Ornithine decarboxylase activity as a marker of androgen and antiandrogen action in the rat epididymis

After castration, there was a marked decrease in serum androgen concentration at 6 h, and a dramatic inhibition of ornithine decarboxylase (ODC) at 12 h. Administration of testosterone propionate to castrated rats at a dose of 0.05 mg/animal restored ODC activity to the normal value. However, no change was observed when intact rats were treated with testosterone even at a 40-fold higher dose, indicating that endogenous androgens present in intact rats are far in excess for maintenance of maximal levels of activity. Administration of the antiandrogen flutamide to intact rats caused a moderate decrease in epididymal weight, whereas this effect was more pronounced in castrated, androgen-treated rats. In the latter, the effect of flutamide was significant at the lowest dose used (0.5 mg/day). ODC activity was significantly decreased by flutamide treatment of intact rats, but even at the highest dose used (10 mg/day) only a 39% inhibition was observed. In flutamide-treated rats, LH concentrations were markedly increased, as were serum and epididymal androgens. In androgen-treated castrated rats, flutamide caused epididymal ODC to fall to undetectable values. These results show that: (1) androgens are essential for the maintenance of ODC activity in the epididymis; (2) epididymal ODC activity is maximally stimulated by endogenous androgens, at least in the pubertal rat; (3) the apparent potency of flutamide is substantially lowered by an increase in epididymal androgens. We suggest that ODC is a sensitive marker of the action of androgens and antiandrogens in the epididymis.     

Developmental changes in and hormonal regulation of estrogen and androgen receptors present in the rabbit epididymis

Both androgen and estrogen receptors (AR and ER) are present in the rabbit epididymis. We have used the sucrose gradient method to examine receptor sedimentation properties, receptor concentration, and distribution of receptors among the caput, corpus, and cauda of the epididymis to determine changes that occur in these parameters as the animals age. The 9S form of the ER is present in all three epididymal segments of the immature rabbit, with the highest concentration occurring in the cauda. The 8.2S form of the AR is also present in all three segments of the immature epididymis, with the highest concentration occurring in the caput. Short-term castration (3 days) leads to an increase in the amount of both AR and ER detected. ER are present in all segments of the immature epididymis at higher concentrations than AR. The functional 9S form of the ER disappears as the animals mature, the result of a tissue-specific protease that our laboratory previously has shown proteolyzes ER to a non-DNA-binding 3.8S form. Long-term castration (3 mo) of adult rabbits results in the reappearance of the 9S form of the ER in all segments of the epididymis. The reappearance of the 9S form of the ER is also seen in animals castrated for 1 mo, but not in those castrated for 2 wk. Administration of testosterone once daily for 2 wk to adult animals castrated for 6 wk results in the disappearance of the 9S form of the ER and the reappearance of the 3.8S form, suggesting that the tissue-specific protease is androgen-dependent. In this way, circulating androgens may play a role in regulating the concentration and form of the ER in the rabbit epididymis. There is little change in the concentration or distribution of AR in the epididymis of adult rabbits castrated for 3 mo as compared to those castrated for 3 days. This implies that circulating androgens are not required for maintenance of AR in the epididymis. Our data demonstrate that there are temporal differences in the presence and concentration of ER and AR in the epididymis and suggest that there is a differential, age-dependent regulation of the development and function of the epididymis by androgens and estrogens.     

Metabolism of 3H-testosterone in epididymis & accessory glands of reproduction in the castrate hamster Mesocricetus auratus

The metabolism of tritiated-testosterone in epididymis and accessory glands of reproduction was studied in the castrate hamster, Mesocricetus auratus. The amount of tritium accumulating in the epididymis was similar to that in the accessory glands 60 minutes postinjection but was significantly higher (p .02-p .001) at 150 minutes. In all accessory organs the rate of tritiated testosterone was slow; marked quantities of testosterone and androstanediol were present but the accumulation of dihydrotestosterone (DHT) was relatively minimal at both time intervals studied. These results may indicate a simultaneous requirement of testosterone and androstanediol to mediate the action of androgens in the hamster while DHT may be of secondary importance.     

Hormonal status of male reproductive system: androgens and estrogens in the testis and epididymis. In vivo and in vitro approaches

The purpose of this article was to summarize our results on the role of androgens and estrogens in human, rodent and equine testes and epididymides, in both, physiological and patological conditions, obtained in the space of the Solicited Project (084/PO6/2002) financially supported by the State Committee for Scientific Research during the last three years. Testosterone produced by Leydig cells of the testes is clearly the major androgen in the circulation of men and adult males of most mammalian species. However, androgen metabolites make up a significant fraction of total circulating steroids. Moreover, androgen metabolism may proceed to amplify the action of testosterone through its conversion to dihydrotestosterone (DHT) or its aromatization to estradiol. The distribution of androgen and estrogen receptors (ARs and ERs) within male reproductive tissues is important because of their crucial role in mediating androgen and/or estrogen action. Attempts were undertaken to discuss not only the role of aromatase and ERs in mediating the action of estrogens in the male, but also the importance of DHT in hormonal regulation of the epididymis. In the latter, alterations caused by finasteride treatment and lead-induced oxidative stress are described. Male reproductive function of the testis and epididymis reflected by the alterations in enzymatic activity, distribution of steroid hormone receptors, differences in steroid hormone levels and altered gene expression of antioxidant enzymes are also discussed.     

Regulation of seminiferous tubular function by FSH and androgen.

Seminiferous tubules contain a cytoplasmic androgen receptor similar to the receptors in the epididymis and ventral prostate. The presence of a cytoplasmic receptor indicates that androgens maintain spermatogenesis by a direct action on certain types of cells within the seminiferous tubule. The Sertoli cell appears to be one of the cell types containing androgen receptors and the receptor might also be present in spermatogonia, primary spermatocytes, or peritubular cells. The Sertoli cell is stimulated by FSH to produce an androgen-binding protein which may serve to increase the accumulation of androgen in the seminiferous epithelium and make it available for binding by intracellular androgen receptors. This may be a way in which FSH enhances the action of androgen on spermatogenesis. Androgens act on the Sertoli cell to increase its response to FSH. This action of androgens on the Sertoli cell results in increased production of androgen-binding protein and may enhance the production of other substances which exert trophic effects on spermatogenesis.     

Immunolocalization of estrogen and androgen receptors and steroid concentrations in the stallion epididymis

The presence of steroids and their receptors throughout development, specifically androgen receptor (AR), estrogen receptor alpha (ERalpha) and estrogen receptor beta (ERbeta), in the epididymis of a high estrogen producing species like the stallion has not been determined. Epididymal and testicular samples were collected for analysis of testosterone and estradiol-17beta (E(2)) concentrations and for immunolocalization of AR, ERalpha and ERbeta. The concentration of testosterone in the testis and epididymis were not different among age groups (P>0.05). AR was localized in the principal cells of the caput, corpus and cauda in all four age groups. This lack of change in testosterone concentration and receptor localization suggests that testosterone is important for both development and maintenance of epididymal function. There was an age-related increase in E(2) concentrations in all regions of the epididymis (P<0.05), suggesting that E(2) is also important for adult function. ERbeta was localized in the principal cells of the caput, corpus and cauda in all four age groups, but the localization of ERalpha was regional and age dependent. In peri-pubertal animals, ERalpha immunostaining was most prominent and estradiol was similarly present in all three epididymal regions; this suggests that estradiol also plays a key role in the maturation of the stallion epididymis during the pubertal transition when sperm first arrive in the epididymis. In conclusion, these results suggest that the stallion epididymis is regulated by both androgens and estrogens throughout development and that estradiol is more important to epididymal function in the stallion than previously believed.     

Modulation of the onset of postnatal development of H(+)-ATPase-rich cells by steroid hormones in rat epididymis

Vacuolar type H(+)-ATPase is involved in lumenal acidification of the epididymis. This protein is highly expressed in narrow and clear cells where it is located in the apical pole, and it contributes to proton secretion into the lumen. We have previously shown that in rats, epididymal cells rich in H(+)ATPase appear during postnatal development and reach maximal numbers at 3-4 wk of age. The factors that regulate the appearance of these cells have not been investigated, but androgens, estrogens, or both may be involved. This study examined whether neonatal administration of estrogens (diethylstilbestrol [DES] or ethinyl estradiol) or an antiandrogen (flutamide), or the suppression of androgen production via administration of a GnRH antagonist (GnRHa), was able to alter the appearance of cells rich in H(+)-ATPase in the rat epididymis when assessed at age 25 days. Surprisingly, all of these treatments were able to significantly reduce the number of H(+)-ATPase positive cells; this was determined by immunofluorescence and confirmed by Western blotting. In contrast, neonatal coadministration of DES and testosterone maintained the expression of H(+)-ATPase in the epididymis at Day 25 despite the high level of concomitant estrogen exposure. These findings indicate that androgens, acting via the androgen receptor, are essential for the normal development of epididymal cells rich in H(+)-ATPase, and that treatments that interfere directly or indirectly with androgen production (GnRHa, DES) or action (flutamide, DES) will result in reduced expression of H(+)-ATPase. Our findings do not exclude the possibility that estrogens can directly suppress the postnatal development of cells in the epididymis that are rich in H(+)-ATPase, but if this is the case, this suppression can be prevented by testosterone administration.     

Maturing the sperm: unique mechanisms for modifying integral proteins in the sperm plasma membrane

The epididymis has been understudied, in part due to its cancer resistance and the development of effective technologies for sperm injection and in vitro fertilization. However, it is worthy of study because--absent advanced reproductive technology--its proper function is essential for conceiving children: sperm leaving the testis are immature and nonfertile. Epididymal functions can be divided into several general categories (1) concentration of sperm; (2) functional maturation; (3) storage in a quiescent state until ejaculation; (4) removal of degenerating sperm; (5) provision of appropriate conditions for survival; (6) transport by the myoid cells; (7) protection; (8) maintenance of the blood epididymal barrier. In the past decade investigators have focused on those maturational changes of the integral proteins of the sperm plasma membrane which are directly related to sperm-ova interactions. It has traditionally been thought that changes in the sperm plasma membrane proteins were limited to simple binding or removal of proteins or interactions with the proteases, glycosylases and glycotransferases present. However, the epididymis can also release secretory products in bulk through apical blebs and inject integral membrane proteins with epididymosomes which fuse with the plasma membrane. The epididymis also activates and cleaves enzymes present on the sperm surface (e.g., germ cell angiotensin converting enzyme), thus enabling them to modify proteins on the sperm membrane. Aside from the need to understand epididymal function relative to the sperm, basic science on epididymal physiology is warranted because it may help us understand the functioning of androgens, protection of tissues from oxidative damage, and resistance to cancer and benign hyperplasic growth.     

Regional differences in the metabolism of testosterone in vitro in the epididymis & ductus deferens of the adult rhesus monkey Macaca mulatta.

Regional differences in the metabolism of testosterone in vitro in the epididymis (1.5 cm segments) and ductus deferens (2 cm segments) were investigated in the adult rhesus monkey, Macaca mulatta. The conversion of tritiated testosterone to its 5alpha-reduced derivatives increased from the proximal to the distal regions of the epididymis. The total amount of 5alpha-reduced products in the subsequent segments of the epididymis was highest in the intact monkey and on the intact side of the unilaterally castrated monkey and was followed in decreasing order by the castrated side of the hemiscastrate and least in the bilateral castrate. Hormonal requirements for maintenance of the biological functions of the epididymis and maturation of spermatozoa in the epididymis are discussed.     

Physiology of the epididymis and spermatozoa

The epididymis is an ideal extragonadal target site to inhibit fertility in the male. Synthesis and secretion of constituents like sialic acids, protein and glycerylphosphoryl choline by the epididymal epithelium under androgen control provide an ideal fluid environment for sperm maturation. An optimal level of sialic acid secretion by the epididymal epithelium is needed to maintain functional integrity of sperm. The existence of specific androgen receptors in the epididymis and spermatozoa are related to their ability to metabolise androgens.     

Characterization of hormonally regulated secretory proteins from the caput epididymidis of the rabbit.

1. The incorporation of [35S]methionine into protein was investigated in tissue minces from different regions of the rabbit epididymis incubated in vitro. Rates of synthesis were in the order: epididymal regions 2-5 greater than region 7 greater than region 6 greater than region 1 greater than region 8 greater than ductus deferens greater than ductuli efferentes. 2. Separation of labelled proteins on polyacrylamide gels containing sodium dodecyl sulphate followed by fluorography revealed that one protein (mol.wt. approx. 90 000) was characteristic of region 1, four proteins (one of mol.wt. 54 000 and three of mol.wt. 20 000) were synthesized principally in regions 2-5, and one protein (mol.wt. 22 500) was produced mainly in regions 6, 7 and 8. 3. Castration for 14 days decreased incorporation of [35S]methionine into total protein to less than 10% of that in controls in all regions of the epididymis. However, testosterone treatment for a further period of 14 days restored protein synthesis to normal values in regions 6, 7 and 8, but not in region 1 or regions 2-5. In regions 2-5 the synthesis of three proteins of mol.wt. 20 000 declined after castration, but was not stimulated by exogenous testosterone. Since the 20 000-mol.wt. proteins were major tissue proteins, accounting for 16-25% of the total synthesized, they were used as markers for investigating hormone action in the epididymis. 4. Castration followed immediately by testosterone treatment or ligation of the ductuli efferentes resulted in a decrease in their synthesis, suggesting that they are partially dependent on factors in testicular fluid. Purification and characterization showed them to be acidic glycoproteins with a number of biochemical and immunological properties in common. 5. It is suggested that there is a synergistic action between blood androgens and factors in testicular fluid in regulating protein synthesis in the proximal regions of the rabbit epididymis.     

Effects of a highly purified antiserum to FSH on testicular function in immature rats

Effects of highly purified antiserum (AS) to follicle stimulating hormone (FSH) on testicular function was studied in immature rats. Treatment with FSHAS for 10 days, from 25-34, decreased weights of the testis (p .001) and increased weights of the epididymis (p .05). Numbers of the cell types in the seminiferous epithelium, particularly Type A spermatogonia pachytene spermatocytes and spermatids, were markedly reduced, possibly due to: 1) decreased division of the initial stem cells, 2) impairment of division of Type B spermatogonia and their transformation to pachytene spermatocytes, and 3) desquamation and degeneration of pachytene spermatocytes and spermatids. FSHAS also affected the sertoli cell function which was reflected in the decreased binding of androgens to supernatant fraction of the testis and epididymides. Treatment with luteinizing hormone-AS for 5 days did not affect testicular function but the binding of androgens to the supernatants of the caput and cauda epididymides and ventral prostate was significantly reduced (p .001). These data indicate that FSH is necessary for the maintenance of the cellular integrity of the seminiferous epithelium during the completion of the 1st wave of spermatogenesis.     

Development of the normal XY male and sex-reversed XXSxr pseudomale mouse epididymis

XXSxr pseudomale mice (chromosomally XX animals "sex-reversed" by the Sxr factor) develop testes and produce sufficient androgens for masculinization as assessed at the macroscopic level. However, adult XXSxr pseudomales lack the epididymal initial segment (I.S.). In this study prenatal and postnatal epididymal development was examined histologically and biochemically, and it was found that XXSxr pseudomales are indistinguishable from normal XY males up to day 21 of postnatal life. By 25 days postnatally, before the onset of the pubertal androgen surge, the I.S. precursor is evident in normal animals but absent in XXSxr mutants. No major abnormalities were seen in other segments of the XXSxr epididymis. Our data suggest that androgen levels in testis and epididymis are not higher in normal XY males than in XXSxr pseudomale mice of the same age. Inadequate availability of androgens at the target site is unlikely to be the cause of the epididymal abnormality in XXSxr pseudomale mice.     

Regional differences in the testosterone to dihydrotestosterone ratio in the epididymis and vas deferens of adult mice

The concentrations of testosterone and dihydrotestosterone (DHT) were measured in the testis and in different segments of the epididymis and vas deferens of adult mice. There were marked regional variations in the concentrations of testosterone and DHT from the testis to the caudal part of the vas deferens. In the testis, testosterone was the predominant androgen (364 +/- 90 ng/g) while DHT was weakly represented (8 +/- 2 ng/g). Qualitative and quantitative changes occurred in epididymis: DHT was the main steroid in the caput (29.3 +/- 2.7 ng/g) and corpus (33.1 +/- 4.4 ng/g) while testosterone and DHT were in similar quantities in the cauda (18.6 +/- 2.6 and 19.0 +/- 2.7 ng/g, respectively). The proximal region of the vas deferens contained higher amounts (71.4 +/- 8.0 ng/g) of androgens (testosterone + DHT) than did the caput epididymidis (39.1 +/- 3.3 ng/g). Testosterone was the predominant androgen in each part of the vas deferens and its concentrations decreased from the proximal (64.5 +/- 7.5 ng/g) to the caudal (26.9 +/- 4.3 ng/g) region. Castration and section of the efferent ducts of the testis showed that the epididymis received testosterone essentially via the blood supply and that epididymal DHT was produced locally from circulating testosterone.     

Epididymal protease inhibitor (EPPIN) is differentially expressed in the male rat reproductive tract and immunolocalized in maturing spermatozoa

EPPIN (epididymal protease inhibitor; SPINLW1), an antimicrobial cysteine‐rich protein containing both Kunitz and whey acidic protein (WAP)‐type four disulfide core protease inhibitor consensus sequences, is a target for male contraception because of its critical role in sperm motility. Here, we characterized EPPIN's expression and cellular distribution in rat tissues and its in vivo regulation by androgens in the epididymis. EPPIN (mRNA and protein) was abundantly expressed in the rat testis and epididymis; we also found that the vas deferens, seminal vesicles, and brain were novel sites of EPPIN expression. PCR studies demonstrated that in addition to Sertoli cells, spermatogenic cells expressed Eppin mRNA. EPPIN was immunolocalized in Sertoli cells and spermatogenic cells (pachytene spermatocytes and round and elongated spermatids) and in epithelial cells and spermatozoa from efferent ductules and epididymis. EPPIN staining was observed on the middle and principal pieces of the flagellum of testicular spermatozoa. Epididymal spermatozoa had more intense EPPIN staining on the flagellum, and the EPPIN staining became apparent on the head and neck regions. This suggested that the EPPIN found on maturing spermatozoa was secreted primarily by the epithelial cells of the epididymis. Surgical castration down‐regulated EPPIN expression levels (mRNA and protein) in the caput and cauda epididymis, an effect reversed by testosterone replacement. Altogether, our data suggested that EPPIN expression in rats is more widespread than in humans and mice, and is androgen‐dependent in the epididymis. This species could be used as an experimental model to further study EPPIN's role in male fertility. Mol. Reprod. Dev. 79: 832–842, 2012. © 2012 Wiley Periodicals, Inc.