Electron Microscopic Observations on the Cortical Reaction of the Brittle-Star Amphipholis kochii Lütken, with Special Reference to its Vitelline Coat Modification as Revealed by the Surface Replica Method

This paper describes the fine structural changes of the egg of the brittle-star Amphipholis kochii Lütken during the cortical reaction. The vitelline coat is 20 nm thick, when Ruthenium Red stain is used, and consists of a dense network of fibers. The cortical granules are large, 1.5–2.0 μm in diameter, and exist in several layers in the egg cortex, unlike the monolayer arrangement found in many other animals. The contents of the cortical granules are clearly distinguished into two components: peripheral fibrous (PF) material and central fibrous (CF) material that consists of two components differing in electron density. The PF material is densely stained by periodic acid-chromic acid-silver methenamine stain, while the CF material is stained little if at all by this technique. The vitelline coat and some PF materials form the fertilization membrane, which is about 40 nm thick and consists of three layers; the outer and the inner layer of the fertilization membrane each have a trilaminated structure. The vitelline coat substances are probably located in the upper part of the fertilization membrane. The hyaline layer, 7–8 μm thick, consists mainly of CF materials. These observations on the morphology of the ophiuroid egg are discussed in comparison with those on other echinoderms, especially echinoids and asteroids.     

Ultrastructural aspects of the surface coatings of eggs and larvae of the starfish,Pisaster ochraceus,revealed by alcian blue

Eggs of the asteroid Pisaster ochraceus demonstrate cortical granules, a thick vitelline membrane, and a poorly stained jelly coat similar to that seen on the eggs of other echinoderms. When fixed in the presence of alcian blue the jelly coat is seen to be made up of three regions, an inner layer consisting of a meshwork of fibres, a middle layer of thicker fibres, and a dense outer layer. At fertilization the cortical granules release their contents into the potential space between the vitelline layers and a low fertilization membrane consisting of the vitelline layer and a dense component of the corticle granule is formed. Initially the remaining contents of the corticle granules form an amorphous hyaline layer that fills the space between the plasma membrane and the fertilization membrane. At hatching a distinct hyaline layer is present. It persists at least to the bipinnaria stage and consists of four distinct layers. A similar layer is also located over much of the early embryonic endoderm but is lost from the regions involved in the formation of the mesenchyme cells, coelom, and mouth just before these events take place. Numerous large clear vesicles are located in the apex of all cells associated with a hyaline layer. Where the hyaline layer is lacking, only scattered vesicles are present suggesting that the vesicles may be involved in maintenance of the layer. Attempts to identify elements of the hyaline layer by immunofluorescence demonstrated that it appears to bind both antisera and control sera in a nonspecific manner.     

Formation and structure of the fertilization envelope in Xenopus laevis

This paper reports the morphological events that occur when the vitelline envelope (VE) of an unfertilized egg of Xenopus laevis is transformed into the fertilization envelope (FE) surrounding the zygote. The VE is about 1 μm thick and is composed of an interlacing network of small filaments. The FE is constructed from the VE plus an electron-dense layer (fertilization layer), about 2–6 μm thick, on the outer surface of the VE, i.e., at the interface between the VE and the innermost jelly-coat layer. The fertilization layer is a stable component of the FE and is not removed by mercaptan solutions used to dejelly eggs. The events of FE formation were observed in the light and electron microscopes after dejellied eggs were activated by pricking. The FE is established when material from the cortical granules is extruded into the perivitelline space. The cortical granule material passes through the VE as the envelope lifts away from the egg surface. Some cortical granule material deposits in the interstices of the VE, but most of it forms the fertilization layer on the outer surface of the envelope. The cortical reaction is completed about 8–9 min after addition of sperm when eggs are fertilized in vitro.     

Immunocytochemical localization of the 35-kDa sea urchin egg trypsin-like protease and its effects upon the egg surface

Trypsin-like protease in sea urchin eggs is thought to reside in cortical granules since it is secreted at fertilization and has been isolated with cortical granule fractions from unfertilized eggs. A 35-kDa serine protease has been purified from Strongylocentrotus purpuratus eggs by soybean trypsin inhibitor-affinity chromatography. For this report the protease was localized by immunocytochemistry before and after fertilization, and its potential biological activity was examined by application of the isolated enzyme to the unfertilized egg surface. The protease was localized on sections by immunofluorescence and immunoelectron microscopy, and was found to reside in the spiral lamellae of S. purpuratus cortical granules and in the electron-dense stellate core of Arbacia punctulata granules. At fertilization the enzyme is secreted into the perivitelline space and accumulates only very briefly between the hyaline layer and the nascent fertilization envelope. Shortly thereafter the enzyme is lost from the perivitelline space and immunological reactivity is no longer associated with the egg surface. The 35-kDa cortical granule protease has vitelline delaminase activity but does not appear to destroy vitelline envelope sperm receptors as judged by the fertility of protease-treated eggs.     

Electron Microscopic Study of Development in a Sea Cucumber,Stichopus tremulus (Holothuroidea), from Unfertilized Egg through Hatched Blastula

In this, the first fine structural study of sea cucumber embryology, eggs and embryos of Stichopus tremulus developing at 7.5°C are described from spawning through hatched blastulae. Spawned eggs are at about first meiotic metaphase and are surrounded by a jelly layer that remains around the embryos until hatching. No vitelline coat can be demonstrated, but whether it is truly absent or removed by electron microscopic processing is not known. Insemination initiates a rapid cortical reaction, completed within 2 min., which involves a wave of cortical granule exocytosis and fertilization envelope formation. The compactly fibrous fertilization envelope is about 50 nm thick and appears to consist entirely of ejected cortical granule material (if one assumes that there is no vitelline coat). As the fertilization envelope elevates, no hyaline layer appears in the perivitelline space. The first and second polar bodies are emitted, respectively, at about 9 and 15 min. after insemination. The first seven or so cleavages are equal, radial, and occur approximately every 4 hr. The blastocoel opens up at the four-cell stage and, during the earlier cleavages, remains connected with the perivitelline space via numerous gaps between the roughly spherical blastomeres. At the 64-cell stage, these gaps begin to close as the blastomeres start to become cuboidal; in addition, an embryonic cuticle is produced on the apical surface of each blastomere. In embryos of several hundred cells, the blastomeres become associated apicolaterally by junctional complexes, each consisting of a zonula adherens and a septate junction. Several hours before hatching, a single cilium is produced at the apical surface of most blastomeres. At hatching (about 50 hr after insemination), the ciliated blastula leaves behind the fertilization envelope and jelly layer. Swimming blastulae soon begin to elongate in the animal-vegetal axis, and a basal lamina develops on blastomere surfaces facing the blastocoel. The discussion includes a fine structural comparison of egg coats among the five classes of the phylum Echinodermata.     

Localization of cortical granule lectin ligand in Xenopus laevis egg jelly

The block to polyspermy in Xenopus laevis involves an interaction between a cortical granule lectin, released at fertilization, and a ligand located in the egg extracellular matrix. The egg extracellular matrix in X. laevis consists of a vitelline envelope and three distinct jelly layers, designated J1, J2 and J3. To localize cortical granule lectin ligand in the egg extracellular matrix, we used enzyme-linked lectin assays that showed that cortical granule lectin ligands were absent in J2, J3 and the vitelline envelope. Cortical granule lectin bound to a ligand(s) in J1 in a galactose-dependent fashion. In addition, we separated egg jelly macromolecules electrophoretically and, in conjunction with western blotting, have shown that J1 contains two major, high molecular weight ligands for cortical granule ligand. Finally, using confocal microscopy, we demonstrated that the ligand(s) for cortical granule lectin occupies a 20–30 μm thick band in a region of J1 just proximal to the vitelline envelope.     

Extracellular coats on the surface of Strongylocentrotus purpuratus eggs: stereo electron microscopy of quick-frozen and deep-etched specimens

Summary Sea urchin (Strongylocentrotus purpuratus) eggs were fixed, quick-frozen, deep-etched, and rotary-replicated, and the three-dimensional structure of the external surface of the egg visualized using stereo electron microscopy. The cell surface is coated with three layers of filaments: the sheetlike vitelline layer adhering closely to the plasma membrane, a second layer of oblique fibrils extending from microvillar tips to the vitelline layer below, and a third, outermost layer of horizontal filaments coursing in bundles over the microvillar tips. After fertilization, the newly elevated vitelline envelope is transformed into a three-layered structure, the central layer being a tightly knit network of fine filaments decorated on each side with a loose network of thicker fibrils. Subsequently, the envelope becomes coated with paracrystalline protein released from the cortical granules, and microvillar casts are reshaped into angular, jagged peaks having two to five sides. The final structure of the fertilization envelope consists of a thick central layer of compact fibrillar material that is coated on each side with thin plates of paracrystalline protein.     

An ultrastructural immunocytochemical localization of hyalin in the sea urchin egg

The fertilized sea urchin egg is invested by the hyaline layer, a thick extracellular coat which is necessary for normal development. On the basis of ultrastructural studies and the fact that hyalin is released during the time of the cortical reaction, it has been generally accepted that hyalin is derived from the cortical granules. However, this has never been proven definitely, and recently, it has been reported that hyalin is a membrane and/or cell surface protein. To determine where hyalin is stored, we carried out an ultrastructural immunocytochemical localization of hyalin in the unfertilized egg. Hyalin purified from isolated hyaline layers was used to immunize rabbits. Antisera so obtained were shown to be hyalin specific following absorption with a combination of sea urchin proteins. Immunocytochemical localizations were carried out on sections of Epon-embedded material using protein A-coated gold particles as an antibody marker. Our results demonstrate that, prior to fertilization, hyalin is stored in the homogeneous component of the cortical granule in Strongylocentrotus droebachiensis and Strongylocentrotus purpuratus. Labeling of small cortical vesicles in both unfertilized and fertilized eggs, suggests that these vesicles may contain a secondary reservoir of hyalin.     

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.     

Mastoparan induces Ca2+-independent cortical granule exocytosis in sea urchin eggs

In most species, cortical granule exocytosis is characteristic of egg activation by sperm. It is a Ca(2+)-mediated event which results in elevation of the vitelline coat to block permanently the polyspermy at fertilization. We examined the effect of mastoparan, an activator of G-proteins, on the sea urchin egg activation. Mastoparan was able to induce, in a concentration-dependent manner, the egg cortical granule exocytosis; mastoparan-17, an inactive analogue of mastoparan, had no effect. Mastoparan, but not sperm, induced cortical granule exocytosis in eggs preloaded with BAPTA, a Ca(2+) chelator. In isolated egg cortical lawns, which are vitelline layers and membrane fragments with endogenously docked cortical granules, mastoparan induced cortical granule fusion in a Ca(2+)-independent manner. By contrast, mastoparan-17 did not trigger fusion. We conclude that in sea urchin eggs mastoparan stimulates exocytosis at a Ca(2+)-independent late site of the signaling pathway that culminates in cortical granule discharge.     

On the contents of the cortical granules from Xenopus laevis eggs

The extruded contents of the cortical granules in eggs of Xenopus laevis were solubilized by exposure to divalent metal ion chelators. Chelator extraction of cortical granule (CG) material from intact fertilized or artificially activated eggs was quantitated by fluorescence spectroscopy. The isolated fertilization envelope, formed upon interaction between CG material and the preexisting vitelline envelope, was also subject to extraction. An ultrastructural analysis revealed that chelator exposure resulted in the disruption of the structural integrity of the CG-derived F-component of the fertilization envelope. CG material was isolated from Xenopus ova by three procedures: (1) extrusion from artificially activated, dejellied eggs; (2) extraction of intact, fertilized eggs; and (3) extraction of isolated fertilization envelopes. Only 4–5% of the CG protein recovered by extrusion or by extraction of the intact fertilized egg could be associated with the isolated fertilization envelopes. One predominant polypeptide fraction with an identical relative mobility was demonstrated in all CG preparations upon polyacrylamide gel electrophoresis in SDS. Polymeric forms of CG protein were detected in chelator extracted preparations. The presence of an intact jelly coat during CG breakdown was a prerequisite to the transformation of the vitelline envelope to a fertilization envelope with altered physicochemical characteristics. Further, the CG-derived F-component of the fertilization envelope did not appear to play a critical role in determining the physicochemical properties of the fertilization envelope.     

Concanavalin A inhibits the dispersion of the cortical granule contents of sand dollar eggs

Dendraster excentricus eggs fertilized in ConA (10 μg/ml) elevate vitelline layers and expel cortical granule contents into the perivitelline space. The granule material does not disperse but remains composed as discrete spheres. The elevated vitelline layer remains thin and weak. It is not a true fertilization membrane because it lacks the structural material supplied by the granules.     

THE ISOLATION OF A MAJOR STRUCTURAL ELEMENT OF THE SEA URCHIN FERTILIZATION MEMBRANE

Procedures for isolating the contents of the cortical granules from the ova of the sea urchin, Strongylocentrotus purpuratus, are reported. Dithiothreitol is used to remove the vitelline coat; the "demembranated" eggs are then subsequently activated with butyric acid. By means of these procedures, the hyaline protein and crystalline or paracrystalline material have been isolated from the cortical granules. The crystalline material consists of sheets of cylinders or tubules 150–200 A in diameter. This material is believed to be a major structural element of the fertilization membrane which, in the absence of the vitelline coat, does not form.     

Oogenesis and egg-shell formation in Aspiculuris tetraptera Schulz (Nematoda: Oxyuroidea).

The ovary of Aspiculuris tetraptera has a prominent terminal cap cell. This is considered to be part of the ovarian epithelium. Oogonia detach from the short rachis and increase in size from 6 to 60 microns; accumulating hyaline granules, shell granules and glycogen. The hyaline granules persist in the eff cytoplasm after shell formation has been completed and are considered to be lipoprotein yolk. The shell granules contribute to the non-chitin fraction of the chitinous layer. A classification of the cytoplasmic inclusions of the nematode oocyte is proposed. Upon fertilization a vitelline membrane is formed which constitutes the vitelline layer of the egg-shell. The chitinous layer is secreted in the perivitelline space, between the vitelline layer and the egg oolemma. Upon completion of chitinous layer synthesis, the egg cytoplasm contracts away from its inner surface. The material of the lipid layer is secreted at the surface of the egg cytoplasm and adheres to the inner surface of the chitinous layer. During secretion of the chitinous and lipid layers by the egg cytoplasm, the uterine cells secrete the unit membrane-like external uterine layer and the crystalline internal uterine layer. A complex system of interconnecting spaces develops in the internal uterine layer. This system is open to the exterior via breaks in the external uterine layer. There is no direct involvement of the uterine cells in the formation of this structure.     

ELECTRON MICROSCOPIC DEMONSTRATION OF A DITHIOTHREITOL-LABILE VITELLINE COAT SURROUNDING THE UNFERTILIZED EGG OF COMANTHUS JAPONICA (ECHINODERMATA: CRINOIDEA)*

In Comanthus, the unfertilized egg is surrounded by a vitelline coat, which is separated from the underlying plasma membrane by a space several hundred Ångstroms wide. By electron microscopy, the vitelline coat is a distinct layer 100 to 150 Å thick, which consists of finely granular material of moderate electron density. Treatment for 3 min in 0.01 M dithiothreitol in sea water buffered to pH 9.2 almost completely removes the vitelline coat and causes the irregularly shaped egg to become spherical. After such DTT-treated eggs have been washed for 2 min in sea water, they cannot be fertilized, but they can undergo a cortical reaction when treated with ionophore A23187. This cortical reaction consists of the exocytosis of cortical granule material directly into the surrounding sea water. By several hours after DTT treatment, most of the eggs, whether exposed to ionophore or not, fragment into spheres of diverse sizes.     

Sea urchin embryo fertilization envelope: immunological evidence that soluble envelope proteins are derived from cortical granule secretions

Although structural studies support the hypothesis that the sea urchin embryo fertilization envelope is derived from the preexisting vitelline envelope template and structural proteins secreted during the cortical reaction, biochemical evidence is minimal. We used an immunological approach to determine the subcellular origin of proteins which were extracted from the fertilization envelope. Fertilization envelopes were isolated from Stronglyocentrotus purpuratus embryos 30 min postinsemination and extracted with 6.0 M urea-0.15 M 2-mercaptoethanol, pH 10.5, for 10 min at 80°C. Extracted proteins were exhaustively dialyzed against 0.015 M 2-mercaptoethanol-0.100 M Tris-HCl at pH 8.6 and mixed with Fruend's complete adjuvant prior to injection into female New Zealand white rabbits. The antiserum which was prepared contained antibodies to six major and two minor polypeptides in the soluble fertilization envelope fraction based on two-dimensional sodium dodecyl sulfate immunoelectrophoresis. Extracts of vitelline envelopes and extracts of unfertilized egg surfaces which are known to contain viteline envelope proteins did not form immunoprecipitates with antiserum against soluble fertilization envelope polypeptides. Extracts of isolated cortical granules and the secreted paracystalline protein fraction formed four and three immunoprecipitates, respectively, which showed complete identity with the soluble fertilization envelope polypeptides based on rocket-line immunoelectrophoresis. Two-dimensional sodium dodecyl sulfate immunoelectrophoresis of cortical granule extract and the secreted paracrystalline protein fraction showed a complex pattern of immunoprecipitates, but a major finding was that cortical granules contain a 193,000-dalton polypeptide which was not found in the paracrystalline protein fraction. These results suggest that proteolytic processing of a cortical granule precursor of the paracrystalline protein fraction occurs during fertilization and that not all of the cortical granule polypeptides are incorporated into the fertilization envelope by means of di- and trityrosine crosslinks with the vitelline envelope proteins.     

FORMATION OF THE CORTICAL CONCAVITY AT FERTILIZATION IN THE SEA URCHIN EGG

During the initial stages of fertilization envelope elevation in eggs of Strongylocentrotus pur puratus and S. droebachiensis a large concavity of the egg cortex was observed in the light microscope. This concavity corresponded in shape and size with the elevating fertilization envelope. However, after the vitelline layers of eggs were disrupted and the eggs inseminated, the concavity failed to develop although the eggs were fertilized and developed normally. We propose that the concavity is formed owing to increased hydrostatic pressure within the perivitelline space. To further support this hypothesis we measured total egg protein secreted during fertilization, and found that 98% was retained within the perivitelline space. Furthermore, 80% of the total protein was contributed by the hyaline layer. Presumably, colloidal osmotic pressure and/or hydration of fertilization product, trapped beneath the fertilization envelope, is responsible for increased hydrostatic pressure within the perivitelline space, and therefore promotes not only fertilization envelope elevation, but the cortical concavity as well.     

Relationship between p62 and p56, two proteins of the mammalian cortical granule envelope, and hyalin, the major component of the echinoderm hyaline layer, in hamsters

Mammalian cortical granules contain two polypeptides (p62 and p56) that are incorporated into the cortical granule envelope after fertilization and function in cleavage of the zygote and the preimplantation blastomeres. Since the echinoderm hyaline layer and mammalian cortical granule envelope are analogous, and since the hyaline layer protein, hyalin, functions in early echinoderm embryogenesis, this study was done to determine whether p62 and p56 and/or other components of the mammalian cortical granule envelope are related to hyalin. A polyclonal antibody (IL2) against purified S. purpuratus hyalin was shown by confocal scanning laser microscopy to bind to hamster cortical granules and to the cortical granule envelope of fertilized hamster oocytes and preimplantation embryos up to the blastocyst stage. In immunoblots, IL2 bound only to 62- and 56-kDa cortical granule proteins that were incorporated into the cortical granule envelope after fertilization. IL2 binding antigens appeared to be resynthesized by preimplantation embryos starting at the 2-cell stage of development. In vivo treatment of 2-cell-stage hamster embryos with IL2 inhibited blastomere cleavage, but treatment of morulae did not inhibit blastocyst implantation. These results support the idea that the mammalian cortical granule envelope proteins, p62/p56, share a common antigenic epitope(s) with echinoderm hyalin, and that p62/p56, like hyalin, play a role in early embryogenesis.     

Evidence for the existence of two assembly domains within the sea urchin fertilization envelope.

The sea urchin fertilization envelope (FE) is a complex, macromolecular aggregate assembled by the addition of cortical granule secretions to the vitelline layer. The completed, trilaminar structure has a dense layer sandwiched between surface coats of paracrystalline material. Two cortical granule enzymes, ovoperoxidase and protease, and a cell surface transglutaminase are required for the assembly process. We have examined, by quick-freeze, deep-etch, rotary-shadow electron microscopy, the effects of inhibiting each of these enzymes upon FE assembly. These experiments reveal two domains within the FE, distinguishable by their enzymatic requirements for proper maturation. The first domain consists of the microvillar casts which require both protease and transglutaminase activities to obtain a normal paracrystalline coat. The second domain comprises the regions between casts and appears to mature by ovoperoxidase-mediated cross-linking of paracrystalline material to the envelope.