Autoradiographic studies of androgen-binding sites in the rat urogenital sinus and postnatal prostate

Binding sites of [3H]testosterone and [3H]dihydrotestosterone in the rat fetal urogenital sinus and postnatal prostate and vagina grown in vitro were examined by steroid autoradiography. Distinct nuclear incorporation of both androgens appeared between 14.5 and 16.5 days of gestation in rat fetuses. Nuclear labelling in the sinus was restricted to the mesenchyme surrounding the epithelium which showed no nuclear labelling. A similar distribution of labelled cells was observed in male and female sinuses up to 18.5 days of gestation. By 20.5 days of gestation, the labelling in the ventral mesenchyme of female urogenital sinuses became less intense but persisted in the mesenchyme of the dorsal sinus wall from which the vagina is formed. In the postnatal prostate, the epithelium showed nuclear [3H]testosterone labelling at 10 days coinciding with the onset of its functional differentiation. Epithelial labelling became more intensive at 4 weeks post partum while that of the mesenchyme declined. The results suggest two phases of androgen action: formation of the prostatic buds mediated by the androgen-activated mesenchyme of the fetal urogenital sinus and the differentiation of the postnatal prostatic epithelium directly stimulated by androgens.     

Virilization of the urogenital sinus of the tammar wallaby is not unique to 5alpha-androstane-3alpha,17beta-diol

The androgen 5alpha-androstane-3alpha,17beta-diol (5alpha-adiol) is synthesized in testes and secreted into plasma of male tammar wallaby pouch young and appears to virilize the urogenital sinus. To provide insight into its mechanism of action, a dose response study showed that administration of 1 microg 5alpha-adiol monoenanthate per g body wt. per week for 3 weeks to 24-day-old female pouch young induced prostate bud formation equivalent to that of males of the same age. Administration of this same dose of the enanthates of testosterone, dihydrotestosterone, and 5alpha-adiol to female pouch young caused equivalent virilization of the urogenital sinus. The fact that 5alpha-adiol does not exert a unique effect, together with our earlier findings in this species that 5alpha-adiol and testosterone are converted to dihydrotestosterone in the urogenital sinus and that virilization of the urogenital sinus is prevented by the androgen receptor antagonist flutamide, suggest that 5alpha-adiol is a circulating precursor for dihydrotestosterone formation in this tissue.     

Androgen metabolism in skin and skeletal muscle of the rainbow trout (Salmo gairdnerii) and in accessory sexual organs of the spur dogfish (Squalus acanthias).

The in vitro metabolism of testosterone, 4-androstene-3,17-dione (androstenedione) and dehydroepiandrosterone by skin and muscle from the rainbow trout (Salmo gairdnerii), and by skin and accessory sexual tissues from the spur dogfish (Squalus acanthias) was studied. In trout skin, testosterone was transformed mainly into 5α-dihydrotestosterone together with smaller amounts of 5α-androstane-3α, 17β-diol, androstenedione, 5α-androstane-3,17-dione and androsterone. Androstenedione was transformed mainly into 5α-androstane-3,17-dione with smaller amounts of testosterone, 5α-dihydrotestosterone, androsterone and 5α-androstane-3α,17β-diol. Dehydroepiandrosterone was transformed to 5-androstene-3β,17β-diol with trace quantities of androstenedione and 5α-androstane-3,17-dione. Unidentified polar nonconjugated metabolites and traces of steroid glucuronides were formed from the three substrates. The patterns of steroid metabolism were similar in dorsal and ventral skin, and in dorsal skin from male and female, adult and immature fish. Most of the 5α-reductase activity in the skin was in the dermis, only a small fraction of the total activity being in the epidermis. The trout muscle converted testosterone into 5α-dihydrotestosterone but in much lower yields than did skin.The skin, clasper, sperm sac and vas deferens of an adult male spur dogfish converted testosterone to 5α-dihydrotestosterone and androstenedione, though in much lower yields than did trout skin. Androstenedione was converted into testosterone, 5α-androstane-3, 17-dione and androsterone, while dehydroepiandrosterone was converted into 5-androstene-3β,17β-diol. No metabolism of testosterone was detected in the skeletal muscle of the dogfish.     

Production of testosterone, 5 alpha-androstane-3 alpha, 17 beta-diol and androsterone by dispersed testicular interstitial cells and whole testes in vitro.

The production of 5 alpha-androstane-3 alpha, 17 beta-diol (androstanediol), androsterone and testosterone by whole rat testes and testicular interstitial cells dispersed with collagenase was studied in vitro. Luteinizing hormone stimulated the production of each of the androgens by cells prepared from 31- to 34-day-old rats. Half maximum stimulation of the production of each androgen occurred with approximately 3.5 ng NIH-LH-B9/ml medium. Androstanediol was the predominant product then androsterone and then testosterone. Luteinizing hormone stimulated the production of testerone, but not androstanediol or androsterone by dispersed interstitial cells from 200-day-old rats. The time-course of production and the effect of the concentration of cells on the production of these androgens suggested that in dispersed testicular interstitial cells from immature animals androstanediol and androsterone are formed, at least partially, by the metabolism of testosterone. In these experiments LH-stimulated testosterone production increased during incubation for 15--60 min and then remained constant up to 180 min. The concentrations of androstanediol and androsterone increased in a linear manner during incubation for 60--180 min. Varying the number of cells incubated yielded a positive correlation between cell concentration and the ratio 5 alpha-reduced androgen : testosterone produced. Luteinizing hormone stimulated production of each androgen by whole tests obtained from rats at 30--175 days of age. The serum concentration of testosterone in these rats increased abruptly at 50 days of age. Significant changes in androgen production in vitro also observed at this age included: (1) increased production of the three steroids when incubated in either the presence or absence of LH and (2) testosterone production, either in the presence or absence of LH, which represented a greater percentage of the total production of the three androgens.     

Androgen dependence of growth and epithelial morphogenesis in neonatal mouse bulbourethral glands

The early development of the mouse bulbourethral gland (BUG) and the role of testosterone (T) in the normal growth and epithelial morphogenesis of this male accessory sex gland were examined. The mouse BUG differentiates from the urogenital sinus on day 17 of gestation (vaginal plug = day 0; birth = day 19), and initially consists of a solid epithelial rudiment encased in a large condensed capsular mesenchyme. The epithelium begins to branch and canalize on day 1 postnatally, and the branches enlarge and become more numerous on days 2 and 3. On day 4, secondary branches appear, and by day 6, the epithelium has become extensively arborized and almost fills the mesenchymal capsule. The BUG increases 3.9-fold in DNA content from day 0 (day of birth) to day 6 postnatally; the epithelium grows proportionately more than the mesenchyme during this period (12-fold vs. 2.3-fold). Growth of BUGs in mice castrated at birth or castrated and then treated with cyproterone acetate, an antiandrogen, over the first 6 days of life was reduced by 80%, but not abolished. Thus, the growth of the BUG is partially independent of androgens during early neonatal life. However, morphogenesis of the BUG epithelium is totally abolished in neonatally castrated mice. T replacement given to neonatally castrated mice during days 0-6 restored development to normal. T injections also reinitiated growth and morphogenesis in developmentally retarded BUGs from 6-day-old neonatally castrated mice. The partial dependence of the neonatal BUG on androgens for growth is similar to that seen in the prostate, which is also derived from the urogenital sinus. In contrast to the prostate, where neonatal castration reduces but does not abolish epithelial morphogenesis, androgen deprivation completely abolished epithelial morphogenesis in the neonatal BUG. (Endocrinology 121: 2153-2160, 1987).     

Distribution and concentrations of androgens in epithelial and stromal compartments of the human benign hypertrophic prostate

Prostate tissues removed from patients with benign prostatic hypertrophy were separated into epithelia and stromal components and the concentrations of testosterone, 5 alpha-dihydrotestosterone, 5 alpha-androstane-3 alpha,17 beta-diol, 4-androstene-3,17-dione, 5 alpha-androstanedione and androsterone in these two fractions were determined by radioimmunoassays after the purification of solvent steroid extracts by Lipidex-5000 column chromatography. On a 'per cell' basis (i.e. relative to DNA), testosterone was equally distributed between the two components, while the other androgens measured were more abundant in the stroma. The observation that 5 alpha-reduced androgens (especially 5 alpha-dihydrotestosterone) were more concentrated in the stroma, and that significant correlations between concentrations of metabolically related androgens were more common in the stroma than in the epithelium, indicate that the stroma is an important site of androgen metabolism in benign prostatic hypertrophic tissues. The present data also support the suggestion that 5 alpha-dihydrotestosterone produced in the prostatic stroma may be transferred to the epithelium by way of sex hormone binding globulin in the extracellular spaces of the prostate.     

Effect of human recombinant mullerian inhibiting substance on isolated epithelial and mesenchymal cells during mullerian duct regression in the rat.

The effect of human recombinant Mullerian Inhibiting Substance (MIS) on the regression of the Mullerian duct (MD) of female rat fetuses was examined in vitro to determine whether MIS acts on MD epithelium and/or mesenchyme at the critical periods of sexual differentiation. Urogenital ridges (URs) of female rat fetuses at 14.5- to 18.5-days of gestation (plug day = 0) were cultured for 3 days with or without recombinant human MIS in CMRL 1066 medium with 10% female fetal calf serum. In URs from 14.5- and 15.5-day-old fetuses, the cranial portion of the MD regressed almost completely during the 3-day culture period in the presence of MIS, whereas the caudal half to third of the MD remained intact but tapered to a fine point cranially. MDs survived in URs from 16.5-day-old fetuses cultured in the presence of MIS except that the cranial portion of the MDs was deformed. MIS did not elicit regression of MDs in URs obtained from 17.5- and 18.5-day-old fetuses, but instead caused the MD epithelium to form bulges projecting into the mesenchyme. MD epithelium at 15.5-days of gestation was separated from the surrounding UR mesenchyme, and both components (MD epithelium and mesenchyme) were cultured separately for 3 days in the presence or absence of MIS. Both epithelial and mesenchymal cells survived in the presence or absence of MIS. MD epithelium formed typical epithelial colonies, whereas UR mesenchyme spread as fibroblastic cells. Analysis of labeling index after incorporation of [3H] thymidine demonstrated that MD epithelial DNA synthesis was not influenced by MIS. In contrast, mesenchymal labeling index was reduced significantly by MIS. This effect of MIS on UR mesenchyme in conjunction with earlier histological observations of mesenchymal condensation during MD regression and an absence of direct effects of MIS on the epithelium suggests that MIS elicits its effect on the MD epithelium via the surrounding mesenchyme.     

Role of the alternate pathway of dihydrotestosterone formation in virilization of the Wolffian ducts of the tammar wallaby, Macropus eugenii

Dihydrotestosterone in androgen target tissues is formed under most circumstances by the 5alpha-reduction of testosterone, but an alternate pathway involves the oxidation of androstanediol to dihydrotestosterone. To investigate the mechanism by which androgens virilize the Wolffian ducts in the tammar wallaby, [(3)H]progesterone was incubated with testes from d 10 and 19 pouch young, and radioactivity was recovered in testosterone and androstanediol at both ages. Analysis of the intermediates indicates that androstanediol was formed both from testosterone via 5alpha-reduction and 3alpha-keto reduction and directly from 5alpha-reduced progestogens. 5alpha-Reductase activity was high in minces of mesonephros/epididymis from d 6-21 pouch young. When minces of urogenital tract tissues from d 19 pouch young were incubated with [(3)H]testosterone, [(3)H]dihydrotestosterone, and [(3)H]androstanediol, dihydrotestosterone was the principal androgen formed in the mesonephros/epididymis, urogenital sinus, and urogenital tubercle, whereas androstanediol was the principal androgen formed by the testis. In intact pouch young studied between d 10 and 34, administration of the 5alpha-reductase inhibitor, 17beta-(N,N-diethyl)carbamoyl-4-methyl-4-aza-5alpha-androstan-3-one, blocked virilization of the Wolffian ducts in males, and administration of androstanediol caused virilization of the Wolffian ducts in females. We conclude that dihydrotestosterone, largely formed in the tissue by the oxidation of androstanediol derived from the testes and also the 5alpha-reduction of testosterone, is responsible for Wolffian duct virilization in this species.     

Influence of androgens on plasma concentrations of growth hormone in growing castrated and intact chickens

Castrated chicks implanted with testosterone or 5 alpha-dihydrotestosterone (5 alpha-DHT) had circulating concentrations of the respective androgen similar to or less than in sham-operated chicks. In castrated chicks, 5 alpha-DHT or 19-nortestosterone (19-NorT) inhibited growth as indicated by body weight, while testosterone and 5 beta-dihydrotestosterone (5 beta-DHT) were without effect. In intact male or female chicks, growth was inhibited by either testosterone or 5 alpha-DHT but was unaffected by 5 beta-DHT or estradiol-17 beta. Plasma concentrations of luteinizing hormone (LH) were reduced in castrated chicks receiving implants of either testosterone or 19-NorT. Only the highest dose of 5 alpha-DHT depressed the circulating concentration of LH; lower doses of 5 alpha-DHT being without effect. During the first 6 weeks of growth, plasma concentrations of GH were unaffected by most steroid treatments (5 alpha-DHT, 5 beta-DHT, low doses of testosterone, estradiol-17 beta) in castrated or in intact male or in female chicks. Similarly, 19-NorT did not affect plasma concentrations of GH in castrated chicks. The high dose of testosterone, however, depressed plasma concentrations of GH in castrated chicks between 2 and 6 weeks of age. Between 8 and 12 weeks of age, all steroids tested, except 5 alpha-DHT, were without effect on plasma concentrations of GH. Plasma concentrations of GH were increased in 5 alpha-DHT-treated chickens. This effect was observed irrespective of dose of 5 alpha-DHT or whether the androgen was administered to castrated or to intact male or to female chicks.     

Formation of 5alpha-reduced C19-steroids from progesterone in vitro by a pathway through 5alpha-reduced C21-steroids in ovaries of late prepubertal rats.

Ovarian homogenates from 10-150-day-old rats were incubated with [3H]progesterone and NADPH. Also, ovarian homogenates from 28-day-old rats were incubated for 5-180 min with either [14C]progesterone, [3H]5alpha-pregnane-3,20-dione or [14C]progesterone plus [3H]5alpha-pregnane-3,20-dione. Following incubation, radioactive metabolites were isolated, identified, and measured by column and paper chromatography, with derivative formation and recrystallizations to constant specific activity. Prepubertal ovaries (10, 20, and 28 days of age) converted 15-60% of progesterone to C21-17-hydroxysteroids and C19-steroids. At 40 and 150 days of age (postpubertal), the formation of these steroids decreased to less than 2%. At 10 and 150 days of age, the major C19-steroids formed from progesterone were androstenedione and testosterone. At 20 and 28 days of age, however, no accumulation of these C19-delta4-3ketosteroids was found (less than 0.1% of each), at which time the conversion of progesterone to 5alpha-reduced C19-steriods, such as androsterone and 5alpha-androstane-3alpha,17beta-diol, reached 30%. In ovaries of 28-day-old rats, the results from incubation studies for the detection of metabolic pathways indicated two biosynthetic pathways leading to 5alpha-reduced C19-steroids, one from progesterone via 5alpha-reduced C21 steroids, such as 3alpha-hydroxy-5alpha-pregnan-20-one and 3alpha,17alpha-dihydroxy-5alpha-pregnan-20-one, and a second via 17-hydroxyprogesterone, androstenedione, and testosterone. It seems that the active 5alpha-reduction of C19-delta4-3-ketosteroids and the formation of 5alpha-reduced C19-steroids by the pathway through 5alpha-reduced C21-steroids, are present in the ovaries of older prepubertal rats and may be the biological significance.     

Unsolved problems in male physiology: studies in a marsupial

Testicular androgens induce formation of the male urogenital tract in all mammals. In marsupials male development occurs after birth and over a prolonged period. For example, in the tammar wallaby virilization of the Wolffian ducts begins by day 20, prostate formation begins about day 25, and phallic development starts after day 80 of pouch life. Between days 20 and 40 5alpha-androstane-3alpha,17beta-diol (5alpha-adiol) is formed in tammar testes and secreted into plasma. Administration of 5alpha-adiol to pouch young females induces urogenital sinus virilization by day 40 and formation of a mature male prostate and phallus by day 150. 5alpha-Adiol is synthesized in pouch young testes by two pathways, one involving testosterone and dihydrotestosterone and the other 5alpha-pregnane-3alpha,17alpha-diol-20-one and androsterone as intermediates, both utilizing steroid 5alpha-reductase. In target tissues 5alpha-adiol acts via the androgen receptor after conversion to dihydrotestosterone but may have other actions as well. Whether 5alpha-adiol plays a role in male development in placental mammals is uncertain.     

Visualization of X-chromosome inactivation mosaicism of Tfm gene in XTfm/X+ heterozygous female mice

The testicular feminization (Tfm) locus, which produces a deficiency in androgen receptors, is located on the X-chromosome. Steroid autoradiographic techniques were used to demonstrate the mosaicism of the X-chromosome inactivation in two androgen target tissues of XTfm/X+ heterozygous female mice. In the mesenchyme of urogenital sinuses of wild-type female fetuses (X+/X+), more than 95% of the cells were androgen-receptor positive (labelled with [3H]testosterone) while in that of heterozygous fetuses (XTfm/X+), about half of the cells were receptor positive (Tfm gene inactive). Statistical analysis of coherent clone size was applied to the heterozygous mesenchyme of the urogenital sinus and the coherent clone size of receptor-positive cells was estimated to be two or three cells per clone. This small clone size suggests that considerable cell mixing occurred in the tissue during embryonic development. Androgen binding in the mammary gland rudiments was restricted to the mesenchymal cells only in close vicinity to the epithelial mammary bud. In the wild-type rudiments most of the mesenchymal cells beneath the epithelium were receptor positive, while in heterozygous rudiments, receptor-positive and -negative cells intermingled. This observation suggests that in the wild-type mammary gland rudiments the epithelial bud may induce the formation of androgen receptors in adjacent mesenchymal cells rather than attract pre-existing receptor-rich mesenchymal cells.     

Stimulatory effect of prolactin on luteinizing hormone-induced testicular 5 alpha-reductase activity in hypophysectomized adult rats

Two pituitaries from 7-week-old female rats were grafted under the capsule of the left kidney of 50-day-old male rat to induce hyperprolactinemia. All of the pituitary-grafted and sham-operated rats were hypophysectomized at 56 days of age. The hypophysectomized rats in groups of 4 were given daily sc injections of saline or 9 micrograms NIADDK-ovine-(o)LH-23 for 4 and 5 days starting from days 58 and 70, respectively (short and long term hypophysectomized groups). The metabolism of [3H]progesterone or [14C]androstenedione by testicular homogenates, concentrations of testosterone and 5 alpha-androgens (androsterone plus 5 alpha-androstane-3 alpha, 17 beta-diol) in the serum and testes, and testicular LH receptors were estimated. Hypophysectomy caused significant decreases in testicular enzyme activities per gram of tissue, androgen production, and testicular LH receptors. In the testes of hypophysectomized rats, LH treatment significantly stimulated 5 alpha-reductase and 17-hydroxylase activities. Although pituitary grafts alone showed little or no effect on these testicular enzyme activities, hyperprolactinemia induced by the grafts markedly enhanced the LH-stimulated 5 alpha-reductase activity in both groups, especially in the long term hypophysectomized group. Therefore, androsterone and 5 alpha-androstane-3 alpha,17 beta-diol were shown to be the major C19-steroid products (immature type of testicular androgen production) in the LH- and PRL-stimulated testes of long term hypophysectomized adult rats. On the other hand, hyperprolactinemia was associated with a significant inhibition and a slight increase of the LH-stimulated 17-hydroxylase activities in the short and long term hypophysectomized groups, respectively. This difference can be attributed to both a PRL-induced increase in testicular LH receptors and a PRL-induced inhibition of 17-hydroxylase via a postreceptor mechanism(s). The present findings demonstrate for the first time that PRL directly stimulates LH-induced 5 alpha-reductase activity in the testes. It appears that PRL may play a role in the increased production of 5 alpha-C19-steroids and the parallel decrease of testosterone production in immature rat testes.     

Prostate formation in a marsupial is mediated by the testicular androgen 5 alpha-androstane-3 alpha,17 beta-diol

Development of the male urogenital tract in mammals is mediated by testicular androgens. It has been tacitly assumed that testosterone acts through its intracellular metabolite dihydrotestosterone (DHT) to mediate this process, but levels of these androgens are not sexually dimorphic in plasma at the time of prostate development. Here we show that the 3 alpha-reduced derivative of DHT, 5 alpha-androstane-3 alpha,17 beta-diol (5 alpha-adiol), is formed in testes of tammar wallaby pouch young and is higher in male than in female plasma in this species during early sexual differentiation. Administration of 5 alpha-adiol caused formation of prostatic buds in female wallaby pouch young, and in tissue minces of urogenital sinus and urogenital tubercle radioactive 5 alpha-adiol was converted to DHT, suggesting that circulating 5 alpha-adiol acts through DHT in target tissues. We conclude that circulating 5 alpha-adiol is a key hormone in male development.     

Androgen physiology: unsolved problems at the millennium

Androgen physiology differs from that of other steroid hormones in two major regards. First, testosterone, the predominant circulating testicular androgen, is both an active hormone and a prohormone for the formation of a more active androgen, the 5alpha-reduced steroid dihydrotestosterone. Genetic evidence indicates that testosterone and dihydrotestosterone work via a common intracellular receptor, and studies involving in vitro reporter gene assays and intact mice in which both steroid 5alpha-reductase isoenzymes have been disrupted by homologous recombination indicate that dihydrotestosterone acts during embryonic life to amplify hormonal signals that can be mediated by testosterone at higher concentrations. However, in post-embryonic life dihydrotestosterone plays unique roles that have not been elucidated. Studies of other 5alpha-reduced steroids, including the plant hormone brassinolide, the hog pheromones androstanol and androstenol, and 5alpha-dihydroprogesterone (in horses and elephants) indicate that this reaction serves different functions in different systems. Second, during embryonic life androgen causes the formation of the male urogenital tract and hence is responsible for development of the tissues that serve as the major sites of androgen action in postnatal life. It has been generally assumed that androgens virilize the male fetus by the same mechanisms as in the adult, namely by the conversion of circulating testosterone to dihydrotestosterone in target tissues. However, in marsupial mammals there is no sexual dimorphism in the levels of testosterone or dihydrotestosterone at the time the male phenotype forms, and in the pouch young of one marsupial, the tammar wallaby, the testes secrete another 5alpha-reduced steroid, 5alpha-androstane-3alpha, 17beta-diol (5alpha-adiol), into plasma. The administration of 5alpha-adiol to female pouch young causes profound virilization of the urogenital sinus and external genitalia, but within target tissues 5alpha-adiol appears to work after oxidation to dihydrotestosterone. Thus, two separate mechanisms evolved for the formation of dihydrotestosterone in target tissues. 5alpha-adiol is the predominant androgen in neonatal testes in several placental mammals, but it is unclear whether it plays a similar role in other mammalian species.     

Androgen receptors are similar in fetal and adult rabbits

In an effort to explain the separate roles of testosterone and dihydrotestosterone (17 beta-hydroxy-5 alpha-androstan-3-one) in virilizing the male fetus, we compared the binding of these androgens to cytosolic receptors from urogenital tract tissues of fetal and adult male rabbits. As measured by a direct binding assay, fetal and adult androgen receptors are similar in respect to specificity, affinity, and amount of binding. Apparent dissociation constants for dihydrotestosterone binding averaged 1.1 nM for fetal receptor and 0.8 nM for adult androgen receptors. Average apparent dissociation constants for testosterone binding were 4- to 24-fold higher than those for dihydrotestosterone in fetal and adult tissues. Nonradioactive dihydrotestosterone and testosterone competed for [3H]dihydrotestosterone binding to the androgen receptor in both adult prostate and fetal urogenital sinus in a manner consistent with their affinity for binding, whereas estradiol, progesterone, and cortisol were weak competitors for [3H]dihydrotestosterone. On sucrose density gradients, both testosterone and dihydrotestosterone were bound to a protein with a sedimentation coefficient of approximately 8S. Although androgen receptors were detectable in urogenital tubercle and urogenital sinus of both male and female fetuses on days 18 and 29 of gestation, we were unable to characterize androgen binding in fetal Wolffian ducts. The nature of the androgen receptor in this tissue remains unresolved. These findings are consistent with the hypothesis that dihydrotestosterone formation acts to amplify the androgenic signal in both the fetus and adult, but is not absolutely required for virilization.     

Tissue interaction in androgen response of embryonic mammary rudiment of mouse: identification of target tissue for testosterone.

In the androgen response of the embryonic mammary rudiment of the mouse, both gland epithelium and surrounding mesenchyme are visibly involved. The question whether this is due to a direct action of testosterone on both tissues was investigated in experimental combination of mammary epithelium and mammary mesenchyme, derived either from normal or from androgen-insensitive (XTfm/Y) embryos. A typical androgen response occurred in combinations of androgen-insensitive epithelium with normal mesenchyme, whereas all combinations of normal epithelium with androgen-insensitive mesenchyme failed to respond. It is therefore concluded that only the mesenchyme of the mammary rudiment is the target tissue for testosterone, and that all changes in the gland epithelium, including its necrosis, are secondarily caused by testosterone-activated mesenchymal cells.     

Estrogen-initiated transformation of prostate epithelium derived from normal human prostate stem-progenitor cells

The present study sought to determine whether estrogens with testosterone support are sufficient to transform the normal human prostate epithelium and promote progression to invasive adenocarcinoma using a novel chimeric prostate model. Adult prostate stem/early progenitor cells were isolated from normal human prostates through prostasphere formation in three-dimensional culture. The stem/early progenitor cell status and clonality of prostasphere cells was confirmed by immunocytochemistry and Hoechst staining. Normal prostate progenitor cells were found to express estrogen receptor α, estrogen receptor β, and G protein-coupled receptor 30 mRNA and protein and were responsive to 1 nm estradiol-17β with increased numbers and prostasphere size, implicating them as direct estrogen targets. Recombinants of human prostate progenitor cells with rat urogenital sinus mesenchyme formed chimeric prostate tissue in vivo under the renal capsule of nude mice. Cytodifferentiation of human prostate progenitor cells in chimeric tissues was confirmed by immunohistochemistry using epithelial cell markers (p63, cytokeratin 8/18, and androgen receptor), whereas human origin and functional differentiation were confirmed by expression of human nuclear antigen and prostate-specific antigen, respectively. Once mature tissues formed, the hosts were exposed to elevated testosterone and estradiol-17β for 1-4 months, and prostate pathology was longitudinally monitored. Induction of prostate cancer in the human stem/progenitor cell-generated prostatic tissue was observed over time, progressing from normal histology to epithelial hyperplasia, prostate intraepithelial neoplasia, and prostate cancer with local renal invasion. These findings provide the first direct evidence that human prostate progenitor cells are estrogen targets and that estradiol in an androgen-supported milieu is a carcinogen for human prostate epithelium.     

Change of mosaic pattern by androgens during prostatic bud formation in XTfm/X+ heterozygous female mice

The testicular feminization (Tfm) gene, which is characterized by a deficiency in androgen receptors, is located on the X-chromosome. Using steroid autoradiography, the mosaicism of the Tfm gene has been demonstrated in the androgen target tissues of XTfm/X+ heterozygous female mouse fetuses and the effects of androgens on the mosaic pattern analysed. In the mesenchyme of urogenital sinuses of wild-type female fetuses (X+/X+), more than 95% of the cells were androgen-receptor positive (labelled with [3H]testosterone) while in that of heterozygous fetuses (XTfm/X+), only half of the cells were receptor positive (Tfm gene inactive), and receptor-positive cells and -negative cells formed small irregular patches. When the heterozygous sinuses were cultured in vitro in the presence of androgens, the sinuses underwent male sexual development and formed epithelial buds (prostate gland rudiments) projecting into the surrounding mesenchyme. Autoradiographic analysis revealed that the mosaicism of the mesenchyme disappeared around the developing epithelial buds: almost all the mesenchymal cells in close vicinity to the buds were receptor positive while in the outer layers receptor-positive and -negative cells coexisted. The proportion of receptor-positive cells was greatly increased in the mesenchyme beneath the non-budding area of the sinus epithelium. This androgen-induced increase was observed before the onset of bud formation. The results obtained in the thymidine incorporation experiments suggest that the increase of receptor-positive cells beneath the sinus epithelium might be explained by the migratory behaviour of the androgen-incorporating cells rather than by their selective proliferation.     

Tissue androgen concentrations in golden hamsters with benign prostatic tumours

Using gas chromatography-high resolution mass spectrometry with selected ion detection, the concentrations of testosterone, 5alpha-dihydrotestosterone, androsterone, 5alpha-androstane-3alpha,17beta-diol, 5alpha-androstane-3beta,17alpha-diol and 5alpha-androstane-3beta,17beta-diol were measured in the dorsal and ventral prostates of two strains of golden hamster (Mesocricetus auratus) at various ages from 60 to 250 days. The tissue concentrations from a control strain were compared with those of the BIO 87.2 strain of hamster, the latter developing benign hyperplasia of the prostate between 90 and 120 days of age. Marked increases in the concentration of total 5alpha-androstanediols in both prostatic lobes of the BIO 87.2 strain were detected, with the highest level of over 345 nmol/g protein being found at 200 days of age. In comparison, the control strain showed a less pronounced increase in concentration at 150 days. Increases in total 5alpha-androstanediols were mainly associated with increases in the concentration of 5alpha-androstane-3alpha,17beta-diol. Concentrations of testosterone in prostatic tissue were also found to increase in the BIO 87.2 animals with peak values being seen at 200 days. Increases in concentration of androsterone were observed by 150 days and these levels were maintained up to 250 days of age. Control animals showed no comparable increases in testosterone and androsterone during the time-course studied. Surprisingly, no significant variation in 5alpha-dihydrotestosterone concentration was detected in either strain from 60 to 250 days although levels were slightly but consistently higher in the BIO 87.2 strain. There were no significant fluctuations in any of the androgens assayed either before or during tumour development. The increases in 5alpha-androstane-3alpha,17beta-diol, testosterone and androsterone were detected only after tumours had become established.