A fucosyl glycoprotein component with sperm receptor and sperm-activating activities from the vitelline coat of ciona intestinalis eggs

In this paper we describe a mild procedure which results in the extraction of a glycoprotein fraction from the vitelline coat (VC) of Ciona intestinalis while leaving behind the bulk of the VC components. When acting upon the spermatozoa this fraction inhibits sperm binding to the VC and fertilization and elicits sperm activation including the acrosome reaction. SDS-PAGE shows that it contains the same (fucosyl) glycoprotein components previously recognized in the total extracts of VC. It is suggested that this material contains the sperm receptors or those components of the receptors that are essential for their Chinese function.     

Evidence for a cannabinoid receptor in sea urchin sperm and its role in blockade of the acrosome reaction

Delta-9-tetrahydrocannabinol ((?)δ⁹ THC), the primary psychoactive cannabinoid in marihuana, reduces the fertilizing capacity of sea urchin sperm by blocking the acrosome reaction that normally is stimulated by a specific ligand in the egg's jelly coat. The bicyclic synthetic cannabinoid [ H]CP-55,940 has been used as a ligand to demonstrate the presence of a cannabinoid receptor in mammalian brain. We now report that [ H]CP-55,940 binds to live sea urchin (Strongylocentrotus purpuratus) sperm in a concentration, sperm density, and time-dependent manner. Specific binding of [ H]CP-55,940 to sperm, defined as total binding displaced by (?)δ⁹ THC, was saturable: K_D 5.16 ± 1.02 nM; Hill coefficient 0.98 ± 0.004. This suggests a single class of receptor sites and the absence of significant cooperative interactions. Sea urchin sperm contain 712 ± 122 cannabinoid receptors per cell. Binding of [ H]CP-55,940 to sperm was reduced in a dose-dependent manner by increasing concentrations of CP-55,940, (?)δ⁹ THC, and (+)δ⁹ THC. The rank order of potency to inhibit binding of [ H]CP-55,940 to sperm and to block the egg jelly stimulated acrosome reaction was: CP-55,940 > (?)δ⁹THC > (+)δ⁹THC. These findings show that sea urchin sperm contain a stereospecific cannabinoid receptor that may play a role in inhibition of the acrosome reaction. The radioligand binding data obtained with live sea urchin sperm are remarkably similar to those previously published by other investigators using [ H]CP-55,940 on mammalian brain and nonneural tissues. The cannabinoid binding properties of this receptor appear to have been highly conserved during evolution. We postulate that the cannabinoid receptor may modulate cellular responses to stimulation. © 1993 Wiley-Liss, Inc.     

Jelly coat and induction of the acrosome reaction in echinoid sperm

In a previous study we established that sperm from four species of echinoids differ in their specificity for induction of the acrosome reaction by heterotypic jelly coat and we presented evidence that there were only small compositional differences in the active component of the jelly coat, a polysaccharide composed of fucose sulfate units. In the current report we present additional studies related to the species specificity of jelly coat with respect to Ca²⁺ uptake (or exchange), which occurs concomitantly with the acrosome reaction, and activation of phospholipase activity, which appears to occur subsequent to the acrosome reaction. The specificity of jelly coat in inducing these processes is the same as that previously observed in induction of the acrosome reaction. Binding of jelly coat to sperm has been demonstrated, and has been shown to be species specific. This finding raises the possibility that a receptor for jelly coat exists on the surface of the sperm. Finally, based on chemical and physical-chemical studies, evidence is presented that establishes that, despite compositional similarities, the fucose sulfate polysaccharides from the four species of eggs differ in structure.     

Purification and immunocytochemical localization of the vitelline coat lysin of abalone spermatozoa

Spermatozoa of the abalone Haliotis discus were treated with high-calcium seawater to induce the acrosome reaction. The soluble components released from the sperm acrosomal vesicles showed potent lytic activity on the egg vitelline coat. A vitelline coat lysin was purified by salting-in, preparative polyacrylamide gel electrophoresis, and high-performance liquid chromatography. Its molecular weight was 15,500 and its isoelectric point 9.6. These properties were similar to those of other molluskan vitelline coat lysins. The lysin was immunocytochemically localized using a protein A-gold technique, in the posterior half of the acrosomal vesicle.     

Egg jelly of the newt, Cynops pyrrhogaster contains a factor essential for sperm binding to the vitelline envelope

The acrosome reaction of newt sperm is induced at the surface of egg jelly and the acrosome-reacted sperm acquire the ability to bind to the vitelline envelope. However, because the substance that induces the acrosome reaction has not been identified, the mechanism by which the acrosome-reacted sperm bind to the vitelline envelope remains unclear. We found here that a Dolichos biforus agglutinin (DBA) specifically mimicked the acrosome reaction immediately upon its addition in the presence of milimolar level Ca(2+). Fluorescein isothiocyanate-labeled DBA bound specifically to the acrosomal cap of the intact sperm in the presence of a Ca(2+)-chelating agent, EDTA, suggesting that binding of DBA to the native receptor for the egg jelly substance on the acrosomal region took the place of the egg jelly substance-induced acrosome reaction. In contrast, the sperm that had been acrosome reacted by DBA treatment did not bind to the vitelline envelope of the egg whose jelly layers were removed. Subsequent addition of jelly extract caused the sperm binding to vitelline envelope, indicating that the egg jelly of the newt contains substances that are involved in not only inducing the acrosome reaction but also binding to the vitelline envelope. This is the first demonstration of the involvement of egg jelly substance in the binding of acrosome-reacted sperm to the vitelline envelope.     

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.     

Ascidian sperm lysin system

Fertilization is a precisely controlled process involving many gamete molecules in sperm binding to and penetration through the extracellular matrix of the egg. After sperm bind to the extracellular matrix (vitelline coat), they undergo the acrosome reaction which exposes and partially releases a lytic agent called "lysin" to digest the vitelline coat for the sperm penetration. The vitelline coat sperm lysin is generally a protease in deuterostomes. The molecular mechanism of the actual degradation of the vitelline coat, however, remains poorly understood. In order to understand the lysin system, we have been studying the fertilization mechanism in ascidians (Urochordata) because we can obtain large quantities of gametes which are readily fertilized in the laboratory. Whereas ascidians are hermaphrodites, which release sperm and eggs simultaneously, many ascidians, including Halocynthia roretzi, are strictly self-sterile. Therefore, after sperm recognize the vitelline coat as nonself, the sperm lysin system is thought to be activated. We revealed that two sperm trypsin-like proteases, acrosin and spermosin, the latter of which is a novel sperm protease with thrombin-like substrate specificity, are essential for fertilization in H. roretzi. These molecules contain motifs involved in binding to the vitelline coat. We found that the proteasome rather than trypsin-like proteases has a direct lytic activity toward the vitelline coat. The target for the ascidian lysin was found to be a 70-kDa vitelline coat component called HrVC70, which is made up of 12 EGF-like repeats. In addition to the proteasome system, the ubiquitination system toward the HrVC70 was found to be necessary for ascidian fertilization. In this review, I describe recent progress on the structures and roles in fertilization of the two trypsin-like proteases, acrosin and spermosin, and also on the novel extracellular ubiquitin-proteasome system, which plays an essential role in the degradation of the ascidian vitelline coat.     

The Parkes Lecture. Zona pellucida glycoprotein mZP3: a versatile player during mammalian fertilization

All mammalian eggs are surrounded by a relatively thick extracellular coat, the zona pellucida (ZP), which facilitates fertilization of eggs by a single spermatozoon. The mouse egg ZP is constructed of only three glycoproteins, termed mZP1-3. Each of these glycoproteins consists of a unique polypeptide that is heterogeneously glycosylated with both asparagine-(N-)linked and serine/threonine-(O-)linked oligosaccharides. Polypeptides of ZP glycoproteins are highly conserved among mammalian species and are similar to polypeptides of egg vitelline envelope glycoproteins of fish, birds and amphibians. One of the mouse ZP glycoproteins, mZP3, serves as both a receptor for spermatozoa and an inducer of the acrosome reaction during fertilization. Free-swimming acrosome-intact spermatozoa recognize and bind to certain serine-(O-)linked oligosaccharides located close to the carboxy terminus of mZP3 polypeptide and, after binding, undergo the acrosome reaction (cellular exocytosis). In this review, in addition to the background information presented, results of recent experiments using homologous recombination to produce mZP3 null mice and site-directed mutagenesis to inactivate mZP3 as a sperm receptor and inducer of the acrosome reaction are presented and discussed.     

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.     

Physiological inducers of the acrosome reaction

This article reviews recent studies on physiological inducers of the acrosome reaction in starfish. Upon encountering the jelly coat of eggs, starfish sperm undergo the acrosome reaction in response to a cooperation of three jelly components: a sulfated glycoprotein named acrosome reaction-inducing substance (ARIS), a group of steroidal saponins named Co-ARIS, and an oligopeptide presumably having an activity to increase the intracellular pH of sperm. ARIS induces the acrosome reaction in high Ca²⁺ or high pH sea water. In normal sea water, both ARIS and Co-ARIS are required for the induction. In addition to ARIS and Co-ARIS, a third jelly component, the oligopeptide, is necessary to mimic the full capacity of the jelly coat to induce the acrosome reaction. ARIS and Co-ARIS cooperatively increase the intracellular Ca²⁺ by stimulating Ca²⁺ channels, while the oligopeptide increases the intracellular pH by stimulating Na⁺/H⁺ exchange systems. When sperm meet the eggs, both changes are simultaneously achieved in them and thus they undergo the acrosome reaction.     

Enzymatic dissection of the functions of the mouse egg's receptor for sperm

During the course of sperm-egg interaction in mice, zona pellucida glycoprotein ZP3 (approximately equal to 80 kDa) serves as both receptor for sperm (J. D. Bleil and P. M. Wassarman, 1980c, Cell 20, 873-882) and inducer of the acrosome reaction (J. D. Bleil and P. M. Wassarman, 1983, Dev. Biol. 95, 317-324). In this investigation, small ZP3 glycopeptides (approximately equal to 1.5-6 kDa), obtained by extensive digestion of the purified glycoprotein with insoluble Pronase, were assayed for both sperm receptor and acrosome reaction-inducing activities. While ZP3 glycopeptides were virtually as effective as intact ZP3 in inhibiting binding of sperm to eggs in vitro ("receptor activity"), unlike intact ZP3, they failed to induce sperm to undergo the acrosome reaction. The latter was determined by indirect immunofluorescence using a monoclonal antibody directed against the acrosomal cap region of sperm. These results suggest that the sperm receptor activity of ZP3 is dependent only on its carbohydrate components, whereas acrosome reaction-inducing activity is dependent on the polypeptide chain of ZP3 as well.     

The Interactions of Sea Urchin Gametes During Fertilization

The interactions between sea urchin spermatozoa and ova duringfertilization usually exhibit a high degree of species specificity.Under natural conditions and reasonable gamete concentrations,most interspecific inseminations fail to yield zygotes. Macromoleculeson the external surfaces of the apposing gametes must surelybe responsible for successful gamete recognition, adhesion andfusion. Species specific recognition between surface componentsof sperm and egg could occur during at least three events comprisingthe fertilization process. The first event is the interactionof the sperm plasma membrane with the egg jelly coat. This inducesthe sperm acrosome reaction resulting in the exocytosis of the"bindin" -containing acrosome granule and also the extrusionof the acrosome process from the anterior tip of the sperm.The second event is the adhesion of the bindin-coated acrosomeprocess to glycoprotein "bindin receptors" on the external surfaceof the egg vitelline layer. The third event is the penetrationof the vitelline layer and the fusion of sperm and egg plasmamembranes. With the isolations of the component of egg jellywhich induces the acrosome reaction, sperm bindin from the acrosomevesicle and the egg surface bindin receptor from the vitellinelayer, there is hope of discovering the molecular basis of thismost interesting intercellular interaction which results inthe activation of embryonic development.     

Effects of protease inhibitors on sperm-related events in sea urchin fertilization

Evidence for sperm-borne proteolytic enzymes exposed during the acrosome reaction in sea urchin sperm has been accumulating. To investigate the possible role(s) such enzymes have in fertilization, we studied the effects of several protease inhibitors on sperm-related events. Soybean trypsin inhibitor, Nα-p-tosyl-l-lysine, chloromethyl ketone, phenylmethylsulfonyl fluoride, and chymostatin neither reduced the number of acrosome reactions nor interfered with gamete binding. p-Nitrophenyl-p′-guanidinobenzoate caused sperm to fuse into irregular clumps, rendering them unable to fertilize eggs. However, l-1-tosylamide-2-phenylethyl chloromethyl ketone (TPCK), an inhibitor of chymotrypsin, prevented the acrosome reaction in Strongylocentrotus purpuratus, S. droebachiensis, and Lytechinus pictus. The effects of TPCK on sperm in subsequent steps of fertilization were also investigated. First, gamete binding assays were performed on fixed eggs. This precluded any effects TPCK might have had on egg-derived secretions (e.g., proteases). Binding of prereacted sperm occurred with both fixed and living eggs. However, fertilization of living eggs in the presence of TPCK was greatly reduced, even though sperm had been prereacted with egg jelly. Vitelline coats were then removed from eggs by trypsin treatment. Eggs in TPCK fertilized and developed normally after the above treatment. These observations are consistent with the hypothesis of a sperm protease participating in the acrosome reaction and the penetration of the egg vitelline coat in the sea urchin.     

Mammalian zona pellucida glycoproteins: structure and function during fertilization

Zona pellucida (ZP) is a glycoproteinaceous translucent matrix that surrounds the mammalian oocyte and plays a critical role in the accomplishment of fertilization. In humans, it is composed of 4 glycoproteins designated as ZP1, ZP2, ZP3 and ZP4, whereas mouse ZP is composed of ZP1, ZP2 and ZP3 (Zp4 being a pseudogene). In addition to a variable sequence identity of a given zona protein among various species, human ZP1 and ZP4 are paralogs and mature polypeptide chains share an identity of 47%. Employing either affinity purified native or recombinant human zona proteins, it has been demonstrated that ZP1, ZP3 and ZP4 bind to the capacitated human spermatozoa and induce an acrosome reaction, whereas in mice, ZP3 acts as the putative primary sperm receptor. Human ZP2 only binds to acrosome-reacted spermatozoa and thus may be acting as a secondary sperm receptor. In contrast to O-linked glycans of ZP3 in mice, N-linked glycans of human ZP3 and ZP4 are more relevant for induction of the acrosome reaction. Recent studies suggest that Sialyl-Lewis^x sequence present on both N- and O-glycans of human ZP play an important role in human sperm?Cegg binding. There are subtle differences in the downstream signaling events associated with ZP3 versus ZP1/ZP4-mediated induction of the acrosome reaction. For example, ZP3 but not ZP1/ZP4-mediated induction of the acrosome reaction is dependent on the activation of the G_i protein-coupled receptor. Thus, various studies suggest that, in contrast to mice, in humans more than one zona protein binds to spermatozoa and induces an acrosome reaction.     

Sperm–egg binding: Identification of a species-specific sperm receptor from eggs of strongylocentrotus purpuratus

We have attempted to identify a surface component of echinoderm eggs that is involved in the species-specific binding of sperm. Cell surface membranes from eggs of the sea urchins Strongylocentrotus purpuratus or Arbacia punctulata were radioiodinated, detergent-treated, and subjected to density-gradient centrifugation. In the presence of bindin, the complementary binding protein isolated from sperm, one component of the membranes sedimented to a different density. This membrane component bound-species specifically to sperm that had undergone the acrosome reaction. This binding led to an inhibition of the ability of treated sperm to fertilize eggs. Exhaustive proteolytic digestion of this receptor fraction yields a high molecular weight glycopeptide that can also bind to bindin. It therefore appears that this egg surface membrane fraction contains a functionally intact, species-specific receptor for sperm.     

Mammalian sperm acrosome: formation, contents, and function

Sperm-egg interaction is a carbohydrate-mediated species-specific event which initiates a signal transduction cascade resulting in the exocytosis of sperm acrosomal contents (i.e., the acrosome reaction). This step is believed to be a prerequisite which enables the acrosome-reacted spermatozoa to penetrate the zona pellucida (ZP) and fertilize the egg. Successful fertilization in the mouse and several other species, including man, involves several sequential steps. These are (1) sperm capacitation in the female genital tract; (2) binding of capacitated spermatozoa to the egg's extracellular coat, the ZP; (3) induction of acrosome reaction (i.e., sperm activation); (4) penetration of the ZP; and (5) fusion of spermatozoon with the egg vitelline membrane. This minireview focuses on the most important aspects of the sperm acrosome, from its formation during sperm development in the testis (spermatogenesis) to its modification in the epididymis and function following sperm-egg interaction. Special emphasis has been given to spermatogenesis, a complex process involving multiple molecular events during mitotic cell division, meiosis, and the process of spermiogenesis. The last event is the final phase when a nondividing round spermatid is transformed into the complex structure of the spermatozoon containing a well-developed acrosome. Our intention is also to briefly discuss the functional significance of the contents of the sperm acrosome during fertilization. It is important to mention that only the carbohydrate-recognizing receptor molecules (glycohydrolases, glycosyltransferases, and/or lectin-like molecules) present on the surface of capacitated spermatozoa are capable of binding to their complementary glycan chains on the ZP. The species-specific binding event starts a calcium-dependent signal transduction pathway resulting in sperm activation. The hydrolytic and proteolytic enzymes released at the site of sperm-zona interaction along with the enhanced thrust of the hyperactivated beat pattern of the bound spermatozoon, are important factors in regulating the penetration of the zona-intact egg.     

Sperm-egg interaction in the painted frog (Discoglossus pictus): An ultrastructural study

The ultrastructure of sperm changes and penetration in the egg was studied in the anuran Discoglossus pictus, whose sperm have an acrosome cap with a typical tip, the apical rod. The first stage of the sperm apical rod and acrosome reaction (AR) consists in vesiculation between the plasma membrane and the outer acrosome membrane. The two components of the acrosome cap are released in sequence. The innermost component (component B) is dispersed first. The next acrosome change is the dispersal of the outermost acrosome content (component A). At 30 sec postinsemination, when the loss of component B is first observed, holes are seen in the innermost jelly coat (J1), surrounding the penetrating sperm. Therefore, this acrosome constituent might be related to penetration through the innermost egg investments. At 1 min postinsemination, during sperm penetration into the egg, a halo of finely granular material is observed around the inner acrosome membrane of the spermatozoon, suggesting a role for component A at this stage of penetration. Gamete-binding and fusion take place between D1 (the egg-specific site for sperm interaction) and the perpendicularly oriented sperm. Spermatozoa visualized at their initial interaction (15 sec postinsemination) with the oolemma are undergoing vesiculation. The first interaction is likely to occur between the D1 glycocalyx and the plasma membrane of the hybrid vesicles surrounding the apical rod. As fusion is observed between the internal acrosome membrane and the oolemma, it can be postulated that gametic interaction might be followed by fusion of the latter with the apical rod internal membrane that extends posteriorly into the inner acrosome membrane. Insemination of the outermost jelly layer (J3) dissected out of the egg, and observations of the ultrastructural changes of spermatozoa in this coat, indicate that J3 rather than the vitelline coat (VC) induces the AR. Interestingly, at the late postinsemination stage, VC fibrils are seen crosslinking the inner acrosome membrane. The role of this binding is here discussed. Mol. Reprod. Dev. 47:323–333, 1997. © 1997 Wiley-Liss, Inc.     

Immunological evidence that a 305-kilodalton vitelline envelope polypeptide isolated from sea urchin eggs is a sperm receptor

Direct isolation of the sea urchin egg vitelline envelope with intact sperm receptors is difficult because the envelope is firmly attached to the egg plasma membrane. We now report a method for producing an inseminated egg preparation in Strongylocentrotus purpuratus (using soybean trypsin inhibitor [STI] and Ca²⁺, Mg²⁺-free seawater) that contains an elevated vitelline envelope (VE*-STI). The VE*-STI is devoid of cortical granule material, and supernumerary sperm do not detach postinsemination, suggesting that the VE*-STI contains active sperm receptors. VE*-STIs contain a 305-kD polypeptide and additional components that range from 225 to 31 kD, whereas the 305-kD polypeptide was considerably reduced in VE*s. Electrophoresis of sperm receptor hydrolase digests of VE*-STIs showed that the 305-kD polypeptide and several other envelope polypeptides are protease substrates. Univalent Fab fragments against VE*s, VE*-STIs, and 305 and 225-kD polypeptides blocked sperm binding and fertilization in an Fab concentration-dependent manner. The 305 and 225-kD polypeptides were localized in the VE*-STI using indirect immunofluorescence. Enzyme-linked immunosorbent assays showed that the 305 and 225-kD polypeptides share determinants, suggesting that the 225-kD polypeptide may be derived from the 305-kD polypeptide by the proteolysis that occurs at the cell surface during fertilization. Fab fragments against S purpuratus VE*-STI antigens neither bound to nor blocked homologous sperm binding and fertilization of Lytechinus variegatus eggs. Cross fertilizability occurred to the extent of 5% or less between L variegatus and S purpuratus, therefore, we conclude that the 305 kD-polypeptide isolated from S purpuratus is a species-specific vitelline envelope sperm receptor.     

Acrosome reaction in sperm of the toad,bufo bufo japonicus

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

Classification,inhibition, and specificity studies of the vitelline coat lysin from toad sperm

The sonicated supernatant of the sperm of the toad, Bufo japonicus, can digest easily the vitelline coat (VC) of uterine eggs, and to a lesser extent the VC of coelomic eggs, but not that of activated eggs. The VC lysis and fertilization were competitively inhibited in the presence of t-butyloxycarbonyl-L-Gln-L-Arg-L-Arg-4-methylcoumaryl-7-amide (Boc-Gln-Arg-Arg-MCA), suggesting the involvement of proteases in the fertilization process. Starting from a sonicated supernatant, a potent VC lysin, possessing hydrolytic activity on Boc-Gln-Arg-Arg-MCA, was obtained by anion-exchange chromatography and gel filtration. The activity of the partially purified lysin was inhibited by diisopropyl fluorophosphate (DFP) and by such trypsin inhibitors as soybean trypsin inhibitor, leupeptin, and (p-amidinophenyl) methanesulfonyl fluoride hydrochloride, but not by chymostatin, E-64, and ethylene glycol bis(β-aminoethyl ether)-N,N,N′,N′-tetraacetic acid. The molecular weight of the lysin was estimated to be 32K, based on the fluorographic image of ³H-DFP binding to the lysin on sodium dodecyl sulfate gel electrophoresis. The VC lysin was most active at pH 7.0–7.6 and under low ionic strength equivalent to fresh water. The release of the VC lysin was induced upon incubation of sperm with the contents of oviducal pars recta granules (PRG), which are known to induce the acrosome reaction. We conclude that the protease studied here represents the VC lysin of toad sperm that is involved in fertilization by digesting the VC of uterine eggs, probably released as a result of the acrosome reaction induced by PRG.