Expression patterns of male germ cell markers in cryptorchid pig testes

Male germ cell apoptosis has been described in heat-damaged testes by cryptorchidism. In the present study, wild type pig testes were compared with cryptorchid testes via histological and immunohistological analyses. Spermatozoa were not detected in two cryptorchid testes and the diameters of seminiferous tubules were significantly reduced in cryptorchid pig testes compared with wild type pig testes. Cells expressing marker genes for undifferentiated spermatogonia, such as protein gene product 9.5 was significantly decreased in cryptochid pig testes. In addition, the numbers of cells expressing DEAD-box polypeptide 4 (VASA), synaptonemal complex protein 3, protamine, and acrosin (a biomarker of spermatocyte, spermatid, and spermatozoa) were significantly reduced in cryptochid pig testes. However, the number of vimentin-expressing Sertoli cells was not changed or was significantly increased in cryptorchid pig testes. This result indicates that male germ cells are specifically damaged by heat in cryptorchid pig testes and not Sertoli cells. These findings will facilitate the further study of spermatogenesis and the specific mechanisms by which cryptorchidism causes male infertility.

The circadian Clock gene regulates acrosin activity of sperm through serine protease inhibitor A3K

Our previous study found that CLOCK knockdown in the testes of male mice led to a reduced fertility, which might be associated with the lower acrosin activity. In this present study, we examined the differential expression in proteins of CLOCK knockdown sperm. Clock gene expression was knocked down in cells to confirm those differentially expressions and serine protease inhibitor SERPINA3K was identified as a potential target. The up-regulated SERPINA3K revealed an inverse relationship with Clock knockdown. Direct treatment of normal sperm with recombinant SERPINA3K protein inhibited the acrosin activity and reduced in vitro fertilization rate. The luciferase reporter gene assay showed that the down-regulated of Clock gene could activate the Serpina3k promoter, but this activation was not affected by the mutation of E-box core sequence. Co-IP demonstrated a natural interaction between SERPIAN3K and RORs (α and β). Taken together, these results demonstrated that SERPINA3K is involved in the Clock gene-mediated male fertility by regulating acrosin activity and provide the first evidence that SERPINA3K could be regulated by Clock gene via retinoic acid-related orphan receptor response elements.

Sperm surface proteases in ascidian fertilization

Ascidian eggs are surrounded by a noncellular layer and two cellular layers, which are penetrated by sperm. Three sperm surface proteases are essential for fertilization of eggs from the stolidobranch ascidian Halocynthia: spermosin, acrosin, and the proteasome. In the phlebobranch Ciona, a chymotrypsin-like protease and the proteasome are essential in fertilization. Sperm from the phlebobranch ascidians Phallusia mammillata, Ascidia (=Phallusia) nigra, and Ascidia columbiana, all express spermosin, acrosin, and the proteasomal chymotrypsin activities on their surfaces. Chymostatin blocks cleavage in phlebobranchs, but inhibitors of spermosin and acrosin only delay it by several minutes. Protease inhibitors have little effect upon sperm binding in Phallusia but strongly affect the rate of sperm passage through the vitelline coat. Peptide substrates and inhibitors to spermosin and acrosin cause a significant decline in the number of eggs undergoing pre-meiotic contractions at 3 min after fertilization. Thus while chymotrypsin activity is essential for penetration of the vitelline coat, spermosin and acrosin both function to increase the rate of fertilization. A crucial step in the divergence of the phlebobranchs and stolidobranchs may have been the conversion of spermosin and acrosin to essential proteases in the stolidobranchs, or, perhaps, their essential function was lost in the evolution of phlebobranchs. Aplousobranch ascidians are all colonial with very small zooids. Sperm from Aplidium californicum, Aplidium solidum (Polyclinidae), and Distaplia occidentalis (Holozoidae) have acrosin and chymotrypsin activities but lack spermosin activity. This enzyme is also missing from sperm of colonial phlebobranch and stolidobranch ascidians, suggesting that spermosin is not necessary for small zooids with internal fertilization.

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 beta-acrosin has a typical hyperbolic curve of a zymogen enzymatic activation. Three of the five recombinant forms (truncated beta-acrosin, Ser/Ala222-truncated beta-acrosin, and truncated beta-acrosin "heavy chain") had the ability to bind ZPGPs. The two shorter forms (the amino and carboxy termini of truncated beta-acrosin) failed to bind. The catalytic site mutant (Ser/Ala222) of truncated beta-acrosin does not differ from the recombinant truncated beta-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.

DNA-protein binding studies in the 5' flanking region of rat proacrosin gene which is transcribed in diploid germ cells

The proacrosin gene is transcribed in diploid spermatogenic cells and translated in haploid round spermatids. In order to evaluate sequences which are involved in proacrosin gene transcription, DNA-protein interactions were analyzed in 1.2 kb of the 5'flanking region of the rat gene. 13 protein binding sites were identified by DNase I footprinting using nuclear extracts from rat testis and brain, respectively. Five footprints (F1, F3, F7, TS2, TS3) which suggest an interaction with testis specific nuclear factors were further examined by gel retardation assays. Three testis specific binding sites (F1, F7, TS2, located 472bp, 697bp and 1004bp upstream of ATG, respectively) could be identified with both methods. The binding site F1 contains a motif which is similar to a testis specific footprint found in mouse protamine 1 gene. The nucleotide sequence of F7 contains the recognition motif of an isoform of the transcription factor GATA1, which is expressed in testis. Furthermore F1 and F7 are located in that part of the 5'flanking region of the proacrosin gene, which can direct proacrosin gene expression in germ cells of male transgenic mice.

Diploid expression and translational regulation of rat acrosin gene

Acrosin, a sperm acrosomal serine protease has been implicated in the recognition, binding and penetration of the zona pellucida of the ovum. Biosynthesis of acrosin was found to start in early round spermatids which are haploid germ cells. Here, we report that acrosin gene transcription occurs as early as at day 19 of rat spermatogenesis which contains diploid but not haploid spermatogenic cells. Translational control of the acrosin gene may be due to cytoplasmic protein factors which through RNA-bandshift experiments were found to bind to the 5'UTR of the acrosin mRNA. In order to differentiate between diploid and haploid spermatogenic cells at the molecular level, transcription of the protamine 2 gene during rat testicular development was evaluated. Protamine 2 transcripts could be demonstrated for the first time in 25-day-old testes which contain diploid as well as haploid spermatogenic cells.

Proacrosin gene expression in rat spermatogenic cells

Mammalian proacrosin gene expression was considered to be exclusively postmeiotic until recent studies detected the presence of proacrosin mRNA in mouse pachytene spermatocytes. To determine if rat proacrosin gene expression was initiated during meiosis, a 314-bp proacrosin cDNA fragment was amplified from rat round spermatid RNA, using proacrosin-specific primers, for use as a probe. Sequence analysis of the round spermatid 314-bp cDNA fragment confirmed > 99% identity with the rat proacrosin cDNA sequence. This 314-bp fragment was subsequently used for Northern blot analysis of RNA isolated from testicular germ cells. A 1.6-kb transcript was detected in pachytene spermatocytes, round spermatids, and a mixed population of condensing spermatids/residual bodies, with the highest level of expression in round spermatids. Northern blot analysis of testicular RNA during development revealed the earliest timepoint of expression to be at 24 days of age, further demonstrating the association of proacrosin mRNA with spermatocytes. These data demonstrate diploid expression of the rat proacrosin gene, in agreement with mouse proacrosin gene expression but in contrast to the apparent haploid expression of proacrosin described for the bull and the boar. These studies provide evidence that, in the rat, the process of acrosome biogenesis begins during meiosis.

Proteolytic enzymes in seminal plasma of domestic turkey (Meleagris gallopavo)

Protease and basic amidase activity was found in the seminal plasma of the domestic turkey. Amidase activity, measured through use of N-alpha-benzoyl-DL-arginine-p-nitroanilide-HCL (BAPNA), was 23-28 times greater for turkey than for guinea fowl or chicken. Within the reproductive tract, seminal plasma from the vas deferens had much greater activity than testicular or epididymal fluids. Turkey seminal plasma enzyme (TSPE) purified by chromatography or isoelectric focusing showed three protein bands by PAGE, each resolving on SDS-PAGE into two subunits with molecular weights of approximately 28,000-32,000 and 38,000-44,000. One of the three proteins also contained a larger subunit (M(r) 76,000-81,000) thought to be transferrin. Turkey acrosin consisted of three subunits with molecular weights below 20,500. Acrosin, but not TSPE, was visualized in native gels with N-alpha-benzoyl-DL-arginine-beta-naphthylamide (BANA)/Fast Garnet stain. Michaelis constants (BAPNA) for TSPE, acrosin, and trypsin were 2.41 +/- 0.12 x 10(-4) M (n = 5), 4.96-6.03 x 10(-4) M (n = 2), and 6.76 +/- 0.95 x 10(-4) M (n = 6), respectively. TSPE, like acrosin and trypsin, was inhibited by benzamidine but not iodoacetamide. While all natural trypsin inhibitors tested inhibited acrosin, TSPE was not inhibited by ovomucoid from chicken or turkey egg white.

Unexplained in-vitro fertilization failure: implication of acrosomes with a small reacting region, as revealed by a monoclonal antibody

To determine the acrosomal characteristics related to in-vitro fertilization (IVF) outcome, spermatozoa from 50 men whose wives had resorted to IVF have been studied by indirect immunofluorescence microscopy with anti-human pro-acrosin monoclonal antibody 4D4 (mAb 4D4), prior to and after incubation in a capacitating medium. The antibody labelled only the acrosomal principal region (APR), revealing its shape (i.e. normal, small or amorphous) and its status (i.e. unreacted, partially or totally reacted). The IVF outcome distinguished: (i) spermatozoa which were able to fertilize at least one oocyte in vitro (group I; n = 25) and (ii) spermatozoa which failed to fertilize any oocyte in vitro (group II; n = 25). The semen characteristics of the two sperm groups, including the acrosome morphology, were similar according to conventional analysis. The mAb 4D4 detected in both the whole and the swim-up sperm cell fractions a lower percentage of normal APR in group II (< 50% for 10 patients in group II versus one patient from group I), which was related to a higher percentage of small APR. Moreover, after 21 h incubation, group II had a lower acrosomal loss index. The spermatozoa of five patients of this infertile group II did not undergo acrosomal modification whereas spermatozoa of all group I patients underwent the acrosomal reaction. The data showed that the relationship between acrosomal anomalies and IVF failure is mainly due to an increased incidence of acrosomes with a reduced size of the region involved in the acrosome reaction. Immunodiagnosis of this acrosomal region by means of mAb 4D4 is informative for IVF outcome.

Human acrosome biogenesis: immunodetection of proacrosin in primary spermatocytes and of its partitioning pattern during meiosis

Proacrosin biosynthesis timing during human spermatogenesis has been studied using the monoclonal antibody 4D4 (mAb 4D4). Frozen and paraffin-embedded sections of testicular biopsies were labelled by standard indirect immunofluorescence and avidin-biotin immunoperoxidase procedures. The labelling specificity was checked by immunochemistry assays on unrelated tissues and by western blotting of testis extracts showing that only the 50–55 × 10(3) Mr proacrosin was recognized by mAb 4D4. Proacrosin was first observed in the Golgi region of midpachytene primary spermatocytes. In late pachytene primary spermatocytes, proacrosin was observed in two regions located at opposite nuclear poles. During the subsequent steps of the first meiotic division, the two bodies containing proacrosin were located: (i) on opposite sides of the equatorial plate during metaphase; (ii) along the microtubular spindle during anaphase; and (iii) close to each chromosomal aggregate during telophase. Two bodies containing proacrosin were still observed in interphasic secondary spermatocytes. The single labelled area observed in early spermatids was found to increase considerably in size during spermiogenesis. Anomalies of proacrosin scattering were observed in patients with Golgi complex partitioning failure. These data reveal proacrosin biosynthesis during diploid and haploid phases of human spermatogenesis and the proacrosin partitioning pattern during meiosis.

Proteins and glycosaminoglycans in the intercellular matrix of the human cumulus-oophorus and their effect on conversion of proacrosin to acrosin

Human cumuli-oophori were cultured in vitro in the presence of radioactive protein and polysaccharide precursors. The time course of the cumulus cell secretion was traced by histoautoradiography. Matrix solubilization, and sodium dodecyl sulphate polyacrylamide gel electrophoresis and high-performance liquid chromatography showed that proteoglycan (Mr greater than 1,700,000) was the main cumulus cell product that was prevailingly deposited in the cumulus intercellular matrix and partly released into the culture medium. It was capable of accelerating the conversion of proacrosin to acrosin and this activity was abolished by enzymatic removal of chondroitin sulphate, the predominant glycosaminoglycan of this proteoglycan fraction. None of the other fractions, including a proteoglycan of Mr 80,000-90,000, containing heparan sulphate, accelerated the conversion of proacrosin to acrosin under the conditions used. The results suggest that chondroitin sulphate is the active component of the high-Mr proacrosin activator of the human cumulus-oophorus.

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.

Zona pellucida induces conversion of proacrosin to acrosin

The effect of heat-solubilized zonae pellucidae (ZP) isolated from mature pig ovaries on the conversion of pig proacrosin to acrosin was examined and compared with the effects of different sulphated polysaccharides. At low concentrations, zona glycoproteins potently stimulated acrosin auto-activation. Up to 2.5 micrograms ml-1 ZP, the acceleration of acrosin activation was shown to be dependent on the ZP concentration. At higher concentrations zona glycoproteins exerted an inhibitory effect on acrosin amidase activity. A similar effect was demonstrated for fucoidan, heparin, and chondroitin sulphate. The results intimate that in vivo, the conversion of proacrosin to acrosin is regulated at the sperm-zona interface.

Molecular cloning of preproacrosin and analysis of its expression pattern in spermatogenesis

Complementary DNA clones for the boar preproacrosin have been isolated from a randomly primed testis cDNA library in lambda gt10 and from an oligo(dT)-primed testis cDNA in lambda gt11. The nucleotide sequence of the 1418-bp cDNA insert includes a 46-bp 5'-untranslated region, an open reading frame of 1248 bp corresponding to 416 amino acids (45.59 kDa) and a 121-bp 3'-untranslated region. The deduced amino acid sequence includes the active-site residues histidine, asparagine and serine of the catalytic triad of the serine proteinase super-family and is colinear with that determined by amino acid sequencing of the boar acrosin light chain and of a small region of the NH2-terminal sequence of the heavy chain. The preproacrosin cDNA contains at the 3' end a 381-bp sequence which codes for an amino acid sequence not yet found in any other serine proteinase. This amino acid sequence is rich in proline (42 out of 127 amino acids) and is suggested to be involved in the recognition and binding of the spermatozoa to the zona pellucida of the ovum. The mRNA for preproacrosin is synthesized as an approximately 1.6-kb-long molecule only in the postmeiotic stages of boar and bull spermatogenesis.

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.

Biochemical and immunological comparisons between the human and boar proacrosin-acrosin proteinase systems

Biochemical and immunochemical methods have been used to examine the proacrosin-acrosin system of human and boar spermatozoa. Marked biochemical similarities including the relative molecular weights of proacrosin (approx. 55,000), alpha-acrosin (45,000-49,000) and beta-acrosin (34,000-38,000) were observed for both species. In addition, the time course of proacrosin autoconversion between 0 to 60 min revealed that the purified proacrosin from both species autoconverted to alpha-acrosin and then to beta-acrosin at approximately the same time intervals. Despite these apparent biochemical similarities, distinct immunological differences between the human and boar proacrosin-acrosin systems were observed. The human proacrosin antibody immunoreacted with purified human proacrosin and alpha-acrosin but not with beta-acrosin. The antibodies to boar proacrosin cross-reacted with the purified boar proacrosin, alpha-acrosin and beta-acrosin. The antibodies to human proacrosin also cross-reacted with boar proacrosin and to a weak extent with boar alpha-acrosin but not with the boar beta-acrosin. While antibodies to boar proacrosin did not react with any of the components of the human proacrosin system. Additionally, in the non-purified sperm extracts the human proacrosin antibody preparation reacted with several proteins larger than proacrosin and one with a molecular weight of approximately 34,000. In the non-purified boar sperm extracts, the antibodies to boar proacrosin only cross-reacted with the known components of the proacrosin-acrosin system suggesting a high degree of specificity. Thus, immunochemical evidence is presented that indicates there are specific structural differences which occur in the proacrosin-acrosin system of mammalian sperm.

Expression of acrosin during mouse spermatogenesis: a biochemical and immunocytochemical analysis by a monoclonal antibody C 11 H

A monoclonal antibody C 11 H was produced against human acrosomal antigen. It also cross-reacted with acrosomes of the boar and the mouse. In boar spermatozoa the antibody reacted, in immunoblotting analysis, with polypeptides of Mr 55,000 and 53,000. The proteolytic activity was detected by zymographic casein overlay assay. Partially purified boar sperm acrosin was bound by the C 11 H affinity column, and acrosin activity was detected in the eluate. These experiments indicate that C 11 H antibody recognizes sperm acrosin. The acrosin expression during spermatogenesis was studied with C 11 H antibody, using mouse testis as a model. Immunocytochemical analysis revealed that step 9 spermatids were the first cells to react with C 11 H antibody. During step 14, the perinuclear pattern of C 11 H-binding disintegrated into small particles around the spermatid nuclei for the period of close association between spermatid bundles and Sertoli cells. During late step 15, the antigen became located at the site in the acrosome typical for step 16 spermatids and spermatozoa. These results indicate that monoclonal C 11 H antibody recognizes acrosin that is first expressed in haploid cells coincident with the onset of nuclear elongation and cessation of RNA transcription. The changes in the distribution pattern suggest that acrosin may be modified by Sertoli cells. In addition to studies on acrosin, this antibody may be useful in investigations of transcription and translation and their regulation during spermatogenesis in general.

Studies on the rabbit proacrosin-acrosin system

A single molecular form (Mr = 68,000 approx) of a homogeneous preparation of rabbit testis proacrosin (S. K. Mukerji and S. Meizel (1979) J. Biol. Chem. 254, 117;21-11728) was initially converted by autoactivation into an acrosin (Mr = 68,000); both gave a single activity and protein bands with similar electrophoretic mobilities (Rm = 0.25) when subjected to polyacrylamide disc gel electrophoresis on 7.5% gel at pH 4.5. Two additional bands (Rm values of 0.395-0.412 and 0.497-0.519, respectively) were noticeable only when proacrosin was activated further after attaining maximum activity. The slowest- and the fastest-moving bands were separated into two acrosin activity peaks by Sephadex G-100 gel-filtration chromatography on a calibrated column. The molecular weights of the two proteins, determined by rechromatography on the same column, was estimated to be 68,000 and 34,000, respectively. Also, sodium dodecyl sulfate-polyacrylamide disc gel electrophoresis of three acrosins gave protein bands which corresponded to molecular weights of approximately 68,000, 52,000, and 34,000, respectively. Electrophoresis data suggest that the loss of acrosin activity generally observed following prolonged activation of proacrosin is caused by self-aggregation of the Mr 34,000 form of acrosin. This property was not shown by Mr 68,000 acrosin. Initial acrosin (Mr = 68,000) was activated by divalent cations such as Ca2+ and Mg2+. The enzyme was inhibited by Zn2+, Fe2+, Hg2+, and sulfhydryl blockers such as 5,5'-dithiobis(2-nitrobenzoic acid), p-hydroxymercuribenzoate, and iodoacetate, apparently due to their reaction with one out of six titratable sulfhydryl groups per mole of acrosin. Probably Zn2+ is involved in acrosomal stabilization. The initial rabbit acrosin (Mr = 68,000) appears to be the major and most stable form, and is generated from proacrosin with little structural alteration. This may be the functionally active form which plays an essential role in mammalian fertilization.

Gossypol inhibition of acrosin and proacrosin, and oocyte penetration by human spermatozoa

Gossypol, a known antispermatogenic agent, was found to effectively inhibit the highly purified boar sperm proacrosin-acrosin proteinase enzyme system by irreversibly preventing the autoproteolytic conversion of proacrosin to acrosin and reversibly inhibiting acrosin activity. The agent appears to prevent the self-catalyzed by not the acrosin-catalyzed activation of proacrosin. In additional experiments, brief exposure of human semen to concentrations of gossypol, which did not visibly alter spermatozoal motility or forward progression, was found to irreversibly inhibit the conversion of proacrosin to acrosin although the activity of the nonzymogen acrosin was not decreased, and also to prevent the human spermatozoa from penetrating denuded hamster oocytes. Gossypol inhibition of proacrosin conversion to acrosin closely paralleled the decline in oocyte penetration. Racemic (+/-) gossypol was equally as effective as the enantiomer (+) gossypol. The results suggest that the inhibition of proacrosin conversion to acrosin is a mechanism by which gossypol exerts its antifertility effect at nonspermicidal concentrations and that low levels of gossypol should be tested for their contraceptive action when placed vaginally.

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.