Immunoelectron Microscopic Demonstration of Cortical Granule Lectins in Coelomic, Unfertilized and Fertilized Eggs of Xenopus laevis

Immunoelectron microscopic studies demonstrated cortical granule lectins (CGLs) in coelomic, unfertilized and fertilized eggs of Xenopus laevis . An antiserum raised against purified cortical granule lectin 1 specifically reacted with the CGLs in immunoblotting and agar diffusion tests. When ultrathin sections were treated with the antiserum and protein A-gold solution, gold particles, indicating antigenic sites, were seen over cortical granules of coelomic and unfertilized eggs, and over the perivitelline space, the vitelline coat and the condensed region of the fertilization layer of fertilized eggs. The pre-fertilization layer immediately adjacent to the outer margin of the vitelline coat in unfertilized eggs was free from gold particles. These observations suggest that released CGLs permeate through the vitelline coat of fertilized eggs and interact with the pre-fertilization layer mainly at the outer margin of the vitelline coat, resulting in formation of the fertilization layer which acts as a block to polyspermy.     

Fine Structure of Bacillus megaterium during Microcycle Sporogenesis

Ultrathin sections were prepared from cultures of Bacillus megaterium QM B1551 undergoing microcycle sporogenesis (initial spore to primary cell to second-stage spore without intervening cell division) on a chemically defined medium. The cytoplasmic core of the dormant spore was surrounded by plasma membrane, cell-wall primordium, cortex, outer cortical layer, and spore coats. Early in the cycle, the coat opened at the germinal groove, the cortex swelled, ribosomes and a chromatinic area associated with large mesosomes (which may later be incorporated into the expanding plasma membrane) appeared in the core, and the cell wall became defined at the site of the cell wall primordium. Poly-β-hydroxybutyrate granules began to appear in the primary cell at about 3 hr. By 7 hr, the forespore of the second-stage spore was delineated by typical double membranes. Between 7 and 12 hr, second-stage cell-wall primordium and cortex developed between the separating forespore membranes. The inner membrane became the plasma membrane of the second-stage spore, and the outer membrane eventually disintegrated within the second-stage spore cortex. A densely staining double layer (spore-coat primordium) developed external to the outer forespore membrane. The inner spore coat and the outer cortical layer of the second-stage spore developed from this primordium. The outer part of the spore coat, probably of sporangial origin, was laid down on the external surface of the inner spore coat. By 12 hr, second-stage spores were almost mature. By 20 hr, the mature endospores, with a thickened outer coat, were often still enclosed by degenerate primary cell wall and by the outer cortical layer and spore coat of the initial spore.     

怀头鲇胚胎发育过程卵膜形态结构变化及对孵化影响

采用扫描电镜和光学解剖镜,对黑龙江水域怀头鲇(Silirus soldatovi)成熟卵膜层次构造和受精卵胚胎发育过程中卵膜形态结构变化进行观察,并比较未脱黏和人工脱黏卵受精卵膜的表面超微结构变化.结果显示,受精卵膜的胶膜表面由一层薄而致密的物质组成,上有微孔构造.未脱黏受精卵膜表面胶膜光滑致密,多孔隙,内有小梁相连,随胚胎发育逐渐膨胀、展开、变薄,破膜期自然脱落.人工脱黏几乎全部脱去鱼卵的胶膜层,从而使卵失去黏性.脱去胶膜层的受精卵膜表面由不规则的颗粒状结构紧密嵌合而成,表面粗糙,胚胎发育过程中颗粒形状变化不大,但颗粒层逐渐变薄而且疏松,直至胚胎破膜而出:胚胎发育后期颗粒层有过早脱落和破洞出现.同时对活体鱼卵进行连续比较观察,讨论了卵膜结构及动态变化与孵化效果的关系.     

Exosporium and Spore Coat Formation in Bacillus cereus T

The exosporium of Bacillus cereus T was first observed as a small lamella in the cytoplasm in proximity to the outer forespore membrane (OFSM) near the middle of the sporangium. Serial sections, various staining methods, and enzyme treatments failed to show any connections between the small lamella and the OFSM. The advancing edge of the exosporium moved toward the polar end of the cell until the spore was completely enveloped. The middle coat was formed between the exosporium and the OFSM from a three-layered single plate or "belt," consisting of two electron-dense layers separated by an electron-transparent layer. This "belt," usually first observed toward the center of the sporangium, developed without changing thickness or appearance over the surface of the forespore. Between the middle coat and the OFSM, a layer of cytoplasm about 50-nm thick was enclosed by the developing coat; this became the inner coat. Electron-dense material was deposited on the outer surface of the middle coat to form the outer coat.     

Properties of the Cortical Granule Lectin Isolated from Xenopus Eggs

The cortical granule lectin that participates in forming the fertilization layer in Xenopus laevis was isolated and partially characterized. About 400 μg of lectin was purified from 5 mg of crude exudate by chromatography on Sepharose 6B and Concanavalin A-conjugated Sepharose 4B columns and electrophoretic separation on polyacrylamide gel. The lectin has a molecular weight of 550 Kd and is composed of two species of polypeptides (46 Kd and 42 Kd). The lectin gave a single precipitin line against material in the prefertilization layer in an agglutination reaction on an agarose plate. The agglutination reaction involved D-galactoside residues and metal ions. The lectin formed an electron-dense layer on the outer surface of the vitelline coat of oviducal eggs covered with the prefertilization layer, but on the outer surface of jelly layer, not on that of the vitelline coat of jellied eggs. Although the jelly could be agglutinated by the lectin, the possibility that the jelly layer is the site of fertilization layer formation was excluded by the fact that the prefertilization layer is the first to meet the cortical granule lectin during normal fertilization.     

FORMATION AND STRUCTURE OF THE SPORE OF BACILLUS COAGULANS

Spore formation in Bacillus coagulans has been studied by electron microscopy using an epoxy resin (Araldite) embedding technique. The developmental stages from the origin of the initial spore septum to the mature spore were investigated. The two forespore membranes developed from the double layer of cytoplasmic membrane. The cortex was progressively deposited between these two membranes. The inner membrane finally became the spore protoplasmic membrane, and the outer membrane part of the inner spore coat or the outer spore coat itself. In the mature spore the completed integuments around the spore protoplasm consisted of the cortex, a laminated inner coat, and a dense outer coat. No exosporium was observed. The method of formation of the cortex and the spore coats is discussed.     

Light and Electron Microscopic Studies on Fertilization of Pelmatohydra Robusta I. Sperm Entry to a Specialized Region of the Egg

Fertilization of a fresh water polyp, Pelmatohydra robusta , was studied by light and electron microscopy. A small depression was observed in the animal pole of the unfertilized egg. The egg pronucleus was always situated in close contact with the bottom of the depression. Microvilli which were covered with an egg coat consisting of filamentous components were observed on the egg surface. Microvilli and the egg coat were not detected on the surface of the depression. Sperm were associated with the egg plasma membrane and entered the egg only at the bottom of the depression. Excess sperm aggregated around the depression of inseminated eggs. After fertilization, the egg made a protrusion in the region where the egg pronucleus and sperm were in close contact with each other. A new egg coat was formed on the entire surface of the fertilized egg. The restriction of sperm-egg interactions to a specialized region of the hydra egg is discussed in connection with the micropyle of Pisces eggs and the animal dimple of Discoglossus (Anura) eggs.     

An electron microscopic investigation of the surface coat of the electrocyte of Electrophorus electricus

Summary The surface coat of the electrocyte of the main electric organ of Electrophorus electricus was studied using cytochemical methods (periodic acid-silver methenamine, periodic acid-chromic acid-silver methenamine, periodic acid-thiosemicarbazide-silver proteinate, Concanavalin A — horseradish peroxidase, ruthenium red, Alcian-blue lanthanum nitrate, colloidal iron hydroxide and cationized ferritin). The surface of the electrocyte presents perpendicularly oriented tubular invaginations of the cell membrane. The fibrous coat 50–100 nm thick, penetrates into the lumen of the invaginations. It is also observed in the synaptic clefts existent in the posterior face of the electrocyte. The coating of the surface membrane gives a positive reaction with all techniques used. Binding of colloidal iron hydroxide particles was observed only in the outer layer of the coat. With the Alcian-blue lanthanum nitrate technique, microtubules were observed in the cytoplasm of the electrocyte.The results indicate that the surface coat of the electrocyte contains mucopolysaccharides, glycoproteins, acid mucopolysaccharides and anionic sites detected at low (colloidal iron hydroxyde) and neutral (cationized ferritin) pH.This work has been supported by Conselho Nacional de Desenvolvimento Cientifico e Tecnológico (CNPq), Conselho de Ensino e Pesquisa da UFRJ (CEPG) and Banco Nacional de Desenvolvimento Econômico     

Acrosome reaction in sperm of the toad,bufo bufo japonicus

The acrosome in the sperm of the toad, Bufo bufo japonicus, consists of a membrane-limited acrosomal cap and a fibrous perforatorium. When sperm are incubated with the oviducal pars recta extract (PRE) for 30–60 min, the outer acrosomal membrane fuses with the overlying plasma membrane at several points with concomitant loss of the contents of the acrosomal cap. The inner acrosomal membrane thus exposed fuses with the plasma membrane at the caudal end of the acrosomal region. This PRE-induced acrosome reaction is completely inhibited by soybean trypsin inhibitor. Sperm found in the innermost jelly layer of inseminated eggs possess an intact acrosome, but those either passing through the vitelline coat or localizing in the perivitelline space are acrosome-reacted in the same manner as when treated with PRE. These observations, combined with recent evidence showing involvement of the pars recta substance in fertilization, indicate that the acrosome reaction occurring in a fertilizing sperm at or near the surface of the vitelline coat is a response to a substance that is derived from the pars recta and deposited in the vitelline coat.     

Eggshell formation during prolonged gravidity of the tuatara Sphenodon punctatus

Scanning electron microscopy (SEM) was used to examine the process of shell formation in tuatara. Tuatara carry eggs in the oviducts for ∼ 7–8 mo before nesting, a period of gravidity more than three times as long as in any other oviparous reptile. Our aim was to determine whether shell formation occurred rapidly after ovulation, or whether it occurred gradually throughout gravidity. Eggs were obtained from females in early gravidity (May, ∼ 1 mo after ovulation), midgravidity (August and September, 4–5 mo after ovulation), and late gravidity, immediately prior to nesting (December, 8 mo after ovulation). The shell membrane (fibrous layer) was well formed by May, but calcification of the outer surface had only just begun. Vertical columns of calcium carbonate were embedded in the shell membrane and appeared to erupt through the outer surface between early and midgravidity. Changes in the appearance of the outer calcareous layer were evident as gravidity progressed. In all shells, calcium carbonate was present as calcite. The appearance of the inner boundary (innermost layer of eggshell) was variable; some shells had a smooth and amorphous inner boundary as previously reported for tuatara and other reptiles, whereas other shells had an inner boundary composed of small spherical granules on the inner surface of which small calcareous spicules were scattered. A previously published model of the process of shell formation in tuatara eggshells is refined in light of our observations. We interpret the ability of female tuatara to shell their eggs gradually during winter as further evidence of their unusual physiological tolerance of cold conditions. © 1996 Wiley-Liss, Inc.     

Changes of ultrastructure in spore coat of Bacillus thiaminolyticus during germination and outgrowth.

Electron microscopic observation showed that the spore coat of Bacillus thiaminolyticus consisted of at least four layers; a high electron dense outer spore coat layer with five prominent ridges, a middle spore coat layer including two layers of a high and a low electron density, and an inner spore coat layer composing six to seven laminated layers. Rapid breakdown of the cortex and swelling of the core occurred in spores which were allowed to germinate by L-alanine for 45 min, whereas no change of surface feature was observed by scanning electron microscopy. Germination and outgrowth of spores in nutrient broth proceeded, being accompanied by morphological changes, in three steps; the first is a rapid breakdown of the cortex and swelling of the core, the second degradation of the inner layer at prominent region of the spore coat, and the last rupture of the spore coat and emergence of a young vegetative cell.     

Aspects of shell formation in eggs of the tuatara,Sphenodon punctatus

The flexible shell from eggs of the tuatara (Sphenodon punctatus) is comprised of both calcareous and fibrous components. The calcareous material is organized into columns that extend deep into the fibrous shell membrane. Many of the fibers of the membrane are enclosed within the crystalline matrix of the columns. Columns widen and flatten slightly at the outer surface of the eggshell to form cap-like structures composed of a compact crystalline matrix containing no fibers. The outer surface of eggs laid prior to completion of shell formation consists of a series of nodes obscured by a densely fibrous matrix. Similar nodes also are found at the inner surface of partially shelled eggs. The nodes represent the outer and inner aspects of columns that had not completed formation prior to oviposition. Our interpretation is that a layer (or layers) of the shell membrane forms first, with nucleation of columns occurring shortly thereafter. Columns grow into the membrane a short distance and enclose fibers of the membrane, but the primary direction of column growth is toward what will become the outer aspect of the shell. Calcareous columns and the shell membrane form more or less in concert until crystal growth outstrips that of the membrane and a cap-like apex of compact crystalline material is formed. The end result is an eggshell in which the shell membrane and calcareous material form a single unit for much of the thickness of the shell.     

Ultrastructure of the Cell Envelope of Escherichia coli B After Freeze-Etching

The cell envelope of Escherichia coli B was investigated with the freeze-etching technique. A considerable gain in visible structural detail over more conventional electron microscopic techniques was obtained. The inner surface of the plasma membrane revealed a smooth surface sparsely studded with particles measuring from 5 to 10 nm in diameter, whereas the outer surface of the plasma membrane showed many more particles of corresponding diameter. The freeze-etched cell wall appeared to be a multilayered structure. The innermost layer could be observed as a profile studded with closely packed elements of about 10 nm in diameter. External to this layer was a smooth surface bordering the outermost cell wall layer. When frozen in the absence of glycerol the outermost surface observed in the cell wall was smooth, but when grown in the presence of glycerol it had a "wavy" appearance with small particles attached to it. The observations support current concepts on the ultrastructure of the enterobacterial cell envelope.     

Structure of shells from eggs of kinosternid turtles

Shells from eggs of five species of kinosternid turtle (Sternotherus minor, Kinosternon flavescens, K. baurii, K. Hirtipes, and K. alamosae) were examined with light and scanning electron microscopy. Except for possible differences among species in thickness of eggshells, structure of shells from all eggs was similiar. In general, kinosternid turtles lay eggs having a rigid calcareous layer composed of calcium carbonate in the form of aragonite. The calcareous layer is organized into individual shell units with needlelike crystallites radiating from a common center. Most of the thickness of the eggshell is attributable to the calcareous layer, with the fibrous shell membrane comprising only a small fraction of shell thickness. Pores are found in the calcareous layer, but they are not numereous. The outer surface of the eggshells is sculptured and may have a thick, organic layer in places. The outer surface of the shell membrane of decalcified eggshells is studded with spherical cores which presumably nucleate growth of shell units during shell formation. The shell membrane detaches from eggs incubated to hatching, carrying with it remnants of the calcareous layer. Such changes in shell structure presumably reflect withdrawal of calcium from the eggshell by developing embryos.     

The magnum-isthmus junction of the fowl oviduct participates in the formation of the avian-type shell membrane

Avian eggs possess a shell membrane in the shape of an asymmetrical ellipsoid and with a limiting membrane that is a smooth layer of homogeneous, dense materials. We describe the role of the magnum-isthmus junction (MIJ) of the oviduct in the formation of the avian-type shell membrane in the domestic fowl Gallus domesticus. The narrow width of the lumen at the MIJ indirectly participates in the determination of the asymmetrical ellipsoid shape of eggs that are encased by the egg-white layer and subsequently by the peri-albumen layer (PL) and the shell membrane. The PL reacts with Alcian blue and exists between the egg white and the limiting membrane. It is added to the ovulating egg at the MIJ and covers the outermost surface of the egg-white layer. The function of the PL is to provide a smooth surface by covering the irregular surface of the egg-white layer. The materials of the PL consist of an Alcian blue-positive polysaccharide (or glycoprotein) of 240 kDa and five proteins of 135, 116, 72, 49, and 46 kDa. The isolated materials have an affinity to bind with the egg-white mass. An antiserum against quail PL materials stains the domestic fowl PL and secretory cells of the luminal epithelium at the MIJ, and cross-reacts with the molecules of 240, 135, and 116 kDa.     

Ultrastructure of cell surface coat (glycocalyx) in rat urinary bladder epithelium

Earlier statements to the contrary, the present study demonstrates the presence of a cell surface coat (glycocalyx) on the luminal plasma membrane of the superficial transitional epithelial cells lining the urinary bladder of male Buffalo rats. This coat was demonstrated with ruthenium red, an electron dense stain, which revealed a surface layer, 60-80 A thick, separated from the outer leaflet of the plasma membrane by an electron lucent layer, approximately 30 A thick. The structure of the glycocalyx was not affected by 12 weeks of treatment with dibutylnitrosamine, a known bladder carcinogen.     

The Cell Surface of Trypanosoma musculi Bloodstream Forms. I. Fine Structure and Cytochemistry*†

SYNOPSIS. An extracellular surface coat was observed at the fine-structural level on the outer lamina of the pellicular and flagellar membranes of intact Trypanosoma musculi bloodstream forms. The surface coat had a mean width of 9.2 nm, and was composed of a somewhat electron dense, uneven, fibrillar-like matrix. Brief trypsin treatment of living blood forms completely removed the cell surface coat. Several cytochemical methods applicable to electron microscopy were used to detect the presence and distribution of carbohydrates in the trypanosome's surface coat and pellicular membrane. The polycationic dye compounds employed were: ruthenium red, ruthenium violet, Alcian blue chloride, and lanthanum nitrate. Electron-dense stain reaction products, indicative of polysaccharides, were evident in the surface coat of cells treated with these dyes, which also agglutinated both living and glutaraldehyde fixed cells. Like the surface coat, the pellicular membrane of trypsinized cells gave strong positive staining reactions with the several dyes, indicating the presence of membrane bounded carbohydrates, and living and glutaraldehyde-fixed trypsinized cells were agglutinated with the polycationic stains. Bloodstream forms were treated with the enzymes, α-amylase, dextranase, and neuraminidase. No obvious morphologic difference, however, was apparent between the surface coat of untreated cells and those subjected to treatment with any of the various glycoside hydrolase enzymes. Further, these enzymes had no apparent gross effect on the staining affinity of the surface coat for the several polycationic dyes. Cationized ferritin was used to visualize the negative cell surface charge of T. musculi bloodstream forms. Large quantities of cationized ferritin were bound in the surface coat matrix. Glycoside hydrolase enzyme treatments had no apparent effect on the amount of ferritin bound in the surface coat. Cationized ferritin was bound also to the outer lamina of the pellicular membrane in trypsinized cells, which had quantitatively less ferritin bound per surface unit area than bloodstream forms untreated by the enzyme. Living and glutaraldehyde-fixed cells were agglutinated with cationized ferritin. The results obtained in the various experiments indicated that polyanionic polysaccharides were constituent terminal ligands of the surface coat matrix and pellicular membrane in T. musculi bloodstream forms.     

Changes of Ultrastructure in Spore Coat of Bacillus thiaminolyticus during Germination and Outgrowth

Electron microscopic observation showed that the spore coat of Bacillus thiaminolyticus consisted of at least four layers; a high electron dense outer spore coat layer with five prominent ridges, a middle spore coat layer including two layers of a high and a low electron density, and an inner spore coat layer composing six to seven laminated layers. Rapid breakdown of the cortex and swelling of the core occurred in spores which were allowed to germinate by L -alanine for 45 min, whereas no change of surface feature was observed by scanning electron microscopy. Germination and outgrowth of spores in nutrient broth proceeded, being accompanied by morphological changes, in three steps; the first is a rapid breakdown of the cortex and swelling of the core, the second degradation of the inner layer at a prominent region of the spore coat, and the last rupture of the spore coat and emergence of a young vegetative cell.     

Structural features of the abalone egg extracellular matrix and its role in gamete interaction during fertilization

Abalone eggs are surrounded by a complex extracellular coat that contains three distinct elements: the jelly layer, the vitelline envelope, and the egg surface coat. In this study we used light and electron microscopy to describe these three elements in the red abalone (Haliotis rufescens) and ascribe function to each based on their interactions with sperm. The jelly coat is a spongy matrix that lies at the outermost margin of the egg and consists of variably sized fibers. Sperm pass through this layer with their acrosomes intact and then go on to bind to the vitelline envelope. The vitelline envelope is a multilamellar fibrous layer that appears to trigger the acrosome reaction after sperm binding. Next, sperm release lysin from their acrosomal granules, a nonenzymatic protein that dissolves a hole in the vitelline envelope through which the sperm swims. Sperm then contact the egg surface coat, a network of uniformly sized filaments lying directly above the egg plasma membrane. This layer mediates attachment of sperm, via their acrosomal process, to the egg surface. © 1995 Wiley-Liss, Inc.     

Changes in the topography of the sea urchin egg after fertilization

Changes in the topography of the sea urchin egg after fertilization were studied by scanning and transmission electron microscopy. Strongylocentrotus purpuratus eggs were treated with dithiothreitol to modify the vitelline layer and to prevent formation of a fertilization membrane. Dithiothreitol treatment caused the microvilli to become more irregular in shape, length, and diameter than those of untreated eggs. The microvilli were similarly modified by trypsin treatment. This effect did not appear to be due to disruption of cytoskeletal elements beneath the plasma membrane, for neither colchicine nor cytochalasin B altered microvillar morphology. Thus, it appears that the vitelline layer may act in the maintenance of surface form of unfertilized eggs. Since dithiothreitol-treated eggs did not elevate a fertilization membrane, scanning electron microscopy could be used to directly observe modifications in the egg plasma membrane after fertilization. The wave of cortical granule exocytosis initiated at the point of attachment of the fertilizing sperm was characterized by the appearance of pits that subsequently opened, releasing the cortical granule contents and leaving depressions upon the egg surface. The perigranular membranes inserted during exocytosis were seen as smooth patches between the microvillous patches remaining from the original egg surface. This produced a mosaic surface with more than double the amount of membrane of unfertilized eggs. The mosaic surface subsequently reorganized to accommodate the inserted membrane material by elongation of microvilli. Blebs and membranous whorls present before reorganization suggested the existence of an unstable intermediate state of plasma membrane reorganization. Exocytosis and mosaic membrane formation were not blocked by colchicine or cytochalasin B, but microvillar elongation was blocked by cytochalasin B treatment.