Hamster sperm antigen P26h is a phosphatidylinositol‐anchored protein

We have previously identified a hamster sperm protein, P26h, proposed to be involved in the interaction between spermatozoa and the egg's zona pellucida. In this study we investigated the mechanism of P26h accumulation on hamster spermatozoa during epididymal maturation. Immunocytochemical studies showed an accumulation of P26h on the acrosomal cap of hamster spermatozoa during epididymal transit. To document the anchoring mechanism of P26h, cauda epididymal spermatozoa were exposed to different treatments. High‐salt buffered solutions were unable to remove P26h from the surface of intact spermatozoa. P26h was released in a dose‐dependent manner when live spermatozoa were treated with a solution of phospholipase C specific to phosphatidylinositol. In contrast, the P26h remained associated to the sperm surface following treatment with trypsin. To document the transfer mechanisms of P26h on the maturing spermatozoa, prostasomes were isolated from the epididymal fluid and subjected to immunodetection. Western blots and immunogold studies showed that P26h was associated to epididymal prostasomes. Phospholipase C treatment performed on epididymal prostasomes, indicated that P26h also is anchored to these vesicles via a phosphatidylinositol. These results suggest that epididymal sperm maturation involves a cell to cell transfer of a phosphaditylinositol‐anchored protein and that prostasomes may be implicated in this process. Mol. Reprod. Dev. 52:225–233, 1999. © 1999 Wiley‐Liss, Inc.     

Comparative immunoreactivity of mouse and hamster sperm proteins recognized by an anti-P26h hamster sperm protein

The binding of the spermatozoon to the zona pellucida is a species-specific phenomenon. We have previously shown that the binding of hamster sperm to the homologous zona pellucida involves a sperm 26-kDa glycoprotein, the P26h, originating in the epididymis. In order to establish to what extent this sperm protein is involved in the species-specific recognition of the egg's extracellular coat, we have compared the inhibitory properties of anti-P26h antibodies in a sperm-zona pellucida assay using hamster and mouse gametes. Anti-P26h IgGs inhibit, in a dose-dependent manner, gamete interactions in both species, although in a less efficient manner in the mouse than in the hamster. While anti-26kDa Fab fragments are as efficient as the intact IgG to inhibit hamster sperm-zona pellucida binding, they have no effect on mouse gamete interaction. ELISA, Western blot, and immunohistochemical experiments have been performed in order to characterize the mouse antigen(s) recognized by the anti-P26h antiserum. ELISA and Western blots showed that this antiserum recognized two proteins on mouse spermatozoa that are less reactive than the hamster P26h. These antigens are localized in the acrosomal region of epididymal spermatozoa of both species. These results indicate that the hamster P26H involved in zona pellucida interaction has certain unique epitopes, while others are common to the sperm of both species. © 1995 Wiley-Liss, Inc.     

P26h and dicarbonyl/L-xylulose reductase are two distinct proteins present in the hamster epididymis

We have previously identified a 34 kDa protein (P34H) on the human sperm surface covering the acrosome. Using the hamster, we have also described a sperm protein, P26h, which is acquired by spermatozoa during epididymal transit. Both P34H and P26h belong to the carbonyl reductase family. Using molecular tools derived from P34H, we searched in the hamster epididymis for another protein related to the human sperm protein. Cloning and sequencing of P31h cDNA revealed 100% homology with the kidney DCXR (Dicarbonyl/L-Xylulose reductase). Northern Blot experiments revealed a single mRNA that was more expressed in the caput than in the corpus and cauda segment of adult epididymides. In situ hybridization was performed on sexually mature hamsters showing that the mRNA was localized in the principal cells throughout the epididymis. Using an anti-P34H antibody we have identified a P34H related protein named P31h (for 31 kDa). This protein showed 2D-electrophoretic behavior different from P26h and was detectable all along the epididymis (caput, corpus, and cauda) by Western Blot analysis. Immunohistochemistry techniques showed that P31h was localized in the perinuclear region of the principal cells of the epididymal epithelium within the three sections, both in sexually mature and immature animals. Results are discussed with regards to the potential function of DCXR in the epididymis.     

Identification and characterization of P31m, a novel sperm protein in Cynomolgus monkey (Macaca fascicularis)

We have previously described a hamster sperm glycoprotein, P26h, which is implicated in the cascade of events occurring during the interaction between mature spermatozoa and the oocyte's zona pellucida. The P26h is acquired on the acrosomal cap of the spermatozoon during its maturation arising within the epididymis. Lately, using a polyclonal antiserum raised against P26h, a 34 kDa protein, P34H, has been identified on the acrosomal cap of the human spermatozoon. The cloning and sequencing of the cDNA encoding P34H has revealed a 65% similarity between the P34H and P26h amino acid sequences. Considering that P26h shows total immunocontraceptive properties in the hamster, it is of relevant importance to have an animal model phylogenetically closer to the human. Using the Cynomolgus monkey, we searched for a protein autologous to the human P34H. A 31 kDa protein, the P31m, localized on the acrosomal cap of the monkey spermatozoon has been identified by a Western blot analysis and by immunohistochemical techniques using an anti-hamster P26h antiserum. Northern blot analysis showed increasing high levels of the P31m mRNA through the epididymis and at lower levels in the testis. In situ hybridization showed the presence of the P31m mRNA in the principal cells of the epididymis. The cloning and sequencing of the cDNA encoding the P31m showed a high homology of 97% identity between the P31m and P34H nucleotidic sequences. This study clearly demonstrates that the monkey P31m is the homologous protein of the hamster P26h and of the human P34H. Mol. Reprod. Dev. 59: 431-441, 2001.     

Localization of ornithine decarboxylase in rat testicular cells and epididymal spermatozoa

We have employed a monospecific, polyclonal antibody to ornithine decarboxylase (ODC) for the immunocytochemical localization of ODC in freshly isolated testicular cells, epididymal spermatozoa, and cultured Sertoli cells. Antigenically detectable material was present in the cytoplasm of all cell types tested and was highly concentrated in the acrosomal vesicle of round spermatids and in the acrosome region of epididymal spermatozoa. The specific enzymatic activity of ODC, as measured biochemically, was much higher in the interstitial cells than in the other testicular cell types, and no ODC activity was detected in the epididymal spermatozoa or in the Sertoli cells after 5 days in culture. These studies showed that, while all testicular cell types studied contained ODC-like immunoreactive molecules, only testicular germ cells and interstitial cells exhibited detectable ODC activity.     

Testis fascin (FSCN3): a novel paralog of the actin-bundling protein fascin expressed specifically in the elongate spermatid head

During spermiogenesis, significant morphological changes occur as round spermatids are remodeled into the fusiform shape of mature spermatozoa. These changes are correlated with a reorganization of microfilaments and microtubules in the head and tail regions of elongating spermatids. There is also altered expression of specialized actin- and tubulin-associated proteins. We report the characterization of a novel, spermatid-specific murine paralog of the actin-bundling protein fascin (FSCN1); this paralog is designated testis fascin or FSCN3. Testis fascin is distantly related to fascins but retains its primary sequence organization. cDNA clones of mouse testis fascin predict a 498 amino acid protein of molecular mass 56 kD that shares 29% identity with mouse fascin. Mapping of murine and human FSCN3 genes shows localization to the 7q31.3 chromosome. Northern analysis indicates that FSCN3 expression is highly specific to testis and that in situ hybridization further restricts expression to elongating spermatids. Antibodies raised against recombinant FSCN3 protein identify a band at 56 kD in testis, epididymis, and epididymal spermatozoa, suggesting that testis fascin persists in mature spermatozoa. In accord with the in situ hybridization results, immunofluorescent microscopy localizes testis fascin protein to areas of the anterior spermatid head that match known distributions of F-actin in the dorsal and ventral subacrosomal spaces. It is possible that testis fascin may function in the terminal elongation of the spermatid head and in microfilament rearrangements that accompany fertilization.     

Spermatogenesis in the golden hamster during the first spermatogenic wave: a flow cytometric analysis

In the present study propidium iodide was used as a fluorescent dye to stain DNA of cells of hamster testicular origin and fluorescent intensities were analyzed by flow cytometry. We used hamster testicular cells from the first spermatogenic wave to observe the consecutive appearance of the different types of cells during puberty. At 12 days postpartum (dpp) diploid cells (including spermatogonia) predominated and some tetraploid cells were also present. Tetraploid spermatocytes increased dramatically by 21 dpp. The first haploid cells appeared at 21 dpp but substantial numbers were first present at 23 dpp. Immature haploid cells predominated at 32 dpp. Elongating condensing spermatids appeared at 34 dpp and spermatozoa began to leave the testis to enter the epididymidis at 36-38 dpp marking the end of the first round of spermatogenesis. Using acridine orange staining flow cytometry, chromatin condensation was followed by measuring fluorescence decrease from early round spermatids to spermatozoa obtained from the initial segment and from the cauda epididymides. The major portion of sperm chromatin condensation (88-90%) in the hamster occurred in the testis and only 10-12% occurred during epididymal sperm maturation. Spermatozoa in the initial segment of the epididymidis of the hamster contained a small amount of RNA that was no longer present in sperm of the cauda epididymidis, indicating that RNA was lost during epididymal sperm maturation in this species. Mol. Reprod. Dev. 55:205-211, 2000.     

Identification of a heat-shock protein Hsp40, DjB1, as an acrosome- and a tail-associated component in rodent spermatozoa

Iba1 is a 17-kDa EF-hand protein highly expressed in the cytoplasm of elongating spermatids in testis. Using Iba1 as a bait, we performed yeast Two-hybrid screening and isolated a heat-shock protein Hsp40, DjB1, from cDNA library of mouse testis. To characterize DjB1 that is encoded by Dnajb1 gene, we carried out immunoblot analyses, in situ hybridization, and immunohistochemistry. Immunoblot analyses showed that DjB1was constitutively expressed in mouse testis and that its expression level was not changed by heat shock. Dnajb1 mRNA was exclusively expressed in spermatocytes and round spermatids in mouse testis, and Dnajb1 protein DjB1 was predominantly expressed in the cytoplasm of spermatocytes, round spermatids, and elongating spermatids. In mature mouse spermatozoa, DjB1 was localized in the middle and the end pieces of flagella as well as in association with the head (acrosomal region). Association of DjB1 with the acrosomal region in sperm head was also observed in rat spermatozoa. These data suggested that DjB1, which was constitutively expressed in postmeiotic spermatogenic cells in testis, was integrated into spermatozoa as at least two components, that is, sperm head and tail of rodent spermatozoa.     

Characterization of an acrosomal matrix protein in hamster and bovine spermatids and spermatozoa.

Experiments have been carried out characterizing an Mr 22,000 protein present in the acrosomes of hamster and bull spermatozoa. The Mr 22,000 protein is resistant to solubilization in detergent solutions containing high or low salt and has a pI of -5.2. With various lectins, the protein from hamster sperm was shown to be sparingly glycosylated with N-acetylglucosamine, mannose, and galactose while that from the bull demonstrated a slight reactivity for galactose. Using a specific monoclonal antibody (MAB 4/18), the Mr 22,000 polypeptide has been localized exclusively to the acrosomes of mature testicular and epididymal hamster and bovine sperm. Acrosomal components of differentiating bovine and hamster spermatids in tissue sections did not react with the monoclonal antibody, although the protein was present in immunoblots of round spermatids. In bovine sperm, MAB 4/18-staining at the ultrastructural level with immunogold-labeled second antibody was present as a reticulum throughout the acrosomal cap and as punctate aggregates in the equatorial segment. In hamster sperm, MAB 4/18-reactivity was present along the periphery of the acrosome in conjunction with matrix components (M1 and M2), as well as along the inner acrosomal membrane. These observations indicate that the acrosomes of bovine and hamster sperm possess an immunologically related Mr 22,000 protein and suggest that differences in MAB 4/18-staining of spermatids and spermatozoa is a result of epitope modification and/or a change in accessibility of the epitope to the antibody probe during the course of spermiogenesis. Based on its localization and solubility properties, we suggest that the Mr 22,000 protein, in conjunction with other polypeptides, forms a structural framework to maintain acrosomal shape and/or compartmentalize acrosomal contents.     

Stage and cell-specific expression of calmodulin-dependent phosphodiesterases in mouse testis

Calcium and cyclic nucleotides are second messengers that regulate the development and functional activity of spermatozoa. Calcium/calmodulin-dependent phosphodiesterases (CaM-PDEs) are abundant in testicular cells and in mature spermatozoa and provide one means by which calcium regulates cellular cyclic nucleotide content. We examined the spatial and temporal expression profiles of three knownCaM-PDE genes, PDE1A, PDE1B, and PDE1C, in the testis. In situ hybridization and immunofluorescent staining showed that both PDE1A and PDE1C are highly expressed but at different stages in developing germ cells. However, a very low hybridization signal of PDE1B exists uniformly throughout the seminiferous epithelium and the interstitium. More specifically, PDE1A mRNA is found in round to elongated spermatids, with protein expression in the tails of elongated and maturing spermatids. In contrast, PDE1C mRNA accumulates during early meiotic prophase and throughout meiotic and postmeiotic stages. Immunocytochemistry showed a diffuse, presumably cytosolic distribution of the expressed protein. The distinct spatial and temporal expression patterns of CaM-PDEs suggest important but different physiological roles for these CaM-PDEs in developing and mature spermatozoa.     

Transient appearance of CRES protein during spermatogenesis and caput epididymal sperm maturation

In previous studies we identified an epididymal gene that exhibits homology to the cystatin family of cysteine protease inhibitors. The expression of this gene, termed CRES (cystatin-related epididymal and spermatogenic), was shown to be highly restricted to the proximal caput epididymal epithelium with less expression in the testis and no expression in the 24 other tissues examined. In this report, studies were carried out to examine CRES gene expression in the testis as well as to characterize the CRES protein in the testis and epididymis. In situ hybridization experiments revealed that within the testis CRES gene expression is stage-specific during spermatogenesis and is exclusively expressed by the round spermatids of Stages VII-VIII and the early elongating spermatids of Stages IX and X. Immunohistochemical studies demonstrated that CRES protein was transiently expressed in both the testis and epididymis. Within the testis the protein was localized to the elongating spermatids, whereas within the epididymis CRES protein was exclusively synthesized by the proximal caput epithelium and then secreted into the lumen. Surprisingly, the secreted CRES protein had completely disappeared from the epididymal lumen by the distal caput epididymidis. Western blot analysis of testicular and epididymal proteins showed that the CRES antibody specifically recognized a predominant 19 kDa CRES protein and a less abundant 14 kDa form. These observations suggest that the CRES protein performs a specialized role during sperm development and maturation. © 1995 Wiley-Liss, Inc.     

Activité aromatase dans les cellules germinales mâles: quelle signification fonctionnelle?

The ability of the male gonad to convert androgens into estrogens is well known. According to age, aromatase activity has been already measured in immature and mature rat Leydig cells as well as in Sertoli cells. Recently, in different studies, a cytochrome P450_arom has even been immunolocalized not only in Leydig cells but also in germ cells of mouse, brown bear and rooster whereas in pig, ram and human the aromatase is mainly present in Leydig cells. Our purpose was to investigate the testicular cell distribution of cytochrome P450_arom mRNA in adult rat using RT-PCR. With 2 highly specific primers located on exons 8 and 9, we have been able to amplify a 289 bp aromatase fragment not only in Leydig cells and Sertoli cells but more importantly in highlyenriched preparations of pachytene spermatocytes, round spermatids and testicular spermatozoa. These amplified products showed 100% homology with the corresponding fragment of the rat ovary cDNA. In parallel, using an anti-human cytochrome P450_arom antibody we have demonstrated the presence of a 55 kDa protein in seminiferous tubules and crude germ cell (pachytene spermatocytes and round spermatids) preparation of the mature rat. After incubation with tritiated androstenedione, the aromatase activities in the microsomal fractions were 3.12±0.19 pmoles/mg/h in the testis, 1.25±0.13 in the seminiferous tubules and 1.53±0.15 in the crude germ cells. In purified testicular spermatozoa the aromatase activity was 2.96±0.69 pmoles/mg/h and found to be 5-fold higher when compared to that of either purified pachytene spermatocytes or round spermatids. Using a quantitative RT-PCR method with a standard cDNA 29 bp shorter, we have compared the amount of cytochrome P450_arom mRNA in mature rat Leydig cells and Sertoli cells. In purified Leydig cells from 90 day-old rats the P450_arom mRNA level was: 36.2±3.4×10^?3 amoles/μg RNA whereas in Sertoli cells the mRNA level was 10 fold lower. In pachytene spermatocytes, round spermatids and testicular spermatozoa the P450_arom mRNA levels were re pectively 367.2±76.6, 117.6±22.0 and <1×10^?3 amole/μg RNA. In conclusion we have demonstrated that the P450 aromatase is present not only in Sertoli cells and Leydig cells from mature rat testis but a biologically active aromatase exists also in germ cells (pachytene spermatocytes, round spermatids and spermatozoa). The existence of an additional source of estrogens within the genital tract of the male is now well documented and that suggests a putative role for these hormones during the male germ cell development.     

SAMP32, a testis-specific, isoantigenic sperm acrosomal membrane-associated protein

To identify novel human sperm membrane antigens, we analyzed two-dimensional gels of sperm extracts containing hydrophobic proteins that partitioned into Triton X-114. Four protein spots with isoelectric points (pIs) ranging from 4.5 to 5.5 and apparent molecular weights from 32 to 34 kDa were sequenced by mass spectrometry and found to contain common peptide sequences. Cloning the corresponding cDNA revealed that these protein spots were products of a single gene (SAMP32), encoding a protein of 32 kDa with a predicted pI of 4.57. SAMP32 has a potential transmembrane domain in the carboxyl terminus and is phosphorylated in vivo on serine 256. Northern blotting of eight human tissues and RNA dot blotting of 76 human tissues showed that SAMP32 expression was testis specific. SAMP32 contained an amino terminal domain homologous to the major malarial circumsporozoite surface protein and a domain similar to that of Krp1 from Schizosaccharomyces pombe in its carboxyl terminus. The SAMP32 locus consists of seven exons on chromosome 6q15-16.2. Antiserum against recombinant SAMP32 recognized protein spots originally cored from a two-dimensional gel. This antiserum strongly stained the equatorial segment and faintly stained the acrosome cap of ejaculated human spermatozoa by immunofluorescence. Immunoelectron microscopy showed that SAMP32 was associated with the inner acrosomal membrane in the principal and the equatorial segments of the sperm acrosome. By immunostaining enzyme-dissociated testicular cells, SAMP32 was localized to Golgi phase round spermatids and subsequent stages of acrosome biogenesis. Recombinant SAMP32 reacted with serum from an infertile man, suggesting that it is isoantigenic. Antibodies against recombinant SAMP32 inhibited both the binding and the fusion of human sperm to zona-free hamster eggs.     

Temporal expression and localization of protein farnesyltransferase during spermiogenesis and posttesticular sperm maturation in the hamster

Spermiogenesis and posttesticular sperm maturation in the epididymis are distinct developmental processes that result in a polarized spermatozoon possessing a plasma membrane partitioned into segment-specific domains of distinct composition and function. The mechanisms that specify the distribution of intracellular organelles and target proteins to restricted membrane domains are not well understood. In this study we examined the expression pattern and distribution of protein farnesyltransferase (FTase) in hamster spermatids and epididymal spermatozoa to determine if protein lipidation may represent a potential mechanism to regulate protein association with specific organelles or the plasma membrane. Round spermatids exhibited only weak immunostaining with antibody against the β-subunit of FTase, whereas elongating spermatids exhibited a high level of FTase expression that was segregated to the cytoplasmic lobe surrounding the anterior flagellum. Although FTase was released with the residual body, mature spermatids retained FTase within the midpiece and cytoplasmic droplet. In epididymal spermatozoa, FTase remained associated with the cytoplasmic droplet during its migration to the midpiece-principal piece junction; following release of the cytoplasmic droplet, no immunodetectable FTase was noted in the midpiece segment. Immunoblotting demonstrated the presence of both the α and β subunits of FTase in sperm lysates. The temporal expression pattern and restricted distribution of FTase in spermatids and epididymal spermatozoa suggest a potential role in regulating protein association with specific organelles and/or membrane domains of the mature spermatozoon. Mol. Reprod. Dev. 48:71–76, 1997. © 1997 Wiley-Liss, Inc.     

Bull subfertility is associated with low levels of a sperm membrane antigen

During epididymal transit, mammalian spermatozoa acquire new surface antigens that may participate in gamete interaction. We have previously described a 26 kDa (P26h) epididymal hamster sperm protein that is proposed to be involved in fertilization. We have also identified its human homolog, P34H. Variability in the amount of P34H on spermatozoa from fertile and idiopathic infertile men provides strong evidence that this protein is a potential marker of male fertility. Since these sperm antigens constitute a family of proteins with common antigenicity, we have investigated the presence of a related protein in bovine sperm. In the present study, a P26h antiserum recognized two bull sperm proteins of 21 kDa and 25 kDa (MW) on SDS‐PAGE. We showed that P25b could be extracted with detergent as a surface protein, whereas the P21b was associated with non‐soluble intracellular structures. Sonication of whole sperm cell suspensions and subsequent Percoll gradient centrifugation revealed that P21b may be a flagellar protein whereas the P25b may be located in the head region. Western blot analysis was used to determine the amount of P25b and P21b proteins present on spermatozoa obtained from fertile and subfertile bulls. P21b protein levels were similar in fertile and subfertile bulls, but P25b protein levels were variable. Thus, all bulls with high Non‐Return Rates (fertile bulls) demonstrated high amounts of P25b, whereas P25b levels were decreased in semen from subfertile bulls. We conclude that the protein P25b is a potential fertility marker in the bull and consequently may provide an invaluation tool for the evaluation of bull fertility. Mol. Reprod. Dev. 52:57–65, 1999. © 1999 Wiley‐Liss, Inc.