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 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.     

Induction of androgen receptor formation by epithelium-mesenchyme interaction in embryonic mouse mammary gland.

The role of tissue interaction in the development of hormone responsiveness was studied in the embryonic mammary gland of the mouse, which becomes sensitive to testosterone on day 14. Previously, the mesenchyme had been identified as the sole target tissue for the hormone, although it was also demonstrated that its response to testosterone required the presence of mammary epithelium. Using autoradiography, we now show that [3H]testosterone or [3H]5 alpha-dihydrotestosterone is bound only by those mesenchymal cells closest to the epithelial mammary bud. When mammary epithelia were experimentally associated with mesenchyme of the mammary region and cultured together for 3 days in vitro, they also became surrounded by several layers of [3H]testosterone-binding mesenchymal cells. Correspondingly, this tissue association was accompanied by a substantial increase of androgen-binding sites in the explants. No hormone-building mesenchymal cells were seen in combinations with epidermis or pancreas epithelium; only salivary epithelium showed a weak positive effect. From these results we conclude that mammary epithelium induces the formation of androgen receptors in adjacent mesenchyme and thereby controls the development of androgen responsiveness in this tissue.     

Promotion of murine hepatocarcinogenesis by testosterone is androgen receptor-dependent but not cell autonomous.

Tfm (testicular feminization) mutant mice lack functional androgen receptors. By studying liver tumor development in Tfm mice, we have shown that the greater susceptibility of male mice relative to female mice for liver tumor induction by N,N-diethylnitrosamine is androgen receptor-dependent. C57BL/6J normal and Tfm mutant mice were injected at 12 days of age with N,N-diethylnitrosamine (0.2 mumol/g, i.p.), and liver tumors were enumerated in 50-week-old animals. Normal males averaged 20 liver tumors per animal; Tfm males, 0.7; normal females, 0.6; and Tfm/+ heterozygous females, 1.5. The androgen receptor gene and the Tfm mutation are X chromosome linked. Because of random X chromosome inactivation, hepatocytes from Tfm/+ heterozygous female mice are mosaic with respect to the expression of mutant or wild-type receptors. To determine if testosterone acts directly as a liver tumor promoter, through the androgen receptor in preneoplastic hepatocytes, or by an indirect mechanism, we chronically treated these mosaic female mice with testosterone and measured the androgen receptor content of the resulting tumors. B6C3F1 Tfm/+ mosaic and +/+ wild-type female mice were injected i.p. at 12 days of age with N,N-diethylnitrosamine (0.1 mumol/g) and ovariectomized at 8 weeks of age. Half of the mice of each group subsequently received biweekly s.c. injections of testosterone (0.15 mg per mouse) for 30 weeks. Tumor multiplicity was the same for wild-type and Tfm/+ mosaic females treated with testosterone (31-32 tumors per animal at 38 weeks of age) and was increased relative to females not treated with testosterone (13-17 tumors per animal at 50 weeks of age). Testosterone treatment did not significantly increase the percentage of androgen receptor-positive tumors in Tfm/+ mosaic females: 58% of the tumors from Tfm/+ mosaic females treated with testosterone were receptor positive compared to 48% in Tfm/+ females not treated with testosterone and 92% in wild-type females treated with testosterone. Finally, the number of androgen receptors in the majority of liver tumors examined was greatly decreased relative to the surrounding normal liver tissue. We conclude that liver tumor promotion by testosterone requires a functional androgen receptor in the intact animal. However, this promotion is not cell autonomous; that is, the response of the preneoplastic hepatocyte is not dependent on the expression of functional receptor in the target cell.     

Inability of Tfm (testicular feminization) epithelial cells to express androgen-dependent seminal vesicle secretory proteins in chimeric tissue recombinants

To assess the role of androgen receptors (ARs) in the expression of androgen-dependent seminal vesicle (SV) secretory proteins, tissue recombinants were prepared with rat seminal vesicle mesenchyme plus ureter epithelium of wild-type or Tfm mice (rat SVM plus wild-type mouse URE and rat SVM plus Tfm mouse URE, respectively). After growth in male hosts, both the wild-type and Tfm ureter epithelia were induced by SVM to differentiate into a simple columnar epithelium exhibiting the complex folded morphology characteristic of the SV. In SVM plus wild-type mouse URE recombinants, epithelial ARs were induced, and the epithelium expressed the full spectrum of SV secretory proteins. By contrast, in SVM plus Tfm mouse URE recombinants, the Tfm epithelium was genetically incapable of producing functional ARs and failed to produce SV secretory proteins. These data demonstrate in vivo that the induction of SV secretory proteins by androgens is an event requiring intraepithelial ARs. In contrast, androgen-dependent epithelial morphogenesis, columnar cytodifferentiation, and probably also proliferation can be expressed in Tfm epithelium grown in association with wild-type mesenchyme, strongly suggesting that these events are indirect effects on the epithelium mediated by mesenchymal ARs.     

Ontogeny of mesenchymal androgen receptors in the embryonic mouse mammary gland

We demonstrate the presence of a high affinity androgen-binding site in the embryonic mouse mammary gland, and describe its appearance and development from the initial formation of the gland bud (day 12) through the androgen-responsive stage (day 14) until term (day 19). Binding assays were done on entire organ rudiments exposed to the ligand [( 3H] testosterone, [3H]5 alpha-dihydrotestosterone, or [3H]methyltrienolone) in vitro, and receptor levels are expressed per gland. In competition experiments, the binding site shows a ligand specificity of a typical rodent androgen receptor. Scatchard analysis yielded a figure of 90-100 million binding sites for one 14-day gland, or approximately 30,000 per target cell. The apparent dissociation constant Kd for ligand binding by the intact tissue was between 0.55 and 0.75 X 10(-9) M. The first binding sites become detectable at the time of mammary bud formation (day 12); their number increases about 20-fold towards the responsive stage (day 14), and they persist at high levels at least until birth. The loss of androgen responsiveness on day 15 is neither accompanied by a loss of receptors nor by a change of their binding affinity.     

Analysis of prostatic bud induction by brief androgen treatment in the fetal rat urogenital sinus

The androgen dependency of prostatic bud formation in fetal rat urogenital sinuses was studied using brief treatments with androgen, and the incorporation of androgens by the sinus mesenchyme was followed by steroid autoradiography. Urogenital sinuses from 16.5-day fetuses of both sexes were grown in organ culture and treated with androgens for periods ranging from 4 to 72 h and then transferred to control medium. A minimum treatment of 24 h was required to induce prostatic buds in male sinuses and of 36 h in all female sinuses. This difference in response disappeared after more prolonged treatment. In both sexes the number of prostatic buds increased with the time of exposure to androgens. Prostatic bud formation continued for 24-36 h after transfer to control medium. Steroid autoradiographic analysis showed that the labelled androgen was concentrated in the mesenchymal nuclei. The rate of incorporation rose steeply during the first 12 h and then more slowly. After transfer to control medium the amount of labelled androgen decreased rapidly to half within 12 h and then decreased more slowly. In the competition experiments a 200-fold excess of unlabelled testosterone or dihydrotestosterone in the labelling medium greatly reduced the nuclear labelling with [3H]testosterone.     

The androgen receptor of the testicular-feminized (Tfm) mutant mouse is smaller than the wild-type receptor

The physicochemical and immunological properties of androgen receptors from kidney and brain of testicular-feminized (Tfm) mutant mice and wild-type mice were compared. Analysis by gel filtration and sucrose density gradients revealed that the mol wt of the mutant receptor was 66K (38A; 3.8S) which was significantly smaller than the 110K (53A; 4.6S) size of the wild-type androgen receptor (P less than 0.05). Mixing experiments failed to demonstrate any role for differential proteolysis in the size differences between these receptors. Interaction of the mutant androgen receptor with specific polyclonal antiandrogen receptor antibodies produced significantly smaller immune complexes than that formed with wild-type receptor (12S vs. 17S; P less than 0.01). This confirmed the smaller size of the Tfm mutant androgen receptor and suggested that it contained fewer epitopes. The Tfm kidney cytosols also demonstrated a decreased concentration of androgen receptor-binding activity relative to that of the wild type. Together, these results suggest that the androgen insensitivity associated with the Tfm phenotype is due to a deficiency of androgen receptor in target tissues and a qualitative defect in the androgen receptor protein itself.     

Induction of nephrogenic mesenchyme by osteogenic protein 1 (bone morphogenetic protein 7).

The definitive mammalian kidney forms as the result of reciprocal interactions between the ureteric bud epithelium and metanephric mesenchyme. As osteogenic protein 1 (OP-1/bone morphogenetic protein 7), a member of the TGF-beta superfamily of proteins, is expressed predominantly in the kidney, we examined its involvement during metanephric induction and kidney differentiation. We found that OP-1 mRNA is expressed in the ureteric bud epithelium before mesenchymal condensation and is subsequently seen in the condensing mesenchyme and during glomerulogenesis. Mouse kidney metanephric rudiments cultured without ureteric bud epithelium failed to undergo mesenchymal condensation and further epithelialization, while exogenously added recombinant OP-1 was able to substitute for ureteric bud epithelium in restoring the induction of metanephric mesenchyme. This OP-1-induced nephrogenic mesenchyme differentiation follows a developmental pattern similar to that observed in the presence of the spinal cord, a metanephric inducer. Blocking OP-1 activity using either neutralizing antibodies or antisense oligonucleotides in mouse embryonic day 11.5 mesenchyme, cultured in the presence of metanephric inducers or in intact embryonic day 11.5 kidney rudiment, greatly reduced metanephric differentiation. These results demonstrate that OP-1 is required for metanephric mesenchyme differentiation and plays a functional role during kidney development.     

Developmental study of androgen responsiveness in the submandibular gland of the mouse.

The development of androgen responsiveness in the submandibular gland of normal and androgen-resistant (Tfm) mice of different ages was studied after varying hormonal treatments. Total esteroproteolytic (tamase) activity of submandibular gland homogenates was used as a marker for androgen action. Newborn mice of all four genotypes (normal male, normal female, carrier Tfm females, and Tfm males) were resistant to androgen. However, at 3 weeks of age the capacity to develop a tamase response appears in normal and carrier Tfm animals given androgen and rapidly rise to maximal levels. The level in the normal animal is regulated thereafter primarly by the level of circulating androgen. In contrast, the tamase response in the Tfm male of all ages and under all androgen regimens was minimal.     

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.     

Induction of androgen-dependent protease and serous-like granules by tri-iodothyronine in the submandibular gland of mice with testicular feminization.

Esteroprotease, an androgen-dependent enzyme of the mouse submandibular gland, was increased by injection of tri-iodothyronine (T3) in mice with testicular feminization (Tfm) which are genetically deficient in androgen receptors. Histochemical and electron microscopic studies also demonstrated increases of RNA and serous-like granules in cells of the convoluted tubules of the gland. These findings suggest that the esteroprotease gene in Tfm mice is normal and that T3 can induced both esteroprotease and serous-like granules independently of androgen.     

De novo induction of a gene product during heterologous epithelial-mesenchymal interactions in vitro

Mesenchymal specification of epithelial cytodifferentiation and morphogenesis has been considered to be a general feature of various epithelial-mesenchymal interacting systems (e.g., salivary gland, mammary gland, feather, hair, and tooth morphogenesis). In contrast, we have demonstrated that a mesenchyme can be induced by a heterologous epithelium to synthesize in quantity a specific gene product(s) unorthodox to the organ from which the mesenchyme was taken. Stage 22-23 avian limb bud epithelium induced 17-day embryonic mouse tooth mesenchyme to differentiate into cartilage. Peptide analysis (cyanogen bromide cleavage after purification of extracted collagen chains) demonstrated that heterologous tissue recombinations produced type II collagen [alpha(II)](3) (i.e., cartilage-type) in addition to type I collagen [alpha(I)](2)alpha(2). Intact or reconstituted mouse molar tooth organs synthesized type I collagen and type I trimer [alpha(I)](3) collagen. Immunohistochemical criteria using anti-type II collagen antibodies identified type II collagen in cartilage-like matrix within the mesenchymal component of heterologous tissue recombinants. Cartilage has never been described during in vivo or in vitro tooth tissue differentiation or associated with the pathology of dental papilla mesenchyme. These results support the hypothesis that epithelial-mesenchymal interactions during embryonic development can selectively induce de novo synthesis of unique gene products.     

In vivo regeneration of murine prostate from dissociated cell populations of postnatal epithelia and urogenital sinus mesenchyme

The existence of a postnatal prostate stem cell is supported by several types of evidence. Withdrawal of androgen leads to involution of the gland, but readdition can rapidly stimulate regeneration. Tissue fragments derived from mouse or rat prostatic epithelia from midgestation embryos or adult mice, when combined with tissue fragments from urogenital sinus mesenchyme and grafted under the kidney capsule, can regenerate prostatic structures. Indirect evidence supports that the stem cell population is contained within the basal layer. Purified prostatic stem cell preparations would be useful to define the physical and functional properties required for regeneration and to compare with cells that accumulate during abnormal growth states, like prostate cancer. We have developed a regeneration system using dissociated cell populations of postnatal prostate epithelia and embryonic urogenital sinus mesenchyme. Efficient in vivo regeneration of prostatic structures in the subcapsular space of the kidney was observed within 4-8 wk with as few as 103 epithelial cells from prostates derived from donors 10 d to 6 wk of age. The regenerated structures show a branching tubular epithelial morphology, with expression of a panel of markers consistent with prostate development. Donor epithelial populations can be readily infected with GFP expressing lentiviral vectors to provide integration markers and easy visualization. The cell preparations of urogenital sinus mesenchyme can be expanded in short-term in vitro culture while their inductive capabilities are retained. Further definition of the subpopulation of prostate epithelial cells containing the regeneration activity should be possible with such technologies.     

Binding of glucocorticoid to the androgen receptor of mouse submandibular glands

An increase in esteroprotease activity, a known cytodifferentiating response to androgen in the submandibular gland, occurred after cortisol acetate, dexamethasone or methyltrienolone (R1881) treatment in castrated genetically normal male (X/Y-castrated) mice, but not in normal male (X/Y) and testicular feminized male (Tfm/Y) mice. A peak with specific binding for [3H]cortisol appeared in sucrose density gradient patterns of extracts from X/Y-castrated mice and in almost the same fraction number as that for [3H]R1881 binding. However, peaks specific for neither [3H]cortisol nor [3H]R1881 binding were observed in Tfm/Y mice. The peak binding [3H]cortisol in extracts from X/Y-castrated mice, as well as the one binding [3H]R1881, were inhibited by unlabelled R1881 and cyproterone acetate, an antiandrogen; the peak was not, however, affected by unlabelled oestradiol-17 beta. The binding capacity of [3H]cortisol determined by Scatchard analysis was similar to that of [3H]R1881 (103 and 106 fmol/mg protein respectively). The Kd value of [3H]cortisol, however, was about 13.6-fold higher than that of R1881. These results suggest that cortisol has the ability to promote androgenic cytodifferentiating action in the mouse submandibular gland by binding to its androgen receptors, if androgens are absent or deficient.     

Growth hormone secretion by individual somatotropes of the testicular feminized rat

To investigate the cellular mechanisms underlying the unique GH secretory apparatus of the androgen-resistant testicular feminized (Tfm) rat we employed a reverse hemolytic plaque assay to assess GH secretion by individual cells from normal male, normal female, and Tfm rats. Acutely dispersed pituitary cells were incubated for 90 min with GH anti-serum in the presence of medium alone, 0.01, 0.1, 1, 10, or 100 nM GHRH, or 3 microM forskolin after which hemolytic plaques were developed over an additional 30 min. Body weights of the Tfm rats [318 +/- 7 g (mean +/- SEM)] were intermediate between intact males (372 +/- 18 g) and females (218 +/- 7 g). The total number of cells recovered from dispersion of Tfm rat pituitaries [3.20 +/- 0.42 X 10(6) (mean +/- SEM)] was greater than that from males (1.43 +/- 0.12 X 10(6); P = 0.001), but not distinguishable from that from females (2.31 +/- 0.30 X 10(6); P = 0.06). However, the absolute population of recovered somatotropes from the Tfm animals (1.24 +/- 0.22 X 10(6) exceeded both male (0.56 +/- 0.10 X 10(6); P = 0.002) and female (0.80 +/- 0.14 X 10(6); P = 0.046) values. Mean basal and maximal GH plaque areas were greater for cells from male rats than for those from either female or Tfm rats (P less than 0.05) regardless of whether GHRH or forskolin was used as the secretagogue. Plaque areas from female and Tfm cells were indistinguishable under all study conditions. These data suggest that a deficiency of androgen receptors prevents establishment of the greater GH secretory capacity of individual somatotropes characteristic of the adult male rat. This androgen receptor-dependent modulation of GH secretory capacity appears to occur at a step distal to the GHRH receptor. The data also suggest that an increase in the absolute population of somatotropes is an additional consequence of androgen receptor deficiency. This combination of individual somatotropes, each possessing a GH secretory capacity similar to that of cells from normal females, but present in greater absolute numbers, may explain the intermediate values found during previous studies of the Tfm rat GH axis which were based on assessment of large mixed populations of pituitary cells.     

Effects of androgens and estradiol on spine synapse formation in the prefrontal cortex of normal and testicular feminization mutant male rats

Recent studies suggest that, in female monkeys and rats, estrogens elicit dendritic spine synapse formation in the prefrontal cortex, an area that, similar to the hippocampus, plays a critical role in cognition. However, whether gonadal hormones induce synaptic remodeling in the male prefrontal cortex remains unknown. Here we report that gonadectomy reduced, whereas administration of 5alpha-dihydrotestosterone or estradiol-benzoate to castrated male rats increased, the number of medial prefrontal cortical (mPFC) spine synapses, with estradiol-benzoate being less effective than 5alpha-dihydrotestosterone. To investigate whether the androgen receptor contributes to the mediation of these changes, we compared the response of testicular feminization mutant (Tfm) male rats to that of wild-type animals. The number of mPFC spine synapses in gonadally intact Tfm rats and 5alpha-dihydrotestosterone-treated castrated Tfm males was considerably reduced compared to intact wild-type animals, whereas the synaptogenic effect of estradiol-benzoate was surprisingly enhanced in Tfm rats. These data are consistent with the hypothesis that remodeling of spine synapses in the prefrontal cortex may contribute to the cognitive effect of gonadal steroids. Our findings in Tfm animals indicate that androgen receptors may mediate a large part of the synaptogenic action of androgens in the mPFC of adult males. However, because this effect of 5alpha-dihydrotestosterone is not completely lost in Tfm rats, additional mechanisms may also be involved.     

Testicular steroidogenesis in the testicular feminized (Tfm) mouse: loss of 17 alpha-hydroxylase activity.

Testicular feminized (Tfm) mice are totally insensitive to androgen and may be used to study the role of the androgen receptor in normal development and function. We have examined testicular and Leydig cell steroidogenesis in Tfm mice. Serum bioactive LH was high in Tfm mice but serum testosterone was low and this was associated with a severe reduction in testicular testosterone production in vitro. Examination of [3H]pregnenolone metabolism by testes of Tfm mice indicated that progesterone, rather than testosterone, was the major steroid produced. Leydig cells were isolated from normal and Tfm mice and from normal mice in which testicular descent was surgically prevented before puberty. As in whole testes, androgen production in response to human chorionic gonadotrophin was severely reduced in Leydig cells from testes of Tfm mice compared with normal or cryptorchid groups. In contrast, progesterone production by Leydig cells from testes of Tfm mice was markedly increased in comparison with other groups. Total steroid production (progesterone plus androstenedione plus testosterone), however, was only 24% of normal in Leydig cells from Tfm mice. The pattern of steroid production by Leydig cells from cryptorchid testes was similar to control, although total steroid production was reduced to about 50% (this was significantly higher than the Tfm group, P less than 0.05). The high progesterone/androgen ratio in testes from Tfm mice suggested that 17 alpha-hydroxylase was depleted in these animals. To confirm this, activity of the four major steroidogenic enzymes associated with the smooth endoplasmic reticulum was measured.(ABSTRACT TRUNCATED AT 250 WORDS)     

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).