Mammalian fertilization: the strange case of sperm protein 56

During mammalian fertilization sperm bind to the egg's zona pellucida (ZP) after undergoing capacitation. Capacitated mouse sperm bind to mZP3 (one of three ZP glycoproteins), undergo the acrosome reaction, penetrate the ZP, and fuse with egg plasma membrane. Sperm protein 56 (sp56), a member of the C3/C4 superfamily of binding proteins, was identified nearly 20 years ago as a binding partner for mZP3 by photoaffinity cross‐linking of acrosome‐intact sperm. However, subsequent research revealed that sp56 is a component of the sperm's acrosomal matrix and, for sperm with an intact acrosome, should be unavailable for binding to mZP3. Recently, this dilemma was resolved when it was recognized that some acrosomal matrix (AM) proteins, including sp56, are released to the sperm surface during capacitation. This may explain why uncapacitated mammalian sperm are unable to bind to the unfertilized egg ZP.     

Activation of a G protein in mouse sperm by the zona pellucida,an egg-associated extracellular matrix

Mammalian sperm possess a guanine nucleotide-binding regulatory protein (G protein), with properties similar to G_i, that appears to be involved in the signal transduction pathway required for zona pellucida (ZP)-mediated acrosomal exocytosis. Mouse sperm treated with pertussis toxin (PT), a toxin that functionally inactivates G_i proteins, bind to the ZP of mouse eggs but are inhibited from undergoing acrosomal exocytosis. We have measured high-affinity GTPase activity and GTPγ[³⁵S] binding in mouse sperm homogenates incubated in the absence and presence of ZP glycoproteins isolated from either ovulated eggs or from ovarian homogenates to determine whether this extracellular matrix can activate the sperm-associated G_i protein. An increase in GTP hydrolysis (～50% over basal activity) and GTPγ[³⁵S] binding (～25–60% over basal activity) is observed when sperm homogenates are incubated in the presence of solubilized ZP glycoproteins, and the increase in GTPase activity is dependent on the concentration of ZP added to the homogenates. Accompanying this increase is a reduction in the ability of PT to catalyze in vitro [³²P]ADP-ribosylation of a M_r = 41,000 sperm G_i protein, suggesting that the increase in GTPase activity and GTPγ[³⁵S] binding is associated with the activation of a PT-sensitive sperm G protein(s). The ability of the ZP to stimulate high-affinity GTPase activity in these homogenates appears to be dependent on the capacitation state of the sperm from which the homogenates are prepared. These data suggest that a component(s) of the ZP may function in a manner similar to that of other ligands by binding to a sperm surface-associated receptor and subsequently activating a G protein coupled to an intracellular signal transduction cascade(s) required for induction of acrosomal exocytosis.     

Signal transduction pathways that regulate sperm capacitation and the acrosome reaction

Ejaculated spermatozoa must undergo physiological priming as they traverse the female reproductive tract before they can bind to the egg’s extracellular coat, the zona pellucida (ZP), undergo the acrosome reaction, and fertilize the egg. The preparatory changes are the net result of a series of biochemical and functional modifications collectively referred to as capacitation. Accumulated evidence suggests that the event that initiates capacitation is the efflux of cholesterol from the sperm plasma membrane (PM). The efflux increases permeability and fluidity of the sperm PM and causes influx of Ca²⁺ ions that starts a signaling cascade and result in sperm capacitation. The binding of capacitated spermatozoa to ZP further elevates intrasperm Ca²⁺ and starts a new signaling cascade which open up Ca²⁺ channels in the sperm PM and outer acrosomal membrane (OAM) and cause the sperm to undergo acrosomal exocytosis. The hydrolytic action of the acrosomal enzymes released at the site of sperm-egg (zona) binding, along with the hyperactivated beat pattern of the bound spermatozoon, are important factors in directing the sperm to penetrate the ZP and fertilize the egg. The role of Ca²⁺-signaling in sperm capacitation and induction of the acrosome reaction (acrosomal exocytosis) has been of wide interest. However, the precise mechanism(s) of its action remains elusive. In this article, we intend to highlight data from this and other laboratories on Ca²⁺ signaling cascades that regulate sperm functions.     

95 kd sperm proteins bind ZP3 and serve as tyrosine kinase substrates in response to zona binding

In the mouse, the zona pellucida (ZP) glycoprotein ZP3 both binds intact sperm and induces acrosomal exocytosis. The subsequent signaling pathway(s) is still uncertain, but Gi-like proteins have been implicated. By analogy with other signal transduction mechanisms, we examined anti-phosphotyrosine antibody reactivity in mouse sperm. Antibodies reacted with three proteins of 52, 75, and 95 kd. Indirect immunofluorescence localized reactivity to the acrosomal region of the sperm head. The 52 kd and 75 kd phosphoproteins are detected only in capacitated sperm, whereas the 95 kd protein is detected in both fresh and capacitated sperm. For the 95 kd protein, the level of immunoreactivity is not related to sperm motility but is enhanced by both capacitation and sperm interaction with solubilized ZP proteins. In addition, binding of radiolabeled whole ZP or purified ZP3 to blots of separated sperm proteins identified two ZP binding proteins of 95 kd and 42 kd. 95 kd sperm proteins that bind to ZP3 also react with anti-phosphotyrosine antibodies (in a ZP concentration-dependent manner), supporting the idea that the same 95 kd sperm protein serves as a ZP3 receptor and as a tyrosine kinase substrate. These findings and our evidence on acrosome reaction triggering via sperm receptor aggregation suggest that a 95 kd protein in the sperm plasma membrane is aggregated by ZP3, which stimulates tyrosine kinase activity leading to acrosomal exocytosis.     

The Biological and Functional Significance of the Sperm Acrosome and Acrosomal Enzymes in Mammalian Fertilization

The mammalian spermatozoon undergoes continuous modifications during spermatogenesis, maturation in the epididymis, and capacitation in the female reproductive tract. Only the capacitated spermatozoa are capable of binding the zona-intact egg and undergoing the acrosome reaction. The fertilization process is a net result of multiple molecular events which enable ejaculated spermatozoa to recognize and bind to the egg's extracellular coat, the zona pellucida (ZP). Sperm–egg interaction is a species-specific event which is initiated by the recognition and binding of complementary molecule(s) present on sperm plasma membrane (receptor) and the surface of the ZP (ligand). This is a carbohydrate-mediated event which initiates a signal transduction cascade resulting in the exocytosis of acrosomal contents. This step is believed to be a prerequisite which enables the acrosome reacted spermatozoa to penetrate the ZP and fertilize the egg. This review focuses on the formation and contents of the sperm acrosome as well as the mechanisms underlying the induction of the acrosome reaction. Special emphasis has been laid on the synthesis, processing, substrate specificity, and mechanism of action of the acid glycohydrolases present within the acrosome. The hydrolytic action of glycohydrolases and proteases released at the site of sperm-zona binding, along with the enhanced thrust generated by the hyperactivated beat pattern of the bound spermatozoon, are important factors regulating the penetration of ZP. We have discussed the most recent studies which have attempted to explain signal transduction pathways leading to the acrosomal exocytosis.     

Regulation of sperm motility by PIP2(4,5) and actin polymerization

Actin polymerization and development of hyperactivated (HA) motility are two processes that take place during sperm capacitation. In previous studies, we demonstrated that the increase in F-actin during capacitation depends upon inactivation of the actin severing protein, gelsolin, by its binding to phosphatydilinositol-4, 5-bisphosphate (PIP₂). Here, we showed for the first time the involvement of PIP₂/gelsolin in human sperm motility before and during capacitation. Activation of gelsolin by causing its release from PIP₂ inhibited sperm motility, which could be restored by adding PIP₂ to the cells. Reduction of PIP₂ synthesis inhibited actin polymerization and motility, and increasing PIP₂ synthesis enhanced these activities. Furthermore, sperm demonstrating low motility contained low levels of PIP₂ and F-actin. During capacitation there was an increase in PIP₂ and F-actin levels in the sperm head and a decrease in the tail. In sperm with high motility, gelsolin was mainly localized to the sperm head before capacitation, whereas in low motility sperm, most of the gelsolin was localized to the tail before capacitation and translocated to the head during capacitation. We also showed that phosphorylation of gelsolin on tyrosine-438 depends on its binding to PIP₂. Activation of phospholipase C by Ca²⁺-ionophore or by activating the epidermal-growth-factor-receptor inhibits tyrosine phosphorylation of gelsolin. In conclusion, the data indicate that the increase of PIP₂ and/or F-actin in the head during capacitation enhances gelsolin translocation to the head. As a result the decrease of gelsolin in the tail allows keeping high level of F-actin in the tail, which is essential for the development of HA motility.     

Is sperm capacitation analogous to early phases of Ca2+‐triggered membrane fusion in somatic cells and viruses?

An important feature of male fertility is the physiological priming of spermatozoa by a multifaceted process collectively referred to as capacitation. The end point of this evasive process is the hyperactivated spermatozoa capable of binding to terminal sugar residues on the egg's extracellular coat, the zona pellucida (ZP), and undergoing acrosomal exocytosis (i.e., induction of the acrosome reaction). The hydrolytic action of acrosomal enzymes released at the site of zona binding, along with the enhanced thrust generated by the hyperactivated beat pattern of the bound spermatozoa, are important factors that regulate the penetration of ZP and fertilization of the egg. Despite many advances in identifying sperm components that promote capacitation, the mechanism underlying the calcium-triggered process remains elusive. The purpose of this review article is to focus on new advances that have enhanced our understanding of in vivo/in vitro capacitation, a prerequisite event resulting from a dramatic modification and reorganization of the sperm membrane molecules. Special emphasis has been laid on accumulating evidence suggesting potential similarities between the sperm capacitation and early phases of calcium-triggered membrane fusion (i.e., tethering and docking) during secretory and endocytotic pathways among eukaryotes.     

Rat caltrin protein modulates the acrosomal exocytosis during sperm capacitation

Caltrin is a small and basic protein of the seminal vesicle secretion that inhibits sperm calcium uptake. The influence of rat caltrin on sperm physiological processes related to fertilizing competence was studied by examining its effect on 1) spontaneous acrosomal exocytosis, 2) protein tyrosine phosphorylation, and 3) sperm-egg interaction. Results show that the presence of caltrin during in vitro capacitation both reduced the rate of spontaneous acrosomal exocytosis without altering the pattern of protein tyrosine phosphorylation, and enhanced the sperm ability to bind to the zona pellucida (ZP). The significantly higher proportion of sperm with intact acrosome observed in the presence of caltrin was accompanied by a strong inhibition in the acrosomal hyaluronidase release. Enhancement of sperm-ZP binding was evident by the increase in the percentage of eggs with bound spermatozoa as well as in the number of bound sperm per egg. Similar results were obtained when the assays were performed using spermatozoa preincubated with caltrin and then washed to remove the unbound protein, indicating that the sperm-bound caltrin was the one involved in both acrosomal exocytosis inhibition and sperm-ZP binding enhancement. Caltrin bound to the sperm head was partially released during the acrosomal exocytosis induced by Ca-ionophore A23187. Indirect immunofluorescence and immunoelectron microscopy studies revealed that caltrin molecules distributed on the dorsal sperm surface disappeared after ionophore exposure, whereas those on the ventral region remained in this localization after the treatment. The present data suggest that rat caltrin molecules bound to the sperm head during ejaculation prevent the occurrence of the spontaneous acrosomal exocytosis along the female reproductive tract. Consequently, more competent spermatozoa with intact and functional acrosome would be available in the oviduct to participate in fertilization.     

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 from beta1,4-galactosyltransferase I-null mice exhibit precocious capacitation

Mammalian sperm must undergo a physiological maturation, termed capacitation, before they are able to fertilize eggs. Despite its importance, the molecular mechanisms underlying capacitation are poorly understood. In this paper, we describe the capacitation phenotype of sperm lacking the long isoform of beta1,4-galactosyltransferase I (GalT I), a sperm surface protein that functions as a receptor for the zona pellucida glycoprotein, ZP3, and as an inducer of the acrosome reaction following ZP3-dependent aggregation. As expected, wild-type sperm must undergo capacitation in order to bind the zona pellucida and undergo a Ca(2+) ionophore-induced acrosome reaction. By contrast, GalT I-null sperm behave as though they are precociously capacitated, in that they demonstrate maximal binding to the zona pellucida and greatly increased sensitivity to ionophore-induced acrosome reactions without undergoing capacitation in vitro. The loss of GalT I from sperm results in an inability to bind epididymal glycoconjugates that normally maintain sperm in an 'uncapacitated' state; removing these decapacitating factors from wild-type sperm phenocopies the capacitation behavior of GalT I-null sperm. Interestingly, capacitation of GalT I-null sperm is independent of the presence of albumin, Ca(2+) and HCO(3)(-); three co-factors normally required by wild-type sperm to achieve capacitation. This implies that intracellular targets of albumin, Ca(2+) and/or HCO(3)(-) may be constitutively active in GalT I-null sperm. Consistent with this, GalT I-null sperm have increased levels of cAMP that correlate closely with both the accelerated kinetics and co-factor-independence of GalT I-null sperm capacitation. By contrast, the kinetics of protein tyrosine phosphorylation and sperm motility are unaltered in mutant sperm relative to wild-type. These data suggest that GalT I may function as a negative regulator of capacitation in the sperm head by suppressing intracellular signaling pathways that promote this process.     

Calmodulin signals capacitation and triggers the agonist-induced acrosome reaction in mouse spermatozoa

Capacitated acrosome-intact spermatozoa interact with specific sugar residues on neoglycoproteins (ngps) or solubilized zona pellucida (ZP), the egg's extracellular glycocalyx, prior to the initiation of a signal transduction cascade that results in the fenestration and fusion of the sperm plasma membrane and the outer acrosomal membrane at multiple sites and exocytosis of acrosomal contents (i.e., induction of the acrosome reaction (AR)). The AR releases acrosomal contents at the site of sperm-zona binding and is thought to be a prerequisite event that allows spermatozoa to penetrate the ZP and fertilize the egg. Since Ca(2+)/calmodulin (CaM) plays a significant role in several cell signaling pathways and membrane fusion events, we have used a pharmacological approach to examine the role of CaM, a calcium-binding protein, in sperm capacitation and agonist-induced AR. Inclusion of CaM antagonists (calmodulin binding domain, calmidazolium, compound 48/80, ophiobolin A, W5, W7, and W13), either in in vitro capacitation medium or after sperm capacitation blocked the npg-/ZP-induced AR. Purified CaM largely reversed the AR blocking effects of antagonists during capacitation. Our results demonstrate that CaM plays an important role in priming (i.e., capacitation) of mouse spermatozoa as well as in the agonist-induced AR. These data allow us to propose that CaM regulates these events by modulating sperm membrane component(s).     

Sperm binding to the zona pellucida is not sufficient to induce acrosome exocytosis

At fertilization, spermatozoa bind to the zona pellucida (ZP1, ZP2, ZP3) surrounding ovulated mouse eggs, undergo acrosome exocytosis and penetrate the zona matrix before gamete fusion. Following fertilization, ZP2 is proteolytically cleaved and sperm no longer bind to embryos. We assessed Acr3-EGFP sperm binding to wild-type and huZP2 rescue eggs in which human ZP2 replaces mouse ZP2 but remains uncleaved after fertilization. The observed de novo binding of Acr3-EGFP sperm to embryos derived from huZP2 rescue mice supports a ;zona scaffold' model of sperm-egg recognition in which intact ZP2 dictates a three-dimensional structure supportive of sperm binding, independent of fertilization and cortical granule exocytosis. Surprisingly, the acrosomes of the bound sperm remain intact for at least 24 hours in the presence of uncleaved human ZP2 regardless of whether sperm are added before or after fertilization. The persistence of intact acrosomes indicates that sperm binding to the zona pellucida is not sufficient to induce acrosome exocytosis. A filter penetration assay suggests an alternative mechanism in which penetration into the zona matrix initiates a mechanosensory signal transduction necessary to trigger the acrosome reaction.     

The acrosomal vesicle of mouse sperm is a calcium store

Subsequent to binding to the zona pellucida, mammalian sperm undergo a regulated sequence of events that ultimately lead to acrosomal exocytosis. Like most regulated exocytotic processes, a rise in intracellular calcium is sufficient to trigger this event although the precise mechanism of how this is achieved is still unclear. Numerous studies on mouse sperm have indicated that a voltage-operated Ca2+ channel plays some immediate role following sperm binding to the zona pellucida glycoprotein ZP3. However, there is also evidence that the mammalian sperm acrosome contains a high density of IP3 receptors, suggesting that the exocytotic event involves the release of Ca2+ from the acrosome. The release of Ca2+ from the acrosome may directly trigger exocytosis or may activate store-operated Ca2+ channels in the plasma membrane. To test the hypothesis that the acrosome is an intracellular store we loaded mammalian sperm with the membrane permeant forms of three Ca2+-sensitive fluorescent indicator dyes: fura-2, indo-1, and Calcium Green-5N. Fluorescence microscopy revealed that the sperm were labeled in all intracellular compartments. When fura-2 labeled sperm were treated with 150 microM MnCl2 to quench all fluorescence in the cytosol, or when the sperm were labeled with the low affinity dye Calcium Green-5N, there was a large Ca2+ signal in the acrosome. Consistent with the acrosome serving as an intracellular Ca2+ reservoir, the addition of 20 microM thapsigargin, a potent inhibitor of the smooth endoplasmic reticular Ca2+-ATPase (SERCA), to populations of capacitated sperm resulted in nearly 100% acrosomal exocytosis within 60 min (tau1/2 approximately 10 min), in the absence of extracellular Ca2+. Additionally, treatment of sperm with 100 microM thimerosal, an IP3 receptor agonist, also resulted in acrosomal exocytosis. Taken together, these data suggest that the mouse sperm acrosome is a Ca2+ store that regulates its own exocytosis through an IP3 Ca2+ mobilization pathway.     

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.     

The C-kit receptor and its possible signaling transduction pathway in mouse spermatozoa

The presence and role of the c-kit protein was investigated in the mature sperm of the mouse. The c-kit monoclonal antibody (mAb) ACK₂ reacted specifically with the acrosomal region and the principal piece of fixed noncapacitated sperm but did not react with the acrosome region in acrosome-reacted sperm. ACK₂ significantly inhibited the acrosome reaction; this inhibition was relieved by the calcium ionophore A23187. The kit ligand stem cell factor (SCF) significantly increased the percentage of sperm undergoing acrosome reaction. This increase was partially inhibited by the calcium channel inhibitor (verapamil), the PI3k inhibitor (wortmannin), and the PLC inhibitor (U-73122). ACK₂ predominantly recognized c-kit proteins of 33, 48, and 150 kDa by Western blotting of mouse sperm extracts. The 48- and 150-kDa protein bands were released into the media and tyrosine autophosphorylated at low basal levels during acrosome reaction. On stimulation with SCF, the level of c-kit phosphorylation increased significantly. These findings suggest that c-kit is present in mature sperm, and its binding to SCF may result in the activation of PLCγ1 and PI3K, leading to receptor autophosphorylation, and ultimately may play a role in capacitation and/or the acrosome reaction. Mol. Reprod. Dev. 49:317–326, 1998. © 1998 Wiley-Liss, Inc.     

Mammalian fertilization: the egg's multifunctional zona pellucida

The zona pellucida (ZP) is a specialized extracellular coat that surrounds the plasma membrane of mammalian eggs. Its presence is essential for successful completion of oogenesis, fertilization and preimplantation development. The ZP is composed of only a few glycoproteins which are organized into long crosslinked fibrils that constitute the extracellular coat. A hallmark of ZP glycoproteins is the presence of a ZP domain, a region of polypeptide responsible for polymerization of the glycoproteins into a network of interconnected fibrils. The mouse egg ZP consists of only three glycoproteins, called ZP1, ZP2, and ZP3, that are synthesized and secreted exclusively by growing oocytes. One of the glycoproteins, ZP3, serves as both a binding partner for sperm and inducer of sperm exocytosis, the acrosome reaction. Female mice lacking ZP3 fail to assemble a ZP around growing oocytes and are completely infertile. Sperm bind to the carboxy-terminal region of ZP3 polypeptide encoded by ZP3 exon-7 and binding is sufficient to induce sperm to complete the acrosome reaction. Whether sperm recognize and bind to ZP3 polypeptide, oligosaccharide, or both remains an unresolved issue. Purified ZP3 self-assembles into long homomeric fibrils under non-denaturing conditions. Apparently, sperm added to ZP3 bind to the fibrils and are prevented from binding to ovulated eggs in vitro. These, as well as other aspects of ZP structure and function are addressed in this article.     

Acrosome reaction induced by immunoaggregation of a proteinase inhibitor bound to the murine sperm head.

ZP3, a glycoprotein of the murine zona pellucida, functions both to bind acrosome intact sperm and to induce the acrosome reaction. Solubilized whole zonae as well as purified ZP3 are able to induce acrosome reactions in capacitated sperm. Pronase digests of whole zonae yield glycopeptides that bind to sperm but are unable to induce acrosome reactions. However, immunoaggregation of these glycopeptides results in the exocytosis of the acrosome in the majority of treated sperm. The data suggest that ZP3 triggers the acrosome reaction by the aggregation of ZP3 binding sites on the sperm head. If aggregation of ZP3 binding sites is important in the induction of the acrosome reaction, then it may be possible to induce the acrosome reaction in the absence of zona by immunoaggregation of the sites. This presentation deals with the immunoaggregation of a proteinase inhibitor of seminal vesicle origin (SVI) that binds to a site on the sperm head known to participate in zona binding. We show that capacitated murine sperm, pretreated with the SVI, will acrosome react, as determined by Coomassie brilliant blue staining, when incubated with rabbit antiinhibitor antiserum (anti-SVI). The percentage of SVI-treated sperm displaying an acrosome reaction is dependent on the concentration of the immune serum. Sperm stain positive for intact acrosomes when anti-SVI Fab fragments or normal rabbit serum is substituted for the immune serum. However, when capacitated sperm, treated with both SVI and anti-SVI Fab fragments, are incubated with goat antirabbit IgG, the majority of sperm acrosome react. The data suggest that the aggregation of SVI bound to the sperm surface, in the absence of zona glycoproteins, is sufficient to induce the acrosome reaction.     

Transitional states of acrosomal exocytosis and proteolytic processing of the acrosomal matrix in guinea pig sperm

In this study, we adapted a FluoSphere bead-binding assay to study the exposure and release of guinea pig sperm acrosomal components during the course of capacitation and acrosomal exocytosis. Prior to capacitation or the initiation of exocytosis, acrosomal proteins were not accessible to FluoSpheres coated with antibodies against two acrosomal matrix (AM) proteins, AM67 and AM50; during the course of capacitation and ionophore-induced acrosomal exocytosis, however, we detected the transient exposure of the solid-phase AM proteins on the surface of guinea pig sperm using the antibody-coated fluorescent beads. Several different transitional stages leading to complete acrosomal exocytosis were classified, and we propose these represent true, functional intermediates since some of the AM proteins are orthologues of mouse proteins that bind the zona pellucida (ZP) of unfertilized eggs. In addition, we present evidence that implicates acrosin in the proteolytic processing of AM50 during AM disassembly. Thus, we propose that the transitional states of acrosomal exocytosis involve early binding of AM proteins to the ZP (by what visually appear to be "acrosome-intact" sperm), maintenance of ZP binding that coincides with the progressive exposure of AM proteins, and gradual proteolytic disassembly of the AM to allow sperm movement through the ZP. We feel this "transitional states" model provides a more refined view of acrosomal function that supports a move away from the widely held, overly simplistic, and binary "acrosome-reaction" model, and embraces a more dynamic view of acrosomal exocytosis that involves intermediate stages of the secretory process in ZP binding and penetration.     

Acrosomal exocytosis of mouse sperm progresses in a consistent direction in response to zona pellucida

Sperm acrosomal exocytosis is essential for successful fertilization, and the zona pellucida (ZP) has been classically considered as the primary initiator in vivo. At present, following what is referred to as primary binding of the sperm to the ZP, the acrosome reaction paradigm posits that the outer acrosomal membrane and plasma membrane fuse at random points, releasing the contents of the acrosome. It is then assumed that the inner acrosomal membrane mediates secondary binding of the sperm to the ZP. In the present work we used a live fluorescence imaging system and mouse sperm containing enhanced green fluorescent protein (EGFP) in their acrosomes. We compared the processes of acrosomal exocytosis stimulated by the calcium ionophore ionomycin or by solubilized ZP. As monitored by the loss of EGFP from the sperm, acrosomal exocytosis driven by these two agents occurred differently. When ionomycin was used, exocytosis started randomly (no preference for the anterior, middle or posterior acrosomal regions). In contrast, following treatment with solubilized ZP, the loss of acrosomal components always started at the posterior zone of the acrosome and progressed in an anterograde direction. The exocytosis was slower when stimulated with ZP and on the order of 10 sec, which is in accordance with other reports. These results demonstrate that ZP stimulates acrosomal exocytosis in an orderly manner and suggest that a receptor‐mediated event controls this process of membrane fusion and release of acrosomal components. These findings are incorporated into a model. J. Cell. Physiol. 220: 611–620, 2009. © 2009 Wiley‐Liss, Inc.     

How the egg regulates sperm function during gamete interaction: facts and fantasies

Although details of the molecular mechanism are not yet clear, considerable evidence suggests that the egg-specific extracellular matrix component ZP3 regulates an essential event of sperm function, the acrosome reaction. Spatial control of this exocytotic event appears to be exerted by immobilization of the triggering ligand, ZP3, in the zona pellucida matrix surrounding the egg. Our data suggest that the signal transduction pathway in sperm activated by this ligand involves highly conserved components that are involved in many other eukaryotic signalling events. Recent experiments indicate that the murine zona pellucida glycoprotein ZP3 regulates acrosomal exocytosis by aggregating its corresponding receptors (ZP3-Rs) located in the mouse sperm plasma membrane. In other experiments, we have identified a putative ZP3-R of mouse sperm with Mr 95,000. Indirect immunofluorescence localizes this ZP3-R, termed p95, to the acrosomal region of the mouse sperm head, which is the anticipated location for ZP3-Rs. Membrane fractionation studies indicate that p95 cofractionates with a plasma membrane-enriched preparation from sperm that contains zona pellucida-receptor activity. In addition to its role as a ZP3-R, p95 also serves as a substrate for a tyrosine kinase in response to zona pellucida binding. On the basis of the data presented here, and borrowing heavily from findings for other signalling systems, we have formulated two testable hypotheses that are compatible with the available data: either p95 is itself a protein tyrosine kinase receptor, or p95 serves as a ZP3 receptor and is separate from a protein tyrosine kinase that is activated during gamete interaction.(ABSTRACT TRUNCATED AT 250 WORDS)