Intermolecular cross-linking of vitelline envelope polypeptides predominates in the hardened sea urchin fertilization envelope

At fertilization, the sea urchin egg vitelline envelope (VE) elevates, and a subset of released cortical granule proteins, paracrystalline protein fraction (PCF), associates with the VE to form the fertilization envelope (FE). Cortical granule peroxidase cross-links FE polypeptides by phenolic coupling of tyrosyl residues. We have used an immunological approach to determine which polypeptides are linked together in the hardened FE of Strongylocentrotus purpuratus. Soluble polypeptides were extracted from hardened FEs, and antibodies were prepared in rabbits against the insoluble envelope matrix (FE ghost). Whole immune serum and purified IgGs each reacted with FE ghosts when using an enzyme-linked immunosorbent assay. VEs isolated by means of three published procedures cross-reacted with the immune serum and purified IgGs. Soluble FE polypeptides also cross-reacted with whole immune serum and IgGs owing to the presence of VE polypeptides. Hyalin, a protein not found in FEs, and PCF did not cross-react with antiserum against FE ghosts. To determine which VE polypeptides were cross-linked in the hardened FE, VE polypeptides were immunoblotted by using antiserum against FE ghosts. Most of the VE polypeptides that ranged from 68,000 to 283,000 molecular weight cross-reacted with the antibody.     

Cross-linking of ZP2 and ZP3 by transglutaminase is required for the formation of the outer layer of fertilization envelope of carp egg

A transglutaminase (TGase) cDNA was cloned from carp ovary. It was highly homologous to zebrafish TGase. Immunoblot and enzymatical assay showed that TGase was present on the chorion and in the cytoplasm of carp eggs. Addition of TGase inhibitor, cadaverine or ethylene diaminetetracetic acid (EDTA) to the cortical reaction medium impaired the formation of the outer layer of fertilization envelope (FE(o)), the adhesive structure of carp egg. Fibroin-like substance (FLS), cystatin, cathepsin-like substance (CLS), and FEO-1 were the components of FE(o), wherein the majority of the former three were conjugated to form macromolecules of 90-205 kDa while the latter one was present in monomer of 22 kDa. Cadaverine interfered slightly the discharge of FLS conjugates out of the perivitelline space (PVS) but affected profoundly the recruitment of FLS conjugates to FE, whereas EDTA completely inhibited both the release and the recruitment of FLS conjugates to FE. Both EDTA and cadaverine did not inhibit the discharge of FEO-1 out of PVS but could inhibit the recruitment of FEO-1 to FE. The mechanism was studied. ZP2 and ZP3, the major constituents of inner layer of FE, were cross-linked during cortical reaction, which rendered FE hardened. In the presence of EDTA, the cross-linking of ZP2 and ZP3 were inhibited, thus FE remained soft. The PVS of an egg with a hardened FE was less expanded than an egg with a soft FE. It was assumed that a less expanded PVS would generate a higher fluid pressure than a more expanded PVS did. Therefore, the transportation of the macromolecules such as the FLS-cystatin-CLS conjugates out of PVS was facilitated in control and cadaverine-treated eggs whose FE were hardened but was blocked in EDTA-treated eggs whose FE were unhardened. On the other hand, the transportation of small molecules such as FEO-1 out of FE was not restrained, so they were discharged out of the PVS of the control and TGase inhibitor-treated eggs. In addition, TGase activity was also required for the recruitment of FLS conjugates to FE.     

Characterization and localization of a mouse egg cortical granule antigen prior to and following fertilization or egg activation.

Immunological approaches were used to characterize an antigen that is present within the cortical granules of mouse oocytes and eggs. Immunoelectron microscopy shows a specific localization of the antigen to the cortical granules in the cortex of mouse oocytes and eggs. Following in vitro fertilization, the antigen is present in the perivitelline space and is associated with the zona pellucida. No cortical granules and very little antigen are detected in the two-cell embryo. This antiserum detects a protein of Mr = 75,000 (p75) following immunostaining of egg proteins on Western blots, or immunoprecipitation of metabolically labeled oocyte proteins or radio-iodinated egg proteins. p75 is also present in exudates obtained from A23187-treated eggs, as detected by either radio-iodination of the released egg proteins, or maturation and ionophore activation of metabolically labeled oocytes. Two-dimensional gel electrophoresis of radio-iodinated egg proteins reveals four species of p75 with pIs between 4.9 and 5.3, whereas only the most basic form of p75 is detected in metabolically labeled oocytes. Multiple forms of the radio-iodinated p75 are present in the exudate of ionophore-treated eggs. p75 displays a greater electrophoretic mobility under nonreducing conditions, indicating the presence of intramolecular disulfide bonds, a common characteristic of secreted proteins. We conclude that p75 is synthesized in oocytes, modified and packaged into cortical granules, and released from eggs following fertilization or activation.     

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.     

Localization and developmental fate of ovoperoxidase and proteoliaisin, two proteins involved in fertilization envelope assembly

Fertilization of the sea urchin egg leads to the assembly of an extracellular matrix, the fertilization envelope. Ovoperoxidase, the enzyme implicated in hardening the fertilization envelope, is inserted into the assembling structure via a Ca2+-dependent interaction with the protein proteoliasin (P. Weidman and B. M. Shapiro, 1987, J. Cell Biol. 105, 561-567). In the present report, polyclonal antisera were raised to ovoperoxidase and proteoliasin (purified from eggs of Strongylocentrotus purpuratus) and characterized by Western blot analysis and an enzyme-linked immunoabsorbent assay (ELISA). By indirect immunofluorescence microscopy all cortical granules of unfertilized eggs, as well as the fertilization envelope, contained both proteoliasin and ovoperoxidase. At the ultrastructural level both proteins are localized to the electron-dense spiral lamellae of the cortical granules. Western blot analysis revealed that ovoperoxidase and proteoliasin persist in early embryos until hatching, but are absent from later developmental stages. Homogenates of eggs of several other echinoderm species (Strongylocentrotus droebachiensis, Strongylocentrotus franciscanus, Pisaster ochraceus, Dendraster excentricus, and Lytechinus pictus) also contain proteins antigenically similar to ovoperoxidase and proteoliaisin, indicating that many echinoderms utilize a similar strategy for assembly of the fertilization envelope. The results underline the need for postsecretory controls in the extracellular matrix modifications that accompany the cortical reaction.     

Cortical granule exocytosis is coupled with membrane retrieval in the egg of Brachydanio

Activation of the teleost (Brachydanio) fish egg includes the exocytosis of cortical granules, the construction of a mosaic surface consisting of the unfertilized egg plasma membrane and the limiting membranes of the cortical granules, and the appearance of coated and smooth vesicles in the cytoplasm (Donovan and Hart, '82). Unfertilized and activated eggs were incubated in selected extracellular tracers to (1) determine experimentally if cortical granule exocytosis was coupled with the endocytosis of membrane during the cortical reaction, and (2) establish the intracellular pathway(s) by which internalized vesicles were processed. Unfertilized eggs incubated in dechlorinated tap water or Fish Ringer's solution containing either horseradish peroxidase (HRP; 10 mg/ml), native ferritin (12.5 mg/ml), or cationized ferritin (12.5 mg/ml) were activated as judged by cortical granule breakdown and elevation of the chorion. Cells treated with HRP and native ferritin exhibited a delay in cortical granule exocytosis when compared with water-activated eggs lacking the tracer. Each tracer was internalized through the formation of a coated vesicle from a coated pit. Since coated pits appeared to be topographically restricted to the perigranular membrane domain of the mosaic egg surface, their labeling, particularly with cationized ferritin, strongly suggested that the retrieved membrane was of cortical granule origin. Cationized ferritin and concanavalin A (Con A) coupled with either hemocyanin or ferritin labeled the surface of the unactivated egg and both domains of the mosaic egg surface. Transformation of the deep evacuated cortical granule crypt into later profiles of exocytosis was accompanied by increased Con A binding. Within activated egg cortices, HRP reaction product, native ferritin, and cationized ferritin were routinely localized in smooth vesicles, multivesicular bodies, and autophagic vacuoles. Occasionally, each tracer was found in small coated vesicles adjacent to the Golgi and within Golgi cisternae. The intracellular distribution of HRP, native ferritin, and cationized ferritin suggests that internalized membrane is primarily processed by organelles of the lysosomal compartment. A second and less significant pathway is the Golgi complex.     

A cortical granule-specific enzyme,B-1,3-glucanase,in sea urchin eggs

The ultrastructural localization of B-1,3-glucanase in three species of sea urchin eggs was determined using a monospecific antibody in an electronmicroscopic immunogold procedure. In all three species, Lytechinus variegatus, Strongylocentrotus purpuratus, and Arbacia punctulata, B-1,3-glucanase was localized specifically to the cortical granules. No other organelle within the egg contained significant label. During the fertilization reaction, B-1,3-glucanase was released from cortical granules into the perivitelline space and became associated with the hyaline layer. No significant label was found in association with the fertilization envelope.     

Sea urchin ovoperoxidase: oocyte-specific member of a heme-dependent peroxidase superfamily that functions in the block to polyspermy

Ovoperoxidase is one of several oocyte-specific proteins that are stored within sea urchin cortical granules, released during the cortical reaction, and incorporated into the newly formed fertilization envelope. Ovoperoxidase plays a particularly important role in this process, crosslinking the envelope into a hardened matrix that is insensitive to biochemical and mechanical challenges and thus providing a permanent block to polyspermy. Here we present the primary structures of two ovoperoxidases as predicted from cDNAs cloned from the sea urchins Strongylocentrotus purpuratus (AF035380) and Lytechinus variegatus (AF035381). We also present a proposed scheme for the post-translational processing of ovoperoxidase based upon comparisons between the cDNA and protein structures and taking into account previously published reports. The sea urchin ovoperoxidase sequences conform to a profile shared by members of a heme-dependent animal peroxidase family, including the mammalian myelo-, lacto-, eosinophil, and thyroid peroxidases. Using in situ RNA hybridizations, we showed that the mRNA of S. purpuratus ovoperoxidase (4 kb) is present exclusively in oocytes, and is turned over rapidly following germinal vesicle breakdown. Taking into account our immunoblot and N-terminal sequencing data along with reports from similar peroxidases, we propose that ovoperoxidases are synthesized in a pre-pro form and proteolytically processed to result in the 70 and 50 kDa forms that are found in the fertilization envelope. The sequence and structural data presented here will facilitate our continuing studies of the biogenesis of cortical granules and the fertilization envelope. Additionally, since ovoperoxidase activities have been reported in a wide range of animals, these cDNAs will be useful in uncovering similar peroxidases used in the fertilization reactions of other metazoan eggs.     

Egg cortical granule N-acetylglucosaminidase is required for the mouse zona block to polyspermy

The mammalian egg must be fertilized by only one sperm to prevent polyploidy. In most mammals studied to date, the primary block to polyspermy occurs at the zona pellucida, the mammalian egg coat, after exocytosis of the contents of the cortical granules into the perivitelline space. The exudate acts on the zona, causing it to lose its ability to bind sperm and to be penetrated by sperm previously bound to the zona. However, the cortical granule components responsible for the zona block have not been identified. Studies described herein demonstrate that N-acetylglucosaminidase is localized in cortical granules and is responsible for the loss in sperm-binding activity leading to the zona block to polyspermy. Before fertilization, sperm initially bind to the zona by an interaction between sperm surface GalTase and terminal N-acetylglucosamine residues on specific oligosaccharides of the zona glycoprotein ZP3 (Miller, D. J., M. B. Macek, and B. D. Shur. 1992. Nature (Lond.). 357:589-593). These GalTase-binding sites are lost from ZP3 after fertilization, an effect that can be duplicated by N-acetylglucosaminidase treatment. Therefore, N-acetylglucosaminidase, or a related glycosidase, may be present in cortical granules and be responsible for ZP3's loss of sperm-binding activity at fertilization. Of eight glycosidases assayed in exudates of ionophore-activated eggs, N-acetylglucosaminidase was 10-fold higher than any other activity. The enzyme was localized to cortical granules using immunoelectron microscopy. Approximately 70 or 90% of the enzyme was released from cortical granules after ionophore activation or in vivo fertilization, respectively. The isoform of N- acetylglucosaminidase found in cortical granules was identified as beta- hexosaminidase B, the beta, beta homodimer. Inhibition of N- acetylglucosaminidase released from activated eggs, with either competitive inhibitors or with specific antibodies, resulted in polyspermic binding to the zona pellucida. Another glycosidase inhibitor or nonimmune antibodies had no effect on sperm binding to activated eggs. Therefore, egg cortical granule N-acetylglucosaminidase is released at fertilization, where it inactivates the sperm GalTase- binding site, accounting for the block in sperm binding to the zona pellucida.     

Reaction of sperm with egg-derived hydrogen peroxide helps prevent polyspermy during fertilization in the sea urchin

Recent evidence suggests roles for egg derived hydrogen peroxide (H₂O₂) and ovoperoxidase (secreted by cortical granules) in both fertilization envelope hardening and the block to polyspermy in sea urchins. Strongylocentrotus purpuratus eggs were found to release H₂O₂ during the cortical reaction at fertilization. Treatment of sperm with equivalent concentrations of H₂O₂ resulted in a rapid loss of sperm fertilizing ability. Attempts were made to induce polyspermy by utilizing ovoperoxidase inhibitors at concentrations known to inhibit fertilization envelope hardening. Eggs fertilized in phenylhydrazine became polyspermic, while 3-amino-1,2,4-triazole-treated eggs did not. These data suggested that a sperm peroxidase might be involved in preventing polyspermy. This hypothesis was tested by the addition of phenylhydrazine or 3-amino-1,2,4-trizaole to H₂O₂-treated sperm. Phenylhydrazine acted to protect sperm fertility from H₂O₂, while 3-amino-1,2,4-triazole increased the adverse effect of H₂O₂. Simultaneous addition of both inhibitors to sperm incubated in H₂O₂ gave an intermediate value of sperm fertility. These data indicate that (1) H₂O₂ generated by sea urchin eggs during the cortical reaction at fertilization is used for two separate processes, fertilization envelope hardening and the prevention of polyspermy; (2) ovoperoxidase is probably not involved in preventing polyspermy; and (3) egg-derived H₂O₂ reacts directly with sperm enzymes to prevent polyspermy. The phenylhydrazine-sensitive enzyme in the sperm is probably a peroxidase that acts to inactivate sperm, while the 3-amino-1,2,4-triazolesensitive enzyme is probably a catalase which protects sperm from H₂O₂. This hypothesis is consistent with model experiments on horseradish peroxidase and bovine liver catalase.     

The alphaBbetaC integrin is expressed on the surface of the sea urchin egg and removed at fertilization

Integrins are expressed on the surface of some vertebrate eggs where they are thought to have a role in fertilization. The objective of this study is to determine if integrins are expressed on sea urchin eggs. The alphaB and betaC subunits were cloned using the homology polymerase chain reaction. Monoclonal and polyclonal antibodies were developed against bacterially expressed fragments of the extracellular domains of the betaC subunit and the alphaB subunit. As well, a monoclonal antibody was developed against a synthesized peptide corresponding to part of the cytoplasmic domain of betaC. Analysis of biotinylated egg cortex extracts immunoprecipitated with either anti-betaC or anti-alphaB yields bands of 130 and 225 kDa. Immunoblots confirm that betaC is part of the complex immunoprecipitated with anti-alphaB. Confocal immunofluorescence and immunogold electron microscopy show that betaC is present on the surface of the unfertilized egg at the tips of microvilli and in cortical granules. During the cortical reaction, immunoreactivity with antibodies to the extracellular domains of betaC and alphaB disappears from the egg surface, and microvillar casts on the fertilization envelope become immunoreactive. With antibodies to the cytoplasmic domain of betaC, immunoreactivity is lost from the surface of the egg, but the fertilization envelope does not immediately become immunoreactive. In immunoblots of egg cortex there are immunoreactive bands of the predicted sizes for alphaB and betaC. However, in fertilization envelopes, a second band that is slightly lower in molecular weight is also present. Eggs fertilized in the presence of soybean trypsin inhibitor have elongated microvilli that remain bound to the elevating fertilization envelope and immunoreactive to anti-betaC antibodies. Eggs fertilized in the presence of an ovoperoxidase inhibitor, 3-amino-1,2,4-triazole, have a patchy distribution of betaC immunoreactivity in fertilization envelopes. Together, these data suggest that alphaBbetaC integrins are expressed on the surface of unfertilized eggs and, during the cortical reaction, the extracellular domains are cleaved by proteases and cross-linked into the fertilization envelope by ovoperoxidase. The alphaBbetaC integrin receptors may have several potential functions prior to their removal at fertilization, including attachment of the vitelline envelope to the egg surface and anchoring the cortical cytoskeleton.     

Regulated proteolysis by cortical granule serine protease 1 at fertilization

Cortical granules are specialized organelles whose contents interact with the extracellular matrix of the fertilized egg to form the block to polyspermy. In sea urchins, the granule contents form a fertilization envelope (FE), and this construction is critically dependent upon protease activity. An autocatalytic serine protease, cortical granule serine protease 1 (CGSP1), has been identified in the cortical granules of Strongylocentrotus purpuratus eggs, and here we examined the regulation of the protease activity and tested potential target substrates of CGSP1. We found that CGSP1 is stored in its full-length, enzymatically quiescent form in the granule, and is inactive at pH 6.5 or below. We determined the pH of the cortical granule by fluorescent indicators and micro-pH probe measurements and found the granules to be pH 5.5, a condition inhibitory to CGSP1 activity. Exposure of the protease to the pH of seawater (pH 8.0) at exocytosis immediately activates the protease. Activation of eggs at pH 6.5 or lower blocks activation of the protease and the resultant FE phenotypes are indistinguishable from a protease-null phenotype. We find that native cortical granule targets of the protease are beta-1,3 glucanase, ovoperoxidase, and the protease itself, but the structural proteins of the granule are not proteolyzed by CGSP1. Whole mount immunolocalization experiments demonstrate that inhibition of CGSP1 activity affects the localization of ovoperoxidase but does not alter targeting of structural proteins to the FE. The mistargeting of ovoperoxidase may lead to spurious peroxidative cross-linking activity and contribute to the lethality observed in protease-null cells. Thus, CGSP1 is proteolytically active only when secreted, due to the low pH of the cortical granules, and it has a small population of targets for cleavage within the cortical granules.     

Fetuin inhibits zona pellucida hardening and conversion of ZP2 to ZP2f during spontaneous mouse oocyte maturation in vitro in the absence of serum.

The zona pellucida of mouse oocytes becomes resistant to chymotrypsin digestion, or "hardened", when spontaneous maturation occurs in serum-free medium (De Felici and Siracusa, Gam Res 1982; 6:107). The hardened zona pellucida is refractory to sperm penetration, thus preventing fertilization. Conversion of the zona pellucida glycoprotein ZP2 to ZP2f by a protease from precociously released oocyte cortical granules appears to be a major contributory factor of zona pellucida hardening (Ducibella et al., Dev Biol 1990; 137:46). Fetal bovine serum (FBS) prevents zona hardening and the ZP2 to ZP2f conversion during oocyte maturation in vitro (Downs et al., Gam Res 1986; 15:115; Ducibella et al., Dev Biol 1990; 137:46). This study was conducted to determine whether fetuin, a major glycoprotein constituent of FBS and a protease inhibitor, could prevent zona pellucida hardening during murine oocyte maturation in serum-free medium. Commercially available preparations of fetuin purified by three different methods were all active in inhibiting zona pellucida hardening in a concentration-dependent manner. Further chromatographic purification of one of these preparations indicated that the activity preventing zona pellucida hardening was associated specifically with fetuin. Fetuin also inhibited the conversion of ZP2 to ZP2f in a concentration-dependent manner during oocyte maturation in serum-free medium. Moreover, oocytes that matured in serum-free medium containing fetuin could be fertilized and could undergo preimplantation development to the blastocyst stage. These results indicate that fetuin, a component of FBS, inhibits zona pellucida hardening during oocyte maturation, and suggest that fetuin acts by preventing the proteolytic conversion of ZP2 to ZP2f by precociously released cortical granules.     

An immunocytochemical localization of the cortical granule lectin in fertilized and unfertilized eggs of xenopus laevis

At fertilization, the vitelline envelope surrounding the egg of Xenopus laevis is modified by the addition of an electron-dense component termed the “F layer.” The F layer functions as a block to polyspermy and as a block to the escape of macromolecules from the perivitelline space, thereby causing an osmotically driven envelope elevation. F-layer formation has been hypothesized to result from interaction between a cortical-granule lectin, released in the cortical reaction, and a jelly-coat ligand. Evidence for this hypothesis was sought by determining the location of the cortical-granule lectin both before and after fertilization, using a specific antibody conjugated to horseradish peroxidase. The cortical-granule lectin was localized only in the cortical granules of the unfertilized egg and was located predominantly in the perivitelline space and the F layer of a fertilized egg. These observations support the hypothesis that the F layer is formed by a cortical-granule-Iectin–jelly layer-ligand interaction.     

Changes in chorion proteins induced by the exudate released from the egg cortex at the time of fertilization in the teleost, Oryzias latipes

The chorion of unfertilized medaka Oryzias latipes eggs consists of two major proteins (77–73 and 49 kDa) and a minor 150 kDa protein. Upon fertilization, these major chorion proteins are polymerized to insoluble high molecular weight proteins via the temporary formation of several new proteins (132, 114, 62 and 61 kDa). Increasing chorion toughness is closely related to the formation of high molecular weight proteins and the increasing insolubility of the chorion proteins. The changes in chorion proteins and hardening could be induced in vitro in isolated chorions by an egg exudate, which includes cortical alveolar contents. The effects of temperature and pH on the egg exudate-induced changes in chorion proteins were examined in the present study. The major proteins could be digested by proteolytic enzymes. The 49 kDa protein was PAS-positive. Analysis with polyclonal antibodies against the major proteins demonstrated that the temporarily formed 62 and 61 kDa proteins were derived from the 77–73 kDa protein and that higher molecular weight proteins, newly formed in the process of chorion hardening, contained the same epitopes as did the 77–73 and 49 kDa proteins. The results suggest that the changes in chorion proteins of the medaka egg at the time of fertilization can be induced by an enzyme(s) released from the egg cortex into the perivitelline space.     

Members of the SNARE hypothesis are associated with cortical granule exocytosis in the sea urchin egg

Cortical granule exocytosis is important for the block to polyspermy at fertilization in the eggs of most vertebrates and many invertebrates. Cortical granules are poised at the cell surface and exocytose in response to sperm stimulation. Following exocytosis, the cortical granule contents modify the extracellular environment of the egg, the major result of which is to block additional sperm binding. Here we show that proteins homologous to members of the SNARE hypothesis—a molecular model designed to explain the trafficking, docking, and exocytosis of vesicles in the secretory compartment—are present in eggs at the right time and place to be involved in the regulation of cortical granule exocytosis. Using polymerase chain reaction (PCR) screens we have found homologues of synaptobrevin/VAMP, syntaxin, synaptotagmin, and rab3. Antibodies generated to fusion proteins or to synthetic peptides encoded by the cloned cDNAs were used in an immunofluorescence assay to show that each of the cognate proteins are present in the cortex of the egg. A synaptobrevin/VAMP homologue appears to be specifically associated with the membrane of cortical granules before fertilization and, following cortical granule exocytosis, is incorporated into the plasma membrane of the zygote. A rab3 homologue is also associated with cortical granules specifically but, following fertilization, the protein reassociates with different, yet undefined, vesicles throughout the cytoplasm of the zygote. Homologues of synaptotagmin and syntaxin are also present at the egg cortex but, in contrast to rab3 and VAMP, appear to be associated with the plasma membrane. Following fertilization, syntaxin and tagmin remain associated with the plasma membrane and are more readily immunolabeled, presumably due to an increased accessibility of the antibodies to the target protein domains. We also show by immunoblotting experiments that the cognate proteins are of the sizes predicted for these homologues. These results suggest that at least some steps in the biology of cortical granules may be mediated by SNARE homologues, and this finding, along with the unique biology of cortical granules, should facilitate examination of specific events of the fertilization reaction and the mechanism of stimulus-dependent exocytosis. Mol. Reprod. Dev. 48:106–118, 1997. © 1997 Wiley-Liss, Inc.     

The GTP-binding protein RhoA localizes to the cortical granules of Strongylocentrotus purpuratas sea urchin egg and is secreted during fertilization

The sea urchin egg has thousands of secretory vesicles known as cortical granules. Upon fertilization, these vesicles undergo a Ca2+-dependent exocytosis. G-protein-linked mechanisms may take place during the egg activation. In somatic cells from mammals, GTP-binding proteins of the Rho family regulate a number of cellular processes, including organization of the actin cytoskeleton. We report here that a crude membrane fraction from homogenates of Strongylocentrotus purpuratus sea urchin eggs, incubated with C3 (which ADP-ribosylates specifically Rho proteins) and [32P]NAD, displayed an [32P]ADP-ribosylated protein of 25 kDa that had the following characteristics: i) identical electrophoretic mobility in SDS-PAGE gels as the [32P]ADP-ribosylated Rho from sea urchin sperm; ii) identical mobility in isoelectro focusing gels as human RhoA; iii) positive cross-reactivity by immunoblotting with an antibody against mammalian RhoA. Thus, unfertilized S. purpuratus eggs contain a mammalian RhoA-like protein. Immunocytochemical analyses indicated that RhoA was localized preferentially to the cortical granules; this was confirmed by experiments of [32P]ADP-ribosylation with C3 in isolated cortical granules. Rho was secreted and retained in the fertilization membrane after insemination or activation with A23187. It was observed that the Rho protein present in the sea urchin sperm acrosome was also secreted during the exocytotic acrosome reaction. Thus, Rho could participate in those processes related to the cortical granules, i.e., in the Ca2+-regulated exocytosis or actin reorganization that accompany the egg activation.     

The biology and dynamics of mammalian cortical granules

Cortical granules are membrane bound organelles located in the cortex of unfertilized oocytes. Following fertilization, cortical granules undergo exocytosis to release their contents into the perivitelline space. This secretory process, which is calcium dependent and SNARE protein-mediated pathway, is known as the cortical reaction. After exocytosis, the released cortical granule proteins are responsible for blocking polyspermy by modifying the oocytes' extracellular matrices, such as the zona pellucida in mammals. Mammalian cortical granules range in size from 0.2 um to 0.6 um in diameter and different from most other regulatory secretory organelles in that they are not renewed once released. These granules are only synthesized in female germ cells and transform an egg upon sperm entry; therefore, this unique cellular structure has inherent interest for our understanding of the biology of fertilization. Cortical granules are long thought to be static and awaiting in the cortex of unfertilized oocytes to be stimulated undergoing exocytosis upon gamete fusion. Not till recently, the dynamic nature of cortical granules is appreciated and understood. The latest studies of mammalian cortical granules document that this organelle is not only biochemically heterogeneous, but also displays complex distribution during oocyte development. Interestingly, some cortical granules undergo exocytosis prior to fertilization; and a number of granule components function beyond the time of fertilization in regulating embryonic cleavage and preimplantation development, demonstrating their functional significance in fertilization as well as early embryonic development. The following review will present studies that investigate the biology of cortical granules and will also discuss new findings that uncover the dynamic aspect of this organelle in mammals.     

Effects of egg quality on normal fertilization and early development of the cod, Gadus morhua L

Normal cod eggs respond to insemination by a rapid cortical reaction followed by an increase in total osmolarity and a small increase in egg diameter. The chorion becomes harder, but this is a slower process reaching its maximum strength after c . 24 h. Bad eggs are characterized by a slower or incomplete cortical reaction, resulting in a slower rise in osmolarity and a softer chorion. Bad eggs rapidly lose their capacity for fertilization. In unfertilized eggs in sea water, no cortical reaction is observed. There is, however, a rise in total osmolarity and a hardening of the chorion.     

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.