Differential regulation of brain aromatase by androgen in adult and fetal ferrets

The contribution of androgens to the regulation of aromatase activity (AA), measured by quantifying the in vitro formation of [3H]estrone from 19-[3H]hydroxyandrostenedione precursor, was studied in equivalent microdissected brain regions of adult and fetal ferrets. In adulthood, AA was similar in the bed nucleus of the stria terminalis, medial (M) and lateral (L) preoptic area (POA), medial (MA) and lateral amygdala (LA), ventromedial hypothalamus (VMH), and parietal cortex of gonadectomized males and females given no concurrent steroid treatment. Daily sc injections of the androgen dihydrotestosterone propionate significantly stimulated AA in MPOA, MA, and VMH of adult males and in MA of females; a similar trend was seen in MPOA and VMH of females. By contrast, no evidence of androgenic regulation of AA was obtained in these three brain regions microdissected from fetuses killed on embryonic day 35 (E35; 41-day gestation). Transplacental administration of the antiandrogen flutamide beginning on day E24 failed to affect AA in MPOA, LPOA, MA, LA, or parietal cortex, although this treatment significantly reduced AA in bed nucleus of the stria terminalis of fetal males. The results suggest that the responsiveness of aromatizing enzymes to androgenic induction is similar in several subcortical brain regions of adult ferrets of both sexes. In breeding males such an action of androgen may augment the neural production of estrogen, which has previously been implicated in the control of sexual behavior and the feedback regulation of LH secretion. By contrast, androgen apparently contributes minimally to the regulation of AA in brain regions of fetal ferrets, particularly in the MPOA, in which a sexually dimorphic nucleus differentiates in males around E37 in response to estrogen produced locally.     

Distribution and regulation of aromatase activity in the rat hypothalamus and limbic system

Conversion of androgen to estrogen in the rat brain is catalyzed by aromatase enzymes. The maximum concentrations of these enzymes are found within the hypothalamus and amygdala, where they appear to play an important role in the process by which androgens affect both behavior and neuroendocrine function. In the present study, we measured the levels of aromatase activity (AA) in 20 nuclei and brain regions of the adult rat brain. Individual nuclei were microdissected from 600-micron frozen sections. Tissues from 3 animals were pooled, and AA was measured by an in vitro radiometric assay that quantifies the stereospecific production of 3H2O from [1 beta-3H]androstenedione as an index of estrogen formation. We report that AA is heterogeneously distributed within the rat brain. The greatest amounts of activity were found in the bed nucleus (n.) of the stria terminalis (700 protein fmol/h . mg) and in the medial (MA) and cortical amygdala (400-600 fmol/h . mg protein) of the male. There was an evident rostral-caudal and medial-lateral gradient in AA throughout the diencephalon. Activity was high in the periventricular preoptic n. and medial preoptic n.; intermediate in the suprachiasmatic preoptic n., anterior hypothalamus, periventricular anterior hypothalamus, and ventromedial n.; and low in the arcuate n.-median eminence, lateral preoptic n., supraoptic n., dorsomedial n., and lateral hypothalamus. Regions devoid of measurable AA included the medial and lateral septum, caudate-putamen, hippocampus, and parietal cortex. In the female, AA was greatest in the MA and cortical amygdala. We found that AA in the MA, stria terminalis n., suprachiasmatic preoptic n., periventricular preoptic in., medial preoptic n., anterior hypothalamus, and ventromedial n. was significantly greater (P less than 0.05) in males than in females. Orchidectomy reduced AA to levels seen in females, and administration of testosterone to castrated males restored AA in these areas. No significant sex differences were observed in any other hypothalamic or amygdaloid nuclei, although AA was increased by testosterone treatment in the periventricular anterior hypothalamus, arcuate n.-median eminence, and lateral hypothalamus. Our results provide a quantitative profile of AA in specific hypothalamic and limbic nuclei of the rat brain as well as information on the control of AA within these discrete regions.     

Androgens alter brain catecholamine content and blood pressure in the testicular feminized male rat

Androgens interact with catecholamines in the central nervous system (CNS) to regulate many physiological processes including blood pressure (BP). To test the hypothesis that testosterone (T) and 5a-dihydrotestosterone (DHT) modulate CNS catecholamines and BP through androgen receptor (AR)-dependent and independent mechanisms, we used the testicular feminized male (Tfm) rat. Females that carry the AR mutation (Tfm mutation) on the X chromosome were bred with spontaneously hypertensive rat (SHR) males. The normal AR male and Tfm offspring were divided into groups: control, castrated, castrated, and T or (DHT) replacement. In both AR normal and Tfm males, BP was reduced by castration, but T restored BP in both groups. In the amygdale, castration decreased dopamine (DA) in both strains and both T and DHT restored it. In the bed nucleus of the stria terminalis castration increased DA which was further increased by DHT and reduced to normal by T in both strains. In the frontal cortex, castration reduced DA content in both strains but only T restored it to normal in SHR but not in Tfm. Brain norepinephrine (NE) content showed a significant strain effect for the preoptic area (POA), but no treatment effect. Although castration did not change NE in the amygdala or POA in either strain, both T and DHT increased NE in the Tfm castrates. Blood pressure was influenced by T manipulation and correlated most significantly with DA content in the amygdala, frontal cortex, and stria terminalis. These data demonstrate an action of androgen on brain catecholamines and BP, which is independent of the classic androgen receptor.     

Quantitative distribution of nuclear androgen receptors in microdissected areas of the rat brain

The binding of androgens to specific high-affinity receptor sites in brain tissue is postulated as an initial event in the mechanism of central androgenic action. In an effort to assess the functional capacity of the androgen receptor system in the central nervous system, we measured the concentration of nuclear (ARn) as well as cytosolic androgen receptors (ARc) in 13 microdissected brain samples from intact male and female Sprague-Dawley rats. Tissues from 6 rats were combined for each determination and androgen receptor contents were measured with single-point in vitro assays that used saturating concentrations of high specific activity 3[H]dihydrotestosterone. We found that ARc levels tended to be higher in females than males although the general patterns of distribution were very similar. As expected, ARn concentrations were significantly higher in males than females. The highest concentrations of ARn (greater than 100 fmol/mg DNA) in males were measured in the ventromedial nucleus of the hypothalamus and medial amygdala; intermediate levels (50-100 fmol/mg DNA) were found in arcuate nucleus-median eminence, medial preoptic nucleus, periventricular preoptic area, bed nucleus of the stria terminalis, anterior hypothalamus, periventricular anterior hypothalamus, lateral septum, and parietal cortex, and low levels (less than 50 fmol/mg DNA) were measured in lateral preoptic nucleus and cortical amygdala. With the exception of the periventricular preoptic area (74 +/- 33 fmol/mg DNA), only very low concentrations of ARn were measured in females. These data provide the first quantitative profile of ARn in discrete brain nuclei and subregions of the rat.     

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)     

Gonadotropin-releasing hormone-stimulated luteinizing hormone secretion by perifused pituitary cells from normal, gonadectomized, and testicular feminized rats

To elucidate further the manner in which gonadal steroids influence the secretion of LH, we examined the effects of gonadectomy and the absence of functional androgen receptors on GnRH-induced LH release from dispersed rat anterior pituitary cells. Intact and gonadectomized (GNX) normal rats and androgen-resistant, testicular feminized (Tfm) animals from the King x Holtzman strain (a mutant strain that possesses defective androgen receptors) were used. Dispersed pituitary cells were perifused with Medium 199 during a 4-h equilibration period and then subjected to eight 2.5-min pulses of GnRH introduced at 30-min intervals at concentrations ranging from 0.03-100 nM. Basal LH secretion by cells from intact male and female rats was indistinguishable (P = 0.79) and was substantially lower (P less than 0.0001) than that by cells from GNX male and female animals. Basal LH secretion by cells from Tfm rats was significantly higher (P less than 0.01) than that by cells from intact animals, but lower (P less than 0.005) than that by cells from GNX animals. In response to GnRH, perifused pituitary cells from animals representing all experimental groups demonstrated concentration-dependent LH release. Pituitary cells from intact female rats showed an overall greater (P less than 0.05) response to GnRH than cells from intact male rats. Pituitary cells from Tfm rats demonstrated a greater GnRH-stimulated LH mean response than cells from intact male (P less than 0.0001) or intact female (P less than 0.0001) rats. Gonadectomy of male rats resulted in an overall GnRH-stimulated LH release similar to that exhibited by cells from gonadectomized female rats (P = 0.61). Cells from Tfm animals released more LH in response to GnRH than those from gonadectomized male and female rats (P less than 0.001). These data demonstrate that the release of LH in response to GnRH by pituitary cells from intact male rats (i.e. in the presence of androgen and functional androgen receptors) is less than that seen by cells from intact females rats. Since circulating levels of testosterone and estradiol are known to be elevated in the testicular feminized rat, the heightened GnRH-stimulated LH release by cells from such animals may reflect either the long term lack of androgenic influence and/or the combined effects of androgen resistance and elevated levels of circulating estrogens.     

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.     

Altered expression of genes involved in regulation of vitamin A metabolism, solute transportation, and cytoskeletal function in the androgen-insensitive tfm mouse testis

Androgens are essential for the development and maintenance of spermatogenesis, but the underlying mechanisms of androgen action in the testis remain unclear. To help clarify these mechanisms, gene expression was measured in testes of pubertal (20 d old), androgen-insensitive, testicular feminized (Tfm) mice and in normal controls. Using microarrays (Affymetrix chips 430A and 430B), initial data identified a large number of genes down-regulated in the Tfm testis (>4700). These genes were largely of germ cell origin, reflecting the arrest of spermatogenesis that is apparent in the 20-d-old Tfm testis. Subsequent screening in vitro and in silico of this gene set identified 20 genes of a somatic tubular origin that were significantly down-regulated in the Tfm testis and six genes that were significantly up-regulated. Altered expression of these genes was confirmed by real-time PCR, and genes down-regulated in the Tfm testis were shown to be up-regulated in testes of hypogonadal (hpg) mice treated with androgen. In a developmental study using real-time PCR most of the regulated genes showed normal expression during fetal and neonatal development and deviated from control only between 10 and 20 d. In all cases, expression was also reduced in the adult, although interpretation is more complex because of the inherent cryptorchidism in the adult Tfm mouse. Of the total number of somatic genes showing differential expression in the Tfm testis, 50% were associated with three separate groups of genes involved in regulation of vitamin A metabolism, solute transportation, and cytoskeletal function. Thus, effects of androgens on tubular function and spermatogenesis may be mediated in part through regulation of the tubular environment and control of retinoic acid concentrations.     

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.     

Endocrine status of the testicular feminized male (TFM) rat

The plasma levels of luteinizing hormone (LH), follicle stimulating hormone (FSH), testosterone (T), androstenedione (A), dihydrotestosterone (DHT), corticosterone and corticosterone binding globulin (CBG) were determined in 160- and 350-day testicular feminized male (tfm) and normal littermate (NL) rats. In the younger group the concentrations of T, A, DHT and 5α-androstan-3α,17β-diol (Adiol) were also determined in testis tissue.Tfm rats showed a greatly elevated plasma LH indicating lack of androgen feedback. Plasma FSH, however, was normal in both age groups, suggesting that inhibin production from tfm testes was relatively unaffected.Intratesticular concentrations of A were greatly elevated in the tfm animals at both ages whilst the testicular levels of T were highly reduced when compared to NL rats. This indicates a gonadal deficiency of the 17β-hydroxy steroid dehydrogenase (17β-HSD). Furthermore, the relatively low T: DHT ratio and high concentrations of Adiol in the tfm testes confirmed previous reports that the high 5α-reductase typical for the immature rat testis is maintained into adulthood in rats with the tfm condition. A considerable degree of peripheral conversion (A → T) probably helps to maintain normal or supranormal plasma levels of T. Gonadectomy rendered all plasma androgens undetectable, indicating that the adrenal contribution was negligible.Increasing age (350 days) was associated with a marked increase in circulating androgens in tfm rats. This is probably the reason for the observed significant reduction in circulating LH in this age group when compared to the 160-day animals. The aging tfm rat is predisposed to testicular tumors which, on the basis of histology, specific [¹²⁵I]hLH binding and in vitro responsiveness to hCG, appear to be of Leydig cell origin.Microflow fluorometry (MFF) of tfm testis cell suspensions revealed the presence of haploid cells, suggesting that meiosis proceeds to a limited extent.Plasma corticosterone levels in the tfm rat were normal although plasma CBG levels were highly significantly elevated at both ages when compared to the levels in NL rats. We suggest that the adrenal hyperplasia observed in tfm rats is secondary to reduced corticosterone production and diminished free corticosterone in the circulation.     

The quantitative distribution of cytosolic androgen receptors in microdissected areas of the male rat brain: effects of estrogen treatment

Estrogen and androgen synergize in the regulation of various neuroendocrine functions. To determine a potential cellular basis of this synergism, we measured androgen receptor (AR) in the cytosol of 16 hypothalamic and limbic nuclei and subregions in castrated male rats and castrated rats treated with estradiol. Androgen receptor was measured by a previously validated in vitro binding assay using the synthetic androgen methyltrienolone [( 3H]R1881). Male Sprague-Dawley rats (250-350 g) were castrated 2 weeks before the implantation of a 2.5-cm Silastic capsule filled with crystalline 17 beta-estradiol. Control rats were sham implanted. Estrogen treatment lasted for 1 week, after which time the animals were killed, their brains were frozen and sectioned, and individual nuclei and subregions were removed by a tissue punch technique. Tissue from six rats were combined for each determination. The highest levels of AR were found in the ventromedial nucleus (16.5 +/- 1.4 fmol/mg protein), medial preoptic area (12.1 +/- 1.4 fmol/mg protein), bed nucleus of the stria terminalis (11.6 +/- 1.4 fmol/mg protein), lateral septum (11.4 +/- 1.4 fmol/mg protein), arcuate nucleus-median eminence (10.9 +/- 2.1 fmol/mg protein), and medial amygdala (10.3 +/- 0.9 fmol/mg protein). Estrogen treatment resulted in significant increases in AR in medial preoptic area (14.8 +/- 0.6 fmol/mg protein; P less than 0.05) and medial amygdala (14.6 +/- 1.2 fmol/mg protein; P less than 0.02). Subsequent studies using block-dissected hypothalamus-preoptic area, anterior pituitary, and prostate revealed significant estrogen-mediated elevations in AR in anterior pituitary cytosol [42.2 +/- 3.0 vs. 26.4 +/- 1.6 fmol/mg protein (control); P less than 0.01], but not in hypothalamus-preoptic area or prostate cytosols. Estrogen treatment had no effect on AR affinity. The binding of [3H]R1881 was specific for AR and was not affected by the addition of radioinert progesterone to the incubation tube. Estimates of AR concentration were similar regardless of whether [3H]R1881 or [3H]dihydrotestosterone was used as the ligand. In this study, we describe the distribution of AR throughout the hypothalamus and limbic areas using biochemical techniques. In addition, we have identified some cellular events that may mediate the synergistic actions of estrogen and androgen on the neuroendocrine system.     

Regulation of the androgen and glucocorticoid receptors in rat and mouse skeletal muscle cytosol

Using a charcoal technique, we determined the relative binding affinity of some anabolic compounds for the androgen and glucocorticoid receptors in cytosol from rat skeletal muscle. Only a few of the compounds analyzed competed for the receptor-binding sites. The androgen and glucocorticoid receptors were analyzed in rat and mouse skeletal muscle cytosols by Scatchard analysis. In rats grouped according to sex and age, the cytosolic protein content was about the same in all groups, but the DNA content decreased with increased weight of the animal regardless of sex (male, female, or castrated male). The glucocorticoid receptor did not differ in concentration (2-3 pmol/g tissue) or ligand affinity (Kd, 10-40 nM) among the groups, but the androgen receptor concentration decreased with increased weight and age of the animals, more in the case of males than in the case of females or castrates. The Kd for the androgen receptor increased with age in males but was constantly about 0.2 nM for castrates or females. In adult intact rats, the androgen and glucocorticoid receptor concentrations in muscle cytosol from females were about 100 and 3000 fmol/g tissue, respectively, the corresponding values for males being about 50 and 2000 fmol/g tissue, respectively. Short term castration or adrenalectomy increased the concentration of and ligand affinity for the androgen and glucocorticoid receptors, respectively. After long term castration of male rats, the concentration of both receptors increased during 5 weeks to about the female level, only to decrease later. Neonatally castrated male rats had about the same androgen receptor concentrations and Kd values as female rats. Female mice had higher androgen receptor concentrations (approximately 700 fmol/g tissue) than rats. Intact male mice had about 200 fmol androgen receptor-binding sites/g tissue, and the same amount was found in mice bearing the testicular feminization (Tfm) mutant gene. In summary, the concentrations of androgen and glucocorticoid receptors in rat skeletal muscle are regulated at least by the testes. The presence of androgen receptors in skeletal muscle from Tfm mice is surprising and may motivate a reinvestigation of the regulation of androgen receptors in Tfm animals.     

Regulation of androgen receptors in Atlantic croaker brains by testosterone and estradiol

A nuclear androgen receptor (AR1), distinctly different from the mammalian AR, has previously been identified in the brain of the Atlantic croaker, Micropogonias undulatus. Interestingly, brain AR1 levels were higher in gonadally recrudesced than in regressed fish. Therefore, the possible involvement of gonadal steroids in the regulation of brain AR1 levels was investigated in the present study. Saturation analysis of [3H]testosterone binding showed that brain AR1 levels were significantly reduced (2-3-fold) in either the nuclear or cytosolic fractions of both males and females three weeks after gonadectomy. Implantation of gonadectomized females with testosterone or estradiol-17beta one week prior to sampling resulted in physiological plasma steroid concentrations and restored brain AR1 levels to 60-105% of those in intact or sham-operated fish. These results suggest that gonadal factors, including both androgens and estrogens, are involved in the physiological regulation of brain androgen receptors in a teleost species during the reproductive cycle.     

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.     

Androgen effects on hippocampal CA1 spine synapse numbers are retained in Tfm male rats with defective androgen receptors

The effects of estradiol benzoate (EB), dihydrotestosterone (DHT), or the antiandrogen hydroxyflutamide on CA1 pyramidal cell dendritic spine synapses were investigated in adult male rats. To elucidate the contribution of the androgen receptor to the hormone-induced increase in hippocampal CA1 synapses, wild-type males were compared with males expressing the Tfm mutation, which results in synthesis of defective androgen receptors. Orchidectomized rats were treated with EB (10 microg/rat.d), DHT (500 mug/rat.d), hydroxyflutamide (5 mg/rat.d), or the sesame oil vehicle sc daily for 2 d and examined using quantitative electron microscopic stereological techniques, 48 h after the second injection. In wild-type males, DHT and hydroxyflutamide both induced increases in the number of spine synapses in the CA1 stratum radiatum, whereas EB had no effect. DHT almost doubled the number of synaptic contacts observed, whereas hydroxyflutamide increased synapse density by approximately 50%, compared with the vehicle-injected controls. Surprisingly, in Tfm males, the effects of EB, DHT, and hydroxyflutamide were all indistinguishable from those observed in wild-type animals. These observations demonstrate that Tfm male rats resemble normal males in having no detectable hippocampal synaptic response to a dose of EB that is highly effective in females. Despite the reduction in androgen sensitivity as a result of the Tfm mutation, hippocampal synaptic responses to both DHT and a mixed androgen agonist/antagonist (hydroxyflutamide) remain intact in Tfm males. These data are consistent with previous results suggesting that androgen effects on hippocampal spine synapses may involve novel androgen response mechanisms.     

Pregnancy-specific beta 1-glycoprotein messenger ribonucleic acid and immunoreactive protein in the rat testis

Human pregnancy-specific beta 1-glycoprotein (PS beta G) is synthesized in large quantities by syncytiotrophoblasts of the placenta. Recent studies using a partial cDNA of PS beta G isolated from human term placenta detected the presence of mRNA highly homologous to placental PS beta G in a number of extraplacental tissues, including human and rat testis. The present study determined in the rat that the amount of PS beta G mRNA based on percentage of total tissue RNA was greatest in the testis of mature rats, followed by senescent and prepubertal rats. In experiments using rats with testicular feminization syndrome (Tfm) which exhibit end-organ insensitivity to androgen stimulation, slot blot analysis of testicular RNA showed reduced levels of PS beta G mRNA in Tfm rats compared to normal rats. Northern blot analysis of rat testicular RNA probed with a human placental PS beta G cDNA demonstrated the presence of a single mRNA species of 1.65 kilobases. Subsequent studies investigated whether proteins immunologically similar to PS beta G were present in the testes from normal and Tfm rats. The rat testes were perfused with fixative, and sections from paraffin-embedded tissues were treated with rabbit anti-human PS beta G, followed by the avidin-biotin-peroxidase complex. Testes from the normal rat showed intense immunostaining in late spermatids (steps 16, 17, 18, and 19 of spermiogenesis), residual bodies, as well as cytoplasm of Leydig cells. Spermatozoa within the epididymis also demonstrated intense immunolabeling. Paraffin sections of the testes from the Tfm rat showed light diffuse cytoplasmic immunostaining in cells of the seminiferous tubules. Since spermiogenesis does not proceed normally, and no spermatids were seen, it was not possible to accurately stage the seminiferous tubules of the Tfm rat. The Leydig cells of the Tfm testes stained intensely, however, as was observed in the testes of the normal rat. These data suggest that the rat may provide an animal model for the investigation of the biological function and regulation of PS beta G in the testis.     

Differences in the Brain and Pituitary β-Endorphin System between the Alcohol-Preferring AA and Alcohol-Avoiding ANA Rats

The content of pro-opiomelanocortin (POMC) mRNA was determined in the hypothalamus, as well as in the anterior and intermediate lobes of the pituitary gland of the alcohol-preferring AA and alcohol-avoiding ANA rats under basal conditions. In addition the content of beta-endorphin-like immunoreactivity (beta-EPLIR) was measured in nine brain regions, the anterior and intermediate lobes of the pituitary gland and the serum. The content of beta-EPLIR was significantly higher in the septum and significantly lower in the amygdala, and periaqueductal gray matter of the AA rats, while there was no significant difference between the AA and ANA rats in the arcuate nucleus plus median eminence, nucleus accumbens, caudate, hippocampus, and cortex. HPLC analysis indicated no significant differences in the relative proportions of non-acetyl and acetyl forms of beta-endorphin peptides in the hypothalamus, distinct brain regions, and anterior and neurointermediate lobes of the pituitary gland, between the AA and ANA rats. The content of POMC mRNA but not of beta-EPLIR was significantly higher in the hypothalamus and neurointermediate lobe of the AA rats, while the content of both beta-EPLIR and POMC mRNA were significantly higher in the anterior pituitary of the AA than of the ANA rats. Thus, there are genetically determined differences in the pituitary and brain beta-endorphin system between the AA and ANA rats, which may be important in controlling the differences in the voluntary ethanol consumption exhibited by these animals.     

Growth hormone (GH) response to GH-releasing hormone by perifused pituitary cells from male, female, and testicular feminized rats

To determine whether a normal complement of androgen receptors is required to permit full expression of sex-related differences in pituitary GH secretion, we compared the GHRH-stimulated GH secretory responses of continuously perifused anterior pituitary cells from normal male, normal female, and androgen-resistant testicular feminized (Tfm) rats. In each experimental replicate, acutely dispersed pituitary cells were exposed to GHRH (0.03-100 nM) administered as 2.5-min pulses in random order at 30-min intervals. The eluate was collected in 5-min fractions for GH determination by RIA. Basal unstimulated secretion of GH by cells from male rats was greater than that by cells from female (P = 0.007) and Tfm (P = 0.03) rats; basal secretion by the other two groups was similar (P = 0.55). Linear concentration-response relationships between GHRH and GH release were defined for cells from male (P = 0.0002), female (P = 0.0001), and Tfm (P = 0.0002) rats. Overall GHRH-stimulated GH secretion by cells from male rats was greater (P less than 0.0001) than that by cells from female rats. Overall secretion by cells from Tfm rats was less (P less than 0.001) than that by cells from male rats but greater (P less than 0.001) than that by cells from female rats. For all experimental groups, body weight was strongly correlated with both basal (r2 = 0.42; P = 0.001) and GHRH-stimulated (r2 = 0.53; P = 0.0001) GH secretion by the dispersed pituitary cells. These data suggest that a deficiency of androgen receptors results in a diminution of the in vitro GH secretory capability of anterior pituitary cells to a level below that by cells from normal males, but not to the level in normal females. The intermediate position of cells from the Tfm rat may represent a partial masculinization or defeminization within this generally female phenotype.     

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.