Salah E. Abdelgadir

Androgen receptor mRNA expression in the rhesus monkey ovary.

Immunocytochemical detection of androgen receptors (ARs) in several compartments of the macaque ovary, including the germinal epithelium, follicle, and corpus luteum, suggests a role for androgens in modulating ovarian function via the classical receptor-mediated pathway. To examine AR mRNA expression in the rhesus monkey ovary, total RNA was isolated from whole ovaries, the germinal epithelium-enriched cortical and medullary compartments of the ovary, and corpora lutea from early (d 3–5), mid (d 6–8), midlate (d 10–12), and late (d 13–15) stages of the luteal phase of the menstrual cycle. RNA was also obtained from luteinized granulosa cells from monkeys receiving gonadotropin treatment to stimulate the development of multiple ovarian follicles. After reverse transcription of total RNA using oligo-dT as a primer, polymerase chain reaction (PCR) was used to amplify a unique 329 bp segment of the monkey AR hormone-binding region. Reverse transcriptase (RT)-PCR products of the expected size were detected in all ovarian and control tissues. Sequence analysis of the AR cDNA from the macaque ovary revealed 99% nucleotide homology and 100% predicted amino acid homology to the cDNA for the hormone-binding region of human AR. Northern analysis demonstrated the presence of a major AR mRNA species at 9.5 kb in corpus luteum, luteinized granulosa cells, and prostate, with additional bands detected in the corpus luteum and prostate at 7.9 and 3.4 kb, respectively. A sensitive RNase protection assay was used to examine AR mRNA levels in ovarian tissues and showed AR mRNA expression throughout the life-span of the corpus luteum. Thus, detection of AR mRNA in the primate ovary, including the periovulatory follicle and corpus luteum, supports the concept that these tissues are targets for receptor-mediated androgen action during the menstrual cycle.

Sex differences in androgen-regulated cytochrome P450 aromatase mRNA in the rat brain.

The conversion of testosterone to estradiol by cytochrome P450 aromatase (P450AROM) in the medial preoptic area is required for full expression of male sexual behavior in rats. Preoptic P450AROM activity is stimulated by androgens through an androgen-receptor mediated mechanism that regulates P450AROM gene expression. The mechanism of enzyme induction appears to be sexually dimorphic in several species leading to greater testosterone-stimulated P450AROM activity in males than in females. The present study was designed to determine whether the sex difference in androgen-regulated P450AROM activity is manifested at the levels of mRNA expression. We compared the concentrations of P450AROM mRNA and enzyme activity between five different treatment groups: intact males, castrated males (CX), ovariectomized females (OVX), CX males treated with dihydrotestosterone (CX+DHT), and OVX females treated with DHT (OVX+DHT). We found that unstimulated levels of P450AROM mRNA and enzyme activity in both the preoptic area and medial basal hypothalamus were similar in the CX and OVX groups. However, when treated with equivalent doses of DHT, the levels of P450AROM mRNA and enzyme activity in both brain regions were significantly higher in males than in females (i.e., CX+DHT group >OVX+DHT group). These results demonstrate that sex differences in the regulation of P450AROM in brain are exerted pretranslationally by androgen and suggest that gender differences in androgen responsiveness play an important role in regulating gene expression in the adult rat brain.

Androgen Regulation of Androgen Receptor Messenger Ribonucleic Acid Differs in Rat Prostate and Selected Brain Areas

Androgens bind to specific high-affinity receptors (AR), thereby initiating gene transcription. We investigated the effects of testosterone (T), dihydrotestosterone (DHT), and 17beta-estradiol (E(2)) on AR transcription and binding in prostate, medial basal hypothalamus (MBH), preoptic area (POA), amygdala, hippocampus, and cortex in the rat. Androgen receptor mRNA was measured by a ribonuclease protection assay. Cytosolic and nuclear AR binding (ARc and ARn, respectively) were measured by in vitro binding assays. In the prostate AR mRNA levels were low in intact animals. Castration produced a fourfold elevation of AR mRNA which was reduced to intact values by treatment with T or DHT (P < 0.05; n = 4). E(2) had no effect compared to castrate levels. In contrast to the prostate, no treatment effect was observed on the expression of AR gene in the MBH, POA, amygdala, hippocampus, or cortex. On the premise that treatment effects on AR mRNA in the brain may require longer than 48 h, we treated rats for 4 and 7 days and found no treatment effect on the expression of AR mRNA in MBH, POA, or amygdala. Next, we compared AR binding with its mRNA between prostate and various brain areas. Castration significantly increased ARc and reduced ARn compared to intact levels, and androgen treatments restored both ARc and ARn to intact values in prostate and brain areas (P < 0.05; n = 5). Changes in AR mRNA levels in prostate corresponded to changes in ARc but not ARn in castrated and androgen-treated males, which suggests that ARc is newly synthesized receptor. In contrast, ARc differed quantitatively between prostate and neural tissues. These results show that DHT regulates AR transcription in rat prostate as effectively as T. Our data also suggest that AR gene transcriptional activity in prostate and selected brain areas may be subjected to differential regulatory mechanisms. This may be due to the presence of tissue-specific regulatory proteins.

Androgen binding in peripheral tissues of fetal rhesus macaques: Effects of androgen metabolism in liver ☆

In rhesus monkeys sexual differentiation of the brain and reproductive tract (RT) is androgen-dependent. Presumably these effects are mediated through the androgen receptor (AR). The AR has not been characterized in fetal tissues such as liver, kidney, heart, spinal cord and RT in this species. We characterized AR binding using [3H]R1881 as the ligand in cytosols from tissues obtained on days 100-138 of gestation. Scatchard analyses revealed a single, saturable, high affinity AR in liver, kidney, heart, spinal cord and RT. The apparent dissociation constant (Kd) ranged from 0.52 to 0.85 nM with no significant tissue differences. The number of AR (Bmax; fmol/mg protein) differed significantly (P less than 0.01) between tissues (liver greater than RT much greater than kidney greater than or equal to heart greater than or equal to spinal cord). Radioinert testosterone (T) and 5 alpha-dihydrotestosterone (DHT) but not androstenedione, progesterone, estradiol-17 beta, estrone or cortisol in a 50-fold molar excess inhibited [3H]R1881 binding to the AR in spinal cord, heart, kidney and RT. However, in liver only DHT competed significantly (P less than 0.01) for binding. This difference in binding of DHT vs T in the liver was further investigated by incubating liver and kidney cytosols with [3H]DHT and [3H]T at 4 degrees C. We identified the metabolic products by mobility on Sephadex LH-20 columns and reverse isotope dilution. Liver cytosols metabolized [3H]DHT to 5 alpha-androstane- 3 alpha,17 beta-diol (5 alpha-diol) and [3H]T to 5 beta-androstane-3 alpha, 17 beta-diol (5 beta-diol) at 4 degrees C. In contrast, kidney cytosols metabolized [3H]DHT while [3H]T remained unchanged. Further studies indicated that a 50-fold molar excess of 5 alpha-diol inhibited the binding of [3H]R1881 in liver cytosols by about 50% whereas the same molar concentration of 5 beta-diol had no effect. These data demonstrate the presence of AR in peripheral tissues of fetal rhesus monkeys and suggest that androgens through their receptors may affect development of these tissues. Liver cytosols are capable of metabolizing T and DHT at 4 degrees C at conditions similar to those used for measuring cytosolic AR. However, T and DHT are metabolized differently, generating different isomers which have different affinities for hepatic AR.

Androgen metabolism by hepatic and renal tissues of the fetal rhesus monkey

Liver and kidney from fetal monkeys (day 125 of gestation) were fractionated into low speed pellets, microsomal and cytosolic fractions. Liver cytosols converted as much testosterone (T) to 5 beta-androstane-3 alpha,17 beta-diol (5 beta-diol) at 0 degrees C as at 4 degrees-45 degrees C without exogenous cofactors. The principal product formed from 5 alpha-dihydrotestosterone (5 alpha-DHT) was 5 alpha-diol. A 1000-fold molar excess of radioinert 5 beta- or 5 alpha-DHT inhibited 5 beta-diol formation from [3H]T by cytosols and increased 5 beta-DHT formation. Similarly, using 5 alpha-DHT as substrate, 5 alpha-diol formation was inhibited. Microsomal and low speed pellets with added cofactors formed products which recrystallized with either etiocholanolone or androsterone from [3H]T or [3H]DHT, respectively. Little product was formed without cofactor. Whole liver homogenates produced 5 beta-reduced products from [3H]T in the presence of an NADPH generating system whereas kidney homogenates produced 5 alpha-reduced products. These data provide new information on the capacity of fetal monkey liver and kidney to metabolize androgens. The 3 alpha-reductases are cytosolic. The 5 alpha- and 5 beta-reductases are mostly in the low speed pellet but are sufficiently represented in cytosols to mediate diol formation. The 17-hydroxysteroid dehydrogenases are in the microsomal fraction. Our results suggest that 5 alpha-DHT is the active androgen in fetal liver since testosterone is metabolized to 5 beta-DHT and 5 beta-diol which are inactive androgens.