Localization of plasminogen activator and inhibitor, LH and androgen receptors and inhibin subunits in monkey epididymis

Epididymis is a site of sperm maturation and storage. Limited and directed-proteolysis regulated by plasminogen activator (PA), plasminogen activator inhibitor type-1 (PAI-1) and other related factors may play an essential role in these processes. Our previous studies have demonstrated that rat epididymis expressed luteinizing hormone receptor (LHR), tissue type (t) and urokinase type (u)PA, mRNAs, and tPA activity was stimulated in vitro by human chorionic gonoadotrophin (HCG). In the present study we further examined localization of mRNAs for tPA, uPA, LHR, androgen receptor (AR), as well as inhibin subunits alpha, betaA and betaB in rhesus monkey epididymis. Using in-situ hybridization with digoxygenin-labelled cRNA probes, we have demonstrated that tPA and PAI-1 mRNAs were localized in epithelial cells of adult monkey epididymis. uPA mRNA was localized in the same areas, but to a much smaller extent. tPA, uPA and PAI-1 mRNAs were greatly expressed in the caput and corpus of adult epididymis than in other regions. In-vitro experiments showed that both tPA and uPA activities in epididymal cells were dramatically stimulated by HCG, but not by follicle stimulating hormone (FSH). LHR (but not FSH receptor) and AR mRNAs were localized in the epithelial cells of the epididymis. However, LHR mRNA was detected in both adult and immature infant monkeys, whereas AR was found only in the adult. Inhibin alpha, betaA and betaB mRNAs were also detected in this organ, betaA mRNA being more strongly expressed in the caput than in other regions of the epididymis. We suggest that LH and androgen may be the key hormones in coordination with the PA-PAI-1 system in regulating epididymal differentiation and sperm maturation.      

层黏连蛋白受体在小鼠睾丸和附睾中的表达

目的 探讨层黏连蛋白受体(LAMR1)在小鼠睾丸和附睾中的表达.方法收集3只正常成年昆明小鼠睾丸和附睾.采用原位杂交和免疫组织化学方法,检测LAMR1 mRNA及蛋白在成年小鼠睾丸和附睾中的分布.结果 LAMR1 mRNA在附睾头和附睾尾表达最强;在睾丸生精细胞中也有表达.免疫组织化学结果显示,LAMR1蛋白从附睾头到...     

Regulation of apical blebbing in the porcine epididymis

Apical blebbing, a non‐classical secretion mechanism, occurs in the mature porcine epididymis as part of its normal function. Proteins secreted by this mechanism contribute to the modification of the sperm plasma membrane during epididymal transit and are thought to contribute to acquisition of fertilizing ability. However, little is known about the regulation of this secretion mechanism in an in vivo model. Previous work demonstrated apical blebbing in the epididymis developed pubertally, suggesting androgens, sperm or other luminal factors regulated this process. Hence, the objective was to evaluate the hypothesized regulation of apical blebbing in the epididymis of pubertal boars by androgens and luminal factors. Androgen receptor blockade (flutamide) and surgical interventions (efferent duct ligation, orchidectomy or transection of the caput epididymis) were used to alter signaling, and the subsequent effects on apical blebbing were evaluated histologically. Apical blebbing was not altered by androgen receptor blockade with flutamide, but was significantly reduced 24 h after efferent duct ligation and after orchidectomy, treatments that eliminated luminal flow from the testis (P < 0.05). Like efferent duct ligation, epididymal transection altered luminal flow without removing the androgen source and significantly reduced the appearance of apical blebbing (P < 0.05). In conclusion, apical blebbing in the porcine epididymis appears to be regulated by luminal factors.     

用原位杂交法研究兔附睾蛋白BE－20的基因表达

兔附睾尾液经ＨＰＬＣ纯化后，获得分子量为２０ｋＤ的附睾特异蛋白，命名为ＢＥ－２０。ＢＥ－２０的抗体具有明显抑制人精子穿透去透明带仓鼠卵的能力。已获得编码ＢＥ－２０的０．５ｋｂｃＤＮＡ片段，命名为ＲＥＤ－２０。用地高辛标记此片段，与兔睾丸、附睾、输精管和肝组织进行原位杂交，观察ＢＥ－２０在各种组织中的定位和表达。采用杂交前热变性与不用热变性组织两种方法进行原位杂交。杂交信号均为紫褐色的颗粒，分布在附睾尾的主细胞和近端输精管的上皮细胞的胞质内，表明胞质内ｍＲＮＡ与地高辛标记ＲＥＤ－２０ｃＤＮＡ探针杂交。组织经热变性后，附睾尾和近端输精管上皮细胞核出现强阳性反应，表明核内的同源ＤＮＡ与地高辛标记的ＲＥＤ－２０ｃＤＮＡ探针杂交。但在睾丸和肝脏内未见杂交信号，提示ＢＥ－２０是附睾尾和近端输精管上皮细胞合成的蛋白质。经分析证明，此蛋白是一种细胞外的蛋白酶抑制剂，可能与防止精子过早获能有关，它是否能用于制备抗生育疫苗有待深入的研究。     

Immunohistochemistry and in situ hybridization of the androgen receptor in the developing human prostate

 As it is suggested that the androgen receptor mechanism is required for prostatic development, we attempted to determine the appearance, expression and distribution of the androgen receptor in embryonic, infantile and pubertal human prostate. Using mono- and polyclonal antibodies and a digoxigenin-labeled 713 bp riboprobe, the androgen receptor expression in paraffin sections of fetal, infantile, and pubertal prostates was studied at the protein and RNA level. Under highly standardized conditions, application of the polyclonal antibodies resulted in a weak cytoplasmic and nuclear labeling of the epithelium of fetal glands. No immunoreaction was obtained with monoclonal antibodies. Applying the polyclonal antibody to pubertal and adult specimens, immunoreactivity of the androgen receptor was positive in nuclei of adluminal and basal epithelial cells, in interstitial and vascular smooth muscle cells and vascular endothelium, whereas ganglionic cells and enteroendocrine cells were negative. In situ hybridization with the digoxigenin-labeled riboprobe gave clear positive results already in epithelium of very young fetal specimens. A semiquantitative visual evaluation of in situ hybridizations showed that intermediate intensity of expression was increased in pubertal and adult specimens, whereas strong expression was reduced in prostatic epithelium. Conclusions: The essential findings are: (1) an early expression of androgen receptor mRNA in the fetal prostate; (2) no immunoreaction of monoclonal antibodies against the androgen receptor in the same specimens, (3) a decrease of androgen receptor mRNA expression, but increase in immunoreactivity of the androgen receptor protein with the onset of glandular maturation during puberty. Accepted: 29 September 1997     

Ontogeny of androgen receptor expression in the ovine fetal central nervous system and pituitary

In fetal sheep, circulating androgens influence fetal stress responsiveness and the timing of parturition. Nevertheless, little is known about the presence and development of androgen receptors (ARs) in the fetal brain. The present study was undertaken to test the hypothesis that expression of androgen receptor occurs in fetal brain and pituitary, and that the abundance of the AR is ontogenetically regulated. We isolated mRNA from pituitary, hypothalamus, hippocampus, and brainstem in fetal sheep that were 80, 100, 120, 130, and 145-day gestation, and 1 and 7 days postnatal (n=4-5 per group). Using real-time RT-PCR, we measured mRNA expression levels of the receptor in these brain regions and pituitary. In a separate study, we isolated protein from the same brain regions in fetal sheep that were 80 (n=3), 120 (n=4), and 145 (n=4) days. AR mRNA expression in hypothalamus increased in late gestation, starting at 145 days, and increasing progressively after birth. A trend of increasing AR protein in hypothalamus was not significant. AR mRNA expression in pituitary was elevated after 80 days gestation, but with no further increases or decreases in late gestation, while AR protein increased significantly at the end of gestation. In hippocampus and brainstem AR mRNA was constant throughout the latter half of gestation, and AR protein was below the sensitivity of our Western blot assay. We conclude that the fetal brain and pituitary are target sites for circulating androgens or androgen precursors in fetal plasma, and we speculate that the increase in hypothalamic action of androgens immediately prior to birth might be integral to the timing of parturition.     

Ontogeny of androgen receptor expression in the ovine fetal central nervous system and pituitary

In fetal sheep, circulating androgens influence fetal stress responsiveness and the timing of parturition. Nevertheless, little is known about the presence and development of androgen receptors (ARs) in the fetal brain. The present study was undertaken to test the hypothesis that expression of androgen receptor occurs in fetal brain and pituitary, and that the abundance of the AR is ontogenetically regulated. We isolated mRNA from pituitary, hypothalamus, hippocampus, and brainstem in fetal sheep that were 80, 100, 120, 130, and 145-day gestation, and 1 and 7 days postnatal (n = 4–5 per group). Using real-time RT-PCR, we measured mRNA expression levels of the receptor in these brain regions and pituitary. In a separate study, we isolated protein from the same brain regions in fetal sheep that were 80 (n = 3), 120 (n = 4), and 145 (n = 4) days. AR mRNA expression in hypothalamus increased in late gestation, starting at 145 days, and increasing progressively after birth. A trend of increasing AR protein in hypothalamus was not significant. AR mRNA expression in pituitary was elevated after 80 days gestation, but with no further increases or decreases in late gestation, while AR protein increased significantly at the end of gestation. In hippocampus and brainstem AR mRNA was constant throughout the latter half of gestation, and AR protein was below the sensitivity of our Western blot assay. We conclude that the fetal brain and pituitary are target sites for circulating androgens or androgen precursors in fetal plasma, and we speculate that the increase in hypothalamic action of androgens immediately prior to birth might be integral to the timing of parturition.     

Structural differentiation of the epithelial cells of the testicular excurrent duct system of rats during postnatal development

The light and electron microscopic appearance of the various epithelial cells lining the efferent ducts and different regions of the epididymis were examined in rats on postnatal days 21, 39, 49, 56, and 90 to determine the role of androgens and/or spermatozoa, as well as other possible factors, on the structural differentiation of these cells. Five conclusions may be drawn from the observations made. First, on day 21 epithelial cells of all regions are structurally undifferentiated. Second, it was not until day 49 that nonciliated cells of the efferent ducts resembled those of adult animals, suggesting that more than one factor, such as androgens, testicular products, and/or spermatozoa, is needed for their full structural differentiation. Third, principal cells of the epididymis become structurally differentiated by day 39, i. e., these cells contained an elaborate Golgi apparatus, endoplasmic reticulum cisternae, and numerous 200–400 nm electron lucent secretory vesicles, as well as a full complement of endocytic organelles; this occurred in spite of the absence of spermatozoa in the epididymal lumen. The differentiation of these epididymal cells may be under the influence of androgens, which are known to be high at this time, but may also be due to specific secretions from Sertoli cells secreted directly into the efferent ducts. Fourth, clear cells of the cauda epididymidis are fully differentiated by day 39. The presence of degenerating germ cells in the lumen of the cauda epididymidis and various cellular debris, as well as high androgen levels, may be factors causing the differentiation of the cells of this region. Finally, clear cells of the corpus and cauda epididymidis only become fully differentiated by day 49, at a time when spermatozoa appear in the lumen, despite high levels of androgens at day 39; this observation indicates that the presence of spermatozoa in the lumen may be a necessary factor in causing their differentiation. Overall, these results suggest that a combination of different factors are necessary for the structural differentiation of the various epithelial cell types of the different regions of the epididymis. © 1992 Wiley-Liss, Inc.     

Androgenic down-regulation of urotensin II precursor, urotensin II-related peptide precursor and androgen receptor mRNA in the mouse spinal cord

We had previously shown that in rat spinal cord motoneurons urotensin II (UII) precursor mRNA was down-regulated by androgens. Very recently, a gene encoding the precursor of a UII analog, termed UII-related peptide (URP), has been identified. Using in situ hybridization, we studied the localization of UII and URP precursor as well as androgen receptor (AR) mRNA in the male mouse thoracic spinal cord. We also evaluated the androgenic regulation of the two peptide precursor and AR mRNA expression in the ventral horn of the mouse thoracic spinal cord. The results revealed that URP precursor mRNA was localized in motoneurons and that the vast majority of the motoneurons expressed both peptide precursor as well as AR mRNA. Seven-day castration induced an increase in UII and URP precursor and AR mRNA levels. Short term (3-24 h) administration of dihydrotestosterone to castrated animals restored the three protein mRNA levels to the levels observed in intact animals. These results suggest that in the ventral horn of the mouse spinal cord both UII and URP precursor and AR mRNA are expressed by the same neurons and that circulating androgens are exerting a down-regulation of the three protein mRNA expression, possibly by a direct action on motoneurons.     

Structural differentiation of the epithelial cells of the testicular excurrent duct system of rats during postnatal development.

The light and electron microscopic appearance of the various epithelial cells lining the efferent ducts and different regions of the epididymis were examined in rats on postnatal days 21, 39, 49, 56, and 90 to determine the role of androgens and/or spermatozoa, as well as other possible factors, on the structural differentiation of these cells. Five conclusions may be drawn from the observations made. First, on day 21 epithelial cells of all regions are structurally undifferentiated. Second, it was not until day 49 that nonciliated cells of the efferent ducts resembled those of adult animals, suggesting that more than one factor, such as androgens, testicular products, and/or spermatozoa, is needed for their full structural differentiation. Third, principal cells of the epididymis become structurally differentiated by day 39, i.e., these cells contained an elaborate Golgi apparatus, endoplasmic reticulum cisternae, and numerous 200-400 nm electron lucent secretory vesicles, as well as a full complement of endocytic organelles; this occurred in spite of the absence of spermatozoa in the epididymal lumen. The differentiation of these epididymal cells may be under the influence of androgens, which are known to be high at this time, but may also be due to specific secretions from Sertoli cells secreted directly into the efferent ducts. Fourth, clear cells of the cauda epididymidis are fully differentiated by day 39. The presence of degenerating germ cells in the lumen of the cauda epididymidis and various cellular debris, as well as high androgen levels, may be factors causing the differentiation of the cells of this region. Finally, clear cells of the corpus and cauda epididymidis only become fully differentiated by day 49, at a time when spermatozoa appear in the lumen, despite high levels of androgens at day 39; this observation indicates that the presence of spermatozoa in the lumen may be a necessary factor in causing their differentiation. Overall, these results suggest that a combination of different factors are necessary for the structural differentiation of the various epithelial cell types of the different regions of the epididymis.     

Androgen regulation of glycosidase secretion in epithelial cell cultures from human epididymis.

The human epididymis and its secretions actively promote sperm fertilizing capacity and provide protection for spermatozoa against harmful influences. Among epididymal secretions, glycosidases have been recently studied and associated with molecular changes on the sperm surface. In the present work, we studied the influence of different concentrations of testosterone, dihydrotestosterone and cyproterone acetate on the secretion of alpha-glucosidase, N-acetyl-glucosaminidase, beta-glucuronidase and alpha-mannosidase by isolated and cultured epithelial cells from human caput, corpus and cauda epididymides. Cell cultures were obtained from aggregates of isolated tubule fragments plated on extracellular matrix-covered multi-well plates. Activities of the glycosidases were measured in conditioned culture media and were higher in the distal regions of the epididymis. Testosterone and dihydrotestosterone significantly increase the enzyme secretion in a concentration-dependent manner. This increase was higher in corpus and/or cauda than in caput epididymis. Cyproterone acetate caused a dose-dependent decrease in glycosidase secretion in cultures from all epididymal regions. It is concluded that the secretion of epididymal glycosidases is regulated by androgen, being stimulated by dihydrotestosterone and testosterone and inhibited by the androgen antagonist cyproterone acetate.     

Aromatase immunolocalization in human ductuli efferentes and proximal ductus epididymis

Cytochrome P450 aromatase is a terminal enzyme that catalyses the conversion of androgens into oestrogens. This study investigated the immunohistochemical localization of aromatase in human efferent ductules and proximal ductus epididymis using a mouse anti‐human monoclonal P450arom IgG as primary antibody and a goat anti‐mouse biotinylated IgG as secondary antibody. A strong immunoreaction was observed in the epithelial cell cytoplasm of both ductuli efferentes and proximal ductus epididymis, whereas the smooth muscle cells were immunonegative in the two regions. The results show, for the first time in humans, that epithelial cells of ductuli efferentes and proximal caput epididymis express aromatase, suggesting that locally produced oestrogens may have a role in epididymal function.     

Gonadotropin-releasing hormone receptor mRNA expression in the ovaries of neonatal and adult rats

Recent studies have shown that gonadotropin-releasing hormone (GnRH) can exert various effects on the rat ovary by acting through its specific receptors. To determine the cell types responsive to the action of GnRH under physiological conditions in the ovary, distribution of the GnRH receptor mRNA was studied histologically by in situ hybridization in neonatal and adult rats. Expression of the luteinizing hormone receptor mRNA was also examined to judge the growing state of follicles and the corpora lutea. In neonatal rat ovaries, no significant GnRH receptor mRNA signal was detected until 5 days after birth. The expression was first observed at 10 days in the interstitial cells. At 15 days of age, the receptor mRNA was expressed in the granulosa cells of most preantral and early antral follicles, while no hybridization signal was detected in oocyte and theca cells. In adult cycling rats, GnRH receptor mRNA was detected mainly in the granulosa cells of most follicles and luteal cells. The granulosa cells of atretic follicles showed a very high level of the mRNA expression throughout their degenerating process. A strong hybridization signal was also detected in the mural granulosa cells of mature follicles. Newly formed (developing) corpora lutea exhibited signals with moderate intensity in the luteal cells, and the older ones showed weaker signals. The finding that the initial expression of GnRH receptor mRNA was seen in the interstitial cells of neonatal ovaries implies an unknown function of the ovarian GnRH receptor in ovarian development. The high level expression of GnRH receptor mRNA in atretic and mature follicles supports the putative roles of GnRH in the induction of follicular atresia and ovulation in rat ovaries.     

雄性大鼠心肌雄激素受体及其mRNA的表达

目的观察雄激素受体(AR)蛋白及其mRNA在大鼠心肌的表达。方法采用免疫组织化学方法和原位杂交的方法观察成年(3月龄)Wistar大鼠心肌中AR阳性神经元的存在及其表达。结果大鼠心肌中存在AR阳性神经元和ARmRNA阳性神经元。结论为AR在心脏的存在提供形态学依据,并在基因水平证实部分心肌细胞中存在雄激素受体的结合位点,提示心肌细胞可能受雄激素影响。