The structure and composition of the cyst wall of the metacercaria of Cloacitrema narrabeenensis (Howell & Bearup, 1967) (Digenea: Philophthalmidae).

The mstacercarial cyst of Cloacitrema narrabeenensis which is formed in the open is composed of four layers: an outermost layer of acid mucopolysaccharide, a layer of protein which is presumed to be tanned, a layer of neutral mucopolysaccharide and an innermost layer of keratinized protein. The two layers which together form the outer cyst wall can be split off by slight pressure from the two remaining layers which together form the inner cyst wall. In the centre of the ventral side of the inner cyst wall, the keratinized layer is incomplete and this ventral plug region is composed of neutral mucopolysaccharide. The cyst wall is therefore very similar to that of Fasciola hepatica, the main difference being that the order of the two layers of the outer cyst is reversed. General evolutionary and functional relationships of metacercarial cysts are discussed.     

Histochemical characteristics of the egg envelopes of Acanthosentis sp. (Acanthocephala).

The histochemical and phase contrast observations on the embryonic envelopes enclosing the acanthor of Acanthosentis sp. reveal the presence of three layers. All the three layers were non-refractile during early stages of their formation, and become refringent subsequently. The outer layer loses its refractile property together with affinity for acid and basic dyes when the eggs are fully developed. This layer is neither tanned nor chitinous. The second layer consists of glyco-lipo-proteinous matrix. The polysaccharide moiety is identified to be strongly sulfated acid mucopolysaccharide. The lipid component has been characterized to be KOH resistant and esters of unsaturated fatty acid. The protein is rich in aromatic amino acids. The third and the innermost layer contains chitin and acid mucopoly-saccharides. The protein is rich in sulfur-containing amino acids. Sulphydryl groups were present during early stages of its formation, but forms disulphide cross-links subsequently. Stages in the development of acanthors were characterized with reference to the formation of envelopes. The permeability experiments carried out on fresh eggs using 0.1% aqueous solutions of bromophenol blue, methylene blue, toluidine blue, basic fuchsin and neutral red indicate that the inward diffusion of these substances is prevented subsequent to formation of disulphide groups in the innermost layer. The results further indicate that the embryo derives nutritive requirements from the fluid of pseudocoel of the female worm through th envelopes covering it.     

Outer Layers of the Azotobacter vinelandii Cyst

Ruthenium red stained a capsule external to the exine of the Azotobacter cyst. The central body is therefore surrounded by three layers, the intine, the exine, and the capsule, all containing acid mucopolysaccharide. Vesicles that appear to originate from the contracting cell membrane of the central body may account for the lipid content of the intine. The exine is composed of laminated sheets that tend to fragment into hexagonal pieces.     

Spectrophotometric determination of acid mucopolysaccharides

The present report describes a novel spectrophotometric method for the quantitative determination of acid mucopolysaccharides based on the interaction of these macromolecules with the zirconyl ion. The method is simple, accurate, and involves the determination of the acid mucopolysaccharide molecules rather than their hydrolytic components (as in the case of existing methods of analysis). Substances, which are normally present in the acid mucopolysaccharide preparations (such as protein, glycoprotein, and nucleic acid), do not interfere with the determination.     

Fine structure of the cell surface and Golgi apparatus of Ochromonas

Ochromonas danica has an unusually flexible cell surface capable of producing projections of varying sizes and shapes: large projections, 340-360 nm long, and small projections, 50-110 nm long. These projections have been demonstrated by transmission and scanning electron microscopy; some of them may break off into the medium and be the source of extracellular membranes and vesicles reported in the cell-free O. danica growth medium. Ruthernium red stained the acid mucopolysaccharide layer just outside the cell surface as well as small blebs at the cell surface. The Golgi complex of O. danica, Ochromonas malhamensis, Ochromonas sociabilis and Ochromonas sp. produced small coated vesicles which may move toward and fuse with the plasma membrane. The role of the several vesicles is unknown but possible functions are discussed.     

Hertiable Disorders of Mucopolysaccharide Metablism

The heritable diseases of mucopolysaccharide metabolism have undergone reclassification during the past several years as a result of advances in knowledge. Recognition of clinical, genetic and biochemical differences has made it possible to delineate six types of mucopolysaccharidosis. All types are characterized by excessive excretion of one or more acid mucopolysaccharides in the urine.The underlying defect is not known at present, but recent investigations have suggested possible defects in protein binding and increased biosynthesis and storage of the various mucopolysaccharides.Treatment of these disorders has been unrewarding, although administration of corticosteroids may be of some benefit.Several diagnostic tests are now available for the determination of excessive urinary acid mucopolysaccharide excretion.     

Copillaria hepatica: Fine structure of egg shell

The structure of the Capillaria hepatica egg shell was studied with the electron microscope and correlated with light microscope histochemical observations. The shell is composed of fibrous and nonfibrous components, both of which stain for protein. The fibrous component, the major portion of the shell, consists of submicroscopic fibers. The nonfibrous component is located in the outer region of the shell but is not always visible; when present it has a reticulated appearance in electron micrographs. The fibrous component is divided into outer and inner regions. The outer region is composed of radially arranged pillars which are connected at their outer surface by a beam-like network and are anchored at the base to a compact inner region. The inner region consists of a series of concentrically arranged lamellae above which is located a nonlaminated region where the pillar bases originate. At each polar end of the shell is a single opening plugged with a material which contains acid mucopolysaccharide. The fine structure of the body of the plug is unresolvable with the electron microscope; its outer surface is impregnated with electron dense particles. Externally the shell is covered by a 250 Å thick continuous membrane which is in close opposition to the surrounding host tissue.     

Histochemical studies of jelly coat of sea-urchin eggs during oogenesis

Summary Jelly coat of sea-urchin eggs consists of polysaccharides and glycoproteins. Some properties of jelly coat have already been investigated, but not histochemically. The oogenesis in Paracentrotus lividus was studied histologically and the oocytes were classified into six different stages. The extracellular jelly appeared first around the growing oocytes II which remained attached to the germinal epithelium. The jelly became thicker when the oocyte approached maturation. Histochemical analysis revealed that the jelly consists of mucopolysaccharide-protein-complexes. The polysaccharide component is composed of both neutral and acid mucopolysaccharides. The former are amylase-resistant. The acid mucopolysaccharides contain both carboxyl and sulfate groups, which are in close proximity to vicinal hydroxyl groups. Sulfated mucopolysaccharide is hyaluronidase-resistant. Sialic acid could not be clearly demonstrated, because it seems to be resistant to neuraminidase. Pepsin digestion indicated the masking of acidic groups by proteins which compete with basic dyes (Alcian blue, Azure A, coriphosphine etc.). Proteolytic digestion enhanced dye-binding ability of jelly, but removed also some of the periodate-reactive mucosubstances. Also a protein component could be demonstrated histochemically. No histochemical difference between jelly coat of oocytes and that of eggs has been found. The possible molecular structure of jelly coat is discussed.     

DEPENDENCE OF SALIVARY EPITHELIAL MORPHOLOGY AND BRANCHING MORPHOGENESIS UPON ACID MUCOPOLYSACCHARIDE-PROTEIN (PROTEOGLYCAN) AT THE EPITHELIAL SURFACE

The morphogenetic role of the acid mucopolysaccharide (glycosaminoglycan) at the epithelial surface of mouse embryo submandibular glands has been studied by comparing the in vitro morphogenesis of epithelia from which the mucopolysaccharide was removed with that of those that retained the mucopolysaccharide. Epithelia isolated free of mesenchyme by procedures which retain the bulk of surface mucopolysaccharide maintain their lobular shape and undergo uninterrupted branching morphogenesis in culture in direct combination with fresh mesenchyme. Under identical culture conditions, epithelia from which surface mucopolysaccharide was removed lose their lobules and become spherical masses of tissue. During continued culture, the spherical epithelia produce outgrowths from which branching morphogenesis resumes. The morphogenetically active mucopolysaccharide is localized within the basal lamina of the epithelial basement membrane and appears to be bound to protein. During culture in combination with mesenchyme, epithelia undergoing uninterrupted morphogenesis show maximal accumulation of newly synthesized surface mucopolysaccharide at the distal ends of the lobules, the sites of incipient branching. In contrast, the material accumulates nearly equivalently over the surface of the spherical epithelia, with the exception that there is greater accumulation of the material at the surfaces of the budding outgrowths, the sites where morphogenesis will resume. Rapidly proliferating cells are localized within the lobules of epithelia undergoing uninterrupted morphogenesis, but are distributed uniformly in the cortex of the spherical epithelia, except for the outgrowths which show a greater localization of proliferating cells. It is concluded that normal salivary epithelial morphology and branching morphegenesis require the presence of acid mucopolysaccharide-protein within the epithelial basal lamina.     

The mucus producing glands and the distribution of the cilia of the pulmonate slug Limax pseudoflavus

The gross anatomy and histochemistry of the mucus-producing glands of Limax pseudoflavus Evans were investigated. The body mucus can be divided into three areas. The dorsal body surface is covered with a sulphated acid mucopolysaccharide/protein mixture secreted largely by five cell types. The pedal mucus is a mixture of neutral mucopolysaccharide from the suprapedal gland. The dorsal and pedal mucus sheets are separated by the peripodal groove whose cells secrete a weakly acid mucus. The duct of the suprapedal gland, the epidermis around the pneumostome, the ventral surface of the peripodal groove and the centre of the underside of the foot are ciliated. The dorsal and pedal mucus remain stationary relative to the body and the substrate respectively and the only rejection currents seen in the mucus are around the pneumostome.
It is suggested that the pedal mucus is formed by the mixture of the products of the suprapedal gland and the mucoprotein secreting gland in the leading edge of the foot, thus producing a mucus suitable for locomotion. Many areas of the animal (e.g. the head, pneumostome, sole and the leading edge of the foot) are capable of producing both a fluid (neutral or weakly acid) and a viscous (acid) mucus. It is postulated that such an arrangement allows for both adhesion and lubrication at different times.     

High molecular mass glycans are major structural elements associated with the laminated layer of in vitro cultivated Echinococcus multilocularis metacestodes

The laminated layer of the larval stage (metacestode) of the cestode parasite Echinococcus multilocularis is composed largely of carbohydrates, which form a tight microfibrillar meshwork around the entire metacestode. Since this laminated layer is the only parasite structure which is in constant contact with host immune and non-immune cells, and appears largely resistant to physiological and immunological reactions of the host, it most likely carries out important functions with regard to host-parasite interactions. In infected hosts, the metacestode is usually concentrically covered by host connective tissue cells and large amounts of collagen, causing a dense scar-like fibrosis, and it is likely that host-derived components are incorporated into the laminated layer at the host-parasite interface. Therefore, in order to obtain information on the molecular composition of this structure, we used parasite larvae which were generated through in vitro cultivation and thus were largely devoid of interfering host components. Lectin fluorescence on section-labelling of metacestodes embedded in LR-White suggested that the laminated layer is largely composed of N-acetyl-beta-D-galactosaminyl, and alpha- and beta-D-galactosyl residues, as well as of the core structure of O-linked carbohydrate chains, N-acetylgalactosamine-beta-1.3-galactose, while N-linked glycopeptides and alpha-D-mannosyl residues and/or glucosyl residues were found mainly within the germinal layer, and within the cellular mass and the surface of developing protoscoleces. Lectin-gold EM confirmed these findings. The laminated layer was isolated from in vitro cultivated metacestodes by urea extraction, and the ultrastructure of the purified laminated layer was assessed comparatively with respect to the laminated layer of intact parasites. The glycan composition was determined using SDS-PAGE and lectin blotting. This work has laid the basis for a more detailed dissection of the molecular composition of the laminated layer.     

The surface coats on spores

There are surface coats on the sporocytes and spores of some pteridophytes and bryophytes which will bind one or more of the stains generally used to demonstrate the presence of an acid mucopolysaccharide surface coat in animal cells, viz. Alcian blue, colloidal iron, lanthanum, thorium, silver, SO,-coriphosphine and phosphotungstic acid. This suggests that the composition of the coat substances in the ferns and bryophytes agrees with that in animal cells. It has been found that thorium-staining in the sporocyte and the coat of the young spore of one fern, Botrychium lunaria , can be abolished with neuraminidase, indicating that sialic acid is a principal component of these coats. The spore wall in the pteridophytes (and probably also in the bryophytes) is constructed within these mucopolysaccharide surface coats, and it is suggested that differences in wall form are attributable to qualitative, quantitative and functional differences of the coats.     

The body wall of cheilostome Bryozoa. I. The ectocyst of Watersipora nigra (Canu and Bassler)

The cuticle of Watersipora nigra is at first translucent, but it later becomes black and differentiates into two layers. It is composed, at least in part, of a protein-polysaccharide complex. Calcified parts are three-layered: (1) an outer, cuticular layer, (2) a calcium carbonate skeleton deposited on a matrix of acid mucopolysaccharide, and (3) a “skeletal membrane.” The relationships of these layers indicate that the skeleton is intracuticular. A layer of cuticular material, the “intercalary cuticle” is present in lateral walls, but not transverse walls; it may become calcified in some species. The cuticles of calcified and uncalcified parts of cheilostomes are not necessarily homologous.     

Intraluminal transport of iron from stomach to small-intestinal mucosa

Inorganic iron rarely exceeds 10⁻⁴ molar concentration in the stomach after a meal. Natural sugars, ascorbic acid, citric acid, and amino-acids form iron complexes, and if they are present in the meal complexing occurs when the gastric contents are neutralized. In their absence an iron complex is formed with gastric mucopolysaccharide, which acts as a carrier, stable at neutral pH. Iron can be detached from this carrier at neutral pH by some low molecular weight substances, of which citric acid, ascorbic acid, and cysteine are particularly effective at low concentrations. Under normal circumstances most of the iron released from food in the stomach becomes bound to the mucopolysaccharide carrier.     

Fine Structure of the Cell Surface and Golgi Apparatus of Ochromonas*

SYNOPSIS. Ochromonas danica has an unusually flexible cell surface capable of producing projections of varying sizes and shapes: large projections, 340–360 nm long, and small projections, 50–110 nm long. These projections have been demonstrated by transmission and scanning electron microscopy; some of them may break off into the medium and be the source of extracellular membranes and vesicles reported in the cell-free O. danica growth medium. Ruthenium red stained the acid mucopolysaccharide layer just outside the cell surface as well as small blebs at the cell surface. The Golgi complex of O. danica, Ochromonas malhamensis, Ochromonas sociabilis and Ochromonas sp. produced small coated vesicles which may move toward and fuse with the plasma membrane. The role of the several vesicles is unknown but possible functions are discussed.     

ACID MUCOPOLYSACCHARIDE (GLYCOSAMINOGLYCAN) AT THE EPITHELIAL-MESENCHYMAL INTERFACE OF MOUSE EMBRYO SALIVARY GLANDS

Acid mucopolysaccharide (glycosaminoglycan) has been demostrated at the epithelial-mesenchymal interface of mouse embryo submandibular glands by (a) specific staining for polymeric sulfate with Alcian blue 8 GX at various magnesium concentrations, (b) specific staining for polymeric uronic acid by selective oxidation of these residues to Schiff-reactive compounds, (c) electron microscope localization of ruthenium red staining, (d) radioautographic localization of glucosamine-³H and ³⁵SO₄, and (e) by susceptibility of the glucosamine radioactivity at the interface to digestion with protease-free hyaluronidase. Moreover, material labeled with glucosamine-³H and ³⁵SO₄ and with chemical characteristics identical with those of acid mucopolysaccharide were isolated from the glands. Acid mucopolysaccharide is distributed over the entire epithelial surface. The amount of acid mucopolysaccharide, as revealed by the staining procedures, is nearly equivalent at all sites. In contrast, the rate of accumulation of glucosamine-labeled mucopolysaccharide is greater at the surface of the distal ends of the growing and branching lobules. This distribution of newly synthesized acid mucopolysaccharide at the sites of incipient cleft formation suggests that surface-associated acid mucopolysaccharide is involved in the morphogenetic process. A mechanism of branching morphogenesis is proposed which accounts for the distribution of collagen fibers and total and newly synthesized acid mucopolysaccharide at the epithelial surface.     

Cytochemistry of the skin of patients with mucopolysaccharidoses.

The distribution of complex carbohydrates has been investigated at the light and electron microscope levels in sweat glands of normal subjects and patients with Hurler's or Hunter's disease. Normal sweat glands examined with a battery of light microscopic histochemical methods revealed sulphated complex carbohydrate in secretory granules of the dark cells. These granules lacked affinity for dialysed iron (DI) at the light and electron microscope levels. The DI method demonstrated acid complex carbohydrates ultrastructurally on the surface of the intercellular canaliculi and central lumen in normal sweat glands. DI-reactive acidic material, presumably of mucopolysaccharide nature, surrounded and extended between collagen bundles in the stroma of normal skin, but was absent from the band which ensheathed the sweat gland and consisted of individual rather than bundled collagen fibrils. DI-reactive mucopolysaccharide lined and partially filled vacuoles of dark cells showing a laminar distribution in vacuoles of clear cells in sweat glands of a Hunter patient. The DI method also visualized mucopolysaccharide distributed throughout vacuoles in fibroblasts of this patient. DI-reactive acid material covered the luminal surface of the sweat gland, coated collagen bundles in the stroma and spared the periglandular collagenous sheath in skin from Hurler and Hunter patients as in that from normal controls. Acid phosphatase was localized ultrastructually in vacuoles and nearby cytoplasm and on plasmalemmae of clear cells, dark cells and myoepithelial cells of sweat glands from Hurler and Hunter patients. Vacuoles of dermal fibroblasts and Schwann cells in these specimens also exhibited strong acid phosphatase activity.     

Laminated figures of the intercisternal regions of dictyosome-like structures from guinea-pig spermatocytes fixed with glutaraldehyde-tannic acid

Dictyosome-like structures (DLS) of guinea pig spermatocytes, when prefixed in mixtures of glutaraldehyde and tannic acid, exhibited laminated figures with a repeating periodicity of about 4.5 nm in the spaces between DLS saccules or in association with the surfaces of the DLS saccules. These laminated figures were similar to those figures derived from saturated lipids in other tissues. Alternatively, spaces between saccules were collapsed leaving only thin, electron-dense material separating adjacent saccules. These changes were not observed when the DLS were prefixed in glutaraldehyde before exposure to tannic acid. The presence of laminated figures following fixation with tannic acid and osmium tetroxide suggests that saturated lipids are present in, or associated with, the intersaccular regions of the DLS. The distribution of laminated figures in other membrane structures was not affected by post fixation with tannic acid nor were laminated figures comparable to those of the DLS observed between cisternae of the Golgi apparatus. These results support previous conclusions that DLS are distinct from Golgi apparatus and are a unique component of the germ cell cytoplasm.     

Expression of different regional patterns of fibronectin immunoreactivity during mesoblast formation in the chick blastoderm

The appearance and distribution of the extracellular material glycoprotein, fibronectin, was investigated in gastrulating chick embryos using affinity-purified anti-human plasma fibronectin antibodies. Preservation of tissue structure and immunoreactivity was carried out by ethanol/acetic acid fixation or by formaldehyde/glutaraldehyde fixation. Using the former fixation method, fibronectin immunoreactivity was detected (1) at the ventral surface of the upper layer or epiblast, mainly anterior and lateral to Hensen's node, in regions where middle-layer or mesoblast cells are not yet present, and (2) sparsely in extracellular spaces of the deep layer. Using the latter fixation method, fibronectin immunoreactivity was, moreover, found at the entire ventral surface of the upper layer, i.e., also at the epithelial-mesenchymal interface, where a basement membrane was previously described. At the light microscope level, we could not detect significant immunoreactivity in the middle layer. Treatment of sections of ethanol-fixed blastoderms with testicular hyaluronidase before immunostaining for fibronectin partially demasked the antigenic sites of this glycoprotein at the epithelial-mesenchymal interface. The present report indicates that the different regional patterns of fibronectin immunoreactivity in the basement membrane of the upper layer are spatially and temporally correlated with migration and positioning of mesoblast cells. These regional patterns are probably due to differences in the composition of fibronectin-associated material such as chondroitin sulfate A and/or C proteoglycans, and/or hyaluronate, before and after mesoblast expansion, rather than to differences in the distribution of fibronectin itself. In this respect, it is noteworthy that the chemical composition of the basement membrane of an epithelium changes as mesenchyme cells migrate over it. The results also favor the idea that fibronectin is a structural component of the whole basement membrane which is used as a substrate for migration of mesenchymal cells.     

THE ENTERIC SURFACE COAT ON CAT INTESTINAL MICROVILLI

The enteric microvilli of the cat, bat, and man are coated with a conspicuous layer composed of fine filaments radiating from the outer dense leaflet of the plasma membrane. This surface coat is prominent on the absorptive cells but is not so thick on the goblet and undifferentiated crypt cells. In other species the surface coat is poorly developed or inconsistent, but all intestinal microvilli have traces of such a coating over the tips and sides of the microvilli. Tissues prepared by the ordinary sectioning techniques for electron microscopy usually reveal this component when stained with uranyl acetate followed by lead staining. The surface coat is intensely periodic acid-Schiff (PAS) positive and reacts with Alcian blue or Hale's colloidal iron stain for acid mucopolysaccharide. It is also stained by toluidine blue at low pH. Repeated washings or incubation with various chemical agents have failed to remove or markedly alter the appearance of the coating, but extruded cells undergoing autolysis lose their surface coats. The stability, consistent presence, and intimate association of the mucopolysaccharide coat suggest that it may be an integral part of the plasmalemma rather than an "extraneous coat."