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).     

Cellular autophagocytosis in mouse seminal vesicle cells in vitro

Cellular autophagocytosis was observed in mouse seminal vesicle cells incubated in vitro up to 8 h in medium 199 or Krebs-Ringer bicarbonate buffer. During the first 2 h of incubation, early forms of autophagic vacuoles were seen in the cells, advanced forms containing degraded material began to cumulate later. After 6--8 h, early vacuoles occurred sparsely, while advanced forms were detected in a great number. During the first 2 h of incubation, we often observed smooth surfaced membrane pairs between the cisternae of rough surfaced endoplasmic reticulum resembling isolating membranes of autophagic vacuoles. They varied in size and shape from short, straight cisternae to long, curved ones, almost completely encircling areas of the cytoplasm. Based on these observations, we propose a tentative scheme of the formation of autophagic vacuoles, viz., the short, straight cisternae would represent the first stage in the development of an autophagic vacuole, while the curved sack-like forms are interpreted as successive steps leading to the complete sequestration of an area of the cytoplasm.     

Immunocytochemical localization of insulin-like immunoreactivity in mouse seminal vesicle

Insulin-like immunoreactivity was localized in tissue sections and cell cultures of mouse seminal vesicle using the indirect technique of immunocytochemistry. Seminal vesicles were cut into fragments, fixed in 2.5% glutaraldehyde, embedded in epoxy resin, sectioned at 1 micron, and transferred to glass slides. Epithelial cell cultures of seminal vesicle were grown on coverslips in Dulbecco's Minimal Essential Medium for 4-6 days and fixed in 2.5% glutaraldehyde. Sections (etched with sodium ethanolate) or coverslips were incubated in guinea pig antiporcine insulin antiserum, in antiserum immunoabsorbed with porcine insulin, or in normal guinea pig serum. For indirect immunocytochemistry, incubation with primary antiserum was followed by treatment with rabbit anti-guinea pig immunoglobulin (Ig) G conjugated to peroxidase, or with protein A and then rabbit peroxidase anti-peroxidase (PAP). Finally, treated samples were incubated in phenylenediamine-pyrocatechol-H2O2 substrate mixture for 6-8 min at room temperature. Specific immunoreactivity to insulin antisera was confined to the epithelium of the seminal vesicle in tissue sections. No staining occurred in subepithelial connective tissue. Specific immunoreactivity was also observed in the cytoplasm of cultured seminal vesicle epithelial cells.     

Elucidation of the protein composition of mouse seminal vesicle fluid

The seminal vesicles are male accessory sex glands that contribute the major portion of the seminal plasma in which mammalian spermatozoa are bathed during ejaculation. In addition to conveying sperm through the ejaculatory duct, seminal vesicle secretions support sperm survival after ejaculation, and influence the female reproductive tract to promote receptivity to pregnancy. Analysis of seminal vesicle fluid (SVF) composition by proteomics has proven challenging, due to its highly biased protein signature with a small subset of dominant proteins and the difficulty of solubilizing this viscous fluid. As such, publicly available proteomic datasets identify only 85 SVF proteins in total. To address this limitation, we report a new preparative methodology involving sequential solubilization of mouse SVF in guanidine hydrochloride, acetone precipitation, and analysis by label-free mass spectrometry. Using this strategy, we identified 126 SVF proteins, including 83 previously undetected in SVF. Members of the seminal vesicle secretory protein family were the most abundant, accounting for 79% of all peptide spectrum matches. Functional analysis identified inflammation and formation of the vaginal plug as the two most prominent biological processes. Other notable processes included modulation of sperm function and regulation of the female reproductive tract immune environment. Together, these findings provide a robust methodological framework for future SVF studies and identify novel proteins with potential to influence both male and female reproductive physiology.     

A seminal vesicle autoantigen of mouse is able to suppress sperm capacitation-related events stimulated by serum albumin

We studied the effect of a mouse seminal vesicle autoantigen (SVA) on BSA-stimulated functions of mouse sperm. Uncapacitated, capacitated, and acrosome-reacted stages of sperm were morphologically scored, and the cellular zinc content was examined cytologically in a modified Tyrode solution at 37 degrees C for 80 min. More than 85% of control cells remained uncapacitated. Addition of 0.3% SVA to the cell incubation did not affect the cell status. Approximately 65% of cells were capacitated in the incubation medium containing 0.3% BSA. Only 30% of the cells became capacitated after incubation with 0.3% BSA and 0.3% SVA together. The decapacitation effect by 0.3% SVA could be subdued by more than 3% BSA in the cell incubation. Whereas BSA did, SVA did not cause removal of Zn(2+) from sperm, but SVA could suppress the BSA effect. The tyrosine phosphorylated proteins in sperm were detected after incubation in a modified HEPES medium containing 0.3% BSA and/or 0.3% SVA at 37 degrees C for 90 min. Whereas BSA enhanced greatly, SVA did not cause phosphorylation of proteins in the range of M:(r) 40 000-120 000. The BSA-stimulated protein tyrosine phosphorylation could be suppressed by SVA in the cell incubation.     

Purification and characterization of a trypsin inhibitor from mouse seminal vesicle secretion

A Kazal-type trypsin inhibitor in mouse seminal vesicle secretion was purified to homogeneity via a series of purification steps including ammonium sulfate fractionation, affinity chromatography on a trypsin Affi-Gel 10 column, and HPLC on a reverse phase C4 column. It was shown to be a weak basic protein with an isoelectric point of 8.7 and to contain no carbohydrate. The protein had a specific activity of 184 U/mg protein in the inhibitory effect on the trypsin digestion of N-benzoyl-Pro-Phe-Arg-p-nitroanilide. Analysis of the kinetic data for the trypsin digestion of N-benzoyl-Phe-Val-Arg 7-amido-4-methylcoumarin revealed that the protein was a competitive inhibitor with an inhibitory constant (Ki) of 0.15 nM. The molecular mass of the protein was determined to be 7 kDa by both gel chromatography and electrophoresis. Results of direct amino acid determinations indicated that this protein corresponded to the reading frame of MP12 cDNA identified from mouse prostate. We found that cleavage only at the reactive site of this protein (Arg19-Ile20) resulted in its denaturation.     

Svp-3, a third polymorphic locus for mouse seminal vesicle proteins

The B10.AKM/Sn congenic strain displays a particular phenotype of mouse seminal vesicle proteins representing the third polymorphic locus of this system. The Svp-3 symbol was assigned to this locus with two codominant alleles, Svp-3a found in the B10.AKM/Sn strain and Svp-3b expressed by all the other strains so far tested. The Svp-3 locus appears tightly linked to Svp-1 on chromosome 2.     

Suppression effect of seminal vesicle autoantigen on platelet-activating factor-induced mouse sperm capacitation

Mammalian sperm gain the ability to fertilize an egg successfully by the capacitation process. An unregulated capacitation process causes sperm to undergo a spontaneous acrosome reaction (AR) and resulting in loss of their fertilization activity. Thus, functional sperm activation is tightly regulated by a capacitation and suppression (decapacitation) mechanism. Factors, such as platelet-activating factor (PAF) present in both sperm and the female genital tract, are able to stimulate sperm capacitation. Seminal plasma is thought to have the ability to suppress sperm capacitation; however, the regulatory mechanisms of seminal plasma protein on sperm capacitation are not well understood. Recently, we demonstrated that seminal vesicle autoantigen (SVA), a major seminal vesicle secretory protein, is able to suppress mouse sperm capacitation. To further study the suppression spectra of SVA on sperm capacitation, we investigated the effect of SVA on PAF-induced mouse sperm capacitation-related signals. Here, we demonstrate that SVA decreases the [Ca(2+)](i) to suppress the PAF's effects on [Ca(2+)](i), the cAMP level, protein tyrosine phosphorylation, and capacitation. The inhibition of PAF-induced protein tyrosine phosphorylation and capacitation by SVA can be reversed by cAMP agonists. Characterization of the interactions of SVA with PAF by TLC overlay and tryptophan fluorescence spectrum analyses indicates that SVA is capable of binding PAF with an apparent dissociation constant K(d) > 50 microM. Together with these results, we demonstrate that SVA deceases [Ca(2+)](i) and cross-talks with PAF-induced intracellular signals to regulate mouse sperm capacitation.     

The protein conformation and a zinc-binding domain of an autoantigen from mouse seminal vesicle.

The protein conformation of a mouse seminal vesicle autoantigen was studied by circular dichroism spectroscopy. At pH 7.4, the spectrum in the UV region appears as one negative band at 217 nm and one positive band at 200 nm. This together with the predicted secondary structures indicates no helices but a mixture of beta form, beta turn, and unordered form in the protein molecule. The conformation is stable even at pH 10.5 or 3.0. The spectrum in the near-UV region consists of fine structures that are disturbed in acidic or alkaline solution. The environments around Trp2 and Trp82 of this protein were studied by intrinsic fluorescence and solute quenching. They give an emission peak at 345 nm, and about 87% of them are accessible to quenching by acrylamide. Correlating the quenching effect of CsCl and Kl on the protein fluorescence to the charged groups along the polypeptide chain suggests the difference in the "local charge" around the two tryptophan residues. The presence of ZnCl2 in the protein solution effects no change in the circular dichroism but perturbs the fluorescence due to Trp82. Analysis of the fluorescence data suggests a Zn(2+)-binding site on the protein, which cannot coordinate with both Ca2+ and Mg2+. The association constant for the complex formation is 1.35 x 10(5) +/- 0.04 x 10(5) M-1 at pH 7.4.     

The androgen-dependent mouse seminal vesicle secretory protein IV: characterization and complementary deoxyribonucleic acid cloning

Seminal vesicle secretory protein IV of a mouse has been isolated, and the cDNA coding for its mRNA has been cloned and sequenced. The 556-nucleotides encode 16 amino acid signal peptides and 92 residues of mature protein. Considerable homology between mouse and rat SVS IV cDNA was found. In the leader peptide and 3'-noncoding region there is 92% and 85% homology, respectively. The other regional homologies are 86% for the first 12, 68.5% for the last 35, and 40% for the middle 44 amino acids. The expression of mouse SVS IV mRNA is under the control of androgen. Administration of testosterone to castrated mice resulted in induction of the mRNA level to 50% of the mature male in 96 h of hormone treatment. Secretion of the protein after testosterone injection follows a similar pattern.     

Fgfr1 and Fgfr2 have distinct differentiation- and proliferation-related roles in the developing mouse skull vault

Fibroblast growth factor receptors (FGFRs) play major roles in skeletogenesis, and activating mutations of the human FGFR1, FGFR2 and FGFR3 genes cause premature fusion of the skull bones (craniosynostosis). We have investigated the patterns of expression of Fgfr1, Fgfr2 and Fgfr3 in the fetal mouse head, with specific reference to their relationship to cell proliferation and differentiation in the frontal and parietal bones and in the coronal suture. Fgfr2 is expressed only in proliferating osteoprogenitor cells; the onset of differentiation is preceded by down-regulation of Fgfr2 and up-regulation of Fgfr1. Following up-regulation of the differentiation marker osteopontin, Fgfr1, osteonectin and alkaline phosphatase are down-regulated, suggesting that they are involved in the osteogenic differentiation process but not in maintaining the differentiated state. Fgfr3 is expressed in the cranial cartilage, including a plate of cartilage underlying the coronal suture, as well as in osteogenic cells, suggesting a dual role in skull development. Subcutaneous insertion of FGF2-soaked beads onto the coronal suture on E15 resulted in up-regulation of osteopontin and Fgfr1 in the sutural mesenchyme, down-regulation of Fgfr2, and inhibition of cell proliferation. This pattern was observed at 6 and 24 hours after bead insertion, corresponding to the timing and duration of FGF2 diffusion from the beads. We suggest (a) that a gradient of FGF ligand, from high levels in the differentiated region to low levels in the environment of the osteogenic stem cells, modulates differential expression of Fgfr1 and Fgfr2, and (b) that signalling through FGFR2 regulates stem cell proliferation whereas signalling through FGFR1 regulates osteogenic differentiation.     

The acrosomal vesicle of mouse sperm is a calcium store

Subsequent to binding to the zona pellucida, mammalian sperm undergo a regulated sequence of events that ultimately lead to acrosomal exocytosis. Like most regulated exocytotic processes, a rise in intracellular calcium is sufficient to trigger this event although the precise mechanism of how this is achieved is still unclear. Numerous studies on mouse sperm have indicated that a voltage-operated Ca2+ channel plays some immediate role following sperm binding to the zona pellucida glycoprotein ZP3. However, there is also evidence that the mammalian sperm acrosome contains a high density of IP3 receptors, suggesting that the exocytotic event involves the release of Ca2+ from the acrosome. The release of Ca2+ from the acrosome may directly trigger exocytosis or may activate store-operated Ca2+ channels in the plasma membrane. To test the hypothesis that the acrosome is an intracellular store we loaded mammalian sperm with the membrane permeant forms of three Ca2+-sensitive fluorescent indicator dyes: fura-2, indo-1, and Calcium Green-5N. Fluorescence microscopy revealed that the sperm were labeled in all intracellular compartments. When fura-2 labeled sperm were treated with 150 microM MnCl2 to quench all fluorescence in the cytosol, or when the sperm were labeled with the low affinity dye Calcium Green-5N, there was a large Ca2+ signal in the acrosome. Consistent with the acrosome serving as an intracellular Ca2+ reservoir, the addition of 20 microM thapsigargin, a potent inhibitor of the smooth endoplasmic reticular Ca2+-ATPase (SERCA), to populations of capacitated sperm resulted in nearly 100% acrosomal exocytosis within 60 min (tau1/2 approximately 10 min), in the absence of extracellular Ca2+. Additionally, treatment of sperm with 100 microM thimerosal, an IP3 receptor agonist, also resulted in acrosomal exocytosis. Taken together, these data suggest that the mouse sperm acrosome is a Ca2+ store that regulates its own exocytosis through an IP3 Ca2+ mobilization pathway.     

Signals of seminal vesicle autoantigen suppresses bovine serum albumin-induced capacitation in mouse sperm

Capacitation is the prerequisite process for sperm to gain the ability for successful fertilization. Unregulated capacitation will cause sperm to undergo a spontaneous acrosome reaction and then fail to fertilize an egg. Seminal plasma is thought to have the ability to suppress sperm capacitation. However, the mechanisms by which seminal proteins suppress capacitation have not been well understood. Recently, we demonstrated that a major seminal vesicle secretory protein, seminal vesicle autoantigen (SVA), is able to suppress bovine serum albumin (BSA)-induced mouse sperm capacitation. To further identify the mechanism of SVA action, we determine the molecular events associated with SVA suppression of BSA's activity. In this communication, we demonstrate that SVA suppresses the BSA-induced increase of intracellular calcium concentration ([Ca2+]i), intracellular pH (pH(i)), the cAMP level, PKA activity, protein tyrosine phosphorylation, and capacitation in mouse sperm. Besides, we also found that the suppression ability of SVA against BSA-induced protein tyrosine phosphorylation and capacitation could be reversed by dbcAMP (a cAMP agonist).     

Fine structure of the seminal vesicle epithelium of the mouse and golden hamster

The seminal vesicle epithelium of the mouse and golden hamster was examined by light microscopy and by transmission and scanning electron microscopy. By transmission electron microscopy, in the seminal vesicle epithelium of both animals secretory epithelial cells which consisted of mostly light and a few dark cells were observed. The epithelial cells possessed secretory granules which contained a densely stained core. The secretory granules in the mouse epithelium reacted weakly with periodic acid-Schiff (PAS) stain and were slightly stained with alcian blue (AB), and those in the golden hamster exhibited strongly positive reactions with PAS and AB. The nuclei in the mouse tissue were spherical or ovoid, and those in the golden hamster tissue had a few lobes. By scanning electron microscopy, the apical surfaces of most of the epithelial cells were commonly flat or domed, and those of some epithelial cells protruded into the lumen as apocrine-like processes, or possessed small and large orifices. Besides the epithelial cells, there were cells characterized by pseudopodium-like cytoplasmic projections, a few membranous structures, an irregular nucleus, and cytoplasm containing a few dense bodies, in the basal portions of the epithelial cells, or between the basal lamina and the epithelial cells. These cells of the two species were similar in their features.     

Effects of seminal vesicle fluid components on sperm motility in the house mouse

Fluid obtained by stripping dissected seminal vesicles was mixed with phosphate-buffered saline and the soluble proteins were separated by gel filtration on BioRad P150 into 4 fractions. Fractions were collected and concentrated using an Amicon ultrafiltration system using YM2 membranes with a molecular weight cut-off of 1000. Epididymal sperm suspensions were incubated in medium containing one of the 4 fractions or 1 mg BSA/ml, or no added protein. After incubation for 2 h the motility of the spermatozoa in each suspension was assessed by a videomicrographic procedure. Two aspects of motility, velocity and the shape of the swimming path, were monitored. The results indicate that the seminal vesicles produce at least three factors that influence sperm motility. Fraction 3 (Mr 12,000-24,000) was detrimental to motility; after incubation for 2 h almost all the spermatozoa were immotile. Fractions 2 (Mr 25,000-40,000) and 4 (Mr 7000-12,000) both influenced the shape of the swimming path: spermatozoa incubated in Fraction 2 had straighter trajectories while those incubated in Fraction 4 showed more progressive paths with less side-to-side movement of the head about the path. These effects of factors from the seminal vesicle fluid on sperm motility may influence the way in which the spermatozoa move in the female reproductive tract and could help to explain why removal of the seminal vesicles reduces fertility in the mouse.     

High and testosterone-dependent glucose 6-phosphatase activity in epithelium of mouse seminal vesicle

For study of the mechanism of seminal fructogenesis, glucose 6-phosphatase activity was examined cytochemically (a method modified from that of Wachstein and Meisel) and biochemically (the method of Leskes et al.) in seminal vesicles from normal, castrated, and castrated and testosterone-treated mice. The reaction product for the activity was localized in the endoplasmic reticulum and nuclear envelope of all cell types composing the seminal vesicle. In normal seminal vesicle, the reaction product was apparently more abundant in columnar and basal cells than in other cell types. Ten, 20, and 30 days after castration, the abundant amount of reaction product in columnar and basal cells decreased to the level in other cell types. In animals treated with testosterone after castration, however, the reaction product in columnar and basal cells remained abundant. If fructose 6-phosphate was added to the reaction medium in place of glucose 6-phosphate, the amount and pattern of deposition of the reaction product did not change. Changes in biochemical activity in castrated or castrated and testosterone-treated animals paralleled the cytochemical results. The results show that the high activity in columnar and basal cells is under the control of testosterone, and the role of this enzyme is probably to release fructose into the seminal fluid.