A morphological study of the nervous system of the praesoma of Octospinifer macilentus (Acanthocephala: Noechinorhynchidae)

The nerve pathways in the praesoma are described for the first time for a member of the genus Octospinifer. Eleven nerves, five paired, and one single, are traced from the cerebral ganglion to their associations with the musculature of the body wall, neck sense organs, and the musculature of the proboscis wall and the invertor muscles of the proboscis. The structure and location of the Stützzelle (support cell) and its association with the neck sense organs are described. A comparison with the nervous system in the praesoma of Noechinorhynchus and Paulisentis is discussed.     

Ultrastructure of lemnisci in Polymorphus magnus (Acanthocephala, Polymorphidae)

The ultrastructure of lemnisci in female acanthocephala (Polymorphus magnus) has been studied. Lemnisci are shown to be specific metabolic centers, where lipids are accumulated and utilized. Lipids get to these centers either by means of absorption by praesomal tegument or from the pseudocoel through the system of invaginations of cytoplasmic membrane limiting the lemnisci. Lipids are supposed to be transported after conversion into the praesoma tegument and secreted to its surface through the striated layer canals.     

The ultrafine structure of the body wall of sexually mature thorny-headed worms Echinorhynchus gadi (Acanthocephala)]

Studies of the fine structure of the adult acanthocephalan Echinorhynchus gadi have given a new information on the structure and organization of the body wall of these parasitic helminths. Their body surface is covered by glycocalyx of mucopolysaccharide nature. Just under it there is the surface membrane which has numerous invaginations forming a network of branching canals from which membrane vesicles are isolating. In their turn these canals pass through "the cytoplasmic canals" of the cortical matrix. Between the surface membrane and cortical matrix there is the base plate. These three structures form the striped layer underlain by the felt layer. It is formed by three layers of fibrous strands (one circular and two longitudinal), which are parallel to the body surface. These strands consist of loosely laid fibrils. The lowest layer is a radial one which occupies 2/3 of the body wall. It consists of the radial strands beginning from the cortical matrix and ending at the basement membrane. Numerous lipid droplets and glycogen granules are formed here. Two types of fibrils with 0.26 and 0.05 diameter have been detected for the first time. The radial layer in the cytoplasm was found to have crystalline structures and polymembrane bodies, numerous nuclei with light karyoplasm and distinct nucleoli. The location of the nuclei is of two types: either in the cytoplasm or in the "lacunae". We have shown that the "lacunae" are specialized sites of the cytoplasm whose boundaries are marked by the fibres of two types. Besides, this type of the acanthocephalan was found to have two "giant lacunae" extending along the body.(ABSTRACT TRUNCATED AT 250 WORDS)     

The body wall of Halicryptus spinulosus (Priapulida) — ultrastructure and changes induced by hydrogen sulfide

Halicryptus spinulosus (Priapulida) is extraordinarily resistant to hydrogen sulfide. As described previously, the body wall of specimens from oxic and from hydrogen sulfide-contaminated habitats differs strikingly in colour. In the present paper the ultrastructure of the body wall of specimens kept under oxic conditions is described. These findings serve as a reference for changes induced by exposure to hydrogen sulfide. There are marked ultrastructural differences between epidermal and muscular mitochondria exposed to hydrogen sulfide. Epidermal mitochondria of individuals subjected to hydrogen sulfide are often associated with dense granules of unknown composition. Findings are compared with those from other taxa which may encounter hydrogen sulfide in their environment.Contribution No. 386 of the Alfred-Wegener-Institut für Polar- and Meeresforschung (Awl Bremerhaven).     

The ultrastructure of the capsule surrounding Pomphorhynchus laevis (Acanthocephala) in its intermediate host Echinogammarus stammeri (Amphipoda).

The capsule or the membranous layer surrounding larvae of Pomphorhynchus laevis Müller, 1776 in its intermediate host, Echinogammarus stammeri S. Karaman, 1931, was studied by electron microscopy. Some observations were also made with a light microscope. Capsule components mainly show a tubular profile; capsule thickness can reach up to 8 microns. In some instances, within the hemocoel of E. stammeri, the parasite was encapsulated by amphipod hemocytes.     

The ultrastructure and formation of the calcareous ossicles in the body wall of the sea cucumber Leptosynapta clarki (Echinodermata,Holothuroida)

Summary The calcareous ossicles of the burrowing sea cucumber Leptosynapta clarki have been examined by scanning and transmission electron microscopy. The ossicles occur in the dermis of the body wall and comprise three main types: 1) curved rods; 2) miliary granules; and 3) anchorshaped structures that are paired with oval plates. Rods average about 80 m in length, and miliary granules are typically 20–30 m long. Both of these ossicles appear to form a protective skeleton in regions where the water vascular system and accompanying nerves are located. Anchors and plates are scattered throughout the interambulacra of the body at densities ranging from 2–8/mm². Each anchor measures about 145 m long and is attached to the plate underlying it by a flexible ligament that is composed of collagen fibrils. Tetracycline labeling studies indicate that anchors and plates take several months to reach full size. All developing ossicles appear to be surrounded by a syncytial network of sclerocytes that characteristically possess numerous mitochondria and a conspicuous external lamina. Fully formed anchors lie directly beneath the epidermis and do not protrude through the outermost layer of the body wall. During burrowing, the curved flukes of the anchorshaped ossicles may provide added traction as the buccal tentacles dig through the sediment.List of abbreviations a anchor - ar ambulacral region - cm circular muscle layer of body wall - cs cytoplasmic sheath - d dermis - ep epidermis - f fluke - ild inner layer of dermis - k keel - me myoepithelium - mg miliary granule - n nerve - old outer layer of dermis - os ossicle - pl plate - s sclerocyte - sh shank - st stock     

Spore morphology and wall ultrastructure of Trachypteris species (Pteridaceae)

Trachypteris is a small genus consisting of four species native to America and Madagascar: Trachypteris induta, T.?pinnata, T.?gilliana, and T.?drakeana. The spores of the genus were studied using light microscopy and scanning and transmission electron microscopy. They are trilete, triangular to globose, with equatorial diameter of 29?C58???m and polar diameter of 26?C53???m. The exospore is 0.5?C1.1???m thick, plane, and two-layered. The perispore is 0.3?C6.8???m thick and two-layered. Depending on the species, two different ornamentations were observed: cristated with partially fused cristae, and ridged with partially fused ridges, forming an incomplete reticulum. Globules immersed in the perispore were occasionally observed. The systematic value of the Trachypteris spores is discussed, and their morphology and ultrastructure are compared with those of other related cheilanthoid ferns. The palynological characteristics presented here may be useful for phylogenetic studies within the Pteridaceae, and particularly within the cheilanthoid ferns.     

The body wall of cheilostome bryozoa IV. The frontal wall of schizoporella unicornis (Johnston)

The frontal wall of Schizoporella unicornis (Johnston) develops as a partition of the coelom just before ascus formation. The ascus develops proximally from the proximal border of the aperture. S. unicornis, therefore, belongs to the monothetic Order Cryptocystidea. The outer part of the opercular cuticle is lost during development.     

The elaboration of the acanthor shell of Acanthosentis acanthuri (Acanthocephala)

The periembryonic envelopes of an Eoacanthocephala Acanthosentis acanthuri and their elaboration during embryogenesis are, for the first time, described in this study. In studying the evolution of the "fertilization membrane" in particular, it became evident that slight modifications occur and then the "fertilization membrane derivative" is gradually pushed towards the exterior by the new envelopes secreted by the developing embryo. It therefore forms the outermost envelope surrounding the mature acanthor. In A. acanthuri, a series of more "true" envelopes composed of solid material and separated by fluid granular spaces were observed around the acanthor. A nomenclature is proposed in order to make a clear distinction between the envelopes (E1-E4) and the granular spaces (G1-G4).     

The ultrafine morphology of the integument of thorny-headed worms (Acanthocephala)

Different cited and author's data on the ultrastructural morphology of tegument in Acanthocephala are analyzed and discussed.     

Spore wall ultrastructure in Anogramma species (Pteridaceae) from Argentina

The sporoderm ultrastructure of Anogramma Link species, which grow in Argentina, was studied using scanning and transmission electron microscopy. The species A. chaerophylla (Desv.) Link and A. lorentzii (Hieron.) Diels were studied with TEM for the first time. The spores of both species have a sculptured, apparently two-layered exospore. The perispore is uniformly thickened on the whole surface: in A. chaerophylla it is three-layered, while, in A. lorentzii it is single-layered with a complex structure. Spherules are present on the perispore surface or incorporated into the structure of A. chaerophylla while, globules exist on and within the perispore in A. lorentzii. The sporoderm ultrastructure in these two species was compared with other cingulate genera within the Pteridaceae. The characteristics found in this work, with respect to spore wall structure and general morphology, suggest that these characters may differentiate species within genus.     

The ultrastructure of the cyst wall of Giardia lamblia

Giardiasis is the most common human protozoal infection. In their cystic phase, giardias are protected from the environment by a filamentous cyst wall made up of carbohydrates, proteins, and by two outer membranes separated from the plasma membrane of the parasite by a peripheral space. The present transmission electron microscope observations of G. lamblia cysts of human origin suggest that the extracellular peritrophic space originates from the growth, elongation, and fusion of large cytoplasmic vacuoles. As the large clear vacuoles grew in size, flattening against the inner face of the plasma membrane, they formed a single vacuole that surrounded the body of the parasite, eventually forming two outer membranes. In mature Giardia cysts, the original plasma membrane of the trophozoite becomes the outermost membrane of the cyst wall (CM1). The large vacuoles form a second membrane surrounding the cyst (CM2), and also form a third membrane (CM3), that becomes the new plasma membrane of the trophozoite. During excystation CM1 and CM2 attach to each other and fragment, leaving abundant membrane residues in the peritrophic space. Knowledge of the biochemical composition and functional properties of the complex outer membranous system of G. lamblia cysts here described will be of use to understand the survival of Giardia cysts in the environment, a major factor responsible for the high prevalence of giardiasis worldwide.