Proacrosin/acrosin activity during spermiohistogenesis of the bull

Ligands and Receptors Involved in the Sperm-Zona Pellucida Interactions in Mammals

Sperm-zona pellucida (ZP) interaction, involving the binding of sperm surface ligands to complementary carbohydrates of ZP, is the first direct gamete contact event crucial for subsequent gamete fusion and successful fertilization in mammals. It is a complex process mediated by the coordinated engagement of multiple ZP receptors forming high-molecular-weight (HMW) protein complexes at the acrosomal region of the sperm surface. The present article aims to review the current understanding of sperm-ZP binding in the four most studied mammalian models, i.e., murine, porcine, bovine, and human, and summarizes the candidate ZP receptors with established ZP affinity, including their origins and the mechanisms of ZP binding. Further, it compares and contrasts the ZP structure and carbohydrate composition in the aforementioned model organisms. The comprehensive understanding of sperm-ZP interaction mechanisms is critical for the diagnosis of infertility and thus becomes an integral part of assisted reproductive therapies/technologies.

Cell biology of acrosomal proteins

Acrosin is a multifunctional enzyme combining several functional properties within a single molecule: the catalytic triad of the proteinase, hydrophobic domains responsible for the special membrane-associating character of the enzyme and the carbohydrate binding sites by which the molecule can bind to the zona pellucida. Acrosin occurs in the sperm acrosome as an inactive precursor, proacrosin, with a molecular mass of 53-55 kDa. Proacrosin is activated by a single proteolytic clip between Arg23 and Val24 generating the high molecular mass acrosin. The activation of proacrosin to the biologically active enzyme which occurs concomitantly with the acrosome reaction appears to be regulated on and by the zona pellucida. It is hypothesized that alternating cycles of binding to the zona, digestion of the zona and release from the zona together with the forward motility of the spermatozoon would be required to achieve penetration.

The Golgi apparatus segregates from the lysosomal/acrosomal vesicle during rhesus spermiogenesis: structural alterations

The acrosome is an acidic secretory vesicle containing hydrolytic enzymes that are involved in the sperm's passage across the zona pellucida. Imaging of the acrosomal vesicle and the Golgi apparatus in live rhesus monkey spermatids was accomplished by using the vital fluorescent probe LysoTracker DND-26. Concurrently, the dynamics of living spermatid mitochondria was visualized using the specific probe MitoTracker CMTRos and LysoTracker DND-26 detected the acrosomal vesicle from its formation through spermatid differentiation. LysoTracker DND-26 also labeled the Golgi apparatus in spermatogenic cells. In spermatocytes the Golgi is spherical and, in round spermatids, it is localized over the acrosomal vesicle, as confirmed by using polyclonal antibodies against Golgin-95/GM130, Golgin-97, and Golgin-160. Using both live LysoTracker DND-26 imaging and Golgi antibodies, we found that the Golgi apparatus is cast off from the acrosomal vesicle and migrates toward the sperm tail in elongated spermatids. The Golgi is discarded in the cytoplasmic droplet and is undetectable in mature ejaculated spermatozoa. The combined utilization of three vital fluorescent probes (Hoechst 33342, LysoTracker DND-26, and MitoTracker CMTRos) permits the dynamic imaging of four organelles during primate spermiogenesis: the nucleus, the mitochondria, the acrosomal vesicle, and the Golgi apparatus.

Spermatozoa lacking acrosin protein show delayed fertilization

Acrosin (ACR), a serine proteinase located in the acrosome of the sperm, has been presumed to be involved in the recognition and binding of the sperm to the zona pellucida of the ovum and the sperm penetration through the zona pellucida. To examine the function of acrosin in vivo, we have generated mice carrying a mutation at the acrosin locus (Acr) through targeted disruption in embryonic stem (ES) cells. One chimeric male and female transmitted the targeted gene through their germ line. Homozygous Acr-/- mice are fertile and yield litters comparable in number and size to those of Acr+/+ mice. These data show that sperm of the homozygous Acr-/- mice are able to penetrate the zona pellucida, fertilize the ovum, and produce viable offspring. However, spermatozoa lacking acrosin protein show a delayed fertilization. One chimeric male which contained the targeted gene in 20% of its sperm transmitted only the Acr+ allele to its progeny. Furthermore, in vitro fertilization with equally mixed sperm cells of Acr+/+ and Acr-/- mice resulted in fertilization only with the Acr+ sperm cells. Incubation of oocytes with Acr+ or Acr- sperm show that the Acr+ sperm are faster to fertilize the oocytes than the Acr- sperm cells. These results suggest that Acr- sperm have a selective disadvantage when they are in competition with Acr+ sperm.

Evaluation of the acrosomal membrane in bovine spermatozoa: Effects of proteinase inhibitors

Thawed bovine spermatozoa are characterized by a lack of homogeneity in the acrosomal membrane. Therefore, it is difficult to visualize the acrosome to assess morphology. Synthetic proteinase inhibitors were tested on thawed bovine semen for their effect on the integrity of acrosomal membranes. The proteinase inhibitors 4-nitrophenyl-4-guanidinobenzoate (NPGB) and N-L-p-tosyl-L-lysine-chloromethylketone (TLCK) were added to a medium containing spermatozoa separated on a percoll gradient. After incubation for 30 min at 38 degrees C in 5% CO(2), 95% air (final concentration 1 mM), the action of these inhibitors was controlled by measuring the activity of acrosome proteinases. The acrosomal membrane was evaluated by means of a dual stain procedure (trypan blue, Giemsa). In contrast to spermatozoa that had been incubated with proteinase inhibitor-free solution, samples that had been incubated with TLCK showed homogeneity in 90% of the acrosomal membranes and excellent visualization of the acrosome itself; in the NPGB-treated samples, homogeneous staining was observed in 83% of spermatozoa (P < 0.0005). It is concluded that alteration of the acrosomal membrane in thawed semen is not directly caused by freezing-thawing, but may be due to activation of acrosomal proteinases, which is increased during staining procedures. The addition of proteinase inhibitors before staining offers a new possibility for improved assessment of the acrosome in bovine spermatozoa.

Acrosin, the peculiar sperm-specific serine protease

The sperm enzyme acrosin has long been known as one of the key enzymes in the mammalian fertilization process. Elucidation of primary structures of preproacrosin from various species have allowed a deeper insight into the structural organization and the complex evolution of the sperm proteinase acrosin. In addition to the typical elements of serine proteases, the acrosin molecule possesses one novel domain that might convey DNA-binding properties.

Guinea pig proacrosin is synthesized principally by round spermatids and contains O-linked as well as N-linked oligosaccharide side chains

Proacrosin is the zymogen precursor of acrosin, a sperm protease believed to play an essential role in fertilization. In this study, we used primary cultures of guinea pig spermatogenic cells to examine the temporal appearance and mechanisms of synthesis and processing of proacrosin during acrosome development. Following [35S]methionine incorporation and immunoprecipitation, cultured spermatogenic cells were found to synthesize two forms of proacrosin (Mr 54,000 and 57,000). Proacrosin was synthesized mainly by round spermatids. By immunoblotting, proacrosin became very prominent in round spermatids and persisted throughout spermiogenesis. Pulse-chase experiments demonstrated that the Mr 54,000 form of proacrosin was converted to the Mr 57,000 form, presumably reflecting posttranslational processing of carbohydrate side chains. When spermatogenic cells were cultured in the presence of tunicamycin, the synthesized proacrosin had an Mr of 54,000. However, in vitro translation of mRNA extracted from guinea pig testis followed by immunoprecipitation indicated that the core polypeptide of proacrosin has an Mr of 44,000. Guinea pig spermatogenic cells incorporated glucosamine and fucose into the oligosaccharides of proacrosin. Treatment of guinea pig testis proacrosin with N-glycosidase or O-glycosidase reduced the Mr by 3-7%. These results indicate that proacrosin is synthesized by postmeiotic cells and the enzyme contains N- and O-linked oligosaccharides.

Acrosin biosynthesis in meiotic and postmeiotic spermatogenic cells

It has been widely accepted that mammalian sperm acrosin is first synthesized only in the postmeiotic stages of spermatogenic cells. In this study, we carried out Northern blot analysis of RNAs prepared from purified populations of mouse spermatogenic cells. The acrosin mRNA was obviously found in meiotic pachytene spermatocytes, and the mRNA content markedly increased in postmeiotic round spermatids. Also, the acrosin mRNA in pachytene spermatocytes was functionally associated with polysomes. These results provide evidence that acrosin biosynthesis is already started in meiotic cells and continues through the early stages of spermiogenesis.

Nucleotide sequences and expression of cDNA clones for boar and bull transition protein 1 and its evolutionary conservation in mammals

During spermatogenesis, the nucleoproteins undergo several dramatic changes as the germinal cells differentiate to produce the mature sperm. With nuclear elongation and condensation, the histones are replaced by basic spermatidal transition proteins, which are themselves subsequently replaced by protamines. We have isolated cDNA clones for one of the transition proteins, namely for TP1, of bull and boar. It turned out that TP1 is a small, but very basic protein with 54 amino acids (21% arginine, 19% lysine) and is highly conserved during mammalian evolution at the nucleotide as well as at the amino-acid level. Gene expression is restricted to the mammalian testis, and the message first appears in round spermatids. Thus production of TP1 is an example of haploid gene expression in mammals. The size of the mRNA for TP1 was found to be identical in 11 different mammalian species at around 600 bp. Hybridization experiments were done with cDNAs from boar and bull, respectively. The positive results in all mammalian species give further evidence for the conservation of the TP1 gene during mammalian evolution and its functional importance in spermatid differentiation.

Proacrosin/acrosin during guinea pig spermatogenesis

Enriched populations of guinea pig spermatogenic cells were isolated by sedimentation velocity at unit gravity. Each cell population was analyzed for the presence of members of the proacrosin/acrosin family by enzymography, immunoblotting, and immunofluorescence. Following sodium dodecyl sulfate-polyacrylamide gel electrophoresis in gels containing 0.1% gelatin, protease activities with molecular weights of 55,000 (major) and 50,000 (minor) were detected in round spermatid extracts. Condensing spermatid extracts contained protease activities with molecular weights between 55,000 and 50,000. These major protease activities had molecular weights similar to antigens detected by immunoblotting with a monospecific rabbit antiserum directed against purified boar acrosin. Extracts of guinea pig sperm and the soluble acrosomal components released following the acrosome reaction induced with ionophore A23187 contained three major protease activities (Mr 32,000, 34,000, 47,000) but only the 47,000 Mr protease cross-reacted with the antibody. The spermatid and sperm protease activities were inhibited and activated by classical effectors of acrosin activity from other species. Immunofluorescence demonstrated that proacrosin/acrosin was present as early as the Golgi phase of spermiogenesis. In addition, immunoreactivity was confined to the acrosomes in a manner characteristic of each spermatid stage. These results demonstrate that proacrosin/acrosin can be detected in the earliest spermiogenic stages by electrophoretic and immunological techniques and suggest that changes in the molecular weights of proacrosin/acrosin occur as spermatids mature.

Ultrastructural localization of labeled acrosomal glycoproteins during in vivo fertilization in the rabbit

Rabbit spermatozoa were labeled predominantly in their acrosomal glycoproteins by 1-3H-glucosamine during spermiogenesis. Ova fertilized in vivo by spermatozoa labeled 22 days earlier were analyzed by fine-structure autoradiography for the localization of the label. The latter was found associated with 1) the fused membranes of the acrosomal cap remaining on the zona pellucida surface, 2) the material released on the zona surface after the acrosome reaction and possibly detectable after tannic acid fixation, 3) the equatorial segment of the sperm head and the preequatorial swellings, and 4) other sperm components, eg, the sperm tail. No labeling, on the other hand, was detected on the denuded leading edge of spermatozoa found either in the penetration slit or in the perivitelline space. Our observations suggest the involvement of acrosomal glycoproteins in different mechanisms of sperm/zona pellucida interaction but are not in favor of a major role of (enzymatic) glycoproteins bound to the inner acrosomal membrane during the penetration of the zona pellucida.

On the interaction of bull and boar acrosins with the zona pellucida of different mammalian species in vitro

Acrosin was prepared from boar and bull spermatozoa and its lytic effect in vitro on the zona pellucida of mouse, golden hamster, rabbit, pig and cow was investigated. Depending upon the species studied, ovarian oocytes, ovulated oocytes and preimplantation embryos were obtained for the experiments. While in golden hamster and rabbit the zona pellucida was removed by both acrosins, this effect was absent for bull acrosin in cow and mouse eggs and for boar acrosin in pig and mouse eggs. In those species in which the zona pellucida was not removed by the acrosins after an incubation period of 2 hours even a prolongation up to 24 hours with higher amounts of acrosin, the addition of acrosomal extracts to the incubation buffer (Tyrode solution pH 7.2) or an increase of the pH value up to 8.6 of the acrosin solution had no effect upon the zona pellucida. Our results indicate that at least in vitro, acrosin does not possess the capacity to lyse the zona pellucida in a species specific fashion. Since the lytic effect of boar and bull acrosin on the zona pellucida of ovarian oocytes and preimplantation embryos is not different from that on ovulated oocytes it can be assumed that neither the maturation of the zona pellucida during oogenesis nor its modification after fertilization, change the susceptibility of the zona pellucida to acrosin digestion.

On the teratogenesis of round-headed spermatozoa: investigations with antibodies against acrosin, an intraacrosomally located acrosin-inhibitor, and the outer acrosomal membrane

Acrosin, the outer acrosomal membrane (OAM) and an acrosin inhibitor were studied in testicular cells and ejaculated spermatozoa of fertile men and in those of an infertile patient with exclusively round-headed spermatozoa in his ejaculates. The investigations were performed with the aid of immunohistochemical techniques using specific antibodies against the three acrosomal markers isolated from boar spermatozoa. The spermatozoa of fertile men exhibit staining for acrosin, the OAM and the acrosin inhibitor in the cap region while the round-headed spermatozoa of the patient are totally negative for the three markers, clearly supporting the conclusions of other authors that round-headed spermatozoa lack acrosomes. The lack of the acrosin system was further substantiated by the gelatin substrate film technique. In the course of normal human spermatogenesis acrosin, the OAM and the acrosin inhibitor we first demonstrable in early round spermatids, namely in identical compartments adjacent to the cell nucleus. During spermatid differentiation the staining for the three markers becomes flattened over the nucleus, resulting in a cap-like structure in testicular spermatozoa. In contrast to the ejaculated round-headed spermatozoa, the early round spermatids in the testis of the infertile patient exhibit fluorescent staining for the three markers in the region adjacent to the nuclear membrane. In the course of further spermiogenesis, the staining did not extend over the nuclear membrane, as was observed during normal spermiogenesis, but became separated from the nuclear membrane, as was observed during normal spermiogenesis, but became separated from the nuclear membrane, was translocated at various locations in the cytoplasm and was finally eliminated with the loss of the cytoplasm. These results are in accordance with the results of electron microscopically investigations on the teratogenesis of round-headed spermatozoa. Furthermore, the developmental pattern of the acrosin inhibitor during normal and abnormal spermiogenesis supports the intraacrosomal location of the acrosin inhibitor recently described by Tschesche et al. (1982).

Biochemical and genetic investigation of round-headed spermatozoa in infertile men including two brothers and their father

Acrosin and the outer acrosomal membrane (OAM) were studied in the spermatozoa of 9 infertile patients who differed in the number of round-headed spermatozoa between 14 and 71% in their ejaculates. These sperm components were also investigated in two infertile brothers who exhibited exclusively round-headed spermatozoa in their ejaculates, and in their fertile father. It turned out that round-headed spermatozoa lack both acrosin and the OAM as studied by indirect immunofluorescent and immunoperoxidase staining technique, gelatinolysis tests and by acrosin activity measurements. The normally shaped spermatozoa of 6 of the 9 infertile patients were found to be positive for acrosin and the OAM as expected, but in the remaining three patients even these spermatozoa were abnormal; in one patient they were unstainable for acrosin and in two patients they were unstainable both for acrosin and the OAM. These results have been confirmed by studies with the gelatinolysis test. The father of the two brothers with exclusively acrosomeless spermatozoa had more than 94% of normally shaped spermatozoa. However, only 10% of these spermatozoa were acrosin positive and only 30% were positive for the OAM. On the basis of these results we postulate that the mode of inheritance of the round-headed spermatozoa syndrome is polygenic rather than monogenic as suggested by previous authors.

Acrosin and the acrosome in human spermatogenesis

Using the indirect immunofluorescent staining technique, the developmental patterns of (pro) acrosin and the outer acrosomal membrane were studied in human spermatogenesis. Specific antibodies against purified acrosin and outer acrosomal membranes from boar spermatozoa were raised in the rabbit and were found to crossreact with (pro)acrosin and outer acrosomal membrane from human spermatogenic cells. It was concluded that (pro)acrosin as well as the molecules building up the outer acrosomal membrane have been highly conserved during mammalian evolution. In the course of human spermatogenesis (pro)acrosin as well as the outer acrosomal membrane first appear in the haploid spermatids; the fluorescent areas of the individual cells steadily increase during spermiogenesis. Staining for acrosin and the outer acrosomal membrane, respectively, was found in identical compartments of the spermatogenic cells in juxtaposition to the nucleus. Round-headed spermatozoa from an infertile patient did not stain for (pro)acrosin or outer acrosomal membrane. The lack of the acrosin system was further substantiated by the gelatin substrate film technique demonstrating the absence of a gelatinolytic protease in round-headed spermatozoa. Hence, round-headed spermatozoa lack the acrosome with its constituent membrane proteins and the acrosin system housed by the acrosome of normal spermatozoa.