Studies on the interactions of sperm with the surface of the sea urchin egg

We have examined the relationship between sperm adhesion and fertilization in the cross species insemination of Arbacia punctulata eggs by Strongylocentrotus purpuratus sperm. As previously reported (Kinsey et al., 1980) the addition of S. purpuratus egg jelly results in induction of the acrosome reaction in sperm and significant numbers of S. purpuratus sperm adhere to A. punctulata eggs. However, in the absence of S. purpuratus egg jelly, S. purpuratus sperm fail to bind to A. punctulata eggs. Although at least 200 S. purpuratus sperm bind to an A. punctulata egg in the presence of S. purpuratus jelly, less than 8% of the eggs are fertilized. The adhesion of S. purpuratus sperm meets the same functional criteria as homologous A. punctulata sperm-egg adhesion. Electron microscopy shows that S. purpuratus sperm that have undergone the acrosome reaction adhere to A. punctulata eggs by their bindin-coated acrosomal process in a manner that is morphologically identical to that observed with homologous A. punctulata sperm. We have also compared the ability of S. purpuratus and A. punctulata sperm to fuse and fertilize with A. punctulata eggs after removal of the vitelline layer. Using high levels of sperm of either species, heterologous as well as homologous fertilization is readily detectable. Under these conditions, where stable binding is not demonstrable, there is no difference in the ability of S. purpuratus and A. punctulata sperm to fertilize A. punctulata eggs. These observations suggest that the failure of S. purpuratus sperm to fertilize A. punctulata eggs under normal conditions may be due to their inability to penetrate the vitelline layer so that they can fuse with the egg plasma membrane. In relation to the possible mechanism of vitelline layer penetration, we have also investigated the mode of action of chymostatin, an inhibitor of chymotrypsin that has been reported to inhibit fertilization of sea urchin eggs (Hoshi et al., 1979). Our findings suggest that the fertilization inhibitory activity of chymostatin is not related to its antichymotrypsin activity. Rather, it appears that this inhibition is due to the induction of an abnormal acrosome reaction in sperm that precludes formation of the acrosome process.     

Characterization of the sperm receptor on the surface of eggs of Strongylocentrotus purpuratus

Eggs of the sea urchins Strongylocentrotus purpuratus and Arbacia punctulata bind sperm with a high degree of species specificity. By use of an in vitro assay that utilizes bindin (the protein from sperm that mediates sperm-egg binding) egg surface-derived glycoconjugates that function as receptors in this adhesion process have been identified and purified. These glycoconjugates are of extraordinarily high molecular weight and exhibit some properties expected for a proteoglycan. The isolated receptors from both species bind to sperm and inhibit fertilization species specifically. Both receptors contain active carbohydrate-rich fragments that can be liberated by proteolytic digestion. The carbohydrate-rich receptor fragment from S. purpuratus is a very high-molecular-weight (>10⁶), negatively charged glycosaminoglycan-like polymer containing fucose, galactosamine, iduronic acid, and sulfate esters. By contrast, the carbohydrate-rich fragment derived from the A. punctulata receptor is of defined molecular weight (6000) and has no net charge. Incubation of acrosome-reacted sperm with nanomolar amounts of the carbohydrate-rich fragments from either species results in inhibition of fertilization, indicating that these receptor fragments retain sperm binding activity. However, studies utilizing heterologous gametes show that the carbohydrate-rich receptor fragments are not species specific in binding. Thus, it appears that although the carbohydrate chains of the receptor are an adhesive element of the receptor, the intact glycoconjugate is required for species-specific binding.     

Chemical characterization of the component of the jelly coat from sea urchin eggs responsible for induction of the acrosome reaction.

Jelly coat, a multicomponent extracellular matrix surrounding the sea urchin egg, induces the acrosome reaction in sperm. The jelly coats of the four species studied, Arbacia punctulata, Strongylocentrotus purpuratus, Strongylocentrotus drobachiensis, and Lytechinus variegatus, were found to be very similar in chemical composition. A sialoprotein (approximately 20% of the mass of the jelly coat) and a fucose sulfate polysaccharide (approximately 80%) are the major macromolecular components of the jelly coat. The acrosome reaction inducing capacity resides solely in the fucose sulfate polysaccharide. Induction of the acrosome reaction ranges from highly species specific to nonspecific. Thus, A. punctulata and S. drobachiensis sperm are induced to undergo the acrosome reaction only with their homologous jelly coat, while S. purpuratus sperm react equally well with homologous or L. variegatus jelly coat, but not with A. punctulata jelly coat. L. variegatus sperm seem to be relatively nonspecific in response. Species-specific induction of the acrosome reaction resides solely in the fucose sulfate polysaccharide, suggesting that there must be structural differences in this polysaccharide in the various species. Therefore, in some species, fertilization appears to involve sperm-egg recognition at the level of the jelly coat as well as at the level of sperm-egg receptors.     

Acrosome reaction is subfamily specific in sea star fertilization

In the fertilization process of sea stars, sperm is activated to go through the acrosome reaction before cell fusion. We focused on induction of the acrosome reaction as a key process in fertilization. Six species of sea stars were used in this study: Asterias amurensis, Asterias rubens, Asterias forbesi, Aphelasterias japonica, Distolasterias nipon, and Asterina pectinifera. Acrosome reaction assays indicate that the acrosome reaction can be induced across species within Asteriinae subfamily. However, cross-fertilization assays indicate that sea stars have species specificity in fertilization. Therefore, steps after the acrosome reaction are responsible for the species specificity. To explain acrosome reaction subfamily specificity at the molecular level, the sugar components of egg jelly were examined and analyzed by principal component analysis. A. amurensis and A. forbesi belong to the same induction group of the acrosome reaction. D. nipon and An. pectinifera are in a unique group. Enzyme-linked immunosorbent assays indicate that Asteriinae subfamily share a common glycan structure, the Fragment 1 of Acrosome Reaction-Inducing Substance from A. amurensis. Fragment 1 plays an important role in the subfamily specificity of acrosome reaction induction. In addition, A. amurensis sperm activating peptide was recognized by sperm from the same superorder. These results demonstrate that the specificity of acrosome reaction induction is present at the subfamily level in sea stars.     

Involvement of an acrosin-like enzyme in the acrosome reaction of sea urchin sperm

Extracts of the jelly coat of eggs of several marine invertebrates are known to induce in homologous sperm morphological changes known as the acrosome reaction. When sperm of the sea urchin Strongylocentrotus purpuratus are treated with low concentrations (0.2 μg fucose/ml) of egg jelly coat or 30 mM CaCl₂ in artificial seawater the acrosome reaction does not occur. However, either of these treatments causes the exposure of an acrosin-like enzyme to exogenous substrate and inhibitors. Subsequent addition of jelly coat to 3.7 μg fucose/ml to sperm in this “initial stage” induces the acrosome reaction (as judged by the appearance of an acrosomal filament). This concentration is also effective for untreated sperm. If inhibitors of the enzyme (diisopropylphosphofluoridate or phenylmethanesulfonyl fluoride) are added to sperm in the initial stage, no acrosomal filaments are observed when the high concentration of jelly coat is added. Whether other morphological changes occur in these sperm has not been examined. If phenylmethanesulfonyl fluoride is added 4 sec after the jelly coat, the acrosomal filaments are observed, but the sperm still fail to fertilize eggs. These results suggest a dual role for the acrosin-like enzyme(s), first in the mechanism of the acrosomal filament formation and then in a subsequent event in the fertilization process.     

A reevaluation of the fertilizin hypothesis of sperm agglutination and the description of a novel form of sperm adhesion

The classical isoagglutination of sea urchin sperm by egg jelly is not an agglutination of cells, as proposed by the fertilizin-antifertilizin hypothesis. Sperm motility is required to obtain the isoagglutination of Strongylocentrotus purpuratus sperm, and the sperm do not adhere to each other in the isoagglutination clusters, which cannot be fixed for microscopy and which disperse rapidly into individual cells when sperm motility is inhibited. These observations suggest that isoagglutination is the swarming of freely moving sperm to a common focus and is quite distinct from the agglutination of sperm by known crosslinking agents (antibodies or lectins).A previously unrecognized form of sperm agglutination is described which follows induction of an acrosome reaction by egg jelly, ammonia, or the ionophore A23187 in a suspension of sea urchin or sand dollar sperm. The sperm form rosettes of up to 100 cells in which the newly extended acrosomal processes adhere to each other. Rosettes can form containing sperm of different species, in which the acrosomal processes adhere without species preference.As observed by transmission electron microscopy, the acrosomal process of Lytechinus pictus sperm consists of an acrosomal tubule covered by a sheath of extracellular material. Rosette formation results from attachment between the extracellular materials of adjacent sperm.Less frequently, the acrosomal process of one sperm adheres to the midpiece of another by fusion of the acrosomal tubule and midpiece plasma membranes.     

MORPHOLOGY OF GAMETE MEMBRANE FUSION AND OF SPERM ENTRY INTO OOCYTES OF THE SEA URCHIN

Sea urchin gametes predominate in molecular studies of fertilization, yet relatively little is known of the subcellular aspects of sperm entry in this group. Accordingly, it seemed desirable to make a detailed examination of sperm entry phenomena in sea urchins with the electron microscope. Gametes of the sea urchins Arbacia punctulata and Lytechinus variegatus were used in this study. Samples of eggs containing 2 to 8 per cent oocytes were selected and fixed with osmium tetroxide in sea water at various intervals after insemination. Fixed specimens were embedded in Epon 812, sectioned, and examined with an electron microscope. An apical vesicle was observed at the anterior end of the acrosome. The presence of this structure, together with other observations, suggested that initiation of the acrosome reaction in sea urchin sperm involves dehiscence of the acrosomal region with the subsequent release of the acrosomal granule. Contact and initial fusion of gamete membranes was observed in mature eggs and oocytes and invariably involved the extended acrosomal tubule of the spermatozoon. Only one spermatozoon normally enters the mature egg. The probability of locating such a sperm in ultrathin sections is exceedingly low. Several sperm do normally enter oocytes. Consequently, observations of sperm entry were primarily restricted to the latter. The manner of sperm entry into oocytes did not resemble phagocytosis. Organelles of the spermatozoon were progressively divested of their plasma membrane as they entered the ground cytoplasm of the oocyte fertilization cone. Initiation of the acrosome reaction, contact and initial fusion of gamete membranes, and sperm entry into oocytes of sea urchins conform to the Hydroides-Saccoglossus pattern of early fertilization events as described by Colwin and Colwin (13).     

The effect of the acrosome reaction on the respiratory activity and fertilizing capacity of echinoid sperm.

We have examined the relationship between the acrosome reaction, sperm respiration, and fertilization using gametes of the sea urchin Strongylocentrotus purpuratus. The results indicate that when sperm are exposed to jelly coat isolated from homologous eggs, the following sequence of events occurs: (1) Sperm undergo the acrosome reaction within 30 sec with little or no loss in their capacity to fertilize eggs; (2) by 60 sec there is a dramatic decrease in fertilizing capacity which stabilizes after 4 or 5 min at a greatly reduced level; (3) by 1.5 to 2 min a progressive decrease in the rate of mitochondrial respiration becomes detectable and continues for 8 to 10 min, finally stabilizing at a greatly reduced rate. This decrease in respiration rate is paralleled by a decline in sperm motility. The effects of jelly coat on the acrosome reaction, sperm respiration, and motility are species specific. From these results we conclude that sperm which have undergone the acrosome reaction retain full fertilizing capacity for a very short time. The rapid decline in fertilizing capacity is followed by a decrease in respiration rate and motility.     

Effects of concanavalin A on the fertilization of sea urchin eggs

Concanavalin A (Con A) affected sperm-egg interactions of Arbacia punctulata and Strongylocentrotus purpuratus by inhibiting insemination at minimally saturating sperm concentrations. However, this inhibition was overcome by increasing the sperm density. Sperm concentrations (10⁶/ml) yielding 100% fertilization of control preparations resulted in only 72% insemination of Con A-treated ova (10⁴/ml). Although a cortical granule reaction occurred in fertilized, Con A-treated eggs, the distance the fertilization membrane separated from the zygote's surface was not as great as observed in controls. These results may be the basis for previous reports of Con A inhibiting fertilization in sea urchins.     

Identification of a secondary sperm receptor in the mouse egg zona pellucida: role in maintenance of binding of acrosome-reacted sperm to eggs

During fertilization in mice, acrosome-intact sperm bind via plasma membrane overlying their head to a glycoprotein, called ZP3, present in the egg extracellular coat or zona pellucida. Bound sperm then undergo the acrosome reaction, which results in exposure of inner acrosomal membrane, penetrate through the zona pellucida, and fuse with egg plasma membrane. Thus, in the normal course of events, acrosome-reacted sperm must remain bound to eggs, despite loss of plasma membrane from the anterior region of the head and exposure of inner acrosomal membrane. Here, we examined maintenance of binding of sperm to the zona pellucida following the acrosome reaction. We found that polyclonal antisera and monoclonal antibodies directed against ZP2, another zona pellucida glycoprotein, did not affect initial binding of sperm to eggs, but inhibited maintenance of binding of sperm that had undergone the acrosome reaction on the zona pellucida. On the other hand, polyclonal antisera and monoclonal antibodies directed against ZP3 did not affect either initial binding of acrosome-intact sperm to eggs or maintenance of binding following the acrosome reaction. We also found that soybean trypsin inhibitor, a protein reported to prevent binding of mouse sperm to eggs, did not affect initial binding of sperm to eggs, but, like antibodies directed against ZP2, inhibited maintenance of binding of sperm that had undergone the acrosome reaction on the zona pellucida. These and other observations suggest that ZP2 serves as a secondary receptor for sperm during the fertilization process in mice and that maintenance of binding of acrosome-reacted sperm to eggs may involve a sperm, trypsin-like proteinase.     

Assembly of the fluorescent acrosomal matrix and its fate in fertilization in the water strider,Aquarius remigis

Animal sperm show remarkable diversity in both morphology and molecular composition. Here we provide the first report of intense intrinsic fluorescence in an animal sperm. The sperm from a semi‐aquatic insect, the water strider, Aquarius remigis, contains an intrinsically fluorescent molecule with properties consistent with those of flavin adenine dinucleotide (FAD), which appears first in the acrosomal vesicle of round spermatids and persists in the acrosome throughout spermiogenesis. Fluorescence recovery after photobleaching reveals that the fluorescent molecule exhibits unrestricted mobility in the acrosomal vesicle of round spermatids but is completely immobile in the acrosome of mature sperm. Fluorescence polarization microscopy shows a net alignment of the fluorescent molecules in the acrosome of the mature sperm but not in the acrosomal vesicle of round spermatids. These results suggest that acrosomal molecules are rearranged in the elongating acrosome and FAD is incorporated into the acrosomal matrix during its formation. Further, we followed the fate of the acrosomal matrix in fertilization utilizing the intrinsic fluorescence. The fluorescent acrosomal matrix was observed inside the fertilized egg and remained structurally intact even after gastrulation started. This observation suggests that FAD is not released from the acrosomal matrix during the fertilization process or early development and supports an idea that FAD is involved in the formation of the acrosomal matrix. The intrinsic fluorescence of the A. remigis acrosome will be a useful marker for following spermatogenesis and fertilization. J. Cell. Physiol. 226: 999–1006, 2011. © 2010 Wiley‐Liss, Inc.     

Antibody to a sperm surface glycoprotein inhibits the egg jelly-induced acrosome reaction of sea urchin sperm

When the surface of sea urchin (Strongylocentrotus purpuratus) sperm is radioiodinated, 75% of the protein-incorporated radioactivity is associated with two glycoproteins of M_r 84,000 (84K) 64,000 (64K) (Lopo and Vacquier 1980). Antibodies were prepared against these two components by separating a Triton X-100 extract of sperm on SDS-polyacrylamide gels, cutting out the band containing the glycoprotein and injecting the homogenized gel into rabbits. Both anti-84K and anti-64K sera agglutinate sperm. Light and EM immunoperoxidase localization show both antigens are distributed over the entire sperm surface. By the immunoperoxidase technique there is some degree of cross-reactivity of both antisera with sperm of other Strongylocentrotus species, but not with those of other genera. Living sperm incubated with anti-84K Fab fragments are completely inhibited from undergoing the egg jelly-induced acrosome reaction and fertilizing eggs. Anti-64K Fab fragments have no effect on the ability of the sperm to undergo the acrosome reaction or fertilize eggs. Sperm incubated in anti-84K or anti-64K Fab fragments undergo the acrosome reaction in response to the Ca²⁺ ionophore A23187, or when the extracellular pH is increased to 9.2 with NH₄OH, indicating that the inhibition of the egg jelly-induced acrosome reaction results from the binding of the anti-84K Fab to an external molecule involved in the initiation or propagation of the acrosome reaction. The 84K glycoprotein is the first sperm surface component identified that might have a role in the induction of the acrosome reaction.     

A study of factors involved in induction of the acrosomal reaction in sperm of the sea urchin, Arbacia punctulata.

Several factors involved in induction of the acrosomal reaction in sperm of the sea urchin, Arbacia punctulata, have been investigated quantitatively using a simple substrate film technique to monitor extension of the acrosomal process by electron microscopy. Verification of typical acrosomal process formation has been accomplished using thin sections. Sperm were found to undergo the acrosomal reaction in artificial sea water in the absence of egg jelly coat at pH values above 9.6. In the presence of egg jelly a high percentage of sperm react at pH 8.6. At this pH, the fraction of sperm that undergo the acrosomal reaction is directly proportional to the concentration of egg jelly. The Ca²⁺ ionophore A23187 induces the acrosomal reaction in the absence of egg jelly at pH 8.6. The proportion of sperm that react is dependent on the concentration of ionophore and on the concentration of Ca²⁺ in the medium. Pretreatment of sperm with low levels of La³⁺ ion, which is known to be a Ca²⁺ ion antagonist, results in inhibition of egg jelly induction of the acrosomal reaction. These findings suggest that there are marked similarities between the acrosomal reaction in sea urchin sperm and membrane fusion dependent secretory processes in other cell types.     

A Model for the Acrosome Reaction in Mammalian Sperm

The acrosome reaction is a complex, calcium-dependent reaction that results in an exocytotic event required for successful fertilization of the egg. It has long been thought that the acrosome reaction occurs upon sperm binding to the zona pellucida, a viscoelastic layer surrounding the oocyte. Recent studies have suggested that the reaction may even occur before the sperm encounters the zona, perhaps mediated by progesterone or some other agonist. It has been particularly difficult to understand differences between progesterone-induced and zona-induced reactions experimentally and whether one substance is the more biologically relevant trigger. Until this present work, there has been little effort to mathematically model the acrosome reaction in sperm as a whole. Instead, attention has been paid to modeling portions of the pathways involved in other cell types. Here we present a base model for the acrosome reaction which characterizes the known biochemical reactions and behaviors of the system. Our model allows us to analyze several pathways that may act as a stabilizing mechanism for avoiding sustained oscillatory calcium responses often observed in other cell types. Such an oscillatory regime might otherwise prevent acrosomal exocytosis and therefore inhibit fertilization. Results indicate that the acrosome reaction may rely upon multiple redundant mechanisms to avoid entering an oscillatory state and instead maintain a high resting level of calcium, known to be required for successful acrosomal exocytosis and, ultimately, fertilization of the oocyte.     

Detection of acrosome-reacted toad sperm based on specific lectin binding to the inner acrosomal membrane

When the sperm of the toad Bufo japonicus were treated with fluorescein isothiocyanate (FITC)-conjugated peanut agglutinin (PNA), soybean agglutinin (SBA), or Dolichos biflorus agglutinin (DBA), a few sperm fluoresced at the acrosomal region. The number of sperm showing this lectin binding to the acrosome increased significantly upon mild sonication of the sperm suspension. Electron microscopy revealed that ferritin-conjugated PNA bind not to the outer acrosomal and overlying plasma membranes, but specifically to the surface of the inner acrosomal membrane exposed by sonication. Both the percentage of FITC-PNA-labeled sperm and the activity of vitelline coat lysin released by sperm increased in good correlation with increasing sonication time, although the PNA-labeled sperm decreased in number upon longer sonication. These results indicate that the binding of FITC-PNA to the sperm provides a reliable measure of the acrosome reaction of Bufo sperm.     

Equatorin is not essential for acrosome biogenesis but is required for the acrosome reaction

The acrosome is a specialized organelle that covers the anterior part of the sperm nucleus and plays an essential role in mammalian fertilization. However, the regulatory mechanisms controlling acrosome biogenesis and acrosome exocytosis during fertilization are largely unknown. Equatorin (Eqtn) is a membrane protein that is specifically localized to the acrosomal membrane. In the present study, the physiological functions of Eqtn were investigated using a gene knockout mouse model. We found that Eqtn^−/− males were subfertile. Only approximately 50% of plugged females were pregnant after mating with Eqtn^−/− males, whereas more than 90% of plugged females were pregnant after mating with control males. Sperm and acrosomes from Eqtn^−/− mice presented normal motility and morphology. However, the fertilization and induced acrosome exocytosis rates of Eqtn-deficient sperm were dramatically reduced. Further studies revealed that the Eqtn protein might interact with Syntaxin1a and SNAP25, but loss of Eqtn did not affect the protein levels of these genes. Therefore, our study demonstrates that Eqtn is not essential for acrosome biogenesis but is required for the acrosome reaction. Eqtn is involved in the fusion of the outer acrosomal membrane and the sperm plasma membrane during the acrosome reaction, most likely via an interaction with the SNARE complex.     

Autoradiographic visualization of the mouse egg's sperm receptor bound to sperm

The extracellular coat, or zona pellucida, of mammalian eggs contains species-specific receptors to which sperm bind as a prelude to fertilization. In mice, ZP3, one of only three zona pellucida glycoproteins, serves as sperm receptor. Acrosome-intact, but not acrosome-reacted, mouse sperm recognize and interact with specific O- linked oligosaccharides of ZP3 resulting in sperm-egg binding. Binding, in turn, causes sperm to undergo the acrosome reaction; a membrane fusion event that results in loss of plasma membrane at the anterior region of the head and exposure of inner acrosomal membrane with its associated acrosomal contents. Bound, acrosome-reacted sperm are able to penetrate the zona pellucida and fuse with the egg's plasma membrane (fertilization). In the present report, we examined binding of radioiodinated, purified, egg ZP3 to both acrosome intact and acrosome reacted sperm by whole-mount autoradiography. Silver grains due to bound 125I-ZP3 were found localized to the acrosomal cap region of heads of acrosome-reacted sperm. Under the same conditions, 125I-fetuin bound at only bacKground levels to heads of both acrosome-intact and - reacted sperm, and 125I-ZP2, another zona pellucida glycoprotein, bound preferentially to acrosome-reacted sperm. These results provide visual evidence that ZP3 binds preferentially and specifically to heads of acrosome intact sperm; properties expected of the mouse egg's sperm receptor.     

How Pig Sperm Prepares to Fertilize: Stable Acrosome Docking to the Plasma Membrane

Background

Mammalian sperms are activated in the oviduct. This process, which involves extensive sperm surface remodelling, is required for fertilization and can be mimicked under in vitro fertilization conditions (IVF).

Methodology/Principal Findings

Here we demonstrate that such treatments caused stable docking and priming of the acrosome membrane to the apical sperm head surface without the emergence of exocytotic membrane fusion. The interacting membranes could be isolated as bilamellar membrane structures after cell disruption. These membrane structures as well as whole capacitated sperm contained stable ternary trans-SNARE complexes that were composed of VAMP 3 and syntaxin 1B from the plasma membrane and SNAP 23 from the acrosomal membrane. This trans-SNARE complex was not observed in control sperm.

Conclusions/Significance

We propose that this capacitation driven membrane docking and stability thereof is a preparative step prior to the multipoint membrane fusions characteristic for the acrosome reaction induced by sperm-zona binding. Thus, sperm can be considered a valuable model for studying exocytosis.     

THE FERTILIZING CAPACITY OF SEA URCHIN SPERM RAPIDLY DECREASES AFTER INDUCTION OF THE ACROSOME REACTION*

When immotile, flagella-less sperm were added to acid-dejellied eggs of Strongylocentrotus purpuratus 11% of the eggs fertilized. Addition of soluble egg jelly increased the percentage fertilization to 90.5. Over 50% of the sperm exposed to egg jelly had undergone the acrosome reaction compared to only 3–5% in the absence of jelly. Egg jelly was added to flagella-less sperm to induce the acrosome reaction and dejellied eggs added at various times thereafter. The fertilizing capacity of the sperm decreased with first order kinetics with 50% loss by 23 sec after induction of the acrosome reaction. Intact, motile sperm bind to formaldehyde-fixed eggs with maximum binding occurring 40 sec after sperm addition. After 40 sec the sperm begin to detach from the fixed eggs and by 240 sec none remain attached. Sperm detachment from fixed eggs and loss of fertilizing capacity after the acrosome reaction show a close temporal correlation.     

A synthetic decapeptide from a conserved ZP3 protein domain induces the G protein-regulated acrosome reaction in bovine spermatozoa

In some animal species, the zona pellucida protein 3 (ZP3) plays a central role during fertilization, functioning as a specific receptor for sperm and as an inducer of the acrosome reaction. On the other hand, the zona pellucida protein 2 (ZP2) acts as a secondary receptor, binding to acrosome-reacted sperm. The objective of these studies was to identify ZP2 and ZP3 domains that may be of importance for the induction of the acrosome reaction. For this purpose, we synthesized a number of ZP2 and ZP3 peptides that were either conserved among species or that were species-specific according to their respective primary structures. We identified a defined, conserved ZP3 decapeptide (ZP3-6 peptide) that bound to the surface of the acrosomal region and induced the acrosome reaction in a concentration-dependent manner in capacitated bovine sperm; this effect was significant in the nanomolar range. Pertussis toxin inhibited the ZP3-6 peptide-induced acrosome reaction but had no effect on the progesterone-induced exocytotic event. Our data are in accordance with previous studies showing that progesterone induces acrosomal exocytosis via a different pathway than ZP3 and strengthen the hypothesis that the effect of ZP3-6 peptide upon acrosomal exocytosis is G protein regulated. Despite the commonly accepted idea that glycosylation of ZP proteins is required for successful sperm-oocyte interaction, we found that acrosomal exocytosis can be induced by a synthetic ZP3 peptide that is not glycosylated. The results presented in this study may be useful for the investigation of the molecular mechanisms of sperm-egg interaction in bovine and other species.