oY flo Dee i # ew =a Peep... MEMOIRS © on TYPICAL BRITISH MARINE PLANTS & ANIMALS EDITED BY W. A. HERDIWAN. D.Se., FURS. a XVII. ~ PECTEN BY W. J. DAKIN, MSc., whibition Scholar in Zoology, University of Liverpool (With 9 Plates) Price Four SHILLincs AND SIXPENCE 4 LONDON Wittiams & NorGate January, 1909 As A eID AAAS LRDEAA AE MANE EX LIBRIS William Healey Dall Division of Mollusks Sectional Library Ald | CT ot NOTICE. Te Committee desire to intimate that no copies of these Memoirs will be presented or exchanged, as the prices have been fixed on such a scale that most of the copies will have to be sold to meet the cost of production. The Memoirs may be obtained at the nett prices stated, from Messrs. Wiliams and Norgate, 14, Henrietta Street, Covent Garden, London. Memoir L. ’) yee CE Il. ILO Ascidia-—published in October, 1899, 60 pp. and five plates, price 2s. Cardium—published in December, 1899, 92 pp., six plates and a map, price 2s. 6d. Kchinus—-published in February, 1900, 36 pp. and five plates, price 2s. Codium—pubhshed in April, 1900, 26 pp. and three plates, price Ls. 6d. Aleyonium—published in January, 1901, 30 pp. and three plates, price 1s. 6d. Lepeophtheirus and Lernezea—published in March, 1901, 62 pp. and five plates, price xs. Lineus— published in April, 1901, 40 pp. and four plates, price 2s. Pleuronectes—published in December, 1901, 260 pp. and eleven plates, price 7s. Chondrus— published in July, 1902, 50 pp. and seven plates, price 2s. 6d. Patella—published in May, 1908, 84 pp. and four plates, price 2s. 6d. Arenicola—published in March, 1904, 126 pp. and eight plates, price 4s. 6d. Gammarus—published in July, 1904, 55 pp. and four plates, price 2s. Anurida—published in October, 1906, 105 pp. and seven plates, price 4s. Ligia—published in January, 1907, 45 pp: and four plates, price 2s. Antedon—published in June, 1907, 55 pp. and seven plates, price 2s. 6d. Cancer—published in June, 1908, 217 pp. and thirteen plates, price 6s. 6d. Pecten—published in January, 1909, 144 pp. and nine plates, price 4s. 6d. Liverpool Marine Biology Committee. VE EC MEMOTRS ON TYPICAL BRITISH MARINE PLANTS & ANIMALS EDITED BE VW Ay TER DILAN. D.Sc. FUR.S: XVII. PECTEN W. J. DAKIN, MSc., h 1851 Exhibition Scholar tn Zoology, University of Liverpool (With g Plates) Prick Four SHILLINGS AND SIXPENCE LONDON Witirams & NorGare January, 1909 SPN AUG 9 - 1949 arn, mE EDITOR’S PREFACE. Tue Liverpool Marine Biology Committee was constituted in 1885, with the object of investigating the Fauna and Flora of the Irish Sea. The dredging, trawling, and other collecting expeditions organised by the Committee have been carried on inter- mittently since that time, and a considerable amount of material, both published and unpublished, has been acecu- mulated. ‘Twenty-one Annual Reports of the Committee ee and five volumes dealing with the ‘* Fauna and Flora ”’ have been issued. At an early stage of the investigations it became evident that a Biological Station or Laboratory on the sea-shore nearer the usual collecting grounds than Liverpool would be a material assistance in the work. Consequently the Committee, in 1887, established the Puffin Island Biological Station on the North Coast of Anglesey, and later on, in 1892, moved to the more commodious and accessible Station at Port Erin in the centre of the rich collecting grounds of the south end of the Isle of Man. A new and larger Biological Station and Fish Hatchery, on a more convenient site, has since been erected, and was opened for work in July, 1902. — In these twenty-one years’ experience of a Biological Station (five years at Puffin Island and sixteen at Port Erin), where College students and young amateurs form a large proportion of the workers, the want has been fre- quently felt of a series of detailed descriptions of the structure of certain common typical animals and plants, chosen as representatives of their groups, and dealt with by specialists. ‘The same want has probably been felt in other similar institutions and in many College laboratories. vi. The objects of the Committee and of the workers at the Biological Station were at first chiefly faunistic and speciographic. The work must necessarily be so when opening up a new district. Some of the workers have published papers on morphological points, or on embry- ology and observations on life-histories and habits; but ee the majority of the papers in the volumes on the “ Fauna and Flora of Liverpool Bay ” have been, as was intended from the first, occupied with the names and characteristics and distribution of the many different kinds of marine plants and animals in our district. And this faunistic work will still go on. It is far from finished, and the Committee hope in the future to add still further to the records of the Fauna and Flora. But the papers in the present series, started in 1899, are quite distinct from these previous publications in name, in treatment, and in pur- pose. They are called “ L.M.B.C. Memoirs,” each treats of one type, and they are issued separately as they are ready, and will be obtainable Memoir by Memoir as they appear, or later bound up in convenient volumes. It is hoped that such a series of special studies, written by those who are thoroughly familiar with the forms of which they treat, will be found of value by students of Biology in laboratories and in Marine Stations, and will be welcomed by many others working privately at Marine Natural History, The forms selected are, as far as possible, common L.M.B.C. (Irish Sea) animals and plants of which no adequate account already exists in the text-books. Probably most of the specialists who have taken part in the L.M.B.C. work in the past will prepare accounts of one or more representatives of their groups. The following list shows those who have either performed or promised. Memoirs from I. to XVIJ. have now been published. Kledone, b Vil. vy Miss A. Isgrove, is completed and will appear at an early date; Doris, by Sir C. Eliot, is far advanced and ought to be out during 1909. It is hoped that Cucumaria, Buecinum, and the Oyster will follow soon. Memoir I. ” Il 3 LE ee ” \ rete ae, ‘Alt weed eva i BS ” X So el. poe Ue EEE: 5p AE VE. pee LL: Ascrp1a, W. A. Herdman, 60 pp., 5 Pls., 2s. . Carpivum, J. Johnstone, 92 pp., 7 Pls., 2s. 6d. . Ecuinus, H. C. Chadwick, 36 pp., 5 Pls., 2s. 7. Copium, R. J. H. Gibson and Helen Auld, Z0.pp., deels:, Us, 6d: 7, Atcyonium,’S. J. Hickson, 30 pp., 3 Pls., 1s. 6d. . LEPEOPHTHEIRUS AND LERN2%A, Andrew Scott, O2eppyvo: Pls., 2s: . Linevs, R. C. Punnett, 40 pp., 4 Pls., 2s. . Puatce, F. J. Cole and J. Johnstone, 260 pp., LPs. 1s: . CHonpRus, O. V. Darbishire, 50 pp., 7 Pls., 2s. 6d. » PArEELA, J. R. A. Davis and H. J. Fleure. 84 pp., 4 Pls., 2s. 6d. ARENIcoLa, J. H. Ashworth, 126 pp., 8 Pls., 4s. 6d. Gammarus, M. Cussans, 55 pp., 4 Pls., 2s. Anvnripa, A. D. Imms, 107 pp., 8 Pls., 4s. . Lictia, C. G. Hewitt, 45 pp., 4 Pls., 2s. AntEepon, H. C. Chadwick, 55 pp.,7 Pls.,2s. 6d. Cancer, J. Pearson, 217 pp., 13 Pls., 6s. 6d. Pecten, W. J. Dakin, 144 pp., 9 Pls., 4s. 6d. ,, X VIII. Kneponn, A. Iserove. Doris, Sir Charles Eliot. Cucumaria, EK. Hindle. OystER, W. A. Herdman and J. T. Jenkins. Osrracop (CyrHEert), Andrew Scott. Buccinum, W. B. Randles. Vill. Bueuta, Laura R. Thornely. Sacitta, KH. J. W. Harvey. Zostrra, R. J. Harvey Gibson. Himantuarta, F. J. Lewis. Dratoms, F. K. Weiss. Fucus, J. B. Farmer. BorrytioipEs, W. A. Hlerdman. Acrinia, J. A. Clubb. Hyproip, EK. I’. Browne. HaicHonprra and Sycon, A. Dendy. SaBELLARIA, A. T. Watson. In addition to these, other Memoirs will be arranged for, on suitable types, such as Pagurus, Pontobdella, a Cestode and a Pycnogonid. As announced in the preface to Ascripia, a donation from the late Mr. F. H. Gossage, of Woolton, met the expense of preparing the plates in illustration of the first few Memoirs, and so enabled the Committee to commence the publication of the series sooner than would otherwise have been possible. Other donations received since from Mrs. Holt, Sir John Brunner, and others, are regarded by the Committee as a welcome encouragement, and have been a great help in carrying on the work. W. A. Herpman. University of Liverpool, December, 1908. L.M.B.C. MEMOIRS No. XVII. PECTEN. BY Mid. AKIN, .MSc:; 1851 Exhibition Scholar, University of Liverpool. INTRODUCTION. Although the greater part of the following account of this type applies to the anatomy and histology of Pecten maximus, the very common smaller species P. opercularis has also been investigated. Some details in which the latter differs from P. mazimus are mentioned in the text, but, on the whole, these differences are but slight, and either species may be dissected and examined while using this Memoir. The work has been carried out chiefly in the Zoology Department of the University of Liverpool and at the Port Erin Biological Station, Isle of Man. The chemical work was done at Larne. Co. Antrim, and some of the observations on the sense organs at Kiel. My thanks are due to Professor Herdman for his valuable advice, and for aid in obtaining living material by dredging at Port Erin; also to the Larne Aluminium Company for per- mission to use their chemical laboratory; and finally to Mr. Chadwick, Curator of the Port Erin Biological Station. TAXONOMY AND DISTRIBUTION. Pecten maximus and P. opercularis are two of the common British species of the genus Pecten, and are known in some places as “scallops. Pecten is the most 2 familiar genus of the family Pectinidae, the correct position of which amongst Pelecypoda or Lamelli- branchiate Molluscs is not easy to determine. The shells, gills, muscles, mantle, siphons, &c., have all been employed in classifying the Lamellibranchiata, but, so far, without really satisfactory results. The following classification proposed by Pelseneer (7), and founded on the structure of the gills, appears to be the most reliable. Protobranchia— Lamellibranchia possessing gills with flat and non-reflected filaments disposed in two rows on opposite sides of the branchial axis. Filibranchia— With gills formed of parallel, ventrally directed, and reflected filaments. The succes- sive filaments are joined together by cilia disposed in “ciliated discs.” Eulamellibranchia—In which the gills and branchial filaments are united at regular intervals by vascular junctions. Septibranchia— Dimyarian Lamellibranchs in which the mantle remains fairly open, the gills have disappeared as respiratory organs and have been transformed into a muscular septum dividing the pallial cavity into two chambers. Ridewood (12) keeps the first of these orders as it stands, but divides the remaining Lamellibranchs into only two orders, as follows :— Ord. 1.—Protobranchia (as above). Ord. Il.—Eleutherorhabda. This is practically the same as the Filibranchia. Ord. I1I.—Synaptorhabda. This includes Pelseneer’s two orders, Eulamellibranchia and Septibranchia. Thus according to both these classifications, the older group, Pseudolamellibranchia is done away with. This order included the Pectinacea and the Ostraeacea: the 3 first of these has been removed to the Filibranchia and the second te the Eulamellibranchia. We see, therefore, that the position of our type is as follows :— Class: Lamellibranchia. Ord.: Filibranchia. Sub- order: Pectinacea. Fam.: Pectinidae. Genus: Pecten. The American scallop, however, Pecten tenwicostatus, has, according to Drew (1), the gill filaments united by interfilamental vascular junctions, thus forming one exception to the definition of the Filibranchia, and serving to show how insufficient single characters may be in a scheme of classification. The genus Pecten is of world-wide distribution, though most of the species are confined to smaller areas, and the habitat extends from the littoral zone down to the 450 fathom line and probably further. The distribution in time extends from the Cretaceous, and possibly it goes even further back to the Carbon- iferous period. Jackson (3) in his work on the Phylogeny of the Pelecypoda, has shown how this genus is related by the structure of the early nepionic shell to the Aviculidae, and in all probability the fossil Aviculopecten of the Devonian rocks was a connecting link, so that the ancestry of the Pectens can thus be traced back to Silurian times. In addition to Pecten maximus and P. opereularis— generally distributed in European seas—the following species are found round the British coast :—Pecten pustio (Linné), Pecten varius (Linné), var. purpurea, Jeffreys, and var. nivea, Macgillivray, P. sulcatus (Miiller), P. fragilis (Jeffreys), P. clavatus, var. septemradiatus, Miller, var. alba, Jeffreys, and var. dwmasi, Payraudeau, P. tigerinus (Miiller), and var. costata, Jeffreys, P. incom- parabilis (Risso), P. striatus (Miller), P. similis ( Laskey), 4 P. vitreus (Chemnitz), P. grenlandicus, Sowerby, and four varieties of Pecten opercularis—var. lineata, da Costa, var. tumida, Jeffreys, var. elongata, Jeffreys, and var. audouinz, Payraudeau. For systematic descriptions of these species and varieties reference should be made to Forbes and Hanley’s * British Mollusca,” and Jeffreys’ “ British Conchology.”’ Both P. maximus and P. opercularis, but especially the latter, are gregarious; and in various places round the British Coast beds of scallops exist where P. opercularis can be obtained in thousands by dredging. _ Both species prefer a sand or gravel bottom, but sometimes they occur on mud. ‘The depth of the great bed of P. opercularis, situated off Port Erin at the South-west end of the Isle of Man, is about 17-22 fathoms, and all the specimens of both species used in preparing this Memoir came from an average depth of about 20 fathoms. BIONOMICS. The animal is found lying free, neither adherent by the shell nor by a byssus. Locomotion, however, is carried on, not by the usual Lamellibranch methods of creeping or leaping, but by spasmodic swimming. This is one of the most interesting peculiarities of the genus, and, moreover, certain features in the anatomy of the molluse have, in all probability, been modified owing to this habit. Pecten opercularts swims much more frequently and for a longer period than P. maximus, and if specimens are kept in aquarium tanks, it is quite easy to follow their movements and make out the structures involved in this curious method of progression. It strikes one at once that, contrary to what might be expected, the animal moves with the ventral edges of the shell foremost. The molluse, which has been lving on one of > oD its valves, causes the shell to open and close in a very rapid manner, and it might be thought that at each sudden clappimg of the two valves, the water between them would be forced out ventrally and that the animal in consequence would move with the hinge line foremost. The free or ventral border of the valves is, however, directed forwards in swimming, and the animal seems to take a series of bites at the water. As will be subsequently described, the valves in both species are not mirror images of each other. Pecten maximus has the right valve very much more convex, while the left is quite flat. In P. opercularis the two valves are much more alike but the right is slightly less convex than the left. Pecten maximus lies on the convex valve or right side, and the flat side is, therefore, superior, and is generally covered with barnacles, serpula, zoophytes, &e. P. opercularis also shows by the attached animals being found always on the same side, that it lies on the right valve. If a specimen is turned over on to the other side, it will make efforts to turn back, and usually regains its normal attitude in a few minutes. The two diagrams in text (fig. 1) show that while the two species both he on the right valve, in one case the more convex side is downwards, and in the other, upwards. If the undisturbed animal is watched as it opens the valves (which it does very slowly), the tentacles (Plate IL., fig. 1, Zn.) will first be seen gradually protruded, then the eyes will become obvious, and lastly, when the valves - are some distance apart, the two free edges of the mantle (which previously lay against the mantle lobes proper) move outwards until they stand almost at right-angles to the plane of the valves, so as to form one curtain or “velum” (fig. 1, V.) hanging from the upper valve and one projecting up to meet this from the lower valve. 6 In the resting condition the valves of the shell are opened very considerably, but the organs in the pallial cavity cannot be seen owing to the fact that the edges of the upper and lower vela are just in contact. By putting a few grains of carmine in the sea water, an inhalent current can be demonstrated. This enters the pallial cavity by passing between the mantle lobes all round the margin of the shell except for a small distance posteriorly. Here there is a strong exhalent current, and thus, although no morphological siphons are present, there are well-defined areas for the inhalent and exhalent respira- tory and nutritive currents. When the animal is about to swim, the following changes take place: the valves slowly open, that is, they move further apart than in the resting condition, and the visceral mass can be seen between the mantle edges. At the same time the two vela lie slightly turned back against the mantle lobes as if moved inwards by the inflowing water due to the divarication of the valves. Towards the end of this opening motion the tentacles are quite suddenly retracted all round the mantle edge, and immediately the shell shuts with a snap. Just at this moment, however, the two vela take up the vertical position, with their margins touching, and by means of their muscular structure retain this position, acting as a perfect barrier to the water which must escape from the pallial cavity. The result is that the water escapes only where the two vela are not well developed, and where they do not dam back the current, and this is on each side of the dorsal edge of the shell. There are, therefore, two jets of water shot out dorsally at each sudden closing of the shell, for the process above described is repeated rapidly for several seconds, and consequently the animal moves onward with the | ventral margin foremost. An inclination to one side or the other can be effected by partial closure of one of these dorsal openings. The sudden retraction of the tentacles is always the signal for the closing of the shell. The animal can, in addition, force the water out at the ventral margin by not bringing the pallial barrier into play. This occurs when it is suddenly stimulated, and then it darts away with the hinge line foremost. It also is interesting to note that when the animal is turned over on to the upper side, it rights itself in a very short time by driving water out sharply between the ventral margins of the shell. This forces the hinge line back against the ground and is then used as a fulcrum on which to turn over. When in the normal position, that is, lying on the convex valve, a slight jet of water sent out ventrally causes that edge of the shell to rise from the bottom, so that the normal movements of swimming can take place without any hindrance from friction with the bottom. The equilateral character of the shell of Pecten is, perhaps, a modification due to the development of the power of swimming and we may also put down to this, the evolution of a muscular velum, the large single adductor muscle with its adaptations for rapid contraction, and also the large internal cartilage for opening the shell. It is doubtful whether adult Pecten maaimus or P. opercularis ever employ the foot for purposes of locomo- tion. This seems to be rudimentary in the adult as far as its use as a locomotive organ is concerned, but as on one occasion I was able to see a P. maximus protrude its foot —which is evidently capable of much distension—out of the shell, it may be possible that in its normal habitat it uses the foot more frequently. I have not been able to 8 examine the very young stages of P. maaimus, but P. opercularis and P. trradians of the American coast have a period before the free stage is reached, when they attach themselves by means of a byssus. In a still earler stage after the free-swimming larva has settled down, the animals are unattached and crawl about actively. The foot is protruded, attached to some object and then contracted, and in this way the animal is pulled along by successive attachments and contractions of the foot. The foot of the adult Pecten is very like a sucker, though in no case have I seen it used in the manner above described. Following the crawling stage we have the byssus stage, and the foot takes part in the attachment of the threads. Jackson (3), who has watched the American species, describes it as follows:—‘‘ Lying on the right valve, the foot is extended on the surface of the dish, the flattened distal portion taking a firm hold as if about to crawl. This position is maintained for a moment or two and then the foot is withdrawn within the body, by the motion of retraction it draws out, or spins, the byssal thread, which the creature had fixed to the surface of the dish while the foot was laid closely against it. Soon the foot is again extended, pressed flatly against the dish and another byssal thread is spun, three is the common number with specimens in confinement.” If disturbed the attached scallop can break or cast off its byssal threads and swim by clapping its shell. The adult P. opercularis only occasionally shows any signs of the byssus, but P. varius, another common British species, is usually attached. | Pecten feeds largely on vegetable matter, such as diatoms, fragments and spores of algae, together with the 9) smaller micro-crustacea suspended in the inhalent current which is continually passing between the mantle lobes. This current is set up by the cilia on the gills and palps, the water is filtered by means of the gills, and the microscopic matter is entangled in mucus and conducted to the mouth. The foot is a great mucus-secreting organ, and the labial palps and lips direct the food current to the mouth opening. When dredging on Pecten grounds, empty shells are frequently dredged up, which are neither old nor have the appearance of having been unoccupied for long. It is probable that starfish, together with the whelk, are accountable for some of these empty shells. A large dog whelk in Port Erin aquarium had killed and partially eaten a P. maaimus by getting the anterior end of its shell between the separated valves of Pecten, and then attacking the adductor muscle with its proboscis. Parasites are very scarce, no internal ones having been met with in any of the specimens sectioned. Lichomolgus maaimus (8) is, however, an interesting ectoparasitic copepod which may be obtained by washing in sea water the gills and mantle to which it adheres. It is of an orange colour, very like that of the gills, and, so far, has only been found in P. maximus, from which the specific name is taken. Very often the shells of Pecten are bored through by Clione celata (a boring sponge). This ramifies extensively between the outer and inner layers of the shell, and gives off short shoots which pass outwards to the external and internal surfaces of the valves. At the points where these tubes perforate the internal layer of the shell, the mantle secretes calcareous nodules of a dark grey or black colour. . The outer surface of the upper valve forms, as one 10 would expect, a good platform for such sessile animals as Balanus, Zoophytes, Serpula, &c.: and the upper valve, of nearly all the specimens of P. opereularis taken off the Isle of Man, and numbering several hundreds, was covered with a Halichondrioid sponge of a rich red colour. THE SHELL. Scallop shells are well known at most seaside resorts. They are sold as ornaments, and have been put to various uses by the fishermen. They were used, moreover, in very early times, and it has been supposed that the flat valves were the plates and the hollow ones the drinking cups of Fingal and his heroes. Until recently, in the Isle of Man, primitive lamps were made from the deeper shells. The majority of Lamellibranchs are equivalve and inequilateral, the right and left valves being mirror images. Pecten, however, shows a departure from this rule as the right and left valves are symmetrical, and in some species, e.g., P. maaimus, are very unlike each other. The equilateral character is in some species disturbed by the areas near the hinge line being unequal in size. The hinge line is practically straight, and a strong internal cartilaginous ligament is situated in a deep triangular pit, under the beak of each valve (PI. L., fig. H, Zg.). The characteristic shape of the valves is given by the auricular area developed on each side of the beak of the shell (Rite fer Sh.a.); The shell of P. maximus is brittle and rather light for the size, which is what one would expect since a heavy shell would be detrimental in swimming. It 1s very inequivalve, the right valve (Pl. I., fig. C) being very convex, whilst the left (Pl. I., fig. D) is quite flat with a concave area near the umbo. In P. opercularis the shell is almost equivalve, both valves being convex, EE the left, however, is slightly more convex than the right (see Text-fig. 1). Both species have suborbicular valves, and these are marked by plications so that the outer surface has a number of ribs arising near the umbo. The ribs are not present in old specimens of P. maximus on the areas immediately adjoining the umbos. a i Fie. 1. Diagrammatic sections of P. opercularis and P. maximus to show shape of valves in natural position. The number of plications appears to be constant throughout life. no new ones arising by bifurcation or interposition, and there are fewer in P. maaimus than in P. opercularis. The average numbers ean be obtained from the following table given by Davenport (41) for the shells of P. opercularis from three localities : — Ribs. Off Eddystone. Irish Sea. Firth of Forth. 14 O27 0) on i O221o7 15 By (OH) Bre Ow, Sie Ge 16 Ti, aa O/, 27 44% 63 12-4% 17 195 364% 152 248% 154 303% 18 182 340% 219 35:7% 164 32:3% 19 66 12:3 % 159 25:9% Soy ISO 20 @) mis O% aby YESS 20 39% 21 0 a0C Seca, Zi O39, 22 O27, iO: 2)0/5 536 614 508 Davenport has also given the relation of the dorso- ventral diameter to the antero-posterior diameter, for 1,657 shells of P. opercularis from these same localities. The results show that the smallest shells are from off the Eddystone lighthouse, the largest from the Firth of Forth, and the intermediate ones from Port Erin in the Irish Sea. 12 Also that the shells of a given dorso-ventral diameter are longest at the Eddystone and roundest at the Firth of Forth. Davenport concludes from the numbers that the ancestral Pectens had a relatively greater dorso-ventral diameter, and that modern ones are becoming longer, since the measurements indicate that change. The variations recorded with regard to most qualities and the size of shells indicate that the Eddystone and Firth of Forth forms are the extremes in a regular series, the Irish Sea specimens being intermediate. The difference in latitude means a difference in temperature, and probably also in the density of the water. By means of the ribs and their secondary thickenings on the inner surfaces of the shell, the two valves interlock and shut closely along the ventral margin. The external ribs and grooves are sculptured with well-marked striae, radiating from the umbo. They are due to the presence of minute denticles arranged regularly in rows. There is also a prominent concentric marking as if the shell was made up of a series of lamellae. These are much more pronounced in places forming definite rings which, since they occur very regularly and in the same positions, may be considered as indicating the age of the shell. A P. maaimus whose dorso-ventral diameter was 7°75 cm. and antero-posterior diameter 86 cm. had an indicated age of three and a half years. The two valves are joined along the hinge line by a narrow external lgament, present in addition to the thick internal ligament for the opening of the shell. The former simply unites the two valves and acts as hinge. The internal ligament is triangular in section, and in appearance like dark brown indiarubber. It fits into, and is attached to, the valves in deep triangular pits. In side view this ligament is also triangular, the apex 13 being nearest the hinge line and the base furthest from it. When the valves are closed the ligament is compressed and the free surface becomes very convex, so that the shell is only kept closed by the adductor muscle over- coming the resistance of the ligament. It will be noticed in both species that when the valves are closed there are two places, one on each side extending from the hinge line to the greatest antero-posterior diameter, where the shell edges do not meet. It is through these two prominent gaps that the water is forcibly ejected in swimming. Owing also to this feature, sea water cannot be retained in the pallial cavity when the animals are removed from their natural habitat, and hence Pecten lives but a short time compared with the Mussel and the Oyster, when exposed to the air. In P. maximus the convex valve overlaps the flat valve by from one-eighth inch to one-quarter inch when they are closed. Jeffreys describes the hinge plate in P. maaimus as toothless, but mentions certain ridges present on it. There are several tooth-like ridges both on the anterior and posterior sides of the ligamental pit, and these inter- lock when the valves close, fitting into grooves between similar ridges on the other hinge plate. They are not developed in P. opercularis. There are, further, two prominences on the right valve just at the point where the auricular areas meet the main portion of the valve (Pl. I., fig. HE, Sh.p.). These two tuberosities rest in two depressions on the left valve when the shell is closed. In both P. maximus and P. opercularis the auricular areas are almost equal in size, and in the former almost similar in shape, with the anterior and posterior margins inclined slightly, making an obtuse angle with the hinge line. In P. opercularis the posterior edges incline, making an obtuse angle asin P. marimus, but the anterior 14 margins form acute angles, and that of the right valve is reflected so that the anterior left auricle overlaps it at this point. The valve is also depressed here slightly, so that a eroove is formed, known as the Byssal Notch, and it is deeper in young forms than in the adult. Since the foot is situated so near the hinge line, it is probable that the eroove is due to its presence, because the valves would otherwise have to open much wider for the protrusion of foot and byssus than is the case in the majority of Pelecypods where the foot is protruded ventrally. This would also account for the greater depth in younger forms and absence in the adult P. maaimus. At the base of the byssal notch are three tooth-like processes, the function of which is unknown. The hinge line is almost level, but in the convex valve it rises slightly on either side of the umbo in such a way that when the shell is closed the most dorsal point is formed by the convex valve which is slightly folded over to join the upper flat valve. The inner faces of the valves are marked by impres- sions indicating the attachments of the various muscles. The Pallial Line is a scar marking the attachment of the numerous retractor muscles of the mantle edge. It is a sinuous line extending without break or indentation (owing to the absence of siphons and their retractor muscles) almost parallel to the shell margin, at a distance of about one and a half inches from it, at the ventral border (Pl. I., fig. E). . The adductor impression is larger on the flat upper valve than on the lower convex one. This impression is, moreover, situated nearer the ventral margin of the shell on the left valve than on the right, owing to the oblique track of the muscle fibres. The single retractor of the foot is attached to the left valve, but its impression forms part of the adductor impression. 15 Microscopic Structure. The observations of Jackson (3) on the earliest shell of Pecten irradians show that the ‘“ prodissoconch ” (the completed first-formed shell) has a homogeneous and laminar structure with fine concentric lines of growth, no indications of the byssal notch, and is dimyarian. The byssal notch arises in the next stage, the ‘“ dissoconch,”’ which is sharply separated off both in structure and shape from the early shell, for a thin layer of prismatic cellular tissue was observed in the right valve extending over the whole shell. There are no ears nor plications of the shell at the early dissoconch stage, though they appear very soon after, and this is interesting because the Devonian Pterinopecten, an ancestral genus transitional between the Aviculidae and the Pectinidae, also shows but shght development of ears. It is very difficult to cut sections of the adult shell owing to its brittle nature; but I have been able to examine a transverse section cut along the antero-posterior diameter of P. opercularis and a section along one of the ribs, that is, along the dorso-ventral diameter of P. maximus (right valve). The structure of the shell is practically the same in both species, but P. maaimus is much coarser than P. opercularvs. The sections differ considerably in appearance from those of Anodon, Mytilus and Cardium, and one cannot trace the three typical layers—periostracum, prismatic layer and nacreous layer. The first appears to have been worn away in these adult shells, though traces of it may be seen in the hollows. The calcareous structures seen probably represent both the prismatic and nacreous layers, but the crystals are not laid down as prisms, neither can two definite layers be made out. The shell is composed 16 mainly of aragonite, the crystals of which appear to inter- lace and to be arranged very irregularly (Plate II, fig. 2). In transverse sections across the ribs (fig. 2), the flattened crystals are laid down so that the structure appears to be lamellar, somewhat like the nacreous layer of other Lamellibranchs. These lamellae run practically parallel to the surface of the shell, and each rib is formed by a great thickening of this lamellate layer, the lamellae being arranged to form two crests as figured. The structure of the shell between two ribs is more irregular, and recalls the geological structure known as false bedding—the laminae lying in various planes. While the median portion of the thickness of the shell is as described above, the external surface layer is formed of crystals which are arranged in some places perpendicularly, or nearly so, to the surface of the shell, and in this way a kind of pseudo-prismatic layer is built up, but it passes gradually into the coarser and more irregular layer below. The inner surface of the shell is also laminar in structure, the laminae being practically parallel to the surface. If the shell sections be cut through the adductor impression, a thin, delicate layer (Pl. II, fig. 2, SA. m.) will be found situated between the inner lamellar layer and the adductor muscle. This is the hmy-looking layer seen in surface view of the muscle impressions, which sometimes adheres to the muscle and can be pulled away with it. It is best seen in sections through a young Pecten, the shell of which has been decalcified. This layer appears to be made up of numerous fine rods placed side by side, vertical to the shell surface. In sections of older shells, the rods are not so distinct, but the layer shows very definite striae perpendicular to its surface. It is by means of this “ Durchsichtige 17 Substanz ” of List (6) that the adductor muscle is attached to the shell, and it is secreted by the modified mantle epithelium of the muscle area, which in the adult is very difficult to trace. The formation of lamellibranch shells is not yet completely understood. The Intussusception theory of Méry assumed that the shell was itself a growing body. Réaumur, after Regeneration experiments, laid the foundation of the Secretion theory, according to which the shell is a secretion product of the animal. This is the theory now generally accepted. The periostracum can be traced to the actual secreting cells in the periostracal groove of the mantle edge, but difficulties have arisen in connection with the other layers, and there is no doubt that the Intussusception theory originated through the difficulty of understanding the formation of a complex shell structure from a solution or secretion partly organic and partly inorganic. In those Lamellibranchs where an outer, prismatic, layer is present, this is secreted and grows only at the mantle edge. The inner nacreous layer, or that part of the lamellar layer of the Pecten shell corresponding to it, is unlimited in growth, and is formed by the outer surface cells of the mantle. The colour of the shell varies considerably. In Pecten maazimus the upper valve is very generally reddish brown, the lower having a somewhat lighter yellow tint; both valves may be mottled with bands or streaks of burnt umber or yellow. P. opercularis varies still more, and may be almost any shade of red, pink, orange, yellow, purple or brown, with streaks and blotches. Both species are sometimes quite white, with a slight orange tint at the umbos. The inner surfaces of the valves are smooth and porcelain-like in appearance, with very frequently in P. mavimus a broad band of a dark chocolate or burnt B 18 sienna colour between the pallial line and the margin of the shell (Pl. I., fig. F). This, however, is absent in some specimens, and does not occur in P. opercularis. GENERAL ORGANISATION AND MANTLE. It is difficult to kill and preserve the specimens with- out a considerable amount of contraction and distortion taking place. Crystals of menthol dropped into the sea water in a small dish containing a specimen of P. opercularis produce the best results with the least retraction of the tentacles and mantle. For P. maaimus. the mixture of Lo Bianco, spirit glycerine and sea water, floated gradually over the water in the vessel containing the specimens, gives very good results. When narcotised sufficiently in this way, the animal should be placed in 5 per cent. formalin, and may remain in this until required, the muscle, however, becoming somewhat hard. The animal should be removed entirely from the shell by separating the mantle lobes carefully with the handle of a scalpel and cutting the attached portions of the adductor muscle, and can then be pinned down and examined under water. For serial sections, the smallest specimens obtainable should be dropped into Perenyi’s fluid or Pikrosulphuric, and fixed according to the usual directions. These fluids dissolve also the calcareous part of the valves so that the specimens are ready for embedding after dehydration. When removed from the shell it will be seen that the viscera and body proper are hidden between two folds of the body wall, the mantle or pallial lobes, which are almost of the same shape and size as the valves of the shell to which they were attached by muscles (PI. TI., fig. I, Mn.). These lobes enclose the pallial cavity, in which LS lie the gills (fig. 1, Br. d., Br. a.) and the lower part of the visceral mass. The Mantle consists of two thin lobes, folds of the tegumentary layer of the body, with epithelium covering both external and internal surfaces (fig. 4, #. Mn.), and but little connective tissue and muscle fibres except at the free margin which is much thickened and muscular. The mantle epithelium is the outermost layer of the body, the shell being a secretion on its surface. The outer layer which lines the shell extends from the hinge line (where it becomes continuous with the same layer on the other side) to the ventral edge of the mantle, as a con- tinuous sheet. It is to be found, though modified, between the adductor muscle and the shell, lying between the muscle fibres proper and the peculiar calcified layer (fig. 2, Sh. m.) which is found on the internal surface of the shell at the muscle impressions. The inner layer is reflected inwards at several points to be continued over the visceral mass. | For example, it passes over the adductor muscle and on to the gonad; dorso-posteriorly it runs across from one mantle fold to the other just above the pericardium (fig. 1, Per.), partly forming its roof and supporting the posterior pallial artery (fig. 14, A. p. p.) which can be easily seen running up towards the hinge line. The two layers of the mantle do not pass over the sides of the digestive gland (fig. 1, Dg.). The inner one becomes closely apposed to it, anteriorly and posteriorly, forming the body wall here, whilst the outer epithelial laver alone clothes the sides of the gland. Dorsally the right and left mantle folds are con- tinuous along the full length of the hinge line, as has already been pointed out, but the level of this is broken about the middle of its length where there is a rectangular 20 depression of the mantle (fig. 1, Lg. P.). Into this depression the ligament dips, lying transversely across it. There are no fusions of the mantle edge to form separate inhalent and exhalent apertures, and consequently there are no siphons. The inhalent and exhalent currents are, however, confined to special regions, so that physiologi- cally the fusions are not needed for the separation of the currents. By scattering some carmine into water in which a Pecten is living, the particles of colour can be seen entering all round the shell between the two folds of the mantle, except for an area extending from the posterior end of the hinge line for a short distance forward. Here there is a very definite exhalent current sometimes accelerated by the animal closing the shell suddenly and forcing the water out at this point only, to eject the faeces. The free margin of the mantle lobes is much thickened and presents three typical folds (fig. 4). The outer one, the shell fold (fig. 4. Sh. F.), is small and bears long tentacles. The median one, the Ophthalmic fold (fig. 4, Op. F.), is not so distinct and also bears tentacles and the eyes which form conspicuous objects when the animal is alive. The most internal fold is much the largest and is turned inwards to form a flap, known as the “velum” (figs. 1 and 4, V.). It is usually pigmented either continuously or at regular intervals. List (6) has shown that the storage of pigment in the mantle cells is directly influenced by light, and that removal of a piece of the shell causes a deepening in colour of the tissue exposed, due to formation of pigment. This curtain-like velum becomes reduced in size as it approaches the base of the angle forming the ears, and it is this inner portion of the mantle on both sides that fuses as mentioned above. The outer folds remain free, with their eyes and tentacles, 21 until the dorsal margin is reached. The tentacles (fig. L, Tn.) ave long, very extensible and active on the outer fold, while those arising from the velum (fig. 1, 7’n. v.) are short and move but little. | When fixed they appear papillose, but this is due probably to the great difficulty in fixing them without contraction and folding of the surface tissue. The outer tentacles are roughly separable into two groups, a series of short tentacles, mainly one row deep, lying next to the shell, and longer ones capable of much extension and contraction inserted in one or two irregular rows. The former are unpigmented in both valves, and le, when the shell is opened, curved back over the shell. The others of the upper or left valve have a streak of pigment on their upper sides, and a similar, but less intense, streak is present to the same side of these tentacles on the lower valve. Further details in regard to the eyes will be given in the chapter on those organs. When the valves of the shell are separated the two vela hang at right angles to the plane of the valves, just touching, like two curtains. The small tentacles he across one another, and form a rude grating. The velum, as we have seen above, is of great importance in connec- tion with locomotion. It has been pointed out in considering the muscle impressions on the shell that the fibres of the adductor cross the body obliquely (figs. 46, 47, A.s.), the result is that the right mantle lobe has a free portion of much greater area than the left. HistoLoGicaL STRUCTURE OF THE MantLe.—Over the whole surface of the mantle there is a single layer of cubical or columnar epithelial cells, forming the epidermis. These cells become much more distinctly columnar towards the free edge of the mantle, and are in many places crowded with pigment granules of a dark 22 brown colour, particularly on the velum. A very delicate cuticle is also present. In the young Pecten the epidermal cells near the margin of the mantle and on its outer surface are very long compared with those of the epidermis elsewhere, and are evidently active secreting cells of the shell substance. In adult specimens this great difference is not seen. The columnar cells on the free margin of the mantle lobes, especially on the eye stalks (fig. 55), have a very peculiar appearance, due either to delicate connecting bridges like the “ prickle cells”’ or to the walls having processes which interlock; most probably the former. Lying amongst these epithelial cells are numerous sense cells (‘“pinselzellen’’), to be described later in the chapter on the sense organs. Underlying the epidermis, there is at the margin of the mantle lobes (fig. +) a substantial connective tissue, consisting of delicate fibres with few scattered nuclei. There are numerous blood spaces in this layer, and the circumpallial artery (fig. 4, A.c.) and the circumpallhal nerve (fig. 4, V.c.) pass through it, in close proximity, the blood vessel being situated on the shell side of the nerve. Passing inwards, away from the margins, the mantle lobes become extremely thin, the structure being more and more trabeculated until, after passing the line of attachment of the pallial muscles, there is practically nothing between the epidermal layer of cells but bridges of fibrous tissue, large spaces being left in which are to be seen numerous blood corpuscles with large nuclei. Ramifying in the connective tissue before mentioned, at the margin of the mantle lobes, are the pallial muscles (igs 3) 4 eco ewan): The pallial musculature of Pecten is both important and complex, and the edges of the mantle are very well supplied, owing to the energetic part played by the velum 23 in the act of swimming and the necessity of withdrawal and protrusion of the edge with its numerous sensory structures. It has both radial (fig. 3, P. 1. r.) and what may be termed concentric muscles; the latter extend round the margin of the mantle parallel to its free edge, and are well developed in the velum (fig. 4, V. d/.c.), which has a very compact muscular structure. The radial muscles are the most obvious when examining the mantle, for it is these which attach the mantle edges to the shell and retract them when the valves close. The hne of attachment on the shell has been previously seen to be a continuous line extending almost parallel to the shell margin and at some distance from it, furthest at the ventral edge and approaching it anteriorly and posteriorly. These pallial muscles proper arise, where attached to the shell, as slightly separated bundles of fibres, as if, in fact, a bundle had the end frayed out slightly. These separated fibres almost immediately come together again to form a conspicuous large fibre which radiates out to the margin and breaks up into very numerous finer bundles, which interlace and become crowded together as they reach their termination at the base of the velum. Between the outer pallial fold bearing the tentacles and the median one bearing tentacles and the eyes, there is a deep groove, known as the Periostracal groove (figs. 4, 6, P. gr.), and in sections the periostracum can be seen arising from the base of the groove through the coalescence of several short fibres from the secreting cells. From here it is continued out, and passes over the edge of the shell to its outer surface. At the bottom of the groove lying along each side there is a ridge formed by much elongated epidermal cells, 24 together with a fold of this layer with a slight support of the underlying connective tissue (fig. 6, P.gr.). The periostracum (fig. 6, P.) emerges from between the two ridges, the cells of which differ from those of the surrounding area. ‘They are glandular, and have deeply staining contents. The cells lining the side of the groove nearest to the eye bear long cilia, and resemble very closely the sense cells which will be described later. Very short cilia are present on the epidermal cells of the outer margin of the shell fold. The cilia are much better developed on the tip of the ophthalmic fold, which bounds the periostracal groove on the inner side. The epithelium of the inner surface of the mantle lobes 1s also ciliated. Insinuated between the ordinary epidermal cells on the outer surface of the mantle, near the margin are to be seen peculiar cells (fig. 5, Mos.) which contain numerous large rounded granules that stain bright red with eosin or a compound stain containing eosin, such as Mann's methyl blue-eosin. in some places these cells seem to be forcing their way to the surface, and in one or two cases the actual dehiscence of the cell and its contents is observed. They are similar to the cells described as eosinophilous cells by Herdman and Boyce in the Oyster (42), and in all probability are wandering cells exercising an excretory function. The tentacles of the shell and ophthalmic folds have a similar layer of columnar epithelial cells to those found on the margin of the mantle, but sense cells are particularly numerous at their tips. The connective tissue of the tentacles (containing muscle fibres running longitudinally from the base to the tip) is divided into segments by transverse muscle fibres, which radiate out from the core of the tentacles to the periphery. A branch from the cireumpallal nerve 25 innervates each tentacle, passing up the centre and giving off branches to the sense cells. If the mantle lobe of one side, preferably the might (where the adductor muscle is attached much nearer to the hinge line), be removed, the general topography of the viscera can be easily made out. The various organs thus exposed are shown in Pl. II, fig. 1. The single adductor muscle occupies a fairly central position (fig. 1, A.u., A.s.), and serves as the support for the greater part of the animal which surrounds it. Against the hinge line is the deeply pigmented, green-black looking gland, the so-called liver, which will be referred to as the digestive gland (fig. 1, Dg.). The gills (Br. a., Br. d.) ave very conspicuous structures, lying between the visceral mass and the mantle and attached to the latter on the right side, so that if the mantle were cut away close to the adductor the gills on this side would also be removed. They consist of a long series of orange coloured filaments suspended from a basal lamina. The body proper may be divided into :—(1) Viscero- pedal mass, (2) the pericardium and rectum, and (3) the renal organs. The viscero-pedal mass consists of (a) the Digestive Gland which is situated at the posterior and dorsal extremity and encloses the stomach, and (0) a long, flattened, tongue-shaped reproductive portion, of a brown colour over the whole area, or if the gonads are ripe— white for part of its length (the testis), and pink or brilhant scarlet for the rest (the ovary). There is no distinct division between the digestive gland and this latter portion of the viscera, but just where they are contiguous the rudimentary foot (fig. 1, 7.) is situated. It is roughly cylindrical in shape; the distal portion, how- ever is sucker-like, with a deep cavity. The foot, it will 26 be seen, appears as an appendage quite distinct from the rest of the visceral mass, and contains no extensions of the reproductive organs. The pericardium (fig. 1, Per.) is situated posterior to the digestive gland. The rectum (fig. A/. ¢. 5) passes through the ventricle of the heart, which is enclosed by the pericardium, and is continued over the adductor muscle, to which it is attached, bending to one side of the median line and eventually terminating in a lipped anus. The aperture of the mouth is placed not far above the foot on the anterior surface of the digestive gland between the two very conspicuous dendritic lips, pigmented with an orange colour (fig. 1, L. p.). At each side where the gills terminate dorsally are two flaps, also pigmented with a yellowish brown colour. These are the Labial Palps (fig. 1, L. p. e.); they become continuous dorsally with the lips. The renal organs (fig. 1, #. 0.) are situated on each side of the reproductive portion of the viscera between it and the gills, and the external opening at their ventral end serves both as renal and reproductive aperture (fig. 1, Ro. Ti \) The positions of these various organs in relation to the shell are not the same as those in the Dimyaria. Thus the pericardium is posterior, the digestive gland (** liver ”’) is dorsal and the foot and visceral mass are situated anteriorly, the hinge line being considered as dorsal. Owing to this, some authors have regarded the hinge line as dorso-anterior, and the antero-posterior diameter as represented by a line drawn from the front corner of the hinge line to the point where the rectum ends. The position of the organs is regarded as due to an increase in size of the posterior adductor after the disappearance of the anterior adductor, together with a movement of the 27 muscle to a more central position. A shortening of the length of the body with a closer attachment of the viscera to the muscle (which plays a prominent part as a support, and rotates slightly), would bring about the conditions observed. Throughout this Memoir, however, the hinge- lie has been taken as marking the dorsal edge of the body. THE MUSCULATURE. Pecten belongs to the Monomyaria, since it possesses only a single adductor muscle. The possession of one adductor muscle by certain lamellibranchs does not indicate genetic relationship, and species which are Iso- myarian, Anisomyarian and Monomyarian may all be found in a single family. In addition to the adductor there are present, the orbicular retractor muscle of the mantle (pallial muscles), a single retractor muscle of the foot on the left side, the intrinsic muscles of the foot and visceral mass, and the heart or cardiac muscles. The Adductor Muscle of the Shell (fig. 1, A. s. and A. u. and fig. 47) is the posterior one of those forms with two adductors present. In the early stages, after the free swimming larva, we have first a protomonomyarian stage when the anterior adductor is formed and is alone present. The next is a dimyarian stage when the posterior adductor is present in addition to the anterior. These two stages are quickly passed through, the anterior adductor disappears and the posterior increases in size and takes up a more central position. This may be called the deutomonomyarian stage. The muscle stretches obliquely across the body from one valve to the other. The attachment to the shell is more dorsal on the right valve, and, owing to the fact that the fibres cross obliquely, the various organs of the body that surround 28 the muscle are also asymmetrical, and the right mantle lobe is of much larger extent below the adductor than the left. There is an obvious separation of the single adductor into two parts (fig. 1, A. w., A. s.) cne of which is of different structure from the other. In the fresh or living animal these two regions are easily distinguished by their different appearance, but they are quite distinct even in preserved specimens. The greater part of the muscle (Add. s.) has a colour- less, semi-translucent appearance, and this part is cylindrical in section near the right valve, but elongates and increases in area as it approaches the left valve, where the muscle impression is slightly larger. Lying against the posterior surface of this main portion, but clothed by the same connective tissue sheath that passes round the two parts and binds them together, is a narrow bundle (Add. u.), crescent shape in section and made up of white, more opaque looking fibres. Coutance (13) and Thoring showed that the larger part serves only for the rapid spasmodic closing of the shell, while the small portion serves for slower but more forcible and sustained activity. If one valve is taken away, which means that the attach- ments of the adductor are cut through, the small white portion falls into a state of permanent contraction (‘ tonus’’) and thus in fixed preparations this portion of the muscle is generally much more strongly contracted, and, therefore, shorter than the larger part of the muscle. The other part contracts and relaxes rapidly if stimu- lated. It is obvious that this development is correlated with the function of swimming, and that the clapping of the valves of the shell is due to the large translucent portion of the adductor, whereas the more permanent closing of the shell is due to the much smaller part. P. 29 mavimus can resist a considerable pull for a short time, 4,000 grams are not sufficient to pull the valves apart unless acting for some time, when, as is the case with other lamellibranchs, a much less weight suffices to open them, in fact, as has been shown, starfishes are able to open oysters by a sustained pull. Corresponding to these differences in appearance and function there are differences in the histology of the two regions. The fibres of the large, rapidly contracting part, when seen in sections, show a very obvious striation, the smaller portion of the muscle consists of smeoth fibres. This relation between the cross striation of muscle fibres and rapidity of movement is of general occurrence (13 & 15). The striated fibres are very much flattened so that they can be seen either in surface or in edge view (fig. 30, 6. and a.). If small portions are fixed in osmic or Flemming and stained with iron haematoxylin it is quite obvious that the striping consists of distinct transverse bands; there is no possibility of its being only an appearance due to fibrillae being thrown into spirals when in a contracted state. The dark bands are three or four times as long as the light, almost unstained, portions. Moreover, the fibres have a series of constrictions which correspond in position with the light stripe; this can be seen extremely well if a fibre is observed in edge view, so that the dark portions correspond to the swellings and the light stripes to constrictions. The difference in intensity of the stain taken up by the two parts, however, is so great that it would be difficult to affirm that the dark stripes are due to a greater thickness of stained protoplasm, though it 1s possible that this may be the case (see 14). The nuclei of the fibres are not frequent in occurrence, and are pushed rather to one side of the fibre and elongated, 30 The muscle is well supphed with blood brought by the adductor artery, and the whole substance of the muscle is permeated with lacunar spaces in which blood cor- puscles can be seen. The adductor contains also a very large quantity of glycogen, which can be easily extracted with water and the characteristic tests applied to the solution. The means of attachment of the adductor muscles to the valves can be best observed in complete sections through a very small Pecten, the shell of which has been decalcified. The union of the muscle fibres with the shell is carried out by a special attachment epithelium, the cells of which fuse with the muscle fibres so that their original epithelial nature is difficult to trace; and this tissue element appears to secrete the specialised layer of shell at the adductor impressions (fig. 2, Sh. m.). The Radial Pallial Muscles (figs. 1, 3 and 4, Pail. M. 7.) are confined to the edges of the mantle lobes, and their attachments and course as seen in surface view, have been described above. At the point where they are attached to the shell, the epithelial cells can be seen extending between them and the shell, but slightly modified. From this point, where the fibres are inserted very obliquely, they pass outwards, towards the margin of the mantle lobes, drawing gradually nearer to the inner surface of the mantle, until most of them terminate at the base of the velum. In certain sections taken through the mantle of P. opercularis, some of these fibres appear to be striated, the stripes being apparently transverse. The striping, however, is not nearly so obvious nor so regular as that of the adductor muscle, and, moreover, 1t cannot be seen in all sections, even those cut very near to each other and treated with the same fixative and stains. The question arises, therefore, whether this cross striation seen in some of the radial pallial muscles is not due to the 31 fibrils being thrown into folds by contraction, producing an apparent striation only. ‘Transverse striation has also been observed in Pecten opercularis, on the ctenidial muscles (fig. 45, Br. m.), the appearance here being exactly as in the mantle. Both cases are probably due to contraction. The Circular Muscles run parallel to the margin of the mantle and are very well developed in the Velum (fig. 4, V. J. ¢.), which is made up almost wholly of these muscle fibres. When Pecten closes its valves rapidly, whilst swimming, the water between the valves must endeavour to escape at the ventral margin by forcing the two vela apart. One can see, then, the use of this develop- ment of circular muscles, because if the vela are kept in a rigid condition by their action, the water will be com- pelled to pass out at each side dorsally, near the hinge line, as previously described. These circular muscles are inserted into the shell in conspicuous bundles anteriorly and posteriorly (fig. 3, V. M/. a.) at the same level as the fusion of the mantle lobes. The Retractor Muscle of the foot is the posterior retractor of the left side, and is the sole representative of the four retractor muscles which attach the foot and con- tained viscera to the shell in the majority of lamelli- branchs. In monomyarian forms, the two anterior retractors are usually absent, but Pecten has gone further, and, moreover, the single retractor which is obvious in P. opercularis has become even more vestigial in P. MALUMUS. In both species the attachment to the shell is in the same position, along the dorsal margin of the adductor muscle, near the junction of its two parts, and the retractor impression on the shell cannot be distinguished from that of the adductor. o2 The fibres are inserted at a considerable angle, and from the shell, they pass first as a flat band and then, becoming circular in section, across the dorsal surface of the adductor, directly towards the base of the foot. This brings the Retractor under the pericardium and the digestive gland until it reaches the visceral mass, through which it plunges, just at the junction of the digestive gland and reproductive organ, lying enclosed in a fairly definite blood space. Transverse sections through the muscle close to the base of the foot show (fig. 47, B. 4.) that the muscle has taken a tube-like form, enclosing the byssus gland. The muscle fibres pass around the gland, which has the form of compressed pouches separated by lamellae of connective tissue, and ultimately they become lost in the tissue of the foot. The Intrinsic Muscles of the foot make up the bulk of the tissue in this part of the body (fig. 8). They run chiefly in two directions. There is a definite layer of circular muscle fibres underlying the surface and extending all round the foot, more internal still is a series of longitudinal muscles running along the axis of the foot. In addition there are many fibres diverging radially from the centre, and also scattered fibres passing in various directions. Other intrinsic muscles are to be found in the visceral mass in the reproductive region. There is a layer of transverse muscles passing round in the connective tissue sheath which encloses the visceral mass, and con- nected with this sheath are scattered muscle bundles running across from one side to the other and serving to strengthen and form a support for the alveoli of the gonad. The Ctenidial Muscles (fig. 45, Br. m., Br. m., Br. mJ) ave arranged as follows:—There is first a layer 33 of muscle fibres (fig. 45, Br. m.’) underlying the epithe- lium but separated from it by connective tissue; these run, like the gill filaments, at right angles to the axis. More remote from the surface there is a somewhat scattered layer of fibres running in the direction of the gill axis. Internal to these again and _ separated from them by more connective tissue is another layer of fibres running in the same direction as the first described (fig. 45, Br. m."). In addition to the above there are two very important compact bundles (fig. 45, Br. m.) which run longitudinally along the gill axis. They are situated at the sides of the axis just above the point at which the various filaments separate from one another (Br. m.). In certain sections of P. opercularis these muscles have shown a very similar striation to that of the pallial muscles. These last muscles serve for contraction of the gills. The Cardiac Muscles.—The auricles and still more the ventricle are well supplied with muscle fibres. They extend around the heart, lying just internal to the wall and passing in various directions from the walls across the cavity dividing it up, so that it has almost the appearance of a sponge. These muscles are described with the heart. It is interesting to note here, however, that in the specimens fixed and sectioned, no traces of definite striation were found on these fibres, except in one case, resembling that of the radial, pallial and ctenidial muscles. ROOT: The Foot is a very small organ situated high up on the anterior surface of the visceral mass (fig. 1, /’.), arising from the surface of the gonad close to the mouth. In shape, it is roughly cylindrical with a sucker-like termination (fig. 7, /’.s.). This free end of the foot G Bd which is almost bifid has a very deep cavity, the dorsal boundary wall of which extends further distally than the ventral, which is notched. Two sides of the foot can be distinguished, the dorsal and the ventral, the latter has a groove running longitudinally along its surface for about half of its length (fig. 7, P.b.). This is the byssal groove and communicates with the byssal gland. The deep cavity of the end of the foot is continued down the centre until it almost reaches, if it does not communicate with, the cavity of the byssal gland and groove. The foot is very contractile, and in fixed specimens is usually much contracted and wrinkled; it does not contain any extensions of the viscera, and the greater part of its bulk 1s composed of muscle fibres running in various directions in a groundwork of connective tissue. It is bounded by the usual epidermal layer of epithelial cells, which are columnar, the depth being about three times the width. These cells are ciliated over the whole outer surface, and even extend into the deep cavity of the end of the foot. These ciliated cells are very fine objects for showing the striated cell margin seen in ciliated epithelium. The epidermis lining the cavity of the foot differs, however, from that on the outer surfaces in that the epithelial cells are compressed in the middle part of their length, so that they are somewhat hour-glass shaped and have interposed between them many mucous glands (fig. 10, Mu.g.). In these, nuclei are indistinguishable, but from the size and shape it is extremely probable that these glands are unicellular. In places, in sections, the mucus can be seen emerging from between the epithelial cells, and if the foot of living specimens is examined the cavity will be almost always found full of mucus. In 35 addition to these there is another layer of mucous glands (fig. 10, Au. g.¢.) situated more internally but not far from the epidermal layer above described. These appear to be similar to the mucus-secreting glands described by Johnstone (4) as occurring on the foot of Cardium. The glands consist of groups of cells aggregated together ; sometimes where a group is more distinct it can be seen to consist of about 5-8 cells forming a kind of bulb. From this clump of cells a long stalk arises which passes to the surface and insinuates itself between the epithelial cells; it may divide into two or more branches just below the epidermal layer. The stalk is non-tubular, and the contours of the cells composing it cannot be distinguished. The ground substance of the cells is finely granular, and stains a peculiar grey-blue tint with methyl-blue-eosin. Under the epidermis there is a layer of connective tissue comparatively free from muscle fibres, and the rest of the foot is made up, as previously mentioned, of connective tissue and muscles. Large blood spaces are to be found scattered through the connective tissue and connected at the base of the foot with the pedal artery which enters it on the dorsal side; the blood lacunae are connected with others which pass over the visceral mass to the dorsal extremity of the renal organ. There is also a very abundant nerve supply; the pedal ganglia, as will be seen later, are not situated in the foot. Two pedal nerves pass from these, and after entering the foot break up into smaller bundles (fig. 8, N.p.), which ramify amidst the connective tissue and innervate the muscles. The Byssal groove which is seen on the ventral surface of the foot, is a deep groove lined by ciliated cel's, and extending almost half way across the diameter of the foot. In Pecten opercularis the foot is twisted so that the 36 surface with the byssal groove faces the right valve, and it will be remembered that it is the right valve of the shell that has the indentation known as the byssal notch. Though there are no traces of the byssus in the adult P. maximus, the byssus gland is very well developed, It is situated very deeply in the tissue, in fact practically outside the foot, in the midst of the retractor muscle. If a series of transverse sections is followed from the byssus groove region of the foot to the retractor muscle, the following sequence will be observed: —The byssal groove is rather wider at the bottom, and this cavity runs in towards the byssus gland. In sections taken below the byssus groove the sides of the groove have coalesced and the cavity alone is present. As we pass further in, the dorsal wall of the cavity becomes ridged by longitudinal projections, which gradually meet the ventral wall, so that ultimately the original cavity is divided up into compartments by parallel partitions running across from the dorsal to the ventral wall (fig. 47, B.g., and fig. 9). These compartments are deep and wide, but very narrow. Sections showing this structure pass through the retractor muscle alone, and are therefore posterior to the actual foot itself. The partitions are composed of connective tissue in which are to be found many muscle fibres, and are bounded by a layer of epithelial cells almost cubical in shape, and of course continuous with those of the byssal gland. They are well provided with cilia. The compartments terminate blindly, and at the same time become reduced in width; but at their blind ends, the cells (fig. 9 B.g.c.) are rather larger than the other epithelial cel's and contain practically no contents.