Characterization of epidermal growth factor receptor in testis, epididymis and vas deferens of non-human primates.

The presence of the epidermal growth factor receptor (EGFR) in testis, epididymis and vas deferens of monkeys was demonstrated using a polyclonal antibody (RK2) raised against a peptide-specific sequence of the intracellular domain of the human EGFR. Immunoblotting of membrane preparations revealed a specific band at approximately 170 kDa corresponding to those of controls, A431 and monkey liver cells. Cryostat sections were stained by biotin-streptavidin peroxidase immunocytochemistry. The liver showed positive staining along the basolateral membranes of the hepatocytes lining the sinusoids. The testis showed positive staining indicating the presence of EGFR in Leydig cells, Sertoli cells and peritubular cells. In the epididymis, immunostaining of the EGFR was observed on both the basolateral and the luminal borders of the epididymal epithelium. Immunofluorescence studies revealed a similar pattern of EGFR distribution in the epididymis and indicated that the luminal immunostaining was vesicular. In the vas deferens, positive immunostaining was detected in a pattern very similar to that observed in the epididymis. There was no positive staining in the interstitium of the epididymis or in the smooth muscle cell layers of the vas deferens. The sections of all tissues treated with pre-immune serum were negative. These results suggest that EGF in the primate testis may act at the level of somatic cells. In addition, the basolateral and luminal EGFR staining in the epididymis and vas deferens suggest that these cells respond to an EGF, or EGF-like, source both at the basal, luminal or at both sides of the cells, or that these tissues serve as sites of EGF transcytosis across the epithelium.     

Species-specific expression of microsomal prostaglandin E synthase-1 and cyclooxygenases in male monkey reproductive organs

We investigated the tissue distribution and cellular localization of microsomal PGE synthase-1 (mPGES-1) and cyclooxygenase (COX)-1 and -2 in male monkey reproductive organs. Western blotting revealed that monkey mPGES-1 was expressed most intensely in the seminal vesicles, moderately in the testis, and weakly in the epididymis and vas deferens. The tissue distribution profile was quite different from those profiles for rats, rabbits, and pigs, e.g., rat mPGES-1 was the most abundant in the vas deferens, and the rabbit and pig enzymes, in the testis. Immunohistochemical staining with mouse monoclonal anti-human mPGES-1 antibody revealed that monkey mPGES-1 was localized in spermatogonia, Sertoli cells, and primary spermatocytes of testis and in epithelial cells of the epididymis, vas deferens, and seminal vesicles. In monkeys, COX-1 was localized in epithelial cells of the epididymis and vas deferens, whereas COX-2 was dominantly found in epithelial cells of the seminal vesicles.     

国人睾丸、附睾和输精管的氧化还原酶的组织化学观察

本文收集了１９—３８岁国人正常男性新鲜睾丸、附睾和输精管１３例,进行了氧化还原酶组织化学染色、光镜定位及定性观察。结果表明：睾丸曲细精管和输出小管上皮的ＧＤＨ,ＮＡＤＨＤ,ＮＡＤＰＨＤ,ＳＤＨ,ＧＰＤＨ,ＩＣＤＨ,ＭＤＨ,ＬＤＨ和Ｇ－６－ＰＤＨ９种酶;睾丸间质细胞和附睾管上皮的ＮＡＤＨＤ,ＮＡＤＰＨＤ,ＳＤＨ,ＩＣＤＨ,ＭＤＨ,ＧＤＨ,ＬＤＨ和Ｇ－６－ＰＤＨ８种酶;输精管的ＮＡＤＨＤ,ＮＡＤＰＨＤ,ＩＣＤＨ和ＧＤＨ４种酶的酶活性呈强阳性或极强阳性。提示输出小管和头部附睾管含有的多种氧化还原酶对精子功能成熟有极重要作用。     

Maturation of guinea pig sperm in the epididymis involves the modification of proacrosin oligosaccharide side chains

Proacrosin from guinea pig cauda epididymal sperm has a lower molecular weight compared with the testicular zymogen. In this study, we have examined the structural basis of this change and where the conversion in proacrosin molecular weight occurs during sperm maturation. Immunoblotting of trifluoromethanesulfonic acid-deglycosylated testicular and cauda epididymal sperm extracts with antibody to guinea pig testicular proacrosin demonstrated that the polypeptide backbones of proacrosins from the testis and cauda epididymal sperm had the same molecular weights (approximately 44,000). Keratanase, an endo-beta-galactosidase specific for lactosaminoglycans, partially digested testicular proacrosin but had no effect on proacrosin from cauda epididymal sperm. In extracts of testis, caput epididymis, and corpus epididymis analyzed by immunoblotting, anti-proacrosin recognized a major antigen with an apparent molecular weight (Mr) of 55,000, although a 50,000-Mr minor antigen began to appear in the corpus epididymis. By contrast, extracts of cauda epididymis, vas deferens, and cauda epididymal sperm had the 50,000 Mr protein as the only immunoreactive antigen. By enzymography following electrophoresis, the major bands of proteolytic activity in extracts of testis, caput epididymis, and corpus epididymis had 55,000 Mr. A band of protease activity with 55,000 Mr also appeared in extracts of the corpus epididymis. However, the most prominent bands of proteolytic activity in cauda epididymis, vas deferens, and cauda epididymal sperm had 50,000 Mr. In addition, two other major protease activities were detected with 32,000 and 34,000 Mr; the relationships of these proteases to proacrosin are unclear. From these results, we conclude that the oligosaccharides of proacrosin are altered during epididymal transit and that this modification occurs in the corpus epididymis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunolocalization of Aquaporin-1, -5, and -7 in the Avian Testis and Vas Deferens

Thirteen mammalian aquaporin (AQP) isoforms have been identified, and they have a unique tissue-specific pattern of expression. AQPs have been found in the reproductive system of both male and female humans, rats, and mice. However, tissue expression and cellular and subcellular localization of AQPs have been poorly investigated in the male reproductive system of birds. The localization of AQP subtypes (AQP1, 2, 3, 4, 5, 7, 8, 9, and 11) in the goose testis and vas deferens has been studied through immunohistochemistry and immunobloting. Interestingly, the testicular and deferential tissues were positive for AQP1, -5, and -7 but not the others. AQP1 immunoreactivity was detected in the capillary endothelial cells of testis and vas deferens. AQP5 was localized in the interstitial tissue of the testis, including Leydig cells, as well as in the basal cells of vas deferens. Double-labeling confocal microscopy revealed coexpression of AQP5 with capillary AQP1 in the testis. AQP7 was expressed in elongated spermatid and spermatozoa tails in the testis, as well as spermatozoa tails in the vas deferens. These results suggest that several subtypes of AQPs are involved in the regulation of water homeostasis in the goose male reproductive system. (J Histochem Cytochem 57:915–922, 2009)     

Difference of fertilizing capacity between testicular sperm and vas deferens sperm in Cynops pyrrhogaster

The fertilizing capacity was compared between testicular and vas deferens sperm in Cynops pyrrhogaster. The testicular sperm was not capable of fertilizing jelly eggs. In contrast, the vas deferens sperm was already capable of fertilizing the newt jelly eggs. There was no inhibitory factor for fertilizing jelly eggs in the testis. These results suggest that the testicular sperm is immature as to the fertilizing capacity. The testicular sperm gained the fertilizing capacity for the jelly eggs by treatment with Holtfreter's solution or 1/20 strength Holtfreter's solution. The treatment may promote the step of maturation to achieve the fertilizing capacity. The treated testicular sperm did not fertilize dejellied eggs, although vas deferens sperm fertilized dejellied eggs. Therefore, the maturation state of the treated testicular sperm is different from that of vas deferens sperm. Newt sperm may be matured within the vas deferens, as the newt does not have an organ like the mammalian epididymis.     

Metabolic Coupling Determines the Activity: Comparison of 11β-Hydroxysteroid Dehydrogenase 1 and Its Coupling between Liver Parenchymal Cells and Testicular Leydig Cells

Background

11β-hydroxysteroid dehydrogenase 1 (11β-HSD1) interconverts active 11β-hydroxyl glucocorticoids and inactive 11keto forms. However, its directionality is determined by availability of NADP+/NADPH. In liver cells, 11β-HSD1 behaves as a primary reductase, while in Leydig cells it acts as a primary oxidase. However, the exact mechanism is not clear. The direction of 11β-HSD1 has been proposed to be regulated by hexose-6-phosphate dehydrogenase (H6PDH), which catalyzes glucose-6-phosphate (G6P) to generate NADPH that drives 11β-HSD1 towards reduction.

Methodology

To examine the coupling between 11β-HSD1 and H6PDH, we added G6P to rat and human liver and testis or Leydig cell microsomes, and 11β-HSD1 activity was measured by radiometry.

Results and Conclusions

G6P stimulated 11β-HSD1 reductase activity in rat (3 fold) or human liver (1.5 fold), but not at all in testis. S3483, a G6P transporter inhibitor, reversed the G6P-mediated increases of 11β-HSD1 reductase activity. We compared the extent to which 11β-HSD1 in rat Leydig and liver cells might be coupled to H6PDH. In order to clarify the location of H6PDH within the testis, we used the Leydig cell toxicant ethane dimethanesulfonate (EDS) to selectively deplete Leydig cells. The depletion of Leydig cells eliminated Hsd11b1 (encoding 11β-HSD1) expression but did not affect the expression of H6pd (encoding H6PDH) and Slc37a4 (encoding G6P transporter). H6pd mRNA level and H6PDH activity were barely detectable in purified rat Leydig cells. In conclusion, the availability of H6PDH determines the different direction of 11β-HSD1 in liver and Leydig cells.     

Evidence for expression of 11β-hydroxysteroid dehydrogenase type3 (HSD11B3/HSD11B1L) in neonatal pig testis

11β-hydroxysteroid dehydrogenase (HSD11B) catalyzes the interconversion between active and inactive glucocorticoid, and is known to exist as two distinct isozymes: HSD11B1 and HSD11B2. A third HSD11B isozyme, HSD11B1L (SCDR10b), has recently been identified. Human HSD11B1L, which was characterized as a unidirectional NADP⁺-dependent cortisol dehydrogenase, appears to be specifically expressed in the brain. We previously reported that HSD11B1 and abundant HSD11B2 isozymes are expressed in neonatal pig testis and the Km for cortisol of NADP⁺-dependent dehydrogenase activity of testicular microsomes obviously differs from the same activity catalyzed by HSD11B1 from pig liver microsomes. Therefore, we hypothesized that the neonatal pig testis also expresses the third type of HSD11B isozyme, and we herein examined further evidence regarding the expression of HSD11B1L. (1) The inhibitory effects of gossypol and glycyrrhetinic acid on pig testicular microsomal NADP⁺-dependent cortisol dehydrogenase activity was clearly different from that of pig liver microsomes. (2) A highly conserved human HSD11B1L sequence was observed by RT-PCR in a pig testicular cDNA library. (3) mRNA, which contains the amplified sequence, was evaluated by real-time PCR and was most strongly expressed in pig brain, and at almost the same levels in the kidney as in the testis, but at lower levels in the liver. Based on these results, neonatal pig testis appears to express glycyrrhetinic acid-resistant HSD11B1L as a third HSD11B isozyme, and it may play a physiologically important role in cooperation with the abundantly expressed HSD11B2 isozyme in order to prevent Leydig cell apoptosis or GC-mediated suppression of testosterone production induced by high concentrations of activated GC in neonatal pig testis.     

Effect of efferentiectomy on enzymes of glycolytic pathway, HMP pathway and TCA cycle in epididymis and vas deferens of rhesus monkey.

The importance of exocrine secretions of testis in the regulation of energy metabolism of the epididymis and vas deferens was examined in rhesus monkeys by performing efferentiectomy. At autopsy the epididymis was divided into initial segment, caput, corpus and cauda portions to make an account of regional differences, if any. Eleven enzymes of glycolysis, two key enzymes of HMP pathway and seven enzymes of TCA cycle were assayed in the epididymal segments and vas deferens of control (intact) and experimental (efferentiectomised for 90 days) monkeys. The results indicate that while anaerobic energy metabolism (glycolysis and HMP pathway) is sensitive to efferentiectomy chiefly in the proximal regions of epididymis, the oxidative pathway (TCA cycle) is dependent on testicular exocrine secretions throughout the length of epididymis, as well as in the vas deferens. Since all androgen-sensitive enzymes do not regress after efferentiectomy, it is suggested that unidentified exocrine factors of testis may have role in regulating energy metabolism in the epididymis and vas deferens.     

Heterogeneity of 11β-hydroxysteroid dehydrogenase in rat tissues

Using specific antisera to purified rat liver 11β-hydroxysteroid dehydrogenase (11-HSD), we showed that the antigen is widely distributed in rat organs. Enzyme activity and immunoreactivity generally corresponded. Highest by both criteria were liver, testis, kidney and lung. In some tissues (epididymis, pancreas and duodenum) activity was found, but antigen corresponding to 11-HSD at a M_w of 34 kDa was absent. It is suggested that these tissues have alternate enzyme forms. The 11-HSD of brain and liver were compared. Brain enzyme may control selective binding of aldosterone to Type I receptors in the hippocampus and other regions. Rat brain 11-HSD resembled that of liver or kidney in most characteristics. It differed in (a) its steroid specificity: cortisol was a good substrate for liver 11-HSD, and a poor substrate for brain enzyme; (b) stability of 11-oxoreductase (11-OR) component. Brain 11-OR was not readily inactivated; 11-OR from other tissues lost activity rapidly and spontaneously. The variations in properties of 11-HSD in specific tissues may reflect aspects of its various specific functions.     

Expression and characterization of isoforms of 3β-hydroxysteroid dehydrogenase/Δ-isomerase in the hamster

The enzyme 3β-hydroxysteroid dehydrogenase/Δ^5→4-isomerase (3β-HSD) is essential for the production of all classes of steroid hormones. Multiple isozymes of this enzyme have been demonstrated in the kidney and liver of both the rat and the mouse, although the function of the enzyme in these tissues is unknown. We have characterized three isozymes of 3β-HSD expressed in various tissues of the hamster. Both western and northern blot analyses demonstrated very high levels of 3β-HSD in the adrenal, kidney and male liver. Conversely, there were extremely low levels of enzyme expression in the female liver. cDNA libraries prepared from RNA isolated from hamster adrenal, kidney and liver were screened with a full-length cDNA encoding human type 1 3β-HSD. Separate cDNAs encoding three isoforms of 3β-HSD were isolated from these libraries. To examine the properties of the isoforms, the cDNAs were ligated into expression vectors for over-expression in 293 human fetal kidney cells. The type 1 isoform, isolated from an adrenal cDNA library, was identified as a high-affinity 3β-hydroxysteroid dehydrogenase. A separate isoform, designated type 2, was isolated from the kidney, and this was also a high-affinity dehydrogenase/isomerase. Two cDNAs were isolated from the liver, one identical in sequence to type 2 of the kidney, and a distinct cDNA encoding an isoform designated type 3. The type 3 3β-HSD possessed no steroid dehydrogenase activity but was found to function as a 3-ketosteroid reductase. Thus male hamster liver expresses a high-affinity 3β-HSD (type 2) and a 3-ketosteroid reductase (type 3), whereas the kidney of both sexes express the type 2 3β-HSD isoform. These differ from the type 1 3β-HSD expressed in the adrenal cortex.     

Differentiation of adult Leydig cells

Adult Leydig cells originate within the testis postnatally. Their formation is a continuous process involving gradual transformation of progenitors into the mature cell type. Despite the gradual nature of these changes, studies of proliferation, differentiation and steroidogenic function in the rat Leydig cell led to the recognition of three distinct developmental stages in the adult Leydig cell lineage: Leydig cell progenitors, immature Leydig cells and adult Leydig cells. In the first stage, Leydig cell progenitors arise from active proliferation of mesenchymal-like stem cells in the testicular interstitium during the third week of postnatal life and are recognizable by the presence of Leydig cell markers such as histochemical staining for 3β-hydroxysteroid dehydrogenase (3β-HSD) and the present of luteinizing hormone (LH) receptors. They proliferate actively and by day 28 postpartum differentiate into immature Leydig cells. In the second stage, immature Leydig cells are morphologically recognizable as Leydig cells. They have an abundant smooth endoplasmic reticulum and are steroidogenically active, but primarily produce 5-reduced androgens rather than testosterone. Immature Leydig cells divide only once, giving rise to the total adult Leydig cell population. In the third and final stage, adult Leydig cells are fully differentiated, primarily produce testosterone and rarely divide. LH and androgen act together to stimulate differentiation of Leydig cell progenitors into immature Leydig cells. Preliminary data indicate that insulin like growth factor-1 (IGF-1) acts subsequently in the transformation of immature Leydig cells into adult Leydig cells.     

The histochemical localization of prostaglandin synthetase activity in reproductive tract of the male rat.

PG synthetase activity was assessed histochemically in the reproductive tract of male rats. Moderate activity was observed in tails of spermatozoa within the corpus and cauda epididymidis but there was no activity in the caput epididymidis or the seminiferous tubules. The sperm tail activity was maximal for cells within the vas deferens. PG synthetase activity was also observed in individual adipose cells adhering to the testicular capsule, epididymis and vas deferens, and in isolated interstitial cells of the testis and the caput, corpus and cauda epididymidis. Specific cells in the capsules of the testes, epididymis and vas deferens also produced PGs. The activity observed in the interstitial cells of the testis and the caput epididymidis was less than that for the other tissues in terms of the proportion of possible cells. The demonstration of PG synthetase activity paralleled to known loss of arachidonic acid from the phospholipids of the spermatozoa as they pass through the male tract. Endogenous substrate was not limiting in the assay system, even in the testis and caput epididymidis where PG synthesis was not normally observed, indicating that a PG synthesis inhibitor may be present in these two tissues. PG synthetase activity within teased seminiferous tubules was markedly increased by physical trauma. Indomethacin diminished but did not eliminate synthesis.     

Histological, fine-structural and histochemical differences in the testicular glands of gobiid and blenniid fishes

The testicular gland (t.g.) is a glandular tissue situated adjacent to the testis of blenniid and several gobiid species. In the present study the t.g. of Blennius pavo Risso and Gobius niger L. were compared by histological and histochemical methods. In B. pavo the spermatozoa have to cross the t.g. to reach the vas deferens and thus they come into contact with the gland cells, whereas in G. niger the vas deferens is situated between the testis and the t.g. The fine structure and histo-chemistry of the t.g. cells reveal that in B.pavo the cells of the t.g. have exocrine as well as endocrine functions. The t.g. cells of B. pavo contain large amounts of lipids, form a secretion containing acid mucopolysaccharides, show positive reaction for acid phosphatase, and some cells stain for 3β-HSD and G6PD. The function of the t.g. of G. niger is exclusively endocrine. Characteristics of the gland cells of this species are well developed smooth ER and tubulovesicular or paracristal-line mitochondria. The stainings for 3β-HSD, G6PD and UDPGD give strong positive results in the whole t.g., indicating the presence of steroids and steroid glucuronides.     

Kinetic analysis of enzymic activities: Prediction of multiple forms of 17β-hydroxysteroid dehydrogenase

An overview of the application of kinetic methods to the delineation of 17β-hydroxysteroid dehydrogenase (17β-HSD) heterogeneity in mammalian tissues is presented. Early studies of 17β-HSD activity in animal liver and kidney subcellular fractions were suggestive of multiple forms of the enzyme. Subsequently, detailed characterization of activity in cytosol and subcellular membrane fractions of human placenta, with particular emphasis on inhibition kinetics, yielded evidence of two kinetically-differing forms of 17β-HSD in that organ. Gene cloning and transfection experiments have confirmed the identity of these two proteins as products of separate genes. 17β-HSD type 1 is a cytosolic enzyme highly specific for C₁₈ steroids such as 17β-estradiol (E₂) and estrone (E₁). 17β-HSD type 2 is a membrane bound enzyme reactive with testosterone (T) and androstenedione (A), as well as E₂ and E₁. Useful parameters for the detection of multiple forms of 17β-HSD appear to be the E₂/T activity ratio, NAD/NADP activity ratios, steroid inhibitor specificity and inhibition patterns over a wide range of putative inhibitor concentrations. Evaluation of these parameters for microsomes from samples of human breast tissue suggests the presence of 17β-HSD type 2. The 17β-HSD enzymology of human testis microsomes appears to differ from placenta. Analysis of human ovary indicates granulosa cells are particularly enriched in the type 1 enzyme with type 2-like activity in stroma/theca. Mouse ovary appears to contain forms of 17β-HSD which differ from 17β-HSD type 1 and type 2 in their kinetic properties.     

Molecular genetics of androgenic 17β-Hydroxysteroid dehydrogenases

17β-Hydroxysteroid dehydrogenase (17β-HSD) type 2 catalyzes the NAD⁺-dependent oxidation of androgens, estrogens and progestins, predominantly in the secretory endometrium, placenta, liver and small intestine. 17β-HSD type 3 catalyzes the NADPH-dependent conversion of androstenedione to testosterone in the testis, and the genetic disease 17β-HSD deficiency is caused by mutations in the 17β-HSD3 gene.     

Studies on the protective role of vitamin C and E against polychlorinated biphenyl (Aroclor 1254)--induced oxidative damage in Leydig cells

Free radical production and lipid peroxidation are potentially important mediators in testicular physiology and toxicology. Polychlorinated biphenyls (PCBs) are global environmental contaminants that cause disruption of the endocrine system in human and animals. The present study was conducted to elucidate the protective role of vitamin C and E against Aroclor 1254-induced changes in Leydig cell steroidogenesis and antioxidant system. Adult male rats were dosed for 30 days with daily intraperitoneal (ip) injection of 2 mg/kg Aroclor or vehicle (corn oil). One group of rats was treated with vitamin C (100 mg/kg bw/day) while the other group was treated with vitamin E (50 mg/kg bw/day) orally, simultaneously with Aroclor 1254 for 30 days. One day after the last treatment, animals were euthanized and blood was collected for the assay of serum hormones such as luteinizing hormone (LH), thyroid stimulating hormone (TSH), prolactin (PRL), triiodothyronine (T₃), thyroxine (T₄), testosterone and estradiol. Testes were quickly removed and Leydig cells were isolated in aseptic condition. Purity of Leydig cells was determined by 3β-hydroxysteroid dehydrogenase (3β-HSD) staining method. Purified Leydig cells were used for quantification of cell surface LH receptors and steroidogenic enzymes such as cytochrome P₄₅₀ side chain cleavage enzyme (P₄₅₀scc), 3β-hydroxysteroid dehydrogenase (3β-HSD) and 17β-hydroxysteroid dehydrogenase (17β- HSD). Leydig cellular enzymatic antioxidants superoxide dismutase (SOD), catalase (CAT), glutathione peroxidase (GPx), glutathione reductase (GR), γ-glutamyl transpeptidase (γ-GT), glutathione-S-transferase (GST) and non-enzymatic antioxidants such as vitamin C and E were assayed. Lipid peroxidation (LPO) and reactive oxygen species (ROS) were also estimated in Leydig cells. Aroclor 1254 treatment significantly reduced the serum LH, TSH, PRL, T₃, T₄, testosterone and estradiol. In addition to this, Leydig cell surface LH receptors, activities of the steroidogenic enzymes such as cytochrome P₄₅₀scc, 3β-HSD, 17β-HSD, antioxidant enzymes SOD, CAT, GPX, GR, γ-GT, GST and non-enzymatic antioxidants such as vitamin C and E were significantly diminished whereas, LPO and ROS were markedly elevated. However, the simultaneous administration of vitamin C and E in Aroclor 1254 exposed rats resulted a significant restoration of all the above-mentioned parameters to the control level. These observations suggest that vitamin C and E have ameliorative role against adverse effects of PCB on Leydig cell steroidogenesis.     

Testis-testicular gland complex of two Tripterygion species (Blennioidei, Teleostei): differences between territorial and non-territorial males

The morphological differences between the testis and testicular gland of territorial and nonterritorial males of Tripterygion tripteronotus and T. delaisi were examined and correlated with differences in reproductive behaviour. In territorial males of both species the testicular gland is much more developed than in non-territorial males. Larger cellular and nuclear sizes in the territorial males indicate that the activity of the gland cells is enhanced. These cells contain SER, numerous lipid droplets and mitochondria with lamellar cristae. Absence of 3β-HSD activity at these sites points to lack of a steroidogenic potency. In both territorial and non-territorial fish, steroid-producing Leydig cells have been demonstrated in the connective tissue betweeen the testis and the testicular gland, and around the collecting sperm duct. In addition, 3β-HSD activity has been found in the scarce interstitial Leydig cells of territorial fish. Morphometric data indicate an enhanced activity of the Leydig cells in territorial fish.