Changes in binding of a 27-kilodalton chimpanzee cauda epididymal protein glycoprotein component to chimpanzee sperm

Motility patterns of caput epididymal chimpanzee sperm, caput epididymal chimpanzee sperm incubated in vitro with chimpanzee cauda epididymal fluid, and cauda epididymal chimpanzee sperm were assessed quantitatively. Sperm recovered from the caput epididymis showed no motility, whereas sperm recovered from cauda epididymis showed progressive forward motility. After incubation in cauda fluid, approximately 25% of caput epididymal sperm showed some motile activity. Electrophoretic analysis of ¹²⁵I-labeled sperm plasma membrane preparations revealed that the surface of caput epididymal sperm, incubated in cauda fluid, was modified by the appearance of a major protein-glycoprotein surface component with an apparent molecular weight of 27 kilodaltons (kD). THis 27-kD component was not detected on caput epididymal sperm incubated in buffer or in caput fluid. However, it was present in cauda fluid and on cauda epididymal sperm. Binding to caput epididymal sperm was cell specific in that chimpanzee erythrocytes incubated in cauda fluid did not bind this 27-kD cauda fluid component. Motility patterns of ejaculated chimpanzee sperm and of ejaculated chimpanzee sperm incubated in the uterus of adult female chimpanzees also were assessed quantitatively. Ejaculated sperm showed progressive forward motility, whereas in utero incubated ejaculated sperm showed hyperactivated motility typical of capacitated sperm. Electrophoretic analysis of ¹²⁵I-labeled sperm plasma membrane preparations revealed the loss of a 27-kD component from the surface of ejaculated sperm after in utero incubation. No significant change in the ¹²⁵I-distribution pattern was detectable when ejaculated sperm were incubated in buffer. These results suggest that the lumenal fluid component, which becomes adsorbed to the surface of chimpanzee sperm during maturation in the epididymis and which is removed from the surface of mature chimpanzee sperm in the female reproductive tract, affects sperm motility.     

Expression and activity of gamma-glutamyl transpeptidase in the rat epididymis.

Following Northern analysis, GGT mRNA was found predominantly within the caput epididymides and kidney. The size of mRNAs for kidney, caput, corpus, and ductus deferens were 2.2, 2.3, 2.2, and 2.3 kb, respectively, whereas cauda showed a doublet of 2.2 and 2.3 kb. GGT transpeptidation and hydrolytic activity within epididymal luminal fluids collected by micropuncture showed caput = corpus greater than cauda and corpus greater than caput greater than cauda, respectively. Caput luminal GGT transpeptidation activity was significantly inhibited by serine-borate and was optimal at pH 8.0. The calculated Km and Vmax values for hydrolysis of GSH by caput luminal GGT were 0.06 microM and 2.19 nmoles/min/microliters luminal fluid at pH 8.5 compared to 0.49 microM and 0.49 nmoles/min/microliters luminal fluid, respectively, at the physiological pH 6.5 of caput fluid. These studies would suggest that the epididymis can control the activity of luminal GGT by pH. Lower Km (0.12 microM) and higher Vmax (1.13 nmoles/min/microliters luminal fluid) values were also calculated when GSSG was used compared to GSH. Results from Triton X-114 partitioning experiments suggest that luminal GGT probably exists in both membrane bound and nonmembrane bound forms. Western blot analysis of proteins within epididymal luminal fluids revealed both subunits of GGT in all epididymal regions studied. However, two lower molecular bands, approximately 22 kDa and 21 kDa, were also observed in cauda fluid. It is suggested that as GGT is transported along the epididymal duct it undergoes degradation, which accounts for its loss of activity in the distal epididymal regions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Epididymal lipocalin-type prostaglandin D2 synthase: identification using mass spectrometry, messenger RNA localization, and immunodetection in mouse, rat, hamster, and monkey.

This study identified prostaglandin D2 synthase (PGDS) in murine epididymal fluid using a proteomic approach combining two-dimensional (2D) gel electrophoresis and mass spectrometry (MS). The caudal epididymal fluid was collected by retroperfusion, and proteins were separated by 2D gel electrophoresis followed by matrix-assisted laser desorption ionization MS analyses after trypsin digestion. The identification was based on the protein-specific peptide map as well as on sequence information generated by nano-electrospray ionization MS/MS. By in situ hybridization, the mRNA was detected in caput, corpus, and cauda, but it was not detected in the initial segment. The PGDS protein was mostly detected in the corpus and cauda by Western blot analysis and immunohistochemistry using a specific polyclonal antibody. In caudal fluid, PGDS was distributed among several isoforms (pI range, 6.5-8.8), suggesting that this protein undergoes posttranslational modification of its primary sequence. After N-glycanase digestion, the molecular mass decreased from 20-25 to 18.5 kDa, its theoretical mass. The PGDS was also detected in the epididymis of rat, hamster, and cynomolgus monkey from the caput to the cauda. In conclusion, MS is a powerful and accurate technique that allows unambiguous identification of the murine epididymal PGDS. The protein is 1) present throughout the epididymis, except in the initial segment, with an increasing luminal concentration from distal caput to cauda; 2) a major protein in caudal fluid; 3) an N-glycosylated, highly polymorphic protein; and 4) conserved during evolution.     

Surface changes in chimpanzee sperm during epididymal transit

Intact chimpanzee caput and cauda epididymal sperm, sperm cell lysates, and caput and cauda epididymal fluid were radiolabeled by enzymatic iodination with lactoperoxidase and Na125 I and were compared by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. Caput epididymal sperm showed nine labeled macromolecular components of 90, 64, 56, 48, 38, 31, 20, 18 and 16 Kd and cauda epididymal sperm showed eleven macromolecular components of 90, 64, 55, 47, 42, 33, 27, 18, 17, 15 and 11 Kd. Six of the components labeled on caput sperm (90, 64, 56, 48, 18 and 16 Kd) were detected in equal amounts of cauda sperm and two (38 and 20 Kd) were detected at greatly reduced labeling intensities. In the cauda epididymidis, four new components (33, 27, 17 and 11 Kd) became prominent features of the sperm surface. Analysis of labeled caput and cauda sperm cell lysates resolved components distinct from those detected on sperm surfaces. Electrophoresis of caput epididymal fluid showed five labeled components of 66, 56, 47, 41 and 37 Kd, while electrophoresis of cauda epididymal fluid showed eight labeled components of 92, 66, 56, 48, 31, 27, 24 and 11 Kd. Three components (66, 56 and 47 Kd) were present in both caput and cauda fluid, two (41 and 37 Kd) in caput fluid only, and five (92, 31, 27, 24 and 11 Kd) in cauda fluid only. Components of 37 Kd were labeled in caput fluid and on caput sperm but not on cauda sperm, whereas components of 27 Kd and 11 Kd were labeled in cauda fluid and on cauda sperm but not on caput sperm. These data show that chimpanzee sperm undergo extensive surface modifications during epididymal maturation and that some of these modifications may be related to exogenous proteins/glycoproteins in epididymal fluids.     

The effects of shRNA-mediated gene silencing of transcription factor SNAI1 on the biological phenotypes of breast cancer cell line MCF-7

Developing spermatozoa require a series of posttesticular modifications within the luminal environment of the epididymis to achieve maturation; this involves several surface modifications including changes in plasma membrane lipids, proteins, carbohydrates, and alterations in the outer acrosomal membrane. Epididymal maturation can therefore allow sperm to gain forward motility and fertilization capabilities. The objective of this study was to identify maturation-dependent protein(s) and to investigate their role with the production of functionally competent spermatozoa. Lectin blot analyses of caput and cauda sperm plasma membrane fractions identified a 17.5 kDa wheat germ agglutinin (WGA)-binding polypeptide present in the cauda sperm plasma membrane not in the caput sperm plasma membrane. Among the several WGA-stained bands, the presence of a 17.5 kDa WGA-binding polypeptide band was detected only in cauda epididymal fluid not in caput epididymal fluid suggesting that the 17.5 kDa WGA-binding polypeptide is secreted from the cauda epididymis and binds to the cauda sperm plasma membrane during epididymal transit. Proteomic identification of the 17.5 kDa polypeptide yielded 13 peptides that matched the sequence of peroxiredoxin-5 (PRDX5) protein (Bos Taurus). We propose that bovine cauda sperm PRDX5 acts as an antioxidant enzyme in the epididymal environment, which is crucial in protecting the viable sperm population against the damage caused by endogeneous or exogeneous peroxide.     

A 105- to 94-kilodalton protein in the epididymal fluids of domestic mammals is angiotensin I-converting enzyme (ACE); evidence that sperm are the source of this ACE

SDS-PAGE analysis of luminal fluid from the ram testis and epididymis revealed a protein of about 105 kDa in the fluid in the caput epididymal region. The molecular mass of this fluid protein shifted from 105 kDa to 94 kDa in the distal caput epididymidis and remained at 94 kDa in the lower regions of the epididymis. The possible sperm origin of this protein was suggested by the decrease in intensity of a 105-kDa compound on the sperm plasma membrane extract and by its total disappearance from the fluid of animals with impaired sperm production caused by scrotal heating. The 94-kDa protein was purified from ram cauda epididymal fluid, and a rabbit polyclonal antiserum was obtained. This antiserum showed that membranes of testicular sperm and sperm from the initial caput were positive for the presence of an immunologically related antigen. The protein was immunolocalized mainly on the flagellar intermediate piece, whereas in some corpus and caudal sperm, only the apical ridge of the acrosomal vesicle was labeled. The purified protein was microsequenced: its N-terminal was not found in the sequence database, but its tryptic fragments matched the sequence of the angiotensin I-converting enzyme (ACE). Indeed, the purified 94-kDa protein exhibited a carboxypeptidase activity inhibited by specific blockers of ACE. All the soluble seminal plasma ACE activity in the ram was attributable to the 94-kDa epididymal fluid ACE. The polyclonal antiserum also showed that a soluble form of ACE appeared specifically in the caput epididymal fluid of the boar, stallion, and bull. This soluble form was responsible for all the ACE activity observed in the fluid from the distal caput to the cauda epididymidis in these species. Our results strongly suggest that the epididymal fluid ACE derives from the germinal form of ACE that is liberated from the testicular sperm in a specific epididymal area.     

Alterations in primate sperm motility with maturation and during exposure to theophylline

Micropuncture was used to collect pure suspensions of sperm from the caput and cauda regions of chimpanzee epididymides, which were analyzed with a Motion Analysis VP-110. Sperm recovered from the caput region showed no forward motility. Incubation of these sperm with cauda epididymal fluid affected motility in 62%–90% of the sperm. Dilution of cauda sperm into buffer containing >50 mM theophylline resulted in immediate initiation of progressive forward motility. Although this motility was maintained by at least 50% of the sperm for over 5 hr, these “activated” caput sperm did not penetrate zona-free hamster ova. These data show that sperm from the caput epididymis of the chimpanzee have the capacity for normal motility but do not have the capacity to bind to and penetrate an ovum. Cauda epididymal chimpanzee sperm were motile at the time of recovery and this motility was maintained for over 5 hr. These sperm penetrated both hamster zona-free ova and intact chimpanzee ova. These data show that sperm from the cauda epididymis of the chimpanzee have the capacity for normal motility and also have the capacity to bind to and penetrate an ovum. This is the first use of computer assisted analysis to quantify motility in maturing nonhuman primate sperm.     

ATP-induced reactivation of ram testicular, cauda epididymal, and ejaculated spermatozoa extracted with Triton X-100

It was possible to demembrante and reactivate not only freshly collected testicular, cauda epididymal, and ejaculated ram sperm but also sperm that had been stored for several days at 0 degrees C and for several months at -196 degrees C in rete testis fluid or egg yolk citrate media. Sperm were usually washed free of seminal plasma before demembranation, but this was not essential for reactivation. Bovine serum albumin (1.0%) in the wash medium increased the survival of sperm, but more than 0.25% in the extraction medium decreased reactivation. A macro-molecular component of cauda epididymal fluid also inhibited the reactivation of testicular sperm. Triton X-100 concentrations between 0.01% and 1.00% in the extraction medium were satisfactory for demembranating the sperm. Rapid cooling (i.e., cold shock) mimicked the effect of detergent in making the sperm responsive to added ATP and demonstrated that damage to ram sperm in cold shock does not involve the axoneme. Ejaculated and cauda sperm were reactivated immediately on addition of ATP and activity persisted for up to 10 min. Testicular sperm, on the other hand, required about 4 min to become fully reactivated. The optimal ATP concentration for activation of sperm was 0.1-1.0 mM. Magnesium ions (0.1-1.0 mM) were important for reactivation, and testicular sperm required a higher magnesium concentration than did cauda or ejaculated sperm. Manganese ions were almost as effective as magnesium for reactivating cauda epididymal and ejaculated sperm. Cobalt and cadmium ions were much less active for cauda and ejaculated sperm and none of these ions were effective for testicular sperm. Fluoride (25-50 mM) inhibited reactivation. The presence of 50 microM cAMP in the extraction medium or preincubation of testicular sperm with theophylline or caffeine increased low levels of activation, but this was not evident with ejaculated or cauda sperm. We conclude that the motor apparatus is already functionally assembled in spermatozoa on leaving the testis, but some fine adjustment must take place during maturation in the epididymis.     

Direct evidence for the secretion of lactoferrin and its binding to sperm in the porcine epididymis

Lactoferrin has been for the first time purified from the porcine cauda epididymal fluid as a 70 kDa protein. Both Western and Northern blot analyses show that lactoferrin is synthesized in the regions from the distal caput to the cauda epididymis and secreted into the luminal fluid. Lactoferrin is first secreted as a 75 kDa glycoprotein and its carbohydrate moieties are gradually digested to form 70 kDa protein in the cauda epididymis. Lactoferrin has already bound to the surface of the epididymal sperm because the anti-lactoferrin antiserum induces the mature sperm tail-to-tail agglutination. These results strongly suggest new physiological functions of lactoferrin on the sperm maturation in the epididymis. Mol. Reprod. Dev. 47:490–496, 1997. © 1997 Wiley-Liss, Inc.     

Lectin binding sites on the plasma membrane of epididymal and ejaculated chimpanzee sperm

Lectins have been used to analyze variations in the distribution and density of exposed saccharides of the sperm plasma membrane during physiologic maturation and after ejaculation. Studies have been conducted in a number of nonprimate species but have been conducted to only a limited extent in nonhuman primates. In this study, pure suspensions of chimpanzee sperm from the caput and cauda epididymis and from the ejaculate were labeled with lectins conjugated to fluorescein isothiocyanate in order to visualize changes in the distribution of exposed membrane glycocomponents. The lectins used were Con A, DBA, RCA-I, and WGA. Con A binding showed minimal change during epididymal transit, with an increased binding to the flagellum after ejaculation. DBA binding was relatively constant in all specimens. RCA-I showed distinct changes in binding pattern between epididymal and ejaculated sperm. On ejaculated sperm strong fluorescence was limited to the posterior head and to the midpiece. WGA binding increased during epididymal passage and decreased after ejaculation. There appears to be a wide variety of saccharide groups available for lectin binding on the surface of epididymal and ejaculated chimpanzee sperm. The general similarity in binding patterns of caput and cauda epididymal chimpanzee sperm exposed to Con A and DBA might reflect the fact that sperm morphology does not change during epididymal transit in this species, thus implying a more stable membrane structure than is present in other primates so far studied.     

The concentration of carnitine in the luminal fluid of the testis and epididymis of the rat and some other mammals.

Luminal fluid was collected by micropuncture techniques from the testis and epididymis of the rat, hamster, rabbit, boar and ram and the concentration of free L-carnitine in the fluid was estimated using enzymic methods. Carnitine was present in the testicular fluid of the rat in concentrations less than 1 mM but increased down the epididymis to reach 53 mM in luminal fluid from the cauda epididymidis, approximately 2000 times higher than in blood plasma. A high concentration was first found in the luminal fluid from the distal caput epididymidis, at about the point where the spermatozoa become motile. Carnitine was also present in the epididymal luminal fluid of the other species studied; the amounts were not as high as those in the rat but were still higher than those in blood plasma.     

Glutathione-independent prostaglandin D2 synthase in ram and stallion epididymal fluids: origin and regulation

Microsequencing after two-dimensional electrophoresis revealed a major protein, glutathione-independent prostaglandin D2 synthase (PGDS) in the anterior epididymal region fluid of the ram and stallion. In this epididymal region, PGDS was a polymorphic compound with a molecular mass around 30 kDa and a range of pI from 4 to 7. PGDS represented 15% and 8% of the total luminal proteins present in this region in the ram and stallion, respectively. The secretion of the protein as judged by in vitro biosynthesis, and the presence of its mRNA as studied by Northern blot analysis, were limited to the proximal caput epididymidis. Using a specific polyclonal antibody raised against a synthetic peptide, PGDS was found throughout the epididymis, decreasing in concentration toward the cauda region. PGDS was also detected in the testicular fluid and seminal plasma by Western blotting. Castration and efferent duct ligation in the ram led to a decrease in PGDS mRNA and secretion. PGDS mRNA was not detected in the stallion 1 mo after castration, and it was restored by testosterone supplementation. This study showed that PGDS is present in the environment of spermatozoa throughout the male genital tract. Its function in the maturation and/or protection of spermatozoa is unknown.     

Responses of monkey epididymal sperm of different maturational status to second messengers mediating protein tyrosine phosphorylation,acrosome reaction,and motility

The maturation of various aspects of sperm function have been demonstrated in monkey and human epididymal sperm, including the ability to undergo the acrosome reaction. The present study aimed to investigate the maturational changes in non‐human primate sperm in the signal transduction mechanisms leading to the acrosome reaction involving cyclic AMP, Ca²⁺ influx, protein kinase C, and protein tyrosine phosphorylation. Sperm from the caput, corpus, and cauda epididymidis of cynomolgus monkeys were incubated in a complete medium for 2.5 hr, followed by 30 min stimulation with 1 mM dibutyryl cAMP and 1 mM caffeine, 50 μM 1,2‐dioctanoyl‐sn‐glycerol (DOG), and 50 μM Ca²⁺‐ionophore A23187. Quantitative Western blotting revealed little difference in tyrosine phosphorylated proteins among the caput, corpus, and cauda sperm without stimulation. Incubation with cAMP increased the amount of tyrosine phosphorylated proteins up to 10‐fold in the corpus and cauda sperm, but to a lower extent in the caput sperm. Ca²⁺‐ionophore attenuated the cAMP stimulation but had no effect on its own. Such responses in tyrosine phosphorylated proteins were in great contrast to the responses in the acrosome reaction, where A23187 was the strongest stimulant, resulting in induction of the reaction in 50 ± 5%, 11 ± 5%, and 8 ± 4% cauda, corpus and caput sperm, respectively (mean ± sem, n = 6). DOG and cAMP in combination induced acrosome reactions in about 10% of viable cells in the cauda and corpus but not caput sperm. Caput sperm responded to cAMP with increases in percentage motility without forward progression whereas cauda sperm displayed marked kinematic changes expected of hyperactivation. Comparisons of responses suggest that the major tyrosine phosphorylated proteins detected are unlikely to be involved immediately in the precipitation of the acrosome reaction, but more related to flagellar motion. Development of signal transduction pathways is part of the epididymal maturational process. Mol. Reprod. Dev. 54:194–202, 1999. © 1999 Wiley‐Liss, Inc.     

Isolation, immunolocalization, and sperm-association of three proteins of 18, 25, and 29 kilodaltons secreted by the mouse epididymis.

Three murine epididymal secretory proteins have been characterized by their site of synthesis, sperm association, and tissue localization by use of polyclonal antisera and immunochemistry. Mouse epididymal protein 7 (MEP 7) was localized initially within the supranuclear regions of some principal epithelial cells in the proximal corpus while other cells remained unstained. In the mid-proximal corpus, all principal cells and stereocilia were stained, and luminal staining increased from corpus to cauda. Some clear cells in the distal corpus and cauda also showed immunoperoxidase staining. Sequential extraction of caudal spermatozoa indicated that MEP 7 was predominantly loosely associated with spermatozoa and that only a small amount of MEP 7 required detergent to extract it from spermatozoa. Examination of other rodent caudal fluids revealed a related protein in rat caudal fluid of 32 kDa, and amino acid sequence analysis of MEP 7 showed a 68% sequence similarity with rat proteins AEG and D/E. MEP 9 immunolocalized within the cytoplasm of all principal cells of the distal caput. In a transition zone between the distal caput and the corpus, some principal cells were stained while others were not. Distal to the corpus, the principal cell staining gradually decreased. In the distal caput and proximal corpus, large heavily stained droplets associated with spermatozoa were seen in the lumen. The staining intensity of these droplets also decreased from corpus to cauda. The clear cells of the distal corpus and cauda did not stain with the antibody to MEP 9. Sequential extraction of caudal spermatozoa showed that some MEP 9 was extractable under low-salt conditions, whereas extraction with 0.1% Triton X-100 was required to remove all MEP 9, indicating it was firmly associated with spermatozoa. The antibody to MEP 9 cross-reacted with a 25-kDa protein present in rat caudal fluid. MEP 10 was localized within the cytoplasm of the principal cells, the stereocilia, and the lumen of the epididymis at the junction of the distal caput and corpus. In the distal corpus, a large number of clear cells were stained, but very few of these cells stained in the cauda. MEP 10 dissociated completely from caudal spermatozoa under low-salt conditions, indicating that it was not firmly bound to spermatozoa. The antiserum to MEP 10 cross-reacted with proteins present in rat and guinea pig caudal fluid. The related rat protein migrated at approximately 20 kDa. Amino acid sequence analysis of MEP 10 revealed an 86% sequence similarity with rat proteins B and C.(ABSTRACT TRUNCATED AT 400 WORDS)     

Prostaglandin F2α concentration in genital tract secretions of dairy bulls

Prostaglandin F_2α (PGF_2α) concentrations in genital tract secretions of conscious dairy bulls were determined by radioimmunoassay procedures and compared with peripheral blood plasma levels. The mean (± SD) PGF_2α concentration of coccygeal venous blood plasma from four bulls was 0.14 ± 0.05 ng/ml. Values for rete testis fluid and seminal plasma were the same, namely 0.17 ± 0.01 ng/ml (n = 5) and 0.17 ± 0.02 ng/ml (n = 4), respectively. However, the PGF_2α level in cauda epididymal plasma was 1.61 ± 0.41 ng/ml, or over 8 to 10 times (P < 0.01) the concentration of any other fluid studied.Added PGF_2α had no effect on the endogenous oxygen consumption of washed cauda epididymal spermatozoa or on the oxidative and glycolytic activities of washed ejaculated spermatozoa in vitro. No evidence was obtained suggesting that the prostaglandin may interact with the stimulatory effect of added testosterone or phosphatidylinositol (PI) on the motility, respiration or glucose uptake of ejaculated spermatozoa.     

Characterization of a 23 kDa sperm-binding polypeptide of the golden hamster epididymis

A 23 kDa polypeptide has been identified on the flagellum of sperm obtained from the cauda epididymis of the golden hamster. A monospecific antiserum to the 23 kDa hamster polypeptide was prepared and used to study its distribution on sperm, in the epididymis, and in epididymal fluid. In the cauda, the polypeptide is found on the midpiece and endpiece of the sperm tail, in detergent extracts of sperm, and in epididymal luminal fluid-enriched fractions. It is not present on sperm or in luminal fluid-enriched fractions from the caput epididymis. Immunocytochemical staining of epididymal tissue has demonstrated the 23 kDa polypeptide in the Golgi region of the principal cells of the proximal cauda and on sperm in the tubules of this segment and in tubules distal to it. Antiserum to the 23 kDa golden hamster polypeptide cross-reacts with sperm from rats and Chinese hamsters, but not with sperm from rabbits, cattle, mice, and guinea pigs. The antigen is localized to the tail of sperm obtained from the cauda of the rat and from the distal caput of the Chinese hamster. Immunoblots of detergent extracts of sperm and luminal fluid-enriched fractions from these two species reveal a 26 dKa polypeptide that is immunologically related to the golden hamster polypeptide.     

过氧化物酶6在大鼠附睾中的表达及分布

通过双向电泳结合质谱技术分离鉴定正常成年大鼠附睾头段与尾段管腔液中的蛋白组成,从附睾头段及尾段管腔液的22个差异蛋白点中鉴定出12个蛋白质.其中11个蛋白质在不同种属哺乳动物的附睾组织中已有鉴定报道,而过氧化物酶6(peroxiredoxin 6,Prdx6)为新发现的存在于附睾头段及尾段管腔液中的体液蛋白.采用RT-PCR、Western印迹及免疫组化技术,对该蛋白在大鼠附睾中的表达及分布进行了分析.实验表明,Prdx6与精子的成熟、贮存及保护有一定关系,其具体机制值得进一步深入研究.     

Identification and expression of boar sperm proteins in the reproductive tract that interact with antibodies in serum from an infertile woman

Serum designated as IS obtained from a young healthy infertile woman induced a head-to-head agglutination of ejaculated boar sperm. The immunoglobulin G (IgG) prepared from IS localized to the acrosomal region of the sperm head obtained from the corpus and cauda epididymis as determined by an indirect immunofluorescent method. The IgG interacted with a boar sperm protein with an estimated molecular weight of 45-kDa, determined by sodium dodecyl sulfate-polyacrylamide gel electrophoretic (SDS-PAGE) immunoblotting technique. However, the IgG did not interact with proteins extracted from sperm obtained from the testis and caput epididymis or from non-gonadal tissues including liver, kidney, spleen, muscle and serum. The IgG interacted with additional proteins of about 75- and 38-kDa present in the corpus and cauda epididymal fluids but not those in the caput epididymal fluid. The staining intensity of the 75-kDa band was reduced and that of the 38-kDa was nullified with ejaculated seminal plasma proteins. The interacting proteins were adsorbed when chromatographed on Concanavalin A Sepharose column, suggesting that they are glycoproteins.     

Glycoprotein changes in the rat sperm plasma membrane during maturation in the epididymis.

To investigate surface glycoprotein changes during post-testicular maturation, plasma membranes were isolated from proximal caput, distal caput, and cauda epididymal rat spermatozoa. Membrane glycoproteins were identified on Western blots of SDS-PAGE fractionated samples using biotinylated lectins and Vecta-stain reagents; these were compared to glycoproteins present in cauda epididymal luminal fluid. Lens culinaris agglutinin, Pisum sativum agglutinin, peanut agglutinin, wheat germ agglutinin, Ricinus communis agglutinin, Ulaex europaeus agglutinin, and Dolichol biflorus agglutinin each bound a specific subset of the polypeptides present. Several types of glycoprotein changes were noted including their appearance, loss, alteration of staining intensity, and alteration of electrophoretic mobility. Some maturation-dependent sperm surface glycoproteins co-migrated with glycoproteins present in epididymal fluid. This approach of direct analysis of the glycoproteins in purified plasma membranes identifies a broader spectrum of maturation-related surface changes occurring within the epididymis than are noted with surface labeling procedures.     

Interactions of labeled epididymal secretory proteins with spermatozoa after injection of 35S-methionine in the mouse

The sequential interactions of epididymal secretory proteins with spermatozoa during epididymal transit were examined. Mice received injections of 35S-methionine, and the radiolabeled luminal fluid and sperm-associated proteins were analyzed by sodium dodecylsulfate-polyacrylamide gel electrophoresis at various times after injection. The majority of the luminal fluid and sperm-associated proteins were found in the caput epididymidis at 8 h; by 7 days, many of these proteins had been transported to the cauda epididymidis. Two classes of epididymal protein-sperm interactions were distinguished on the basis of regional synthesis and secretion. The major class consisted of proteins that were synthesized, secreted, and bound to spermatozoa in the caput epididymidis. In this class, however, the binding of proteins to the spermatozoa was variable. For example, a protein of 25 kDa remained associated with spermatozoa in substantial amounts during epididymal transit, while proteins of 40 and 35 kDa decreased in amount. Other proteins such as a protein of 18 kDa did not remain associated with spermatozoa. Another class of proteins (54, 44, 29 kDa) were synthesized and secreted from all epididymal regions but bound only to caput spermatozoa. Most of the epididymal proteins appeared to be tightly bound to the spermatozoa since spermatozoa already saturated with the unlabeled protein in the distal epididymis remained so even though the spermatozoa were surrounded by labeled proteins in the luminal fluid. These studies demonstrate that a variety of specific interactions occur between epididymal secretory proteins and spermatozoa as they migrate and mature in the epididymis.