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.     

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.     

Calcium-binding protein in bull seminal vesicle secretion and seminal plasma.

A protein which showed high affinity for calcium ions was isolated from bull seminal vesicle secretion and seminal plasma. Its calcium-binding activity depended on the ionic strength and pH of the medium. The dissociation constant was 7-7 X 10(-7) M and there were 14 binding sites per protein molecule. The molecular weight of calcium-binding protein from bull seminal vesicle secretion, estimated by the gel filtration method, was 110,000. The protein may be involved in the regulation of the calcium ion level in seminal plasma.     

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).     

Novel purification method for mammalian seminal plasma phospholipid-binding proteins reveals the presence of a novel member of this family of protein in stallion seminal fluid

A family of bull seminal plasma (BSP) phospholipid-binding proteins (BSP proteins), potentiate heparin- and HDL-induced capacitation. The homologous proteins have been purified from stallion and boar seminal plasma, and detected in low concentrations in other mammalian seminal plasma. In this study, we developed a new isolation method for mammalian seminal plasma choline phospholipid-binding proteins wherein they are present in low concentrations. The method is based on the interaction of this family of proteins with egg yolk low-density lipoprotein fraction (LDF). In order to demonstrate the feasibility of the method, we incubated LDF with alcohol precipitates of bull, boar, and stallion seminal plasma. LDF were re-isolated by ultracentrifugation along with bound proteins. LDF with associated proteins were dialyzed, lyophilized, and delipidated. BSP homologous proteins were finally purified by p-aminophenyl phosphorylcholine (PPC)-agarose and/or gelatin-agarose chromatographies, and analyzed by SDS-PAGE. With this new protocol, phospholipid-binding proteins of bull, boar, and stallion seminal plasma were recovered almost 100%. A new 12 kDa stallion seminal plasma protein of the same family was also isolated and partially sequenced. The radio-immunoassay (RIA) data showed that 10 mg of LDF can bind all BSP proteins present in 120 mg of alcohol precipitated BSP proteins. These results confirm the efficiency of the method and that the LDF step could be used for the isolation of all BSP proteins homologs from different mammalian species.     

beta-N-acetylglucosaminidase in the reproductive organs and seminal plasma of the bull

The highest specific activity of beta-N-acetylglucosaminidase (beta-NAG) was found in the different parts of the epididymis, where the activity seemed to be partly in secretory and partly in non-secretory, tissue-bound form. Epididymal spermatozoa also contained moderate beta-NAG activity. The beta-NAG was separated by chromatofocussing and anion exchange chromatography with HPLC into multiple forms with distinct pI values (8.0-4.0). The cauda epididymidis, ampulla and the seminal vesicles formed the major secretory sources of the high beta-NAG activity in bull seminal plasma. The major secretory forms of beta-NAG in caput and cauda epididymidis showed distinct elution profiles. In the fractionation with gel filtration on Sepharose 6B, the beta-NAG activities derived from bull testis and caput epididymidis had smaller molecular weights than did the secretory enzymes in seminal plasma, seminal vesicle secretion and cauda epididymidis. Maximum activity of all beta-NAG isoenzymes was observed at pH 5.0. They were almost totally inactivated at 60 degrees C and about 75-80% of the activity was lost at 55 degrees C. All the isoenzymes were strongly inhibited by thiol reagents but not with other metal ions and chelating agents. Histochemical studies showed a strong granular (lysosomal) reaction for beta-NAG in basal cells and basal parts of the principal cells in all but the initial segment of the epididymis. An apical (secretory) reaction was prominent in the distal caput and corpus as well as in distal cauda. After the distal caput the luminal sperm mass became increasingly mixed with a beta-NAG-positive material. The epithelial cells of the ampulla and seminal vesicle displayed a moderate apical (secretory) reaction.     

Isolation and characterization of a basic carboxypeptidase from human seminal plasma

A carboxypeptidase which cleaves the C-terminal arginine or lysine from peptides was purified by a two-step procedure; gel filtration on Sephacryl S-300 and affinity chromatography on arginine-Sepharose. The activity increased 280% after the first step, indicating the removal of an inhibitor from the crude starting material. The activity in the crude seminal plasma eluted from the Sephacryl S-300 column with an apparent Mr 98,000 and after purification with an Mr 67,000, indicating that it binds to another protein in the crude seminal plasma. When analyzed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, a single band at Mr 53,000 was seen which was converted to two smaller bands (Mr 32,000 and/or 26,000) after reduction. The seminal plasma carboxypeptidase has a neutral pH optimum, is inhibited by o-phenanthroline and by the inhibitor of carboxypeptidase B-type enzymes, 2-mercaptomethyl-3-guanidinoethylthiopropanoic acid, and can be activated by cobalt. The purified enzyme has a high specific activity (67.8 mumol/min/mg) with the ester substrate benzoyl (Bz)-Gly-argininic acid and readily cleaves Bz-Ala-Lys, Bz-Gly-Arg, and Bz-Gly-Lys. It also hydrolyzes biologically active peptides such as bradykinin (Km = 6 microM, kcat = 43 min-1), Arg6-Met5-enkephalin (Km = 103 microM, kcat = 438 min-1), and Lys6-Met5-enkephalin (Km = 848 microM, kcat = 449 min-1). The seminal plasma carboxypeptidase did not cross-react with antiserum to human plasma carboxypeptidase N; other properties distinguish it from the blood plasma enzyme as well as from pancreatic carboxypeptidase B and granular, acid carboxypeptidase H (enkephalin convertase). The carboxypeptidase could be involved in the control of fertility by activating or inactivating peptide hormones in the seminal plasma. In addition it could contribute to the degradation of basic proteins during semen liquefaction.     

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.     

Ion-exchange chromatography used to isolate a spermadhesin-related protein from domestic goat (Capra hircus) seminal plasma

Mammalian seminal plasma contains among others, proteins called spermadhesins, which are the major proteins of boar and stallion seminal plasma. These proteins appear to be involved in capacitation and sperm-egg interaction. Previously, we reported the presence of a protein related to spermadhesins in goat seminal plasma. In the present study, we have further characterized this protein, and we propose ion-exchange chromatography to isolate this seminal protein. Semen was obtained from four adult Saanen bucks. Seminal plasma was pooled, dialyzed against distilled water and freeze-dried. Lyophilized proteins were loaded onto an ion-exchange chromatography column. Dialyzed-lyophilized proteins from the main peak of DEAE-Sephacel were applied to a C2/C18 column coupled to an RP-HPLC system, and the eluted proteins were lyophilized for electrophoresis. The N-terminal was sequenced and amino acid sequence similarity was determined using CLUSTAL W. Additionally, proteins from DEAE-Sephacel chromatography step were dialyzed and submitted to a heparin-Sepharose high-performance liquid chromatography. Goat seminal plasma after ion-exchange chromatography yielded 6.47 +/- 0.63 mg (mean +/- SEM) of the major retained fraction. The protein was designated BSFP (buck seminal fluid protein). BSFP exhibited N-terminal sequence homology to boar, stallion and bull spermadhesins. BSFP showed no heparin-binding capabilities. These results together with our previous data indicate that goat seminal plasma contains a protein that is structurally related to proteins of the spermadhesin family. Finally, this protein can be efficiently isolated by ion-exchange and reverse-phase chromatography.     

Isolation and characterization of the major proteins of ram seminal plasma

Mammalian seminal plasma contains among others, two major families of proteins, namely spermadhesins and those proteins that contain fibronectin type II domains. Spermadhesins are the major proteins of boar and stallion seminal plasma and homologous proteins have been identified in the bull. These proteins appear to be involved in capacitation and sperm-egg interaction. In bovine seminal plasma, proteins containing fibronectin type II domains are the major proteins and are designated BSP proteins. These proteins play a role in sperm capacitation. In this study, we present the isolation and characterization of the major proteins of ram seminal plasma. Precipitated proteins from Suffolk ram seminal plasma were loaded onto a gelatin-Agarose column. The unadsorbed (fraction A) and retarded proteins (fraction B) were removed by washing the column with phosphate buffered-saline and the adsorbed proteins (fraction C) were eluted with 5 M urea. SDS-PAGE of fraction B indicated the presence of a 15.5 kDa protein, which is the major protein of ram seminal plasma (approximately 45% of total protein by weight) and was identified as a spermadhesin by N-terminal sequencing. SDS-PAGE analysis of fraction C revealed the presence of four proteins, which represented approximately 20% of total ram seminal plasma proteins by weight, and were identified as proteins of the BSP family and named RSP proteins. These RSP proteins were designated RSP-15 kDa, RSP-16 kDa, RSP-22 kDa, and RSP-24 kDa. Only RSP-15 kDa and -16 kDa proteins cross-reacted with antibodies against BSP proteins. Ram spermadhesin and RSP proteins interact with heparin but only RSP proteins bind to hen's egg yolk low-density lipoprotein. In conclusion, spermadhesin is the major protein of ram seminal plasma and other major proteins belong to the BSP protein family.     

Beta-galactosidase in the seminal plasma and reproductive organs of the bull

The distribution of beta-galactosidase activity was studied in different reproductive organs, seminal plasma and spermatozoa of the bull. The highest specific activity of beta-galactosidase was found in testis and in different parts of the epididymis, where the activity seemed to be partly in secretory (cauda secretion) and partly in non-secretory, bound form (caput to cauda epididymidis). Gel filtration on Sepharose 6B at pH 7.0 revealed two beta-galactosidase forms (GF-1, Mr approximately 500,000-600,000 and GF-2, Mr approximately 190,000-220,000) in reproductive organs and seminal plasma. The pH-optimum of both beta-galactosidase forms was about 3.75-4.75. Hg2+ and p-chloromercuribenzoate inhibited strongly these activities. Further, form GF-2 seemed to be slightly more sensitive to the thermal inactivation at 50-70 degrees C than form GF-1. In chromatofocusing beta-galactosidase activities in bull seminal plasma coeluted with those of the cauda epididymidis (pI-values 7.5-6.4). On the contrary, prostate, Cowper's gland, testis, ampulla and seminal vesicles had enzyme activities eluting at lower pI-values (6.3-4.2). Thus, the seminal plasma activity is mainly an indicator for the function of the epididymal cauda.     

Adsorption of seminal plasma proteins by boar spermatozoa

Seminal plasma protein adsorption by boar spermatozoa was examined using ejaculated sperm from vesiculectomized boars and seminal plasma from vasectomized boars. Sperm adsorbed 14 pg protein/sperm in 10 min. When seminal plasma proteins were radiolabeled, most of the adsorbed radiolabel was present in low M(r) proteins, particularly a 12700 M(r) protein. A 349300 M(r) seminal plasma protein was also readily adsorbed. Three radiolabeled seminal plasma proteins (307600, 165400 and 7400 M(r)) were not detected on the sperm; either they are not adsorbed by the sperm or the sperm were previously exposed to these proteins in other accessory sex gland fluids and had already adsorbed them. A 29100 M(r) sperm protein was also radiolabeled (4.9% of the adsorbed radiolabel), although there was no corresponding seminal plasma protein. Large quantities of seminal plasma protein (particularly low M(r) proteins) are adsorbed by sperm not previously exposed to seminal vesicle secretion. The functions of these proteins are yet to be determined.     

Binding of a major secretory protein from bull seminal vesicles to bovine spermatozoa

Summary The seminal vesicles synthesize in an androgen-dependent manner a neutral protein of 13.5 kDa molecular weight that makes up about 40% of their secretion (major protein). An antiserum against this protein raised in rabbits was used to localize the antigen within the seminal vesicles. In addition to intraluminal secretion of the seminal vesicles and the ampulla of the vas deferens, ejaculated and 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. Comparison of spermatozoa taken from the tail of the epididymis with ampullary spermatozoa showed that about 90% of the latter, but only 10–20% of the former presented this distributional pattern of immunoreactive sites. Epididymal epithelium as well as calf seminal vesicle epithelium showed no immunoreactivity with major protein antiserum. Using a pre-embedding staining technique with gold-labeled primary or secondary antibodies, respectively, no immunostaining could be achieved at the ultrastructural level. Incubation experiments of epididymal spermatozoa in EGTA-containing solutions in the absence of calcium resulted in a gradual labilization and eventual loss of the plasma membrane of the sperm middle piece. After removal of (at least part of) the plasma membrane, bound major protein could be visualized immunohistochemically close to the mitochondria of the middle piece using a gold-labeled primary or secondary antibody. The acceptor site for major protein therefore seems to reside inside the plasma membrane of the sperm middle piece. Incubation of epididymal spermatozoa in phospholipase-containing solutions removed the acceptor site from the spermatozoa. Separation by polyacrylamide treatment of proteins from epididymal sperm cells extracted by sodium hydroxide or phospholipase treatment, subsequently transblotted on nitrocellulose sheets and directly labeled with gold-tagged major protein, demonstrated a protein duplet with a molecular weight of 65 and 67 kDa, respectively, which appears to represent the specific binder of major protein underneath the sperm surface. Binding of major protein to this 66 kDa acceptor site is regarded as a physiological event that may be related to the onset of hyperactivated sperm motility.Dedicated to Professor Dr. Th.H. Schiebler on the occasion of his 65^th birthdayThis study was supported by the Deutsche Forschungsgemeinschaft (grant Au 48/7-8)     

Isolation and characterization of gelatin-binding proteins from goat seminal plasma

A family of proteins designated BSP-A1, BSP-A2, BSP-A3 and BSP-30 kDa (collectively called BSP proteins for Bovine Seminal Plasma proteins) constitute the major protein fraction in the bull seminal plasma. These proteins interact with choline phospholipids on the sperm surface and play a role in the membrane stabilization (decapacitation) and destabilization (capacitation) process. Homologous proteins have been isolated from boar and stallion seminal plasma. In the current study we report the isolation and preliminary characterization of homologous proteins from goat seminal plasma. Frozen semen (-80°C) was thawed and centrifuged to remove sperm. The proteins in the supernatant were precipitated by the addition of cold ethanol. The precipitates were dissolved in ammonium bicarbonate and lyophilised. The lyophilised proteins were dissolved in phosphate buffer and loaded onto a gelatin-agarose column, which was previously equilibrated with the same buffer. The column was successively washed with phosphate buffer, with phosphate buffer saline and with 0.5 M urea in phosphate buffer saline to remove unadsorbed proteins, and the adsorbed proteins were eluted with 5 M urea in phosphate buffer saline. Analysis of pooled, dialysed and lyophilised gelatin-agarose adsorbed protein fraction by SDS-PAGE indicated the presence of four protein bands that were designated GSP-14 kDa, GSP-15 kDa, GSP-20 kDa and GSP-22 kDa (GSP, Goat Seminal Plasma proteins). Heparin-affinity chromatography was then used for the separation of GSP-20 and -22 kDa from GSP-14 and -15 kDa. Finally, HPLC separation permitted further isolation of each one from the other. Amino acid sequence analysis of these proteins indicated that they are homologous to BSP proteins. In addition, these BSP homologs bind to hen's egg-yolk low-density lipoproteins. These results together with our previous data indicate that BSP family proteins are ubiquitous in mammalian seminal plasma, exist in several forms in each species and possibly play a common biological role.     

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.     

Characterization of a new bioactive protein from bovine seminal fluid

A new acidic seminal fluid protein (aSFP) was purified from bovine seminal fluid, using anion exchange chromatography and FPLC on MonoQ. The purified aSFP displays a pI of 4.8 and an apparent molecular weight of 14 kDa. Homogeneity of aSFP was demonstrated by FPLC and SDS-polyacrylamide gel electrophoresis. Monospecific anti-aSFP IgGs were employed to characterize aSFP in bovine seminal plasma and seminal vesicle secretion by immuno blot analysis. Proteinchemical characterization of aSFP included amino acid analysis as well as determination of 23 amino acid residues of the N-terminal sequence of aSFP. According to this sequence, aSFP appears to represent a hitherto unknown protein. aSFP stimulated cell division and progesterone secretion of bovine granulosa cells in vitro in a potent and dose dependent manner. aSFP appears to be a potent growth factor with effects on ovarian granulosa cells.     

The phospholipid-binding protein of the reproductive tract of the bull — Effect on the removal of spermatozoal cytoplasm droplets in other species and influence of antibodies on its reactivity

The phospholipid-binding protein (PBP) isolated from bull seminal vesicle fluid removed cytoplasm droplets not only from bull, but also from ram, boar and rabbit epididymal spermatozoa. However, the presence of a protein cross-reacting with anti-PBP antisera was demonstrated by immunofluorescent staining in ram seminal vesicles and ampullae. In contrast to PBP from bull, the ram PBP-like protein did not lyse bull or ram erythrocytes. Rabbit antiserum against PBP only negligibly reduced the ability of PBP to remove cytoplasm droplets from bull epididymal spermatozoa, but it inhibited the haemolytic effect of the protein.     

Transgelin: An androgen-dependent protein identified in the seminal vesicles of three Saharan rodents

During the breeding season, a major androgen-dependent protein with an apparent molecular weight of 21 kDa was isolated and purified from the seminal vesicles of three Saharan rodents (MLVSP21 from Meriones libycus, MSVSP21 from Meriones shawi, and MCVSP21 from Meriones crassus). The 21-kDa protein was isolated and purified from soluble seminal vesicle proteins of homogenate by one-dimensional polyacrylamide gel electrophoresis (SDS-PAGE). Using polyclonal antibodies directed against POSVP₂₁ (Psammomys obesus seminal vesicles protein of 21 kDa), a major androgen-dependent secretory protein from sand rat seminal vesicles, identified previously as transgelin, we showed an immunological homology with POSVP₂₁ by immunoblotting. These three major androgen-dependent proteins with a same apparent molecular weight of 21 kDa designated as MLVSP₂₁ (Meriones libycus seminal vesicles protein of 21 kDa), MSVSP₂₁ (Meriones shawi seminal vesicles protein of 21 kDa), and MCVSP₂₁ (Meriones crassus seminal vesicles protein of 21 kDa) were localized by immunohistochemistry and identified by applying a proteomic approach. Our results indicated that the isolated proteins MLSVP₂₁, MSSVP₂₁, and MCSVP₂₁ seem to correspond to the same protein: the transgelin. So that transgelin can be used as a specific marker of these rodent physiological reproduction mechanisms.