidia of certain species of mussels at any time during the year. Thus in Lake Pepin, 
 a widened portion of the Mississippi River between Minnesota and Wisconsin, where the 
 Lake Pepin muckct or fat mucket is being propagated on a large scale by the Bureau, 
 a sufficient number of gravid mussels can be obtained for carrying on the operations from 
 the time they are commenced in May until they are tenninated in October or November. 
 
 In the case of the short-term breeders the breeding activities are restricted to a 
 season of about five months, from April to August, inclusive. The period of incubation 
 for any individual mussel of this class is undoubtedly very much shorter, although tem- 
 perature or other conditions may cause the period of incubation to be lengthened or 
 shortened. 
 
 In Tables 15 and 16 there are listed the more common species of mussels with indi- 
 cation of the months in which females have been found with mature glochidia. The 
 lack of a record of gravidity may, of course, be due in some cases not to an actual gap 
 in the breeding season but to the want of opportunity for sufficient observation of the 
 species during a particular month. (See also Ortmann, 1909; Lefevre and Curtis, 1912; 
 and Utterback, 191 6.) 
 
 The commercial and noncommercial species are grouped in different tables, not 
 only because the records are more complete for the former but because those who are 
 concerned with the conduct or regulation of the mussel fishery will be interested almost 
 exclusively in the mussels of direct economic importance. 
 
 Table 15. — The More Important Commercial Mussels, with Indication of Months During 
 Which Females Have Been Found with Mature GLOcmDiA. 
 
 Scientific name. 
 
 Common name. 
 
 i 
 
 J3 
 
 i 
 
 a 
 < 
 
 i 1 
 
 >> 
 
 3 
 
 < 
 
 
 
 
 
 >5 
 
 a 
 
 
 
 
 
 
 
 
 
 
 
 
 (?) 
 
 X 
 
 X 
 X 
 
 X 
 X 
 X 
 X 
 
 
 
 Dromedary mussel 
 
 
 
 
 
 
 
 
 
 
 
 
 yellow sand-shell . . 
 
 X 
 
 X 
 
 X 
 
 X 
 X 
 
 X 
 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 
 X 
 
 X 
 
 X 
 X 
 
 X 
 X 
 
 X 
 X 
 X 
 X 
 X 
 X 
 
 
 
 
 
 
 
 
 
 
 
 
 Mucket 
 
 
 X 
 X 
 
 X 
 X 
 X 
 X 
 
 X 
 X 
 X 
 X 
 X 
 X 
 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 
 X 
 X 
 X 
 X 
 X 
 
 X 
 X 
 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 
 X 
 X 
 X 
 X 
 
 X 
 
 X 
 X 
 
 X 
 
 
 Lampsilis luteola 
 
 Fat mucket . ... 
 
 X 
 
 
 
 
 
 Pocketbook . 
 
 X 
 
 X 
 
 
 
 
 
 
 
 
 X 
 X 
 
 
 X 
 X 
 
 X 
 X 
 
 X 
 X 
 
 X 
 
 
 
 
 
 
 Bullhead 
 
 
 
 
 
 
 
 
 
 
 
 X 
 
 X 
 
 X 
 
 z 
 
 
 
 Rabbit's foot 
 
 
 
 
 
 
 X 
 X 
 
 X 
 X 
 
 
 
 
 
 
 
 X 
 
 X 
 
 X 
 
 X 
 X 
 
 
 
 
 
 Washboard 
 
 X 
 
 X 
 
 
 X 
 
 X 
 
 X 
 
 
 
 X 
 X 
 X 
 
 X 
 X 
 X 
 X 
 X 
 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 X 
 
 X 
 
 
 
 Moakey-face 
 
 
 
 
 
 
 
 
 
 
 
 
 
 X 
 
 
 
 
 
 
 Round Lake 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 X 
 
 
 
 
 
 
 Pimple-back 
 
 
 
 
 
 
 
 
 
 
 do 
 
 
 
 
 
 
 X 
 X 
 
 
 
 
 
 
 
 
 
 
 
 X 
 X 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 PiE-toe 
 
 
 
 
 
 X 
 X 
 
 X 
 
 X 
 
 
 
 
 
 
 
 
 
 
 X 
 X 
 X 
 X 
 X 
 
 
 
 
 
 White heel-splitter 
 
 X 
 
 
 
 X 
 X 
 X 
 
 
 X 
 
 X 
 
 X 
 
 X 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 X 
 
 X 
 
 
 
 
 
 
 
 
 
 1 
 
 
 
 
 
142 
 
 BULLETIN OP THE BtrREAU OF FISHERIES. 
 
 Table i6 —Some Noncommercial Mussels, with Indication of Months During Which Females 
 
 Have Been Found with Glochidia. 
 
 Scientific name. 
 
 Common name. 
 
 i 
 
 i 
 
 i 
 
 a 
 < 
 
 
 i 
 
 l-» 
 
 >. 
 
 3 
 1— » 
 
 3 
 < 
 
 1 
 
 a 
 
 i 
 
 ^ 
 
 
 
 
 
 
 
 
 
 
 
 X 
 
 
 
 
 Alasmidonta marginata 
 
 Anodonta cataracta 
 
 
 X 
 X 
 X 
 
 
 
 X 
 
 
 
 
 
 X 
 
 X 
 X 
 
 X 
 X 
 
 X 
 
 X 
 
 
 
 
 X 
 X 
 
 X 
 
 X 
 
 X 
 
 X 
 
 X 
 
 (?) 
 
 X 
 
 X 
 
 X 
 
 Anodonta imbcciilis 
 
 Anodonta i mpUcata 
 
 
 
 
 
 Anodonta suborbiculata 
 
 Arcidcns confragosus 
 
 Paper-shell 
 
 Rock pocketbook 
 
 X 
 X 
 
 X 
 
 
 
 '.'.'.'. 
 
 X 
 
 
 
 X 
 
 
 X 
 
 X 
 
 Hemilastena ambigua 
 
 Lampsilis alata 
 
 T^ampsilis borealis 
 
 
 X 
 
 X 
 
 X 
 
 X 
 
 X 
 
 X 
 
 X 
 
 X 
 X 
 X 
 X 
 
 X 
 X 
 
 X 
 
 
 
 
 Lampsilis capax 
 
 I,arapsilis cracilis 
 
 Pocketbook 
 
 X 
 
 X 
 
 
 X 
 
 X 
 
 X 
 X 
 X 
 X 
 
 X 
 
 X 
 
 X 
 
 X 
 
 X 
 
 X 
 
 
 
 Lampsilis iris 
 
 
 
 
 
 
 X 
 X 
 
 
 
 
 
 
 
 Lampsilis Ijcvissima 
 
 Lampsilis lienosa 
 
 Lampsilis parva 
 
 
 X 
 
 
 X 
 
 X 
 
 X 
 
 X 
 
 X 
 X 
 
 
 X 
 
 
 
 
 Lampsilis subrostrata 
 
 Lampsilis texasensis 
 
 T flmpsilis veutricosa satura 
 
 Plagiola donaciformis 
 
 Plagiola elcyans 
 
 Deer-toe 
 
 
 
 
 
 
 ... 
 
 X 
 X 
 X 
 
 X 
 
 X 
 
 X 
 X 
 
 X 
 
 
 
 
 
 Quadrula cooperiana 
 
 Quadrula granifera 
 
 Strophitus edentulus 
 
 Purple warty-back 
 
 Squaw-foot 
 
 
 r " 
 
 X 
 
 ... 
 
 X 
 
 X 
 
 X 
 X 
 
 X 
 X 
 
 X 
 X 
 
 X 
 X 
 X 
 
 X 
 X 
 
 X 
 
 X 
 
 
 Symphynota costata 
 
 Symphynota compressa 
 
 Tnmcilla arcseformis 
 
 Fluted shdl 
 
 Sugar-spoon 
 
 
 
 
 
 
 .... 
 
 . . * 
 
 
 
 
 Truncilla capsaeformis 
 
 Unio tetralasmus 
 
 Oyster mussel 
 
 
 ::: 
 
 
 
 X 
 
 ::: 
 
 
 
 
 
 
 E 
 
 It will be observed that, generally speaking, the several species of Quadrula and 
 Unio, as well as Pleurobema cBsopus (bullhead), TrUogonia iuherculata (buckhom), and 
 Obliquaria reflexa (three-horned warty-back) are short-temi breeders, while the species 
 of Lampsilis, as well as Obovaria ellipsis (hickory-nut), and Symphynota complanata 
 (white heel-splitter), Plagiola securis (butterfly), and others are long-term breeders. 
 Most interesting is the case of the washboard, Quadrula heros, which, from its taxonomic 
 position, would be expected to have the short summer breeding season, but which at 
 least simulates the long-term breeders. The glochidia become mature from early 
 autumn to winter, apparently varying with the latitude, but so far as known are not 
 held for a long period after maturity. They react like the short-term summer breeders 
 when removed from the water in that they quickly abort the contained glochidia. It 
 may be either that its relationship has been incorrectly appraised or that it represents a 
 transition stage from the short-temi to the long-tenn breeding class. Certainly it is 
 the one species of mussel subjected to close study which has never been found to have 
 either eggs or glochidia in its gills during the summer months. 
 
 Finally, it may be remarked that the terms "short-term" and "long-term," as 
 applied to the breeding season, are perhaps inappropriate and misleading. So far as 
 we know, in all species (except the washboard, in one respect) the development of the 
 egg into the glochidium follows promptly on ovulation, occupies a period of a very few 
 weeks, and occurs during warm weather. The short-term breeders are those which 
 throw' out the glochidia at once, while the long-term breeders carry them over until the 
 following year. It seems to be a general rule that the short-term breeders pass through 
 all phases of reproductive activity on a rising temperature, while the long-term breeders 
 
FRESH-WATER MUSSElvS. 
 
 143 
 
 begin their breeding activities on falling temperatures of one season, but discharge the 
 glochidia on rising temperatures of the folloAving season. 
 
 Several experiments have shown that the glochidia taken from long-term breeders 
 in the fall of the year may be successfully infected upon fish and that the young mussels 
 will undergo development. It appears, however, that these "green" or newly formed 
 glochidia require a longer period of parasitism than those which have been nursed by the 
 parent through the winter season (Corwin, 1920). 
 
 The origin and purpose of the retention of glochidia during the winter season re- 
 mains a mystery. This may be an instance of nature's remarkable adaptations, per- 
 mitting the development of the egg to occur during the warmer months of summer, and 
 the glochidia to be discharged for attachment upon fish in the spring when there is a 
 general tendency toward an upstream movement of fishes. It is distinctly interesting 
 to note that the long-term breeders (mucket, sand-shells, etc.), as a general rule are 
 mussels of much more rapid growth than the short-term breeders (mggerhead, pimple- 
 back, etc.), although the young of the former are delayed for nearly a year in becoming 
 attached to fish and completing their metamorphosis. 
 
 It is important to point out one fact which is clearly established by data in Table 
 15, page 141. There is no month of the year in which a considerable number of commer- 
 cial mussels are not gravid with glochidia. This fact deserves careful consideration in 
 connection with measures of conservation, since it makes impracticable the protection 
 of mussels by "closed seasons" of months based upon the times of breeding. 
 
 GLOCHIDIUM. 
 
 The larval mussel or glochidium, when completely developed and ready to emerge 
 from the egg membrane and before attaching itself to 
 a fish, has apparently an extremely simple organization. 
 The soft mass of flesh possesses neither gills nor foot nor 
 other developed organ characteristic of the adult mussel, 
 but it bears a thin shell composed of two parts which 
 are much like the bowls of tiny spoons hinged together 
 at the top (text fig. 8). The two parts or valves of the 
 shell can be drawn together by a single adductor muscle, 
 but, when the muscle is relaxed, they gape widely apart 
 as shown in the illustration. There are also on the 
 inner surface of each side of the body several pairs of 
 "sensory" cells with hairlike projections. It has been 
 assumed that the cells were sensory in function, and 
 recently L. B. Arey, working at the Fairport station, 
 determined after detailed experiments upon several 
 species of Lampsilis and Proptera that there is a well- 
 developed sense of touch centralized in the hair cells. He regards the tactile response 
 as entirely adequate to insure attachment of the glochidium. 
 
 In at least three genera of American mussels (several species of Unio, Anodonta, 
 and Quadrula) the glochidium possesses a peculiar larval thread of uncertain signifi- 
 cance (text lig. 8). This thread, so generally mentioned in textbooks based upon studies 
 of European mussels, is not found on the great majority of American species. We 
 
 Fig. 8. — Glochidium of Quadrula heros with 
 gaping valves, seen from a side view. 
 The larval thread (/. t.) is seen between 
 the valves. Imier and outer sensory hair 
 cells (s. h. c.) are visible on each valve. 
 
144 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 have observed it on glochidia of the following species: The washboard, Quadrula heros, 
 the blue-point, Q. plicata, the pig-toe, Q. undata, the bullhead, Pleurobcvia cesopus, the 
 spike. Unto gibbosus, the slop-bucket, Anodonta corpulcnta, and the river pearl mussel, 
 Margaritana margariiifera. The squaw-foot, Strophitus edentulus, has a modified larval 
 thread (Lefevre and Curtis, 1912, p. 173). 
 
 That the structure of the glochidium is less simple than appears to the ordinary 
 observer is shown by the fact that, in the fully developed glochidium, close microscopic 
 study will reveal the rudiments of foot, mouth, intestine, heart, and other organs which 
 will not, however, assume their destined form and functions until after the period of 
 parasitism. The shell of the glochidium is firm but somewhat brittle owing to the car- 
 bonate of lime of which it is partly composed. If the lime is dissolved out with acid, 
 the remaining shell, composed only of cuticle, preserves its general form, although it 
 becomes wrinkled and collapsible. 
 
 The number of glochidia borne in the brood pouches of a fully grown female mussel 
 according to the counts and computations made by various obser\'ers, varies in the 
 different species from about 75,000 to 3,000,000. An example of the paper-shell, Lamp- 
 silis gracilis, yielded by computation 2,225,000 glochidia. The mussel was 7.4 cm. 
 (about 3 inches) in length. Several examples of the Lake Pepin mucket yielded glo- 
 chidia in the following numbers, the length of the mussel being indicated in parentheses: 
 (6.1 cm.) 79,000; (7 cm.) 74,000; (7.4 cm.) 125,000; (8.5 cm.) 129,000. 
 
 The glochidia of mussels are very diverse in size and form, although for any given 
 species the dimensions and shape of the glochidium have been regarded as fairly con- 
 stant (Surber, 1912 and 191 5). Differences in sizes of glochidia within the species are 
 noted by Ortmann (1912 and 1919)" and Howard (1914, p. 8). The matter requires 
 investigation. As regards their form, glochidia are separable into three well-known types : 
 (i) the "hooked" type, {2) the "hookless" or "apron" type, and (3) the "ax-head" type. 
 
 (i) The "hooked" type (PI. XIV, figs, i and 2) possesses a rather long stout hinged 
 hook at the ventral- margin of each triangular or shield-shaped valve. These glochidia 
 are usually larger than those of the other two types and the shell is considerably heavier. 
 The hooks are provided with spines which no doubt assist the glochidium in retaining 
 its hold upon the host. As all hooked glochidia generally (though not invariably) attach 
 to the exterior and exposed parts of the fish, the fins and scales, the advantage of the 
 heavier shell and stout hooks may readily be seen. This type of glochidium is possessed 
 by mussels of the genera Anodonta, Strophitus, and Symphynota (floaters, squaw-foot, 
 and white heel-splitter, etc.). (See also text figs. 9 and 12.) 
 
 (2) The shells of glochidia of the "hookless" type (PI. XIV, figs. 3, 4, and 5), while 
 lighter than those of the hooked type, are nevertheless of sufficient strength to with- 
 stand considerable rough handling. So far as we now know, all the glochidia of this 
 type are gill parasites with the exception of the washboard, Quadrula hcros, which 
 has been successfully carried through the metamorphosis on both gills and fins. The 
 hookless glochidia vary rather widely in shape and in size (text figs. 9 to 12); among 
 the smallest is that of the spectacle-case, A/argon'towa monodonta (0.05 by 0.052 mm).; 
 while one of the largest is that of the purple pimple-back, Quadrula granifera (0.290 by 
 0.355 mni.). Placed side by side, about 500 of the smallest or about 80 of the largest 
 
 a Ortmann gives many cases of small discrepancies between his measurements and those of others, based no doubt upon the 
 different sources of material. In several cases he has observed differences in sizes of glochidia from different individuals. See 
 papers in the Nautilus, Vol. XXVin,i9i4. and Vol. XXJX, 1915. In one instance he reports glochidia of two sizes from one indi- 
 vidual C1913, p. 353), Sec also Surber. 1913, p. 4. 
 
Bui.i,. U. S. B. F., 1919-20. 
 
 PUATE XIV. 
 
 
 :^:v,:-^::.^ 
 
 V 
 
 iiTJL'i'VI 
 
 11 
 
 [Figures from Lefevre and Curtis, 1912.] 
 
 Figs, i and 2. — Hooked ^lochidiura oi Sym phynota costata. 
 
 Figs. 3, 4, and 5. — Hooklessglochidiumof Lampsilis subro- 
 strata. 
 
 Figs. 6 and 7. — Ax-head glochidinm of LampsiUs (Prop- 
 tcra) alata. 
 
 Fig. 8. — Conglutinates (masses of glochidia) from the three- 
 horned warty-back, Obliquaria rcflexa. 
 
 Fig. 9. — Portion of conglutinate of Obliquaria rcflexa, 
 magnified. Glochidia still within egg membranes which 
 are closely pressed and adhering together. 
 
 Fig. 10. --Conglutinates (masses of glochidia) from the 
 mucket, LaviPsilis lnjamcntina. 
 
 Fig. II. — Portion of conglutinate of Lampsilis Ucameniina 
 magnified. Glochidia inclosed in membranes are embedded 
 in a mucilaginous matrix. 
 
Bull. U. S. B. F., 1919-20 
 
 Fig. 3. — Three pill filaments of rock bass, with glochidia of 
 mucket. 
 
 T't.i r— Partoffig. I. enlarged. 
 
 Fig. 4. — Stages in formation of cyst surrounding a glochidium of the mucktt. Taken at : -^ inimitt s. ^d minutes, i hour. 
 
 and 3 hours, respectively, after infection. 
 
 '■% 
 
 Fig. 5.— Young muckets, one week after liberation from the fish, showing new 
 growth of shell, cilia on foot, and positions assumed in crawling. Enlarged. 
 
 (Figs, i-s after Lefevre and Curtis. 
 
 Fig. 6. — Young Lake Pepin muckets at 
 ages of 1. 2, ji. and 4 months, respec- 
 tively. Xatural size. 
 
FRESH-WATER MUSSELS. 
 
 145 
 
 m 
 
 Fig. 9. — Glochidia of commoa fresh-water mussels 
 
 q. Anodo7itoitles fcrussacianus 
 
 subcylin-dr aceus. 
 ft, Arcidcns confragosus. 
 i, Cyprogenia irrorata. 
 j, Dromus dramas. 
 
 n 
 
 (After Surber, 1912 and 1915-) 
 
 a, Alasmidonla calceola. 
 
 b, Alasmidonta marginata. 
 
 c, Anodania corptdenta. 
 
 d, AtwdotUa gratidis. 
 
 e, AnodonlairniieciUis. 
 
 k, Lanipsilis anodontoides. 
 I, Lampsilis brei'ictdus brittsi. 
 m. Lam P silts fallaciosa. 
 n, Lampsilis gracilis. 
 0, Lampsilis hifjginsii. 
 
 / fAnodonta suborbiculata. 
 
146 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 m 
 
 u 
 
 Fig. 10. — Glochidia of common fresh-water mussels. (After Surber. 1912 and 1915.) 
 
 a, Lampsilis iris. 
 
 b, Latnpsilis lienosa unicostaia. 
 
 c, L.ainpsilis ligantentina. 
 d, Lampsilis luieola. 
 
 e, Lampsilis multiratliaia. 
 
 f, Lampsilis parva. 
 p. Lampsilis picta. 
 
 k, Lampsilts recta, 
 i, Lampsilis subrostrata. 
 j. Lampsilis trabcUis. 
 k, Lampsilis venlricosa. 
 I, Lampsilis ventr ices a satur a. 
 m, Afargaritana monodonta. 
 n, Obliquaria reflexa. 
 
 o. Obovaria cir cuius, 
 p. Obovaria ellipsis, 
 q, Obovaria rctusa. 
 r. Plagiola donaciformis. 
 s, Plagiola elegans. 
 i. Plagiola securis. 
 u, Pleurobema cesopus. 
 
FRESH-WATER MUSSELS. 
 
 147 
 
 m 
 
 n 
 
 Fig. II. — Glochidia of common fresh-water mussels. (After Surber, 1912 and 1915.) 
 
 a and 6, Proptera alaia. 
 
 c, ProPtcra capax. 
 
 d, Proptera laevissima. 
 e and/, Proptera purpurata. 
 
 0, Quadrula coccinea, 
 h, Quadrula eberms. 
 
 I, Quadrula orani/era. 
 j, Quadrula keros. 
 k, Quadrula lachrymosa. 
 I, Quadrula metanevra. 
 m, Quadrula obliqua. 
 
 n, Quadrula plicata. 
 o, Quadrula pusiulaia. 
 P, Quadrula Pustulosa. 
 q, Quadrula solida. 
 r, Quadrula undata. 
 
148 
 
 BULLETIN OP THE BUREAU OF FISHERIES. 
 
 f 
 
 Fig. 12. — Glochidia of common Iresh-water mussels. (After Surber, 1912 and 1915.) 
 
 a, Strophitus edentulus, 
 
 b, Symphynota complanaia. 
 
 c, Symphynota compressa. 
 
 dt Symphynota costata. 
 
 e, Truncilla sulcata. 
 
 /, Tritogonia iuberculata. 
 
 g, Vnio crassidens. 
 h, Vnio gibbosus. 
 
 would make a line i inch in length. Hookless glochidia are possessed by practically all 
 of the more important commercial mussels; in fact, as far as we know, this type of glo- 
 chidium characterizes all the genera and species not mentioned in the paragraphs im- 
 mediately preceding and following. 
 
 (3) The "ax-head" type (Pi. XIV, figs. 6 and 7) is considered more closely related to 
 the hookless than to the hooked type, although glochidia of this type, except those of 
 a single species, Lampsilis (Proptera) Icevissima (Coker and Surber, 191 1), possess four 
 hooklike prongs, one at each lower comer of the shell. These pointed projections of 
 the shell are not comparable to the pivoted hooks of glochidia of the hooked type. The 
 ax-head type of glochidium occurs with the following species: Lampsilis {Proptera) 
 (data, Icevissima, purpurata, and capax. (See also text fig. 11, a to f.) 
 
 When the glochidia are fully developed they are ready to break out from the egg 
 membrane and to be liberated from the gills of the mussel, although as previously indi- 
 cated many species of mussels retain the developed glochidia in their gills for many 
 months. A characteristic feature of the mature and healthy glochidium is the active 
 snapping together and opening of the shell. This action can be stimulated by adding a 
 drop of fish blood or a few grains of salt to the water in which the glochidia are held. 
 
 STAGE OF PARASITISM. 
 
 After the fully matured glochidium has been expelled from the brood pouch of the 
 mother, its continued development is dependent upon its coming in contact with the 
 gills or fins of a suitable fish host and attaching to them. If it fails to make this attach- 
 
Bull. U. S. B. F., 1919-20. 
 
 Plate XVI. 
 
 Fig. I.— Filaments of gill of fresh-wau i Inim with heavy natural infection of 
 Plagiola donactfonnis. Estimated tuta! number of ylochidia carried by fish 
 
 4,Soo. 
 
 Fig. 2. — Glochidia of washboard mussel, Quadrnla hcros, on 
 fin nf fresh-water drum. Cyst very much enlariied. 
 
 Fig. 3.— Section through vacated cysts on gill filaments; 
 Qiiadnila ebenus on river herring. 
 
Bull., U. S. B. F., 1919-20. 
 
 Plate XMI. 
 
 Fig. 2. — A young mussel, Sytnpkynota 
 costata, six days after completing the 
 stage of parasitism. (Lefevre and 
 Curtis.) 
 
 Fig. I. — Glochidium ol Symphynota costata in process of transformation 
 during stage of parasitism. (Lefevre and Curtis.) 
 
 r" 
 
 Fig. 3. — A young squaw-foot mussel, Slrop-hitus edenlulm, which had 
 completed metamorphosis without parasitism; showing two adduc- 
 tor mussels, foot, gills, and rudiments of other organs of adult mussel. 
 (Lefevre and Curtis.) 
 
 Fig. 4. — A young mucket, Lampsilis 
 ligamentitia. a week after the close of 
 the parasitic period. (Lefevre and 
 Curtis.) 
 
FRESH- WATER MUSSEL^. 1 49 
 
 ment it will die within a few days' time. In other words, the glochidium must pass the 
 life of a virtual parasite on the fish while undergoing its metamorphosis into the free- 
 living juvenile stage. In the light of our present knowledge, this is true of all the fresh- 
 water mussels (Unionidae) except the squaw-foot, Strophitus edentulus, and one of the 
 small floaters, Anodonta imhecillis. The former species may complete its metamorphosis 
 either with or without parasitism (Lefevre and Curtis, 191 1 and 1912, p. 171; and 
 Howard, 1914, p- 44), while the latter, as it appears, never endures a condition of para- 
 sitism (Howard, 1914, p. 44). 
 
 On coming in contact with the gill filament or fin of the fish the glochidium attaches 
 itself by firmly clamping its valves to the tissue of the host. A certain portion of the 
 tissue of the fish thus becomes inclosed within the mantle space of the glochidium, and this 
 quickly disintegrates and is taken into the cells of the glochidium and consumed as food 
 (Lefevre and Curtis, 191 2, p. 169). Within a very short time the tissue of the fish 
 commences to grow over the glochidium, presumably in an effort to heal the slight 
 wound caused by the "bite" of the glochidium, or perhaps as the result of a positive 
 stimulus imparted by the glochidium. L. B. Arey (report in preparation) successfully 
 
 induced encystment by attaching to the 
 
 filaments of excised gills of fish minute .,•■■' j^^ ""-■ 'Vv-x 
 
 metallic clamps the size of glochidia or / ff00^K '■ ' Ft 
 
 smaller. The growth of tissue continues ^" / ' . ; j 'ijiA 
 
 until the larval mussel is completelv -if^^"^ ^ ' ^ 4- -I' .V 
 
 inclosed within a protective covering / ■ i ' ^igs^ i ' I i 
 
 known as the cyst (PI. XVI, fig. 2). \ ° .., ....i^^ 
 
 The several stages of encystment are '■ — xJ./Ai-^^M.., ^ ^^3J '' "" 
 
 clearly represented in the series of fig- „, ,_.j. , ■ , \. , ,•„ , . ■, ,„ ^, ^ 
 
 ■^ ^ . Fig. 13. — Glochidium of pmk hecl-splitter. Lampsuts (.PropteraJ 
 
 UreS reproduced from Lefevre and Curtis alala, in condition of parasitism on gill of slicepsliead, showing 
 
 (^1012) (Pi. XV fig. 4) and the process growthofthejuvenilemussdbeyond the bounds of the glochidlal 
 
 maybecompleted within 24 or 36 hours. 
 
 The appearance of a gill bearing a considerable number of glochidia is shown by 
 figure I of Plate XV, while figure 2 is an enlarged view of a few of the gill filaments of 
 a black bass carrying glochidia of the mucket. 
 
 It is not our purpose to go in detail into the changes which occur in the glochidium 
 during the period of its parasitism. They are principally changes of internal structure 
 which scarcely affect the external appearance. Nevertheless, at the conclusion of para- 
 sitic life the young mussel is a very different sort of an organism from the simply organized 
 glochidium which has been described on page 143. Generally it has not increased in size, 
 but the single muscle which held the valves of the glochidial shell together has given place 
 to two adductor muscles as in the adult; the mouth and the intestine are formed, 
 the gills and foot are represented by rudiments which are prepared to function. The 
 larval mussel is, in fad , ready to begin its independent life and to take care of itself. All 
 of the changes which occur during parasitism require the expenditure of energy and the 
 use of body-building material, and as the glochidium enters upon the parasitic life with 
 no considerable store of food material, it is reasonable to assume that it derives at least 
 a small amount of nutritive material from the fish. Since no growth in size generally 
 occurs, the drain upon the fish therefore must be comparatively slight. There are, how- 
 ever, a few species (none of the commercial mussels, so far as we know) in which, during 
 the period of metamorphosis, the larval mussel grows to a comparatively large size 
 
I50 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 (text fig. 13), and, in such cases, the mussel must be generously nourished by the fish. 
 (See Coker and Surber, 191 1.) 
 
 The duration of the parasitic period varies greatly with the season of the year during 
 which it occurs, and with other conditions which are not fully understood. The results 
 of some recent experiments indicate that glochidia of long-term breeders have a rela- 
 tively long infection period when they are infected upon fish shortly after maturing 
 and a relatively short period when infected after they have remained in the marsupial 
 pouches over winter; that is, young glochidia complete metamorphosis in parasitism 
 
 more slowly than old glo- 
 chidia. The temperature of 
 the water seems to be one 
 of the factors governing the 
 duration of the parasitic 
 period, and doubtless the 
 vitality of the host fish is 
 another; but there is diver- 
 sity even among glochidia of the same species when infected on the same fish. Lefevre 
 and Curtis (1912, p. 168), for example, show under such circumstances variations from 
 9 to 13 days, and even from 13 to 24 days. The following instances (Table 17) from 
 records at the Fairport station are illustrative : 
 
 Tablb 17. — Infections Showinq Duration of Parasitic Period. 
 
 Fig. 14.- 
 
 -A dorsal view of a juvenile pink heel-splitter showing glochidial shell still 
 visible. (Xi8). 
 
 Species of mussel. 
 
 Species of fish. 
 
 Date of 
 infection. 
 
 Duration 
 
 of 
 infection 
 in days. 
 
 Average 
 water tem- 
 perature 
 during 
 period. 
 
 
 
 June 5, 1919 
 June 20, 1919 
 July 3.1919 
 July 9. 1919 
 July 23.1919 
 June 5. 1919 
 June 20. 1910 
 July 14, 1919 
 
 13 
 12 
 II 
 13 
 12 
 13 
 13 
 10 
 II 
 
 13 
 
 10 
 12 
 12 
 12 
 11 
 10 
 
 IS 
 
 13 
 14 
 19 
 
 20 
 
 68 
 (") 
 («) 
 6to S 
 
 9 to II 
 
 11 to 12 
 11 
 
 14 to 18 
 
 14 to 2 1 
 
 
 Do 
 
 do 
 
 
 Do 
 
 do 
 
 
 Do 
 
 . . do 
 
 
 Do 
 
 do 
 
 
 Lampsilis luteola 
 
 
 
 Do 
 
 
 
 Do 
 
 do 
 
 
 Do 
 
 do 
 
 
 Do 
 
 ....do 
 
 .... do 
 
 
 Do 
 
 do 
 
 July as- 1919 
 ... do ... 
 
 
 Do 
 
 ... do 
 
 
 Do 
 
 do 
 
 do 
 
 
 Do 
 
 .... do 
 
 Aug. 21, 1919 
 
 
 Do 
 
 do 
 
 
 Do 
 
 .. do 
 
 Aug. 22, 1919 
 June 5. 1919 
 June 30,1919 
 
 
 
 do 
 
 
 Do 
 
 do 
 
 
 Do 
 
 do 
 
 
 Lampsilis luteola 
 
 
 July 2; 1914 
 
 
 Do 
 
 
 
 Do 
 
 
 Aug. 18. 1914 
 Sept. 26. 1914 
 Sept. 16, 1914 
 Aug. 21.1912 
 July 7. 1912 
 Aug. 4. 191:; 
 July 12. 191S 
 July 13, 1918 
 July 7. 1919 
 Oct. 7. 1912 
 
 
 Do 
 
 do 
 
 
 Do 
 
 
 
 
 
 75-1 
 78. 1 
 
 Do 
 
 
 Do 
 
 do 
 
 75-5 
 76. 5 
 78. 3 
 
 
 
 Lampsilis fallaciosa 
 
 do 
 
 
 ....do 
 
 
 QltnHrnlp Jipfft^ 
 
 
 
 
 
 
 n still carrying infection, Apr. 14, 1915. 
 
 In about one week after attachment, as a rule, the wall of the cyst begins to assume a looser texture, 
 the intercellular spaces becoming infiltrated with lymph, and from this time on to the end of the parasitic 
 period there is little further change in its structure. 
 
 Before liberation of the young mussel, the valves open from time to time and the foot is extended. 
 By the movements of the latter the cyst is eventually ruptured, its walls gradually slough away, and the 
 mussel thus freed falls to the bottom (Lefevre and Curtis, 1912, p. 171). 
 
FRESH-WATER MUSSELS. I5I 
 
 Before taking up the history of the mussels in independent juvenile life, we must 
 discuss the very significant facts which have been discovered concerning the special 
 relation between mussel species and fish species, and refer also to the rare instances known 
 of mussels which complete their development without the aid of fish. 
 
 HOSTS OF FRESH-WATER MUSSELS. 
 
 As has previously been indicated in a general way, mussels do not attach to fish 
 indiscriminately, but for each species there is a restricted choice of hosts. Some are 
 more catholic in their tastes than others, yet for any mussel there is a limited number 
 of species of fish upon which it will attach and complete its metamorphosis. The Lake 
 Pepin mucket has nine known hosts, while the niggerhead has apparently but one; 
 the yellow sand-shell is restricted to gars, and the pimple-back to catfishes. It is, of 
 course, employing language in a loose sense to refer to this selection of hosts in terms of 
 taste or choice; it is a matter of physiological reaction. When fish and glochidia are 
 artificially brought together, glochidia will sometimes attach to the wrong fish, but in 
 such cases they soon drop off, or even if partial or complete encystment ensues, the glochi- 
 dium does not develop normally and after a time cyst and glochidium are sloughed ofiE 
 and lost. It seems evident, then, that successful encystment and development depend 
 upon appropriate reactions on the part of both glochidium and fish, and that failure 
 ensues upon the lack of a favorable reaction on the part of either parasite or host. The 
 reaction may depend in part upon the condition of the individual glochidium or fish, but 
 primarily it depends upon the species of mussel and the species of fish. 
 
 It is evident that the artificial propagation of mussels can not be conducted success- 
 fully and economically unless we have accurate knowledge of what species of fish serve 
 as hosts for the several species of mussels. Such knowledge has been gained by following 
 two methods of inquiry, the observational and the experimental. 
 
 By the obser\'ational method, fish taken in the rivers are subjected to careful 
 examination for the presence of glochidia on the gills or fins. Preliminary to and 
 attendant on such studies, glochidia have been taken from as many species of mussels as 
 could be found in gravid condition, these have been studied with the microscope, meas- 
 ured, and figured, so that in most cases the species of mussel can be identified in the 
 glochidium stage as well as in the adult. (See text figs. 9 to 12.) This method of deter- 
 mining the natural hosts is exceedingly laborious. Infection in nature is a matter of 
 chance, and only a small proportion of fish bear infections. If it were otherwise, artificial 
 propagation might not be necessary. One must, therefore, examine large numbers of fish 
 from different localities and at different seasons, and even then the glochidia of some 
 species may not be encountered, or they may not be found upon all the hosts to which 
 they are adapted. During the calendar year 191 3, for example, 3,671 fish of 46 species 
 were examined for natural infections principally during the warmer months from April 
 to October. Of these, 324, or 8.9 per cent, were found to be infected with glochidia of 
 some species, but only 104 of these, or less than 3 per cent, were infected with glochidia 
 of commercial species of mussels'. The fishes infected with commercial mussels belonged 
 to 12 species, and the glochidia represented 20 species. The average number of glochidia 
 of a given species on infected fish ran from i to 416, with a mean of 125." 
 
 « In August, 1912, 5 examples of the river herring were taken and found to bear glochidia of niggerhead mussels in numbers 
 ranging from 1.S95 to 3.740 per fish (Surber, 1913, p. no). Similarly, heavy infections are freciuently found on the fresh-water 
 drum, but the glochidia are not usually those of commercial mussels. 
 
152 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 The experimental method is simpler in some respects. It consists in submitting 
 various species of fish to infection with the glochidia of a given species of mussel and 
 observing whether or not the glochidia attach. Since glochidia will sometimes attach to 
 fish which are not their natural hosts, it is necessary to hold the fish under observation 
 until the mussels have completed the metamorphosis and dropped off. It is, however, 
 impracticable to have on hand all the species of fish at the particular time when the 
 glochidia of a given species of mussel may be available. Furthermore, the failure of an 
 artificial infection to go through successfully on fish held in confinement may be due, 
 not to the want of a natural affinity between mussel and fish, but to the fact that the 
 fish does not retain its full vitality in close confinement, or to some other defect in the 
 experimental conditions. Neither of the two methods for the study of infections may, 
 then, be relied upon exclusively for the determination of the natural hosts of fresh- water 
 mussels. On the contrary, it has been found necessary to carry on the two lines of study 
 hand in hand, according to the plan which was adopted at the beginning of the scientific 
 work of the station. In this way, though our knowledge of the hosts of mussels is as 
 yet incomplete, there has been obtained a considerable body of information most of 
 which is summarized in the following table (i8)," listing 17 species of mussel and 30 
 hosts (29 fishes and i amphibian), and indicating those which serve as hosts for each 
 species of mussel. 
 
 EXPLANATION OF TABLE i8. 
 
 N. Found on the gills in natural infection. 
 
 Nf. Found on the fins in natural infection. 
 
 n. Record of natural infection but of doubtful significance. 
 
 A. Carried through on gills after artificial infection. 
 
 Af. Carried through on fins after artificial infection. 
 
 a. Results of artificial infection tmsatisfactory or not uniform. 
 
 o. Tested and found unsuitable. 
 
 T. Tested; development occurred; host perhaps suitable, but experiment not carried to conclusion. 
 
 Table 18. — Commercial Mussels and Their Hosts. 
 
 Mussels. 
 
 H 
 
 1 
 
 1 
 
 a 
 
 < 
 
 i 
 < 
 
 & 
 
 •s 
 
 < 
 
 .11 
 < 
 
 - 
 
 CO ^ 
 
 6 
 M 
 
 '0. 
 
 ■i 
 
 s 
 W 
 
 ? 
 
 a. 
 si 
 
 a 
 1 
 s 
 
 1 
 1 
 
 § 
 
 a 
 
 •3 
 
 s 
 
 □ 
 
 g . 
 
 A 
 
 s 
 
 
 
 si 
 i 
 
 A 
 
 NA 
 
 a 
 
 IS 
 
 li 
 80 
 
 j 
 
 A 
 
 3 
 
 3 .a 
 
 If 
 
 no 
 
 J3 
 
 Scientific name. 
 
 Common name. 
 
 e 
 
 
 
 c 
 
 g 
 
 1-i 
 
 Lampsilis anodontoidcs . . . 
 
 T.ampsilistallaciosa 
 
 Lampsilis higginsii 
 
 T.ampsilisligamentina 
 
 Yellow sand-shell 
 
 
 
 
 
 a 
 
 
 
 
 
 
 
 
 
 
 
 AN 
 
 
 
 
 
 
 
 
 
 
 
 
 
 n 
 
 
 
 
 
 
 
 
 
 
 Mucket 
 
 
 
 
 
 
 
 
 
 n 
 
 
 a 
 
 
 
 
 
 
 
 
 a 
 
 
 
 N 
 
 
 
 
 
 
 
 
 
 n 
 
 
 
 
 
 a 
 
 
 Lampsilis ventricosa 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 NA 
 
 
 
 AfNf 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 n 
 
 A 
 
 N 
 
 
 
 
 
 
 A 
 
 
 A 
 
 
 
 'n' 
 
 a 
 
 Ni 
 
 
 
 
 
 Af 
 
 
 
 
 
 
 
 
 
 
 
 
 
 Quadrula metanevra 
 
 
 
 
 
 
 
 
 
 
 a 
 
 a 
 
 
 
 
 
 N 
 
 N 
 
 
 
 
 N 
 AN 
 
 
 A 
 
 
 
 Qtiadrula pustulata 
 
 
 
 
 
 
 
 
 
 do 
 
 na 
 
 A 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 Pig-toe 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 1 
 
 
 
 
 1 
 
 
 1 
 
 
 
 
 » A great many daU regarding the hosts of noncommercial species ot mussels had been accumulated, but unfortunately most 
 of the records applying to such species were destroyed with the burning of the laboratory in December. 1917. 
 
PRESH-WATER MUSSELS. 
 Tabib iS. — Commercial Mussels and Their Hosts — Continued. 
 
 153 
 
 Mussels. 
 
 i 
 
 % 
 
 '5 
 
 3 
 
 1 
 
 ►4 
 
 3 
 1 
 
 0) 
 
 i| 
 
 .a .3 
 1-° 
 
 •§1 
 .B 
 
 i. 
 
 .a 
 
 ■a g 
 ■3 XI 
 
 •a 
 
 a 
 
 M 
 
 a 
 
 > 
 
 in 
 
 •g 
 
 1 
 s'-g 
 
 a u 
 
 d 
 
 ca 
 
 •3 
 
 s 
 
 3 
 
 1" 
 
 •0 
 
 .9 
 
 u 
 
 P 
 
 •a 
 
 ! 
 
 •5s 
 
 is 
 
 .a 3 
 
 to 
 .3 
 
 Q. 
 
 •s 
 a 
 
 3 
 
 E 
 
 be 
 
 3 
 
 1 
 i 
 
 1 
 
 i 
 f 
 
 Scientific name. 
 
 Common name. 
 
 Lampsilis anodontoides . 
 
 Lampsilis lallaciosa 
 
 Lampsilis liigginsii 
 
 Lampsilisligamentina.. . 
 Lampsilis luteola 
 
 Yellow sand-shell 
 
 Slough sand-shell 
 
 n 
 
 
 
 
 
 na 
 
 
 
 
 
 
 no 
 
 n 
 
 no 
 
 a 
 
 
 
 n 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 N 
 A 
 A 
 
 
 
 
 aN 
 NA 
 aN 
 
 A 
 
 
 
 
 
 
 NA 
 on 
 
 a 
 
 
 
 N 
 A 
 
 AN 
 A 
 
 
 
 AN 
 AN 
 
 NA 
 A 
 
 N 
 
 AN 
 
 
 
 
 
 
 
 NA 
 
 A 
 A 
 
 AN 
 A 
 
 
 
 
 
 
 n 
 
 
 Fat mucket 
 
 
 
 
 NA 
 
 Black sand-shell 
 
 
 
 
 
 Lampsilis ventricosa .... 
 Obovaria ellipsis 
 
 Pocketbook 
 
 
 
 A 
 
 A 
 
 
 
 
 
 AN 
 
 
 
 A 
 
 
 
 
 
 
 N 
 
 
 
 
 
 
 
 
 
 A 
 
 
 NA 
 
 
 
 
 
 
 
 
 
 
 
 
 Quadrula ebenus 
 
 
 
 
 
 AN 
 
 
 n 
 
 TN 
 n 
 
 
 
 "n" 
 
 
 
 
 
 
 
 
 Nt 
 
 
 
 Quadrula nietanevra 
 
 Quadrula plicata 
 
 Quadrula pustulata 
 
 
 
 N 
 N 
 
 
 
 
 
 
 n 
 an 
 
 
 
 
 A 
 
 Nf 
 
 AN 
 
 n 
 
 on 
 
 A 
 
 n 
 
 
 
 
 Warty-back. 
 
 
 
 
 
 
 
 
 
 
 
 N 
 
 
 
 
 
 
 
 
 
 
 n 
 
 
 
 
 
 
 
 
 
 
 
 
 
 Quadrula undata 
 
 Pig-toe 
 
 
 
 
 
 
 
 
 n 
 
 n 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 It will be observed that the number of hosts corresponding to a particular species 
 of mussel (as so far determined) varies from one to thirteen. It is of interest to give 
 the number of known hosts for each species of fresh-water mussel, as determined both 
 by observation of natural infections and by the experimental method, and this is done 
 in Table 19. 
 
 Table 19. — Number of Species or Fish Known to Serve as Hosts for Certain Species of 
 
 Mussels. 
 
 Mussels. 
 
 Scientific name. 
 
 Common name. 
 
 Natural 
 infection. 
 
 Artificial 
 infection. 
 
 Total. 
 
 Lampsilis anodontoides. . 
 
 Lampsilis fallaciosa 
 
 Lampsilis higginsii 
 
 Lampsilisligamentina. ., 
 
 Lampsilis luteola , 
 
 Lampsilis recta , 
 
 Lampsilis ventricosa 
 
 Obovaria ellipsis 
 
 Plagiola securis 
 
 Quadrula ebenus 
 
 Quadrula heros 
 
 Quadrula metanevra. . . . 
 
 Quadrula plicata 
 
 Quadrula pustulata 
 
 Quadrula pustulosa 
 
 Quadrula solida 
 
 Quadrula undata 
 
 Yellow sand-shell . . . 
 Slough sand-shell . . . 
 
 Higgin'seye 
 
 Mucket 
 
 Fat mucket 
 
 Black sand-shell 
 
 Pocketbook 
 
 Missouri niggerhead. 
 
 Butterfly 
 
 Niggerhead 
 
 Washboard 
 
 Monkey-face 
 
 Blue-point 
 
 Warty-back 
 
 ....do 
 
 Pig-toe. 
 
 (?) 
 
 (?) 
 
 Table 20 lists the com.mon species of fish showing the number of species of mussels 
 which each fish has been observed to carry as parasites. The greatest number is six, 
 for the bluegill, Lepomis pallidus, the white crappie, Pomoxis annularist and the sauger, 
 Stizostedion canadense. 
 
154 
 
 BUI^LETIN OF THE BUREAU OF FISHERIES. 
 
 Table 20. — Number op Species op Commercial Mussels Known to be Carried as Parasites 
 
 BY Certain Fishes. 
 
 Fishes. 
 
 Natural 
 infection. 
 
 Artificial 
 infection. 
 
 Common. 
 
 
 Scientific name. 
 
 Common name. 
 
 
 
 Bullhead 
 
 I 
 
 I 
 2 
 I 
 
 I 
 3 
 
 I 
 I 
 
 3 
 
 (?) 
 
 5 
 I 
 I 
 
 (?) 
 
 I 
 2 
 5 
 
 2 
 
 I 
 4 
 I 
 
 2 
 2 
 
 
 
 3 
 
 
 
 3 
 I 
 3 
 I 
 I 
 I 
 
 3 
 I 
 
 3 
 
 4 
 
 
 I 
 4 
 5 
 4 
 3 
 I 
 
 3 
 I 
 
 I 
 
 
 
 2 
 
 
 
 
 I 
 
 I 
 
 
 
 
 
 
 2 
 
 
 
 I 
 
 
 Anieiiinis iiebulosus . 
 
 do. . . . 
 
 
 
 Eel 
 
 
 Aplodiiiotus grutmiens 
 
 Sheepshead 
 
 
 
 
 
 Esox lucius 
 
 Pike 
 
 
 
 
 
 Ictalurus punctatus 
 
 Spotted cat 
 
 
 
 
 
 
 
 
 Lepisosteus tristoechus 
 
 Alligator gar 
 
 
 Lepoinis cyanellus 
 
 
 
 l,ci)otnis euryorus 
 
 Sunfish 
 
 
 Lepoinis hiimilis. 
 
 
 (') 
 
 
 Bluegill 
 
 
 
 
 
 
 
 
 Micropterus salmoides 
 
 
 
 
 
 (?) 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 Mad Tom 
 
 
 
 
 6 
 
 pfiyfiiitfdion vitr^urn 
 
 Wall-eye . .. 
 
 I 
 
 
 
 
 f^ An amphibian. 
 
 It is necessary to point to some significant practical conclusions from the data pre- 
 sented. Since mussels are "choice" as to their hosts, the chances for the successful 
 attachment of glochidia in nature are greatly diminished. The glochidia when dis- 
 charged from a parent mussel are lost if no fish are at hand to receive them or if the 
 fish that pass are not of one of the very limited number of species which are useful to 
 the glochidia of that particular mussel. 
 
 There must necessarily be some definite ecologic relation between the mussel and 
 the fish. The bottom that is inhabited by the hickory-nut mussel must be one that is 
 frequented by the sand sturgeon during the breeding season of that mussel. Again, if 
 one were looking for the river herring, it would be reasonable to expect to find them, 
 during June at least, in places where niggerhead beds are known to exist. It is evi- 
 dent that no species of mussel could exist unless its host were of such habit as to be at 
 the right places at the right times in a sufficient number of cases to perm't first, of the 
 infection occurring, and second, of the young dropping where they can survive. 
 
 What the factors are that bring mussels and fish into proper association we can not 
 say. In the case of one species of mussel (the pocketbook) at least, it is known that the 
 gravid mussel protrudes from its shell a portion of its mantle as a long brightly marked 
 flap that waves in the water, assuming the appearance of an insect larva or other at- 
 tractive bait (p. 85). Again we have the sheepshead fish (fresh-water drum) which is 
 known to feed upon small mollusks, mussels, and the sphaeriids and univalves that live 
 on mussel beds, and which thus exposes itself to easy infection ; sheepshead, indeed, are 
 almost invariably found to be loaded with glochidia. The behavior of the pocketbook 
 is believed to be exceptional, and the sheepshead is one of a very few species of fish 
 
FRESH- WATER MUSSELS. 1 55 
 
 known to feed directly upon mussels. It is certain, however, that the fresh-water mussel 
 beds harbor quantities of other small animal life, such as insect larvae, snails, and 
 worms, and are gardens for the food of fishes (p. 119) ; in this, probably, lies the prin- 
 cipal clue to the association of fish and mussels. 
 
 Finally, an economic consideration should be emphasized. The conservation of the 
 fishes is as important to the preservation of the fresh-water mussel resources and the 
 industries dependent upon them as is the propagation and protection of mussels. The 
 disappearance, or the radical diminution in number, of certain species of fish would re- 
 sult in the complete or virtual disappearance of corresponding species of mussel. On 
 the other hand, if the growth of mussels in more or less dense beds produces conditions 
 which are favorable to the growth of fish food, and observations do so indicate, then 
 the disappearance of the fresh-water mussels would result in the diminution of the 
 food supply for fishes, and the conservation of mussels is important for the preserva- 
 tion of our resources in fish. 
 
 PARASITISM AND IMMUNITY. 
 
 It is worth while to inquire as to the effect of the glochidia upon fish. Are they 
 parasites in the same sense as tapewonns or round wonns ? Do they sap the vitality of 
 the fish, and are they accordingly to be regarded as in the nature of a disease? While 
 the relation of the glochidium to the fish can not be fully stated in the present stage of 
 investigation, it can be said that the principal effect upon the fish, at first, at least, is the 
 slight laceration of the gills caused by the attachment of the glochidium. The fish 
 quickly heals over this wound to inclose the glochidium and form a small cyst, and 
 after that there is in nearly all cases no evidence of further irritation or of material 
 detriment to the surrounding tissues, except as the cyst and glochidium are sloughed 
 off at the expiration of the proper period. 
 
 The fish feels the attachment of the glochidia; it shows that by the flirting move- 
 ments which are made as infection begins, and it is known that excessive infections of 
 young fish, at least, may cause the gills to become so lacerated and inflamed as to pro- 
 duce the death of the fish (Lefevre and Curtis, 1912, p. 165). The use of small fish is 
 avoided in experiments and operations conducted at Fairport, and as care is taken to 
 avoid excessive infections it can be said that of thousands of fish artificially infected 
 and kept under observation in experimental work at that place there has been no case 
 of death or evidently diminished vitality with evidence to implicate the glochidia as 
 cause. 
 
 After the microscopic lesion of the gill is healed over, which usually occurs in the 
 course of a day, the commercial species of mussels generally make little demand upon 
 the fish. No doubt they derive some nourishment from the fish, but this must be very 
 slight, since the young mussels, after spending two or three weeks in undergoing meta- 
 morphosis, are found to be of the same size as before they attached to the fish." The 
 demands upon the energies of the fish caused by the glochidia are probably not greater 
 than those arising from a few extra movements. 
 
 It has recently been learned that some fish acquire a certain immunity to glochidia, 
 thus being protected against too frequent repetition of infections. Reuling (191 9) has 
 
 a The mussels which grow in size while in parasitism (p. 149) are not commercial species. 
 
 9745°— 21 6 
 
156 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 found that some of the very large bass, having doubtless experienced some previous 
 natural infections, become immune after one heavy artificial infection, while small bass, 
 without previous infections presumably, require two or three artificial infections before 
 showing immunity. When immunity is acquired, the fish can not be successfully infected 
 with glochidia of any species of mussel. The period of duration of immunity is not 
 known. 
 
 An earlier significant discovery had been made by C. B. Wilson (1916, p. 341). His 
 observations and experiments showed that the fish which are most susceptible to glo- 
 chidia are those which are subject to parasite copepods (fish lice) ; that there is a definite 
 connection or fellowship of copepods and mussel parasites, so that knowing the species of 
 mussel for which a given species of fish serves as host, one may often predict what species 
 of copepod fish of that species will carry ; and finally, that the presence of glochidia on an 
 individual fish renders that fish practically or completely immune to the attacks of the 
 fish lice, and vice versa. These conclusions may be stated in another way: While 
 glochidia and copepods have essentially identical taste in fish hosts, the presence of the 
 one is antagonistic to the other. 
 
 These observations indicate that artificial infection of fish with glochidia may have a 
 positively beneficial effect upon the fish in giving i t protection against a class of parasites 
 which are pernicious in effect; for copepods are relatively large parasites which sap the 
 vitality of fish and have been known to cause serious mortalities. 
 
 The case of the sheepshead or fresh-water drum, Aplodinotus grunniens, ma}' be sig- 
 nificant. Sheepshead are found to be almost invariably loaded with glochidia upon the 
 gills, carrying infections which would be regarded as highly excessive if caused artificially 
 (PI. XVI, fig. i). They are, no doubt, greatly exposed to infection in consequence of 
 the habit of feeding upon molluscs, which they are well fitted to crush with their strong 
 grinding teeth. By carrying successfully glochidia, which they secure while devouring 
 the parent mussel, they are aiding in the propagation of the mussel which may serve them 
 as food. Indeed, the sheepshead unwittingly engages in growing its own food supply. 
 Now, of the fish which have been examined in numbers, the sheepshead is the one species 
 of fish (besides those of the sucker family, which carry neither glochidia nor copepoda) 
 which has never been found to have copepods on the gills. Its immunity from copepods 
 is now easily understood, and it may be presumed that this immunity is worth the cost 
 of almost continually carrying heavy infections of glochidia. 
 
 METAMORPHOSIS WITHOUT PARASITISM. 
 
 So generally, almost universally indeed, are fresh-water mussels dependent upon fish 
 for the completion of their development, that peculiar interest attaches to the two ex- 
 ceptions which have so far been encountered. Lefevre and Curtis (191 1) discovered that 
 glochidia of one species, the squaw-foot, Strophiius edentulus Rafinesque, may undergo 
 metamorphosis into the juvenile stage without the aid of the fish (PI. XVII, fig. 3). In 
 this mussel, as in others, the eggs when deposited in the gills are packed in a formless 
 mucilaginous matrix, but in the course of the development of the glochidia, the matrix 
 becomes changed into the fonn of many cylindrical cords, in each of which a few glo- 
 chidia are embedded. There is evidently in this case a special provision for the nour- 
 ishment of the embryo from materials supplied by the mother, so that metamorphosis 
 
FRESH- WATER MUSSELS. 157 
 
 of the glochidium is accomplished at the expense of the parent rather than of a fish. 
 Howard (1915) subsequently found that the glochidia of this species could be made to 
 attach to fish and would undergo metamorphosis in the usual way on this fish. He also 
 discovered that the glochidia of another species, a small floater, Anodonta inibecillis, 
 developed into the juvenile mussel within the gills of the parent, and that they would not 
 remain attached to fish. 
 
 It is significant that there are just a few species of mussels which diverge in two 
 directions from the general rule that fresh-water mussels undergo metamorphosis only in 
 parasitism and without evident growth in size during the process. On the one hand, 
 we have the cases just cited of change of form accomplished without parasitism, and on 
 the other the instances mentioned on page 149 of two or three species in which the larval 
 mussel increases many times in growth while still encysted upon the fish. The tendency 
 manifested by two species is toward independence of fishes or other hosts, while the 
 tendency revealed by a few others is toward a much greater dependence upon fishes. 
 The vast majority of species, including all the mussels having shells of commercial value, 
 occupy the middle ground of limited dependence upon fish; they must live upon the 
 fish, but they require little from them. The hope has been cherished that in time a 
 means would be found of supplying artificially to the glochidia of the common species of 
 useful mussels the food materials and other conditions necessary for the metamorphosis, 
 so that it might become possible to rear mussels without the use of fish. So far, how- 
 ever, failure has marked every attempt to accomplish this purpose. 
 
 JUVENILE STAGE. 
 
 At the close of the period of parasite life, the young mussel is no longer a glochidia, 
 and while it possesses the rudiments of the principal organs of the adult, it has vet to 
 undergo many changes of structure — or better perhaps, a progressive development in 
 structure — before it fully assumes the adult form and maimer of life (PI. XV, figs. 5 and 6; 
 PI. XVII, fig. 4). To the intermediate stages, or series of stages, between parasitism and 
 the development of functional sex organs the term juvenile may properly be applied. 
 The siphons or respiratory tubes, the labial palps, outer gills, and sex glands are among 
 the conspicuous features of structure acquired during this stage. 
 
 With many and probably most of the common sjiecies of mussels, the early juve- 
 nile mussel is no larger than the glochidium — in the case of the L,ake Pepin mucket slightly 
 less than one one-hundredth inch in length and slightly more than one one-hundredth inch 
 in height. Its thin mussel shell underlies the glochidial shell, and is scarcely visible until 
 after several days of growth. The most conspicuous feature of the young mussel at this 
 time is the foot, which may be protruded from the shell as a relatively long, slender, and 
 active organ of locomotion. The following description applies primarily to the Lake 
 Pepin mucket: The foot is somewhat cleft at the apex to give a bilobed appearance and 
 it is clothed with ciUa or minute living paddles, which are in rapid motion while the foot 
 is extended. The foot has also the power of adhesion to surfaces as smooth as glass; by 
 means of it the young mussel can move about rapidly or effect temporary attachments to 
 foreign objects. It is not long before the peculiar characters of the juvenile foot are lost, 
 for during the first month of independent life this organ becomes changed into the char- 
 acteristic form of the foot of the adult mussel. 
 
158 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 At a very early stage a special organ of attachment is formed in some species, espe- 
 cially among the Lampsilinise (Sterki, 1891, 1891a; Frierson, 1903, 1905; and Lefevre and 
 Curtis, 1912). This is the byssus, a sticky hyaline thread produced by a byssus gland 
 formed in the middle line of the rear portion of the lower side of the foot. In the wash- 
 board, Quadriila heros, a very few days after leaving the fish there is apparent a tough 
 mucuslike secretion by means of which the juvenile mussel may anchor itself. The 
 byssus may serve to anchor the mussel by attachment to foreign objects, but its func- 
 tion needs to be more definitely ascertained. Juvenile nmssels are sometimes captured 
 in considerable numbers, owing to the sticky thread becoming attached or entangled on 
 the crowfoot hooks or lines or on aquatic vegetation drawn into the boat. While such 
 observations suggest the function of keeping the mussel from being carried away by 
 the current, nevertheless the organ is well developed in young Lake Pepin muckets 
 which are observed to bury themselves deeply in the bottom. The byssus is retained a 
 varying length of time in different species and in different individuals of the same species. 
 The byssus has been seen in young muckets, Lampsilis ligamentina, late in the second 
 year of free life and rarely in adults of Plagiola donacijormis. The species of mussel 
 observed with byssus are listed below. 
 
 SPECIES OF MUSSELS THE JUVENILES OF WfflCH ARE KNOWN TO HAVE A BYSSUS. 
 
 I/ampsilis alata, pink heel-splitter. 
 
 L. anodontoides, yellow sand-shell. 
 
 L. capax, pocketbook. 
 
 L. ellipsiformis. 
 
 L. fallaciosa, slough sand-shell. 
 
 L. gracilis, paper-shell. 
 
 L. iris, rainbow-shell. 
 
 I<. laevissima, paper-shell. 
 
 L. ligamentina, mucket. 
 
 L. luteola, Lake Pepin mucket. 
 L. recta, black sand-shell. 
 L. ventricosa, pocketbook. 
 Obovaria ellipsis, hickory-nut. 
 Plagiola donaciformis. 
 P. elegans, deer-toe. 
 Quadrula ebenus, niggerhead. 
 Q. plicata, blue-point. 
 
 The shell formed during the first month (more or less) of development possesses 
 certain peculiar characteristics — besides having a relatively low lime content and being 
 transparent, it bears on its surface certain relatively high ridges, knobs, etc. (PI. XX). 
 The cause or the meaning of these nicely formed ridges is unknown, but the pattern of 
 sculpture of the early juvenile shell is characteristic for the species. Though all the 
 remainder of the shell be perfectly smooth, the "urabonal sculpture," as it is called, can 
 be made out in well preserved adult shells of most species, and their markings are given 
 significance in the classification of mussels. 
 
 We need not concern ourselves here with the details of development of the internal 
 organs, except to say that a considerable elaboration of structure must ensue before 
 the mussel is prepared to assume its culminating function — the reproduction of its 
 kind. The first act of breeding marks the close of the juvenile period, and this occurs 
 in the Lake Pepin mucket two years after the beginning of the juvenile stage, or early 
 in the third summer of life counting from the deposition of the egg in the gill of the 
 mother. In some species of mussels, those of small adult size, or those possessing very 
 thin shells, sexual maturity comes at an earlier age, but in most species of mussels it 
 undoubtedly occurs later. (See p. 137.) 
 
 The maximum sizes, at various ages, attained by Lake Pepin muckets under obser- 
 vation, are shown in the following table: 
 
FRESH-WATER MUSSELS. 
 Table 21. — Maximum Size ok Young Lake Pepin Muckets at Various Ages. 
 
 159 
 
 Age. 
 
 I^ength. 
 
 Age. 
 
 Length. 
 
 
 Millimeters. 
 0.35 
 •5 
 
 4-2 
 
 Inches, 
 
 0. 01 
 .02 
 ■ 17 
 
 
 Millimeters. 
 13.0 
 32-3 
 58.3 
 
 Inches. 
 
 
 5 months 
 
 
 
 End of second growing season 
 
 
 
 
 This species displays perhaps the most rapid growth of any commercial mussel, 
 although it is surpassed in this respect by some of the noncommercial floaters and 
 paper-shells. The maximum size attained in the second year by mussels of several 
 other species reared at the Fairport station is given in Table 22. 
 
 Table 22. — Size and Age of Mussels Reared at Fairport Station. 
 
 Species. 
 
 Lampsilis ligamentina, mucket 
 
 Lamp-silis anodontoides, yellow sand-shell . , 
 Obliquaria refiexa, three-horned warty-back 
 
 Plapiola donaciformis 
 
 Quadrula plicata, blue-point 
 
 Quadrula undata, piy-toe 
 
 Obovaria ellipsis, hickory-nut 
 
 Length. 
 
 MiUimeters. 
 20. o 
 41.0 
 16. o 
 20. o 
 13- S 
 15-8 
 II. 4 
 
 Inches. 
 
 Approxi- 
 mate age. 
 
 Yean 
 
 Remarks. 
 
 Accidentally reared. 
 Intentionally reared. 
 Accidentally reared. 
 
 Do. 
 
 Do. 
 
 Do. 
 
 Do. 
 
 Much remains to be learned regarding the habits and habitats of the juvenile mus- 
 sels of many species. The study is somewhat difficult, because mussels in the juvenile 
 stage are usually hard to find. This is the experience of all collectors, although rich 
 finds of larval mussels are occasionally made in particular locations (Howard, 1914, 
 pp. 34 and 47). In 1914 Shira collected 1,394 juveniles representing 16 species in Lake 
 Pepin, and 92.9 per cent were taken upon sand bottom where there was scattering vege- 
 tation. This figure can not, however, be taken as an index of preference for that par- 
 ticular sort of habitat, since 86.2 per cent were taken at one station. Isely (191 1 , p. 78) 
 made a collection of 32 juveniles comprising 9 species, 6 of which were represented in 
 the Lake Pepin collections, but Isely's specimens were all taken in fairly swift water, 
 I to 2 feet deep, and from a bottom of coarse gravel. In rearing young mussels, prin- 
 cipally Lake Pepin muckets, in ponds at Fairport, the best success has been attained 
 on prepared bottom of sand; yet when Howard reared Lake Pepin muckets in a crate 
 floating in the river, silt accumulated to a considerable depth, and the juvenile mussels 
 were sometimes found deeply submerged in the soft mud ; nevertheless, more than 200 
 young mussels survived the season in a very small crate, and excellent growth was made. 
 
 After the byssus is shed the young mussels often bury themselves in the bottom 
 more deeply than do adults. They are inclined to travel considerably at this stage, 
 but the rate of movement and the distances covered are less than might be thought 
 from observation of the conspicuous and apparently fresh tracks behind the young mus- 
 sels. It has been found that the tracks will retain the appearance of freshness for sev- 
 eral days ; hence the trail which one might at first suppose to have been made in a few 
 hours may represent a journey covering a considerable period of time. Clark observed 
 a young mussel which made forward movement every 10 seconds, each movement being 
 
l6o BULLETIN OF THE BUREAU OF FISHERIES. 
 
 followed by a brief rest period. A young hickory-nut mussel was observed to travel 
 O.I meter (about 4 inches) in 29 minutes. The rate of travel of sand-shells is much more 
 rapid. 
 
 Because of their small size and delicate shell the early juvenile mussels are doubt- 
 less the prey of numerous enemies. Turbellarian and chaetopod worms are known to 
 devour them. No doubt they are sometimes eaten by fish and aquatic animals, such as 
 are accounted enemies of larger mussels, yet there has been found little evidence of 
 serious depredations upon young mussels by such animals. Perhaps the most serious 
 natural mortality among juvenile mussels occurs from falling upon unfavorable bottoms 
 or from the effects of currents, especially in times of flood, which may draw the rela- 
 tively helpless mussels into environments in which they have small chance for survival. 
 It may be expected, too, that the repeated dragging of crowfoot bars over favorable 
 mussel bottoms works damage to juveniles both by injuries directly inflicted and by 
 pulling them from the bottom and exposing them to the action of currents from which 
 they had previously found protection. 
 
 ARTIFICIAL PROPAGATION. 
 
 PRINCIPLE OF OPERATION. 
 
 As the previous account of the Ufe history of fresh-water mussels has shown, the 
 mussel not only deposits great numbers of eggs but nurtures them in brood pouches 
 within the protection of her shell. There is not, as in fish, a great wastage of eggs and 
 larvae in the very earliest stage of development. There exists, therefore, no necessity 
 for artificial aid to effect fertilization ; that is, to bring the male and female reproductive 
 elements together. Nature's own provisions have adequately provided for the bringing 
 of enormous numbers of each generation of offspring to the glochidium stage. It is 
 after this stage is attained that the greatest mortality occurs; the great abundance of 
 glochidia produced by • each female is, indeed, evidence that enormous losses are to 
 occur subsequently, and observation indicates that the critical stages are, first, when the 
 glochidia are liberated from the parent to await a host, and, second, when the juvenile 
 mussels are dropped from the fish that serves as host. 
 
 The artificial propagation of mussels as now practiced aims to carry the young 
 mussels through the first great crisis. Its object is to insure to a large number of 
 glochidia the opportunity to effect attachment to a suitable fish. Under present 
 conditions the operations can be conducted extensively and economically only in the 
 field. The procedure in brief is to take fish in the immediate vicinity of the places to 
 be stocked, infect them with glochidia of the desired species of mussels, and liberate 
 them immediatel}'. Artificial propagation, then, as applied to fresh-water mussels, is 
 a very different sort of operation from that employed in the propagation of fish, 
 although it is no less directly adapted to the conditions and needs of the objects to be 
 propagated. 
 
 METHODS. 
 
 In each field the operations are conducted under the immediate direction of a qual- 
 ified person who may be either a permanent or temporary employee of the Bureau work- 
 ing under the Fairport station. The fishing crew is comprised of three or four local 
 fishermen, or laborers, temporarily employed. 
 
FRESH-WATER MUSSELS. l6l 
 
 The equipment for seining and handling the fish consists of a motor boat, one or 
 two flat-bottomed rowboats, seines or other nets, including small dip nets, tanks, 
 buckets, etc. The motor boat is used to cover the various fishing grounds as rapidly 
 as possible to distribute the infected fishes, and to move the outfit from place to place 
 as it becomes advisable or necessary to extend the field of operations. The rowboat is 
 employed in the actual work of seining and handling the fish. If the fish are taken in 
 very large numbers it is convenient to have one or two tanks, similar to the ordinary 
 4-foot galvanized stock tanks and equipped with handles. Under ordinary conditions, 
 tubs serve very well, especially if the fish have to be transported by hand for some dis- 
 tance, as is the case when the fish are taken in rescue work from land-locked ponds or 
 lakes. At times, when the field of operations is at some distance from a place where 
 living and sleeping accommodations can be secured, a camping outfit, or a house boat, is 
 used for quartering the crew. The head of the party must be provided wdth a dissecting 
 microscope, a magnifying hand lens, and simple dissecting instruments. 
 
 Before an infection can be made, it is first necessary to obtain a supply of glochidia 
 of the desired species of mussels. In localities where commercial shelling is actively prac- 
 ticed this can be done by visiting the shellers' boats and examining the catch for freshly- 
 taken gravid mussels. If it is desired to use the glochidia at once, the brood pouches 
 are immediately cut from the females and placed in water; btit if it is desired to use them 
 over a period of several days, the gravid shells are purchased and the glochidia removed 
 as needed. In locations where shells are scarce, or where little or no commercial shelling 
 is done, it is sometimes necessary to hire a sheller to procure the mussels. 
 
 The fish are next sought by means of seines or nets, and when secured are sorted and 
 transferred to the tanks or tubs; the fish that are not required for purposes of mussel 
 propagation are immediately liberated in suitable waters. When the containers are 
 comfortably filled with fish, overcrowding being avoided, the brood pouches of one or 
 more mussels, as necessary, are cut out and opened with scissors or scalpel and the 
 glochidia are teased out in a small pail or other container f ropi which they are poured into 
 the tanks with the fish. Figures i to 4, Plate XVIII, show the seining and infection 
 operations in the field. 
 
 The experienced operator can usually tell at a glance whether or not the glochidia 
 are sufficiently ripe for infection. If they freely separate when removed from the brood 
 pouches and placed in a dish of water, it is usually a sign that a sufficient degree of ripe- 
 ness has been obtained. If, however, they adhere in a conglutinate mass and can be 
 separated only with difficulty, it is certain indication that they are unsuitable for 
 infection; examination with a hand lens in such case will show also that the glochidia 
 are still inclosed in the egg membrane, thus revealing their immaturity. If the glochidia 
 are fully developed, one can readily determine if they are alive and active by dropping 
 a few particles of salt or a couple of drops of fish blood into a small dish containing some 
 of the glochidia. It is a sign of maturity and vitality if the valves begin to snap together 
 as the salt or blood diffuses through the water. 
 
 After being removed from the brood pouches the life of the glochidia is usually 
 rather short, but it is possible to keep them alive a day or two if the water in which they 
 are retained is changed at frequent intervals and not permitted to become too warm. 
 
 The operator is guided by his experience as to the quantity of glochidia to be placed 
 with a given lot of fish and as to the length of the infection period. The water may be 
 
l62 
 
 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 stirred from time to time in order to keep the glochidia in somewhat even suspension, 
 but in most cases the movements of the fish themselves insure a circulation of the water 
 and a general distribution of the glochidia. At intervals individual fish are taken by 
 hand or small dip net, and the gills examined with a lens; when, in the opinion of the 
 operator, a sufficient degree of infection has occurred, the fish are placed at once in 
 open waters, or transferred to other containers for conveyance to a place suitable for 
 their liberation. The rapidity with which infection takes place depends upon a variety 
 of conditions, such as temperatures of water, kind and size of fish, and activity of glochi- 
 dia. Ordinarily a period of from 5 to 25 minutes is sufficient to insure an optimum 
 infection. The infection time is usually shorter in warm water than in cold. As basis 
 for approximate computation of the number of glochidia planted, several average-sized 
 specimens of each species of fish infected are killed and the gills removed for subsequent 
 counts of the glochidia attached. The counting is done by the foreman with the aid of a 
 microscope and usually in the evening after the close of the field operations of the day. 
 The number of glochidia per fish of each species having been determined by the count of 
 representative examples, and the numbers of fish of the species being known, the entire 
 number of glochidia planted on a given lot of fish is easily computed. The data in detail 
 are promptly recorded on form cards pro^'ided for the purpose. The count of total 
 glochidia planted is of course only approximate, but the method of count and computation 
 described is as accurate as the conditions of operation permit, and it is as precise as the 
 methods of count generally practiced in fish-cultural operations. In the long run, the 
 actual errors on one side and the other must approximately balance. 
 
 That degree of infection which employs the fish to best advantage in mussel propa- 
 gation, without doing appreciable injury to the host, is termed the "optimum infection." 
 It varies with the species of mussel and with the kind and the size of the fish. Table' 23 
 gives illustrative instances. 
 
 Table 23. — Optimum Infection for Certain Species of Mussel on Several Species of Fish. 
 
 Spwcies of mussel. 
 
 Fish host. 
 
 Number of 
 
 Scientific name. 
 
 Common name. 
 
 Species. 
 
 Size in 
 
 inches. 
 
 glodiidia 
 on fish. 
 
 
 I^ake Pepin mucket 
 
 B'ack bass 
 
 8 
 8 
 8 
 5 
 <; 
 6 
 
 16 
 8 
 
 14 
 
 
 Do 
 
 
 White bass 
 
 
 Do 
 
 do 
 
 V, all-eyed pike 
 
 Bhiei:ill 
 
 
 Do 
 
 do 
 
 
 Do 
 
 do 
 
 Crappie 
 
 
 Do 
 
 do 
 
 
 
 
 
 
 
 
 Mucket 
 
 Black bass 
 
 
 
 Pimple-back 
 
 Channel catfish 
 
 1, 200 
 
 
 
 
 Incidental to the field work in mussel propagation, valuable results are frequently 
 gained in the reclamation of fish from the overflowed lands bordering the various rivers. 
 All fishes rescued in connection with propagation work, whether suitable or unsuitable 
 for infection, are liberated in the open waters, and under such circumstances the value 
 of the fish thus saved in large measure recompenses for the cost of the mussel propaga- 
 tion work. 
 
 The operations of mussel propagation as just described serve to carry the young 
 mussels through the most critical stage of the life history — to give to thousands the 
 
Bull. U. S. B. F., 1919-20. 
 
 Plate XVIII. 
 
 l-iL.. I.— btiiiiiiji fish from uverfiow water for infection with glochidia of mussels. 
 
 Fig. 2. — Seining fish in Lake Pepin for mussel propagation. 
 
 Fig. 3. — Transferrin!: fish to infectiun tank. Foreman in 
 boat is pouring the glochidia from a can into the tank. 
 
 Fig. 4. — Sorting the fish for infection with glochidia. 
 
Bull. U. S. B. F., 1919-20. 
 
 Plate XIX. 
 
 Fig, 1. — A floating crate containing fuur baskets in which fish infected with glochidia were placed and young mussels reared. 
 
 (Compare PI. V, lig. 3.) 
 
 1*1G. 2. — Lifting one of the Ijuskttb from ihe trale fur exaniiuatiun and cleaning. 
 
FRESH- WATER MUSSEIvS. 163 
 
 chance of life that would ordinarily fall only to dozens. As previously pointed out 
 (p. 151), an extensive series of observations of fish reveals the fact that but few are 
 naturally infected with mussels and these usually in slight degree. The chance that a 
 large proportion of the glochidia discharged by any mussel will become attached to a 
 proper host is slight, and it is only because nature is prodigal in the production of glochi- 
 dia that the various species of mussels can maintain their numbers under natural condi- 
 tions. With the disturbance of natural conditions by the active pursuit of a commercial 
 shell fishery, nature's fair balance is destroyed, and some compensatory artificial aid to 
 the propagation of mussels is rendered necessary. 
 
 It is not presumed that all the vicissitudes of mussel life are removed by the bringing 
 together of fish and mussel. Nature undoubtedly exacts heavy tolls at other stages. 
 Many of the young mussels on being liberated from the fish will fall in unfavorable 
 environments and meet an early death, while those that survive the earliest stage of 
 independent life may still be subjected to numerous enemies throughout the juvenile 
 period at least. Nevertheless, glochidia of certain species can be planted in such large 
 numbers and at such slight cost that, after making due allowance for an extraordinary 
 subsequent loss, substantial returns can be expected. That such results do obtain is 
 indicated both by experiments to be later described (p. 166) and by common experience 
 
 MUSSEL CULTURE. 
 
 The rearing of young mussels in tanks, in ponds, or (if under conditions of control) 
 in the river, may properly be termed "mussel culture," as distinguished from "mussel 
 propagation," which, as we have seen, consists in bringing about the attachment of 
 glochidia to fish and liberating the fish in public waters. For several years experiments 
 in mussel culture have been carried on by the Bureau of Fisheries at Fairport and else- 
 where, with a view both to securing information regarding the life history of mussels 
 and to testing experimentally the possibilities of culture as a public measure of conserva- 
 tion or as a field for private enterprise. At first little success attended these efforts. 
 It was found that the mussels could readily be carried through the parasitic stage, but 
 that soon after leaving the fish hosts they perished. Apparently there was something 
 inimical to the young mussels in the artificial conditions of aquaria, tanks, or ponds, 
 although these might be supplied with running water derived from the natural habitat 
 of mussels. 
 
 The first reported rearing of mussels under control was accomplished with the 
 Lake Pepin mucket in a crate floating in the Mississippi River (Howard, 191 5). Ex- 
 periments initiated by the senior author in the ponds at Fairport, Iowa, about the same 
 time were also successful with the same species. Subsequently broods of the Lake Pepin 
 mucket have been reared from year to year by various methods. Less consistent results 
 have been obtained with the following river mussels: The pocketbook, LampsUis ventri- 
 cosa, the pimple-back, Quadrula piistulosa, and until recently the yellow sand-shell, 
 LampsUis anodonioides, and the mucket, LampsUis ligamentina. Apparently the condi- 
 tions required for rearing the Lake Pepin mucket are less difficult to meet under control 
 than is the case with the other species mentioned. The reason is, doubtless, that Lamp- 
 sUis luteola, being a lake-dwelling species as well as an inhabitant of rivers, is adapted to 
 more varied conditions. 
 
 The methods employed in rearing mussels may be designated as follows: (i) The 
 floating crate with closed bottom (chiefly used in rivers) ; (2) the floating crate with open 
 
1 64 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 bottom (chiefly used in ponds) ; (3) the bottom crate ; (4) pen with wooden or box bottom ; 
 (5) concrete ponds ; (6) earth ponds ; (7) troughs of sheet metal, wood, or concrete tanks, 
 and aquaria. 
 
 (i) The floating crate with closed bottom was devised to meet the special conditions 
 of a large river where the level is subject to considerable change, where excessive turbidity 
 frequently prevails, and where there is a decided current. To prevent the washing away 
 of the microscopic mussels, while permitting the passage of water and food through the 
 crate, the crates are constructed of fine-meshed (100 mesh to the inch) wire cloth on a 
 wooden frame. The form of the crates and the manner of using them may be under- 
 stood from the illustrations (PI. XIX, figs, i and 2). They are described in more detail 
 in a forthcoming paper by A. D. Howard. A plant of young mussels is obtained by 
 placing infected fish in the crate and removing them after they are freed of the mussels. 
 The results with the floating crate have been quite satisfactory with the Lake Pepin 
 mucket, and a few yellow sand-shells have also been obtained in them. Other river 
 mussels have failed to develop beyond early stages. Good results with river mussels 
 would be expected, but it is found that even with the crate floating in the river, the 
 conditions within it are not those of the natural habitat of the mussel on the clean 
 current-swept bottom of the river. No one has yet devised a container to employ under 
 such conditions that would fully answer the requirements. 
 
 (2) The floating crate with open bottom has been used in artificial earth ponds. 
 The bottom is actually closed to fish, though open to juvenile mussels, since it is made of 
 coarse-mesh wire cloth (i K-inch mesh). The infected fish are kept inclosed until freed of 
 glochidia, which fall through the wire to the bottom of the pond. To obtain the mussels 
 when developed, the water is temporarily drawn from the pond. Good results have 
 been obtained with the Lake Pepin mucket only. 
 
 (3) The bottom crate has been used in studies of growth of larger mussels, by 
 Lefevre and Curtis (191 2, p. 180), Coker, and others, and in experiments in pearl culture 
 by Herrick (Coker, 1913). It has recently been adapted for the purpose of retaining 
 infected fish and securing plants of early postparasitic stages of mussels. The crate 
 tests on the bottom of the pond. It may have either a solid bottom or one of screen 
 wire which, of course, sinks a little way into the mud covering the bottom of the pond. 
 
 (4) The pen of galvanized netting with wooden floor is adapted to quiet water 
 without current. The pen, having walls of wire cloth that extend from the bottom to a 
 safe distance above the surface of the water, allows the fish to seek their own range of 
 depth and permits the mussels that fall from the fish to remain close to the bottom of the 
 pond or lake, as is natural for them. The mussels are collected by raising the wooden 
 bottom at the end of the growing season. Excellent results have been obtained in Lake 
 Pepin with the Lake Pepin mucket. In the most successful experiment more than 
 11,000 living young were secured in one crop in a pen 12 feet square. These were 
 liberated from 79 fish which had been artificially infected (Corwiu, 1920). 
 
 (5) Concrete ponds having vertical sides have been planted in the usual way and 
 the fish removed with a seine after the mussels have been shed. Some 50 examples 
 of a river-inhabiting species, the pimple-back, Quadrula pustidosa, were reared to the 
 age of 4 years in one experiment, but other trials with this species have failed. The 
 usual consistent results have been secured with the Lake Pepin mucket. 
 
 (6) Earth ponds with devices for control of depth and water supply have been 
 stocked with mussels by introducing infected fish. As a rule the fish are not removed 
 
FRESH-WATER MUSSELS. 
 
 165 
 
 until the end of the season when the pond is drawn. The Lake Pepin mucket in con- 
 siderable numbers have been reared in earth ponds. A few pocketbook mussels, L. 
 veniricosa, were obtained after a recorded plant in a pond of modified type, having earth 
 bottom. but wooden sides. Mussels of several other species have been found in ponds 
 f 10m accidental plantings. The sporadic occurrences of young mussels in the first ponds 
 and in the reservoir constructed at the Biological Station at Fairport, Iowa, are of 
 interest as showing how, through parasitism upon fish, many species of mussel will 
 quickly invade new waters. It is significant that none of the species which have intro- 
 duced themselves abundantly into these ponds are commercially valuable. Apparently 
 the commercially useless mussels are more easily and abundantly distributed by natural 
 means than the useful ones. A list of the species noted, with additional data, is com- 
 prised in the following table (cf . PI. XX) : 
 
 Table 24. — Mussels Recorded from Ponds at the Fairport Station. 
 
 Scientific name. 
 
 Common name. 
 
 Number or frequency. 
 
 Length in 
 millimeters. 
 
 Anodonta corpulenta Cooper 
 
 Anodonta suborbiculata Say « 
 
 Anodonta imbecillis Say 
 
 Arcidens conf ragosus Say " 
 
 LampsiJjs ligamentina Lam 
 
 Lampsilis (Proptera) alata Say 
 
 Lampsilis (Proptera) capax Green. . . 
 Lampsilis (Proptera) Isevissima Lea. 
 
 Lampsilis subrostrata Say f^ 
 
 Lampsilis gracilis Barnes , 
 
 Lampsilis parva Barnes '^ , 
 
 Obliquaria reflcxa Rafinesque 
 
 Plagiola donaciformis Lea , 
 
 Quadrula plicata Say , 
 
 Quadrula undata Barnes 
 
 Strophitus edentulus Say ^^ , 
 
 Symphynota complanata Barnes 
 
 Obovaria ellipsis Lea , 
 
 Floater 
 
 Paper-shell 
 
 --..do 
 
 Rock pocketbook. 
 
 Mucket 
 
 Pink heel-splitter. , 
 
 Pocketbook 
 
 Paper-shell 
 
 Abundant . 
 
 Abundant. 
 
 7 
 
 7 
 
 Paper-shell. . 
 
 Three-homed warty-back . 
 
 Deer-toe 
 
 Blue-point 
 
 Pig-toe 
 
 Squaw-foot 
 
 White heel-splitter 
 
 Hickory-nut 
 
 Abundant. 
 
 do 
 
 do 
 
 do 
 
 Abundant . 
 
 60-90 
 67.4 
 a-48 
 
 39-49 
 6-20 
 
 69. s 
 
 49- S 
 
 37-90 
 
 8. 43 
 
 9. 1-71 
 
 5-7-27 
 
 16 
 
 2.6-30 
 
 13-5 
 
 IS- 8 
 
 6a- X 
 
 64-91 
 
 11-4 
 
 ^ Uncommoa in the river. 
 
 (7) Experiments have also been made with various containers of small dimensions 
 which are usually supplied with running water- Such are the glass aquarium and the 
 tank or trough which may be made of wood, concrete, or sheet metal- Of these the one 
 most used for experimental rearing of mussels at Fairport, Iowa, has been the trough of 
 sheet metal painted with asphaltum. A special arrangement for water supply is em- 
 ployed. The water is not taken directly from the main reservoir, but is drawn from the 
 surface of a pond containing vegetation ; in some cases it is also strained through cloth. 
 In this way water is obtained that is very clear and probably free to a large extent from 
 such small animals of the bottom as would prey upon the young mussels- The Lake 
 Pepui mucket, the river mucket, and the yellow sand-shell have been reared through the 
 first year in such troughs- The experiments are of such importance as to merit detailed 
 description. The following account is based upon a report of F- H- Reuling, who first 
 assisted in the experiments and later was charged with their conduct. (See also Reuhng, 
 1919-) 
 
 The experiments were conducted in a series of eight galvanized iron troughs, placed 
 at a sufficiently low level to receive a gravity supply of water from pond iD. This pond 
 was supplied by gravity from the reservoir which received its supply direct from the 
 Mississippi River through the pumping plant- The water in pond iD remained com- 
 paratively clear throughout the season, and this was one of the primary considerations 
 
l66 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 it) locating the troughs. The troughs were 12 feet long, i foot wide, and 8 inches deep, 
 painted with asphaltum, and each had its independent inflow from a common screened 
 supply pipe in the pond. The bottom of each trough was covered with fine sand to a 
 depth of about one-half inch. 
 
 Records were kept of the progress of the larval mussels through the process of devel- 
 opment, and when they had reached that stage when they were ready to drop from the 
 fish, counts on the fish gave a close approximation of the number dropped in the trough. 
 
 The results of the experiments the first season were quite meager, as only 7 young 
 of the Lake Pepin mucket, Lampsilis luieola, varying from 6 mm. to 17.8 mm. in length, 
 and 4 of the mucket, L. ligamenHna, with an average length of 2.6 mm., were reared. 
 However, in case of the mucket the results were very encouraging, as it marked the first 
 instance of juveniles of this species being artificially reared to this size. 
 
 During the season of 191 8 greater results were obtained with the Lake Pepin mucket, 
 the young mussels being successfully reared in four troughs. In one trough a count of 
 746 was obtained. The experiments with ligameniina yielded negative results, though 
 a lack of glochidia for infection greatly handicapped the work with this species. 
 
 The results in 191 9 were still more gratifying. Young Lake Pepin muckets were 
 obtained in each of five troughs planted with this species. In one trough 2,008 were 
 counted at the end of the season, these little mussels varying in length from 9 mm. to 
 17.5 mm., the growth comparing very favorably with that made by the young of this 
 species in their natural habitat. In a trough devoted to the river mucket, L. ligamentina, 
 a total of 565 were reared. These little mussels varied in length from 5 mm. to 8.5 mm. 
 In a trough planted with the yellow sand-shell a count of 2,006 was obtained at the end 
 of the season, the young mussels varying in length from 5.5 mm. to 12 mm. The result 
 of this experiment is highly interesting, in that it is the first record of the artificial rearing 
 of this very valuable species in any quantity. 
 
 The 746 young luteola reared during the summer of 1 91 8 were carried over the winter 
 in a shallow crate bottom 5 feet square and 8 inches deep, submerged in one of the earth 
 ponds. During the summer of 191 9 an inventory of the crate bottom gave a count of 
 238 young mussels, a survival percentage of about 32 per cent. 
 
 The method of artificial rearing of young mussels, as detailed above, denotes a 
 distinct departure from the methods previously used and gives the operator complete 
 control of conditions throughout. The results of the experiments have been such as to 
 justify the employment of the method on a much larger scale in future, and plans are 
 under way for materially increasing the facilities and equipment. Certain phases of the 
 work need further study and amplification. Additional information on the possible 
 enemies of the young mussels in the troughs is needed; a study of their food should be 
 made; it should be learned if artificial feeding is practicable; and further experiments 
 should be made to determine the most favorable bottom material for the troughs, 
 whether fine sand alone, or sand with a slight admixture of silt, etc. The present indi- 
 cations are that fine sand is the most desirable bottom material. 
 
 In summary of the topic of the culture of fresh-water mussels, it may be stated that 
 the results of many experiments conducted under diverse conditions demonstrate that 
 the valuable Lake Pepin mucket can be reared in quantities, under conditions of control. 
 Sufficient success has been attained with other species to warrant confidence that, with 
 them also, methods of securing constant results will be found. 
 
Bt'i.i.. U. vS. B. F., 1919-20. 
 
 Plate XX. 
 
 |g^ ^^ 
 
 |fl|b flQ^ VB ^^Ir 
 
 Juveniles of 20 species of mussels found in the artificial ponds at the U. S. Fisheries Biological 
 Station within two years from the time of construction of the ponds. Reading from left to right 
 these are; 
 
 Top row: Anodonta imbccillis, Anodauta corpulenta, Anodonia suborbiculata, Arcidcns confragosus. 
 
 Second row: Strophitits edentulus .Symphynota complanaia, Lampsilis alata. Lamp si lis laciisiiina. 
 
 Third row: Lampsilis capax, LarnPsilis gracilis, Lampsilis reitlricosa. Lampsihs luteola. 
 
 Fourth row: LamPsilis subroslrata, Lampsilis Parva. Lampsilis ligatnentina. Oborana ellipsis. 
 
 Fifth row: Plagmla donatijormis. Oblig-iiarta reflexa, Quadrnla plicata, Quadrula undata. 
 
 All reproduced natural size excepting the two right-hand figures in top row which are reduced 
 one-half. (Photographed by J. B. Southall.) 
 
Bull. U. S. B. F., 1919-20. 
 
 Plate XXI. 
 
 Ant(iri©r ^ 
 
 retractor mus&fc 
 Antarior 
 adductor mu&cU' 
 Trotractor tnusclii; 
 fosition 0/ mouth' - 
 (bacK batwaan / 
 Labial palp^) / 
 
 OuIerUft labial palp 
 Inner U j 1 lals.al palp Visceral mass 
 
 Lunula 
 
 Uefl manlle- 
 
 fg^I*&rior r<;^tracJor mui>c\<i. 
 fQ^Xt^riotr adductor muaclc 
 
 ^wura-brantniai 
 chamber 
 
 RigUt mantle, 
 Owtsr ri^nt ^tll 
 inn<ir right ^ill 
 inner le- j t ^til 
 
 Fig. I. — The structure of a fresh-water mussel. (Based upon drawing of white heel-splitter. Sytnphynota tomManata. 
 
 from Lefevre and Curtis, 1912.) 
 
 Fig. 3.- 
 
 -A tool which, if employed with care, may be used for partially opening livinjj mussels for examination cf conditions 
 
 within the shell. 
 
PART 3. STRUCTURE OF FRESH-WATER MUSSELS. 
 INTRODUCTION. 
 
 A general description of the structure of fresh-water mussels may assist those 
 without special knowledge of the anatomy of mussels to follow intelligently the account 
 of the natural history, propagation, and development which it has been the primary 
 purpose of this report to give. It may also serve as a helpful introduction to persons 
 with limited technical knowledge who wish to make original observations or experi- 
 ments concerning the habits and growth of mussels. It has been the special purpose 
 of the authors to point out the more conspicuous gaps in our knowledge of the behavior 
 of mussels and their relations to the environment. Many of these gaps can readily be 
 bridged by any who will take the trouble to observe painstakingly and repeatedly the 
 conditions under which fresh-water mussels live in the streams, lakes, or ponds in one's 
 own neighborhood. The species subjected to observation or experiment should of 
 course be definitely known, but identifications of species can always be obtained of 
 Government agencies or from independent specialists in the study of mollusks. 
 
 In most localities some species of mussels are easily obtainable and observable 
 in nature or in aquaria. In rivers of the Atlantic States, generally, the common mussel 
 is the Unio complanatus. The more familiar forms in lakes and alongshore in streams 
 of the Mississippi Valley and the Great Lakes drainage are the fat mucket Lampsilis 
 luieola, " and some of the floaters of the genus Anodonta. Closely related to the fat 
 mucket is the mucket, Lampsilis ligamentina, which is common in the Mississippi and 
 its tributaries as well as in many streams discharging into the Great Lakes. As a rep- 
 resentative type in the simplicity of its fonn and of the sculpture and markings of its 
 shell, the mucket serves as the basis of the following general description, except 
 as explicit qualifications are made. With more or less modification, the account may 
 be applied to whatever species is most readily available. The functions of the organs 
 described will generally be briefly indicated. 
 
 Let it be understood first that a living mussel is commonly partly embedded in the 
 bottom, with the forward end directed obliquely downward and the rear end upward. 
 The "mouth" as understood by fishermen is in reality the double siphonal opening 
 in the hinder part of the mussel; the true mouth, through which food is taken into the 
 body, is a very small and scarcely discernible opening in the part of the soft body which 
 is farthest away from the exposed end of the mussel. 
 
 The fresh-water mussels difi'er markedly in structure from the oyster or the pearl 
 oysters which pertain to a different order of lamellibranchs. They are likewise far 
 removed from the sea mussels, which lie in a third order. Their nearer relatives are 
 the sea clams and the small Cyrenians of the rivers; the sea clams and the little clams 
 (Cyrenians) of the rivers are more closely allied to each other than to fresh-water 
 mussels. The pearly fresh-water mussels or Naiades comprise two great families, 
 
 " The best commercial type of the mussels of this species is also known as the "Lake Pepin mucket." 
 
 167 
 
1 68 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 the Unionidae, with which the present paper is concerned, and the Mutelidae of South 
 America and Africa. The Mutelidae differ from the Unionidee in some particulars of 
 structure, especially in the form of teeth on the shell and in the form of larva, which 
 is a lasidium, instead of a glochidium such as has been described above. 
 
 THE SHELL. 
 
 The shell is composed of two parts very similar in exterior aspect, but generally 
 differing from each other in interior form. Each portion is called a valve, and the 
 two valves are hinged together. 
 
 EXTERNAL FEATURES. 
 
 In form the shell is roughly elliptical, evenly rounded in front, but more or less 
 angular behind. The lower or ventral margin is generally evenly rounded, but may be 
 arched inward just behind the middle, especially in shells of females. The dorsal or hinge 
 margin is rather straight except for the rounded prominence on each valve just in front 
 of the middle of the back; this knob, or arched portion of each valve, is called the 
 umbo. Where the umbones of opposite valves approximate each other they are more 
 or less elevated above the surrounding shell surface to form the beaks. The beaks in 
 many species, though not in the mucket, are beautifully sculptured with coarse or fine 
 ridges in the form of single or double loops. With the river mucket, beak sculpture 
 is entirely wanting, while it can be seen clearly in Symphynota complanata (PI. XX, 2d 
 row, 2d fig). Almost every species, if good specimens are available, show some form of 
 beak sculpture;" commonly, however, in older specimens the beaks are so much eroded 
 that the ridges are hardly, if at all, apparent. 
 
 In some streams scarcely a single example can be found with the beaks preserved; 
 in other waters erosion occurs less commonly and the beak markings can be observed 
 even in some of the large examples. 
 
 In some cases the resting periods of winter have left distinct marks by color or 
 otherwise on the shell, so that rings or zones corresponding to the growth of each year 
 are recognizable. The rings of annual growth are not, however, generally recognizable 
 on shells having a dark-colored exterior surface. It is also observed that such rings 
 may result from other causes than the interruption of growth by the severity of winter. 
 (See p. 132.) 
 
 A conspicuous feature of the shell is the prominent ridge, which extends from the 
 beaks backward and downward to the posterior ventral angle of the shell. A somewhat 
 similar ridge characterizes almost every species of mussels. 
 
 The exterior color of the shell is a most variable character. Generally speaking, 
 the body color is a greenish straw, relieved by narrow green rays, very narrow on the 
 beaks and widening out toward the lower margin. These rays are a nearly constant 
 character in the mucket, but vary in number, in width, in brightness of color, and in 
 being continuous or interrupted. The periostracum, or horny covering, of shells grow- 
 ing in clear streams is generally much more brightly rayed than that of those in turbid 
 
 o The beak sculpture of young specimens is a very important diagnostic character or means of distinguishing species which 
 may closely resemble each other in general form. Compare the yellow and the slough sand-shells, Lampsilis anodontoides and 
 LampsUisfaUaciosa, or the pocketbooks, Lampsilis ventrkosa and Lampsilis (.Proptera) capax, which are occasionally distinguished 
 by this feature alone. The beak is, of course, the beginning of the shell— the oldest portion. 
 
FRESH- WATER MUSSELS. l6g 
 
 ones. Young shells are more brightly rayed than old, the rays generally fading some- 
 what or wholly disappearing with age. In different localities, and even in the same 
 bed, the colors are various, the shells may be nearly uniformly straw-colored or largely 
 green; again, a red or rusty-brown color may predominate. The red color without 
 is commonly associated with a pink nacre within. The shell may be smooth and glossy 
 or roughened by fine lines; a silky appearance may be caused by innumerable fine 
 laminae or folds projecting out from the surface of the periostracum. The silky surface 
 is characteristic of some species, as the hickory-nut, Ohovaria ellipsis. 
 
 Looking now at the top or hinge of the shell there is seen just back of the beaks a 
 long, narrow, tough, leathery, elastic band, the ligament, an important part of the hinge 
 mechanism. Just in front of the beak is a small region between the shell valves, which 
 is occupied by a similar horny material. This is called the anterior limule, but in the 
 mucket it is scarcely developed, being about one-half inch long and very narrow in a 
 specimen of 3 inches total length. A posterior lunule may be found just back of the 
 ligament. The compressed form of the shell is noticeable in this view. Roughly speak- 
 ing, the thickness of a mucket from side to side is about one-third of the length, while 
 the width — or height, more correctly — is about two-thirds of the length. 
 
 INTERNAL FEATURES. 
 
 The interior surface of the shell is smooth, white, and lustrous, and usually somewhat 
 iridescent in the extreme posterior portion. In color it is white or pinkish in the mucket, 
 but in other species it may be salmon or purple. Often the proper color is obscured by 
 yellow, greenish, rusty, or salmon-colored stains, resulting from disease, injury, or in- 
 clusion of mud in the nacre. The body of the shell is mainly calcareous, being composed 
 chiefly of a compound of calcium of somewhat the same chemical composition as marble 
 or limestone, but differing in physical structure from either. An account of the struc- 
 ture of shell is given in another place (p. 129). 
 
 The conspicuous features of the interior aspect of the shell are the general con- 
 cavity of each valve; the deeper beak cavities; the dorsal margin roughened by ridges 
 or protuberances known as the "teeth;" two rounded, impressed, and roughened sur- 
 faces, one near each end, the adductor m.uscle cicatrices; and a curved impressed line 
 parallel to the margin of the shell, extending between the two scars just mentioned. 
 This last is the pallial line and marks the attachment of certain muscles of the mantle. 
 
 The two valves, it is noted, are practically identical except for the teeth, which 
 instead of being equal in the two valves, correspond to each other in such a way that 
 the teeth of one valve fit into the spaces between the teeth of the opposite valve. The 
 two valves are thereby interlocked so that they can not slide over each other. Heavier 
 teeth characterize the mussels that are adapted to live in strong currents, while weak 
 teeth or the total lack of them mark the species that must live in quiet waters. The 
 teeth in each valve are of two forms; at the anterior or front end are the stout, rough, 
 and somewhat conical cardinal or pseudocardinal teeth ; while behind these, and more 
 or less separated from them, are long, narrow, bladelike ridges, the lateral teeth. On the 
 right valve there is one lateral tooth which exactly fits into the deep narrow furrow 
 between the two slenderer lateral teeth of the left valve. The two valves are practically 
 exact mirror images of each other except for the teeth ; accordingly, in species such as the 
 
I70 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 Anodontas, which are without teeth, the bilateral S3'mmetry is complete. In some 
 marine bivalves the two shells are essentially different, as in the oyster, where one is 
 concave while the other is flattened and smaller. 
 
 The ligament is composed of two parts; the dark outer layer is inelastic and con- 
 tinuous with the periostracum of the shell; while the inner part, comprising the bulk 
 of the ligament, is elastic and bears somewhat inappropriately the name of cartilage. 
 The elastic cartilage is confined between the inelastic layer above and the firm hinge of 
 the shell below. It is compressed when the shell is closed. The natural or relaxed 
 condition of the shell is, therefore, open; that is to say, with the valves separated below 
 by about one-half inch. Consequently, the shell is kept closed in life only by an exertion 
 on the part of the animal. This is accomplished by means of two stout bands of muscle 
 fibers, constituting the anterior and posterior adductor muscles, which extend from one 
 valve to the other near each end of the shell. These are firmly attached to the shell 
 at each end, the places of attachment being the conspicuous rounded impressions pre- 
 viously noticed. 
 
 The hinge mechanism is completed by the lunule previously referred to. This is 
 a thin horny covering occupying the space between the valves in front of the beak. 
 Unlike the ligament behind, it is stretched when the shell is open. The lunule doubtless 
 has no especial significance except to serve as a protective covering and to make a firm 
 union of the two valves. 
 
 Besides the two adductor impressions and the pallial line, some smaller muscle im- 
 pressions are apparent. Such are those of the muscles which draw back the foot, or 
 the anterior and posterior retractor muscles. These are small impressions, two in each 
 valve, just above the big adductor impressions and in this mussel {LampsUis ligamentina) 
 confluent with the latter. The impression of the protractor, or the muscle which aids 
 in protruding the foot, is usually quite distinct and just beneath the anterior adductor 
 impression. Deep in the beak cavity and on the under surface of the cardinal teeth, 
 or the bridge between cardinal and lateral teeth, are small pits which are the points of 
 attachment of numerous small muscles that serve to elevate the foot. These last are 
 the dorsal muscle scars referred to in systematic descriptions. (See PI. XXI, fig. i.) 
 
 DIVERSITY IN FORM. 
 
 Many modifications of the above description would have to be made for other species 
 of mussels. The shell may be pear-shaped as in the niggerhead (Quadrula chenus), or 
 nearly circular as in Quadrula circulus; it may be very much inflated as in LampsUis 
 capax or in L. ventricosa (the pocketbook), or exceedingly compressed as in Symphynota 
 compressa. In some the shell is not only greatly flattened from side to side but also 
 extends upward in wings before and behind the beaks. Such species are given locally 
 such descriptive names as pancakes, hatchet-backs (LampsUis alaia), or heel-splitters 
 {Symphynota complanaia). Some shells are proportionately very heavy, while others, 
 included mostly in the genus Anodonta, the paper-shells or floaters, are so thin as to be 
 useless for any present economic purpose. The Anodontas, adapted to live in lakes or 
 close alongshore in streams, are further characterized by the entire absence of teeth. 
 
 Variations in thickness or in uniformity of thiclcness are important from the stand- 
 point of the button makers, and so also are variations in the surface sculpture. Some 
 
FRESH- WATER MUSSELS. 171 
 
 forms are covered with protuberances or knobs in regular or irregular pattern, thus ac- 
 quiring such common names as warty-backs or pimple-backs; while others have strong 
 ridges ruiming obliquely across the shell, as the three-ridge, Quadrula uridulata, the 
 blue-point, Q. plicata, and the washboard, Quadrula heros. One species, Unio spinosus, 
 of Alabama, bears long sharp spines on the shell. Diversity of interior color has pre- 
 viously been alluded to. No satisfactory explanation of the colors of nacre has yet 
 been offered. Certain species are almost always white-nacred, as the pimple-back, 
 maple-leaf, and niggerhead. Others are white or pink, examples of the two colors 
 living side by side. Some species have usually a deep purple or salmon nacre, but 
 white-nacred shells of the same species may predominate in particular streams. 
 
 Variations in external color are conspicuous in any collection of shells even from 
 the same mussel bed. Along with shells of uniform color, light or dark, we find shells 
 of glossy surface and brilliantly rayed; the rays may be continuous or variously inter- 
 rupted, sometimes composed of small zigzag markings forming striking and fantastic 
 patterns. In short, the differences in form and color of shell are unlimited and could 
 not be described, even within the limits of a systematic monograph. 
 
 THE SOFT BODY. 
 
 For observation of the body the mussel may be carefully opened by severing the 
 adductor nmscles close to one valve, preferably the left, and gently freeing the soft 
 mantle from the shell as the knife blade is passed from one end of the shell to the other. 
 Removing or bending back the upper (left) valve, the body of the mussel is seen to be 
 almost completely enveloped in a thin mantle corresponding to the interior of the shell 
 inform and size (PI. XXI, fig. i). 
 
 FORM AND FUNCTIONS OF THE MANTLE. 
 
 The mantle is composed of right and left sheets entirely free from each other except 
 along the back where the two sheets are continuous not only with each other but with 
 the body as well. The mantle is, in fact, a double fold from the back of the mussel 
 draped over the body and lining the shell. A thin wing or dorsal extension of the man- 
 tle covers entirely the surfaces of the cardinal and lateral teeth and underlies the liga- 
 ment. 
 
 The mantle is not of uniform character throughout but shows a broad border thicker 
 than the central portion and somewhat muscular. This border along its inner line is 
 attached to the shell through many fine muscle fibers, the attachment of which forms 
 the pallial line on the shell. The border is muscular and, therefore, contractile; the 
 lower or right mantle, which has not been separated from the shell, will have its edge 
 contracted away somewhat from the margin of the valve; generally there is apparent 
 a thin film of horny material which connects the edge of the mantle with the extreme 
 edge of the shell. It is not infrequently the case that in separating the surface of the 
 mantle from the shell a delicate transparent membrane is distinguishable, some parts 
 of which adhere to the mantle and some parts to the shell. Unless, therefore, a rupture 
 has occurred, the mantle normally is actually continuous at the margin with the outer 
 surface of the shell, and probably organically but delicately connected to the inner surface 
 of the shell over its entire surface. 
 9745°— 21 7 
 
172 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 The relations of the mantle as observed will have greater significance from a state- 
 ment of its functions. Besides supplementing the gills in respiration and serving along 
 its border as a sensory organ, a chief function of the mantle is the formation of shell. 
 The extreme edge of the mantle secretes the horny covering of the shell, as also the liga- 
 ments and lunule, while the remaining mantle surface secretes the calcareous shell. 
 For our purpose, accordingly, the mantle is a most significant organ. Diseases or other 
 influences affecting the mantle frequently show effects in the shape, color, or quality 
 of the shell, and it is in the mantle, probably, that all free pearls are produced. The 
 mantle is not, however, the only portion of the mussel capable of forming shell. The 
 two adductor muscles pass entirely through the mantle, having direct attachment to the 
 shell. While the shell becomes thicker in other parts by the superposition of layer after 
 layer of calcareous material from the surface of the mantle, the thickening of the shell 
 against the muscles is in some measure, apparently, a function of the muscles them- 
 selves. It is not surprising, therefore, that these muscles also give rise to a large number 
 of pearl formations, baroques, and slugs, but not, ordinarily, good pearls. No other 
 parts commonly give origin to pearls, although it is reported that pearls have been 
 found within the body. Baroque pearls and slugs are frequently found in the tissue 
 just beneath the hinge line, but this is actually a part of the mantle. 
 
 The shell substance formed by the muscles is called hypostracum, and is largely 
 horny in nature. Since each muscle occupies a nearly constant relative position regard- 
 less of the size to which the mussel attains, it is evident that in any adult individual the 
 muscle traveled in the course of life history from the back to its latest position; the 
 hypostracum, therefore, does not occupy a single spot but is a tapering vein passing 
 through the nacre from the beak to the position of the muscle at any given time. Simi- 
 larly the hypostracum of the pallial line is the margin of a thin stratum of like sub- 
 stance which extends from the beak or beginning of the shell and di^ddes the nacre 
 into two portions (p. 130). 
 
 The mantle has other functions of great importance. When the muscles are relaxed 
 and the shell is gaping, the opening between the valves of the shell is largely closed by 
 the apposed margins of the mantle. Nothing can enter between the valves of the shell 
 without affecting the highly sensitive border of the mantle and thus giving warning 
 to the animal, which may then contract its muscles and close the shell instantly. The 
 nerves of the margin of the mantle are not only sensitive to tactile stimuli, but apparently 
 are also connected v.dth organs of something like visual function, so that the animal 
 may close or open its shell under the influence of shadows or bright light. 
 
 It is the margins of the mantle that surround and fonn the two siphonal openings 
 at the hinder end of the shell, through one of which water and food pass into the shell, 
 while through the other water passes out, conveying the waste products. The lower 
 of these two openings particularh' is protected by projections of the mantle, in the form 
 of papillae or fimbriae, which, being ^'ery sensitive, give warning of any objectionable 
 character or content of the water. 
 
 OTHER CONSPICUOUS ORGANS. 
 
 Without disturbing the upper mantle two internal organs are distinctly evident. 
 The heart is recognized by its throbbing action. It lies at the back just belo^v the lateral 
 teeth of the hinge and in front of the posterior adductor muscle. The rate of beating 
 
FRESH- WATER MUSSELS. 173 
 
 varies in dififerent species and under different conditions but is generally under 20 pul- 
 sations per minute. The heart will continue to beat a long time after the shell has been 
 opened. Near the anterior adductor is a greenish mass of tissue, the so-called liver 
 or digestive gland, surrounding the white stomach. Through the transparent tissue, 
 covering the chamber inclosing the heart, another portion of the alimentary tube is 
 generally distinguishable. This is the rectum or hinder portion of the intestine which 
 passes directly through the heart to discharge just above the posterior adductor muscle. 
 The brownish tissue beneath the heart represents the organ of Bojanus, as it is called, 
 with functions corresponding to a kidney. 
 
 To distinguish other organs the mantle must be folded back. The muscular mass of 
 plowshare iorm and brownish white in color, constituting the anteroventral border 
 of the body, is the foot. Several curtainlike flaps are conspicuous. Toward the forward 
 end are two large earlike flaps, the labial palpi or lipfolds. They are easily torn in folding 
 the mantle back, but if in good condition, it may seen that each of these palps is contin- 
 uous, around the front end of the body, with the palp of the opposite side. Immediately 
 in front of the body they are very narrow and lie one above and the other just below an 
 exceedingly small opening, the mouth, which can be seen only by very careful exami- 
 nation. 
 
 The other two folds are much larger and rounded below. These are the gills, which 
 extend from the anterior third of the body to the extreme posterior end. The inner is 
 slightly the larger. The outer gill is connected above and on the outside to the mantle. 
 Folding this one back, it is seen that it is attached also to the inner gill above. The inner 
 gill on the inner side is attached to the body and, behind the body, to the inner gill 
 of the opposite side. In many species the inner gill is partially free from the body. 
 These gills, though thin, are really basketlike structures, containing chambers within, 
 as will be described below. 
 
 INTERNAL STRUCTURE. 
 
 It is not the province of this paper to enter minutely into the internal anatomy. 
 But the following epitomized statement of the structure of the animal is given to serve 
 as a key to the understanding of the functions of the organism as a whole. 
 
 The digestive system comprises the mouth, with a short tube or gullet, leading 
 from the mouth to the stomach; the dark brown digestive gland, or so-called liver, 
 which surrounds the stomach; and the intestine, which is a long tube that leads down- 
 ward from the stomach and coils upon itself behind the foot in a complex way, before 
 bending upward to approach the back and extend posteriorly straight through the heart 
 as the rectum, which opens just above the posterior adductor muscle. A long, slender 
 flexible gelatinous rod, the crystalline style, is frequently found in the intestine; it 
 serves a function in separating food from foreign particles and comprises a store of 
 enzymes or ferments for use in the processes of digestion (Nelson, 1918). 
 
 The excretory system comprises a functional kidney with a bladder which discharges 
 into the cavity surrounding the heart. 
 
 The circulatory system includes, as in higher animals, heart, blood, arteries, and 
 veins. The blood of a mussel is colorless but maintains a regular circulation from the 
 heart through certain arteries to many smaller vessels ramifying all through the body, 
 returning by a main vein to the kidneys, thence to the gills and back through other 
 veins to the heart to begin its course anew. The blood, however, which passes from 
 
174 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 the arteries to the mantle, returns, not through the kidneys or the gills, but directly 
 to the heart. 
 
 The mantle and the gills constitute the chief respiratory organs, where the blood 
 is aerated. The significance of the mode of circulation is evident. The venous blood 
 returning from the body laden with waste products passes first to the kidney, thence 
 to the gills to be cleared of impurities and freshened with oxygen, after which it returns 
 to the heart in purified condition. The blood returning from the mantle requires no 
 further purification or oxygenation before entering the heart. 
 
 Without a distinct brain, the body of the mussel is coordinated through a ner\'ous 
 system, consisting of three pairs of nerve centers, which are connected together by 
 nerve cords. Two of these centers or ganglia lie one on each side of the gullet near the 
 mouth, a second pair is in the foot, while the third lies just beneath the posterior adductor 
 muscle. From these ganglia fine nerves are sent off to supply the various tissues 
 and organs. 
 
 Though eyes and ears are not present, sensory organs are not entirely wanting. 
 A small organ near the ganglia beneath the posterior adductor is supposed to serve to 
 test the purity of the water. Another, the otocyst, is sometimes found near the ganglia 
 in the foot and possibly serves as a balancing organ, by means of which the mussel 
 may feel whether it is in horizontal or vertical position. Sensory cells are found along 
 the border of the mantle, especially near the posterior openings for the passage of water. 
 (Seep. 87.) 
 
 The organs of reproduction comprise a large part of the body mass above the foot. 
 The ova or semen are discharged through small openings on each side of the body into 
 the chamber above the gills. In the case of the male the sperms are thence passed 
 out with the respiratory (exhalent) current and set free in the water. They may be 
 drawn into the female with the water of the inhalent current, to fertilize the ova perhaps 
 as they are passed down from the suprabranchial chamber into the tubes in the gills 
 where incubation takes place. In some species the reproductive tissue is brightly 
 colored — orange, pink, or red. 
 
 STRUCTURE AND FUNCTIONS OF THE GILLS. 
 
 The gills, as the name would suggest, are primarily breathing organs. Nevertheless, 
 they have an equal if not a greater function in food gathering, and, furthermore, in 
 fresh-water mussels and in some other lamellibranchs, the gills have acquired a third 
 office which is of coordinate importance with the other two. We have seen that the 
 incubation of the egg takes place in the water tubes of the gills, a part or all of which may 
 be filled with embryo mussels. The respiratory function of the gills of the female mussel 
 must be greatly reduced during the period of incubation, and this condition is made 
 possible by the fact that the mantle of the mussel plays an equal role with the gills 
 in respiration. In becoming adapted to this function of protection and perhaps nour- 
 ishment of the eggs and young, the gills of the female have undergone varied modifica- 
 tions in different species. In consequence, when gravid females can be examined, the 
 gills of different mussels are often found to be more strikingly distinct than is the external 
 form or any other obvious character. This is especially true when microscopic study 
 of the structure of the gills can be made. 
 
FRESH- WATER MUSSELS. 175 
 
 Whether or not, therefore, these differences are a true guide to relationships, the 
 gills become one of the most convenient organs for distinguishing genera or species and 
 serve as the most important basis of modern classification. 
 
 Some knowledge of the anatomy of the gills is necessary for proper comprehension 
 of the life process of mussels in breathing, feeding, and reproduction. 
 
 The gills consist, as we have seen, of two platelike bodies on each side between the visceral mass 
 and the mantle. We have thus a right and a left inner gill and a right and a left outer gill. Seen from 
 the surface, each gill presents a delicate double striation, being marked by faint lines running parallel 
 with the long axis and by more pronotmced lines running at right angles to the long axis of the organ. 
 Moreover, each gill is double, being formed of two similar plates, the inner and outer lamellse united 
 with one another below as well as before and behind but free at the top or dorsally. The gill has thus 
 the form of a long and extremely narrow bag open above. Its cavity is subdivided by vertical bars of 
 tissue, the interlamellar junctions, which extend between the two lamellse and divide the intervening 
 space into distinct compartments or water tubes, closed below but freely open along the dorsal edge of the 
 gill. The vertical striation of the gill is due to the fact that each lamella is made up of a nimiber of 
 close-set gill filaments; the longitudinal striation, to the circumstance that these filaments are con- 
 nected by horizontal bars, the interfilamentar junctions. At the thin free, or ventral, edge of the 
 gill the filaments of tlie two lamellte are continuous with one another, so that each gill has actually a 
 single set of V-shaped filaments, the outer limbs of which go to form the outer lamella, their inner limbs 
 the inner lamella. Between the filaments, and boimded above and below by the interfilamentar 
 jimctions, are minute apertiu-es or ostia, which lead from the mantle cavity through a more or less 
 irregular series of cavities into the interior of the water tubes. (After Parker and Haswell.) 
 
 The gills, then, which appear as thin plates, are really comparable to long baskets 
 greatly flattened from side to side, the interior of the basket being subdivided into a 
 series of deep tubes, all in one row. The surface of the basket, which is perforated by 
 many pores visible only with a microscope, is covered with very minute paddles like 
 fine flat hairs. The concerted action of these little paddles, called cilia, keeps driving 
 the water from without the gill through the minute pores into the water tubes. Through 
 these tubes the water passes upward into a chamber above the water tubes, called the 
 suprabranchial chamber, and thence backward and finally out of the shell. 
 
 Since the cilia are habitually driving the water through the surface of the gills 
 into the water tubes, it follows that there must be a regular stream of water entering 
 the mantle chamber from without through the open valves, as well as an outgoing 
 stream passing out from the chamber above the gills. These two streams are known 
 as the inhalent current and the exhalent current, respectively. If a mussel is observed 
 in undisturbed condition on the bottom of an aquarium (PI. V, figs, i and 2), the two 
 openings between the edges of the mantle are readily seen and the currents may easily 
 be observed by introducing with a pipette into the water near each opening a little 
 colored water. The coloring matter placed near the lower inhalent current is drawn 
 into the shell, but that placed near the upper opening is driven forcibly away. The 
 two pronounced currents, or rather two aspects of the same current, are, it may be 
 repeated, formed entirely by the minute paddles surrounding the innumerable pores 
 of the gill surfaces. 
 
 The gills themselves are living strainers in the course of this current, and as the 
 water passes through them the material which serves as food is filtered out to be passed 
 on to the mouth; at the same time, the blood in the minute vessels and spaces within 
 the gill filaments and partitions is being purified and recharged with oxygen. The 
 matter strained from the water becomes clotted with mucus and is driven along by the 
 cilia over the surface of the gills to the labial palpi, where it is taken up and if suitable 
 for food is passed on to the mouth, for the surfaces of the palpi as well as of the gills 
 
176 BULLETIN OF THE BUREAU OF FISHERIES. 
 
 are covered by cilia or minute paddles, the combined action of which forms a wonderful 
 mechanism for conveying the food from any point of the gill surface into the funnel- 
 shaped mouth. The detailed working of this mechanism and the places and means of 
 "switching off" undesirable matter form too complex a subject to be treated in this 
 paper. (See Allen, 1914, and Kellogg, 1915.) 
 
 The course of the water is better understood after observing the mode of attachment 
 of the gills. The outer lamella of the outer gill is attached to the mantle throughout 
 its entire length, while its inner lamella and the outer lamella of the inner gill are attached 
 together to the body. There is thus above each gill a small suprabranchial chamber 
 just above the water tubes. Behind the body or visceral mass, however, the inner 
 lamella of the right and left inner gills are attached together, and there is, therefore, 
 a single large chamber above the four gills — the cloaca or exhalent chamber. The 
 water, after passing through the pores of the gill surface, makes its course up the water 
 tubes and backward by the suprabranchial chamber into the cloaca, to be passed thence 
 out of the shell." 
 
 It will be understood that the eggs and young borne in the water tubes of the gills, 
 which become marsupial pockets, are most favorably located for respiration, being 
 situated, as it were, in the respiratory current of the mother. There is, among the 
 various species of the Unionidae, great variation in the extent to which the gills are 
 employed as marsupia (p. 139). In certain species the water tubes of all four gills are 
 filled with eggs, in others only those of the outer gills receive the eggs, while in still 
 others a portion of each outer gill is set apart as a marsupium. This may be the posterior 
 half, the posterior third, or a few water tubes in the middle. 
 
 It is largely because of the great significance of the gills with their remarkably 
 diverse functions of food collection, respiration, and gestation that the modifications 
 both in the external form and in the histologic structure of the gills are important and 
 serv'e so well as a basis of classification. Generally speaking, species in which all four 
 gills serve as marsupia are considered lower or more primitive forms. Those in which 
 the marsupia are most highly specialized are regarded as most highly developed. 
 
 " The effect of the gills in filtering the water is made clear when one fills two iars with turbid river water after placing in each 
 sufficient sand for a mussel to become embedded. If one or two mussels are placed in one of these jars, the water will become 
 clear in a comparatively short time. 
 
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178 BULLETIN OF THE BUREAU OF FISHERIES. 
 
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