Purification and partial characterization of the 17 kDa sperm coating protein from boar seminal plasma.

Sperm coating proteins of 16, 17, and 19 kDa have been purified from boar seminal plasma. The 17 kDa protein has been identified as an antigen recognized by monoclonal antibody ACR.3 and is thus identical to low molecular mass zona pellucida binding protein from boar spermatozoa (Moos et al., 1990). The 17 and 19 kDa proteins are glycosylated and tend to form hetero-complexes. The 17 kDa ACR.3 antigen is sequentially released from the sperm cell surface during capacitation and, after induction of the acrosome reaction, the 16 kDa form was also observed. Immunocytochemical studies on boar reproductive tissues have suggested that the seminal vesicle epithelium may be the source of these proteins.     

Monoclonal antibodies to intra-acrosomal proteins inhibit gamete binding in vitro

The sperm-zona pellucida-binding assay in vitro was used as a functional test for zona pellucida-binding ability of boar spermatozoa after co-incubation with monoclonal antibodies against intra-acrosomal proteins. The effect of monoclonal antibodies ACR.2 against boar acrosin (55, 53, 45 and 38 kDa), and Hs-8 against boar intra-acrosomal protein (230, 110, 88, 60, 48 kDa) on boar spermatozoa-porcine oocyte binding was examined. The sperm-zona pellucida-binding was reduced when medium was supplemented with monoclonal antibodies during sperm-oocyte co-incubation, but not when capacitated spermatozoa were pretreated with monoclonal antibodies before incubation with oocytes. Our results show that the monoclonal antibodies (ACR.2, Hs-8) against intra-acrosomal proteins reduce the secondary sperm-zona pellucida-binding with statistically significant difference. This suggests the role of these proteins in the early phases of fertilization.     

Effect of recombinant boar beta-acrosin on sperm binding to intact zona pellucida during in vitro fertilization

In a previous paper we demonstrated that boar beta-acrosin recombinant proteins were able to bind non-enzymatically to solubilized pig zona pellucida (ZP) glycoproteins. Here we report the participation of boar beta-acrosin in the secondary binding of sperm to intact pig ZP. This was achieved by using two boar recombinant proteins: beta-acrosin and a mutant of the catalytic site, beta-acrosin Ser/Ala(222). Assays of binding between the iodinated recombinant beta-acrosin and whole ZP showed that this binding could be saturated, was specific, and was stable over time. Using autoradiography, we determined that recombinant beta-acrosin bound on the entire surface of the ZP but initially was distributed heterogeneously. This suggests that the ligands for beta-acrosin may not be homogeneously distributed on the ZP. To study the contribution of acrosin in sperm secondary binding to the ZP, we preincubated in vitro-matured oocytes with these recombinant proteins and then performed in vitro fertilization assays. Under the experimental conditions used, binding of beta-acrosin recombinant proteins did not block sperm penetration. These results suggest that there may be other proteins that participate in the secondary binding, and that these proteins may recognize ligands that are different from those blocked by beta-acrosin recombinant proteins.     

Binding of boar spermatozoa to porcine oocytes: Effect of low molecular weight 17 kDa protein

The effect of seminal plasma and low molecular weight ACR.3(17 kDa) protein on boar spermatozoa-porcine oocyte binding was examined. Boar seminal plasma that contains the sperm-adhesive ACR.3 protein was added to spermatozoa prior to their coincubation with oocytes, and the binding capacity of the spermatozoa so treated was compared to that of untreated cells. Similarly, purified ACR.3 protein, that binds to the egg zona pellucida, was added to noncapacitated spermatozoa, and the binding capacity of treated and untreated cells was again evaluated. In the two cases, the treatment of spermatozoa reduced their capacity to bind to the zona pellucida. We propose that the reduction in binding is due to competition for the ACR.3 binding sites on the zona pellucida between the soluble ACR.3 protein and the ACR.3 protein attached to the sperm surface. Furthermore, sperm-ZP binding was examined in the presence of ACR.3 monoclonal antibody, which specifically reacts with ACR.3 protein. Preliminary results show that addition of ACR.3 monoclonal antibody to a suspension of boar spermatozoa prior to their coincubation with oocytes did not markedly change sperm-zona binding in comparison with the control untreated spermatozoa. Our results suggest that ACR.3 protein may mediate the primary sperm-egg zona pellucida binding, and that it is one of the likely candidates for the primary sperm-ZP binding protein. Mol Reprod Dev 46:168–175, 1997. © 1997 Wiley-Liss, Inc.     

Biochemical and binding characteristics of boar epididymal fluid proteins

During the passage through the epididymis, testicular spermatozoa are directly exposed to epididymal fluid and undergo maturation. Proteins and glycoproteins of epididymal fluid may be adsorbed on the sperm surface and participate in the sperm maturation process, potentially in sperm capacitation, gamete recognition, binding and fusion. In present study, we separated proteins from boar epididymal fluid and tested their binding abilities. Boar epididymal fluid proteins were separated by size exclusion chromatography and by high-performance liquid chromatography with reverse phase (RP HPLC). The protein fractions were characterized by SDS-electrophoresis and the electrophoretic separated proteins after transfer to nitrocellulose membranes were tested for the interaction with biotin-labeled ligands: glycoproteins of zona pellucida (ZP), hyaluronic acid and heparin. Simultaneously, changes in the interaction of epididymal spermatozoa with biotin-labeled ligands after pre-incubation with epididymal fluid fractions were studied on microtiter plates by the ELBA (enzyme-linked binding assay) test. The affinity of some low-molecular-mass epididymal proteins (12-17 kDa and 23 kDa) to heparin and hyaluronic acid suggests their binding ability to oviductal proteoglycans of the porcine oviduct and a possible role during sperm capacitation. Epididymal proteins of 12-18 kDa interacted with ZP glycoproteins. One of them was identified as Crisp3-like protein. The method using microtiter plates showed the ability of epididymal fluid fractions to change the interaction of the epididymal sperm surface with biotin-labeled ligands (ZP glycoproteins, hyaluronic acid and heparin). These findings indicate that some epididymal fluid proteins are bound to the sperm surface during epididymal maturation and might play a role in the sperm capacitation or the sperm-zona pellucida binding.     

Zona pellucida-binding and fucose-binding of boar sperm acrosin is not correlated with proteolytic activity

The major fucose-binding protein of 53 kDa was isolated from boar spermatozoa by mild detergent extraction and subsequent high-performance gel filtration and reversed-phase high-performance liquid chromatography. This protein has been identified as high-molecular-mass acrosin by N-terminal sequencing. Treatment of the isolated protein with diisopropyl fluorophosphate abolishes the enzymatic activity but not the zona pellucida- and fucose-binding properties. Mercaptolysis and S-pyridyl-ethylation of native two-chain acrosin followed by HPLC and SDS-PAGE revealed that the binding properties are located on the acrosin heavy chain.     

Isolation of antiSLIP1-reactive boar sperm P68/62 and its binding to mammalian zona pellucida

Single-step purification of boar sperm P68/62 that is cross-reactive with a polyclonal antibody against sulfolipidimmobilizing protein 1 (SLIP1) was achieved by chromatofocusing. This method is useful for obtaining P68/62 in quantity. The two proteins, P68 and P62, were antigenically related, since the antibody generated specifically against the 68-kDa band reacted with both the 68- and 62-kDa bands. Like rat testis SLIP1, purified boar sperm P68/62 bound to sulfogalactosylglycerolipid (SGG) and inhibited sperm-egg binding in a dose-dependent manner when added exogenously to sperm-egg coincubates. This inhibitory effect occurred at the level of the zona pellucida (ZP), and further studies showed that biotinylated boar sperm P68/62 bound to the ZP of unfertilized mouse eggs. Furthermore, biotinylated boar sperm P68/62 bound to isolated ZP of unfertilized eggs from other species, including pig, rat, cat, dog, and human, as well as to ZP of intact fertilized mouse eggs and preimplantation embryos of various developmental stages, although the degree of its binding to the ZP of intact eight-cell embryos, morulae, and blastocysts was much lower than that of fertilized eggs and two-cell embryos. These results suggest that P68/62 of capacitated sperm must act together with other sperm surface proteins/molecules that regulate zona binding specificity within homologous species and in unfertilized eggs. Together with our previous findings, we suggest that rather than being a true ZP receptor, sperm P68/62 may be involved in the initial step of sperm-ZP binding that is adhesive in nature. Mol. Reprod. Dev. 49:203–216, 1998 © 1998 Wiley-Liss, Inc.     

Interference with the 19S proteasomal regulatory complex subunit PSMD4 on the sperm surface inhibits sperm-zona pellucida penetration during porcine fertilization

Proteolysis of ubiquitinated sperm and oocyte proteins by the 26S proteasome is necessary for the success of mammalian fertilization, including but not limited to acrosomal exocytosis and sperm-zona pellucida (ZP) penetration. The present study examined the role of PSMD4, an essential non-ATPase subunit of the proteasomal 19S regulatory complex responsible for proteasome-substrate recognition, in sperm-ZP penetration during porcine fertilization in vitro (IVF). Porcine sperm-ZP penetration, but not sperm-ZP binding, was blocked in the presence of a monoclonal anti-PSMD4 antibody during IVF. Inclusion in the fertilization medium of mutant ubiquitins (Ub+1 and Ub5+1), which are refractory to processing by the 19S regulatory complex and associated with Alzheimer’s disease, also inhibited fertilization. This observation suggested that subunit PSMD4 is exposed on the sperm acrosomal surface, a notion that was further supported by the binding of non-cell permeant, biotinylated proteasomal inhibitor ZL3VS to the sperm acrosome. Immunofluorescence localized PSMD4 in the sperm acrosome. Immunoprecipitation and proteomic analysis revealed that PSMD4 co-precipitated with porcine sperm-associated acrosin inhibitor (AI). Ubiquitinated species of AI were isolated from boar sperm extracts by affinity purification of ubiquitinated proteins using the recombinant UBA domain of p62 protein. Some proteasomes appeared to be anchored to the sperm head inner acrosomal membrane, as documented by co-fractionation studies. In conclusion, the 19S regulatory complex subunit PSMD4 is involved in the sperm-ZP penetration during fertilization. The recognition of substrates on the ZP by the 19S proteasomal regulatory complex is essential for the success of porcine/mammalian fertilization in vitro.     

Monoclonal antibodies to rabbit and pig zonae pellucidae distinguish species-specific and shared antigenic determinants

Monoclonal antibodies against rabbit or porcine zonae pellucidae (ZP) demonstrate species-specific and shared antigenic determinants. In addition, these antibodies are used to characterize the biochemical nature of these determinants. All of six monoclonal antibodies developed against porcine ZP react with porcine but not with rabbit ZP. Only one of seven monoclonal antibodies developed against rabbit ZP cross-reacts with porcine ZP. None of these antibodies recognized antigens associated with other tissues tested. High-resolution, two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) followed by immunoblotting was used to demonstrate that the cross-reactive antibody recognizes an antigenic determinant which is associated with the major low molecular weight glycoprotein of both the pig and rabbit ZP. Since this antibody recognizes all charge species of this glycoprotein, it is apparent that the antigenic determinant recognized by this antibody involves protein. Further studies demonstrate that proteolytic digestion of ZP will destroy the antigenic determinant while glycosidic digestion of ZP has no effect on antibody binding. Although polyclonal antibodies to this glycoprotein inhibit sperm from binding to the zona pellucida, this monoclonal antibody does not affect sperm binding. None of the species-specific antibodies recognize ZP glycoproteins following 2D-PAGE. This is a property typical of antibodies directed against conformational antigenic determinants. The presence of common as well as unique zona antigenic determinants could explain why ZP proteins induce heteroantibodies which result in infertility while alloimmunization has no effect on fertility.     

猪精子中与卵透明带糖蛋白ZP3结合的蛋白质

依次经ＰＳＬ－Ｓｅｐｈａｒｏｓｅ亲和层析柱和纤维素ＣＭ－５２离子交换层析柱,从猪精子的ＣＨＡＰＳ抽提液分离得４个蛋白质组分。用固相透明带精蛋白结合试验（ＩＺＰＧＢＡ）检测;表明精子蛋白ＳＰ１和ＳＰ２具有结合透明带糖蛋白ＺＰ３的活性,ＳＰ２并显示凝集血球的活性。精子蛋白ＳＰ１与卵预温育明显抑制精卵结合,抑制活性与加入的精子蛋白的浓度呈正相关。用生物素标记的ＺＰ３和蛋白质印迹技术,证明ＳＰ１中的６８ｋＤ精子蛋白与ＺＰ３结合,提示６８ｋＤ精子蛋白参与精卵结合。     

Two-dimensional polyacrylamide gel electrophoresis characterization of APz, a sperm protein involved in zona binding in the pig and evidence for its binding to specific zona glycoproteins

A boar sperm integral plasma membrane protein (APz) involved in the adhesion of uncapacitated and capacitated sperm to the porcine zona pellucida (ZP) has been characterized by two-dimensional polyacrylamide gel electrophoresis (PAGE) and tested for its ability to bind to various zona glycopeptides. APz shows microheterogeneity and focuses over a wide pH range, with predominant forms focusing above pH 7. The protein, when excised from nonreducing polyacrylamide gels, inhibited sperm-egg binding and bound heat-solubilized zonae preventing these zonae from blocking sperm binding to eggs. In an indirect assay, a polyclonal monovalent antibody, which blocks sperm-egg binding and which is absorbed by APz, was used to determine the ability of zona glycopeptides to prevent the sperm-egg blocking activity of the antibody from being absorbed by intact sperm. When whole heat-solubilized ZP was added to sperm at doses that block sperm-egg binding and the excess ZP was removed, the sperm-egg blocking activity of the antibody was not absorbed by these sperm, and antibody-containing supernatants blocked the binding of untreated sperm to eggs as effectively as antibody that was not mixed with fresh sperm. When alpha ZP3 was used in the same manner, sperm-egg blocking activity again was not absorbed by antibody-treated cells. Beta ZP3, however, failed to block sperm-egg binding and failed to absorb the sperm-egg blocking activity of the antibody. These findings support the argument that the action of APz is physiologically significant and involves specific binding sites on the ZP3 component of the ZP.     

Expression in Escherichia coli and immunological characterization of three zona pellucida proteins (ZP1, ZP2, and ZP3) from a marsupial,the brushtail possum (Trichosurus vulpecula)

The brushtail possum (Trichosurus vulpecula) zona pellucida (ZP) is composed of three major glycoproteins, designated ZP1, ZP2, and ZP3 based on their size and homology with eutherian ZP proteins. These proteins are candidate antigens for the development of an immunocontraceptive vaccine to control the fertility of the brushtail possum in New Zealand, where it is an introduced pest. In order to further their immunological and functional characterization, recombinant possum ZP proteins were produced in Escherichia coli (E. coli) strain JM109, M15, SG13009, or BL21 codon plus. Each of the proteins produced possessed a N-terminal six histidine tag (His)(6) to facilitate purification and consisted of amino acid (aa) residues 18-471 of possum ZP1, aa residues 40-311 of ZP2 (ZP2-N), aa residues 305-634 of ZP2 (ZP2-C), and aa residues 23-342 of ZP3. Immunoblot using anti-RGS(His)(4) antibodies and polyclonal rabbit anti-porcine ZP antibodies detected major bands at 54 kDa for ZP1, 32 kDa for ZP2-N, 39 kDa for ZP2-C, and 40 kDa for ZP3. Immunization of male and female rabbits with ZP2-N, ZP2-C, and ZP3 purified on Ni-NTA resin under denaturing conditions generated antibodies reactive with recombinant ZP proteins on Western blot and with native ZP proteins in possum ovarian sections using immunofluorescence. Antibodies generated against ZP1 in the same way were reactive with recombinant ZP proteins on Western blot only. The recombinant possum ZP proteins and specific antibodies produced in this study give an indication of the antigenic relationship of the possum ZP proteins and are vital tools for future studies of sperm-ZP binding in marsupials and for the evaluation of ZP-based contraceptive vaccines in possums and other marsupials.     

Characterization of equine zona pellucida glycoproteins by polyacrylamide gel electrophoresis and immunological techniques.

This study was designed to explore the composition of the equine zona pellucida (EZP) by one- and two-dimensional polyacrylamide gel electrophoresis (1D- and 2D-PAGE), silver staining and immunoblotting techniques. Antral follicles palpable on frozen-thawed equine ovaries were aspirated with a needle and syringe, and the resultant follicular fluid, cellular material and oocytes were pooled. Oocytes were placed in Petri dishes, moved by narrow-bore pipette to droplets of phosphate-buffered saline (PBS) and mechanically cleaned of cumulus cells. The EZP from these collected oocytes was solubilized, and then analysed by 1D- and 2D-PAGE. Silver stained 2D-PAGE of the EZP revealed the presence of three EZP glycoprotein families of apparent molecular mass ranges of 93-120 kDa, 73-90 kDa and 45-80 kDa. Immunoblot analysis of EZP glycoproteins resolved by 2D-PAGE using rabbit antisera against pig zonae pellucidae (R alpha HSPZ) confirmed the presence of three EZP glycoprotein families and established the existence of common epitopes between equine and porcine ZP glycoproteins. Further immunodetection using 2D-PAGE-separated glycoproteins illustrated that the 45-80 kDa family is recognized by the monoclonal antibody R5, developed against the porcine ZP glycoprotein of molecular mass 55-120 kDa. Guinea-pig antiserum against endo-beta-galactosidase-treated rabbit ZP 55 kDa glycoprotein (R55K), which specifically recognizes the rabbit ZP glycoprotein with the lowest molecular mass, also recognized the EZP 45-80 kDa glycoprotein family. Guinea-pig polyclonal antisera developed against total heat-solubilized rabbit ZP (GP alpha HSRZ) recognized the 73-90 kDa EZP glycoprotein family exclusively. After heat solubilization and treatment of EZP with endo-beta-galactosidase to remove polylactosaminoglycans, silver stained 1D-PAGE again demonstrated the presence of three glycoproteins with apparent molecular masses of 60, 75 and 90 kDa. The partially deglycosylated 60 kDa equine glycoprotein is recognized on immunoblot by the monoclonal antibody R5; the 75 kDa EZP glycoprotein is recognized by GP alpha HSRZ; and all three EZP glycoproteins separated by 1D-PAGE are recognized by R alpha HSPZ. These data add further support to the concept of cross-species zona pellucida glycoprotein antigenicity.     

Porcine zona pellucida ZP3α glycoprotein mediates binding of the biotin-labeled Mr 55,000 family (ZP3) to boar sperm membrane vesicles

The two M_r 55,000 glycoproteins, ZP3α and ZP3b?, of porcine zona pellucida copurify as a preparation designated ZP3. Gamete binding assays have implicated ZP3α, but not ZP3b?, as participating in sperm-zona recognition events. We now report that boar sperm contain membrane-associated binding sites with specificity for ZP3α. Biotin-labeled (b-) preparations of ZP3 bind to intact boar sperm in a saturable manner, with localization on the anterior head region. Membrane vesicles obtained from capacitated sperm by nitrogen cavitation retain b-ZP3 binding sites as determined by an enzyme-linked method employing alkaline phosphatase-conjugated strepavidin. In competitive binding assays using b-ZP3 (0.1μg/ml) as probe, heat-solubilized zonae and ZP3 were effective competitors, whereas the nonzona molecules fetuin and fucoidin were not. Digestion of ZP3 with endo-b?-galactosidase, an enzyme that trims polylactosamines, enhanced its affinity for membrane receptors. In contrast treatments such as chemical deglycosylation, pronase digestion, or disruption of disulfide bonds abolished the ligand activity of ZP3. Finally, purified ZP3α was an at least 100-fold better antagonist than purified ZP3b?. The results demonstrate that binding of b-ZP3 to isolated boar sperm membranes is mediated by sperm receptors with specificity for the ZP3α macromolecular component and reveal a complex contribution of both carbohydrate and protein moieties toward the ligand activity of this sperm adhesive zona molecule. © 1993 Wiley-Liss, Inc.     

Functional interactions between sulphated polysaccharides and proacrosin: implications in sperm binding and digestion of zona pellucida.

Acrosin is a serine protease located within mammalian acrosome as inactive proacrosin. Sulphated polymers bind to proacrosin and acrosin, to a domain different from the active site. Upon binding, these polymers induce proacrosin activation and some of them, such as fucoidan, inhibit sperm binding to the zona pellucida. In this work we have studied the interaction of solubilised zona pellucida glycoproteins (ZPGs), heparin and ARIS (Acrosome Reaction Inducing Substance of Starfish) with boar and human acrosin. We have found that ARIS, solubilised ZPGs and fucoidan, but not heparin, inhibit the binding of the monoclonal antibody against human acrosin C5F10 to boar or human proacrosin. These results suggest that fucoidan, solubilised ZPGs and ARIS bind to a related domain on the proacrosin surface. Moreover, ARIS was able to induce human proacrosin activation. On the other hand, neither ARIS nor heparin from porcine intestinal mucosa or bovine lung induced hamster sperm acrosome reaction or sperm motility. Recent data showed that acrosin is involved in dispersal of the acrosomal matrix after acrosome reaction. Thus, the control of the ZPG glycan chains over proacrosin activation may regulate both sperm penetration rate and limited proteolysis of zona pellucida proteins.     

Egg extracellular coat proteins: from fish to mammals

The extracellular coat surrounding fish (vitelline envelope; VE) and mammalian (zona pellucida; ZP) eggs is composed of long, interconnected filaments. Fish VE and mammalian ZP proteins that make up the filaments are highly conserved groups of proteins that are related to each other, as well as to their amphibian and avian egg counterparts. The rainbow trout (O. mykiss) egg VE is composed of 3 proteins, called VEalpha (approximately 58 kDa), VEbeta (approximately 54 kDa), and VEgamma (approximately 47 kDa). The mouse (M. musculus) egg ZP also is composed of 3 proteins, called ZP1 (approximately 200 kDa), ZP2 (approximately 120 kDa), and ZP3 (approximately 83 kDa). Overall, trout VE and mouse ZP proteins share approximately 25% sequence identity and have features in common; these include an N-terminal signal sequence, a ZP domain, a consensus furin cleavage-site, and a C-terminal tail. VEalpha, VEbeta, and ZP1 also have a trefoil or P-type domain upstream of the ZP domain. VEalpha and VEbeta are very similar in sequence (approximately 65% sequence identity) and are related to ZP1 and ZP2, whereas VEgamma is related to ZP3 (approximately 25% sequence identity). Mouse ZP proteins are synthesized and secreted exclusively by growing oocytes in the ovary. Trout VE proteins are synthesized by the liver under hormonal control and transported in the bloodstream to growing oocytes in the ovary. The trout VE is assembled from VEalpha/gamma and VEbeta/gamma heterodimers. The mouse ZP is assembled from ZP2/3 heterodimers and crosslinked by ZP1. Despite approximately 400 million years separating the appearance of trout and mice, and the change from external to internal fertilization and development, trout VE and mouse ZP proteins have many common structural features; as do avian and amphibian egg VE proteins. However, the site of synthesis of trout and mouse egg extracellular coat proteins has changed over time from the liver to the ovary, necessitating some changes in the C-terminal region of the polypeptides that regulates processing, secretion, and assembly of the proteins.     

Expression of progesterone receptor(s) during capacitation and incidence of acrosome reaction induced by progesterone and zona proteins in boar spermatozoa

Sperm acrosome reaction (AR) is a prerequisite step for in vivo fertilization. In the vicinity of the oocyte, zona protein(s) (ZP) and progesterone (P4), a component of follicular fluid, are proven to be responsible for physiological AR induction. In the present study, a thorough analysis of the role of the progesterone receptor (PR) in this processing including in vitro physiological studies and biochemical isolation and characterization of the receptor protein was conducted. Following capacitation for 0, 2, 4 and 6h, pooled fertile boar semen samples (n=6) with >70% sperm motility were labeled with P4-BSA-FITC (100 microg/ml) to detect the activation of PR. Parallel sperm samples were treated with P4 (10 microg/ml) for 20 min to test AR inducing efficiency at different time points. To compare the ability of ZP and P4 to induce AR, spermatozoa capacitated in a modified medium supplemented with 1mg/ml heparin for 4h, were then treated with heat solubilized ZP (150 microg/ml), P4 (10 microg/ml) or ZP+P4 for 20 min. FITC-peanut agglutinin staining was applied to observe the disrupt acrosomal morphology. A purification protocol for crude boar sperm membrane proteins was developed based on ligand-receptor affinity chromatography procedures. The PR proteins were then identified by using mAb C262 raised against intracellular PR, combined with second antibody (SDS-PAGE, Western blotting). Their N-terminal amino acid sequence was determined. The amount of PR-activated spermatozoa was enhanced with time (onset: 27+/-5%, 2h: 41+/-4%, 4h: 49+/-3% and 6h: 52+/-4%, mean+/-S.E., n=6) as evidenced by increasing percentage of spermatozoa with completed cap fluorescent staining. In parallel sperm samples, percentages of AR induced by P4 were 9+/-2, 14+/-2, 18+/-2, and 24+/-2%, respectively. In solvent control at all time points, less than 10% spermatozoa had undergone AR. Capacitation for 4h or greater time periods resulted in optimal percentage of PR-activated and acrosome-reacted spermatozoa. After sperm incubation in heparin-medium, ZP+P4 treatment induced greater amounts of AR than either P4 or ZP alone (13+/-1% compared with 8+/-1 and 10+/-1%, P<0.01). Inducing capacity of P4 was comparable to that of ZP. The molecule weights of two apparent PR molecular masses were detected to be at Mr 74 kDa and Mr 63 kDa. N-terminal amino acid sequence of 74 kDa protein was XPXNIVLIFADXLXY, which had 78% homology to arylsulfatase A and 88% homology to 72 kDa protein from boar spermatozoa. The activation of PR is associated with the capacitating process and that appears to be required for P4-induced AR. P4 and ZP appear to be equally capable of independently inducing the AR but lack synergetic or additive effects in this induction process. Both might represent alternative pathways thus resulting in alternative systems for induction of the prerequisite acrosomal exocytosis (supported by NSC 90-2313-B-005-114; 91-2313-B-005-131).     

Characterization of the functional domains of boar acrosin involved in nonenzymatic binding to homologous zona pellucida glycoproteins

During the first steps of the gamete interaction, the proacrosin/acrosin system seems to play a crucial role in the secondary binding, holding acrosome-reacted spermatozoa during their passage through the zona pellucida. To analyze the functional domains of acrosin, we decided to express recombinant boar acrosin proteins in bacteria and to study their binding capacities to zona pellucida glycoproteins (ZPGPs). The expressed proteins were immunodetected by Western blot with a polyclonal antiacrosin antibody. The recombinant truncated β-acrosin has a typical hyperbolic curve of a zymogen enzymatic activation. Three of the five recombinant forms (truncated β-acrosin, Ser/Ala²²²-truncated β-acrosin, and truncated β-acrosin “heavy chain”) had the ability to bind ZPGPs. The two shorter forms (the amino and carboxy termini of truncated β-acrosin) failed to bind. The catalytic site mutant (Ser/Ala²²²) of truncated β-acrosin does not differ from the recombinant truncated β-acrosin in its mechanism of interaction to ZPGPs, indicating that this secondary binding is done by a nonenzymatic process. Our results show that binding between acrosin and ZPGPs depends on the secondary and tertiary structures of acrosin and does not depend on an active catalytic site. Mol. Reprod. Dev. 49:426–434, 1998. © 1998 Wiley-Liss, Inc.     

Activation of boar proacrosin is effected by processing at both N- and C-terminal portions of the zymogen molecule

A mixture of 55 and 53 kDa boar proacrosins was autoactivated at pH 8.5 to produce a 43 kDa intermediate form and a 35 kDa mature acrosin, and each of four forms of (pro)acrosins was isolated. Analysis of the N-terminal sequences of the two proacrosins indicated the existence of a segment corresponding to the acrosin light chain at the N-terminal end of the zymogen. Two N-terminal sequences identical with those of the light and heavy chains were found in the intermediate form and mature acrosin. The proacrosins and the intermediate contained many more proline residues than the mature enzyme. These results indicate that the activation of boar acrosin zymogen is achieved by the removal of a C-terminal segment rich in proline residues and by the cleavage of the Arg23-Val24 bond leading to the formation of the light and heavy chains.