5alpha-reductase isoenzymes 1 and 2 in the rat testis during postnatal development

The pubertal initiation of spermatogenesis is reliant on androgens, and during this time, 5alpha-reduced androgens such as dihydrotestosterone (DHT) are the predominant androgens in the testis. Two 5alpha-reductase (5alphaR) isoenzymes (5alphaR1 and 5alphaR2) have been identified, which catalyze the conversion of testosterone to the more potent androgen DHT. The present study aimed to investigate the developmental pattern of 5alphaR isoenzymes and their relationship to the production of 5alpha-reduced androgens in the postnatal rat testis. Both 5alphaR1 and 5alphaR2 isoenzyme mRNAs were measured by real-time polymerase chain reaction, isoenzyme activity levels by specific assays, and testicular androgens by radioimmunoassay after high-performance liquid chromatographic separation. Both 5alphaR1 and 5alphaR2 mRNAs and activity levels were low in the 10-day-old (prepubertal) testis, peaked between Days 20 and 40 during puberty, and then declined to low levels at 60-160 days of age. The developmental pattern of both 5alphaR isoenzyme activity levels was mirrored by the testicular production of 5alpha-reduced metabolites. Although 5alphaR1 was greater than 5alphaR2 at all ages, it is likely, given the substrate preferences of the two, that both isoenzymes contribute to the pubertal peak of 5alpha-reduced androgen biosynthesis. The peak in 5alphaR isoenzymes and 5alpha-reduced metabolite production coincided with the first wave of spermatogenesis in the rat, suggesting a role for 5alpha-reduced metabolites in the initiation of spermatogenesis. This was explored by acute administration of a 5alphaR inhibitor (L685,273) to immature rats. The L685,273 markedly suppressed testicular 5alphaR activity during puberty by 75%-86%. However, a marked increase was observed in testicular testosterone levels (in the absence of changes in LH), and no decrease was observed in the absolute levels of 5alpha-reduced metabolites. Therefore, whether the formation of DHT in the presence of low testosterone levels in the pubertal testis is required for the initiation of spermatogenesis cannot be tested using 5alphaR inhibitors. We conclude that both 5alphaR1 and 5alphaR2 isoenzymes are involved in the peak of 5alpha-reduced androgen biosynthesis in the testis during the pubertal initiation of spermatogenesis.     

Sexual differentiation of the rodent hypothalamus: hormonal and environmental influences

Brain sexual differentiation is a complex developmental phenomenon influenced by the genetic background, sex hormone secretions and environmental inputs, including pollution. The main hormonal drive to masculinize and defeminize the rodent brain is testosterone secreted by the testis. The hormone does not influence sex brain differentiation only in its native configuration, but it mostly needs local conversion into active metabolites (estradiol and DHT) through the action of specific enzymatic systems: the aromatase and 5alpha-reductase (5alpha-R), respectively. This allows the hormone to control target cell gene expression either through the estrogen (ER) or the androgen (AR) receptors. The developmental profile of testosterone metabolizing enzymes, different in the two sexes, is therefore of the utmost importance in affecting the bioavailability of the steroids active in brain differentiation. Widely diffused pollutants, like polychlorinated biphenyls (PCBs) are able to affect the production and/or action of testosterone metabolites, exerting detrimental influences on reproduction and sex behavior. The main studies performed in our and other laboratories concerning the pattern of expression and the control of the enzymatic systems involved in brain androgen action and metabolism are shortly reviewed. Some recent data on the influence exerted by PCBs on these metabolic systems are also reported.     

Profiling of Androgen Response in Rainbow Trout Pubertal Testis: Relevance to Male Gonad Development and Spermatogenesis

The capacity of testicular somatic cells to promote and sustain germ cell differentiation is largely regulated by sexual steroids and notably androgens. In fish species the importance of androgens is emphasized by their ability to induce sex reversal of the developing fries and to trigger spermatogenesis. Here we studied the influence of androgens on testicular gene expression in trout testis using microarrays. Following treatment of immature males with physiological doses of testosterone or 11-ketotestosterone, 418 genes that exhibit changes in expression were identified. Interestingly, the activity of testosterone appeared stronger than that of 11-ketotestosterone. Expression profiles of responsive genes throughout testis development and in isolated germ cells confirmed androgens to mainly affect gene expression in somatic cells. Furthermore, specific clusters of genes that exhibit regulation coincidently with changes in the natural circulating levels of androgens during the reproductive cycle were highlighted, reinforcing the physiological significance of these data. Among somatic genes, a phylogenetic footprinting study identified putative androgen response elements within the proximal promoter regions of 42 potential direct androgen target genes. Finally, androgens were also found to alter the germ line towards meiotic expression profiles, supporting the hypothesis of a role for the somatic responsive genes in driving germ cell fate. This study significantly increases our understanding of molecular pathways regulated by androgens in vertebrates. The highly cyclic testicular development in trout together with functions associated with regulated genes reveal potential mechanisms for androgen actions in tubule formation, steroid production, germ cell development and sperm secretion.     

Molecular aspects of brain aromatase cytochrome P450

Aromatase cytochrome P450 (P450arom) enzyme activity catalyses the conversion of androgens to estrogens in specific brain areas. During central nervous system (CNS) development local estrogen formation influences sexual differentiation of neural structures, regulates neuroendocrine functions and sexual behavior. A proposed mechanism (and re-examination) of the sexual differentiation of the rodent brain is presented. The metabolic pathway of androgen metabolism by P450arom was characterized in the medial basal hypothalamic (MBH) tissue from male rats during various prenatal and postnatal developmental intervals. The P450arom enzyme activity was determined using a saturating concentration of [³H]testosterone as the substrate, and the rates were quantified by scintillation counting. The MBH P450arom activity was highest during prenatal development (i.e. 3–6 pmol/h/mg protein), declined to moderate levels in newborns and infantile animals (approximately 1 pmol/h/mg protein) and then continued to decline to low activity rates in adult animals (approximately 80 fmol/h/mg protein). Regulation of the P450arom gene was characterized by a series of molecular biology studies where the controlling mechanism for brain P450arom was determined in MBH and amygdaloid tissue sites. Evidence for brain P450arom-specific mRNA in perinatal rats is presented as well as comparisons with rat ovary, a rat Leydig tumor cell line (R2C) and human fetal brain P450arom. Specifically, P450arom gene expression is driven in perinatal rat brain tissue by a different promoter compared to rat ovarian tissue or a R2C cell line, whereas human fetal brain tissue utilizes an almost identical promoter segment to that observed in the rodent. These findings provide an insight into the regulation of brain P450arom gene expression and suggest that there is an additional level of control for the expression of this gene during perinatal development. However, further study is necessary to understand the molecular basis of this complex developmental pattern of brain P450arom expression.     

Brain androgen-inducible aromatase is critical for adolescent organization of environment-specific social interaction in male rats

Previous observations have indicated that specific behavioral responses to anxiogenic stimuli emerge over adolescent development in male rats and that gonadal androgens during puberty are essential for this emergence. The objective of the current study was to evaluate mechanisms via which androgens might be organizing the brain during adolescence for appropriate mature adaptive responses. Male rats were exposed to fadrozole (an aromatase inhibitor, 5 mg/kg), flutamide (an androgen receptor antagonist, 10 mg/kg), or MK-434 (a 5 alpha-reductase inhibitor, 10 mg/kg) from day 29 to 60 and tested for environment-specific social interaction (SI) at 60 days of age. The emergence of adult-typical SI was impaired by exposure to the aromatase inhibitor and to the antiandrogen, whereas exposure to the 5 alpha-reductase inhibitor was without effect. Peripheral indices of drug effects indicated that the respective mechanisms had been altered by the different compounds. These results suggest that testosterone induction of aromatase is critical for the organization of mature SI behavior in male rats over adolescent development.     

Estrogènes et spermatozoïdes

Aromatase is the terminal enzyme responsible for estrogen biosynthesis; it is present in the endoplasmic reticulum membrane of steroidogenic cells in vertebrates. This enzyme functions with the ubiquitous reductase as the electron donor. The aromatase gene is unique and its expression is regulated in a tissue and more precisely in a cell-specific fashion via the alternative use of several promoters located in the first exons. This enzymatic complex is generally involved in development, reproduction, sexual differentiation and behaviour, but also in bone and lipid metabolism, brain functions and diseases such as breast and testicular tumors. The aromatase gene expression and its transduction in a fully active protein in testicular somatic cells and germ cells together with the widespread distribution of estrogen receptors (ERα & β) in the testis and the genital tract of the male, are clearly in favor of a physiological role for estrogens in the spermatogenesis processings especialy in sperm maturation. Therefore, we begin to understand the physiopathological roles of the estrogens in males indeed, the aromatase deficiency is associated, with severe bone maturation problems and sterility in man. Conversely, it is also obvious that estrogens in excess are responsible of the impaired spermatogenesis. These female hormones (or the ratio androgens/estrogens) do play a physiological role in the development and maintenance of male gonadal functions and obviously, several steps are concerned especially the sperm production and maturation.     

Development of Fetal Testicular Cells in Androgen Receptor Deficient Mice

During mammalian development, androgens produced by the fetal testis are the most important hormones controlling the masculinization of the reproductive tract and the genitalia. New findings show that the male germ line is the most sensitive to anti-androgenic endocrine disruptors during the embryonic period. In a recent study, we reported that endogenous androgens physiologically control germ cell growth in the male mouse fetus during early fetal life. In the present study, we extended this result by showing the presence of a functional androgen receptor in the gonocytes in the latter part of the fetal life. We also studied the effect of androgens on the development of the somatic testicular cells using the Tfm mice which carry a naturally inactivating mutation of the androgen receptor. Fetal Leydig cell are largely independent of endogenous androgens during fetal development whereas fetal Sertoli cell number is decreased following a default of peritubular myoid cells differenciation. They also point to the gonocyte as a special target for androgens during the embryonic period and indicate a novel mechanism of androgen action on gonocytes. Elucidation of this new pathway in the fetal testis will clarify not only fetal testis physiology but also the effects of environmental anti-androgens that act during fetal life and open new perspectives for future investigations into the sensitivity of fetal germ cell to androgens.     

Androgen metabolism in the juvenile oscine forebrain: a cross-species analysis at neural sites implicated in memory function.

Juvenile songbirds are useful models for studying the neural bases of memory. Memory-reliant behaviors demonstrated at this stage include song learning (most songbirds) and food caching (food-storing songbirds). Sex steroids are implicated in the modulation of memory processes in several vertebrates. The songbird forebrain expresses aromatase, 5alpha-reductase and 5beta-reductase, enzymes which convert testosterone to estradiol, 5alpha-, and 5beta-dihydrotestosterone, respectively. To explore the role of local androgen metabolism on memory processes, we documented the activities of these enzymes in the anterior neostriatum (NAN), caudomedial neostriatum (NCM), and hippocampus (HP) of four species of juvenile songbird, two of which are food storers. Areas were dissected, homogenized, and provided with radiolabeled substrate; and formed estrogens, and 5alpha- and 5beta-reduced androgens were measured. In the NAN, 5beta-reductase was the predominant enzyme, suggesting that local inactivation of testosterone may preserve the sensitive period of song acquisition. In the NCM, estrogens were formed in abundance despite high 5beta-reductase, suggesting that locally high estrogen synthesis may play a role in processes of song perception. In the HP, both estrogens and 5alpha reduced androgens were formed, suggesting that HP function may be modulated by both estrogens and androgens. Finally, a derived measure of steroid-differential reveals that food-storing songbirds differ from nonstorers in the steroidal milleiu within the HP, but not in the NAN or NCM. Thus, distinct loci within the juvenile songbird forebrain are exposed to different patterns of androgen metabolites. This local conversion may play a role in the neuroendocrine modulation of memory in these birds.     

Sexual differentiation of the zebra finch song system parallels genetic, not gonadal, sex.

Mechanisms regulating sexual differentiation of the zebra finch song system present an intriguing puzzle. Masculine development of brain regions and behavior can be induced in genetic females by posthatching estradiol treatment. That result is consistent with the hypothesis that estradiol, converted within the brain from testicular androgen via the aromatase enzyme, masculinizes neural structure and function. In contrast, treatment during specific stages of development with the aromatase inhibitor Fadrozole has not prevented masculine development, and the presence of testicular tissue in genetic females did not induce masculine organization of neuroanatomy or singing behavior. Fadrozole treatments in those previous studies were limited, however, and most genetic females had both ovarian and testicular tissue. The present experiments were designed to provide increased aromatase inhibition and to reliably produce genetic females with only testicular tissue. Eggs received a single injection at a later age or with higher doses of Fadrozole than had been used previously. Some embryos were exposed to Fadrozole more frequently by either injecting eggs on 2 days of development or dipping them for 10-12 days in Fadrozole. Finally, in some individuals from Fadrozole-treated eggs, the left gonad was removed, leaving each genetic male and female with a single right testis. None of these treatments significantly affected development of the song system compared to appropriate control groups. These results suggest that sexual differentiation of the zebra finch song system is not regulated by embryonic aromatase activity or by gonadal secretions and instead involves events that need not be mediated by steroid hormones.     

The role of cell-cell interactions in androgen action

Androgen-regulated mesenchymal-epithelial interactions play an important role during embryonic development of the male urogenital tractus. Studies on the effects of androgens on cultured testicular cells derived from the immature rat testis indicate that, even during postnatal life, similar interactions may be instrumental for normal androgen action. Androgen receptors are found in epithelial Sertoli cells as well as in mesenchymal peritubular cells. The effects of androgens on isolated Sertoli cells, however, are limited. Coculture with peritubular cells increases the sensitivity and/or the responsiveness of a number of Sertoli cell parameters (transferrin, ABP, aromatase activity) to androgens. This effect is at least in part mediated by the secretion of one or more diffusible factors (P-Mod-S) by the peritubular cells. We investigated whether such indirect effects of androgens, relying on mesenchymal—epithelial interactions are also observed in other androgen target tissues. To this end stromal cells were isolated and cultured from the immature rat ventral prostate and the production of factors with P-Mod-S activity was monitored using Sertoli cells as the test system.Under coculuture conditions these stromal cells stimulate Sertoli cell transferrin secretion in an androgen-regulated fashion, exactly as peritubular cells. This stimulatory effect is related in part to the collaborative (and androgen-independent) deposition of an extracellular matrix and in part to the secretion of an androgen-regulated diffusible mediator. This mediator has the same physicochemical characteristics as P-Mod-S and it affects other Sertoli cell parameters (ABP, aromatase activity, inhibin, cGMP) in the same way as P-Mod-S. Cultured stromal and peritubular cells look very similar and stain positive after immunostaining for -smooth muscle isoactin. Tissue sections suggest that these cells may be derived from myoid peritubular cells in the testis and similar periacinar cells in the prostate. The hypothesis is advanced that P-Mod-S may be a more universal mediator of indirect effects of androgens in diverse target tissues and that this factor is derived from myoid cells closely associated with the epithelial component.     

Aromatase pathway mediates sex change in each direction

The enzyme aromatase controls the androgen/oestrogen ratio by catalysing the irreversible conversion of testosterone into oestradiol (E2). Therefore, the regulation of E2 synthesis by aromatase is thought to be critical in sexual development and differentiation. Here, we demonstrate for the first time that experimental manipulation of E2 levels via the aromatase pathway induces adult sex change in each direction in a hermaphroditic fish that naturally exhibits bidirectional sex change. Our results demonstrate that a single enzymatic pathway can regulate both female and male sexual differentiation, and that aromatase may be the key enzyme that transduces environmental, including social, cues to functional sex differentiation in species with environmental sex determination.     

Brain aromatase in control versus castrated Norway Brown, Sprague-Dawley and Wistar adult rats.

Brain aromatase cytochrome P450 converts androgens to estrogens that play a critical role in the development of sexually dimorphic neural structures, the modulation of neuroendocrine function(s), and the regulation of sexual behavior. We characterized the influence of surgical castration on brain aromatase in Norway Brown and Wistar adult rats and compared their responses to Sprague-Dawley rats that were surgically or biochemically castrated (with flutamide, a known androgen receptor blocker). Aromata enzyme activity was measured by the tritiated water release assay in the medial basal hypothalmus/preoptic area (MBH/POA) and amygdala brain regions. The present results demonstrate that independent of the rat strain examined, MBH/POA aromatase is regulated by androgens (in Sprague-Dawley, Norway Brown and Wistar males). However, intact Wistar animals displayed significantly higher MBH/POA aromatase levels compared to Sprague-Dawley control values. Conversely, in the amygdala region, there was an apparent lack of androgen hormone action upon aromatase enzyme activity in some of the rat strains tested. The importance of brain aromatase regulating estrogen biosynthesis and influencing brain development and function is covered.     

Effect of Testosterone on Neuronal Morphology and Neuritic Growth of Fetal Lamb Hypothalamus-Preoptic Area and Cerebral Cortex in Primary Culture

Testosterone plays an essential role in sexual differentiation of the male sheep brain. The ovine sexually dimorphic nucleus (oSDN), is 2 to 3 times larger in males than in females, and this sex difference is under the control of testosterone. The effect of testosterone on oSDN volume may result from enhanced expansion of soma areas and/or dendritic fields. To test this hypothesis, cells derived from the hypothalamus-preoptic area (HPOA) and cerebral cortex (CTX) of lamb fetuses were grown in primary culture to examine the direct morphological effects of testosterone on these cellular components. We found that within two days of plating, neurons derived from both the HPOA and CTX extend neuritic processes and express androgen receptors and aromatase immunoreactivity. Both treated and control neurites continue to grow and branch with increasing time in culture. Treatment with testosterone (10 nM) for 3 days significantly (P < 0.05) increased both total neurite outgrowth (35%) and soma size (8%) in the HPOA and outgrowth (21%) and number of branch points (33%) in the CTX. These findings indicate that testosterone-induced somal enlargement and neurite outgrowth in fetal lamb neurons may contribute to the development of a fully masculine sheep brain.     

The ontogeny of the urogenital system of the spotted hyena (Crocuta crocuta Erxleben)

Studies were conducted to elucidate the importance of androgen-mediated induction of the extreme masculinization of the external genitalia in female spotted hyenas. Phallic size and shape; androgen receptor (AR) and alpha-actin expression; and sex-specific differences in phallic retractor musculature, erectile tissue, tunica albuginea, and urethra/urogenital sinus were examined in male and female fetuses from Day 30 of gestation to term. Similar outcomes were assessed in fetuses from dams treated with an AR blocker and a 5alpha-reductase inhibitor (antiandrogen treatment). Clitoral and penile development were already advanced at Day 30 of gestation and grossly indistinguishable between male and female fetuses throughout pregnancy. Sex-specific differences in internal phallic organization were evident at Gestational Day 45, coincident with AR expression and testicular differentiation. Antiandrogen treatment inhibited prostatic development in males and effectively feminized internal penile anatomy. We conclude that gross masculinization of phallic size and shape of male and female fetuses is androgen-independent, but that sexual dimorphism of internal phallic structure is dependent on fetal testicular androgens acting via AR in the relevant cells/tissues. Androgens secreted by the maternal ovaries and metabolized by the placenta do not appear to be involved in gross masculinization or in most of the sex differences in internal phallic structure.     

Normal sexual differentiation: molecular genetic and endocrinology]

Analysis of the sexual determination and differentiation factors has progressed by the important findings made in biochemistry (hormonal assays, determination of the receptor concentration), in cellular and molecular endocrinology (mechanism of the hormonal action) and in genetics (identification, isolation and cloning of the genes implied in the sexual determination and differentiation pathways). We first describe the basis of sexual determination and differentiation, and then we analyze the different roles of SRY gene, encoding for the testis determining factor, androgen receptor gene, 5 alpha-reductase gene and anti-Müllerian hormone gene.     

Comparison of the effect of cortisol on aromatase activity and androgen metabolism in two human fibroblast cell lines derived from the same individual

The effect of preincubation with cortisol on estrogen and androgen metabolism was investigated in human fibroblast monolayers grown from biopsies of genital and non-genital skin of the same person. The activity in the cells of aromatase, 5 alpha-reductase, 17 beta-hydroxysteroid oxidoreductase and 3 alpha-hydroxysteroid oxidoreductase was investigated by isolating estrone, estradiol, estriol, dihydrotestosterone, androstanedione, androsterone, 3 alpha-androstanediol, testosterone and androstenedione after incubation of the cells with [14C]testosterone or [14C]androstenedione. For experiments with 14C-labeled substrate the cells were incubated in medium, charcoal stripped of steroids without Phenol Red. Preincubation from 6 to 36 h with cortisol in concentrations of 10(-8) - 10(-6) M showed maximal stimulation of aromatase activity after 12 h preincubation with cortisol in concentrations of 0.5-1.0 x 10(-6) M in both cell lines. When preincubation with cortisol was omitted no estrogen synthesis was detected. The formation of androgen was not altered after preincubation with cortisol. Pronounced differences were found in estrogen and in androgen metabolism in the two cell lines suggesting a local regulation of the hormonal environment. The aromatase activity, which is low in many tissues could be stimulated by cortisol without altering the androgen metabolism was found to be a suitable system for investigations of the cellular interconversion of androgens and estrogens and for investigations of the in vitro regulation of the enzymes involved.     

Differentiation of smooth muscle cells in the fetal rat testis and ovary: localization of alkaline phosphatase,smooth muscle myosin,F-actin,and desmin

Summary The histochemical demonstration of alkaline phosphatase (AP) activity and localization of smooth muscle myosin (SMM), F-actin, and desmin were carried out on frozen sections of testes and ovaries from 15-day-old fetal to newborn rats. The presence of immunocytochemically localized SMM and desmin was confirmed by Western blot analysis of proteins from isolated gonads. The development of smooth muscle cells was predominant in the testis. The first SMM-positive cells with an increasing intensity for F-actin and desmin appeared in the testicular tunica albuginea and around the testicular cords by the age of 16 days. A continuous layer of SMM- and F-actin-positive (but not uniformly desmin-positive) myoid cells was detected in the newborn testis. In the early gonads and in the newborn ovary, a majority of the interstitial cells expressed desmin, indicating that, in undifferentiated tissues, non-myogenic cells may also express desmin. During fetal development, male and female gonocytes showed a decrease in F-actin content but retained their high AP activity. In the cortex of the newborn rat ovary, the observed high AP activity and the presence of desmin may be associated with the postnatal histogenesis of the follicles. The presence of SMM-containing cells in the hilus of the ovary may be required for the demarcation of the ovary from the mesonephros by the constriction of the mesovarium. The occurrence of SMM-positive cells predominantly in male fetuses suggests that the development of the contractile cells in the fetal testis may be induced by testicular androgens.     

Androgens in relation to prenatal development and postnatal inversion of the gubernacula in rats.

Exposure of male rats to the anti-androgen flutamide during fetal life, from day 10 after conception to the day of birth, allowed quantitatively unaltered development of the gubernacula. Apparently, androgens play no important role or no role at all in their growth. Castration of newborn male rats did not interfere with the inversion during further postnatal life of the gubernacula to create the muscular parts of the scrotum (cremaster muscles). Prenatal exposure to flutamide, followed by castration immediately after birth, also allowed gubernacular inversion and cremaster muscle growth. Neonatal administration of testosterone, after castration at birth, did not enhance gubernacular inversion or promote cremaster muscle growth in infancy or during adulthood. Apparently, postnatal gubernacular inversion and cremaster muscle growth are independent not only of androgens, but also of all testis hormones. Neonatal administration of the potent androgen 5 alpha-dihydrotestosterone propionate suppressed gonadotrophin secretion and, in intact males, inhibited testicular growth. Administration from the day of birth to day 33 delayed testicular descent and enhanced growth of the genital apparatus, but did not affect the size of the cremaster muscles. These experiments indicate that androgens are not involved in the processes that create the cavities into which testes descend to acquire their full reproductive potential.