Acrosin in the spermiohistogenesis of mammals

Abstract. Using the indirect immunofluorescence staining technique, the developmental pattern of acrosin during spermatogenesis of boar, ram, rabbit, mouse, rat, and Russian hamster ( Phodopus sungorus ) was studied. Specific antibodies against purified boar acrosin raised in rabbits crossreacted with the acrosin of all species investigated thus suggesting that the antigenic determinants of the acrosin molecule cross-reacting with anti-boar acrosin antiserum have been highly conserved in mammalian evolution. During spermatogenesis acrosin was first demonstrable in haploid spermatids and increased in the course of the differentiation of the spermatids to spermatozoa. During the entire period of spermatid differentiation acrosin appeared in juxtaposition to the nucleus. In boar and ram the results obtained with the indirect immunofluorescence staining procedure were confirmed with the indirect immunoperoxidase staining method.     

Acrosin in the spermiohistogenesis of mammals

Using the indirect immunofluorescence staining technique, the developmental pattern of acrosin during spermatogenesis of boar, ram, rabbit, mouse, rat, and Russian hamster (Phodopus sungorus) was studied. Specific antibodies against purified boar acrosin raised in rabbits cross-reacted with the acrosin of all species investigated thus suggesting that the antigenic determinants of the acrosin molecule cross-reacting with anti-boar acrosin antiserum have been highly conserved in mammalian evolution. During spermatogenesis acrosin was first demonstrable in haploid spermatids and increased in the course of the differentiation of the spermatids to spermatozoa. During the entire period of spermatid differentiation acrosin appeared in juxtaposition to the nucleus. In boar and ram the results obtained with the indirect immunofluorescence staining procedure were confirmed with the indirect immunoperoxidase staining method.     

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.     

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.     

Facteurs impliqués dans le remodelage de la chromatine au cours de la spermiogenèse

Round spermatids are post-meiotic cells with a haploid genome contained in a nucleus, with a structure initially similar to that of the somatic cell nucleus. During spermatogenesis, the spermatid nucleus undergoes drastic remodelling during which it first elongates and then condenses into the very specific and tightly packaged structure of the sperm nucleus. During this remodelling dthe histones are replaced by transition proteins, which, in turn, are replaced by protamines, the specific nuclear proteins of the spermatozoa. Immediately prior to their replacement, the histones are hyperacetylated. The first part of our work was to precisely characterise the changes in histone acetylation during murine spermatogenesis. We have shown that the core histones H2A, H2B, H3 and H4 are hyperacetylated in the elongating spermatids. We have also shown that these changes in acetylation are associated with degradation of the enzymes responsible for histone deacetylation, histone deacetylases or HDACs, while histone acetyl transferases are still present in these cells. The histone acetylation pattern was also investigated during human spermatogenesis, revealing that histone hyperacetylation in the nucleus of elongating spermatids, which appears to be conserved during the course of evolution, also occurs during human spermatogenesis. Moreover, our data obtained from the testes of men with severely altered spermatogenesis, including SCO syndromes (Sertoli Cells Only Syndromes), show that a global hyperacetylation of the Sertoli cell nuclei is associated with an absence of meiotic and post-meiotic cells. This suggests that the global histone acetylation variations observed during spermatogenesis are part of a signalling pathway involving germ cell — Sertoli cell communication. Altogether, these data provide a basis for a better understanding of the mechanisms and identification of the factors involved in post-meiotic remodelling of chromatin.     

Immunocytochemical localization of actin and tubulin in rat testis and spermatozoa

Using commercial monoclonal antibodies against actin and tubulin (alpha and beta), the respective antigens were localized on semithin and ultrathin sections of the rat testis. Tubulin immunofluorescence was found in the socalled manchette surrounding the heads of the maturating spermatids as well as the sperm tail. The distribution pattern varied with sperm development. Modified Sertoli cells found at the transition between the seminiferous tubules and the rete testis displayed much filamentous tubulin-reactive material. The immunofluorescence findings could be confirmed at the ultrastructural level using the indirect immunogold method. Actin immunofluorescence was demonstrated in vascular smooth muscle cells, interstitial macrophages and - most intensely - in peritubular cells. Inside the seminiferous tubules the Sertoli cell junctions and the ectoplasmic specializations of the Sertoli cells that follow the outer contour of spermatid heads displayed distinct actin immunofluorescence. In addition to the locations mentioned, actin-like immunoreactivity was visualized at the ultrastructural level in the chromatoid body and the subacrosomal space of spermatids as well as on the outer dense fibers of the sperm tail. Immunoblotting experiments with actin antibodies showed that in extracts from testicular spermatozoa, intact or fragmented into heads and tails, from isolated Sertoli cells grown in vitro, and from testis tissue in addition to authentic actin a protein was present in sperm tail extracts that strongly bound the actin antibody. This protein may be an actin-related protein and may be responsible for the actin-like immunoreactivity of the outer dense fibers of the sperm tail.     

Effects of season and breed on sperm acrosin activity and semen quality of boars

Acrosin activity and semen quality (sperm concentration, ejaculate volume and number of spermatozoa) were assessed from March 1997 to March 1998 in semen of Large White, Pietrain and Duroc x Pietrain boars. Semen quality varied with season, including high production of spermatozoa in autumn and winter and low production in summer. Semen quality also differed across breeds. Acrosin activity of boar spermatozoa was not affected by breed (range 3.16-3.32 mU/10(6) spermatozoa), but exhibited distinct seasonal changes. Monthly changes in acrosin activity were parallel to changes in number of sperm in the ejaculate from November to March. On the other hand, dramatic changes in acrosin activity between July and October (range 1.85-4.59 mU/10(6) spermatozoa) were not paralleled by similar changes in number of ejaculated sperm. These fluctuations in acrosin activity may reflect either changes in sperm acrosin production or disturbances to sperm membranes, probably related to effects of high summer temperatures during spermatogenesis. Results confirmed seasonal and breed-related differences in boar semen quality characteristics.     

Appearance of an intra-acrosomal antigen during the terminal step of spermiogenesis in the rat

Summary In a survey of sperm antigens in the rat, a new intra-acrosomal antigen was found using a monoclonal antibody MC41 raised against rat epididymal spermatozoa. The MC41 was immunoglobulin G₁ and recognized spermatozoa from rat, mouse and hamster. Indirect immunofluorescence with MC41 specifically stained the crescent region of the anterior acrosome of the sperm head. Immuno-gold electron microscopy demonstrated that the antigen was localized within the acrosomal matrix. Immunoblot study showed that MC41 recognized a band of approximately 165000 dalton in the extract of rat sperm from the cauda epididymidis. Immunohistochemistry with MC41 demonstrated that the antigen was first detected in approximately step-2 spermatids, and distributed over the entire cytoplasmic region of spermatids from step 2 to early step 19. The head region became strongly stained in late step-19 spermatids and then in mature spermatozoa. Distinct immunostaining was not found in the developing acrosome of spermatids throughout spermiogenesis. These results suggest that the MC41 antigen is a unique intra-acrosomal antigen which is accumulated into the acrosome during the terminal step of spermiogenesis.     

Acrosin activity is a good predictor of boar sperm freezability

The main aim of this study was to determine whether acrosin activity could predict boar sperm freezability. For this purpose, we characterized the changes in sperm quality and acrosin activity throughout the cryopreservation procedure of sperm samples from 30 Pietrain boars by analyzing four critical steps: step 1 (extended sperm at 15 °C), step 2 (cooled sperm at 5 °C), step 3 (30 minutes postthaw), and step 4 (240 minutes postthaw). Freezability ejaculate groups were set on the basis of sperm motility and membrane integrity after freeze–thawing. Results obtained highlighted the low predictive value in terms of freezability of sperm motility and kinematics and sperm membrane integrity, as no differences between good and poor freezability ejaculates were seen before cryopreservation. Significant differences (P < 0.05) between ejaculate groups were observed in the cooling step at 5 °C for sperm kinetic parameters, and after thawing for sperm motility and membrane integrity. In contrast, acrosin activity appeared as an indicator of boar sperm freezability because the differences (P < 0.05) between good and poor freezability ejaculates manifested yet in extended samples at 15 °C. On the other hand, we also found that variations in sperm kinematics, membrane lipid disorder, intracellular calcium content, acrosome integrity, and acrosin activity throughout the cryopreservation procedure were indicative of a significant damage in spermatozoa during the cooling step in both ejaculate groups. In conclusion, the main finding of our study is that acrosin activity can be used as a reliable predictor of boar sperm freezability because it differs significantly between good and poor freezability ejaculates yet before freeze–thawing procedures took place, i.e., in the refrigeration step at 15 °C.     

Immunohistochemical localization of the transferrin receptor in the seminiferous epithelium of the rat

The transferrin receptor has been immunohistochemically localized in the seminiferous epithelium of the rat with a monoclonal antibody, MRC OX26, which recognizes the transferrin receptor glycoprotein. The receptor was detectable on mitotically and meiotically dividing germ cells and, less abundantly, on round spermatids. It was lost from germ cells during spermatid elongation and was undetectable on immature spermatozoa. The transferrin receptor was also present on Sertoli cells in the testes of immature animals and on Sertoli cells in the testes of aspermatogenic animals that had been irradiated in utero. It was not detectable on Sertoli cells in the testes of cryptorchid animals. These studies demonstrate that the transferrin receptor is abundant on dividing germ cells as well as dividing somatic cells.     

Immunocytochemical localization of actin and tubulin in rat testis and spermatozoa

Summary Using commercial monoclonal antibodies against actin and tubulin ( and ), the respective antigens were localized on semithin and ultrathin sections of the rat testis. Tubulin immunofluorescence was found in the socalled manchette surrounding the heads of the maturating spermatids as well as the sperm tail. The distribution pattern varied with sperm development. Modified Sertoli cells found at the transition between the seminiferous tubules and the rete testis displayed much filamentous tubulin-reactive material. The immunofluorescence findings could be confirmed at the ultrastructural level using the indirect immunogold method. Actin immunofluorescence was demonstrated in vascular smooth muscle cells, interstitial macrophages and — most intensely — in peritubular cells. Inside the seminiferous tubules the Sertoli cell junctions and the ectoplasmic specializations of the Sertoli cells that follow the outer contour of spermatid heads displayed distinct actin immunofluorescence. In addition to the locations mentioned, actin-like immunoreactivity was visualized at the ultrastructural level in the chromatoid body and the subacrosomal space of spermatids as well as on the outer dense fibers of the sperm tail.Immunoblotting experiments with actin antibodies showed that in extracts from testicular spermatozoa, intact or fragmented into heads and tails, from isolated Sertoli cells grown in vitro, and from testis tissue in addition to authentic actin a protein was present in sperm tail extracts that strongly bound the actin antibody. This protein may be an actin-related protein and may be responsible for the actin-like immunoreactivity of the outer dense fibers of the sperm tail.     

Characterization of baboon testicular antigens using monoclonal anti-sperm antibodies

Sperm antigens that appear during spermatogenesis in the baboon were identified by using three monoclonal antibodies generated in culture from mice immunized with baboon caudal epididymal spermatozoa. Antibodies BSA1 and BSA2 recognize trypsin-sensitive 84,000 and 45,000 dalton determinants that are restricted to the tail and anterior acrosomal regions of the sperm, respectively, as determined by Western blot and immunofluorescence techniques. The tail antigen absent in 2- and 3-yr-old baboon testes first appears in spermatid cells at about 4 yr of age. In contrast, the acrosomal antigen recognized by BSA2 is present in 3-yr-old primitive testicular germ cells. In the mature testis, the 45,000 molecular weight determinant is predominantly localized in the nucleus of late pachytene spermatocytes and round spermatid cells as observed via the avidinbiotin immunoperoxidase method. Antibody BSA3 reacted only with sailidase-treated sections of adult testis. This trypsin-resistant determinant, not expressed on testicular sperm, is recognized by antibody BSA3 only on epididymal sperm, thus indicating a post-testicular sperm modification.     

Electron-microscopic localization of baboon acrosomal antigens using antisperm monoclonal antibody.

A sperm antigen corresponding to baboon sperm monoclonal antibody 1A9 was localized in the testis and ejaculated sperm in this animal, using the immunofluorescence technique and immunogold labelling. Immunohistochemical studies of the baboon testis showed that the antigenic determinant was localized in the late spermatid cells and spermatozoa close to the seminiferous tubules. Immunofluorescence studies indicate that the protein was localized on the acrosome region of ejaculated baboon sperm. At the electron-microscopic level, gold particles indicative of the presence of this determinant recognized by 1A9 monoclonal antibody were detected on the inner acrosomal region of ejaculated baboon sperm.     

Identification of actin in boar spermatids and spermatozoa by immunoelectron microscopy

Actin was localized in testicular spermatids and in ionophore-treated ejaculated sperm of boar by use of a monoclonal anti-actin antibody labeled with colloidal gold. With the on-grid postembedding immunostaining of Lowicryl K4M sections, actin was identified in the subacrosomal region of differentiating spermatids, in the microfilaments of the surrounding Sertoli cells, and in the myoid cells of the tubular wall. Ejaculated sperm, labeled with the preembedding method, showed actin between the plasma membrane and the outer acrosomal membrane of the equatorial segment. Indirect immunofluorescence was positive in the equatorial segment and in the acrosomal cap of intact sperm, whereas reacted sperm at the anterior head region retained fluorescence only in the inner acrosomal membrane. Rhodamine-phalloidin failed to stain intact and reacted sperm. The distribution of actin in sperm head membranes (inner acrosomal membrane, membranes of the equatorial segment), which are retained after the acrosome reaction, is discussed.     

Determination of acrosin activity of boar spermatozoa by the clinical method: optimization of the assay and changes during short-term storage of semen

A clinical assay to evaluate total acrosin activity developed for human semen has been optimized for use in boar spermatozoa. The main modifications included a decrease of sperm number per assay from 1.0 to 10.0 x 10(6) to 12.5 to 75.0 x 10(3) spermatozoa, and the time of incubation from 180 to 60 min. Linearity of response for differing quantities of spermatozoa was maintained. Extensive washing of spermatozoa was necessary to eliminate seminal plasma, the source of acrosin inhibitors. Seminal plasma that was diluted 1000 times inhibited acrosin activity by about 50%. To abolish the inhibitory effect of seminal plasma it was necessary to use 25,000-fold dilution. Total acrosin activity of boar spermatozoa was about 100 times higher than that of human spermatozoa. Acrosin activity of boar spermatozoa in extended semen decreased during 7 d of storage. These results indicate that the clinical assay of acrosin activity can be used for boar spermatozoa to evaluate the quality of boar semen.     

Ultrastructural localization of guinea pig spermatozoal autoantigens on germinal cells by immunoperoxidase techniques.

Three guinea pig spermatozoal autoantigens S, P and T, each one able to induce autoimmune aspermatogenic orchiepididymitis and autoantibodies, were ultrastructurally localized in male germinal cells by immunoperoxidase techniques. Both living and prefixed sectioned cell preparations were treated and examined. Fab antibody fragments were used to study intracellular antigens (whole antibodies were inefficient). Water-soluble S and P autoantigens were found in acrosomal structures in the same sites: proacrosomal and acrosomal granules of the young spermatids, on the head caps of spermatids and acrosomal cap of spermatozoa, along the inner and outer acrosomal membranes and in the outer zone of the acrosomal matrix of the same cells. S was never found in the inner zone of spermatid or spermatozoa acrosomes, while P was present in this inner zone, but only of young spermatids. Water-insoluble T autoantigen was found on the plasmalemma and outer acrosomal membranes of spermatids and spermatozoa, inside the spermatid cytoplasm and, sometimes, on the inner acrosomal membrane of young spermatids. The specificity of the immunological localization for each antigen was confirmed by testing with specific antisera following absorption with homologous and heterologous antigens. No other testicular cell type (including Sertoli cells per se) was found to bear S, P or T autoantigens. When use was made of autoimmune sera obtained through autologous whole spermatozoa, the observed staining was an additive combination of what was observed when using the preceding three immune sera, anti-S, anti-P and anti-T.     

Proacrosin and the differentiation of the spermatozoa

Using the indirect immunofluorescence staining technique, the occurrence and localization of proacrosin, the zymogen form of acrosin, was studied during spermatogenesis in the bull, ram, boar and rabbit. Proacrosin staining was demonstrable for the first time in the early haploid spermatid and increased with the differentiation of the spermatid to spermatozoon. The spermatozoon is covered by a cap-like structure of uniform fluorescence corresponding to the acrosomal compartment of the male gamete. No fluorescence could be found in diploid spermatogenic cells, i.e., in spermatogonia and spermatocytes. An identical developmental pattern of proacrosin was observed with the indirect immunoperoxidase staining technique. However, with this staining technique a distinct distribution of proacrosin staining was observed in the acrosome of epididymal and ejaculated spermatozoa of the bull, ram, boar, rabbit and man. Proacrosin seems to be distributed in the acrosome in granules rather than in the homogeneous form, as was indicated by the results of indirect immunofluorescence staining.     

Spermiogenesis in the bullfrog (Rana catesbeiana): a study of cytoplasmic events including cell volume changes and cytoplasmic elimination

The process by which spermatid cytoplasmic volume is reduced and cytoplasm eliminated during spermiogenesis was investigated in the bullfrog Rana catesbeiana. At early phases of spermiogenesis, newly formed, rounded spermatids were found within spermatocysts. As acrosomal development, nuclear elongation, and chromatin condensation occurred, spermatid nuclei became eccentric within the cell. A cytoplasmic lobe formed from the caudal spermatid head and flagellum and extended toward the seminiferous tubule lumen. The cytoplasmic lobe underwent progressive condensation whereby most of its cytoplasm became extremely electron dense and contrasted sharply with numerous electron-translucent vesicles contained therein. At the completion of spermiogenesis, many spermatids with their highly condensed cytoplasm still attached were released from their Sertoli cell into the lumen of the seminiferous tubule. There was no evidence of the phagocytosis of residual bodies by Sertoli cells. Because spermatozoa are normally retained in the testis in winter and are not released until the following breeding season, sperm were induced to traverse the duct system with a single injection of hCG. Some spermatids remained attached to their cytoplasm during the sojourn through the testicular and kidney ducts; however, by the time the sperm reached the Wolffian duct, separation had occurred. The discarded cytoplasmic lobe (residual body) appeared to be degraded with the epithelium of the Wolffian duct. It was determined that the volume of the spermatid was reduced by 87% during spermiogenesis through a nuclear volume decrease of 76% and cytoplasmic volume decrease of 95.3%.