(2)Rhabdocoela, which possess a complete alimentary tract separated from the body-wall (except for a few suspensory strands) by a space or body-cavity, filled with fluid. This space is sometimes (Vortex viridis) lined by an endothelium of flattened parenchymatous cells. There are two compact testes, which are enclosed (as are the ovaries and yolk-glands) in a distinct membrane. An otolith is present in some genera and species. Terrestrial, fresh-water, marine.
(3)Alloeocoela, in which the body-cavity is greatly reduced. Except in the Bothrioplanidae, the gonads have no distinct membrane. Testes numerous; yolk-glands present. Marine with a few exceptions.
Occurrence and Habits of the Rhabdocoelida.—TheAcoelaare usually minute, active Turbellaria abounding amongst weeds throughout the lower half of the Littoral, and the whole of the Laminarian zone, but are most plentiful in the pools exposed during spring-tides on our coasts, especially on the shores of Devonshire. The species ofHaplodiscus, however, andConvoluta henseniare modified pelagic forms found in the Atlantic Ocean.[61]Convoluta paradoxa(Fig. 19, B) is the commonest British species. It is from 1 to 9 mm. in length, and of a brown colour, marked above by one or more transverse white bars. The brown colour is due to a symbiotic alga, the nature of which has not been thoroughly investigated. In an allied species, however (C. roscoffensis), from the coast of Brittany, the alga, which is here green, has been carefully examined by Professor Haberlandt,[62]and it appears from his researches that the algae form a special assimilating tissue, enabling theConvolutato live after the fashion of a green plant. At Roscoff, these elongated greenConvolutalive gregariously in the sandy tide-pools, fully exposed to the sun's rays, and have the appearance of a mass of weed floating at the surface of the water. Access to the atmosphere and to sunlight are necessary in order to enable the assimilating tissue to form the carbohydrates, upon which this form lives exclusively. Not only has the alga itself undergone such profound changes (loss of membrane, inability to live independently after the death of the host) as to disguise its true nature (a tissue-cell derived from algal ancestors), but theConvolutahas also undergoneconcomitant changes, in form, in the loss of a carnivorous habit, and in the development of marked heliotropic movements, thus adapting itself to an holophytic or plant-like mode of nutrition. Nevertheless the Acoela, as a group, are carnivorous, feeding upon Diatoms, Copepoda, and small Rhabdocoela, the absence of a digestive tract indeed being probably more apparent than real.[63]
TheRhabdocoelalive under varied conditions. One form,Prorhynchus sphyrocephalus, has been found among plants far from water in the neighbourhood of Leyden, by De Man.[64]With this exception the group is purely aquatic, and though a few genera and even individuals of the same species occur both in salt and fresh water, whole sub-families and genera are either marine or paludicolous. Among the latter,Mesostoma,Castrada,Vortex, andDerostomaare common in brooks and ponds, especially at certain times, often only for one month (May or June) in the year. Species ofMacrostoma,Stenostoma, andMicrostomaare also abundant in similar places. The two latter occur in chains formed by fission; but the sexual individuals (which are of distinct sexes, contrary to the usual hermaphrodite condition of Flat Worms) only appear at stated times and are not well known. A large number of genera are purely marine, and one family, the Proboscidae (distinguished by having the anterior end invaginated by special muscles and converted into a sensory organ), is entirely so. The most cursory examination of littoral weeds reveals species ofMacrorhynchus,Acrorhynchus,Promesostoma,Byrsophlebs, andProxenetes, the character of which may be gathered from von Graffs great monograph, or from Gamble's paper on the "British Marine Turbellaria."[65]Much, however, still remains to be done before we possess an adequate idea of the occurrence of this group on our coasts.
fig19Fig. 19.—Forms of Rhabdocoelida.A,Mesostoma tetragonumO. F. M. (Rhabdocoela), × 10;B,Convoluta paradoxaOe. (Acoela), × 10;C,Vorticeros auriculatumO. F. M., × 6;D,Monotus fuscusOe. (Alloeocoela), × 4.ap, Adhesive papillae;d, intestine;m, pharynx;ot, otolith;rh, rhabdites;te, testes;ut, uterus with eggs;yg, yolk-glands; ♂, male, ♀, female genital pores. (Aafter Braun.)
Fig. 19.—Forms of Rhabdocoelida.A,Mesostoma tetragonumO. F. M. (Rhabdocoela), × 10;B,Convoluta paradoxaOe. (Acoela), × 10;C,Vorticeros auriculatumO. F. M., × 6;D,Monotus fuscusOe. (Alloeocoela), × 4.ap, Adhesive papillae;d, intestine;m, pharynx;ot, otolith;rh, rhabdites;te, testes;ut, uterus with eggs;yg, yolk-glands; ♂, male, ♀, female genital pores. (Aafter Braun.)
Fig. 19.—Forms of Rhabdocoelida.A,Mesostoma tetragonumO. F. M. (Rhabdocoela), × 10;B,Convoluta paradoxaOe. (Acoela), × 10;C,Vorticeros auriculatumO. F. M., × 6;D,Monotus fuscusOe. (Alloeocoela), × 4.ap, Adhesive papillae;d, intestine;m, pharynx;ot, otolith;rh, rhabdites;te, testes;ut, uterus with eggs;yg, yolk-glands; ♂, male, ♀, female genital pores. (Aafter Braun.)
Some Rhabdocoels are parasitic.Fecampia erythrocephala, which occurs in the lacunar spaces and alimentary canal of young shore crabs (Carcinus maenas), is a white cylindrical animal ¼ inch long, with a red snout. After attaining maturity it works its way out of the crab and encysts under stones, forming a pyriform mass in shape like a "Prince Rupert's drop." Within this case the eggs develop, and the young probably emerge through the open narrow end of the hard white tube, but how they reach the crab is not known.Graffilla muricicolais found in the kidney ofMurex brandarisandM. trunculus, at Naples and Trieste;G. tethydicolain the foot ofTethys.Anoplodium parasiticumoccurs among the muscles which attach the cloaca ofHolothuria tubulosato the body-wall; andA. schneiderioccurs in the sea-cucumber,Stichopus variegatus. These are truly parasitic forms, constituting a special sub-family. They have no rhabdites in the skin; the nervous system and sense-organs are only slightly developed; and the pharynx has undergone a notable reduction in relation to the simpler mode of obtaining nourishment. Other cases of association between certain Rhabdocoels (closely allied to, if not identical with, certain free-living species) and Lamellibranchs or Sea-urchins, are, however, of another kind. Thus on the gills or in the mantle cavity of species ofMytilus,Cyprina,Tellina, and upon the test ofClypeaster, such forms asEnterostoma mytili,Acmostoma cyprinae, andProvortex tellinaehave been found. But it is probable that these Turbellaria here obtain merely a temporaryshelter and possibly a supply of the food of the mussel or sea-urchin.
TheAlloeocoelaafford a well-established case of association.Monotus fuscus(Fig. 19, D), an abundant, active, elongated animal, lives on our coasts in the upper part of the littoral zone amongPatella,Balanus, and sometimesChiton. When the tide is low, theMonotus, to obtain moisture and darkness, creeps between the mantle-folds of these animals, where it may readily be found. Upon the return of the tide it leaves its retreat and creeps or swims about freely. Other Alloeocoela collect in great numbers in tufts of red-seaweeds (Florideae). By placing such tufts in vessels, the sea-water, especially as darkness sets in, begins to swarm withCylindrostoma 4-oculatum, species ofEnterostomaandPlagiostoma;P. vittatum, with three violet bands across the white body, being a particularly obvious form.Vorticeros auriculatum(Fig. 19, C), another abundant species, is remarkable for the long tentacles which can be completely withdrawn, and in this condition it completely resembles aPlagiostoma.
The presence of a species (P. lemani) of the characteristically marine genusPlagiostoma, in the Lake of Geneva, and in one or two other Swiss lakes, at depths varying from 1 to 150 fathoms, is very interesting, and is perhaps the only well-established case of the survival of a once marine Rhabdocoelid under changed conditions.Plagiostoma lemaniis by far the biggest of the group to which it belongs, being over half an inch in length. It is usually found in fine mud, sometimes amongChara hispida, and has the general appearance of an inactive white slug. We are indebted to Forel and Duplessis for the discovery of this species, and also ofOtomesostoma morgiense, aMesostomawith an otolith, dredged in 10 to 50 fathoms in the Lake of Geneva, the Lake of Zürich, and found recently also by Zacharias in the Riesengebirge. The genusBothrioplana, first found by Braun in the water-pipes of Dorpat, has been carefully investigated by Vejdovsky,[66]who places it in a special family, Bothrioplanidae, among the Alloeocoela. One species has recently been found near Manchester.
A comprehensive survey of the Rhabdocoelida shows that, with the chief exception of the Proboscidae, the more lowly organised forms, the Acoela and Alloeocoela, are marine, whereas the fresh-water forms are in most cases the most highly organisedgenera (Mesostoma,Vortex). ButMacrorhynchus helgolandicus, though minute (1.5-2 mm. long), has a more complex structure[67]than any other species of the specialised marine genus to which it belongs, and is a remarkable instance of great complexity being associated with small size.
Reproduction.—The Rhabdocoelida present the greatest diversity in the development of the reproductive system. The Acoela and Alloeocoela have the simplest arrangement. Scattered testes, often without a distinct membrane, form the spermatozoa, which in most cases wander into parenchymatous spaces, but inMonoporus rubropunctatusandBothrioplana, into distinct vasa deferentia. In both groups a protrusible penis opens independently to the exterior, and may be simply muscular or provided with a chitinous armature. Two ovaries are present, and the oviducts, if distinct, are continuations of the ovarian membrane. In most forms a "bursa seminalis," which receives the spermatozoa of another individual, is appended to the female genital canal. In many of the Alloeocoela, however, a portion of the ovary is sterile, and its cells, forming a yolk-gland, feed the fertile portion, the whole structure being then spoken of as a germ-yolk-gland. In many others (Monotidae) this sterile part has become an independent yolk-gland, which communicates by yolk-ducts with the oviducts. The Acoela form no egg-case, the body of the parent becoming a bag for the ova, which elaborate their own food-yolk. The Alloeocoela lay hard-shelled eggs, which are produced inBothrioplanaandAutomolosby the activity and interaction of reproductive organs, resembling closely those of certain Triclads.[68]
The Rhabdocoela exhibit every stage in the development of a complex reproductive system, from the simple ovaries and testes of aMicrostomaorMacrostoma, to the intricate system of ducts and glands of aMacrorhynchus(Proboscidae), in which there is still much to be made out. The complications of the copulatory organs chiefly arise from the way in which the spermatozoa are brought into contact with a nutritive prostatic fluid, or are formed into spermatophores; and also from the penial armature,which is often very complex, and may consist of a curved chitinoid hook or a coiled loop (Promesostoma), of hooks (Proboscidae), or of an intricate arrangement of plates (Proxenetes); or the penis may take on a complex corkscrew-like form (Pseudorhynchus). The (frequently armed) female genital canal usually possesses a bursa seminalis for the fertilisation of the eggs, but a receptaculum seminis or spermatheca may serve for the reception, the bursa, for the lodgment of the spermatozoa of another individual. The fertilised ovum is provided with a supply of food-yolk and with a shell, which may be formed in a special diverticulum, the "uterus." The development of these organs strains the resources of the animal to the utmost, and in some Proboscidae the alimentary canal is squeezed out and disintegrates, in order to make room for them.
A fewMesostoma(M. ehrenbergii,M. productum,M. lingua) produce two kinds of eggs—thin- and thick-shelled. The latter are laid throughout the summer, and lie dormant through winter. The young which hatch in spring out of these "winter" eggs develop rapidly, and when only 7 to 8 mm. long (i.e.one-third the size of the parent) already possess functional genital organs; the penis, however, is rudimentary, and incapable of being used for copulation. Hence it is probable that this stunted progeny self-fertilise their thin-shelled or "summer" eggs. After the formation of these eggs the same parent is said (Schneider[69]) to produce thick-shelled or winter eggs, but however that may be, the first young which hatch from the thin-shelled ova are produced in great numbers at a time (April to May) when food is abundant. These grow rapidly to the full size, and then having attained maturity, cross-fertilise one another's ova, which become encased in a thick brown shell; and it is these numerous "winter" eggs that lie dormant throughout the autumn and winter. ManyMesostoma, and practically all other Rhabdocoela, however, produce only thick-shelled eggs, and in all cases it is probable that to these many species owe their wide distribution, the exact range of which is, however, unknown, as is also the means of dispersal.
Classification of Rhabdocoelida.
Proporus venenosusO. Sch. Plymouth.
Monoporus rubropunctatusO. Sch. Plymouth.
Haplodiscus.
Aphanostoma diversicolorOe. Common.
A. elegansJen. Plymouth.
Convoluta saliensGrff. Plymouth, Millport.
C. paradoxaOe. (Fig. 19, B). Common.C. flavibacillumJen. Plymouth, Port Erin, Millport.
Amphicoerus.
Polychoerus.
Mecynostoma.
Macrostoma hystrixOe. Stagnant water.
Omalostoma.
Microstoma lineareOe. Fresh water.
M. groelandicumLev. Plymouth, amongUlva.
Stenostoma(Catenula)lemnaeDug. Near Cork.
S. leucopsO. Sch. Common in fresh water.
Alaurina claparediiGrff. Skye.
Prorhynchus stagnalisM. Sch. In Devonshire rivers.
Promesostoma marmoratumM. Sch. Common.
P. ovoideumO. Sch.,P. agileLev. Plymouth.P. soleaO. Sch. Plymouth, Port Erin.P. lenticulatumO. Sch. Port Erin.
Byrsophlebs graffiiJen. Plymouth, Millport.
B. intermediaGrff. Millport, Port Erin.
Proxenetes flabelliferJen. Millport, Plymouth, Port Erin.
P. cochlearGrff. Millport.
Otomesostoma.
Mesostoma productumLeuck.,M. linguaO. Sch.,M. ehrenbergiiO. Sch.,M. tetragonumO. F. M. (Fig. 19, A). All at Cambridge.
M. rostratumEhr. Widely distributed.M. viridatumM. Sch. Manchester.M. robertsoniiGrff.,M. flavidumGrff. Both at Millport.
Bothromesostoma personatumO. Sch. Preston.
Castrada.
Pseudorhynchus bifidusM‘Int. Millport, St. Andrews, Port Erin.
Acrorhynchus caledonicusClap. Generally distributed.
Macrorhynchus naegeliiKöll.,M. croceusFabr. Plymouth, Millport.
M. helgolandicusMetsch. West coast.
Gyrator hermaphroditusEhrbg. St. Andrews. Also common in fresh water.
Hyporhynchus armatusJen. Plymouth, Port Erin.
H. penicillatusO. Sch. Plymouth.
Vorticidae
Schultzia.Provortex balticusM. Sch. Generally distributed.
P. affinisJen.,P. rubrobacillusGamb. Plymouth.
Vortex truncatusEhrbg. Abundant in fresh water.
V. armigerO. Sch. Millport (fresh water).V. schmidtiiGrff.,V. millportianusGrff. Millport.V. viridisM. Sch. Generally distributed.
Jensenia.
Opistoma.
Derostoma unipunctatumOe. Edinburgh.
Graffilla.
Anoplodium.
Fecampia erythrocephalaGiard. Plymouth, Port Erin.
Acmostoma.Plagiostoma dioicumMetsch.,P. elongatumGamb.,P. pseudomaculatumGamb.,P. sagittaUlj.,P. caudatumLev.,P. siphonophorumO. Sch.,P. ochroleucumGrff. All at Plymouth.
P. sulphureumGrff. Port Erin.P. vittatumF. and Leuck. Millport, Plymouth, Port Erin.P. koreniJen. Plymouth, Millport.P. girardiO. Sch. Plymouth, Port Erin, Valencia.
Vorticeros auriculatumO. F. M. (Fig. 19, C). Port Erin, Plymouth.
V. luteumGrff. Plymouth.
Enterostoma austriacumGrff. Plymouth, Port Erin.
E. fingalianumClap. Skye, Plymouth.E. coecumGrff. Millport.
Allostoma pallidumvan Ben. Millport.
Cylindrostoma 4-oculatumLeuck. Skye, Millport, Plymouth.
C. inermeHall,C. elongatumLev. Plymouth.
Monoophorum striatumGrff. Plymouth.
Bothrioplana.
Bothrioplanasp.? Manchester.
Otoplana.
Monotus lineatusO. F. M.,M. fuscusOe. (Fig. 19, D). Both common littoral forms.
M. albusLev. Plymouth.
Automolos unipunctatusOe. Skye, St. Andrews, Plymouth.
A. horridusGamb.,A. ophiocephalusO. Sch. Plymouth.
TREMATODA
CHARACTERS OF TREMATODES—HABITS AND STRUCTURE OF TREMATODA ECTOPARASITICA (MONOGENEA)—LIFE-HISTORIES OFPOLYSTOMUM INTEGERRIMUM,DIPLOZOON PARADOXUM, ANDGYRODACTYLUS ELEGANS—TREMATODA ENDOPARASITICA (DIGENEA)—OCCURRENCE AND HABITS OF DIGENEA—LIFE-HISTORY OFDISTOMUM MACROSTOMUM—DISTOMUM HEPATICUMAND ITS EFFECTS—BILHARZIA HAEMATOBIA—BISEXUAL TREMATODES—TABLE OF HOSTS—CLASSIFICATION.
From the Turbellaria we now pass on to a consideration of the second great subdivision of the Platyhelminthes, the Trematodes or "flukes," of which the "liver-fluke" is the best known, since it is one of the most dangerous parasites that infest domestic animals.
It has been pointed out that the Polyclads, Triclads, and Rhabdocoels are carnivorous, and that in each of these groups sporadic cases of parasitism occur. In other words, when the prey is much larger than the Turbellarian, the latter tends to become a parasite, and we can trace the development of the parasitic habit from the gradual association of Turbellaria with Ascidians, Crustacea, Molluscs, and Polyzoa merely for protective purposes, through the adoption, not only of the body of the host for shelter, but of its flesh for food; though it is only in some Rhabdocoels (Graffilla, etc.) that there exists a degeneration corresponding to the easier mode of nutrition and simpler life. The Trematodes,[70]however, are wholly parasitic, either on the outer surface, the gills, or internal organs of their host, which is almost always aVertebrate. Some Trematodes lodge in the mouth; others wander down the oesophagus into the stomach or intestine, where they fix themselves to the mucous membrane. Again, others work their way into the digestive glands by the ducts, and thus become further and further removed from the external world, and more adapted to live in the particular organs of that host in which they best flourish. The most important result of the adoption of this internal habitat by endoparasitic Trematodes is, however, seen in their life-history. If a liver-fluke were to deposit its million or so of eggs in the bile-ducts of the sheep, and these were to developin situ, the host could not withstand the increased drain upon its vital resources, and host and parasites would perish together. Hence it is clear that the infection of a second host by Trematodes is highly necessary, whether they beectoparasitic, in which case the infection is easily effected, when two hosts are in contact, by the adult worms, as well as when they are apart, by free-swimming larvae. InendoparasiticTrematodes it is brought about by the migration of the young to the outer world, their entrance into a, usually, Invertebrate host and their asexual multiplication within it, and the capture and deglutition of this "intermediate host" by the final Vertebrate one. Within the latter the immature parasites find out the organ in which their parents flourished, and here they too grow and attain maturity. The chances of any one egg of an endoparasitic Trematode producing eventually an adult are, therefore, far less favourable than in the case of an ectoparasitic form. In other words, while the former must lay a great number of small eggs, the latter need only deposit a (comparatively) few large ones, and this fact has a corresponding influence on the structure of the genitalia in the two cases. The Digenea, which employ two hosts in a lifetime, have accordingly a different generative mechanism from that of the Monogenea. The great need of the latter is a powerful apparatus for adhering to the surface of the body of its host; while the adaptations which the endoparasite requires are, in addition, (1) protection against the solvent action of the glands of its host, (2) the power of firm adhesion to a smooth internal surface, and (3) the ability not only to produce a large quantity of spermatozoa and ova, but in the absence of a fellow-parasite, to fertilise its own ova; and we find these conditions abundantly satisfied.
Trematoda monogenea(ectoparasitica).
There are four subdivisions of the Monogenea:—
I.Temnocephalidae, with four to twelve tentacles, and one sucker posteriorly (Fig. 20).
II.Tristomatidae, with two lateral, anteriorly-placed suckers. Oral suckers are absent, a large posterior sucker is constant, and is often armed with hooks (Fig. 22, C).
III.Polystomatidae, with, usually, two oral suckers and a posteriorly-placed adhesive disc armed with suckers and hooks (Figs. 23 and 24).
IV.Gyrodactylidae(Fig. 29).
Habits and Structure of Ectoparasitic Trematodes.
I.Temnocephalidae.—These interesting forms, of which a good account has lately been written by Haswell,[71]occur on the surface (rarely in the branchial chamber) of fresh-water crayfish and crabs in Australasia, the Malay Archipelago, Madagascar, and Chili. Others have been found on the carapace of a fresh-water tortoise, and in the branchial chamber of the molluscAmpullariafrom Brazil. Wood-Mason discovered others, again, in bottles containing spirit-specimens of Indian fish.Temnocephalais rarely more than a quarter of an inch long, and looks like a minute Cephalopod or a broad flattenedHydra. By the ventral sucker each species adheres to its own particular host, the tentacles being used as an anterior sucker for "looping" movements. The food, consisting of Entomostraca, Rotifera, and Diatoms, is first swallowed whole by the large pharynx (Fig. 20,ph), which can be protruded through the ventrally-placed mouth, and is then received into a simple lobed intestine (d). The skin, especially on the surface of the tentacles, is provided here and there with patches of cilia borne by the cellular epidermis,—the only undoubted case of external cilia occurring in an adult Trematode. Minute rhabdites formed in special gland-cells, occur plentifully on the tentacles, and are another distinctly Turbellarian feature. The excretory system is peculiar (Fig. 21). Fine ducts proceed from the various organs of the body, and open to the exterior by means of a pair of contractile sacsplaced on the dorsal surface. Each sac is a single cell, and within it not one merely, but several "flames," or bunches of rhythmically contractile cilia, are present. These are placed on the course of excessively fine canals, which perforate the protoplasm of this cell. The terminal branches of the excretory canals end in branched cells, apparently devoid of "flames."
fig20_21Fig. 20.—Temnocephala novae-zealandiaeHas. × 10. Ventral view to show the digestive and reproductive systems. (After Haswell.)Fig. 21.—The same from the dorsal surface, to show the excretory system (double line), and the nervous system (black and shaded). (After Haswell.)d, Intestine;dln, dorso-lateral nerve;dn, dorsal nerve;ex.o, excretory aperture on dorsal surface;ex.s, terminal excretory sac;m, mouth;ov, ovary;ovd, oviduct;ph, pharynx;rh, rhabdites;rh.c, cells in which the rhabdites are formed;rv, yolk receptacle;sc, sucker;sh, shell-gland;te, testes;ut, uterus;vg, vagina;vn, ventral nerve;vs, vesicula seminalis;yd, yolk-duct;yg, yolk-gland. ♀, ♂, common genital pore.
Fig. 20.—Temnocephala novae-zealandiaeHas. × 10. Ventral view to show the digestive and reproductive systems. (After Haswell.)Fig. 21.—The same from the dorsal surface, to show the excretory system (double line), and the nervous system (black and shaded). (After Haswell.)d, Intestine;dln, dorso-lateral nerve;dn, dorsal nerve;ex.o, excretory aperture on dorsal surface;ex.s, terminal excretory sac;m, mouth;ov, ovary;ovd, oviduct;ph, pharynx;rh, rhabdites;rh.c, cells in which the rhabdites are formed;rv, yolk receptacle;sc, sucker;sh, shell-gland;te, testes;ut, uterus;vg, vagina;vn, ventral nerve;vs, vesicula seminalis;yd, yolk-duct;yg, yolk-gland. ♀, ♂, common genital pore.
Fig. 20.—Temnocephala novae-zealandiaeHas. × 10. Ventral view to show the digestive and reproductive systems. (After Haswell.)
Fig. 21.—The same from the dorsal surface, to show the excretory system (double line), and the nervous system (black and shaded). (After Haswell.)
d, Intestine;dln, dorso-lateral nerve;dn, dorsal nerve;ex.o, excretory aperture on dorsal surface;ex.s, terminal excretory sac;m, mouth;ov, ovary;ovd, oviduct;ph, pharynx;rh, rhabdites;rh.c, cells in which the rhabdites are formed;rv, yolk receptacle;sc, sucker;sh, shell-gland;te, testes;ut, uterus;vg, vagina;vn, ventral nerve;vs, vesicula seminalis;yd, yolk-duct;yg, yolk-gland. ♀, ♂, common genital pore.
The reproductive system is very similar to that of certain Rhabdocoels. An armed penis and the female genital duct open into a genital atrium, and this by a single aperture (♀, ♂, Fig. 20) to the exterior. The fertilised ovum and yolk are enclosed in a stalked shell formed in the uterus.
The interest and importance of the Temnocephalidae lies in the fact that they are almost as much Turbellaria as Trematodes.In habits, in the character of the skin, the muscular, digestive, and reproductive systems, they find their nearest allies in Rhabdocoels (Vorticidae). But in the excretory and nervous systems, the latter composed of two dorsal, two lateral, and two ventral trunks all connected together (Fig. 21), they are Tristomid Trematodes. Thus they may fitly connect an account of the two great groups.
fig22Fig. 22.—A,Nematobothrium filarinavan Bened. Nat. size. Two individuals (aandb) are found together, encysted on the branchial chamber of the Tunny.B,Udonella caligorumJohns. A Tristomid, several of which are attached to the ovary of a Copepod (Caligus), itself a parasite on the gills of the Hake. × 8.C,Epibdella hippoglossiO. F. M. A Tristomid found on the body of the Halibut. Nat. size.m, Mouth;ms, lateral suckers;ov, ovary;ps, posterior sucker;te, testes. (All after P. J. van Beneden.)
Fig. 22.—A,Nematobothrium filarinavan Bened. Nat. size. Two individuals (aandb) are found together, encysted on the branchial chamber of the Tunny.B,Udonella caligorumJohns. A Tristomid, several of which are attached to the ovary of a Copepod (Caligus), itself a parasite on the gills of the Hake. × 8.C,Epibdella hippoglossiO. F. M. A Tristomid found on the body of the Halibut. Nat. size.m, Mouth;ms, lateral suckers;ov, ovary;ps, posterior sucker;te, testes. (All after P. J. van Beneden.)
Fig. 22.—A,Nematobothrium filarinavan Bened. Nat. size. Two individuals (aandb) are found together, encysted on the branchial chamber of the Tunny.B,Udonella caligorumJohns. A Tristomid, several of which are attached to the ovary of a Copepod (Caligus), itself a parasite on the gills of the Hake. × 8.C,Epibdella hippoglossiO. F. M. A Tristomid found on the body of the Halibut. Nat. size.m, Mouth;ms, lateral suckers;ov, ovary;ps, posterior sucker;te, testes. (All after P. J. van Beneden.)
II.Tristomatidae andIII.Polystomatidae.[72]—The members of these families are found on the body, or attached to the gills, of fresh-water and marine fishes. The edible and inedible fish of our coasts have each their particular ectoparasitic Trematodes; while the Minnows, Sticklebacks, and Miller's Thumbs of streams and ponds are attacked byDiplozoon,Gyrodactylus, and other forms. The aquatic Amphibia also harbour a number.Polystomum integerrimumis common in the bladder of Frogs, where it leads a practically aquatic life. Other species ofPolystomuminhabit the buccal and nasal cavities of certain Chelonia, but naturally no terrestrial Vertebrates are infested externally by theseTrematodes. The blood and epithelia of the host are sucked, and to this end the pharynx has frequently a chitinous armature to aid in the abrasion or inflammation of the tissues upon which the parasite feeds. In the case of a Sturgeon attacked byNitzschia elongata, a Tristomid, the mouth of the host appeared to be highly inflamed by these attacks (v. Baer).
fig23Fig. 23.—Octobothrium merlangiKuhn, from the gills of the whiting, × 8.int, Intestine;ms, mouth;scsuckers with chitinoid armature;ykyolk-glands. (After v. Nordmann.)
Fig. 23.—Octobothrium merlangiKuhn, from the gills of the whiting, × 8.int, Intestine;ms, mouth;scsuckers with chitinoid armature;ykyolk-glands. (After v. Nordmann.)
Fig. 23.—Octobothrium merlangiKuhn, from the gills of the whiting, × 8.int, Intestine;ms, mouth;scsuckers with chitinoid armature;ykyolk-glands. (After v. Nordmann.)
The suckers, in the two families under consideration, vary in number and complexity. There is always a powerful apparatus at the hinder end of the body securing the Trematode firmly to the slimy body or gills of its host, and, usually in the Polystomatidae, a pair of suckers at the sides of the mouth accessory to the pumping action of the pharynx. InAxine, and to a less extent inOctobothrium(Fig. 23), the suckers are strengthened by a complex hingework of chitinoid bars or hooks, which serve as insertions for the muscles of the suckers, and thus increase their efficiency.
The mouth is invariably present just beneath the anterior end of the body. It leads into a muscular, pumping pharynx (Fig. 24,ph), and this into a bifurcated intestine which ends blindly. The two openings of the excretory system lie on the dorsal surface (as inTemnocephala), and the excretory canals branch through the substance of the body, ending usually in "flame-cells." The nervous system is highly developed, and resembles that ofTemnocephala(Fig. 21) in detail. Upon the brain one or even two pairs of eye-spots are present in the larvae, and may persist throughout life. Tactile setae occur inSphyranura, a parasite of the North American AmphibianNecturus, but a cellular epidermis is apparently rendered impossible, perhaps from the nature ofthe mucus in which the body is bathed, or to the attempts of the host to free itself from these parasites; and hence an investing membrane is present, which morphologically is either a modified epithelium, or a cuticle formed by the glandular secretion of the parenchyma.
fig24Fig. 24.—Polystomum integerrimumFröh., from the bladder of the Frog, and seen from the ventral surface. The alimentary canal is black, the white dots upon it being the yolk-glands,dvi, Ductus vitello-intestinalis (probably homologous with the Laurer's canal or "vagina" of Digenea);eh, hooks of sucking disc;int, intestine;m, mouth;ov, ovary;pe, penis;ph, pharynx;sc, suckers with an embryonic hook persisting in each;te, testes;ut, uterus with eggs;vag, left vagina;vd, vas deferens;yd, yolk-duct;yg, yolk-glands; ♂ ♀, common genital aperture. (Modified from Zeller.) × 8.
Fig. 24.—Polystomum integerrimumFröh., from the bladder of the Frog, and seen from the ventral surface. The alimentary canal is black, the white dots upon it being the yolk-glands,dvi, Ductus vitello-intestinalis (probably homologous with the Laurer's canal or "vagina" of Digenea);eh, hooks of sucking disc;int, intestine;m, mouth;ov, ovary;pe, penis;ph, pharynx;sc, suckers with an embryonic hook persisting in each;te, testes;ut, uterus with eggs;vag, left vagina;vd, vas deferens;yd, yolk-duct;yg, yolk-glands; ♂ ♀, common genital aperture. (Modified from Zeller.) × 8.
Fig. 24.—Polystomum integerrimumFröh., from the bladder of the Frog, and seen from the ventral surface. The alimentary canal is black, the white dots upon it being the yolk-glands,dvi, Ductus vitello-intestinalis (probably homologous with the Laurer's canal or "vagina" of Digenea);eh, hooks of sucking disc;int, intestine;m, mouth;ov, ovary;pe, penis;ph, pharynx;sc, suckers with an embryonic hook persisting in each;te, testes;ut, uterus with eggs;vag, left vagina;vd, vas deferens;yd, yolk-duct;yg, yolk-glands; ♂ ♀, common genital aperture. (Modified from Zeller.) × 8.
The reproductive organs of the Polystomatidae may be understood from Figs. 24, 27, and 28. At the point of union of the oviduct (Fig. 28,ovd), the vitelline ducts (yd), and the commencement of the uterus (ut), a slender duct is given off which opens into the intestine, and is known as the "vitello-intestinal canal" (Fig. 24,dvi; Fig. 28,gic). This duct has apparently the same relations as the "canal of Laurer" of Digenea,[73]except only that the latter opens to the exterior directly. In connexion with this vitello-intestinal canal a "vagina" is present, which inPolystomumand most Monogenea is paired (Fig. 24,vag), inDiplozoonand in oneor two other forms, however, unpaired. The vagina receives the penis of another individual during copulation (Fig. 26), and does not appear to have an homologue in the liver-fluke or other Digenea.
fig25Fig. 25.—Eggs of Monogenea.A, Eggs ofEncotylabe pagelliv. Ben.-Hesse;B, eggs ofUdonella pollachiiv. Ben.-Hesse (with young forms just hatching out);C, egg ofMicrocotyle labracisv. Ben.-Hesse. (After van Beneden and Hesse.) × 50.
Fig. 25.—Eggs of Monogenea.A, Eggs ofEncotylabe pagelliv. Ben.-Hesse;B, eggs ofUdonella pollachiiv. Ben.-Hesse (with young forms just hatching out);C, egg ofMicrocotyle labracisv. Ben.-Hesse. (After van Beneden and Hesse.) × 50.
Fig. 25.—Eggs of Monogenea.A, Eggs ofEncotylabe pagelliv. Ben.-Hesse;B, eggs ofUdonella pollachiiv. Ben.-Hesse (with young forms just hatching out);C, egg ofMicrocotyle labracisv. Ben.-Hesse. (After van Beneden and Hesse.) × 50.
Life-Histories of the Polystomatidae.[74]—Polystomum integerrimum.After the mutual fertilisation of two individuals, the eggs are laid in the water by the protrusion of the body of the parent through the urinary aperture of the Frog. About 1000 eggs are laid in the spring at the rate of 100 a day for ten days. After about six weeks, the larva (.3 mm. long) hatches out, and swims about freely by means of bands of large ciliated cells (Fig. 26, A); but if it does not meet with a tadpole within twenty-four hours, it dies. Should it, however, encounter one, the larva creeps along it in a looping fashion until it approaches the opercular spout, or opening of the branchial chamber, on the left side; into this it darts suddenly, fixes itself, and throws off its cilia. Here it remains eight or ten weeks, feeding, increasing in size, and forming the suckers from behind forwards.At the time of the tadpole's metamorphosis, the youngPolystomumworks its way down the pharynx into the oesophagus and along the intestine, till it reaches and enters the opening of the bladder. Three years afterwards it becomes mature.
Sometimes, however,Polystomumexperiences another fate. The larvae settling down on the external gills of a young, recently-hatched tadpole, and obtaining a richer supply of blood than in the previous case, grow far more rapidly, so that in five weeks they are mature, although still in the branchial chamber of the tadpole. They do not then wander into the alimentary canal, but usually, having discharged their eggs, die at the time of the tadpole's metamorphosis. Still more interesting, however, is the difference between the genitalia in these and in the normalPolystomum. In contrast with the latter, these possess (1) one testis and a rudimentary penis; and their spermatozoa differ in structure and shape from those of the normalPolystomum. (2) The vaginae are absent, a fact connected with the absence of a functional copulatory organ. (3) In compensation for the loss of these, a duct connects the single testis and the point of union of oviduct and yolk-ducts, and by this self-fertilisation occurs. (4) The uterus is absent; the "ootype" or duct into which the shell-gland opens, communicating directly with the exterior. In (1) and (4) these aberrantPolystomumresembleP. ocellatum, from the TortoiseEmys europaea.
fig26Fig. 26.—Polystomum integerrimum.A, Free-swimming larva, seen from the ventral surface. × 80.B, Two mature individuals in mutual coition attached to the bladder of a Frog. × 5. (After Zeller.)d, Intestine;ex.o, excretory pore, dorsal in position, seen here by transparency;ey, eye-spots;gl, frontal glands;m, mouth;ph, pharynx;sd, adhering disc;vag, vagina.
Fig. 26.—Polystomum integerrimum.A, Free-swimming larva, seen from the ventral surface. × 80.B, Two mature individuals in mutual coition attached to the bladder of a Frog. × 5. (After Zeller.)d, Intestine;ex.o, excretory pore, dorsal in position, seen here by transparency;ey, eye-spots;gl, frontal glands;m, mouth;ph, pharynx;sd, adhering disc;vag, vagina.
Fig. 26.—Polystomum integerrimum.A, Free-swimming larva, seen from the ventral surface. × 80.B, Two mature individuals in mutual coition attached to the bladder of a Frog. × 5. (After Zeller.)d, Intestine;ex.o, excretory pore, dorsal in position, seen here by transparency;ey, eye-spots;gl, frontal glands;m, mouth;ph, pharynx;sd, adhering disc;vag, vagina.
fig27Fig. 27.—A, Egg ofDiplozoon paradoxumv. Nord., consisting of a shell enclosingov, the actual ovum, surrounded byyc, the yolk-cells;B, larva just hatched (× 125);C, twoDiporpa(I and II) about to unite;D, conjugation in progress but not yet complete.dt, Dorsal papilla;e, eye;g, intestine;m, mouth;sc, ad-oral sucker;th, spirally-wound thread attaching the egg to the gill of the Minnow;vs, ventral sucker; (in D) I, I, oneDiporpa, ventral view; II, II, the other, dorsal view. (After Zeller.)
Fig. 27.—A, Egg ofDiplozoon paradoxumv. Nord., consisting of a shell enclosingov, the actual ovum, surrounded byyc, the yolk-cells;B, larva just hatched (× 125);C, twoDiporpa(I and II) about to unite;D, conjugation in progress but not yet complete.dt, Dorsal papilla;e, eye;g, intestine;m, mouth;sc, ad-oral sucker;th, spirally-wound thread attaching the egg to the gill of the Minnow;vs, ventral sucker; (in D) I, I, oneDiporpa, ventral view; II, II, the other, dorsal view. (After Zeller.)
Fig. 27.—A, Egg ofDiplozoon paradoxumv. Nord., consisting of a shell enclosingov, the actual ovum, surrounded byyc, the yolk-cells;B, larva just hatched (× 125);C, twoDiporpa(I and II) about to unite;D, conjugation in progress but not yet complete.dt, Dorsal papilla;e, eye;g, intestine;m, mouth;sc, ad-oral sucker;th, spirally-wound thread attaching the egg to the gill of the Minnow;vs, ventral sucker; (in D) I, I, oneDiporpa, ventral view; II, II, the other, dorsal view. (After Zeller.)
fig28Fig. 28.—Hinder part of the body ofDiplozoon paradoxum. The fusion of the twoDiporpa, where they come into contact, is now complete. They now cross each other like an X, and are twisted, so thatDiporpaI, in front of the point of fusion, is seen from the dorsal surface; behind, from the ventral surface; and the reverse is the case withDiporpaII. The compound animal is seen from the opposite surface to that shown in Fig. 27, D. The digestive and excretory organs are omitted. (After Zeller.) IAnt. dorsal, dorsal surface ofDiporpaI, facing the anterior end; IPost. ventral, ventral surface ofDiporpaI, posterior end; and similarly for IIAnt. ventraland IIPost. dorsal.d, Piece of the intestine showing opening of,gic, vitello-intestinal canal;ov, ovary;ovd, point of union of female genital ducts;sc, suckers;te, testis;ut(inDiporpaI), "ootype" or chamber into which shell-glands open. This is continuous with the uterus (ut) ofDiporpaI;uto, ventral opening of uterus;vag, vagina, withvd, vas deferens, permanently inserted into it through the genital pore;yd, yolk-ducts;yg, yolk-glands.
Fig. 28.—Hinder part of the body ofDiplozoon paradoxum. The fusion of the twoDiporpa, where they come into contact, is now complete. They now cross each other like an X, and are twisted, so thatDiporpaI, in front of the point of fusion, is seen from the dorsal surface; behind, from the ventral surface; and the reverse is the case withDiporpaII. The compound animal is seen from the opposite surface to that shown in Fig. 27, D. The digestive and excretory organs are omitted. (After Zeller.) IAnt. dorsal, dorsal surface ofDiporpaI, facing the anterior end; IPost. ventral, ventral surface ofDiporpaI, posterior end; and similarly for IIAnt. ventraland IIPost. dorsal.d, Piece of the intestine showing opening of,gic, vitello-intestinal canal;ov, ovary;ovd, point of union of female genital ducts;sc, suckers;te, testis;ut(inDiporpaI), "ootype" or chamber into which shell-glands open. This is continuous with the uterus (ut) ofDiporpaI;uto, ventral opening of uterus;vag, vagina, withvd, vas deferens, permanently inserted into it through the genital pore;yd, yolk-ducts;yg, yolk-glands.
Fig. 28.—Hinder part of the body ofDiplozoon paradoxum. The fusion of the twoDiporpa, where they come into contact, is now complete. They now cross each other like an X, and are twisted, so thatDiporpaI, in front of the point of fusion, is seen from the dorsal surface; behind, from the ventral surface; and the reverse is the case withDiporpaII. The compound animal is seen from the opposite surface to that shown in Fig. 27, D. The digestive and excretory organs are omitted. (After Zeller.) IAnt. dorsal, dorsal surface ofDiporpaI, facing the anterior end; IPost. ventral, ventral surface ofDiporpaI, posterior end; and similarly for IIAnt. ventraland IIPost. dorsal.d, Piece of the intestine showing opening of,gic, vitello-intestinal canal;ov, ovary;ovd, point of union of female genital ducts;sc, suckers;te, testis;ut(inDiporpaI), "ootype" or chamber into which shell-glands open. This is continuous with the uterus (ut) ofDiporpaI;uto, ventral opening of uterus;vag, vagina, withvd, vas deferens, permanently inserted into it through the genital pore;yd, yolk-ducts;yg, yolk-glands.
Diplozoon paradoxum.—The life-history ofDiplozoonis unique. For whereas the larvae of most animals grow up, each into a single adult, inDiplozoon, of the few larvae that survive the dangers of their free-swimming existence, only those become mature which conjugate permanently with another individual. But although there are thus only half as many adultDiplozoonas there were conjugating larvae (orDiporpa, as they were called when they were considered distinct forms), yet the total number of eggs produced is probably as great as if each larva became individually mature.
fig29Fig. 29.—Gyrodactylus elegansv. Nord., from the fins of the Stickleback. (After v. Nordmann.) × 125.emb, Embryo.
Fig. 29.—Gyrodactylus elegansv. Nord., from the fins of the Stickleback. (After v. Nordmann.) × 125.emb, Embryo.
Fig. 29.—Gyrodactylus elegansv. Nord., from the fins of the Stickleback. (After v. Nordmann.) × 125.emb, Embryo.
Diplozoon paradoxumlays its eggs on the gills of the Minnow, which it frequently infests in great numbers. The ovum divides rapidly at the expense of the yolk-cells, and in a fortnight a larva (.2 mm. long) of the shape and complexity shown in Fig. 27, B, hatches out, which, however, succumbs if it does not meet with a Minnow in five or six hours. Should it survive, a dorsal papilla, a median ventral sucker, and a second pair of posterior suckers develop. Thus theDiporpastage is attained. TheseDiporpamay acquire a third and even a fourth pair of suckers, and continue to live three months, but they only develop and mature their reproductive organs, if each conjugates with anotherDiporpa(Fig. 27, C, D), and this only occurs in a small percentage of instances. Each grasps the dorsal papilla of the other by its own ventral sucker, thus undergoing a certain amount of torsion. Where the two bodies touch, complete fusion occurs, and, as shown in Fig. 28, the unitedDiporpa(orDiplozoon, as the product is now called) decussate, each forming one limb of the X-shapedDiplozoon, within which the two sets of complex genitalia develop (Fig. 28).
IV.Gyrodactylidae.—Gyrodactylus(Fig. 29), the structure of which is in many ways peculiar, produces one large egg at a time. An embryo, in which the large and smaller hooks of the adhesive disc can be seen (emb), develops from this egg while still within the body of the parent, and may give rise to yet another generation within itself. The details of the process have not, however, been well ascertained.