Relative potency of testosterone and dihydrotestosterone in preventing atrophy and apoptosis in the prostate of the castrated rat.

Although dihydrotestosterone (DHT) is the principal androgen in the prostate, testosterone can also act as an androgen in this tissue. To determine the relative potencies of testosterone and DHT in preventing prostate regression, castrated rats were implanted for 4 d with varying doses of testosterone in the presence or absence of the 5alpha-reductase inhibitor finasteride. In the absence of finasteride, testosterone in the prostate is converted to DHT, creating an intraprostatic DHT dose response. In the presence of finasteride, this conversion is blocked, and an intraprostatic testosterone dose response is achieved. DHT was 2.4 times more potent than testosterone at maintaining normal prostate weight and duct lumen mass, a measure of epithelial cell function. The two androgens were equipotent at preventing DNA fragementation and expression of testosterone-repressed prostate message, two measures of apoptosis (cell death). The intraprostatic testosterone concentration that results from finasteride treatment in rats is sufficient to inhibit apoptosis but will not maintain normal epithelial cell activity. In conclusion, whereas DHT is more potent than testosterone at stimulating prostate epithelial cell function as measured by ductal mass, the two androgens are equipotent at preventing prostate cell death after castration. These results explain why finasteride causes prostate involution in the rat with minimal evidence of prostate cell death.

Differential effect of 5 alpha-reductase inhibition and castration on androgen-regulated gene expression in rat prostate.

Castration reduces prostate size and causes intraprostatic testosterone (T) and dihydrotestosterone (DHT) to fall to very low levels. 5 alpha-Reductase inhibition also reduces prostate size, but results in a marked increase in intraprostatic T levels. To compare the effects of 5 alpha-reductase inhibition and castration on prostate physiology, male Sprague-Dawley rats were left intact, castrated, or given the selective 5 alpha-reductase inhibitor finasteride for up to 9 days. To be sure that finasteride itself did not directly affect gene expression, an additional group of rats was castrated and given finasteride for 4 days. The prostates were weighed, intraprostatic RNA, DNA, and androgen levels were measured, and mRNAs for two androgen-regulated genes, prostate steroid-binding protein (PSBP; an androgen-induced gene) and testosterone-repressed prostate message (TRPM-2), were quantitated by Northern and slot blot analyses. Finasteride caused a 95% reduction in intraprostatic DHT levels and a 10-fold increase in intraprostatic T levels. Finasteride, as expected, caused a pronounced decrease in prostate weight (45% on day 4). DNA content fell correspondingly (48% on day 4). Intraprostatic DNA (micrograms of DNA per gland) on day 4 was 328 +/- 53 in control rats, 171 +/- 10 in finasteride-treated rats (P less than 0.001 compared to controls), 115 +/- 2 in castrated rats (P less than 0.05 compared to finasteride), and 107 +/- 43 in finasteride-treated plus castrated rats (P = NS compared to castration alone). There were no significant differences in DNA levels among the groups when expressed per mg prostate tissue, indicating that mean prostate cell size was unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)

Preferential metabolism of dihydrotestosterone to androstanediol 17-glucuronide in rat prostate.

Androstanediol glucuronide (Adiol G), a marker of peripheral dihydrotestosterone (DHT) metabolism and action, may be conjugated through the hydroxyl group at either the 3-carbon (Adiol 3-G) or 17-carbon (Adiol 17-G) position. Adiol 17-G is the predominant Adiol G isomer derived from DHT in normal men. To determine whether peripheral tissues may be responsible for this selective conversion of DHT to Adiol 17-G, a glucuronyl transferase assay was developed using rat prostate cells. Adiol 17-G was separated from Adiol 3-G by HPLC and selective precipitation with an antibody specific for Adiol 3-G. Using androstanediol (Adiol) as a substrate, enzyme kinetics were linear with respect to time and enzyme concentration. In the presence of 0 or 5 microM Adiol and 1 microCi [3H]Adiol, greater than 99% of the resulting Adiol G was Adiol 17-G. The percent conversions of DHT, Adiol, and androsterone to their glucuronide conjugates were 0.22%, 3.5%, and 0.24%/10(6) prostate cells, respectively. Using DHT as an inhibitor of Adiol glucuronidation, the Ki was 39.1 microM, compared to an apparent Km for Adiol of 15 microM. We conclude that rat prostate cells can selectively convert Adiol to Adiol 17-G, and that Adiol glucuronidation is favored over that of DHT or androsterone under these experimental conditions. Since DHT and Adiol are readily interconvertable, these results suggest that Adiol 17-G is the major DHT metabolite in the rat prostate.

Androgen-induced regrowth in the castrated rat ventral prostate: role of 5alpha-reductase.

Testosterone (T), the major circulating androgen, must be converted to dihydrotestosterone (DHT) by the enzyme 5alpha-reductase (5alpha-R) to be maximally active in the prostate. The present study was designed to determine the relative potency of T and DHT on regrowth of the involuted prostate and to elucidate the role of 5alpha-R in the growing prostate. To create dose-response curves for intraprostatic T or DHT, rats were castrated for 2 weeks to allow their prostates to fully regress and then given T implants of various sizes in the presence or absence of the 5alpha-R inhibitor, finasteride. Markers for androgen effects on regrowth of the prostate were prostate weight, duct mass (a measure of secretory activity) and DNA content (a measure of cell number). To assess the relative uptake of T and DHT by the prostate, a comparison was made of intraprostatic DHT levels resulting from T and DHT implants. In the prostate, 1.6-1.9 times more T than DHT was required to achieve a half-maximal response for each of the three markers of prostate regrowth. The dose-response curves revealed that thresholds for intraprostatic T and DHT had to be attained before significant growth was observed. The threshold for T was 2- to 3-fold greater than that for DHT. However, at high intraprostatic concentrations, the effects of T mimicked those of DHT. When the relationship between serum T levels and prostate regrowth was considered, 13 times more serum T was required for half-maximal prostate regrowth when its conversion to DHT was blocked by finasteride. This is partly due to decreased androgen accumulation in the prostate when T was the major intraprostatic androgen. Finally, T or DHT implants in the absence of finasteride resulted in similar intraprostatic DHT levels, indicating that uptake of each serum androgen into the prostate was similar. However, to achieve similar levels of DHT or T in serum, much larger DHT pellets were needed, suggesting more rapid metabolism of DHT in tissues other than the prostate. We conclude that the role of 5alpha-R is 2-fold: it converts testosterone into a modestly more potent androgen and enhances prostatic accumulation of androgen. DHT, in principle, could serve equally well as T as the circulating androgen, although the rate of DHT production would have to be considerably higher to counter the apparent rapid clearance from serum. In addition, we hypothesize that T has arisen as the major circulating androgen instead of DHT because it can be aromatized to estradiol, which itself has important roles in male reproductive function and bone physiology.

Evidence for atrophy and apoptosis in the ventral prostate of rats given the 5 alpha-reductase inhibitor finasteride.

Castration causes cell loss in the rat ventral prostate through a process called apoptosis. Although 5 alpha-reductase inhibition also causes prostate cell loss, the mechanisms involved have been debated. To investigate this question further, we have evaluated the histological responses of the rat ventral prostate to both castration and 5 alpha-reductase inhibition. Rats were left intact, castrated, or given the selective 5 alpha-reductase inhibitor finasteride. After 4, 9, 14, and 21 days the prostates were excised, the androgen and DNA content determined, and the tissue was subjected to histological and histomorphometric analysis. Finasteride and castration decreased prostate weight at day 21 by 65% and 93%, respectively. Castration decreased DNA content (micrograms per prostate) by a maximum of 88% at 14 days. Finasteride had no significant effect on DNA content after 4 days and decreased DNA content by a maximum of 52% at 14 days. When castrate prostate sections were stained for tissue transglutaminase, a marker of apoptotic cell death, a maximum of 23% of epithelial cells were stained by day 14 with a return to control levels by day 21. Finasteride caused a less intense increase in staining in which 16% of epithelial cells stained for tissue transglutaminase on day 9 with a return to baseline by day 14. When prostate sections were stained for DNA breaks, another marker of cell death, castration, caused a peak of staining on day 4 with 6% of epithelial cells staining and a return to near control levels by day 21. Finasteride-induced staining was less intense with peak staining at day 4 (0.7% of epithelial cells) and a return to control values by day 9. Morphometrics were used to assess the effect of castration and finasteride on prostate duct size and epithelial cell mass. After 4 days of finasteride treatment, the mean ductal mass decreased by 47%, with no significant change thereafter. The mean epithelial cell mass decreased by 15% on day 4 and 60% on day 9, with no further decrease thereafter. Castration caused a more rapid and greater decrease in both morphometric parameters with a 95% reduction in the mass of prostate ducts and a 93% decrease in epithelial cell mass by day 9. We conclude that castration induces a more profound involution of the rat ventral prostate than does 5 alpha-reductase inhibition. Cell loss occurs in both groups, but the degree of cell loss is less with finasteride.(ABSTRACT TRUNCATED AT 400 WORDS)

Differential suppression of testosterone and estradiol in hirsute women with the superactive gonadotropin-releasing hormone agonist leuprolide.

To determine the dose of the GnRH agonist leuprolide necessary to maximally suppress ovarian testosterone secretion, 10 moderately to severely hirsute women (5 with idiopathic hirsutism and 5 with polycystic ovarian syndrome) were given gradually increasing leuprolide doses, starting with either 5 or 10 micrograms/kg.day. Serum testosterone and estradiol, basal LH, and the LH response to GnRH were measured before and at the end of each treatment period, until maximal suppression of estradiol and testosterone occurred. Leuprolide was then continued for a total of 6 months to assess its clinical efficacy. Hirsutism scores and hair growth rates were determined before and after therapy. Serum estradiol and the LH response to GnRH were maximally or near-maximally suppressed in all women by the lowest doses of leuprolide used. Basal serum LH was not maximally suppressed in all women until a dose of 15 micrograms/kg.day was reached, and maximal testosterone suppression required 15 micrograms/kg.day or more in 7 of the 10 women. The addition of 0.5 mg dexamethasone daily for 4 weeks at the end of the study in 5 of the women reduced serum testosterone to undetectable levels. Symptomatic improvement in hirsutism occurred in 9 women, hirsutism scores decreased by at least 3 points in 5 women, and hair growth rates decreased in 8 women. These data indicate that low doses of leuprolide were sufficient to maximally suppress serum estradiol and the LH response to exogenous GnRH. Higher leuprolide doses were needed to maximally suppress serum testosterone and the basal LH levels. Leuprolide (20 micrograms/kg.day) effectively reduced hair growth in the majority of these women.

Clinical review 73: Medical treatment of androgen-dependent hirsutism.

Although hirsutism is more a cosmetic and psychosocial problem than a disease, hirsute women are often some of the most grateful patients in an endocrinologist's practice. The combination of mechanical hair removal and judicious use of medications will improve hair growth in most women. Unfortunately, no drug is approved by regulatory agencies in North America for treatment of hirsutism. Well designed comparative studies with objective end points are needed to demonstrate which drugs work best in which hirsute women. Because pharmaceutical companies are reluctant to market drugs for women of child-bearing age, there has been little industry support for such studies.

Effect of leuprolide and dexamethasone on hair growth and hormone levels in hirsute women: the relative importance of the ovary and the adrenal in the pathogenesis of hirsutism.

Ten hirsute women with polycystic ovarian syndrome (PCO) and nine with idiopathic hirsutism (IH) underwent selective ovarian suppression with leuprolide for 5-6 months and then were randomized to receive, in addition, dexamethasone or placebo for 4 more months. Serum hormone levels and hair growth rates were determined before and after each treatment period. During the initial treatment period with leuprolide alone, testosterone decreased by 54 +/- 6% (mean +/- SEM) in PCO and by 36 +/- 3% in IH (P = 0.02). Androstenedione decreased by 53 +/- 6% in PCO and by 31 +/- 7% in IH (P = 0.02). Androstanediol glucuronide (Adiol-G) decreased by 14 +/- 6% in PCO and by 7 +/- 3% in IH. There was no change in dehydroepiandrosterone sulfate (DHEAS). While initial serum androgen levels were higher in PCO than in IH, they were similar after ovarian suppression in the two groups. After ovarian suppression, Adiol-G was more consistently correlated with testosterone and androstenedione than was DHEAS, suggesting that Adiol-G may be a better marker than DHEAS of adrenal androgen secretion. Hair growth rates decreased by 37 +/- 6% in PCO and by 14 +/- 10% in IH (P = 0.07). The change in hair growth correlated with the change in androstenedione (r = 0.66; P = 0.002), but not significantly with the change in testosterone (r = 0.29; P = 0.2). After the addition of dexamethasone therapy (0.5 mg daily), testosterone, androstenedione, and DHEAS levels fell to near or below assay detection limits, while Adiol-G decreased by 80 +/- 3%. Hair growth rates decreased slightly more in women during dexamethasone (46 +/- 6%) than during placebo (26 +/- 9%; P = 0.18). In summary, the ovary was the major source of circulating testosterone and androstenedione in PCO. The adrenal contributed a substantial minority of these hormones in PCO and was the major source of androgen secretion in IH. Adrenal hyperandrogenism was common in both IH and PCO. Hair growth rates correlated best with changes in serum androstenedione levels. Adiol-G, which was derived primarily from adrenal precursors, was a better marker of adrenal androgen secretion than was DHEAS in these subjects.

Effect of daily and alternate day low dose prednisone on serum cortisol and adrenal androgens in hirsute women.

To test the hypothesis that alternate day prednisone treatment more effectively suppresses adrenal androgen secretion (compared to cortisol secretion) than daily prednisone treatment, we measured serum dehydroepiandrosterone (DHEA), DHEA sulfate (DHEAS), and cortisol concentrations during these two prednisone treatment schedules in eight hirsute women. The women were assigned randomly to receive either a daily nighttime dose of prednisone (100 micrograms/kg) or an alternate nighttime prednisone dose (200 micrograms/kg) for 4 months. During the following 4 months the women received the other schedule. Serum hormone levels were measured 0, 4, and 8 months before and after iv administration of 25 U synthetic ACTH. To optimally compare the daily and alternate day prednisone regimens, hormonal determinations were made on 2 successive days (days 1 and 2) after the last dose of prednisone. We found no evidence for greater suppression of adrenal androgens or lesser suppression of cortisol with alternate day prednisone treatment. Basal serum DHEA and DHEAS concentrations were suppressed to a greater degree than was cortisol during both daily and alternate day prednisone treatments. ACTH-stimulated DHEA and cortisol concentrations were equally suppressed. Only two of the eight women noted improvement in hirsutism during the study, and four women gained weight. Thus, adrenal androgen secretion was more easily suppressed than was cortisol secretion by this low dose of glucocorticoid, but there was no advantage to alternate day therapy.

Androsterone sulfate: physiology and clinical significance in hirsute women.

Androsterone sulfate (Andros-S) is the most abundant 5 alpha-reduced androgen metabolite in serum. To determine whether this steroid could serve as a marker of 5 alpha-reductase activity, we developed a specific RIA, using tritiated Andros-S to assess procedural losses. Baseline serum Andros-S levels (mumol/L; mean +/- SEM) in 14 hirsute women (3.0 +/- 0.4) were not reduced by ovarian suppression with leuprolide (3.0 +/- 0.3), but were decreased by 79% with combined ovarian and adrenal suppression with leuprolide and dexamethasone. The mean Andros-S level in polycystic ovarian syndrome (3.2 +/- 0.4) and in idiopathic hirsutism (3.5 +/- 0.5) was not significantly different from levels in normal women (3.0 +/- 0.5), but were significantly greater than levels in obese women (1.7 +/- 0.3; P < 0.05). The serum concentrations of Andros-S were about 10-fold greater than those of androsterone glucuronide and 100-fold greater than those of androstanediol glucuronide. Serum Andros-S concentrations correlated strongly with dehydroepiandrosterone sulfate (R = 0.59; P < 0.001) and to a lesser degree with androstanediol glucuronide and androsterone glucuronide (R = 0.28 and 0.49, respectively). There was a weak correlation with androstenedione levels and the androstenedione response to ACTH (R = 0.38 and 0.34, respectively), and no significant correlation with serum testosterone (R = 0.19). The ratio of any of the 5 alpha-reduced products (Andros-S, androstanediol glucuronide, and androsterone glucuronide) to precursors (androstenedione and testosterone) was not increased in hirsute women, suggesting that these women did not have a generalized increase in 5 alpha-reductase activity. In conclusion, these results confirm that Andros-S is the most abundant 5 alpha-reduced androgen metabolite in serum. It is primarily, if not exclusively, of adrenal origin in hirsute women. The fact that its levels were not elevated in hirsutism, although those of other adrenal androgens and androgen metabolites (androstanediol glucuronide and androsterone glucuronide) were, suggests that variations in sulfotransferase activity or metabolic clearance of Andros-S may be important determinants of serum Andros-S levels. Although Andros-S may be a marker of systemic 5 alpha-reductase activity, there was no evidence of a generalized increase in 5 alpha-reductase activity in hirsute women. Andros-S is therefore not recommended as a marker of either adrenal androgen production or of hirsutism.

The role of adrenal hyperandrogenism, insulin resistance, and obesity in the pathogenesis of polycystic ovarian syndrome.

Hyperandrogenism, insulin resistance, and obesity are common features of polycystic ovarian syndrome (PCOS). This study was designed to investigate the relationship among these factors and how they might contribute to ovulatory dysfunction in PCOS. Adrenal androgen secretion and insulin resistance were quantified in oligomenorrheic women with PCOS and in three groups of eumenorrheic women: weight-matched hirsute women, obese nonhirsute women, and thin nonhirsute women. Adrenal androgen secretion was defined as the androstenedione response to synthetic corticotropin. Insulin resistance was estimated by calculating the area under the curve for serum insulin levels in response to a 75 g oral glucose load. The mean serum androstenedione response (nmol/L) to corticotropin in PCOS (5.6 +/- 1.3) was greater than that in eumenorrheic hirsute women (3.4 +/- 0.5; P < 0.10), obese nonhirsute women (1.8 +/- 0.8; P < 0.05), and lean nonhirsute women (1.9 +/- 0.5; P < 0.05). The serum androstenedione response was not correlated with body mass index (BMI). The area under the curve for serum insulin (mU/L.min/1000) in PCOS (29.1 +/- 5.3) was greater (P < 0.001) than in eumenorrheic hirsute women (9.1 +/- 1.7), obese nonhirsute women (5.8 +/- 1.0), and lean nonhirsute women (4.5 +/- 0.4). The serum insulin response was highly correlated with BMI (P < 0.001) in the three groups of obese women, but women with PCOS became significantly more insulin resistant with increasing BMI (P < 0.02). There was no correlation between adrenal androgen secretion and insulin resistance in any of the groups. We conclude that adrenal hyperandrogenism and insulin resistance are independent predictors of anovulation in hirsute women. These conditions are present in both oligomenorrheic and eumenorrheic hirsute women, but are present to a greater extent in anovulatory women. Obese women with PCOS also differ from eumenorrheic controls by developing a greater degree of insulin resistance as body mass increases.

Sensitivity of cortisol and adrenal androgens to dexamethasone suppression in hirsute women.

To test the hypothesis that adrenal androgen secretion is more easily suppressed than is cortisol secretion by glucocorticoids, we examined the dose-response relationship for suppression of serum dehydroepiandrosterone (DHA), DHA sulfate (DHAS), testosterone, and cortisol by dexamethasone. Nine hirsute women received daily doses of dexamethasone, starting with 0.1 mg and increasing by 0.1-mg increments every 4 weeks, until the cortisol response to ACTH was reduced to 20% or less of the response before treatment. Serum hormone levels were measured at each dexamethasone dose before and after iv administration of 25 U synthetic ACTH. Although low doses of dexamethasone caused a similar suppression of basal cortisol, DHA, and DHAS levels, ACTH-stimulated DHA levels were suppressed to a greater extent than ACTH-stimulated cortisol levels. Higher dexamethasone doses did not result in a significant difference between the degree of cortisol and adrenal androgen suppression, as near-maximal suppression occurred for all three hormones. Maximal suppression of basal testosterone levels occurred at or below the dexamethasone dose of 0.3 mg. We conclude that the adrenal androgen secretory capacity is more sensitive to suppression by dexamethasone than is the adrenal cortisol secretory capacity. Furthermore, glucocorticoid therapy for hirsutism need not achieve complete cortisol suppression to effect a major reduction in adrenal androgen levels.

Androstanediol glucuronide isomers in normal men and women and in men infused with labeled dihydrotestosterone.

3 alpha-Androstanediol glucuronide (Adiol G) is a major metabolite of dihydrotestosterone (DHT). Adiol G actually represents 2 different compounds, since the glucuronide can be conjugated at the 3-carbon position (Adiol 3-G) or at the 17-carbon position (Adiol 17-G). To determine which glucuronide represents the predominant physiological DHT metabolite and which isomer is the major circulating form, we developed a RIA to directly measure Adiol 3-G in serum extracts. In 10 normal men, mean serum Adiol 3-G and total Adiol G levels were 4.44 +/- 0.49 (+/- SE) nmol/L (208 +/- 23 ng/dL) and 27.9 +/- 2.8 nmol/L (1310 +/- 129 ng/dL), respectively (13.9 +/- 3.0% of Adiol G was Adiol 3-G). In 10 normal women sampled during the early follicular phase, mean serum Adiol 3-G and total Adiol G levels were 2.64 +/- 0.64 nmol/L (124 +/- 30 ng/dL) and 14.9 +/- 1.5 nmol/L (697 +/- 69 ng/dL), respectively (17.4 +/- 3.6% of Adiol G was Adiol 3-G). In 4 normal men infused for 8 h with tritiated DHT, 17.4 +/- 3.4% of the resulting tritiated Adiol G was Adiol 3-G. These results indicate that Adiol 17-G is the predominant circulating form of Adiol G in normal men and women and that it is also the major Adiol G isomer derived from DHT.

Evidence for atrophy and apoptosis in the prostates of men given finasteride.

Finasteride, a 5 alpha-reductase inhibitor, decreases prostate size and improves symptoms in men with benign prostatic hyperplasia. However, little is known about prostate histopathology in men taking finasteride. To determine the mechanism by which finasteride reduces prostate size, tissue was collected at the time of prostatectomy from men taking either no medication (n = 10) or 5 mg finasteride daily for 6-18 days (n = 6; group 1), 23-73 days (n = 5; group 2), or 3 months to 4 yr (n = 5; group 3). To assess whether finasteride causes epithelial atrophy, morphometric measurement of epithelial cell and duct width was used. The mean epithelial cell width in control prostates (mean +/- SEM, 21 +/- 0.7 microns) decreased with duration of treatment to 19 +/- 1 microns in group 1, 15 +/- 2 microns in group 2, and 8 +/- 0.3 microns in group 3. Mean duct width decreased from 135 +/- 6 microns in the control prostates to 128 +/- 10 microns in group 1, 103 +/- 3 microns in group 2, and 63 +/- 6 microns in group 3. To assess whether prostate cell death was occurring, sections were in situ end labeled for DNA breaks and immunostained for tissue transglutaminase (tTG), a marker of apoptosis (programmed cell death). The percentage of epithelial cells staining for DNA breaks was 0.4 +/- 0.2 in control prostates, 2.8 +/- 0.9 in group 1, 1.7 +/- 0.5 in group 2, and 0.7 +/- 0.3 microns in group 3. Anti-tTG staining of epithelial cells was graded on a scale of 0-4. In control prostates, 3 +/- 1% of the ducts were grade 3 or 4 (> 50% of epithelial cells staining). In finasteride-treated prostates, 2 +/- 2% of the prostates in group 1, 13 +/- 4% of the prostates in group 2, and 0.5 +/- 0.5% of the prostates in group 3 were grade 3-4. These results indicate that a progressive decrease in epithelial cell size and function occurs during the first several months in the prostates of men treated with finasteride. The staining for DNA breaks and the tTG staining also indicate that an increased rate of apoptosis is occurring transiently in these prostates. We conclude that finasteride causes prostate involution through a combination of atrophy and cell death.

The effects of N,N-diethyl-4-methyl-3-oxo-4-aza-5 alpha-androstane-17 beta-carboxamide, a 5 alpha-reductase inhibitor and antiandrogen, on the development of baldness in the stumptail macaque.

We used a primate model of male-pattern baldness to test the efficacy of a topically applied 5 alpha-reductase inhibitor and antiandrogen (4-MA) in the prevention of baldness. Six periadolescent stumptail macaques were given daily topical applications of either 4-MA in dimethylsulfoxide or dimethylsulfoxide alone for 27 months. The three control monkeys developed varying degrees of baldness, while the three 4-MA-treated monkeys retained their juvenile pattern of hair growth. The percentage of actively growing hair follicles in the frontal scalp did not change in the 4-MA-treated group [46 +/- 6 (+/- SE) vs. 48 +/- 4], while a significant decrease occurred in the control group (63 +/- 6 vs. 25 +/- 12; P less than 0.025). Skin 5 alpha-reductase activity was reduced in the scalp of the 4-MA-treated monkeys. We conclude that topical 4-MA can prevent the development of baldness in the stumptail macaque, a primate model of androgen-dependent baldness.

Clinical and biochemical parameters of androgen action in normal healthy Caucasian versus Chinese subjects.

Stimulation of androgen-sensitive hair follicles is mediated by dihydrotestosterone (DHT), which is formed in these tissues by 5 alpha-reduction of testosterone. A possible mechanism for increased body hair in some human populations might, therefore, be an increase in 5 alpha-reductase activity, resulting in elevated tissue levels of DHT. If present, this finding could have other important clinical implications, since the 5 alpha-reductase enzyme is pivotal in the pathophysiology of prostatic disease. To explore differences in clinical and biochemical parameters of androgen action, we conducted a study of 184 caucasian and Chinese subjects in whom we evaluated chest hair density and serum levels of androgen precursors and 5 alpha-reduced androgen metabolites. Differences in chest hair density were most notable in the men, in whom comparative mean chest hair scores (using a scale of 0-4) were 3.0 vs. 0.8 (P less than 0.0001), caucasian vs. Chinese. Levels of 5 alpha-reduced androgen products were also strikingly higher in the caucasian vs. Chinese subjects. Serum 3 alpha-androstanediol glucuronide levels (nanomoles per L) were 34.7 +/- 2.4 vs. 19.7 +/- 0.9 (P less than 0.001) for the men and 21.5 +/- 3.2 vs. 9.4 +/- 0.6 (P less than 0.001) for the women, and serum levels of androsterone glucuronide (nanomoles per L) were 179 +/- 26 vs. 107 +/- 7 (P less than 0.01) for the caucasian vs. Chinese men and 173 +/- 23 vs. 81 +/- 9 (P less than 0.001) for the women. Serum levels of total and bioavailable testosterone did not differ between the racial groups, but serum levels of the precursor androgens, dehydroepiandrosterone sulfate and androstenedione, were significantly higher in the caucasian vs. Chinese men, but not in the women. We conclude that increased serum levels of 5 alpha-reduced androgen metabolites in caucasians vs. Chinese subjects provide circumstantial evidence for a racial difference in 5 alpha-reductase activity and suggest a mechanism for the increased body hair observed in the caucasian men. Increased levels of precursor androgens may also play a role.

Testolactone-associated high androgen levels, a pharmacologic effect or a laboratory artifact?

Testolactone, an aromatase inhibitor, blocks conversion of androgens to estrogens. In familial male precocious puberty, slowing of pubertal progression and growth velocity occurs with testolactone and spironolactone. Girls with McCune-Albright syndrome, given testolactone, respond similarly. A 2-yr-old female (case 1) on testolactone for non-McCune-Albright gonadotropin independent precocious puberty had marked elevations of androstenedione (18 ng/mL, normal: 0.2-3.1) and testosterone (3.6 ng/mL, normal < 0.2) but no virilization. Investigations were undertaken to determine whether elevations in testosterone and androstenedione were caused by interference in these RIAs. After a single oral dose of testolactone (5 mg/kg in case 1; 4 mg/kg in case 2, a 3-yr-old boy with familial male precocious puberty; 10 mg/kg in a healthy postmenopausal control), serum testosterone and androstenedione were measured serially by RIA for 24 h. Androstenedione went from normal to a mean peak of 45.4 ng/mL at 1-2 h and returned to baseline by 24 h. Testosterone, undetectable at baseline (case 1 and control) or 1.8 ng/mL (case 2) rose to a mean peak of 6.9 ng/mL and returned to baseline by 24 h. Testolactone, in serial dilutions, cross-reacted in the testosterone assay. Testolactone significantly interferes in these serum RIAs, making their use unreliable in follow-up of patients treated with testolactone.

Androstanediol glucuronide production in human liver, prostate, and skin. Evidence for the importance of the liver in 5 alpha-reduced androgen metabolism.

Androstanediol glucuronide (Adiol G) has been reported to be a marker of peripheral androgen metabolism and action. It consists of two isomers, Adiol 3-G and Adiol 17-G. Adiol G is formed from unconjugated precursors by the enzyme glucuronyl transferase. To determine the likely source of Adiol G formation in man, we developed a glucuronyl transferase assay and measured the activity of this enzyme in human liver, abdominal and scalp skin, and prostate. In human liver, glucuronyl transferase activity was linear with respect to time (up to 120 min) and tissue concentration (up to 1 mg/ml). Apparent Michaelis-Menten constant Km (micromolar) and maximum velocity (Vmax) (picomoles per mg/30 min) were 5.6 and 140 for dihydrotestosterone, 8.9 and 1300 for androstanediol, and 3.1 and 46 for androsterone, respectively. Conversion of androstanediol to Adiol G (/0.5 mg tissue.30 min) was 5.8-13.2%. Over 80% of the Adiol G formed in human liver was Adiol 17-G, similar to what has been previously found in human serum. Glucuronyl transferase activity was present at low levels in human prostate (conversion of androstanediol to Adiol G was 0.04-4.6%/50 mg tissue.120 min). Analogous conversion rates (/50 mg tissue.120 min) for human scalp skin were 0.2-0.4% and for human abdominal skin were 0.07-0.14%. Although dihydrotestosterone may be converted to androstanediol in peripheral tissues such as skin and prostate, our results suggest that the principal site of androgen conjugation to glucuronic acid is the liver. The present results cast doubt upon the role of androstanediol glucuronide as a specific marker of cutaneous androgen metabolism.

Effects of finasteride (MK-906), a 5 alpha-reductase inhibitor, on circulating androgens in male volunteers.

Finasteride, a 5 alpha-reductase inhibitor, was administered to normal male volunteers in a blinded placebo-controlled study at daily oral doses of 25, 50, and 100 mg for 11 days (part 1) and daily oral doses of 0.04, 0.12, 0.2, and 1.0 mg for 14 days (part 2). Results from part 1 showed a significant reduction in dihydrotestosterone (DHT) at all doses and a significant increase in both testosterone (T) and delta 4-androstenedione at the 50- and 100-mg doses. No change was seen in LH, FSH, cortisol, or estradiol levels. Serum lipids, including total cholesterol, low density lipoprotein, high density lipoprotein, and triglycerides were not affected by treatment. Results from part 2 again showed significant reduction in DHT at all doses. DHT levels returned to pretreatment values within 14 days of discontinuing treatment. Significant increases in T were observed only in the 1.0 mg group and only during the first 8 days of treatment. The T/DHT ratio increased with all doses and returned to baseline when drug was discontinued. The DHT metabolites and androstanediol glucuronide and androsterone glucuronide were significantly reduced at all doses. There were no significant adverse experiences reported during part 1 or 2. In conclusion, finasteride is well tolerated by normal volunteers and results in significant suppression of serum DHT at all doses tested.

Morphine inhibits the pituitary-adrenal response to ovine corticotropin-releasing hormone in normal subjects.

To determine the locus of opiate modulation of ACTH secretion, 11 normal subjects were given ovine corticotropin-releasing hormone (CRH) 30 min after receiving either placebo or morphine sulfate. Plasma ACTH, cortisol, arginine vasopressin (AVP), epinephrine, norepinephrine, and CRH were measured 30 min before and up to 150 min after CRH administration. Morphine blunted the ACTH response for the first 60 min and cortisol response for the first 90 min after CRH administration. Morphine did not lower arginine vasopressin or catecholamine levels. To determine whether morphine's effect on ACTH and cortisol was due to a direct action on the corticotroph cell, dispersed rat pituitary cells were perifused with medium containing 1 microgram/ml morphine sulfate or medium alone. Morphine had no effect on the ACTH response of these cells to 10 nM CRH pulses. Similarly, morphine had no effect on ACTH production by dispersed rat pituitary cells in monolayer culture in response to 90- and 180-min incubations with 5 nM CRH. We conclude that morphine blunts the early response of the pituitary gland to CRH in vivo. Based on the lack of a direct effect of morphine on rat pituitary cells in vitro, we postulate that morphine given in vivo may modulate the pituitary ACTH response to CRH through other suprapituitary factors.