The major protein of bull seminal plasma is a secretory product of seminal vesicle

We isolated the major protein with apparent molecular weight, Mr, 15,000-16,000 from seminal plasma as well as from seminal vesicle secretion of bull and proved by amino acid analysis and tryptic peptide mapping that the two proteins were identical. An antiserum against this major protein was employed to quantitate and identify the major protein in seminal plasma as well as in seminal vesicle secretion. The antiserum did not cross-react with proteins from bovine or human plasma or follicular fluid, respectively. Cell-free translation of poly(A+)RNA isolated from seminal vesicle tissue resulted in formation of one major species with apparent Mr 18,000. Using the anti-major protein antiserum, this major species was specifically immuno absorbed. We thus provided evidence that the major protein component of bull seminal plasma is a secretory protein of seminal vesicles. Furthermore, it appeared that the isolated major protein may be closely related to the protein PDC109, purified from bull seminal plasma and sequenced by Esch et al. (Biochem. Biophys. Res. Commun. 113, 861-867 (1983).     

Identification and preliminary characterization of a sperm-binding protein in normal human semen

In the seminal plasma of normal men a protein, immunologically related to a major protein (RSV-IV) secreted from the rat seminal vesicle epithelium, was detected by competition with RSV-IV in a specific radioimmunoassay using a rabbit anti RSV-IV antiserum. The protein was partly (80%) purified by column chromatography; characterization by gel electrophoresis indicated that the protein is slightly basic and has a molecular weight of 140 000. The protein was present on the surface of human spermatozoa as well as in the ejaculates of azoospermic men and it is believed to be a sperm-binding protein.     

Synthesis of a testosterone-dependent secretory protein by rat seminal vesicle-derived cell lines.

Primary cell cultures were established from explants of rat seminal vesicle. The establishment of primary cell cultures required, among other factors, the presence of testosterone. Two cell populations were detected in such primary cultures: fibroblast-like cells and epithelial-like cells; the latter encompassed a subtype of small cells and a subtype of large squamous cells (most likely the result of a degenerative process acting upon the former). Histochemical, as well as electron-microscopical observations, indicated the presence of a persistent secretory activity in the small epithelial cells; fibroblast and large squamous epithelial cells were inactive in this respect. Staining of the cells with a peroxidase-conjugated antibody and analysis of the proteins produced in the presence of labelled methionine, showed that one of the major rat seminal vesicle secretory proteins, namely RSV-IV, was also produced. Conditions which favoured the growth of epithelial cells, rather than of fibroblasts, were determined. The use of nearly homogeneous cell populations and the use of collagen-coated Petri dishes, allowed the cloning of two independently obtained permanent cell lines, namely SVC-1 and SVC-2. The in vitro growth rate of both cell lines was modulated by the amount of testosterone in the medium. Both cell lines were able to synthesize a significant amount of RSV-IV protein under testosterone control.     

Isolation and characterization of gelatin-binding bison seminal vesicle secretory proteins

Bovine seminal plasma (BSP) contains a family of major proteins designated BSP-A1/A2, BSP-A3, and BSP-30kDa (collectively called BSP proteins) that bind to sperm at ejaculation and potentiate sperm capacitation. Homologous proteins have been identified in stallion, boar, goat, and ram seminal plasma. We report here the isolation and characterization of homologous proteins from bison seminal vesicle secretions. Seminal vesicle secretory proteins were precipitated by adding cold ethanol and recovered by centrifugation. The precipitates were resuspended in ammonium bicarbonate, dialyzed, and lyophilized. Lyophilized proteins were dissolved in 0.05 M phosphate buffer (PB) and loaded onto a gelatin-agarose column. The unadsorbed proteins and adsorbed proteins were eluted with PB and 5 M urea in PB, respectively. The gelatin-adsorbed fraction was analyzed by SDS-PAGE and revealed the presence of four major proteins designated BiSV-16kDa, BiSV-17kDa, BiSV-18kDa, and BiSV-28kDa (BiSV: bison seminal vesicle proteins). Heparin-Sepharose chromatography allowed the separation of BiSV-16kDa, which did not bind heparin from other BiSV proteins, which bound heparin. Immunoblotting revealed that BiSV-16kDa cross-reacted with BSP-A3 antibodies, BiSV-17kDa and BiSV-18kDa cross-reacted with BSP-A1/-A2 antibodies, and BiSV-28kDa cross-reacted with BSP-30kDa antibodies. Radioimmunoassays indicated that approximately 25% of bison seminal vesicle total proteins are related to BSP proteins. The amino-terminal sequencing indicated that BiSV proteins share almost 100% sequence identity with BSP proteins. In addition, BiSV proteins bind to low-density lipoproteins isolated from hen's egg yolk. These results confirm that BSP protein homologs are present in mammalian seminal plasma and they may share the same biological role.     

Androgens affect the processing of secretory protein precursors in the guinea pig seminal vesicle. II. Identification of conserved sites for protein processing

The guinea pig seminal vesicle epithelium is an androgen-dependent tissue that synthesizes and secretes four major secretory proteins (SVP-1, SVP-2, SVP-3, and SVP-4). Sequencing of near full-length cDNA clones corresponding to the two most abundant mRNAs produced by the seminal vesicle reveals that all four secretory proteins are cleaved from two secretory protein precursors. Amino acid sequences from purified SVP-2 match the central region of the predicted amino acid sequences from the smaller cDNA clone, GP2 (581 nucleotides). Similar analysis demonstrates that the predicted amino acid sequence from the longer cDNA clone, GP1 (1368 nucleotides), codes for the related proteins SVP-3 and SVP-4 as well as SVP-1. The 43.2 kilodalton polyprotein precursor coded by GP1 contains two different sets of 24 amino acid tandemly repeated sequences. The two secretory protein precursors have extensive regions of peptide sequence homology, particularly in regions where protein processing must occur to produce the mature secretory proteins. Analysis of the predicted secondary structure of the two precursor polypeptides revealed a strong correlation between structural features and sites of protein processing.     

Heterogenous turnover of sperm and seminal vesicle proteins in the mouse revealed by dynamic metabolic labeling

Plasticity in ejaculate composition is predicted as an adaptive response to the evolutionary selective pressure of sperm competition. However, to respond rapidly to local competitive conditions requires dynamic modulation in the production of functionally relevant ejaculate proteins. Here we combine metabolic labeling of proteins with proteomics to explore the opportunity for such modulation within mammalian ejaculates. We assessed the rate at which proteins are synthesized and incorporated in the seminal vesicles of male house mice (Mus musculus domesticus), where major seminal fluid proteins with potential roles in sperm competition are produced. We compared rates of protein turnover in the seminal vesicle with those during spermatogenesis, the timing of which is well known in mice. The subjects were fed a diet containing deuterated valine ([(2)H(8)]valine) for up to 35 days, and the incorporation of dietary-labeled amino acid into seminal vesicle- or sperm-specific proteins was assessed by liquid chromatography-mass spectrometry of samples recovered from the seminal vesicle lumen and cauda epididymis, respectively. Analyses of epididymal contents were consistent with the known duration of spermatogenesis and sperm maturation in this species and in addition revealed evidence for a subset of epididymal proteins subject to rapid turnover. For seminal vesicle proteins, incorporation of the stable isotope was evident from day 2 of labeling, reaching a plateau of labeling by day 24. Hence, even in the absence of copulation, the seminal vesicle proteins and certain epididymal proteins demonstrate considerable turnover, a response that is consonant with the capacity to rapidly modulate protein production. These techniques can now be used to assess the extent of phenotypic plasticity in mammalian ejaculate production and allocation according to social and environmental cues of sperm competition.     

Interaction of proteins RSV IV and RSV V in rat seminal vesicle secretion

The RSV IV polypeptide, molecular weight ratio (Mr = 10,000), which is produced by the rat seminal vesicle, has previously been suggested to be associated with another polypeptide in the gland secretion (Higgins et al., '76). This study provides that RSV IV is a component of a protein shown by immunoassays, electrophoresis, and amino acid composition analysis to contain, together with RSV IV, the seminal vesicle secretory RSV V polypeptide (Mr = 13,000). This RSV IV-RSV V complex (namely CFS protein) had an isoelectric point at pH 7.2 and an approximate molecular weight of 22,000 daltons. This complex inhibits the previously reported in vitro binding of the isolated RSV IV to epididymal sperm cells, thus suggesting a functional role for the RSV IV-RSV V interaction.     

The major basic proteins of bull seminal vesicle secretion

We have employed HPLC on reversed phase columns to analyse the major basic proteins from bull seminal vesicle secretion. The identification of proteins was achieved by comparison with authentic protein samples from bull seminal plasma as well as immunological characterisation using antisera directed against the latter proteins. The major basic proteins from bull seminal plasma: bull seminal proteinase inhibitor II (BUSI II), the seminal ribonuclease BS1, the protein P6 as well as the antimicrobial protein were also identified as the main constituents of the fraction of basic proteins derived from seminal vesicle secretion. FPLC using Mono S HR columns was also found to resolve the mixture of basic proteins and proved to be especially useful with respect to the isolation of the antimicrobial protein from basic proteins of seminal vesicle secretion. The identity of the antimicrobial protein from bull seminal plasma with the respective protein from seminal vesicle secretion was confirmed by amino-acid analysis and comparison of tryptic peptide patterns by HPLC. The antimicrobial protein was isolated from seminal vesicle secretion with a yield of 3 mg/ml of secretion.     

Purification and structure of caltrin-like proteins from seminal vesicle of the guinea pig

Two different small proteins that cross-react with the antiserum against bovine caltrin (calcium transport inhibitor) have been purified from the seminal vesicle contents of the guinea pig. The primary structure and some molecular characteristics of the pure proteins are reported. The two proteins interact with concanavalin A indicating the presence of carbohydrates in their molecules. Chemical deglycosylation with trifluoromethanesulfonic acid, after reduction and carboxymethylation, results in complete loss of affinity for the lectin. Removal of sugar components from the structure destroys the ability of caltrin-like proteins to react with antibodies to bovine caltrin. The protein moving faster on polyacrylamide gel electrophoresis is designated guinea pig caltrin I, the other is II. They contain 45 and 55 amino acids, and the molecular weights of the peptide portions are 5082 and 6255, respectively. Although they have entirely different amino acid sequences, they share some common features: recognition by rabbit antibodies to bovine caltrin, the predominance of basic residues and the presence of 3 cysteine residues in fraction I and 8 in fraction II. The proteins have pI values of 9.5 and 10.2, respectively, which are consistent with the amino acid composition. The two pure fractions are approximately equally effective, on a weight basis, as inhibitors of 45Ca2+ uptake by guinea pig spermatozoa. The data presented reinforce the hypothesis that caltrin-like proteins are responsible for the previously reported (Coronel, C.E., San Agustin, J., and Lardy, H.A. (1988) Biol. Reprod. 38, 713-722), calcium-transport inhibitor activity detected in reproductive tract fluid from adult male guinea pigs.     

Ascaris suum: Free amino acids and proteins in the pseudocoelom,seminal vesicle and glandular vas deferens

The free amino acids and proteins of the seminal vesicle and pseudocoelomic fluids in the male Ascaris suum were examined and compared. The seminal fluid contained a high concentration of lysine (lysine: glutamic acid ratio of 5:1) while the pseudocoelomic fluid contained more glutamic acid than lysine with alanine, serine, glycine and proline being the most abundant free amino acids. The proteins present in the seminal fluid differed from those in the pseudocoelomic fluid in both number and molecular weight. The sperm activating substance (SAS) present in homogenates of the glandular vas deferens of male worms is nondialyzable, heat-sensitive and can be precipitated using 45% saturated ammonium sulfate. Active moieties can be recovered following passage of the ammonium sulfate precipitates through ultrafiltration membranes or by applying gland homogenates to an ion exchange column. When subjected to SDS-polyacrylamide gel electrophoresis, the active fractions revealed both low and high molecular weight substances. During attempts to purify a single activating substance, it was noted that the more heterogeneous fractions contained the highest activating capacity. Thus, no precise relationship between the biological activity and the purity of the various fractions was determined.     

The major protein of bull seminal plasma: Biosynthesis and biological function

We isolated the major protein of apparent M_r of 15,000–16,000 from seminal plasma as well as from seminal veiscle secretion of bull and proved by amino acid analysis and tryptic peptide mapping that the two proteins were identical. An antiserum against this major protein was employed to quantitate and identify the major protein in seminal plasma as well as seminal vesicle secretion. The antiserum did not cross-react with proteins from bovine or human plasma or follicular fluid respectively.Cell-free translation of poly(A)RNA from seminal vesicle tissue and immunoprecipitation yielded one major species with apparent M_r of 18,000. Using the anti-major protein antiserum, this major species was specifically immuno absorbed. Cloning and sequencing of a major protein-specific cDNA led to the identification of clone pMP17, encoding a precursor of the major protein of 128 amino acid residues. We proved that the major protein is identical to protein PDC 109 (Eschet al., Biochem. Biophys. Res. Comm. 113:861–867, 1983).The seminal vesicles synthesize major protein in an androgen-dependent fashion. In addition to intraluminal secretion of the vas deferens, ampullary spermatozoa revealed an intense immunoreaction which was restricted to the neck region of the sperm head and the middle piece, while the principal piece of the tail as well as the sperm head were devoid of immunoreactive material. Epididymal epithelium (as well as calf seminal vesicle epithelium) showed no immunoreactivity with major protein antiserum. Immunoelectron microscopy demonstrated that only spermatozoa devoid of a plasma membrane around the middle piece were able to bind the antiserum against major protein. After removal of the plasma membrane from epididymal spermatozoa, binding of major protein to subplasmalemmal binding sites was visualised using gold-labeled MP.Transblotting with gold-labeled MP demonstrated a protein of about 66 kDa which appears to represent the major protein-receptor. Binding of major protein to the receptor (after loss of the plasma membrane in the mid-piece region of the spermatozoa after contact with secretions from seminal vesicles) is interpreted as a phyisological process presumably related to the onset of sperm motility.     

Studies on proteins of animal ribosomes

Summary Total ribosomal protein from rat liver ribosomes can be separated into about 20 chief electrophoretic fractions by preparative polyacrylamide gel electrophoresis. Ten electrophoretically homogeneous fractions have been isolated from the total mixture of ribosomal protein, respectively from proteins, prefractionated by CM-cellulose chromatography. Amino acid composition and molecular weights of some fractions have been determined. The amino acid composition of these fractions and of the total protein mixture are basically similar but there are also significant differences with regard to some amino acids. The molecular weights of the proteins studied are in the range between 7,000 and 29,000.     

Isolation and characterization of histones and other acid-soluble chromosomal proteins from Physarum polycephalum

Chromosomal basic proteins were isolated from amoebal and plasmodial stages of the acellular slime mold Physarum polycephalum. Polyacrylamide electrophoresis on high resolution acid-urea gels separated the five histone fractions in the sequence H1, H2A, H2B, H3, and H4. Under these electrophoretic conditions Physarum histones migrated more like plant (rye) than animal (calf) histones. Furthermore, Physarum histones H1, H2A, and H2B have higher molecular weights on sodium dodecyl sulfate (SDS) gels than the corresponding calf fractions. No differences were detected between amoebal and plasmodial histones on either acid-urea or SDS-polyacrylamide gel electrophoresis. Amoebal basic proteins were fractionated by exclusion chromatography. The five histone fractions plus another major acid-soluble chromosomal protein (AS) were isolated. The Physarum core histones had amino acid compositions more closely resembling those of the calf core histones than of rye, yeast, or Dictyostelium. Although generally similar in composition to the plant and animal H1 histones, the Physarum H1 had a lower lysine content. The AS protein was extracted with 5% perchloric acid or 0.5 M NaCl, migrated between histones H3 and H4 on acid-urea polyacrylamide gels, and had an apparent molecular weight of 15 900 on SDS gels. It may be related to a protein migrating near H1. Both somewhat resembled the high mobility group proteins in amino acid composition.     

Gene expression and cDNA cloning identified a major basic protein constituent of bovine seminal plasma as bovine monocyte-chemoattractant protein-1 (MCP-1).

P6 is one of the major basic proteins of bovine seminal plasma. Using cell-free translation of poly(A)+RNA from bovine seminal vesicle tissue and monospecific anti-P6-IgGs, we show that P6 is a secretory product of the seminal vesicles. Immunohistochemical experiments supported this finding. Immunoscreening of a lambda gt11 cDNA library derived from seminal vesicle poly(A)+RNA furnished a number of positive cDNA clones, from which clone pH42 was characterized by sequencing. The partial amino acid sequence of a CNBr-fragment of P6 permitted identification of the reading frame of clone pH42 encoding the precursor protein of P6. The P6 precursor contains a signal peptide of 23 amino acids followed by the mature P6 sequence of 76 amino acid residues. The cDNA sequence of pH42 was 80% homologous with that of the human monocyte-chemoattractant protein-1 (hMCP-1). The respective amino acid sequences for the precursor molecules are 72% identical. Northern analysis of seminal vesicle poly(A)+RNA using pH42 as probe probe identified a 0.9-kb P6 mRNA. Stimulation of P6 mRNA expression by phytohemagglutinin in bovine peripheral mononuclear leukocytes suggests that P6 is identical to bovine MCP-1.     

The amphipathic membrane proteins associated with gangliosides: The Paul-Bunnell antigen is one of the gangliophilic proteins

Two amphipathic protein fractions soluble in organic solvents as well as in water have been isolated from the ganglioside fraction of bovine erythrocyte membranes by successive chromatography in chloroform-methanol mixture on DEAE-Sephadex, silicic acid, and α-hydroxypropylated Sephadex G50 (LH60) columns. These two fractions contained a similar low molecular weight protein but with distinctively different amino acid composition. One of these proteins has been characterized by having a strong Paul-Bunnell antigen activity and had a binding affinity to ganglioside. A similar protein without Paul-Bunnell antigen activity was isolated as the major ganglioside-associated protein.     

Androgens affect the processing of secretory protein precursors in the guinea pig seminal vesicle. I. Evidence for androgen-regulated proteolytic processing

The guinea pig seminal vesicle epithelium synthesizes and secretes four major secretory proteins (SVP-1-4). Previous work has established that these four proteins are cleaved from two primary translation products in a complex series of protein processing reactions. The present studies suggest that these protein processing reactions are regulated by androgens. In vitro labeling of seminal vesicle proteins revealed significant differences in the patterns of secretory protein intermediates produced by tissue from intact and castrated animals. Seminal vesicle tissue explants from castrated animals secreted a subset of the processing intermediates secreted by tissue from intact animals. The changes in the patterns of secretory protein intermediates became more pronounced with increasing time after castration, and were fully reversible by treatment of castrated animals with testosterone, suggesting that androgens were affecting the processing or secretion of secretory protein precursors. Amino-terminal protein sequencing of secretory protein processing intermediates that accumulate in the seminal vesicle lumen after castration suggests that the guinea pig seminal vesicle contains an androgen-regulated proteolytic processing activity.     

Processing of two protein precursors yields four mature guinea pig seminal vesicle secretory proteins

The translation of the two most abundant guinea pig seminal vesicle epithelium mRNAs (1800 nucleotides and 950 nucleotides) and the subsequent processing of their protein products were studied in an effort to elucidate the mechanism by which the four mature guinea pig seminal vesicle epithelium (GPSVE) secretory proteins are produced. The primary translation products of the 1800 nt and 950 nt mRNAs are two secretory protein precursors of 45 kDa and 20 kDa, respectively. Removal of signal peptides from these two precursors produces proteins of 43 kDa and 18.5 kDa, which are recognized by polyclonal antisera directed against the four mature secretory proteins. The existence of further processing intermediates in the production of the secretory proteins is suggested by the appearance of other immunoreactive polypeptides following incubation of GPSVE in nutrient medium containing [3H] leucine. Immunological and pulse-chase analysis strongly suggests that the 43-kDa protein gives rise to SVP-1, -3, and -4 and that SVP-2 is derived from the 18.5-kDa protein.     

Genetic variability and improvement of seed proteins in wheat

Summary Albumins, globulins, gliadins and glutenins presumably comprising 100 percent of the wheat seed proteins were sequentially extracted and electrophoresed on SDS-polyacrylamide gels. The SDS-electrophoretic patterns within each of the four fractions from T. boeotiaum, T. urartu, T. turgidum, T. timopheevii, T. aestivum, Ae. speltoides and Ae. squawosa were similar. They differed from one species to another only in a few minor components or density of certain components. Similarity in MW's of components, as indicated by the SDS-electrophoretic patterns, suggests that the wheats and Aegilops exhibit no variability for structural genes coding seed proteins. A minimum of 60 to 70 and a maximum of 360 to 420 structural genes with major or minor effects control the total seed protein in T. aestivum. Presumably, only one or the other homoeoallele was expressed in the polyploids. Different components of albumins and globulins presumably had distinct MW's and amino acid composition, while the components of gliadins and glutenins could be classified into a few groups each containing one or more components with the same MW and nearly identical amino acid composition. The genes for components with similar MW's and amino acid composition arose through multiplication of a single original gene and perhaps share the same regulatory mechanism. Seed protein content and quality in wheat might be improved through the incorporation of structural genes, coding for polypeptides with distinct MW's, from distantly related species, rather than by manipulation of the structural genes within the Triticum-Aegilops group. Regulatory mutants similar to opaque-2 of corn could be used to alter the proportion of gliadins in relation to albumins and globulins, to improve amino acid composition of wheat proteins.     

Comparison of soluble proteins in juice and wine from Koshu grapes

Proteins were separated from Koshu grape juice and wine by precipitation with ammonium sulfate. The protein fractions were further fractionated by gel electrophoresis and gel isoelectric focusing, followed by amino acid analyses. The juice contained more than eleven protein fractions with molecular weights between 13,000 and 65,000, and their isoelectric points were between 3.6 and 10.5. The wine also contained more than eleven protein fractions with molecular weights between 21,000 and 65,000, while their isoelectric points were between 3.6 and 11.0. All the juice proteins and some major wine proteins were glycoproteins. The same three protein fractions were present in both juice and wine. The other juice proteins were lost during wine-making and thus, were not detected in the wine. About half of the proteins detected in the wine were not observed in the juice. Some juice proteins were bound to the flavonoid phenolics extracted from the wine and were removed as insoluble precipitates. There was specific interaction between wine flavonoids and juice proteins.     

Characterization of basic proteins of bull seminal plasma

We have employed high-performance liquid chromatography on reversed phase columns to analyse the major basic proteins from bull seminal plasma. The proteins were separated preparatively and characterized with respect to molecular mass, amino-acid composition as well as by means of immunodiffusion against specific antisera. The following proteins could be identified: bull seminal proteinase inhibitor II (BUSI II), two seminal RNAases, the seminal antimicrobial protein and proteolytic fragments, derived from it, and a hitherto unknown protein P6 of molecular mass 20 000 Da. Another unknown protein, P5, found to be formed during preparation of the basic protein fraction turned out to be a proteolytic fragment of protein P6 with a molecular mass of 8 750 Da for the polypeptide chain. Antisera against the isolated proteins were raised in rabbits and their specificity established. Single radial immunodiffusion was used to determine the concentration of the above basic proteins in bull seminal plasma: BUSI II (0.25 mg/ml), seminal RNAases (6.5 mg/ml) and protein P6 (2.9 mg/ml).