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.
Testosterone exerts negative feedback control on gonadotropin secretion either directly, after aromatization to estradiol, or after 5 alpha-reduction to dihydrotestosterone (DHT). Conflicting data exist as to the role of DHT in the modulation of this negative feedback. To determine whether suppression of endogenous DHT alters gonadotropin secretion, we gave the selective 5 alpha-reductase inhibitor finasteride (5 mg daily), or placebo, to 20 healthy men for 28 days. Basal and GnRH-stimulated LH, bioactive LH, FSH, testosterone, and DHT levels were measured before and after 14 and 28 days of treatment. Basal DHT fell from 1.1 +/- 0.2 to 0.15 +/- 0.04 nmol/L after 28 days of finasteride treatment. A significant rise in baseline testosterone from 17.6 +/- 2.0 to 18.3 +/- 2.3 nmol/L was seen at 14 days (P = 0.046), but not at 28 days. No significant changes were seen in either basal or GnRH-stimulated gonadotropin levels on any day. We conclude that suppression of serum DHT levels with 5 mg finasteride daily in healthy young men has no discernible effect on serum gonadotropin levels.
Medical treatment of Graves' disease involves use of antithyroid drugs with or without the addition of exogenous L-T4. There have been conflicting reports as to whether the addition of T4 reduces TSH receptor antibodies and improves remission rates more than antithyroid drugs alone. To further examine the effect of drug therapy on serum concentrations of TSH receptor antibodies. 70 patients with Graves' disease were treated with methimazole (Tapazole) alone until they were euthyroid. Then they were randomized to receive either: 1) methimazole alone in a dose sufficient to normalize TSH (0.3-5.4 mIU/L; Group 1); 2) 30 mg methimazole daily plus sufficient T4 (Synthroid) to maintain TSH in the high-normal range (2.0-5.4 mIU/L; Group 2); or 3) 30 mg methimazole daily plus sufficient T4 to suppress TSH to below 0.6 mIU/L (Group 3). The duration of treatment in all groups was 18 months. At baseline and after 6 and 18 months, TSH receptor antibodies were measured both by the ability of patients' sera to stimulate cAMP production by FRTL-5 cells (thyroid-stimulating Ig) and by the ability of patients' sera to inhibit binding of radiolabeled TSH to solubilized porcine thyroid membranes (TSH-binding, inhibiting Ig). Thyroid-stimulating Ig(TSI) and TSH-binding, inhibiting Ig(TBII) concentrations were similar among the three groups at baseline. Mean baseline TSI (expressed as the percent of normal control) for all patients combined was 306 +/- 21%. Mean baseline TBII (expressed as percent inhibition of TSH binding) was 38 +/- 2%. TSI was elevated in 85% and TBII was elevated in 75% of patients at baseline. After 18 months, TSI was elevated in 64% of patients, and TBII was elevated in 28%. Serum TSI decreased by 36 +/- 5% during the study, and there was no significant difference in the degree of reduction among the three groups (P = 0.99). Serum TBII decreased by 59 +/- 3%, and there also was no significant difference among the groups (P = 0.83). At baseline, serum TBII correlated with free T4 (r = 0.33, P < 0.01), total T3 (r = 0.55, P < 0.01), and thyroid size (r = 0.35, P < 0.01). There was no correlation between TSI and any of the baseline parameters or between TSI and TBII at any timepoint. In conclusion, we found that the addition of T4 to methimazole does not result in a greater decrease in TSH receptor antibody concentrations than treatment with methimazole alone. From these results, we would predict no difference in remission rates among these patients, but confirmation of this prediction will need to await long-term follow-up of these subjects.
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.
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