Microscopic Anatomy and Ultrastructure of a Polian Vessel in the Sipunculan Thysanocardia nigra Ikeda, 1904 from the Sea of Japan

The microscopic anatomy and ultrastructure of a Polian vessel have been studied in the sipunculan Thysanocardia nigra Ikeda, 1904 from the Sea of Japan using the methods of histology and electron microscopy. We describe ultrastructural features of the inner and outer coelothelium, which is constructed of podocytes and multiciliary cells. Between the processes of the podocyte cells, we found double diaphragms that are considered characteristic macromolecular filters. We conclude from an analysis of the ultrastructural features of the vessel wall that coelomic fluid may be filtered from the tentacular coelom to the trunk coelom via the wall of the Polian vessel.     

Ultrastructure of Microvillar Coelomocytes from the Trunk Coelom of Thysanocardia nigra Ikeda, 1904 (Sipuncula) from the Sea of Japan

This research is part of a study on the ultrastructure of coelomocytes and cellular complexes from the body cavity of sipunculans. New free-swimming elements called microvillar cells in the trunk coelom of Thysanocardia nigra Ikeda, 1904 are examined using transmission electron microscopy. The cell harbors a giant vesicle filled with a fibrous matrix and rosettes of minute osmiophilous granules. The nucleus is peripheral, and a few cell organelles are situated between the cell membrane and the vesicular membrane. The cell membrane bears numerous microvilli with enlarged apical points. Numerous small microvillar vesicles swimming in the coelomic fluid separate from the microvillar cells. The functional morphology of coelomocytes and cellular complexes is discussed.Original Russian Text Copyright © 2005 by Biologiya Morya, Maiorova, Adrianov.     

Ultrastructure of tentacles in the sipunculid worm <Emphasis Type="Italic">Thysanocardia nigra</Emphasis> Ikeda, 1904 (Sipuncula)

The ultrastructure of the tentacles was studied in the sipunculid worm Thysanocardia nigra. Flexible digitate tentacles are arranged into the dorsal and ventral tentacular crowns at the anterior end of the introvert of Th. nigra. The tentacle bears oral, lateral, and aboral rows of cilia; on the oral side, there is a longitudinal groove. Each tentacle contains two oral tentacular canals and an aboral tentacular canal. The oral side of the tentacle is covered by a simple columnar epithelium, which contains large glandular cells that secrete their products onto the apical surface of the epithelium. The lateral and aboral epithelia are composed of cuboidal and flattened cells. The tentacular canals are lined with a flattened coelomic epithelium that consists of podocytes with their processes and multiciliated cells. The tentacular canals are continuous with the radial coelomic canals of the head and constitute the terminal parts of the tentacular coelom, which shows a highly complex morphology. Five tentacular nerves and circular and longitudinal muscle bands lie in the connective tissue of the tentacle wall. Similarities and differences in the tentacle morphology between Th. nigra and other sipunculan species are discussed.Original Russian Text Copyright © 2005 by Biologiya Morya, Maiorova, Adrianov.     

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.     

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 coelom in the brachiopod Lingula anatina

The organization of the coelomic system and the ultrastructure of the coelomic lining are used in phylogenetic analysis to establish the relationships between major taxa. Investigation of the anatomy and ultrastructure of the coelomic system in brachiopods, which are poorly studied, can provide answers to fundamental questions about the evolution of the coelom in coelomic bilaterians. In the current study, the organization of the coelom of the lophophore in the brachiopod Lingula anatina was investigated using semithin sectioning, 3D reconstruction, and transmission electron microscopy. The lophophore of L. anatina contains two main compartments: the preoral coelom and the lophophoral coelom. The lining of the preoral coelom consists of ciliated cells. The lophophoral coelom is subdivided into paired coelomic sacs: the large and small sinuses (= canals). The lining of the lophophoral coelom varies in structure and includes monociliate myoepithelium, alternating epithelial and myoepithelial cells, specialized peritoneum and muscle cells, and podocyte‐like cells. Connections between cells of the coelomic lining are provided by adherens junctions, tight‐like junctions, septate junctions, adhesive junctions, and direct cytoplasmic bridges. The structure of the coelomic lining varies greatly in both of the main stems of the Bilateria, that is, in the Protostomia and Deuterostomia. Because of this great variety, the structure of the coelomic lining cannot by itself be used in phylogenetic analysis. At the same time, the ciliated myoepithelium can be considered as the ancestral type of coelomic lining. The many different kinds of junctions between cells of the coelomic lining may help coordinate the functioning of epithelial cells and muscle cells.     

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 Morphology of the Phoronid Phoronopsis harmeri

We studied the morphology and gross anatomy of the phoronid Phoronopsis harmeriusing light microscopy and scanning electron microscopy. The body of Ph. harmeriis subdivided into several regions: a lophophore, a head, anterior, and posterior parts of the body, and an ampulla. The lophophore is spiral and comprises 0.5 turns. In males, there are lophophoral organs in the tentacular crown; under the lophophore, there is an epithelial fold or collar. The internal organization shows partitioning into three coeloms: the coelom of the epistome, the tentacular coelom, and the trunk coelom. The trunk coelom is divided into a series of chambers by a complex system of mesenteries. The intestine is U-shaped, and the epistome is located above the mouth opening. The circulatory system is closed and consists of the following vessels: the efferent and afferent circular, left and right lateral (efferent), and medial (afferent) vessels. In Ph. harmeri, there is a dorsolateral (afferent) vessel running through the ampulla and the lower part of the posterior trunk region. The excretory system is composed of paired metanephridia that resemble asymmetrical U-shaped tubes. Sexual dimorphism is characteristic of the structure of the distal part of the nephridium, which opens into the body cavity. The nervous system consists of a dorsal nervous field, a circular nerve plexus, and a giant left nerve fiber. Ph. harmeriis a dioecious species; the gametes develop in a vasoperitoneal tissue that envelops the intestine in the posterior part of the trunk region.     

Fine Structure of Tentacles,Arms and Associated Coelomic Structures of Cephalodiscus gracilis (Pterobranchia,Hemichordata)

The tentacles of the pterobranch Cephalodiscus, a hemisessile ciliary feeder, originate from the lateral aspects of the arms and are covered by an innervated epithelium, the majority of its cells bearing microvilli. Each side of a tentacle has two rows of ciliated cells and additional glandular cells. The coelomic spaces in the tentacles are lined by cross-striated myoepithelial cells, allowing rapid movements of the tentacles. One, possibly two, blood vessels accompany the coelomic canal. On their outer sides the arms are covered by a simple ciliated epithelium with intra-epithelial nerve fibres; the inner side is covered by vacuolar cells. On both sides different types of exocrine cells occur. The collar canals of the mesocoel are of complicated structure. Ventrally their epithelium is pseudostratified and ciliated; dorsally it is lower and forms a fold with specialized cross-striated myoepithelial cells of the coelomic lining. Arms, tentacles, associated coelomic spaces and the collar canal of the mesocoel are considered to be functionally interrelated. It is assumed that rapid regulation of the pore width is possible and even necessary when the tentacular apparatus is retracted, which presumably leads to an increase of hydrostatic pressure in the coelom.     

Ultrastructure of the tentacles of Themiste lageniformis (Sipuncula)

Summary An ultrastructural study of the tentacles of Themiste lageniformis (Sipuncula) was conducted as part of a larger study of head metamorphosis in the species.The oral surface of the tentacles is constructed of a multiciliated, pseudostratified, columnar epithelium while the aboral surface is an unciliated, cuboidal epithelium. Intraepidermal mucous cells lie near the junction of the oral and aboral regions. The basal portion of the epidermal cells is embedded in a thick, collagenous extracellular matrix which contains outer circular muscles, inner longitudinal muscles, the main tentacular nerve and its branches. Three tentacular canals are present and are lined by peritoneum. Hemerythrocytes and coelomocytes flow through the lumen of the canals in a regular pattern.Justification for the designation of the tentacular canals as coelomic rather than vascular is discussed.     

Coelomocyte Morphology in the Holothurians Apostichopus japonicus (Aspidochirota: Stichopodidae) and Cucumaria japonica (Dendrochirota: Cucumariidae)

The cellular composition of the coelomic fluid of the Far Eastern holothurinans Apostichopus japonicus and Cucumaria japonica was studied using light and transmission electron microscopy and histochemistry. In the coelomic fluid of A. japonicus, the following types of coelomocytes were distinguished: progenitor cells; amoebocytes; vacuolated cells; small (or young) morula cells; morula cells of type I, type II, and type III; crystal cells; and vibratile cells. In the coelomic fluid of C. japonicawere found progenitor cells, amoebocytes, vacuolated cells, morula cells of type I and type II, crystal cells, and hemocytes containing a respiratory pigment. The issue of stem cell type, which gives rise to coelomocytes, is discussed.     

Fine structure of the epistome in Phoronis ovalis: significance for the coelomic organization in Phoronida

Abstract. The hypothesis of a common ancestry of the lophophorate taxa Brachiopoda, Bryozoa, Phoronida, and the Deuterostomia can be traced back to the late 19th century when Masterman recognized a tripartite organization of the body consisting of pro-, meso-, and metasome, along with coelomic body cavities in each compartment, as characteristic for Echinodermata, Pterobranchia, Phoronida, and Brachiopoda. This idea became quite popular under the name "archicoelomate" concept. The organization of the phoronids, and especially of their transparent actinotroch larva, has for a long time been used as a touchstone for the validity of this concept. As a coelomic lining can reliably be recognized only on the ultrastructural level, this technique has been applied for adults of Phoronis ovalis , which is assumed to be a sister species to all other phoronids. Phoronis ovalis contains only two coelomic compartments, a posterior coelom inside the trunk (metasoma), occupying the space between the trunk epidermis and the digestive epithelium, and an anterior lophophoral coelom inside and basal to the tentacular crown (mesosoma). There is no coelomic cavity inside the epistome (prosoma). This part of the body is filled with myoepithelial cells, which are continuous with the epithelial lining of the lophophore cavity. These cells form a lumenless bilayer and possess long, tiny myofilamentous processes, which are completely embedded in an extracellular matrix. A comparison with data on P. muelleri shows that there is no need to assume three different coelomic cavities in Phoronida, in contrast to the predictions of the archicoelomate concept. At least for this taxon, a correspondence to the situation in deuterostomes can hardly be found.     

Ultrastructure of coelomic epithelium and coelomocytes of the starfish Asterias rubens L. in norm and after wounding

Samples of coelomic epithelium (CE) and coelomocyte suspension of intact and wounded starfish Asterias rubens L. were studied by electron microscopy. The CE was shown to be composed of three types of cells: flagellar (approximately 60%), secretory (approximately 3%), and myoepithelial (approximately 37%); flagellar and secretory cells form the CE apical surface. Secretory cells are represented by two subtypes, i.e., granular and mucous secretory cells. Myoepithelial cells are located in the basal zone of the epithelium. In 4–5% of cases, adjacent flagellar cells are separated by various sizes of intercellular gaps. These gaps seem to be lacunae left by the flagellar cells after their release into the coelomic cavity. The morphological pattern of the conversion of CE flagellar cells into coelomocytes was characterized. After a moderate wounding used in the present study, no significant structural alterations in the CE organization were revealed. In coelomocyte suspension, small rounded young coelomocytes (approximately 3%) and the larger mature coelomocytes (approximately 97%) were found. On the surface of one of the young coelomocytes, a flagellum was revealed. Surface of the mature coelomocytes forms processes of various size and structure; their cytoplasm contains lysosomes and phagocytic vacuoles of different size. After wounding, a coelomocyte activation was found that consisted of a sharp rise in the number and length of filopodia on their surface, as well as the formation of multicellular aggregates. The complex of ultrastructural data allows it to be suggested that the histogenesis of coelomocytes from CE flagellar cells is a process of cell transdifferentiation.     

Ultrastructure and formation of the body cavity lining in Phoronis muelleri (Phoronida, Lophophorata)

Among other characteristics a trimeric coelomic compartmentation consisting of an anterior protocoel, followed by a mesocoel and a posterior metacoel is traditionally believed to substantiate the sister-group relationship between Lophophorata and Deuterostomia, together forming the Radialia. As molecular data cannot support this hypothesis a reanalysis of the coelomic cavities in Phoronida is undertaken, because corresponding coelomic compartmentation is widely accepted to support the Radialia hypothesis. A coelomic cavity can be recognized on the ultrastructural level because its lining is a true epithelium with polarized cells interconnected by apical adherens junctions. This study reveals that neither in larval nor adult Phoronis muelleri (Phoronida) an anterior cavity with such a lining is present. What on the light microscopic level leads to the impression of a cavity inside the larval episphere, actually is an enlarged subepidermal extracellular matrix with an amorphous, presumably gel-like filling, into which several muscle cells are embedded. Larvae, thus, possess only one coelomic cavity, the large trunk coelom of the larva which is adopted in the adult organization. The second coelomic cavity of adult P. muelleri, the lophophore coelom, develops as a double-layer of epithelialized mesodermal cells at the base of the adult tentacle buds and becomes fluid filled during metamorphosis. Like the larval episphere, larval tentacles and most parts of the blastocoel are filled by an amorphous matrix. Reanalysis of the literature and comparison with Brachiopoda and Bryozoa allows the hypothesis that a protocoel is lacking in all Lophophorata, and that merely two unpaired coelomic cavities, one tentacle and one trunk coelom, can be assumed for the ground pattern of this taxon. These results do not provide further evidence for the Radialia hypothesis, but also do not contradict it. Accepted: 28 August 2000     

Microscopic Anatomy and Ultrastructure of Nephridium in the Sipunculan Thysanocardia nigra Ikeda, 1904 from the Sea of Japan

The microscopic anatomy and ultrastructure of nephridium have been studied in the sipunculan Thysanocardia nigra Ikeda, 1904 (Sipuncula, Sipunculidea) from the Sea of Japan using histological and electron microscopic techniques (SEM and TEM). This paper describes ultrastructural features of nephridial epithelium, muscle grid, and coelomic epithelium on the surface of the nephridium, the area of the ciliary funnel, and the tongue. Several types of cells were distinguished in the excretory tube of the nephridium: (1) a columnar epithelium of the excretory bunches; (2) a cubical or flattened epithelium of flask-shaped infoldings; and (3) granulocytes that migrate from the coelom to the extracellular matrix of the nephridial wall. The system of podocytes and multiciliary cells were described in the nephridial coelothelium. Two types of secretion of nephridial epithelium have been discovered: a merocrine secretion of columnar cells and an apocrine secretion of cells of the flask-shaped infoldings. Using ultrastructural data, two zones of filtration through the wall of excretory tube have been found, namely (1) the tips of flask-shaped infoldings (via the extracellular matrix and microvillary canals between the epithelial cells) and (2) areas between the flask-shaped infoldings (via the contacts of podocytes, extracellular matrix, and the basal labyrinth of the columnar cells). Unlike previously studied representatives of the genus Phascolosoma, no coelomic epithelium is present on the tips of the flask-shaped infoldings in Th. nigra. This data on the anatomy and histology allow us to conclude that the funnel only works like a gonoduct.     

The röle of the head coelom in proboscis eversion in Arenicola marina (I.)

The dependence of proboscis eversion on the behaviour of the trunk coelom and the effect of increasing the external resistance to eversion have been investigated in Arenicola marina (L.).Two types of proboscis eversion are distinguished; Type I, in which there is an increase of 50–100% in the volume of the head region and where the high pressures recorded in the trunk coelom are needed, it is suggested, to force fluid into the head coelom; Type II, in which the volume change in the head region is small and where simultaneous recordings of head and trunk coelomic pressures indicate that the head coelom can be isolated from the rest of the coelom.Pressures in the trunk are only related to the extent of proboscis eversion when there is a high external resistance to eversion.     

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.     

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.     

Epidermal ultrastructure of Anoplodium stichopi (Plathelminthes,Dalyellioida), a flatworm endosymbiotic in Stichopus tremulus (Holothurioida)

Summary The epidermal ultrastructure of Anoplodium stichopi Bock 1925 (Platyhelminthes, Dalyellioida, Umagillidae) was studied using transmission and scanning electron microscopy. The species lives in the perivisceral coelom of the aspidochirote holothurian Stichopus tremulus Gunnerus 1767. Two types of cells were observed in the epidermis of A. stichopi: ciliated cuboidal epithelial cells and nonciliated pear-shaped cells. The surface of the ciliated epidermal cells is folded into anastomosing ridges. Numerous coated vesicles are subjacent to the surface folds and mitochondria are abundant just below them. Observations indicate that A. stichopi takes up nutrients pinocytically from the coelomic fluid of the host. The ciliation of A. stichopi is sparse.     

An ultra-structural study of the gills of Echinus esculentus

Summary The ultrastructure of the gills of Echinus esculentus is described using transmission electron microscopy. The gills are covered by typical epithelial cells overlying a collagenous basement membrane. The coelomic lumen of the gills is thrown into a series of irregular grooves and ridges which are formed by long narrow cells from each of which projects a single cilium. There is a layer of muscle cells lying underneath these cells adjacent to the basement membrane. They are innervated by axons containing large granular vesicles and the significance of this innervation is discussed in terms of neuromuscular junctions in general within the echinoderms. This study shows that the main function of the gills is excretory and describes three apparent systems whereby excretory products and necrotic coelomocytes are removed.