Cytoplasmic events in human meiotic arrest as revealed by immunolabelling of spermatocyte proacrosin

Abstract. Proacrosin appears in the Golgi complex as early as the mid-pachytene stage and immediately thereafter initiates partition to be equally distributed in sper-matids. The anti-proacrosin monoclonal antibody 4D4 (mAb 4D4) was used as a marker of these cytoplasmic events in ten men exhibiting spermatogenesis arrest in three specific stages: (i) leptotene/zygotene spermatocyte I with impaired chromosome pairing (six cases), (ii) early pachytene I (one case) and (iii) metaphase/anaphase I (three cases). Prophase arrest stages were identified on testis sections stained by silver nitrate. MAb 4D4 labelling revealed two types of leptotene/zygotene arrest depending on whether proacrosin was expressed or not. The data obtained enabled us to distinguish between: (i) nuclear blockages due to chromosome and/or nuclear matrix anomalies, when cytoplasmic events were either inhibited or not inhibited, and (ii) nuclear anomalies due to microtubular disturbances. In this latter case, cytokinesis was impaired as early as the prophase I, thus indicating a relationship between the Golgi partitioning and the microtubule network. Data show that meiotic arrest investigations, by means of an appropriate marker of the cytoplasmic events, provide valuable information on spermatogenic developmental processes.     

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.     

Localization of boar sperm proacrosin during spermatogenesis and during sperm maturation in the epididymis.

The localization of proacrosin was determined by using colloidal gold labeling and electron microscopy of boar germ cells during spermiogenesis to post-ejaculation. Proacrosin was first localized in round spermatids during the Golgi phase of spermiogenesis; it was associated with the electron-dense granule, or acrosomal granule that was conspicuous within the acrosome. It remained within the acrosomal granule during the cap and acrosome phases of spermiogenesis. At these stages, there was no apparent association of the proacrosin molecule with the acrosomal membranes. During the maturation phase of spermiogenesis, proacrosin was seen to become dispersed into all regions of the acrosome except the equatorial segment. When sperm from different segments of the epididymis and ejaculated sperm were examined, localization was observed throughout the acrosome except for the equatorial segment. Here proacrosin appeared to be localized on both the inner and outer acrosomal membranes as well as with the acrosomal matrix, although further studies are required to verify the membrane localization. No labeling was seen on the plasma membrane. These data suggest that the synthesis and movement of proacrosin to sites in the acrosome are controlled by an as yet unknown process. The absence of proacrosin on the plasma membrane of mature ejaculated sperm makes it unlikely that this enzyme plays a role in sperm-zona adhesion prior to capacitation.     

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.     

Purification and partial peptide sequence analysis of the boar proacrosin binding protein

Boar proacrosin binding protein has been purified and the partial peptide sequence of the CNBr‐digested proacrosin binding protein has been determined. Proacrosin binding protein was purified as a proacrosin and proacrosin binding protein complex from the acid extracts of boar spermatozoa through gel filtration. After the proacrosin binding protein was dissociated from proacrosin by freeze‐thaw method, the proacrosin binding protein was purified through gel filtration. Fractions containing the proacrosin binding protein were pooled and were concentrated by lyophilization and then subjected to CNBr digestion. Four major CNBr‐digested peptides were subjected to N‐terminal peptide sequencing. All four showed the same N‐terminus sequence. Mol. Reprod. Dev. 54:76–80, 1999. © 1999 Wiley‐Liss, Inc.     

Germ cell-specific expression of a proacrosin-CAT fusion gene in transgenic mouse testis.

Acrosin is a serine proteinase located in a zymogen form, proacrosin in the acrosome of the sperm. It is released as a consequence of the acrosome reaction and is believed to be the most important enzyme in the fertilization process. In the mouse, the proacrosin gene is transcribed premeiotically in spermatocytes, but protein biosynthesis starts in haploid spermatids and is restricted to the emerging acrosome. Four lines of transgenic mice harboring 2.3 kb of 5' untranslated region of the rat proacrosin gene fused to the CAT-reporter gene were generated by microinjection of fertilized eggs. The chimeric gene was found to be present in 10-100 copies per genome in the different strains. The 5' untranslated region of rat proacrosin gene could properly direct CAT-gene expression to spermatocytes and CAT-mRNA translation to round spermatids as it is known for mouse proacrosin gene. However, CAT protein is not restricted to the acrosome; rather, it is distributed in the spermatid cytoplasm. This could be due to the lack of DNA sequences for a hydrophobic leader peptide that have been found in all mammalian proacrosins studied until now but that was not present in transgene. It can be concluded from our results that cis-acting sequences required for tissue specific proacrosin expression reside on a 2.3-kb restriction fragment and are conserved in the proacrosin genes of mouse and rat.     

Distribution and morphological changes of the Golgi apparatus during Drosophila spermatogenesis

In spermatogenesis, the Golgi apparatus is important for the formation of the acrosome, which is a sperm‐specific organelle essential for fertilization. Comprehensive examinations of the spatiotemporal distribution and morphological characterizations of the Golgi in various cells during spermatogenesis are necessary for functional analyses and mutant screenings in the model eukaryote Drosophila. Here, we examined the distribution and morphology of the Golgi during Drosophila spermatogenesis with immunofluorescence and electron microscopy. In pre‐meiotic germ cells, the Golgi apparatuses were distributed evenly in the cytoplasm. In contrast, they were located exclusively in two regions near the poles during the meiotic metaphase, where they were segregated prior to the chromosomes. In cells in anaphase to telophase, the Golgi were predominantly left behind in the equatorial region between the separating daughter nuclei. After completion of meiosis, the dispersed Golgi were assembled at the apical side of the spermatid nucleus to form the acrosome. Further investigation of the Golgi distribution in β2‐tubulin mutants showed aberrant and uneven distributions of the Golgi among sister cells in the meiotic spermatocytes and in the post‐meiotic spermatids. At the ultrastructural level, the Golgi apparatus in pre‐meiotic spermatocytes comprised a pair of stacks. The two stacks were situated adjacent to each other, as if they had duplicated before entering into meiotic division. These results highlight the dynamic nature of the Golgi during spermatogenesis and provide a framework for analyzing the correlations between the dynamics of the Golgi and its function in sperm development.     

Male mice lacking three germ cell expressed genes are fertile

In recent years, much knowledge about the functions of defined genes in spermatogenesis has been gained by making use of mouse transgenic and gene knockout models. Single null mutations in mouse genes encoding four male germ cell proteins, transition protein 2 (Tnp-2), proacrosin (Acr), histone H1.1 (H1.1), and histone H1t (H1t), have been generated and analyzed. Tnp-2 is believed to participate in the removal of the nuclear histones and initial condensation of the spermatid nucleus. Proacrosin is an acrosomal protease synthesized as a proenzyme and activated into acrosin during the acrosome reaction. The linker histone subtype H1.1 belongs to the group of main-type histones and is synthesized in somatic tissues and germ cells during the S-phase of the cell cycle. The histone gene H1t is expressed exclusively in spermatocytes and may have a function in establishing an open chromatin structure for the replacement of histones by transition proteins and protamines. Male mutant mice lacking any of these proteins show no apparent defects in spermatogenesis or fertility. To examine the synergistic effects of these proteins in spermatogenesis and during fertilization, two lines of triple null mice (Tnp-2-/-/Acr-/-/H1.1-/- and Tnp-2-/-/Acr-/-/H1t-/-) were established. Both lines are fertile and show normal sperm parameters, which clearly demonstrate the functional redundancy of these proteins in male mouse fertility. However, sperm only deficient for Acr (Acr-/-) are able to compete significantly with sperm from triple knockout mice Tnp-2-/-/Acr-/-/H1.1-/- (70.7% vs. 29.3%) but not with sperm from triple knockout mice Tnp-2-/-/Acr-/-/H1t-/- (53.6% vs. 46.4%). These results are consistent with a model that suggests that some sperm proteins play a role during sperm competition.     

Receptor-mediated and adsorptive endocytosis by male germ cells of different mammalian species

Summary The routes for adsorptive and receptor-mediated endocytosis were studied in vivo after microinjection of tracers into the lumen of the seminiferous tubules, and in vitro in isolated germ cells of different mammals. Cationic ferritin was located on the plasma membrane, in vesicles, in tubules, in multivesicular bodies and in lysosome-like granules of mouse spermatocytes. In these cells the number of multivesicular bodies varied during spermatogenesis. Spermatids and to a lesser extent residual bodies also performed adsorptive endocytosis. In the rat and monkey (Macaca fascicularis) diferric transferrin was specifically taken up by germ cells via receptor-mediated endocytosis. The labelling was observed subsequently in membrane pits, vesicles, endosome-like bodies and pale multivesicular bodies. A progressive decrease in the frequency of the labelling of the germ cells by transferrin-gold particles was observed from spermatogonia to spermatocytes and to early spermatids, which could indicate that iron is particularly required by germ cells during the mitotic and meiotic processes. Adsorptive and receptor-mediated endocytosis therefore occurs in all classes of germ cells. These endocytic processes are most probably required for germ cell division, differentiation and metabolism.     

Proacrosin activation and acrosin release during the guinea pig acrosome reaction

The kinetics of proacrosin activation and release from guinea pig spermatozoa during the nonsynchronous acrosome reaction were studied. Epididymal spermatozoa were incubated at 37 degrees C in a defined medium (pH 7.8) containing 1.7 mM Ca2+. After 195 min, 78% of the motile spermatozoa had undergone the acrosome reaction as determined by light microscopy. Acrosin and proacrosin levels in the spermatozoa and medium were measured at the beginning of the incubation period. Most of the total acrosin activity (78%) was associated with the spermatozoa, of which greater than 90% was in the form of proacrosin. Proacrosin represented a small, stable fraction (23%) of the total acrosin in the medium; it did not activate to acrosin while in the medium. After 195 min, a decrease in sperm-associated total acrosin (42%; p less than 0.05) was accompanied by an increase in the total acrosin level in the medium (115%; P less than 0.05). No change in the relative proacrosin content (percent of total acrosin) was evident in either medium or spermatozoa. Additional experiments quantified acrosin and proacrosin during the progression of the acrosome reaction. Both the loss of sperm-associated total acrosin and the increase in total acrosin levels in the medium were highly correlated with the fraction of acrosome-reacted spermatozoa (r = 0.954 and 0.922, respectively; P less than 0.001). However, the rate of acrosin appearance in the medium was only 60% (P less than 0.001) of the rate of acrosin loss from the spermatozoa. The fractional proacrosin content of spermatozoa (94%) and medium (31%) remained unchanged during the acrosome reaction (r = 0.15 and 0.30, respectively; P greater than 0.1).(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of proacrosin conversion in isolated guinea pig sperm acrosomal apical segments

Following sodium dodecyl sulfate-polyacrylamide gel electrophoresis, proacrosin has been identified in extracts of intact guinea spermatozoa as a major silver staining band which reacted immunologically with antibodies made against purified proacrosin from guinea pig testis. Proacrosin exhibited an approximate Mr of 50,000 and was rapidly converted to an Mr 45,000 protein following induction of the acrosome reaction with 2.0 mM CaCl2 and 1 micrograms/ml A23187. Apical segments isolated at pH 6.0 from guinea pig spermatozoa also contained a major silver staining band of Mr 50,000 which cross-reacted with antibodies to guinea pig testis proacrosin. Subcellular fractionation of spermatozoa indicated that proacrosin remained in the particulate fraction of homogenized spermatozoa and was enriched within the isolated acrosomal apical segment. When apical segments isolated at pH 6.0 were incubated at pH 7.5, proacrosin was rapidly converted to the Mr 45,000 form observed in spermatozoa undergoing the acrosome reaction. The conversion process in isolated apical segments was inhibited by leupeptin and was accelerated in the presence of calcium, magnesium, and manganese. Zinc completely inhibited the conversion of proacrosin to the Mr 45,000 protein. Neither proacrosin nor the Mr 45,000 protein were released into the supernatant fluid during the incubation of apical segments at pH 7.5. Furthermore, the proteins were resistant to solubilization by 150 mM NaCl and 1% Triton X-100 but were solubilized by treatment of apical segments with 1 M NaCl. These results provide evidence as to the identity and subcellular distribution of proacrosin in intact guinea pig sperm prior to zymogen conversion and suggest that isolated apical segments exhibit a subset of the exocytotic reactions leading to completion of the acrosome reaction.     

日本沼虾高尔基体在精子发生过程中的变化

用岸民镜技术研究了日本沼虾精子发生过程中生精细胞内高尔基体变化。结果表明：精原细胞内,高尔基体结构典型,分布在核膜附近,许多膜囊通过过连接小管相互连接。初级精母细胞内,高尔基体结构紧凑且更典型,更造近核膜,在反面的分泌活动旺盛,产生大量初级溶酶体;     

The interaction of boar sperm proacrosin with its natural substrate, the zona pellucida, and with polysulfated polysaccharides

Boar sperm acrosin is an acrosomal protease with trypsin-like specificity, and it functions in fertilization by assisting sperm passage through the zona pellucida by limited hydrolysis of this extracellular matrix. In addition to a proteolytic active site domain, acrosin binds the zona pellucida at a separate binding domain that is lost during proacrosin autolysis. In this study, we quantitate the binding of proacrosin to the physiological substrate for acrosin, the zona pellucida, and to a non-substrate, the polysulfated polysaccharide fucoidan. Binding was analogous to sea urchin sperm bindin that binds egg jelly fucan and the vitelline envelope of sea urchin eggs. Proacrosin was found to bind to fucoidan and to the zona pellucida with binding affinities similar to bindin interaction with egg jelly fucan. These interactions were competitively inhibited by similar relative molecular mass polysulfated polymers. Since bindin and proacrosin have distinctly different amino acid sequences, their interaction with acidic sulfate esters demonstrates an example of convergent evolution wherein different macromolecules localized in analogous sperm compartments have the same biological function. From cDNA sequence analysis of proacrosin, this binding may be mediated through a consensus sequence for binding sulfated glycoconjugates. Proacrosin binding to the zona pellucida may serve as both a recognition or primary sperm receptor, as well as maintaining the sperm on the zona pellucida once the acrosome reaction has occurred.     

A basic 18-amino acid peptide contains the polysulfate-binding domain responsible for activation of the boar proacrosin/acrosin system

Proacrosin is the zymogen of acrosin, a serine protease localized in the acrosomal matrix of mammalian sperm. Proacrosin/acrosin binds to solubilized zona pellucida glycoproteins (ZPGs) and various polysulfates in a non-enzymatic mechanism. In addition, both polysulfates and ZPGs induce proacrosin activation once they bind to the polysulfate-binding domain (PSBD) of the enzyme. We show here that the peptide (43)IFMYHNNRRYHTCGGILL(60) inhibited the proacrosin activation induced by either fucoidan or ZPGs. In addition, the peptide was recognized by the monoclonal antibody C5F10, which is directed against the PSBD region. Our data suggest that the PSBD is composed of many "subsites" that may or may not interact with each other.     

Histone synthesis and replacement during spermatogenesis in the mouse.

Separation of labelled nuclei by sedimentation velocity at unit gravity (Staput method) was used to study the timing of histone synthesis and replacement by testis-specific basic nuclear protein (TSP) during spermatogenesis in the mouse. Animals were injected (intratesticularly) with 1.25 micronCi per testis 3H-arginine or 2.5 micronCi per testis 3H-lysine, testis nuclei were separated, and the acid extract of each nuclear fraction was analyzed by acrylamide gel electrophoresis. The distribution of labelled histones and TSP in separated nuclei was assessed 2 h after incorporation. Changes in the labelled histone and TSP content of nuclei during subsequent differentiation (1--34 days post-label) was followed in fractions of separated testis cell nuclei and in nuclei of cauda epididymal spermatozoa. Analysis of total histone and (TSP) content indicated quantitative changes during development. Nuclei from primary spermatocytes had relatively larger amounts of histones H1 and H4. Spermatid nuclei showed a relative reduction in histones H1 and H4, coincident with the appearance of TSP in these nuclei. These results suggested that synthesis and/or removal of certain histones must occur in late primary spermatocyte and early spermatid stages of spermatogenesis. Results of labelling experiments indicated several periods of histone synthesis during spermatogenesis: (1) closely associated with the last DNA synthesis(i.e., in early primary spermatocytes), (2) late in meiotic prophase (i.e., in pachytene primary spermatocytes) and (3) simultaneous with TSP synthesis (i.e., in late spermatids). Histone H1 was more heavily labelled toward the end of the primary spermatocyte period. Histone H4 was more heavily labelled in the early primary spermatocyte period, and again at the time of TSP synthesis in spermatids. Histones synthesized before the pachytene primary spermatocyte stage appeared to be replace, but histones synthesized later in spermatogenesis appeared to be at least partially retained in epididymal spermatozoa. These results suggested that repeated specific alterations in the protein complement of the nucleus are an integral part of spermatogenic differentiation in the mouse.     

Ultrastructural localization of proacrosin and acrosin in ram spermatozoa

Proacrosin and acrosin were localized immunocytochemically at the electron microscope level in ram spermatozoa undergoing an ionophore-induced acrosome reaction. Antigenicity was preserved after fixation with 0.5% w/v ethyl-(dimethylaminopropyl)-carbodimide, and an antibody preparation was used that reacted with all major forms of ram acrosin. All stages of the acrosome reaction could be observed in a single preparation. At the earliest stage, labeling was observed throughout the acrosomal contents, which were just beginning to disperse. As dispersal proceeded, labeling diminished, being associated only with visible remnants of the acrosomal matrix. By the time the acrosome had emptied, almost no labeling could be detected on the inner acrosomal membrane. The relationship between matrix dispersal and proacrosin activation was studied in isolated ram sperm heads. While proacrosin was prevented from activating, the acrosomal matrix remained compact; but as activation proceeded, the matrix decondensed and dispersed in close parallel. By the time proacrosin activation was complete, the acrosomal contents had almost entirely disappeared. We conclude that proacrosin is distributed throughout the acrosomal contents as an intrinsic constituent of the acrosomal matrix. During the acrosome reaction, proacrosin activation occurs, resulting directly in decondensation of the matrix. All the contents of the acrosome including acrosin disperse and, by the time the acrosome is empty and the acrosomal cap is lost, only occasional traces of acrosin remain on the inner acrosomal membrane. Since the acrosomal cap is normally lost during the earliest stages of zona penetration, acrosin's role in fertilization is unclear: it does not appear to be a zona lysin bound to the inner acrosomal membrane.     

Comparative activation studies with extracted and purified human proacrosin

Proacrosin was purified from acid extracts of human spermatozoa by concanavalin A precipitation and Bio-Gel P-100 chromatography. Two molecular weight forms of proacrosin were obtained, a major one with a Mr of 70,000-71,000 and a minor one with a Mr of 47,000-53,000. In contrast to sperm extracts, the purified forms of proacrosin were free of acrosin inhibitor(s) and nonzymogen acrosin. By modulating pH, ionic strength and temperature, the activation of proacrosin in sperm extracts was compared to only the major form of purified proacrosin, since it seemed to be the source of the lower molecular weight form of proacrosin. In both preparations, proacrosin activation occurred maximally over a broad pH range (7.6-8.8 for purified proacrosin and 7.6-9.6 for extract). Additionally, an ionic strength of 0.1 and above caused a decrease in proacrosin activation in both preparations. Similarly, proacrosin was sensitive to short incubation periods at 45 degrees C and above which caused a decrease in the amount of proacrosin found in both preparations.     

Cytochemical detection of phosphatase and arylsulphatase activities in the midgut of Centropages typicus (Copepod, Calanoid)

Ultrastructural study of the midgut of Calanoid Copepods revealed the presence of several cell types in all species. In a previous report we described and assigned a function to each of these cell types. In order to affirm the validity of those assignments we undertook an investigation of enzymatic activity especially of phosphatase and arylsulphatase. By cytochemical methods, alkaline phosphatase activity was detected in R-, R'-D- and B-cells, with labelling being observed on the apical plasmic membrane level in all four, and in B-cells on the pinocytotic vesicle membranes. Acid phosphatase and aryl-sulphatase activities were only detectable in B-cells; the most frequently labelled structures were located in the vacuolar system, dictyosomes and Golgi vesicles, although Golgi structures occasionally reacted to acid phosphatase. Nome of the dense bodies observed in B-cells reacted to arylsulphatase. Similarly they were unevenly labelled during acid phosphatase tests. Hence it may be assumed that dense bodies are not involved in hydrolases. It is possible that these enzymes originated from vesicles generated by the Golgi saccules surrounding and joined to the vacuoles, thus bypassing the lysosome I stage.