Immunochemical identification of multiple cell surface antigens appearing during specific stages of mouse spermatogenesis

Cell surface antigens that appear in a defined temporal sequence during mouse spermatogenesis were previously detected serologically, but not identified biochemically, with four heterologous antibodies prepared against purified populations of pachytene spermatocytes (AP), round spermatids (ARS), vas deferens spermatozoa (AVDS), and mixed seminiferous cells (ASC) [Millette and Bellvé, J Cell Biol 74:86–97, 1977]. These antigens have now been identified immunochemically on nitrocellulose blots from SDS polyacrylamide gels. Three antisera (AP, ARS, and ASC) recognize a similar subset of determinants on one-dimensional immunoblots of germ cells and plasma membranes prepared from a mixed population of late spermatogenic cells. Comparisons of minor bands to reveal differences among these antisera. AVDS exhibits the least complex binding pattern. The results indicate that at least ten surface constituents appear during the pachytene stage of meiosis, coincident with a period of maximal RNA and protein synthesis [Monesi, Exp Cell Res 39:197–224, 1965]. Furthermore, two-dimensional immunoblot comparisons of plasma membranes isolated from pachytene spermatocytes and round spermatids reveal differences between surface determinants detectable at these two spermatogenic stages. For example, ASC recognizes two newly described proteins that are restricted to pachytene spermatocytes (? M_r 57,000, pI 6.45) and to round spermatids (? M_r 39,500, pI 4.85), respectively.     

Spatial and temporal expression of cell surface galactosyltransferase during mouse spermatogenesis and epididymal maturation

We have previously shown that sperm-egg recognition in the mouse is mediated by the binding of galactosyltransferase (GalTase) on the sperm surface to its appropriate glycoside substrate in the egg zona pellucida [L. C. Lopez, E. M. Bayna, D. Litoff, N. L. Shaper, J. H. Shaper, and B. D. Shur (1985) J. Cell Biol. 101, 1501-1510]. In the present study, we have defined the spatial and temporal expression of surface GalTase during spermatogenesis and epididymal maturation. Purified populations of spermatogenic cells were isolated by unit gravity sedimentation, and surface GalTase expression was determined by indirect immunofluorescence and by direct enzymatic assay. GalTase is present on the surface of all spermatogenic cells assayed. During differentiation, there is a progressive redistribution of GalTase from an initially diffuse and uniform localization on the surface of primary spermatocytes to a restricted plasma membrane domain overlying the dorsal aspect of the mature acrosome. This apparent redistribution of surface GalTase was confirmed by direct enzymatic assays, which show that surface GalTase activity, normalized per cell, remains relatively constant throughout spermatogenesis, despite a drastic reduction in cell surface area. When normalized to the relevant cell surface area, the GalTase concentration per square micrometer increases 77-fold from pachytene spermatocytes to cauda epididymal sperm. Cell surface GalTase is thought to be a cytoskeletally associated transmembrane protein [N. L. Shaper, P. L. Mann, and J. H. Shaper (1985) J. Cell Biochem. 28, 229-239]; consequently we examined whether cytoskeletal components may be involved in the redistribution of GalTase during spermatogenesis. beta-Tubulin, monomeric actin, and filamentous actin were found to be present during spermatogenesis, as assayed by indirect immunofluorescence and by Western immunoblotting. alpha-Actinin and vinculin were not detectable under these conditions and served as negative controls. During spermatogenesis, the distribution of tubulin coincides with the appearance of the mitotic spindle, flagellum, and manchette. On the other hand, the distribution of filamentous actin coincides with surface GalTase, suggesting that actin-containing microfilaments may participate in the redistribution of surface GalTase during spermatogenesis.     

Biochemical evidence of haploid gene activity in spermatogenesis of the mouse

Mice were exposed to two X-ray doses of 300 and 100 R with 4 days interval in order to deplete the testes of spermatogonia and early meiotic cells. After X-ray treatment, the seminiferous tubules were labelled in culture with radioactive RNA precursors, dispersed into single cells by trypsin treatment and these were fractionated into several cell classes by velocity sedimentation at unit gravity in a Ficoll gradient. With this method quasi-homogeneous populations of middle-late pachytene spermatocytes and round spermatids (steps 1–8 of spermiogenesis) were obtained. RNA was extracted from these two cell types and analysed by linear sucrose gradient fractionation and by affinity chromatography on a poly(U)-Sepharose column. The results showed that round spermatids, as well as pachytene spermatocytes, synthesize both ribosomal RNA (rRNA) and poly(A)⁺ RNA (presumptive messenger RNA) (mRNA). The post-meiotic synthesis of RNA ceases completely in mid-spermiogenesis after nuclear elongation in spermatids has set in.     

Analysis of cell surface galactosyltransferase activity during mouse trophectodermal differentiation

The ectoplacental cone (EPC) of the Day 7.5 mouse embryo consists of a core of adhesive, proliferating trophoblast cells which transform to invasive trophoblast giant cells during implantation. Adhesive trophoblast cell types express monoclonally defined lactosaminoglycans (LAGs) at the cell surface; transformation to giant cells results in a loss of LAG cell surface expression (H. J. Hathaway and B. S. Babiarz, 1988, Cell Differ. 24, 55-66). LAGs can serve as substrates for cell surface galactosyltransferase (GalTase), providing an adhesive mechanism between a number of different cell types (B. D. Shur, 1984, Mol. Cell. Biochem. 61, 143-158). It was hypothesized that the LAGs in the EPC represented a substrate for a similar GalTase-mediated cell:cell adhesion system. Cell surface GalTase activity was demonstrated on EPC trophoblast on Day 7.5 of development by the incorporation of galactose from exogenous radiolabeled substrate. In 24- to 48-hr EPC trophoblast cultures the enzyme was localized by immunofluorescence to areas of cell:cell contact. Monolayers of differentiated trophoblast giant cells lacked this labeling pattern. The cell surface glycopeptide substrate for GalTase eluted as a single peak with an apparent molecular mass of 15,000 Da. A portion of this material was sensitive to endo-beta-galactosidase digestion, indicating that it contained a LAG structure. Perturbation of the enzyme:substrate complex in 24- to 48-hr EPC outgrowths, with alpha-lactalbumin, uridine 5'-diphosphogalactose, or anti-GalTase antibody, resulted in the disruption of cell:cell contacts. Differentiation to trophoblast giant cells resulted in a loss of sensitivity to surface GalTase perturbation. The results suggest that adhesive EPC trophoblast cells possess a GalTase-mediated cell:cell adhesion system which is downregulated upon differentiation to invasive trophoblast giant cells.     

Stage-specific increase in cell surface galactosyltransferase activity during spermatogenesis in mice bearing t alleles

Mouse sperm surface galactosyltransferase (GalTase) mediates fertilization by binding to its appropriate glycoconjugate substrate in the egg zona pellucida. GalTase is present throughout all stages of spermatogenesis, during which time it redistributes within the plasma membrane from a uniform, diffuse distribution on primary spermatocytes to a restricted domain overlying the dorsal surface of the acrosome. Previously, we have shown that GalTase activity is elevated on transmission-distorting t-bearing sperm populations, relative to normal sperm, and in this paper, we define the stage when surface GalTase activity becomes elevated during t spermatogenesis. GalTase specific activity is equal between normal and t-bearing primary spermatocytes, but following meiosis, surface GalTase activity becomes elevated nearly fourfold on t-bearing round spermatids. The increased GalTase activity on t-bearing spermatids is not due to decreased hydrolysis of the GalTase substrates, and is appropriately localized over the acrosomal region, even on misshapen sperm heads occasionally seen in t-sperm populations. These studies define the stage when a specific biochemical defect associated with mutant alleles of the T/t complex first becomes detectable. The t factors that elevate GalTase activity on round spermatids may be similar to previously identified t-specific testicular proteins that are maximally expressed at the same developmental stage, and which map to the same portion of the T/t complex.     

Meiotic DNA synthesis during mouse spermatogenesis

The incorporation of radioactivity into various cells in the sequence of spermatogenesis was measured by preparing highly purified spermatozoan nuclei from the cauda epididymidis of mice at daily intervals after injection of (3H)thymidine. The stages of differentiation of these sperm at the time of thymidine administration were calculated from the kinetics of spermatogenesis. The procedure for purification of sperm nuclei included sonication, mechanical shearing, and treatment with trypsin, DNase, Triton X-100, 2M NaC1, and sodium dodecyl sulfate. DNA was isolated from these nuclei by treatment with dithiothreitol and pronase, followed by phenol extraction and ethanol precipitation. The levels of radioactivity in the epididymal sperm head preparations were low (less than 13 dpm/mouse) for 27 days after injection, and then rose dramatically to over 4 times 104 dpm/mouse. Further experiments demonstrated that the 11 dpm of 3H radioactivity contained in sperm heads at 21 or 26 days after injection of (3H)TdR was significantly above background and contamination levels from other cells or other sources. Most of the radioactivity was in the sperm DNA and represented incorporation of tritium from (3H)TdR into the nuclear DNA of meiotic cells at 0.002 percent of the rate of incorporation into S-phase cells. Little, if any, (3H)TdR was incorporation into the DNA of spermatids. The levels of DNA synthesis during the meiotic prophase in the mouse appear to be much lower than those reported for other organisms.     

Appearance of cell surface auto- and isoantigens during spermatogenesis in the rabbit

The appearance of spermatogenic cell surface auto- and isoantigens can be precisely determined by utilizing techniques that separate spermatogenic cells. Using cytotoxic (complement dependent) auto- and iso- rabbit antirabbit whole semen sera, specific spermatogenic auto- and isoantigens were first detected following the maturation of spermatogonia into primary pachytene spermatocytes. The antisera employed were cytotoxic (complement dependent) for pachytene diplotene and primary spermatocytes and spermatids but not for type A, intermediate, or type B spermatogonia. Furthermore, Sertoli cells, endothelial cells, Leydig cells, and erythrocytes were not lysed by the antisera. These observations support the concept of a blood-testis barrier. Only after migration of spermatogonia to the luminal side of the barrier can autoantigenic molecules be synthesized and/or inserted into the plasma membrane of spermatogenic cells. Thus, the appearance of surface autoantigens offers a model system to study the synthesis of specific molecules which are inserted into the plasma membrane at a precise time during development.     

Two genes required for cell fusion during yeast conjugation: evidence for a pheromone-induced surface protein.

We characterized two genes, FUS1 and FUS2, which are required for fusion of Saccharomyces cerevisiae cells during conjugation. Mutations in these genes lead to an interruption of the mating process at a point just before cytoplasmic fusion; the partition dividing the mating pair remains undissolved several hours after the cells have initially formed a stable "prezygote." Fusion is only moderately impaired when the two parents together harbor one or two mutant fus genes, and it is severely compromised only when three or all four fus genes are inactivated. Cloning of FUS1 and FUS2 revealed that they share some functional homology; FUS1 on a high-copy number plasmid can partially suppress a fus2 mutant, and vice versa. FUS1 remains essentially unexpressed in vegetative cells, but is strongly induced by incubation of haploid cells with the appropriate mating pheromone. Immunofluorescence microscopy of alpha factor-induced a cells harboring a fus1-LACZ fusion showed the fusion protein to be localized at the cell surface, concentrated at one end of the cell (the shmoo tip). FUS1 maps near HIS4, and the intervening region (including BIK1, a gene required for nuclear fusion) was sequenced along with FUS1. The sequence of FUS1 revealed the presence of three copies of a hexamer (TGAAAC) conserved in the 5' noncoding regions of other pheromone-inducible genes. The deduced FUS1 protein sequence exhibits a striking concentration of serines and threonines at the amino terminus (46%; 33 of 71), followed by a 25-amino acid hydrophobic stretch and a predominantly hydrophilic carboxy terminus, which contains several potential N-glycosylation sites (Asn-X-Ser/Thr). This sequence suggests that FUS1 encodes a membrane-anchored glycoprotein with both N- and O-linked sugars.     

Characterization of Staphylococcus aureus cell wall glycan strands, evidence for a new beta-N-acetylglucosaminidase activity

Using sequential digestion with the glycyl-glycine endopeptidase lysostaphin followed by the pneumococcal N-acetylmuramyl-L-alanine amidase (amidase), the glycan strands of the peptidoglycan of Staphylococcus aureus were purified and analyzed by a combination of reverse-phase-high pressure liquid chromatography (HPLC) and mass spectrometry. Reverse-phase-HPLC resolved the glycan strands to a family of major peaks, which represented oligosaccharides composed of repeating disaccharide units (N-acetylglucosamine-[beta-1, 4]-N-acetylmuramic acid) with different degrees of polymerization and terminating with N-acetylmuramic acid residues at the reducing ends. The method allowed separation of strands up to 23-26 disaccharide units with a predominant length between 3 and 10 and an average degree of polymerization of approximately 6. Glycan strands with a higher degree of polymerization (>26 disaccharide units) represented 10-15% of the total UV absorbing glycan material. A unique feature of the staphylococcal glycan strands was the presence of minor satellite peaks that were present throughout the HPLC elution profile eluting either just prior or shortly after the major oligosaccharide peaks. A number of observations including mass spectrometric analysis suggest that the satellites are the products of an N-acetylglucosaminidase activity that differs from the atl gene product and that appears to be involved with modification of the glycan strand structure.     

Post-meiotic shifts in HSPA2/HSP70.2 chaperone activity during mouse spermatogenesis

HSPA2 (formerly HSP70.2) is a testis-specific member of the HSP70 family known to play a critical role in the completion of meiosis during male germ cell differentiation. Although abundantly present in post-meiotic cells, its function during spermiogenesis remained obscure. Here, using a global proteomic approach to identify genome-organizing proteins in condensing spermatids, we discovered an unexpected role for HSPA2, which acquires new functions and becomes tightly associated with major spermatid DNA-packaging proteins, transition proteins 1 and 2. Hence, HSPA2 is identified here as the first transition protein chaperone, and these data shed a new light on the yet totally unknown process of genome-condensing structure assembly in spermatids.     

Post-meiotic gene activity in spermatogenesis of the mouse

Mouse male germ cells at middle-late pachytene and early spermatid stages obtained by velocity sedimentation at unit gravity in albumin gradients were labelled in culture with [³H]uridine. The newly synthesized RNAs extracted from polysomes of the 2 cell types were studied by sucrose gradient fractionation and poly(U) Sepharose chromatography.The results showed that round spermatids, as well as pachytene spermatocytes, synthesize both ribosomal and polyadenylated RNA molecules. Since these latter are engaged in polysomes they are presumably active messenger RNA molecules.     

Alterations in cell surface galactosyltransferase activity during limb chondrogenesis in brachypod mutant mouse embryos

The autosomal mutation brachypod (bpH/bpH) in the mouse affects the development of precartilage mesenchymal condensation in the limb-bud. We have previously shown that this defect is localized to the expression of terminal N-acetylglucosamine (GlcNAc) glycoproteins in the plasma membrane (Elmer and Wright, '83). The present study is focused on cell surface galactosyltransferase (GalTase), an ectoenzyme that transfers galactose to its GlcNAc substrate. Purified plasma membrane preparations derived from wild-type (+/+), heterozygote (+/bpH) and brachypod (bpH/bpH) embryonic mouse limb cells were assayed for GalTase activity during in vitro and in utero chondrogenesis using High-Performance Liquid Chromatography (HPLC). On embryonic day E12, prior to overt expression of the mutant gene, no significant difference in GalTase activity was observed. By the third day in culture, all major chondrogenic elements of the autopod were present in +/+ and +/bpH embryos, whereas the mutant autopods were markedly deficient in staining and appeared consistently shorter. The accumulation of alcianophilic cartilage matrix in the wild-type was accompanied by a 29% increase in GalTase activity, which reflected the net change (29%) observed during development from days E12 to E13 in utero. The GalTase activity for the in utero E13 mutant (13%) was significantly different from control. In culture, day E12 mutant autopods actually decreased in their GalTase level by 3 days so that the activity was reduced to only 57% of the wild-type. Though GalTase activity in the heterozygote showed an intermediate expression, optical image analysis did not reveal consistent differences in cartilage development when compared to +/+, arguing against a gene-dosage effect at the gross anatomical level. These data indicate that an increase in plasma membrane GalTase activity is a natural developmental event that occurs during limb-bud chondrogenesis and a decrease in GalTase activity contributes to the dysmorphogenesis in brachypod limb-buds.     

Characterization of a chicken polyubiquitin gene preferentially expressed during spermatogenesis.

We have previously reported that a chicken polyubiquitin gene (Ub II) not expressed under normal or heat shock conditions in chick fibroblasts is transcribed during spermatogenesis [(1987) Nucleic Acids Res. 15, 9604]. The level of Ub II mRNA is several-fold higher in testis cells than in somatic tissues. The gene Ub II possesses characteristic features not seen in the polyubiquitin gene expressed in heat shock conditions (Ub I). The 5' noncoding region of Ub II shows the consensus cAMP regulatory element (CRE) followed immediately downstream by a CA dinucleotide. It has been proposed that this extended CRE may be involved in the coordinate expression of various genes during spermatogenesis.     

Expression of murine Asb-9 during mouse spermatogenesis

We previously showed that Asb-4 and Asb-17 is uniquely expressed in developing male germ cells. A recent report showed that Asb-9 is specifically expressed in the kidney and testes; however, detailed expression patterns in developing germ cells have not been shown. Northern blot analysis in various tissues demonstrated that mAsb-9 was strongly expressed in the testes. Expression analysis by RT-PCR and Northern blot in developing mouse testes indicates that mAsb-9 is expressed from the fourth week after birth to adulthood, with the highest expression in round spermatids. Expression sites were further localized by in situ hybridization in the testes. Pachytene spermatocytes and spermatids expressed mAsb-9 but spermatogonia and generated spermatozoa did not. This study reveals that mAsb-9 could be a specific marker of active spermatogenesis and would be useful for studies of male germ cell development.