Requirement of protein tyrosine kinase and phosphatase activities for human sperm exocytosis.

The acrosome is a membrane-limited granule that overlies the nucleus of the mature spermatozoon. In response to physiological or pharmacological stimuli, sperm undergo calcium-dependent exocytosis termed the acrosome reaction, which is an absolute prerequisite for fertilization. Protein tyrosine phosphorylation and dephosphorylation are a mechanisms by which multiple cellular events are regulated. Here we report that calcium induces tyrosine phosphorylation in streptolysin O (SLO)-permeabilized human sperm. As expected, pretreatment with tyrphostin A47-a tyrosine kinase inhibitor-abolishes the calcium effect. Interestingly, the calcium-induced increase in tyrosine phosphorylation has a functional correlate in sperm exocytosis. Masking of phosphotyrosyl groups with a specific antibody or inhibition of tyrosine kinases with genistein, tyrphostin A47, and tyrphostin A51 prevent the acrosome reaction. By reversibly sequestering intra-acrosomal calcium with a photo-inhibitable chelator, we show a requirement for protein tyrosine phosphorylation late in the exocytotic pathway, after the efflux of intra-acrosomal calcium. Both mouse and human sperm contain highly active tyrosine phosphatases. Importantly, this activity declines when sperm are incubated under capacitating conditions. Inhibition of tyrosine phosphatases with pervanadate, bis(N,N-dimethylhydroxoamido)hydroxovanadate, ethyl-3,4-dephostatin, and phenylarsine oxide prevents the acrosome reaction. Our results show that both tyrosine kinases and phosphatases play a central role in sperm exocytosis.

Treatment of human spermatozoa with seminal plasma inhibits protein tyrosine phosphorylation.

It has long been known that seminal plasma contains factors that influence the fertilizing capacity of spermatozoa in many different ways. However, little is understood of the biochemical cascades triggered when spermatozoa and seminal plasma interact. In this study, we examined how incubation with seminal plasma affected protein tyrosine phosphorylation in human spermatozoa. Increased protein tyrosine phosphorylation is a hallmark of sperm capacitation in several mammalian species, including human. Seminal plasma blocks protein tyrosine phosphorylation when added to washed, non-capacitated spermatozoa. Removal of seminal plasma and incubation in capacitating medium led to partial recovery of the tyrosine phosphorylation cascade. Addition of seminal plasma to a suspension of spermatozoa previously incubated for 5 h under capacitating conditions decreased the level of tyrosine phosphorylation on all proteins in a dose-dependent manner. In this case, the phosphotyrosine signal did not increase upon removal of seminal plasma followed by overnight incubation in fresh capacitating media, indicating that removal of seminal plasma was necessary but not sufficient for protein tyrosine phosphorylation to occur. These results indicate that human seminal plasma contains factors that influence the tyrosine phosphorylation status of human spermatozoa.

Molecules involved in mammalian sperm-egg interaction.

To achieve fertilization, sperm and egg are equipped with specific molecules which mediate the steps of gamete interaction. In mammals, the first interaction between sperm and egg occurs at an egg-specific extracellular matrix, the zona pellucida (zp). The three glycoproteins, ZP1, ZP2, and ZP3, that comprise the zp have been characterized from many species and assigned different roles in gamete interaction. A large number of candidate-binding partners for the zp proteins have been described; a subset of these have been characterized structurally and functionally. Galactosyltransferase, sp56, zona receptor kinase, and spermadhesins are thought to participate in the primary binding between sperm and zp and may initiate the exocytotic release of hydrolytic enzymes in the sperm head, the acrosome reaction. Digestion of the zp by these enzymes enables sperm to traverse the zp, at which time the proteins PH20, proacrosin, sp38, and Sp17 are thought to participate in secondary binding between the acrosome-reacted sperm and zp. Once through the zp, sperm and egg plasma membranes meet and fuse in a process reported to involve the egg integrin alpha 6 beta 1 and the sperm proteins DE and fertilin. These molecules and the processes involved in gamete interaction are reviewed in this chapter within a physiological context.

Regulation of mouse epididymal epithelium in vitro by androgens, temperature and fibroblasts.

The epididymal epithelium provides the microenvironment for sperm maturation. However, the molecular basis of epididymal function is still poorly understood because of the limitations of in vivo systems. For this reason, we have developed an in vitro culture system for mouse epididymal epithelial cells. Cells were purified by enzymatic digestion and centrifugation through a Percoll gradient, and plated on inserts coated with a replacement basement membrane. Cultured cells maintained ultrastructural and immunocytochemical features of epithelia, but did not retain the androgen responsiveness of epididymal cells (as judged by androgen receptor detection and secretion of specific markers) unless cocultured with fibroblasts. The androgen receptor was detected in the nuclei of epididymal epithelial cells only when grown with epididymal fibroblasts in the subjacent chamber. Moreover, specific epididymal secretory proteins were secreted only when epithelial cells were cultured in the presence of both androgens and fibroblasts at 32 degrees C. These results highlight the importance of cell-cell interaction, as well as temperature regulation in the physiology of the epididymis. They also establish the existence of two independent pathways in the differentiation of these cells. The first, leading to the expression of epithelial characteristics, is fibroblast-independent, whereas the second, conferring tissue-specific features, depends upon coculture with fibroblasts.

Activation of mouse sperm phosphatidylinositol-4,5 bisphosphate-phospholipase C by zona pellucida is modulated by tyrosine phosphorylation.

Many cellular responses to the occupancy of membrane receptors include the hydrolysis of phosphatidylinositol-4,5 bisphosphate (PIP2) by phospholipase C (PLC) and the subsequent generation of inositol 1,4,5-triphosphate (IP3) and diacylglycerol (DAG). In the gamete interaction system, sperm respond to binding to the egg's extracellular matrix, the zona pellucida (zp), by exocytosis of the acrosome in a process known as the acrosome reaction (AR). Under physiological conditions, zp binding stimulates ARs only after sperm have undergone a final maturation phase, known as capacitation. One of the zp glycoproteins, ZP3, serves as the ligand for sperm plasma membrane receptors and as the trigger for this regulated exocytosis. Both phosphoinositide-linked and tyrosine kinase-mediated pathways participate in the signalling cascade triggered by sperm-zp interaction. This paper reports that stimulation with solubilized zp increased PIP2-PLC enzymatic activity from mouse sperm. ZP3 is the zp component responsible for this stimulation. The effect was abolished by tyrphostin, suggesting that zp activation of PLC was mediated by tyrosine phosphorylation and that gamma was the PLC isoform involved. We show the presence and distribution of PLC gamma 1 in mouse sperm. Immunostaining studies indicate that PLC gamma 1 is restricted to the sperm head. Sperm capacitation induced translocation of PLC gamma 1 from the soluble to the particulate fraction. These data suggest that PLC gamma 1 constitutes a component in the cascade that couples sperm binding to the egg's extracellular matrix with acrosomal exocytosis, a regulated secretory response upon which fertilization depends absolutely.

Interaction of a tyrosine kinase from human sperm with the zona pellucida at fertilization.

A 95-kilodalton mouse sperm protein with characteristics of a protein tyrosine kinase has been identified as a receptor for ZP3, a glycoprotein in the egg's extracellular matrix. The structure of the human homolog was determined by screening an expression library from human testis; a testis-specific complementary DNA was isolated that encodes a protein similar to receptor tyrosine kinases and appears to be expressed only in testicular germ cells. Antibodies against a synthetic peptide from the intracellular domain recognized a 95-kilodalton human sperm protein that contains phosphotyrosine; human ZP3 stimulates the kinase activity of this sperm protein. Synthetic peptides corresponding to regions of the predicted extracellular domain inhibited sperm binding to human zona pellucida. Availability of the primary sequence of a receptor for ZP3 provides a rational starting point for sperm-targeted contraceptive development.

Regulation of mouse gamete interaction by a sperm tyrosine kinase.

A 95-kDa mouse sperm protein has been previously identified as a putative receptor involved in the sperm-egg interactions that lead to fertilization. The ligand for this receptor is the zona pellucida glycoprotein ZP3. This constituent of the oocyte-specific extracellular matrix mediates not only sperm binding to the zona but also triggers acrosomal exocytosis. The latter, also termed the acrosome reaction, is a key regulatory event upon which fertilization is absolutely dependent. Previously, we showed that the 95-kDa protein that binds ZP3 is a substrate for tyrosine kinase, and its phosphotyrosine content increases after sperm-zona pellucida binding. Here, we show the presence of protein tyrosine kinase activity in sperm plasma membranes and in electroeluted 95-kDa protein. The tyrosine kinase activity of the isolated protein is stimulated by solubilized zona pellucida and inhibited by tyrphostin RG-50864, a membrane-permeable tyrosine kinase inhibitor. Furthermore, tyrphostin inhibits zona-triggered acrosomal exocytosis in a dose-dependent manner. These findings indicate that the 95-kDa protein participates in a critical regulatory event of gamete interaction; moreover, our experiments suggest that sperm protein tyrosine kinase may be an excellent target for the control of fertility.

Protein dynamics in sperm membranes: implications for sperm function during gamete interaction.

A number of mammalian sperm plasma membrane antigens have been implicated as playing a functional role in sperm-egg interaction, by virtue of the fact that antibodies against these antigens interfere with fertilization. Two such mouse sperm plasma membrane antigens are M42, a 200/220 kD glycoprotein doublet, and M5, a 150-160 kD glycoprotein. We show that both of these antigens are concentrated on the posterior region of caudal epididymal and capacitated mouse sperm heads and are relatively diffusible, as determined by fluorescence recovery after photobleaching measurements (D = 3-8 x 10(-9) cm2/s with approximately 23% diffusing). Crosslinking of these antigens with bivalent antibodies causes them to redistribute into the anterior region (acrosomal crescent) of the sperm head. In contrast, we describe a third antigen, P220, which is also localized to the posterior region of the sperm head on caudal epididymal sperm but which exhibits very little diffusion and does not redistribute upon crosslinking. Bivalent anti-M42 blocks the ZP3-induced acrosome reaction. We have found that monovalent Fab fragments of anti-M42 do not block the ZP3-induced acrosome reaction, but that inhibition is restored by addition of a second antibody which crosslinks the Fabs. Thus, crosslinking is required for both inhibition of the acrosome reaction and redistribution. This suggests that redistribution of antigen away from the posterior region of the head may be part of the mechanism of inhibition of the ZP3-induced acrosome reaction.

Generation of a mouse sperm membrane fraction with zona receptor activity.

To identify mouse sperm components involved in primary sperm binding to zonae pellucidae, a mouse sperm plasma membrane-enriched fraction was generated using a vortex method. The crude membrane fraction recovered after vortexing was resolved into three bands and a pellet by centrifugation on a discontinuous sucrose gradient. Ultrastructural analysis indicated that Bands 2 and 3 were composed predominantly of membranes, although Band 3 was contaminated with mitochondria; Band 1 and the gradient pellet contained insufficient material and were unsuitable for ultrastructural analysis. To determine where plasma membranes migrate in the gradient, sperm were labeled vectorially with 125I; subsequently, membrane fractions were analyzed by SDS-PAGE and autoradiography. Band 2 was enriched threefold in radiolabel when compared with Band 3. Examination of intact and vortexed sperm stained with regionally distributed anti-mouse sperm monoclonal antibodies revealed that vortexing removed anterior head plasma membrane preferentially. Bioactivity, defined as the ability to inhibit primary sperm binding to the zona pellucida in a concentration-dependent manner, was contained in the crude membrane fraction and Band 2 exclusively, with inhibition of 53% and 44%, respectively, at the maximum concentration tested. Band 3 exhibited no significant bioactivity. We conclude from these results that a plasma membrane-enriched fraction, Band 2, isolated from mouse cauda epididymal sperm, exhibits zona pellucida receptor activity.

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)

Sperm antigens in fertilization.

PIP: A review of sperm antigens involved in fertilization includes a description of sperm differentiation, seminal fluid components that coat sperm, sperm antigens involved in binding to the zona pellucida (ZP), antigens involved in the acrosome reaction, in zona pellucida penetration, and those active in fusion with the ova membrane. Sperm antigens are located in certain domains of the cell, and they are altered during capacitation and passage through the female tract. Caltrin and acrosome-stabilizing factor are applied by seminal fluid. At least 2 antigens have been studied that occur in sterile women, although one cross reacts with milk proteins. Some antigens active in ZP binding are trypsin, proacrosin, acrosin, PH-20 from guinea pigs, and rabbit sperm autoantigen I. Antigens involved in the acrosome reaction, such as M42, are likely to cross react with other body proteins that also entail exocytosis. A mouse antigen involved in ZP penetration, MS 207 is well characterized. PH-30 from guinea pigs and M29 from mouse participate in sperm-egg membrane fusion, as does fertilization antigen I from human and mouse sperm which is know to cause infertility. Oddly, patients' sera react with polymers but not monomers of this antigen. Studies with antisperm antibodies suggest that it will not be necessary to agglutinate all sperm to block fertility, only to inhibit a single sperm epitope and function. It will probably be feasible to inhibit multiple successive events, and possibly to induce temporary immunity.^ieng

Anti-idiotype antibodies prevent antibody binding to mouse sperm and antibody-mediated inhibition of fertilization.

Antibodies to components of sperm can interfere with sperm function and prevent fertilization by blocking specific steps of gamete interaction. It can be proposed that anti-idiotype antibodies (anti-Ids) that recognize determinants located close to or within the antigen-binding site of an anti-sperm antibody could block antibody binding to sperm antigen and antibody-mediated inhibition of fertilization. To test this hypothesis, rabbit polyclonal antibodies to idiotypic determinants of the monoclonal anti-sperm antibody M42.15 were developed and characterized. Previous studies demonstrated that M42.15 monoclonal antibody (mAb) inhibits fertilization in vitro and in vivo by inhibiting sperm-zona pellucida interaction. Anti-idiotype antibodies to M42.15 mAb (anti-Id M42) were isolated by affinity chromatography on immobilized M42.15 mAb. Binding specificity of anti-Id M42.15 was demonstrated in a solid-phase radioimmune binding assay and by specific immunoprecipitation of soluble M42.15 mAb. Anti-Id M42 competitively inhibited M42.15 mAb, but not P220.2 mAb, binding to mouse sperm, confirming that the anti-Id preparation contained antibodies directed against idiotopes within or adjacent to the antigen-binding site of the mAb. At equimolar concentrations, anti-Id M42 inhibited binding of 125I-labeled M42.15 mAb to sperm by greater than 80%. These results showed that anti-Id M42 efficiently blocked antibody binding to sperm and suggested that anti-Id M42 could be used to neutralize the anti-fertility activity of the M42.15 mAb. When tested in in vitro fertilization assays, anti-Id M42, but not rabbit immunoglobulin, prevented M42.15 mAb-induced inhibition of fertilization. Together, these results show that the inhibitory activity of anti-sperm antibodies capable of interfering with gamete interaction can be neutralized by anti-Id that recognize determinants close to the antigen-combining site of the anti-sperm antibody.

Mammalian sperm interaction with extracellular matrices of the egg.

One conclusion that may be drawn from the foregoing discussion is that examination of mammalian gamete interaction at a molecular level is underway. As yet, however, it would be premature to suggest a detailed molecular model to account fully for acrosomal exocytosis. Too many possibilities exist at present, not just for sperm but for virtually all other exocytotic systems studied. It is evident, however, that many elements of typical signal transduction pathways are present in sperm, and recent work supports the idea that such pathways may be used in AR triggering. Investigations at the cellular level provide sufficient data to formulate a sequence of gamete interactions that may apply generally to mammals. This sequence is summarized in Fig. 8.2. It is suggested that the cumulus ECM functions to restrict access of only primed (i.e., capacitated) sperm to the egg. Those sperm that undergo a spontaneous AR in the midst of the cumulus ECM are prevented from further participation in fertilization by adherence to cumulus cells. Thus, a select population of capacitated, acrosome-intact sperm arrive at the zona pellucida surface under the normal conditions of fertilization. Binding to the zona pellucida is initiated by plasma membrane receptors interacting with ZP3. This primary binding results in receptor clustering, which itself is the triggering event for acrosomal exocytosis. The signal is transmitted intracellularly via G proteins to effect fusion between the plasma and outer acrosomal membranes. As a result, proacrosin is exposed. Direct evidence for specific use of ZP2 in secondary binding has not yet been reported, but is inferred from results with mouse (Bleil and Wassarman 1986), and procine (Brown and Jones 1987; Jones et al. 1988; Topfer-Petersen and Henschen 1987, 1988) gametes. This secondary binding between ZP2 and proacrosin occurs together with pH-dependent autoactivation of proacrosin to acrosin. Limited proteolysis of the zona pellucida matrix by acrosin causes digestion and increases the affinity of freshly exposed proacrosin for the zona pellucida. This cycle continues, eventually generating the narrow penetration slit through the zona pellucida. Undoubtedly, other factors are at play here, particularly motility, and it is assumed that vigorously active ('hyperactive') sperm are the cells that participate in these events. This scheme can account for the many diverse observations made in different species if two factors, kinetics and affinity, are considered. In some species, FTU aggregation may occur spontaneously at a rate faster than in others, leading to a higher level of spontaneously acrosome-reacted sperm.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of antibodies to idiotypic determinants of monoclonal anti-sperm antibodies.

Rabbit polyclonal antibodies to the idiotype of murine monoclonal anti-sperm antibodies were developed and characterized. M29.6 and M42.15 are monoclonal antibodies (mAbs) that inhibit fertilization in vivo and in vitro. Sera from rabbits inoculated with purified mAbs (Ab1) were absorbed with normal mouse and isotype-specific immunoglobulin (Ig); the anti-idiotype Ig fraction (Ab2) was isolated by protein A-chromatography or by chromatography on the corresponding idiotype column. Binding specificity of Ab2 was confirmed by measuring the reactivity of Ab2 with homologous and heterologous mAbs. Ab2 competitively inhibited 125I-labeled Ab1 binding to mouse sperm, suggesting that the Ab2 preparation possessed subpopulations directed against idiotopes similar or adjacent to the antigen-binding site of the mAb. Anti-idiotype antibodies reactive with the antigen-combining site of the anti-sperm mAb may contain subpopulations that mimic the mouse sperm epitope recognized by Ab1. Immunization with Ab2 induced anti-(anti-idiotype) antibodies (Ab3), which competitively inhibited binding of 125I-labeled Ab1 to immobilized Ab2. These results are consistent with the hypothesis that immunization of mice with antibodies to the idiotype of sperm-specific mAbs can induce antibodies that share structural similarities with the anti-sperm mAb used for their induction. Immunization with anti-idiotype antibodies that mimic sperm antigen structure represents a possible strategy for induction of immunity to sperm.

Epididymal maturation and the acrosome reaction in mouse sperm: response to zona pellucida develops coincident with modification of M42 antigen.

Development of the sperm's capacity to interact with the zona pellucida was investigated at the stage when the acrosome reaction (AR) is induced. The response of epididymal sperm to agents that affect the occurrence of the AR was used to monitor maturational changes. Despite the finding that sperm from the three main epididymal regions were competent to undergo ARs induced by the divalent cation ionophore A23187 (56% AR, 74% AR, and 83% AR in caput, corpus, and cauda, respectively), the cells' responses to solubilized zonae pellucidae were different. When challenged with 5 zonae equivalents/microliter, both corpus and cauda sperm shed their acrosomes in high numbers (75% AR and 86% AR, respectively), whereas caput sperm did not (23% AR). Previous work has shown that the presence of M42 monoclonal antibody (mAb) during in vitro and in vivo fertilization inhibits sperm penetration through the zona pellucida by specific interference with zonae pellucidae-induced ARs. In this study, presence of the M42 mAb did not affect the incidence of A23187-induced ARs, whereas the zona-induced ARs that occurred in both corpus and cauda sperm were inhibited fully with M42 immunoglobulin (Ig) G. In addition, the antigen recognized by M42 mAb on sperm, termed M42 Ag, was examined during epididymal maturation. Although antigen localization appeared indistinguishable by immunofluorescence on sperm taken from the caput, corpus, and cauda regions of the epididymis, modification of this antigen during epididymal transit was detected. Equilibrium-binding studies using 125I-M42 IgG demonstrated a progressive increase during epididymal transit in the amount of M42 mAb that bound to fixed cells. Corpus and cauda sperm bound 185% and 240%, respectively, of the 125I-M42 IgG detected on caput sperm. These changes in expression of M42 Ag paralleled a structural change: the Mr of the antigen decreased from a 195,000/210,000 doublet in caput sperm to a 185,000/200,000 doublet in corpus and cauda sperm, as determined by immunoblot analysis of sodium dodecyl sulfate (SDS)-extracted sperm. Results presented here demonstrate that mouse sperm develop the capacity to undergo a zona-induced AR during epididymal maturation. The M42 antigen, which is involved in the zona-induced AR, is modified during epididymal transit coincident with development of the sperm's responsiveness to zonae. Our working hypothesis, based on these results, is that development of the sperm's capacity to undergo a physiological AR is related to modification of M42 Ag.

Mouse sperm antigens that participate in fertilization. IV. A monoclonal antibody prevents zona penetration by inhibition of the acrosome reaction.

To investigate the molecular basis of gamete interaction in mammals, monoclonal antibodies (mAbs) have been generated by syngeneic immunization with mouse testis. Previous work has described two particular mAbs, M41 and M42, which localize indistinguishably to the plasma membrane overlying a restricted portion of the acrosome, but recognize different antigens. One of the mAbs, M42, inhibits mouse fertilization in vitro significantly, but only in the presence of the zona pellucida, whereas M41 has no apparent effect upon any assayable event in the fertilization process. The experiments described here were performed to identify the precise event of sperm-zona interaction (sperm-zona binding, induction of the acrosome reaction, or penetration through the zona) that is affected by M42 mAb. Capacitated mouse sperm binding to the zona pellucida was undiminished following pretreatment with M42 mAb, when compared to levels achieved using either no mAb- or to M41 mAb-treated control sperm. When the effect of mAbs on the zona-induced AR was examined, the percentage of acrosome reacted (AR) sperm at the zona surface increased with time, plateauing at approximately 90 min post-insemination, with 78% of the bound cells AR in the control and the M41 mAb-treated groups. M42-treated sperm never achieved greater than 23% AR cells over the 120-min interval assayed. To quantitate this effect, capacitated sperm were exposed to increasing concentrations of acid-solubilized zonae. Increased proportions of AR sperm were found in the control and M41 mAb-treated groups, up to a maximum of 70-76% AR cells with 8 or 12 zonae/microliter. In contrast, M42-treated sperm displayed only 21-28% AR cells over the entire range of zonae concentrations tested. An entirely different result emerged when acrosome reactions were induced with A23187: M42 was no longer able to prevent the AR. This ability of A23187 to override M42 mAb's inhibitory effect on the AR permitted specific examination of the possible effect of M42 mAb on sperm penetration through the zona pellucida. In the presence of A23187, zona penetration levels for M42 mAb-treated sperm were equivalent, both qualitatively and quantitatively, to control and to M41 mAb-treated sperm under the same conditions. It appears, therefore, that M42 mAb identifies a high molecular weight doublet (220-240 kDa) of mouse sperm that participates specifically in the induction of the sperm's acrosome reaction as it occurs under physiological conditions.

Immunological identification of sperm antigens that participate in fertilization.

Using monoclonal antibodies (mAbs) as probes for specific components of the spermatozoon, we have initiated an investigation aimed at identifying those sperm components that participate in the events of gamete interaction. We intend to exploit these mAbs not only for identifying functional sperm components, but also for defining the constituents of discrete domains that comprise the structure of this highly differentiated cell. Among the large group of anti-sperm mAbs that we have generated, we have focused to date upon two categories. The first category consists of mAbs that localize to the acrosomal crescent, a restricted region of plasma membrane overlying the acrosome. Within this category, the mAbs share many similarities with regard to subclass, species and tissue cross-reactivity, and antigen solubility, in addition to cellular distribution. Nevertheless, despite these similarities, some mAbs in this category (e.g., M42) inhibit fertilization, whereas others (e.g., M41) are non-inhibitory. The block to fertilization observed in the presence of M42 is dependent upon the zona pellucida surrounding the egg. The specific event prevented by M42 appears to be the induction of the acrosome reaction at its physiological site, the surface of the zona pellucida. The sperm components recognized specifically by M42 are a cluster of high molecular weight moieties, ranging from approximately 220,000 to 240,000. The mAbs described in the second category display common localization at the equatorial segment of the sperm head. The pair of mAbs discussed from this category, M2 and M29, again bear considerable similarity to each other, yet differ significantly in their ability to inhibit fertilization. M2 does not inhibit, whereas M29 causes a marked inhibition of fertilization. With M29, however, the block to fertilization is independent of the zona pellucida. The M29 mAb interferes with sperm interaction with the egg plasma membrane subsequent to sperm attachment; since M29 does not prevent sperm binding to the egg plasma membrane, the specific event affacted, in all likelihood, is gamete membrane fusion. M29 recognizes a single sperm component, with subunit molecular weight of approx. 40,000. A variety of experiments are underway currently, both to characterize the antigens recognized by these mAbs further as well as to identify additional sperm components that participate in the fertilization process.

Mouse sperm antigens that participate in fertilization. I. Inhibition of sperm fusion with the egg plasma membrane using monoclonal antibodies.

Monoclonal antibodies (mAbs) have been generated to determine the sperm components responsible for interaction with an egg that results in fertilization. Here, we report upon a group of six different mAbs, all of which localize to a restricted region of the sperm head, the equatorial segment. Several of these mAbs demonstrated cross-reactivity with sperm from the other species tested (human, hamster, rabbit); when cross-reaction occurred, the mAb distribution was restricted to the equatorial segment despite the various configurations that this homologous region assumes in different species. When tested for an effect upon the fertilization process in vitro, ascites fluids containing two of the six mAbs, M29 and M37, displayed significant inhibition. The concentration dependency of this inhibition was observed using purified M29 immunoglobulin M, over a range of 0 to 0.2 mg/ml. The mAb inhibition of fertilization was independent of the presence of either the cellular (the cumulus) or acellular (the zona pellucida) layers surrounding the egg, indicating that the specific locus of inhibition for both of these antisperm mAbs was the egg plasma membrane. Immunologic detection of sperm components separated by electrophoresis on 12% sodium dodecyl sulfate-polyacrylamide gels followed by transfer to nitrocellulose sheets was used to identify the sperm components recognized by two of the mAbs in this group: M29, which inhibited fertilization, and M2, which did not inhibit fertilization. Using M29 mAb, a single sperm component with an apparent subunit molecular weight of approximately 40,000 was detected, whereas in the nitrocellulose strips incubated with M2 mAb two components displayed reactivity, a very prominent band at approximately 44,000 and a tight cluster of bands at approximately 36,000. Parallel nitrocellulose strips of mouse liver did not display these reactivities, consistent with indirect immunofluorescence data in which only testis and sperm, and not liver, kidney, ovary, and epididymal epithelium, demonstrated positive reactivity. These results indicate that the use of mAbs permits identification of sperm components that participate, putatively, in individual events of the fertilization process. Furthermore, using this strategy, we have identified a specific sperm component that appears to be a candidate for a role in sperm fusion with the egg plasma membrane.

Mouse sperm antigens that participate in fertilization. II. Inhibition of sperm penetration through the zona pellucida using monoclonal antibodies.

To dissect the process of mammalian sperm interaction with the egg at a molecular level, we have generated monoclonal antibodies (mAbs) to mature mouse sperm using syngeneic mouse testis as the immunogen. In this paper, we report upon three members of a mAb family, all of which displayed identical immunofluorescence patterns on cauda epididymal mouse sperm. Each of these mAbs, termed M42, M5, and M41, localized to a restricted region of plasma membrane overlying the acrosome. When tested for an effect on the fertilization process in vitro, two of the mAbs, M42 and M5, demonstrated significant inhibition. The inhibitory capacity was dependent upon the presence of the zona pellucida; neither M42 nor M5 was capable of blocking fertilization when zona pellucida-free mouse eggs were used. Identification of the antigens recognized by this group of mAbs was achieved by immunologic detection of sodium dodecyl sulfate-extracted sperm components separated via electrophoresis on 12% sodium dodecyl sulfate-polyacrylamide gels followed by transfer to nitrocellulose. M42, which blocked fertilization, recognized a high molecular weight cluster of bands with Mr of approximately 220,000 to 240,000. M5, which also prevented fertilization, specifically recognized a sperm component with subunit molecular weight of approximately 54,000. M41, which did not interfere with fertilization, did not interact with any high molecular weight components, but recognized components with Mr of approximately 60,000, 35,000, and 21,000. Taken together with the work presented in a companion paper (Saling, Irons, and Waibel, this issue), we have demonstrated that it is possible to describe particular cellular regions of mammalian sperm with respect not only to location and function, but also to the molecules that are candidates for a role in that function.

Mouse sperm antigens that participate in fertilization. III. Passive immunization with a single monoclonal antisperm antibody inhibits pregnancy and fertilization in vivo.

Passive immunization was used to study the effect of antimouse sperm monoclonal antibodies on fertilization in vivo. The effects of two antibodies were compared in this investigation. One of them, M29, has been shown previously to localize to the equatorial segment of the sperm head and to inhibit mouse fertilization in vitro in a concentration-dependent manner. The second antibody, M2, binds to the same area of the sperm head, and also belongs to the M immunoglobulin class (IgM), but does not affect fertilization in vitro. Superovulated female mice received two antibody injections intraperitoneally (at the times of the pregnant mare's serum gonadotropin and human chorionic gonadotropin injections) at concentrations of 0.5-4.0 mg of IgM or control IgG; animals were mated within 6-12 h of the hCG injection. Fertilization and concomitant establishment of pregnancy were reduced significantly, in a dose-dependent manner, only in those animals immunized with M29 IgM (e.g., 4 mg M29 IgM: 12.6% of 304 eggs fertilized; 4 mg M2 IgM: 96% of 192 eggs fertilized). Intraperitoneal administration of the antibodies did not depress superovulation levels nor oocyte viability. 125I-labeled M29 IgM was used to determine the amount of antibody present in the oviductal ampulla at the time of fertilization in passively immunized mice. Luminal M29 IgM was found to be a linear function of the intraperitoneal dose: 0.002-0.003% of the injected dose was present in the oviductal lumen 14-16 h post-hCG.(ABSTRACT TRUNCATED AT 250 WORDS)