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.     

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.     

The First Discovery of Trematodes (Digenea) in the Deep-Sea Acorn Worms Torquaratoridae (Hemichordata,Enteropneusta)

Doklady Biological Sciences - Trematodes found in the enteropneust hemichordates are described for the first time. Metacercariae have been found in the trunk coelom, in the collar coelom, in the...     

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.     

The physiological function of the coelom in starfish larvae and its evolutionary implications

The coelom in the bipinnaria larva of Asterias acts as a buoyancy tank. The concentrations of magnesium and sulphate in the coelomic fluid are lower than in seawater, reducing the density. The coelomic epithelium is a secretory epithelium, probably secreting sodium or chloride ions that then draw in the counter ion and water. The rate of urine production is very high for an isotonic marine animal, compensating for the large surface/volume ratio of the coelom. This function would account for the precocious development of the coelom and its association with an excretory duct. It is proposed that the coeloms of other pelagic larvae such as the actinotroch of Phoronis and of echiuran larvae have a similar function and that this may have been an original function of the coelom, although in many phyla this function has been modified or lost.     

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.     

Coelomogenesis during the abbreviated development of the echinoid Heliocidaris erythrogramma and the developmental origin of the echinoderm pentameral body plan

The development of the coeloms is described in an echinoid with an abbreviated larval development and shows the early morphogenesis of the coeloms of the adult stage. The development is described from images obtained by laser scanning confocal microscopy. The development in Heliocidaris erythrogramma is asymmetric with a larger left coelom forming on the larval-left side and a smaller right coelom forming on the larval-right side. The right coelom forms after the development of the left coelom is well advanced. The hydrocoele forms from the anterior part of the left coelom. The five lobes of the hydrocoele from which the pentamery of the adult derives take shape on the outer, distal wall of the anterior part of the left coelom. The hydrocoele separates from the more posterior part of the left coelom, which becomes the left posterior coelom. The lobes of the hydrocoele are named, based on the site of the connexion of the stone canal to the hydrocoele. The mouth is assumed to form by penetration through only the outer, distal wall of the hydrocoele and the ectoderm. Both larval and adult polarities are evident in this larva. A comparison with coelomogenesis in the asteroid Parvulastra exigua, which also has an abbreviated development, leads to predictions of homology between the echinoderm and chordate phyla that do not require the hypothesis of a dorsoventral inversion event in chordates.     

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.     

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.     

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.     

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 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.     

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.     

N-cadherin localization in early heart development and polar expression of Na+,K(+)-ATPase, and integrin during pericardial coelom formation and epithelialization of the differentiating myocardium.

N-cadherin, a Ca(2+)-dependent cell adhesion molecule, has been localized previously to the mesoderm during chick gastrulation and to adherens junctions in beating avian hearts. However, a systematic study of the dynamic nature of N-cadherin localization in the critical early stages of heart development is lacking. The presented work defines the changes in the spatial and temporal expression of N-cadherin during early stages of chick heart development, principally between Hamburger and Hamilton stages 5-8, 18-29 hr of development. During gastrulation N-cadherin appears evenly distributed in the heart forming region. As development proceeds to form the pericardial coelom (stages 6, 7, and 8, i.e., between 22 and 26 hr of development) N-cadherin localization becomes restricted to the more central areas of the mesoderm. The localization also shows a periodicity that correlates closely with the distance between foci of cavities that eventually coalesce to form the coelom. This distribution suggests that N-cadherin may have a function in the sorting out of somatic and splanchnic mesoderm cells to form the coelom. This separation of the mesoderm in the embryo for the first time physically delineates the precardiac mesoderm population. Concomitant with cell sorting during coelom formation, the precardiac cells change shape and show a distinct polarity as conveyed by (1) the apical expression of N-cadherin on precardiac cell surfaces lining the pericardial coelom, (2) the primarily lateral expression of Na+,K(+)-ATPase, and (3) an enrichment of integrin (beta 1 subunit) on basal cell surfaces. The somatic mesoderm cells apparently down-regulate N-cadherin expression. N-cadherin is also absent from the precardiac cells close to the endoderm. The latter cells eventually form the endocardium, i.e., the endothelial lining of the heart. By contrast, in the tubular, beating heart N-cadherin is found throughout the myocardium. In summary, immunolocalization patterns of N-cadherin during early cardiogenesis suggest that this cell adhesion molecule has a major role in the dynamics of pericardial coelom formation. Subsequently, its continued expression during cell differentiation of the cardiomyocyte to form the myocardium, but not endocardium, suggests N-cadherin is an essential morphoregulatory molecule in heart organogenesis.     

Axial complex of Crinoidea: Comparison with other Ambulacraria

The anatomy of Crinoidea differs from that of the other modern echinoderms. In order to see, whether such differences extend to the axial complex as well, we studied the axial complex of Himerometra robustipinna (Himerometridae, Comatulida) and compared it with modern Eleutherozoa. The axial coelom is represented by narrow spaces lined with squamous coelothelium, and surrounds the extracellular haemocoelic lacunae of the axial organ. The latter is located, for the most part, along the central oral-aboral axis of the body. The axial organ can be divided into the lacunar and tubular region. The tubular coelomic canals penetrating the thickness of the axial organ have cuboidal epithelial lining, and end blindly both on the oral and aboral sides. The axial coelom, perihaemal coelom, and genital coelom are clearly visible, but they connect with the general perivisceral coelom and with each other via numerous openings. The haemocoelic spaces of the oral haemal ring pass between the clefts of the perihaemal coelom, and connect with the axial organ. In addition, the axial organ connects with intestinal haemal vessels and with the genital haemal lacuna. Numerous thin stone canaliculi pierce the spongy tissue of the oral haemal ring. They do not connect with the environment. On the oral side, each stone canaliculus opens into the water ring. The numerous slender tegmenal pores penetrate the oral epidermis of the calyx and open to the environment. Tegmenal canaliculi lead into bubbles of the perivisceral coelom. Some structures of the crinoid axial complex (stone canaliculi, communication between different coeloms) are numerous whereas in other echinoderms these structures are fewer or only one. The arrangement of the circumoral complex of Crinoidea is most similar to Holothuroidea. The anatomical structure and histology of the axial complex of Crinoidea resembles the “heart-kidney” of Hemichordata in some aspects.     

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.     

The mechanism of burrowing of Sipunculus nudus

The method of burrowing of Sipunculus nudus L. and the movement beneath the sand is described. Pressures in the coelom have been measured and the forces exerted during burrowing are calculated.     

From larval bodies to adult body plans: patterning the development of the presumptive adult ectoderm in the sea urchin larva

Echinoderms are unique among bilaterians for their derived, nonbilateral adult body plan. Their radial symmetry emerges from the bilateral larval body plan by the establishment of a new axis, the adult oral–aboral axis, involving local mesoderm–ectoderm interactions. We examine the mechanisms underlying this transition in the direct-developing sea urchin Heliocidaris erythrogramma. Adult ectoderm arises from vestibular ectoderm in the left vegetal quadrant. Inductive signals from the left coelom are required for adult ectodermal development but not for initial vestibule formation. We surgically removed gastrula archenteron, making whole-ectoderm explants, left-, right-, and animal-half ectoderm explants, and recombinants of these explants with left coelom. Vestibule formation was analyzed morphologically and with radioactive in situ hybridization with HeET-1, an ectodermal marker. Whole ectodermal explants in the absence of coelom developed vestibules on the left side or ventrally but not on the right side, indicating that left–right polarity is ectoderm autonomous by the gastrula stage. However, right-half ectodermal explants robustly formed vestibules that went on to form adult structures when recombined with the left coelom, indicating that the right side retains vestibule-forming potential that is normally suppressed by signals from the left-side ectoderm. Animal-half explants formed vestibules only about half the time, demonstrating that animal–vegetal axis determination occurs earlier. However, when combined with the left coelom, animal-half ectoderm always formed a vestibule, indicating that the left coelom can induce vestibule formation. This suggests that although coelomic signals are not required for vestibule formation, they may play a role in coordinating the coelom–vestibule interaction that establishes the adult oral–aboral axis.