Behaviour of the vitelline envelope in Bufo arenarum oocytes matured in vitro in blockade to polyspermy

During activation of amphibian eggs, cortical granule exocytosis causes elaborate ultrastructural changes in the vitelline envelope. These changes involve modifications in the structure of the vitelline envelope and formation of a fertilization envelope (FE) that can no longer be penetrated by sperm. In Bufo arenarum, as the egg traverses the oviduct, the vitelline envelope is altered by a trypsin-like protease secreted by the oviduct, which induces an increased susceptibility of the vitelline envelope to sperm lysins. Full-grown oocytes of B. arenarum, matured in vitro by progesterone, are polyspermic, although cortical granule exocytosis seems to occur within a normal chronological sequence. These oocytes can be fertilized with or without trypsin treatment, suggesting that the vitelline envelope is totally sperm-permeable. Vitelline envelopes without trypsin treatment cannot retain either gp90 or gp96. This suggests that these glycoproteins are involved in the block to polyspermy and that trypsin treatment of matured in vitro oocytes before insemination is necessary to enable vitelline envelopes to block polyspermy. The loss of the binding capacity in vitelline envelopes isolated from B. arenarum oocytes matured in vitro with trypsin treatment and activated by electric shock suggests that previous trypsin treatment is a necessary step for sperm block to occur. When in vitro matured oocytes were incubated with the product of cortical granules obtained from in vitro matured oocytes (vCGP), vitelline envelopes with trypsin treatment were able to block sperm entry. These oocytes exhibited the characteristic signs of activation. These results support the idea that B. arenarum oocytes can be activated by external stimuli and suggest the presence of unknown oocyte surface receptors linked to the activation machinery in response to fertilization. Electrophoretic profiles obtained by SDS-PAGE of solubilized vitelline envelopes from oocytes matured in vitro revealed the conversion of gp40 (in vitro matured oocytes, without trypsin treatment) to gp38 (ascribable to trypsin activity or cortical granule product activity, CGP) and the conversion of gp70 to gp68 (ascribable to trypsin activity plus CGP activity). Taking into account that only the vitelline envelopes of in vitro matured oocytes with trypsin treatment and activated can block sperm entry, we may suggest that the conversion of gp70 to gp68 is related to the changes associated with sperm binding.     

Ascidian eggs release glycosidase activity which aids in the block against polyspermy

To ensure normal development, most animals have evolved a number of mechanisms to block polyspermy including prevention of binding to surface coats as well as sperm-egg fusion. Ascidian sperm bind to vitelline coat (VC) glycosides. In the genus Ascidia, N-acetylglucosamine (GlcNAc) is the ligand to which sperm bind. The number of sperm bound to the VC is biphasic following fertilization; sperm binding increases through the first minute or so, then abruptly declines. At fertilization, the eggs of Ascidia callosa, A. ceratodes, A. mentula, A. nigra and Phallusia mammillata release N-acetylglucosaminidase into the sea water (SW). This has been shown to inactivate VC GlcNAc groups, blocking the binding of supernumerary sperm and polyspermy in A. nigra. This block to polyspermy is inactivated by GlcNAc (2mM) or 150 mM-Na+ (choline substituted) SW. These treatments are not additive and therefore probably affect the same process. In A. callosa, fertilization in low Na+ SW causes a 60% decline in enzyme release and a similar increase in the number of sperm remaining on the VC at 4 min as well as a great increase in polyspermy. Thus the principal block to polyspermy in ascidian eggs involves the release of N-acetylglucosaminidase which appears to be Na+ dependent. Enzyme activity is found in the supernatant SW by 15 s after fertilization, suggesting that it is stored very near the egg surface. Histochemical staining of whole eggs and embryos shows loss of surface-associated enzyme activity following fertilization. Like other lysosomal enzymes this N-acetylglucosaminidase is mannosylated and has an acidic pH optimum.     

Germ-cell warfare in ascidians: sperm from one species can interfere with the fertilization of a second species

Ascidians (invertebrate chordates) are very abundant in many marine subtidal areas. They often live in dense multispecies clumps; thus, interspecific competition for space may be intense. Although most noncolonial species are broadcast spawners, their eggs can be fertilized only by sperm of the same species (1). Multiple fertilization is lethal and all animals have evolved blocks to polyspermy. Ascidian eggs block polyspermy by enzymatic (2) and electrical mechanisms (3). Sperm bind to N-acetylglucosamine groups on the vitelline coat (4, 5, 6, 7). Follice cells surrounding the vitelline coat release N-acetylglucosaminidase during egg activation (8), preventing the binding of all sperm but a few (2). I show here that this interaction is not species-specific; sperm from one species can cause glycosidase release from follicle cells of a second species. Furthermore, once glycosidase release has been induced, the subsequent addition of sperm from the egg-producing species fails to fertilize a substantial proportion of these eggs. This leads to the hypothesis that sperm from one species of ascidian can interfere with fertilization of a second species. While intraspecific sperm competition has been well documented in several taxa (9, 10), this is the first record of sperm competition between species, or interspecific sperm competition.     

Biochemical and morphological changes in the chorion of the carp (Cyprinus carpio) oocyte, following the cortical reaction

Following oviposition and/or fertilization in fieshwater, the soft vitelline membrane surrounding the carp oocyte elevates and becomes tough (fertilization envelope). We have studied the biochemical (protease digestion) and morphological (analysis scanning electron microscopy) changes associated with this transformation. The vitelline envelope is easily digested by most proteolytic enzymes; following elevation, the chorion becomes very resistant to proteolyse. This chorion is much thinner and smoother than the vitelline membrane, but retains a characteristic porous appearance. These results are compared with previous observations obtained by transmission electron microscopy and are discussed in relation to the blockage to polyspermy.     

Benzohydroxamic acid induces polyspermic fertilization in the sea urchin Arbacia punctulata

Benzohydroxamic acid (BHA) is a competitive inhibitor of the sea urchin sperm peroxidase. We now report that addition of BHA to fertilization cultures of Arbacia punctulata promotes polyspermy. This effect is dose and sperm density dependent. The cortical reaction (elevation of the fertilization envelope) is not retarded by BHA. BHA must be added to the cultures before the eggs complete the cortical reaction at 60 sec post insemination in order to induce polyspermy. Since sea urchin eggs release H2O2 during the cortical reaction at fertilization, these findings support our hypothesis that the sperm peroxidase has a functional role in helping to prevent polyspermy.     

Sperm binding and fertilization envelope formation in a cell surface complex isolated from sea urchin eggs

An isolated surface complex consisting of the vitelline layer, plasma membrane, and attached secretory vesicles has been examined for its ability to bind sperm and to form the fertilization envelope. Isolated surface complexes (or intact eggs) fixed in glutaraldehyde and then washed in artificial sea water are capable of binding sperm in a species-specific manner. Sperm which bind to the isolated surface complex exhibit the acrosomal process only when they are associated with the exterior surface (vitelline layer) of the complex. Upon resuspension of the unfixed surface complex in artificial sea water, a limiting envelope is formed which, based on examination of thin sections and negatively stained surface preparations, is structurally similar to the fertilization envelope formed by the fertilized egg. These results suggest that the isolated egg surface complex retains the sperm receptor, as well as integrated functions for the secretion of components involved in assembly of the fertilization envelope.     

The ascidian egg envelope in fertilization: structural and molecular features

In this report, unpublished and recent findings concerning the structure and function of the ascidian egg coat are compiled in context with fertilization. In the initial stage of ascidian fertilization, sperm interact with a complex egg investment that consists of a layer of follicle cells attached to an acellular vitelline coat. Increasing evidence exists that ascidian sperm are activated at their encounter with the follicle cells. The molecular basis of sperm-follicle cell interactions is discussed in context with sperm binding, membrane proteins and sperm bound glycosidase. The model that suggests a block to polyspermy established by glycosidase released from the follicle cells on fertilization is evaluated and compared with assured facts. Although a number of questions remain to be answered, our recent findings that a cloned beta-hexosaminidase from P. mammillata binds exclusively to the follicle cells of unfertilized but not fertilized eggs, indicates that the follicle cells participate in the block to polyspermy. A dual function, mediating sperm activation and a block to polyspermy attributes to the ascidian follicle cells a key position in fertilization.     

Blocks to polyspermy in Chaetopterus

Blocks to polyspermy may act either at the level of the egg plasma membrane to prevent gamete fusion or at the level of egg surface coats to prevent gamete attachment. The present study was undertaken to determine what type(s) of block(s) to polyspermy exist in Chaetopterus. The results showed the existence of both types. A rapid block acts at the plasma membrane level based on independence from detectable changes in the vitelline layer and is dependent on external sodium ions. A vitelline layer block had been predicted on morphological evidence and is supported here by demonstrating an increase in polyspermy following chemical disruption of the vitelline layer. However, the vitelline layer of the fertilized egg retained its ability to initiate the acrosome reaction in sperm and attach sperm which had undergone the acrosome reaction. The vitelline layer block resulted from the retraction of egg microvilli from the vitelline layer, and not from elevation of the vitelline layer per se. Thus the vitelline layer of the fertilized egg could be involved in preventing sperm penetration into the egg without being altered structurally or functionally.     

The site of the acrosome reaction during in vivo penetration of the sheep oocyte

In vivo fertilization of sheep eggs has been studied by electron microscopy. Remnants of the acrosome reaction were present at the zona surface of every penetrated egg, indicating that the acrosome reaction in sheep occurs at the surface of the zona pellucida. To determine whether follicular oocytes could specifically bind spermatozoa, oocytes isolated from different size classes of antral follicles were transferred into the oviducts of mated ewes, recovered 4 hr 30 min later, and analyzed by electron microscopy. Oocytes from follicles up to 1 mm in diameter failed to bind spermatozoa and were not penetrated. In contrast, the zona of oocytes from follicles ? 2 mm in diameter induced the acrosome reaction. These oocytes were penetrated but failed to achieve cortical granule exocytosis and so to mount a block to polyspermy. Moreover, sperm nuclei incorporated into the ooplasm did not decondense although the sperm nuclear envelope was dispersed.     

Polyspermic fertilization of sea urchin eggs treated with protease inhibitors: Localization of sperm receptor sites at the egg surface

The normal elevation of the fertilization membrane and the establishment of the block to polyspermy are retarded in Arbacia punctulata eggs by specific protease inhibitors, soybean trypsin inhibitor (SBTI), leupeptin, and antipain. Ultrastructural observations show that the vitelline layer remains attached to the plasma membrane of fertilized SBTI treated eggs at numerous sites (cortical projections). Quantitive morphometric analysis indicates that the vitelline layer elevates from about 65% of the surface of SBTI treated eggs during the first 3 min post insemination. However, the vulnerability of SBTI treated eggs to refertilization (polyspermy) only declined during the subsequent gradual detachment of the vitelline layer from the cortical projections over the next 15 min. Antipain and leupeptin (10^?5 to 10^?3M) also promoted polyspermy in Arbacia eggs by a process of refertilization extending for a 10- to 15-min period after the initial monospermic insemination. Normal cleavage and development was obtained when eggs were placed in leupeptin and antipain (10^?3M) after the fertilization membrane had elevated. The data indicate that the normal secretory function (or functions) of the cortical granule protease in establishing the block to polyspermy is retarded by these protease inhibitors, and that the vitelline layer is transformed into a mechanical barrier to prevent penetration by supernumerary sperm during its detachment from the plasma membrane of the egg. Furthermore, the vitelline layer in unfertilized eggs appears to be a mosaic structure, with sperm receptor sites localized in regions of the egg's surface, which give rise to cortical projections in the presence of SBTI.     

The vitelline envelope to fertilization envelope conversion in eggs of Xenopus laevis

Fertilization of the Xenopus laevis egg causes the conversion of the vitelline envelope to the fertilization envelope, a change reflected in the loss of sperm penetrability of the egg and the appearance of an electron-dense layer on the outer aspect of the fertilization envelope. As seen by one-dimensional gel electrophoresis, two components with molecular weights of 69,000 and 64,000 in the vitelline envelope were converted to 66,000 and 61,000 in the fertilization envelope. By two-dimensional gel electrophoresis, the components in the 69,000 and 64,000 molecular weight regions of the vitelline envelope were seen to shift to more basic isoelectric points upon conversion to the fertilization envelope. Peptide mapping by limited proteolysis suggested that the 69,000 and 64,000 molecular weight components shared the same polypeptide chains but the smaller glycoprotein lacked a carbohydrate side chain found on the larger species. Similar sites on each glycoprotein were affected when the vitelline envelope was converted to the fertilization envelope. No N-terminal amino acids could be identified on the envelope components, indicating that these glycoproteins have blocked N-termini. Ionophore A23187-activation of jellied eggs (but not dejellied eggs) caused the molecular weight changes in the absence of sperm. Thus, factors from the jelly and the cortical granules but not from sperm apparently are involved in the processing of the 69,000 and 64,000 molecular weight components.     

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.     

Propranolol induces polyspermy during sea urchin fertilization

Propranolol, a β-adrenergic receptor blocker, is found to induce polyspermy in sea urchin eggs. Unfertilized sea urchin eggs treated for 10 min with 50 μM of propranolol, and then inseminated, become polyspermic and show a fertilization envelope which is barely visible to the light microscope. Examination of treated eggs by transmission and scanning electron microscopy shows that the drug does not alter the cortex of the unfertilized egg. However, after insemination an incomplete cortical reaction occurs. This might well account for both polyspermy and the defective elevation of the fertilization envelope. Since the effects of the drug are reversed by simultaneous treatment with adrenalin, perhaps propranolol interferes with the monoaminergic system that has been proposed to be active. The involvement of the monoaminergic system in the fertilization process is present in the sea urchin egg. © 1996 Wiley-Liss, Inc.     

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.     

Ultrastructural study of polyspermy during early embryo development in pigs, observed by scanning electron microscope and transmission electron microscope

Polyspermy is generally considered a pathological phenomenon in mammals. Incidence of polyspermy in porcine eggs in vivo is extremely high (30-40%) compared with other species, and polyspermy rate in the in vitro fertilized eggs in pigs can reach 65%. It is still unknown whether polyspermy to a certain degree is a physiological condition in pigs, and whether porcine eggs have any capability with which to remove the accessory sperm in the cytoplasm. The objectives in the present study are to observe the ultrastructural changes of accessory sperm during early embryonic development in pigs. A total of 58 normal, early embryos at one-, two, three-, and four-cell and morular stages were collected from gilts and were studied by scanning electron microscopy (SEM) and transmission electron microscopy (TEM). The surface ultrastructure showed that sperm fusion with the zona pellucida was a continuous process during one-, two-, three-, and four-cell and morular stages, as observed by the SEM. Accessory sperm were present in the cytoplasm of cleaved embryos. The sperm heads in the cytoplasm of cleaved embryos did not decondense. TEM revealed the presence of a condensed sperm head within a lysosome (or phagolysosome) in a three-cell embryo. These observations suggest that polyspermy may be a physiological condition in pigs and that early embryos may develop to term if accessory sperm do not interrupt the embryo genome. Furthermore, lysosome activity could be another physiological mechanism for removing accessory sperm in the cytoplasm of fertilized eggs and cleaved embryos after fertilization in pigs.     

An electrical block is required to prevent polyspermy in eggs fertilized by natural mating of Xenopus laevis

In 27% DeBoer's saline (DBS), which yields maximum fertility rates, Xenopus eggs fertilized in vitro are monospermic, regardless of sperm concentration. One block to polyspermy (the “slow” block), described previously, occurs at the fertilization envelope that is elevated in response to the cortical reaction. This paper describes properties of an earlier, “fast” block at the plasma membrane and evaluates the functional significance of the two blocks at physiological sperm concentrations in natural mating conditions. Unfertilized eggs have a resting membrane potential of ?19 mV in 27% DBS. Fertilization triggers a rapid depolarization to +8 mV (the fertilization potential, FP); the potential remains positive for ca. 15 min. Activation of eggs with the ionophore, A23187, produces a slower but similar depolarization (the activation potential, AP). As in other amphibian eggs, the FP appears to result from a net efflux of Cl^?, since the peak of the FP (or the AP in ionophore-activated eggs) decreases as the concentration of chloride salts in the medium is increased. In 67% DBS no FP or AP is observed; eggs fertilized in 67% DBS become polyspermic and average 2 sperm entry sites per egg. In the 5–37 mM range, I^? and Br^?, but not F^?, are more effective than Cl^? in producing polyspermy. In 20 mM NaI the plasma membrane hyperpolarizes in response to sperm or ionophore; 100% levels of polyspermy and an average of 14 sperm entry sites per egg are observed. NaI does not inhibit or retard elevation of the fertilization envelope; the cortical reaction and fertilization envelope are normal in transmission electron micrographs. In 67% DBS, which also inhibits the fast block, the slow block was estimated to become functional 6–8 min after insemination. Eggs fertilized by natural mating in 20 mM NaI exhibit polyspermy levels of 50–90% and average 5 sperm entry sites per egg. Since eggs become polyspermic when fertilized by natural mating under conditions that inhibit the fast, but not the slow, block to polyspermy, we conclude that the fast block is essential to the prevention of polyspermy at the sperm concentrations normally encountered by the egg.     

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.     

Glycosidases,proteases and ascidian fertilization

Spermatozoa should bind to and then penetrate the vitelline coat for fertilization in ascidians and many other animals. There is substantial evidence that the binding of ascidian sperm is mediated by a sperm glycosidase and complementary saccharide chains of glycoproteins in the vitelline coat. Involvement of a sperm proteasome in the binding is also suggested. For the penetration, sperm proteases such as chymotrypsin-like enzyme, acrosin, spermosin and proteasome are suggested to play essential roles. Sperm glycosidase, that is translocated from the tip of sperm head to the surface overlying the mitochondrion, anchors the mitochondrion at the outer surface of vitelline coat. Therefore it assists sperm to penetrate the vitelline coat and traverse the perivitelline space. For fusion with egg plasma membrane, sperm metalloendoprotease seems to be involved. Egg glycosidases and proteases serve for some steps after fertilization, such as the prevention of polyspermy, expansion of perivitelline space and regulation of cell cycle.     

Sperm proteasomes are responsible for the acrosome reaction and sperm penetration of the vitelline envelope during fertilization of the sea urchin Pseudocentrotus depressus

The roles of sperm proteasomes in fertilization were investigated in the sea urchin Pseudocentrotus depressus. Two proteasome inhibitors, MG-132 and MG-115, inhibited fertilization at 100 microM, whereas chymostatin and leupeptin showed no inhibition. Among three proteasome substrates, Z-Leu-Leu-Glu-MCA showed the strongest inhibition toward fertilization. MG-132 inhibited the egg-jelly-induced, but not ionomycin-induced, acrosome reaction. In addition, MG-132, but not E-64-d, inhibited fertilization of dejellied eggs by acrosome-reacted sperm. MG-132 showed no significant inhibition toward the binding of reacted sperm to the vitelline layer. Proteasomes were detected by Western blotting in the acrosomal contents, which are partially released upon exocytosis. We also found that the inhibition pattern of the caspase-like activity of the proteasome in the acrosomal contents by chymostatin and proteasome inhibitors coincided well with their inhibitory abilities toward fertilization. Furthermore, the vitelline layer of unfertilized eggs appears to be ubiquitinated as revealed by immunocytochemistry and Western blotting. Extracellular ATP, required for the degradation of ubiquitinated proteins by the proteasome, was also necessary for fertilization. These results indicate that the sperm proteasome plays a key role not only in the acrosome reaction but also in sperm penetration through the vitelline envelope, most probably as a lysin, during sea urchin fertilization.     

Effect of oviduct cells on the incidence of polyspermy in pig eggs fertilized in vitro

The consequences of interactions between porcine sperm, eggs, and oviduct cells before and during fertilization in vitro (IVF) has been examined with particular reference to the block to polyspermy. The pattern of polypeptides secreted by porcine oviduct epithelial cells has been determined and its effects on sperm both during pre-fertilization co-culture and during fertilization have been examined. In standard IVF procedures with no oviduct cell involvement, high rates of penetration (91%) were accompanied by equally high rates of multiple sperm penetration (91% of penetrated eggs). Fertilization on oviduct cell monolayers or a combination of 1 h co-culture of sperm and oviduct cells before the addition of in vitro matured oocytes did not reduce polyspermy. However, a sperm-oviduct cell co-culture period of 2.5 h followed by IVF on oviduct cells selectively reduced the rate of polyspermy by 40% and 50% in two separate series of trials (United Kingdom and Japan, respectively): Overall fertilization rates after this treatment were high (95% or 84%, respectively). A 3.5 h period of pre-fertilization co-culture further reduced polyspermy to only 14% of penetrated eggs, but this treatment was accompanied by a sharp drop in the fertilization rate from an overall mean of 88% for all other groups to 19% after 3.5 h co-culture.