The ultrastructure of the morula cells of Eupentacta quinquesemita (Echinodermata: Holothuroidea) and their role in the maintenance of the extracellular matrix

The ultrastructure of the morula cells of Eupentacta quinquesemita and the distribution of these cells in the dermal connective tissue are described. Morula cells are abundant in the dermis and appear to function in the maintenance of the extracellular matrix (ECM) as a source of ground substance material. The synthetic activity of these cells is described in detail. Morula cells are filled with large secretory vesicles containing three electrondense materials which are derived from rough endoplasmic reticulum and Golgi activity. The synthetic product of these cells contains glycosaminoglycans and is secreted into the ECM by degranulation. The ultrastructural and histochemical similarity of the degranulation product to the ECM ground substance suggests that they are comprised of the same material. Morula cells appear to function primarily in connective tissues where ground substance predominates. The cells often contain secretory vesicles at various stages of formation, all of which eventually mature and degranulate. The synthetic pathway of the morula cells appears to result ultimately in the complete disruption and death of the cells. The function of morula cells in the holothuroid ECM is discussed, and the synthetic activity of the cells is compared with that of other secretory cells.     

Ultrastructural pathology of the compound eye and optic neuropiles of the retinal degeneration mutant (w rdgB KS222) Drosophila melanogaster

Summary Lanthanum, applied to the outside of the fixed sciatic nerve of Rana pipiens, did not enter the endoneurium, but was halted by functionally tight junctions at the inner layers of the perineurium. This component of the bloodnerve barrier consists of several concentric layers of cells interspersed with an extracellular matrix of amorphous ground substance, collagen fibrils, and fine filaments. Numerous vesicular profiles are closely associated with the surface membranes of all the cells. The application of lanthanum to fixed tissue revealed that these profiles are attached to the cell surface by narrow necks, and open to the extracellular space. The attenuated cells are filled by the vesicular structures, which often appear to overlap. Stereoscopic electron microscopy showed that these vesicles did not fuse with each other or with the apposing cell surface to form transcellular channels. Channel formation does not appear to contribute significantly to the permeability of any of the perineurial layers.     

Ultrastructure of Rickettsia rhipicephali, a new member of the spotted fever group rickettsiae in tissues of the host vector Rhipicephalus sanguineus.

Rickettsia rhipicephali is similar in ultrastructure to R. rickettsii while differing from other rickettsiae of the typhus group and of Q fever and others by its lack of a prominently reticulated cytoplasmic matrix and in the thickness of the inner osmophilic layer of the cell wall. In tissues of the tick vector Rhipicephalus sanguineus, R. rhipicephali had a mean length and width of 1.2 and 0.46 micrometer, respectively. It possessed a trilaminar cell wall with an adhering capsule-like layer. The trilaminar cell wall was approximately 12 to 18 nm thick; its inner osmophilic layer was thicker than that previously reported for other rickettsiae. The capsule-like layer varied from 7 to 18 nm thick. The plasma membrane was similar in structure, measurement, and appearance to that of other reported rickettsiae. The cytoplasm appeared to be composed of a finely granular, amorphous, ground substance and randomly dispersed ribosomes and lacked a reticular matrix or nuclear fibrils. In massively infected salivary glands and ovarial tissues of its tick vector, R. rhipicephali produced a low degree of histopathology which does not appear to affect the engorgement and egg-laying process of the ticks.     

Histochemical studies on the yolk-nucleus in fish oogenesis

Summary A histochemical study of the oogenesis of two species of fresh water fishes, Channa maruleus and Heteropneustes fossilis, was undertaken to reveal the origin, structure, histochemical nature, and function of the so-called yolk-nucleus. The basophilic substance of the yolk-nucleus, which is situated in the juxta-nuclear cytoplasm, gradually accumulates adjacent to the nuclear membrane. It is a homogeneous, spherical mass. In Channa, some basophilic, dense bodies develop in the yolk-nucleus. Histochemical tests show that the yolk-nucleus and dense bodies are rich in RNA and proteins. Mitochondria of lipoprotein composition and lipid inclusions, composed of unsaturated phospholipids, appear in association with the yolk-nucleus. Throughout previtellogenesis, the yolk-nucleus continues to proliferate its basophilic, RNA-containing substance and other inclusions. Finally it disintegrates while lying in the peripheral cytoplasm of the larger oocytes which show the synthesis of yolk bodies. During yolk formation, lipid inclusions and mitochondria start disappearing from view but the RNA-containing substance, originated from the yolk-nucleus of previtellogenesis, continues to persist among the growing yolk bodies. The latter arise de novo from the ground cytoplasm, under the influence of the RNA-containing substance, mitochondria and lipid inclusions of previtellogenesis.This work was carried out in the Department of Zoology, University of Gorakhpur, Gorakhpur, India.Population Council Post-Doctoral Fellow.     

Ultrastructural and cytochemical studies on the connective tissue of chaetognaths

The hydroskeleton plays a central role in the architecture of the trunk of the Chaetognath. Its fibrous part is composed by a ‘basement membrane’ which separates the epithelial and nervous level from the locomotory muscle and other tissues which surround the general cavity. This structure corresponds to a dense connective tissue sheath; together with the aqueous phase of the general cavity it constitutes the main part of the hydroskeleton. The axes of the lateral and caudal fins are extensions of this connective tissue; they are rich in ground substance and contain several kinds of fibrils and granules.The ‘basement membrane’ is made of a network of densely packed parallel layers of collagen fibrils which form helices which wrap around the trunk. The collagen fibrils of this connective stratum are sandwiched between two basal lamina; they are embedded in a reduced extracellular matrix whose components are closely related to the architecture of the collagen fibrils. In the core of the fin, the ground substance is very abundant and classical cross-striated collagen fibrils are not to be found. A compact fibrillar transition zone is to be noted between the dense connective stratum surrounding the body and the hyaline axis of the fins. In this zone, no crossbanded collagen fibrils are to be seen.The hydroskeleton and the fins show variations within the phylum. They could be related to speciation, and the ancestral pathway of the phylum. Furthermore these variations are related to the general problem of the evolution of the extracellular matrices and collagen molecule itself.     

FURTHER CYTOLOGICAL STUDIES OF A PERIODIC ACID-SCHIFF'S SUBSTANCE IN THE OVULES OF PASPALUM ORBICULARE AND P. LONGIFOLIUM

A periodic acid-Schiff's substance present in the micropylar end of the ovules of Paspalum orbiculare and P. longifolium was further studied by light and electron microscopy of glutaraldehyde-osmium-fixed and freeze-substituted, osmium-fixed tissues. The PAS substance is water soluble and is found in intercellular spaces between the nucellus and inner integument, the inner and outer integuments, the outer integument and ovary wall, and in the micropyle. Structurally the substance consists of fibrils embedded in a dense, amorphous matrix and may be associated with membranous structures in special layers between the plasmalemma and the cell wall in nucellar and integumentary cells. Part of the water soluble substance is believed to be secreted from the nucellar and integumentary cells. A large amount of this substance may be formed as a result of the dissolution of about one third of the distal micopylar portion of the outer integument prior to anthesis. Many of the electron-dense fibrils seem to be fibrillar intercellular substances and others appear to originate from the cell walls, including the cuticle. Both the matrix and the fibrils may be chemically heterogeneous and together form a mucilagenous substance which may facilitate the final growth of pollen tubes in these two species.     

Fine Structure of the Cellular Parenchyma and Extracellular Matrix of Ophiotaenia loennbergii (Cestoda: Proteocephalidea)

The cellular parenchyma and extracellular matrix (ECM) of Ophiotaenia loennbergii were studied by light and transmission electron microscopy. The parenchyma consists primarily of muscle cells divided into three compartments that maintain some cytoplasmic continuity: (1) myofibrils; (2) broadly lobate nucleated myocytons (muscle cell perikarya) with the perinuclear cytoplasm dominated by greatly dilated cisternae of granular endoplasmic reticulum: (3) thin anucleated sarcoplasmic extensions formed in sheets with abundant glycogen and extremely large lipid droplets, which cause the cytoplasmic sheets to bulge. These cellular compartments are separated from each other by abundant ECM, which consists primarily of an electron-lucent amorphous ground substance. Filaments are scarce in all ECM except the tegumental basement lamella. This is the first report of parenchyma and ECM fine structure in the Proteocephalidea. The results provide additional evidence that cestode parenchyma is formed from similar cells, but is subject to substantial variability between different species.     

Structural studies on the polyhedral inclusion bodies, virions, and DNA of the nuclear polyhedrosis virus of the cotton bollworm Heliothis zea.

The polyhedral inclusion body of the cotton bollworm nuclear polyhedrosis virus contains virions occluded in an orthogonal crystalline matrix. The virions appear as rods or, more frequently, as oval structures that form upon bending of the nucleocapsid within the viral membrane. The nucleocapsid consists at least of DNA surrounded by a capsid composed of subunits, possibly helically arranged. The viral DNA is circular and supercoiled. It is heterogenous in size with contour lengths ranging from 15 to 45 mum.     

Histology of skin and hair follicle

The skin consists of an outer epidermis, the dermis, and the hypodermis. It includes nerves, blood vessels, glands and hair follicles. Epidermis is a continually renewing, stratified squamous epithelium. It is populated by keratinocytes (80 %) and dendritic cells (20 %) : melanocytes, Langerhans and Merkel cells. In standard histology, keratinocytes are arranged in layers that represent different stages of their differentiation while melanocytes and Langerhans cells appear as clear cells respectively between the basal and the supra-basal cells of epidermis. The Merkel cells cannot be clearly identified. Dendritic processes of the dendritic cells can only be recognized by immunocytochemistry. At the dermal-epidermal junction, a PAS reactive basement membrane follows the contour of the basal cells. Dermis consists of collagenous and elastic fibers embedded into an amorphous ground substance. Fibroblasts, macrophages, mast cells and lymphocytes are its resident cells. Hypodermis is composed of adipocyte lobules defined by fibrous connective tissue septa. Hair follicle consists of 3 parts : the lower portion, from the base of the follicle including hair bulb to the insertion of the arrector pili muscle or buldge ; the isthmus, from the insertion of the arrector pili to the entrance of the sebaceous duct, and the infundibulum, from the entrance of the sebaceous duct to the follicular orifice. The lower portion is composed of the dermal hair papilla, the hair matrix, the hair, and the inner and the outer root sheaths. The hair matrix cells within hair bulb give rise to the hair and to the inner root sheath. With the electron microscope, one can obtain a more detailed view of the characteristic skin structures. Much of them can now be explained in terms of function and in many instances, in correlation with its biochemical composition. An attempt has been made in this paper to precisely give the location of molecules that are relevant in basic skin functions and understanding of auto-immune and genetic diseases.     

Localization of calcium and phosphorus in early predentin-matrix components by electron spectroscopic imaging (ESI)-analysis in rat molars

Summary The subcellular distribution of the inorganic elements calcium (Ca) and phosphorus (P) was studied in the first-formed dentin matrix during initial mineralization in neonatal rat molars. This most peripheral matrix region is comprised of a proteoglycan-rich ground substance, interwoven by a collagenous network, matrix vesicles, aperiodic fibrils derived from the dental basal lamina, and apical odontoblastic cell processes. All matrix components may possibly serve as templets for mineral deposition during initial calcification of first-formed mantle dentin and predentin. By means of the very sensitive ESI-analysis we studied the subcellular localization of Ca and P and their possible association with distinct organic extracellular matrix components and odontoblasts. Ca-signals were found in the ground substance, at striated collagen fibrils and plasma membranes of odontoblasts in the cuspal early matrix region, but occurred only sparsely in the ground substance of the more distal matrix region where odontoblast processes attach to aperiodic fibrils of the dental basal lamina. Ca was generally absent in matrix vesicles. In contrast, P-signals were found in matrix vesicles, at aperiodic fibrils and at the plasma membranes of odontoblasts. Ca and P co-localized at striated collagen fibrils (type I or II). These results suggest that striated collagen fibrils might serve as primary deposition sites for calcium phosphate during early biological calcification of organic extracellular macromolecules.     

H3-proline incorporation into cartilage: Electron microscope autoradiographic observations

Electron microscope autoradiography was used to study cartilage from regenerating limbs of adult newts, Triturus, after intraperitoneal injections of proline-³H. The labeling in the endoplasmic reticulum, small vesicles, Golgi vacuoles, ground cytoplasm and extracellular matrix was compared during the secretion of radioactive products. The data appear to indicate that a large part of the radioactive secretion probably leaves the cell after having been in only one cellular compartment. Although this compartment may be the endoplasmic reticulum, a considerable amount of radioactivity fluxes through the ground cytoplasm and the possibility cannot be excluded that some secretory components leave the cell directly from the ground cytoplasm. The data appear incompatible with the hypothesis that all the radioactivity seen in the extracellular matrix arrived there via a single pathway involving first the endoplasmic reticulum and then the Golgi vacuoles. It is not, however, incompatible with a hypothesis that a fraction of the radioactive product uses this pathway.     

Connective matrix organization in chronic granulomas of experimental paracoccidioidomycosis

The histological and ultrastructural aspects of chronic granulomas from rats infected intraperitoneally with Paracoccidioides brasiliensis are described with special emphasis on the composition of the extracellular matrix.The granulomas were structurally arranged in two zones, one central containing fungi, and the other peripheral.The extracellular matrix was composed of collagen types I and III, proteoglycans, glycoprotein, and an undefined amorphous substance. The main cellular population was represented by macrophages, epithelioid cells, and giant cells in the central zone, and fibroblasts in the peripheral zone.The fibrotic process was a critical event in this stage of the infection, and showed a centrifugal direction. This might be provoked by direct stimulus from the fungi or by macrophage-fibroblastic interaction.     

Identification of a nuclear protein matrix

The structural framework of the rat liver nucleus has been identified and consists of a nuclear protein matrix. This matrix is 98.4% protein, 0.1% DNA, 1.2% RNA, and 0.5% phospholipid. The nuclear protein matrix is composed primarily of three acidic polypeptide fractions in the molecular weight range of 60–70,000 daltons.     

Ultrastructure of the Alimentary Canal in Five-Month-Old Pentactulae of the Holothurian Eupentacta fraudatrix

Five-month-old pentactulae (juveniles) of the holothurian Eupentacta fraudatrixpossess a well-developed alimentary canal comprising an esophagus, a stomach, an intestine, and a rectum. The intestine in turn consists of five parts. The esophagus, stomach, and rectum are lined with a cuticular epithelium. The intestinal lining lacks a cuticle and is composed of mainly polyfunctional vesicular enterocytes. Granular enterocytes are less abundant; their cytoplasm contains electron-dense granules, which are probably zymogenic. The gut connective tissue consists of electron-lucent ground substance with collagen fibers and embedded coelomocytes. The gut mesothelium is composed of myoepithelial and peritoneal cells and contains the neurons of the hyponeural nerve plexus.     

An ultrastructural study on spicule formation in the pennatulid colony Renilla reniformis

Examination of the coenenchyme tissues of Renilla reniformis revealed two regions of crystal formation: the endoderm containing small oval deposits of unknown composition and the mesoglea containing larger elongated spicules composed of calcite. Spicule formation takes place intracellularly in scleroblasts and may be explained by the following sequential processes: an organic matrix consisting of a homogeneous ground substance and fibers is formed in a large vacuole. Calcite needles 0.4 μ in diameter develop in close association with matrix fibers and vesicles, and grow to form the central core of the spicule. Large electron dense bodies dominate the scleroblast cytoplasm during these early stages of growth. In a later stage, smaller needles 0.2 μ in diameter develop surrounding the core to form the distal lobes of the spicule. ‘Lollipop’-shaped vesicles containing fibers appear in the scleroblast cytoplasm at the onset of this stage. This material is released at the calcification front and presumably is incorporated into the spicule as an organic matrix of crystals in the distal lobes.     

Acid polysaccharides in the skeletal matrix and calicoblastic epithelium of the stony coral Mycetophyllia reesi

Like many corals the skeletal organic matrix and associated epithelium of Mycetophyllia reesi is physico-chemically unstable to preparative procedures for electron microscopy. Ethanol cryofracture of mineralized and demineralized material is accompanied by delamination of tissue and skeleton. Filamentous algae occur in the interface and account for some but not all of the separation artifact. Transmission microscopy accompanied by decalcification requires embedment in glycerol jelly to preserve the skeletal organic matrix. Even then, the matrix is not fixed and is not retained within the gel using standard double fixation with or without tannic acid as an additive. Ruthenium red, in combination with osmium, prevents the matrix from physical disruption, although positional artifacts relative to the calicoblastic epithelium are still evident. Inclusion of other glycan precipitating agents in the fixative sequence (Alcian blue, iron diamine or the detergent cetylpyridinium chloride) are more useful in preserving an acid polysaccharide-rich, fibrillar, extracellular matrix after demineralization. This material is not observed in SEM preparations. The calicoblast cells appear to be the source of this extracellular material that also appears to contribute to the composition of the mineralizing matrix. Moreover, a hyaluronan-like substance appears to play a significant role in matrix structure as suggested by its degradation by hyaluronidase.     

An ultrastructural examination of the mesoglea of Hydra

Summary The survey of the mesoglea of four species of Hydra indicates a basic similarity of structure. In each species the mesoglea consists of an amorphous ground substance with three different types of fibers and particulate material dispersed in this matrix. A probable interpretation of the fine structure of the mesoglea is that collagen-like protein demonstrated by other investigators, forms all or part of the beaded fibers. Acid mucopolysaccharide which can be demonstrated histochemically probably corresponds to the amorphous ground substance in which the mesogleal fibers are dispersed. The role of the mesoglea as an extra-cellular skeleton and cementing substance is discussed.This work was supported in part by USPHS Training grant 5T1-DH21-04 and Inst. Grant IN-57-F from the American Cancer Society.     

Extracellular matrix components of the placental extravillous trophoblast: immunocytochemistry and ultrastructural distribution

 Invasive extravillous trophoblast cells of the human placenta are embedded in a self-secreted extracellular matrix, the matrix-type fibrinoid. The ultrastructure and molecular composition of the matrix-type fibrinoid of the term human placenta were studied by transmission electron microscopy and immunogold labelling. We used antibodies directed against different matrix proteins such as collagen type IV, laminin, vitronectin, heparan sulfate, various fibronectin isoforms, and against the oncofetal blood group antigen, ”i”. Immunogold labelling patterns of matrix proteins are the basis for the subdivision of the trophoblast-derived matrix-type fibrinoid into mosaic-like patches of structurally and immunocytochemically different compartments. Firstly, fine granular patches with structural similarities to basal lamina material are composed solely of collagen type IV and laminin. Secondly, an ultrastructurally amorphous glossy substance shows reactivity with antibodies against heparan sulfate and vitronectin. A third type of patches, fine fibrillar networks embedded in the above-mentioned glossy matrix, are reactive with antibodies against normal fibronectin isoforms (IST-4, IST-6, IST-9) and oncofetal isoforms (BC-1, FDC-6). The blood group precursor antigen ”i” was not only expressed on the surfaces of the extravillous trophoblast cells but was associated with the fibronectin-positive fibrils. In conclusion, within this extracellular matrix, clear compartments of different composition can be distinguished from each other. Glycosylation with ”i” in this matrix may be involved in immunological masking, thus preventing rejection of placenta and fetus. Accepted: 6 May 1996     

Basement membrane components secreted by mouse yolk sac carcinoma cell lines

Three new cell lines (NE, ME, LRD) were cloned from mouse-embryo-derived teratocarcinomas and characterized on the basis of developmental, ultrastructural, and cytochemical criteria as nullipotent embryonal carcinoma (EC), pure parietal yolk sac (PYS) carcinoma and mixed parieto-visceral yolk sac carcinoma respectively. Cell lines NE and ME were composed of a monomorphous cell population; however, the morphology of ME was growth-medium-dependent. LRD was composed of a heterogeneous cell population and formed embryoid bodies. NE secreted soluble laminin, osteonectin, entactin and fibronectin but did not form visible pericellular matrix. ME formed pericellular matrix which was composed of laminin and entactin, but did not contain fibronectin. The LRD cells formed pericellular matrix which was composed of laminin, entactin and fibronectin. Whereas laminin from ME and LRD reacted with polyclonal antibodies and a monoclonal antibody to parietal yolk sac laminin, the laminin from NE cells was unreactive with the monoclonal antibody. Osteonectin was found in the supernatant of LRD and ME, but could not be demonstrated immunohistochemically in the extracellular matrix. We conclude that some extracellular matrix components, such as laminin and fibronectin, are produced not only by yolk sac carcinoma cells but by nullipotent EC as well, although the latter do not assemble them into extracellular matrix. Laminin produced by EC is immunochemically different from laminin secreted by yolk sac carcinoma. The extracellular matrix produced by mixed parieto-visceral yolk sac carcinoma is different from the matrix laid down by the pure PYS in that the latter does not contain fibronectin. The lack of osteonectin in the extracellular matrix of yolk sac carcinoma cells indicates that not all polypeptides secreted by these cell lines are incorporated into the extracellular matrix. The new cell lines described in this paper differ with regard to their capacity to form extracellular matrix and secrete its various components. Hence they could be used for further studies of basement membrane assembly in vitro.     

Visions for novel biophysical elucidations of extracellular matrix networks

The extracellular matrix consists of multifunctional molecules, which are composed of a large numbers of different domains. Clearly these domains and even the entire molecules do not function independently as isolated species, but interact with each other in large networks. In many cases specific regions of the networks may be considered as molecular machines in which the different molecules are arranged in highly defined spatial structures and act in a dynamic, concerted fashion. At present most structural information is limited to single molecules, and dynamics have been measured mainly for pairs of interacting partners in solution. Work needs to be extended to large integrated systems and the functions of molecular machines need to be explored. Electron tomography, fluorescence resonance energy transfer, and other biophysical techniques are very promising.