Ultrastructure of the body cavities in Phylactolaemata (Bryozoa)

Only species belonging to the bryozoan subtaxon Phylactolaemata possess an epistome. To test whether there is a specific coelomic cavity inside the epistome, Fredericella sultana, Plumatella emarginata, and Lophopus crystallinus were studied on the ultrastructural level. In F. sultana and P. emarginata, the epistome contains a coelomic cavity. The cavity is confluent with the trunk coelom and lined by peritoneal and myoepithelial cells. The lophophore coelom extends into the tentacles and is connected to the trunk coelom by two weakly ciliated coelomic ducts on either side of the rectum. The lophophore coelom passes the epistome coelom on its anterior side. This region has traditionally been called the forked canal and hypothesized to represent the site of excretion. L. crystallinus lacks an epistome. It has a simple ciliated field where an epistome is situated in the other species. Underneath this field, the forked canal is situated. Compared with the other species, it is pronounced and exhibits a dense ciliation. Despite the occurrence of podocytes, which are prerequisites for a selected fluid transfer, there is no indication for an excretory function of the forked canal, especially as no excretory porus was found. J. Morphol. 2009. © 2008 Wiley‐Liss, Inc.     

The microscopic anatomy and ultrastructure of the contractile vessel in the sipunculan Themiste hexadactyla (Satô, 1930) (Sipuncula: Sipunculidea)

The microscopic anatomy and ultrastructure of the contractile vessel of the sipunculan Themiste hexadactyla (Satô, 1930) from Vostok Bay (the Sea of Japan) were studied by histological and electron microscope methods. The ultrastructural features of the internal (endothelium) and external (coelothelium) lining of the contractile vessel are described and illustrated. Numerous macromolecular filters, the so-called “double diaphragms,” were found in the external coelothelium facing the cavity of the trunk coelom. This suggests a possible filtration from the tentacular coelom into the trunk coelom though the contractile vessel wall. The microscopic peculiarities of the main tube of the contractile vessel and its numerous lateral branches twining around several internal organs are described in detail. The contractile vessel is polyfunctional: it can act as the main reservoir for the cavity fluid during the withdrawal of the tentacular crown and performs the functions of the distribution system in sipunculans.     

Organization of the epistome in <Emphasis Type="Italic">Phoronopsis harmeri</Emphasis> (Phoronida) and consideration of the coelomic organization in Phoronida

Results provided by modern TEM methods indicate the existence of the lophophoral and trunk coelomes but not of the preoral coelom in Phoronida. In the present work, the epistome in Phoronopsis harmeri was studied by histological and ultrastructural methods. Two kinds of cells were found in the frontal epidermis: supporting and glandular. The coelomic compartment is shown to be inside the epistome. This compartment has a complex shape, consists of a central part and two lateral branches, and contacts the lophophoral coelom, forming two complete dissepiments on the lateral sides and a partition with many holes in the center. TEM reveals that some portions of the incomplete partition are organized like a mesentery, with the two layers of cells separated by ECM. The myoepithelial cells of the coelomic lining form the circular and radial musculature of the epistome. Numerous amoebocytes occur in the coelom lumen. The tip of the epistome and its dorso-lateral parts lack a coelomic cavity and are occupied by ECM and muscle cells. The fine structure of the T-shaped vessel is described, and its localization inside lophophoral coelom is demonstrated. We assert that the cavity inside the epistome is the preoral coelom corresponding to the true preoral coelom of the larva of this species. Proving this assertion will require additional study of metamorphosis in this species. To clarify the patterns of coelom organization in phoronids, we discuss the bipartite coelomic system in Phoronis and the tripartite coelomic system in Phoronopsis.     

Ultrastructure of the Coelomocytes in the Tentacular Coelom of Thysanocardia nigra Ikeda, 1904 (Sipuncula)

Free-floating coelomocytes in the tentacular coelomic cavity of the sipunculan Thysanocardia nigra Ikeda, 1904, were studied using light interference contrast microscopy and scanning and transmission electron microscopy. The following coelomocyte types were distinguished: hemerythrocytes, amoebocytes, and two morphological types of granular cells. No clusters of specialized cells that had been reported to occur in the trunk coelom of Th. nigra were found in the tentacular coelom. The corresponding types of coelomocytes from the tentacular and trunk coelomic cavities were shown to differ in size. These two coeloms are completely separated in sipunculans.     

Rhabditis pellio Schneider (Nematoda) from the Earthworm,Aporrectodea trapezoides Duges (Annelida)

Studies were conducted on the behak, ior of the nematode, Rhabditis pellio, in the earthworm, Aporrectodea trapezoides, from southern California. Juvenile and adult nematodes were found in the bladders and tubules of the metanephridia of the host. Similar nematodes that entered the coelom were encapsulated and incorporated into multiple capsules ("brown bodies"). It was demonstrated that this host response is an effective defense reaction since dead and dying nematodes, as well as living forms, were found in the capsules.     

Ultrastructural evidence of the excretory function in the asteroid axial organ (Asteroidea,Echinodermata)

The ultrastructure of the axial organ of Asterias amurensis has been studied The organ is a network of canals of the axial coelom separated by haemocoelic spaces. The axial coelom is lined with two types of monociliary cells: podocytes and musculo-epithelial cells. Podocytes form numerous basal processes adjacent to the basal lamina on the coelomic side. Musculo-epithelial cells form processes running along the basal lamina. Some bundles of these processes wrapped in the basal lamina pass through haemocoelic spaces between neighboring coelomic canals. It is hypothesized that the axial organ serves for filtration of fluid from haemocoelic spaces into the axial coelom cavity, from which urine is excreted through the madreporite to the exterior.     

Phylogeny of marine Gregarines (Apicomplexa)--Pterospora, Lithocystis and Lankesteria--and the origin(s) of coelomic parasitism

Gregarines constitute a large group of apicomplexans with diverse modes of nutrition and locomotion that are associated with different host compartments (e.g. intestinal lumena and coelomic cavities). A broad molecular phylogenetic framework for gregarines is needed to infer the early evolutionary history of apicomplexans as a whole and the evolutionary relationships between the diverse ultrastructural and behavioral characteristics found in intestinal and coelomic gregarines. To this end, we sequenced the SSU rRNA gene from (1) Lankesteria abbotti from the intestines of two Pacific appendicularians, (2) Pterospora schizosoma from the coelom of a Pacific maldanid polychaete, (3) Pterospora floridiensis from the coelom of a Gulf Atlantic maldanid polychaete and (4) Lithocystis sp. from the coelom of a Pacific heart urchin. Molecular phylogenetic analyses including the new sequences demonstrated that several environmental and misattributed sequences are derived from gregarines. The analyses also demonstrated a clade of environmental sequences that was affiliated with gregarines, but as yet none of the constituent organisms have been described at the ultrastructural level (apicomplexan clade I). Lankesteria spp. (intestinal parasites of appendicularians) grouped closely with other marine intestinal eugregarines, particularly Lecudina tuzetae, from polychaetes. The sequences from all three coelomic gregarines branched within a larger clade of intestinal eugregarines and were similarly highly divergent. A close relationship between Pterospora schizosoma (Pacific) and Pterospora floridiensis (Gulf Atlantic) was strongly supported by the data. Lithocystis sp. was more closely related to a clade of marine intestinal gregarines consisting of Lankesteria spp. and Lecudina spp. than it was to the Pterospora clade. These data suggested that coelomic parasitism evolved more than once from different marine intestinal eugregarines, although a larger taxon sample is needed to further explore this inference.     

Morphology of the male system and spermatophores of the arrowworm Ferosagitta hispida (Chaetognatha)

Transmission electron microscopy reveals that the somatic testicular tissues and sperm ducts are elaborations of the epithelial lining of the tail coelom. The testes consist of closely packed spermatogonia embedded between specialized lateral field cells. These cells contain few organelles and appear to function mainly as a compartment boundary. Masses of spermatogenic cells are released into the tail coelom from the anterior end of the testes. The sperm ducts, lined by simple cuboidal ciliated epithelium, collect mature spermatozoa from the tail coelom and convey them to the blindly ending seminal vesicles. The sperm ducts also modify coelomic fluid entering them along with the spermatozoa. The seminal vesicles consist of a simple glandular lining epithelium embedded in the stratified epidermis. Secretions of the lining epithelium surround the enclosed sperm mass and correspond in position to a noncellular spermatophore coat visible by light microscopy around released sperm masses. Spermatophores leave the seminal vesicles through a temporary split that forms between microfilament-containing suture cells. Maturation of spermatozoa and filling of the seminal vesicles is cyclical, occurring late each day. © 1994 Wiley-Liss, Inc.     

The lantern of Aristotle: organization of its coelom and origin of its muscles (Echinodermata,Echinoida)

Summary Comparative ultrastructural analyses of the muscles that work the lantern of Aristotle support the opinion that the muscles in question are myoepithelially organized or derivatives of myoepithelia. They are part of the epithelium of the peripharyngeal cavity (=lantern coelom). The coelom epithelium may become multiplelayered in certain regions and is composed of (1) a layer of muscle cells that vary in number and size, (2) nerve cells and their processes that are interspersed between the muscle layer and (3) monociliated adluminal cells that build a continuous cell lining and completely cover the muscle layer. According to their complexity, the lantern muscles exhibit consecutive stages of myoepithelial variations and may finally simulate subepithelial musculature. The results of this study support the hypothesis of a histological development of subepithelial musculature from simple myoepithelia, although both epithelial and mesenchymal musculature may occur in the Echinodermata. Detailed knowledge of the organization of the lantern's coelom space was a prerequisite for the present study. In contrast to previous examinations the lantern coelom is not a continuous space, but is subdivided into several cavities that are partially completely separated from each other. On the one hand, this subdivision is probably caused by the sophisticated arrangement of the lantern's ossicles and on the other by the septa that give rise to muscles that fulfill different functions. lanter's ossicles and on the other by the septa that give     

Ultrastructure of Axial Vascular and Coelomic Organs in Comasterid Featherstars (Echinodermata: Crinoidea)

Abstract The spongy body of Davidaster rubiginosa, D. discoidea, and Comactinia meridionalis, is an axial haemal plexus consisting of two structurally similar, but positionally distinct, regions: an oral circumesophageal part and an aboral part which lies lateral to the axial organ. The axial organ is a large axial blood vessel which is infiltrated by hollow cellular tubes lined with monociliated epithelial cells. The spongy body plexus is a tangle of small blood vessels overlain by podocytes and myocytes. The spongy body and the axial organ are situated in the axial coelom, which is confluent with the perivisceral coelom, the water vascular system, and the parietal canals. The parietal canals open to the exterior via ciliated tegmenal ducts and surface pores. The crinoid spongy body is morphologically similar to the axial gland of asteroids, ophiuroids, and echinoids (AOE). Although the axial glands of these three classes of echinoderms are mutually homologous structures, the homology of the crinoid spongy body and the AOE axial gland is questionable because of differences in organization and developmental origin. Alternatively, the crinoid spongy body may be homologous to asteroid gastric haemal tufts, which are podocyte-covered blood vessels suspended in the perivisceral coelom. The functional organization of the spongy body suggests a filtration nephridium and predicts an excretory function. An alternative hypothesis is that the spongy body is a site of nutrient transfer from the blood vascular system to the perivisceral coelom.     

Free-swimming Cellular Complexes in the Coelom of the Sipunculid Thysanocardia nigra Ikeda, 1904 (Sipuncula)

The ultrastructural characteristics of coelomic cell complexes in the coelomic fluid were investigated with the use of transmission electron microscopy on the example of Japanese sipunculid. In the sipunculid coelom, complexes consisting of several cells were found for the first time: the central glandular cell and the outer layer of podocytes. Peculiar cell complexes (urns), comprising by ciliary and granular cells, were described in Thysanocardia for the first time. It had been proposed that both types of coelomic cell complexes dissociated from extensive chloragogenic tissue clusters on the intestine surface of Th. nigra. The variety of cell complexes in the coelom of other sipunculid is discussed.     

Insilico Studies on Antimicrobial Peptide (AMP) in Leeches

International Journal of Peptide Research and Therapeutics - The earthworm immune system is robust and comprises of the coelom cytolytic factor (CCF), lysenin and antimicrobial peptides (AMPs,...     

The aboral ring and the development of early gonads in the echinoid Paracentrotus lividus (Echinodermata, Echinoidea)

Abstract. The development of the genital apparatus is described for the echinoid Paracentrotus lividus. This apparatus derives from the aboral ring, an annular structure that includes an inconspicuous coelom and, in juveniles, the germinal rachis. The germinal epithelium grows out from the germinal rachis, and the gonadal wall and coelom in early (tubular) gonads share similarities with their equivalents in the aboral ring. The original germinal rachis regresses to form a genital cord one cell wide in late juveniles. A genital cord was observed in a few field-collected adult individuals (>40 mm test diameter).     

Wild Cane Toads (Rhinella marina) Expel Foreign Matter from the Coelom via the Urinary Bladder in Response to Internal Injury,Endoparasites and Disease

Dissections of >1,200 wild-caught cane toads (Rhinella marina) in tropical Australia confirm a laboratory report that anurans can expel foreign objects from the coelom by incorporating them into the urinary bladder. The foreign objects that we found inside bladders included a diverse array of items (e.g., grass seeds, twigs, insect prey, parasites), many of which may have entered the coelom via rupture of the gut wall. In some cases, the urinary bladder was fused to other organs including liver, fat bodies, ovaries, Bidder’s organs, lungs, mesentery, stomach wall, gall bladder, and the abdominal wall. Acanthocephalan parasites (of a range of developmental stages) were identified from the walls of the urinary bladders of three cane toads. This organ may play a significant role in destroying or excreting metazoan parasites, as well as inanimate objects.     

Short communication. First record of Torticaecum sp. (Trematoda: Didymozoidae) in the chaetognath Serratosagitta serratodentata (Krohn, 1853) from Caribbean waters

From samples collected in the Caribbean Sea during February, March, May and August 1991, a total of 22 508 holoplanktonic chaetognaths were caught. During the analyses of the samples, one non-cysted specimen of didymozoid metacercaria was found in the coelom of the chaetognath Serratosagitta serratodentata (prevalence 0.004%). Owing to the lack of an authentic stomach and the morphology of the intestine, this trematode seems to belong to the Torticaecum larval type. This is the first report of both the chaetognath species as a host and the geographical locality for this parasite.      

The coeloms in a late brachiolaria larva of the asterinid sea star Parvulastra exigua: deriving an asteroid coelomic model

Morris, V.B., Selvakumaraswamy, P., Whan, R., and Byrne, M. 2011. The coeloms in a late brachiolaria larva of the asterinid sea star Parvulastra exigua: deriving an asteroid coelomic model. —Acta Zoologica (Stockholm) 92 : 266–275. The coeloms and their interconnexions in a late pre‐metamorphic brachiolaria larva of a sea star are described from the series of images in the frontal, transverse and sagittal planes obtained by confocal laser scanning microscopy. A larval, brachial coelom connects with the coeloms of the adult rudiment that lie posteriorly. The connexion is through the anterior coelom, which lies over the head of the archenteron, to the right anterior coelom and then to the left posterior coelom through the ventral horn of the left posterior coelom. The right posterior coelom is a separate coelom. The hydrocoele is on the larval left side separated from other coeloms except for a connexion to the anterior coelom. On the larval right side, the anterior coelom and right anterior coelom connect with the pore canal that opens to the exterior at the hydropore. From these coeloms, we derived an asteroid coelomic model comprising the larval left and right coeloms linked over the head of the archenteron by a common anterior coelom. The asymmetry of the hydrocoele and the left posterior coelom on the left side linked through the common anterior coelom to the right side, with the external opening, translates into the oral and aboral coeloms of the adult stage. The coelomic model has application in the search for morphological homology between the echinoderm classes and the deuterostome phyla.     

Fine structure of the segmental ocelli of Armandia brevis (Polychaeta: Opheliidae)

Summary Armandia brevis responds negatively to light during the benthic phase and positively to light during the epitokous phase of its life history. In addition to the prostomial photoreceptors this slender translucent marine worm possesses eleven pairs of ocelli arranged serially from the 7th to the 17th segments.Each ocellus is located at the inner edge of the epidermis slightly in front of the parapodium and contains a single photoreceptor cell which gives off approximately 15 sensory processes. These processes are composed of a central core of neurofibrils surrounded by a mitochondrial layer and a compact array of microvilli. The sensory processes project into and nearly fill the ocellar cavity which is lined by squamous glial cells.The pigment cup enclosing the photoreceptor is composed of about 30 cuboidal cells packed with brown granules. The pigment cells form a mesothelium, being in direct continuity with the coelom. The cup is separated from the glial cells by a basal lamina which separates the epidermal tissues from the mesodermal derivatives of the body wall. Slender muscle fibers traverse the coelom and pass between the cells of the pigment cup.The prostomial photoreceptors were re-examined and found in this material to be composed of microvilli rather than of folds containing labyrinthine tubular infoldings of the cell surface as previously reported.The author thanks Dr. Richard M. Eakin for support and criticism. This investigation was financed by a postdoctoral fellowship, number 1-F2-GM-20, and grant number GM 10292 from the National Institute of General Medical Science.     

Triloborhynchus psilastericola n. sp., a parasitic turbellarian (Fam. Pterastericolidae) from the starfish Psilaster andromeda (Müller and Troschel)

The turbellarian Triloborhynchus psilastericola n.sp. (family Pterastericolidae) occurs in the starfish Psilaster andromeda. On approaching maturation it moves from the host's coelom into the glandular pockets of the pyloric caeca with simultaneous loss of almost the entire ciliation. Mature turbellarians feed on the tissue of the pyloric caeca.