Hirsutism, polycystic ovarian disease, and ovarian 17-ketosteroid reductase deficiency

We studied an 18-year-old woman with progressive hirsutism, secondary amenorrhea, and polycystic ovarian disease. Excess androstenedione was secreted by the ovaries, most likely because of a genetic deficiency of ovarian 17-ketosteroid reductase, the enzyme that converts androstenedione to testosterone. Markedly elevated basal plasma levels of androstenedione, estrone, and testosterone were regulated by gonadotropin but not by ACTH. The rate of androstenedione production in the patient's blood at base line and after administration of dexamethasone was very high (10.0 to 11.6 mg per day; value in control women with hirsutism, less than 4.1 mg per day), whereas her blood production of testosterone was 0.64 to 0.7 mg per day, similar to or higher than that in control women with hirsutism. The fractional blood conversion ratio of androstenedione to testosterone was normal (5.6 percent). Thus, 88 to 93 percent of the testosterone in the blood was derived from the peripheral conversion of androstenedione, and very little testosterone was secreted by the ovaries. These in vivo biochemical data suggest that the patient had a deficiency of ovarian 17-ketosteroid reductase activity but normal pubertal activity. The patient's two younger sisters with peripubertal symptoms of androgen excess also had elevated serum levels of androstenedione. We propose that the increased secretion of androstenedione in the three siblings in this family was probably due to a genetic deficiency of ovarian 17-ketosteroid reductase.     

ACTH stimulation tests and plasma dehydroepiandrosterone sulfate levels in women with hirsutism

BACKGROUND. Hirsutism in women is a clinical manifestation of excessive production of androgens. The source of the excess androgen may be either the ovaries or the adrenal glands, and distinguishing between these sources may be difficult. METHODS. To determine whether measurements of plasma dehydroepiandrosterone (DHEA) sulfate and ACTH stimulation tests, both widely used in the evaluation of hirsutism in women, provide useful information, we performed both tests in 22 normal women and 31 female patients with hirsutism. The hormones measured in plasma during the ACTH stimulation tests were progesterone, 17-hydroxypregnenolone, 17-hydroxyprogesterone, DHEA, androstenedione, 11-deoxycortisol, and cortisol. RESULTS. The women with hirsutism were divided into four groups based on their individual responses to ACTH stimulation: patients with a possible 3 beta-hydroxy-delta 5-steroid dehydrogenase deficiency, those with a possible 21-hydroxylase deficiency, those with a possible 11 beta-hydroxylase deficiency, and those with no apparent defect in steroidogenesis. The results in 19 patients (61 percent) suggested subtle defects in adrenal steroidogenesis. There was no significant correlation between the basal plasma DHEA sulfate levels and the hormonal response to ACTH, nor were the basal levels of hormones predictive of the levels after ACTH stimulation. Eleven patients had significantly elevated basal levels of plasma DHEA sulfate; only 5 of these 11 had responses to ACTH suggestive of compromised steroidogenesis. Thirteen patients who had responses suggestive of defective steroidogenesis had DHEA sulfate levels within the normal range. CONCLUSIONS. A substantial proportion of women with hirsutism have mild defects in adrenal steroidogenesis, revealed by an ACTH stimulation test, that are indicative of late-onset (nonclassic) congenital adrenal hyperplasia. Measurements of basal steroid levels are not helpful in differentiating among the causes of increased androgen production in such patients and may be misleading.     

Impact of overnight dexamethasone suppression on the adrenal androgen response to an oral glucose tolerance test in women with and without polycystic ovary syndrome

In order to test the hypothesis that adrenocortical overactivity, possibly related to the stress of testing, may impact on the measurement of circulating androgen concentrations during glucose- induced hyperinsulinaemia, we prospectively screened 10 patients with the polycystic ovary syndrome (PCOS) and nine healthy control women with an oral glucose tolerance test (OGTT), before and after the administration of dexamethasone. Blood sampling was performed at 0, 30, 60, 90, and 120 min following the oral ingestion of 75 g of glucose, before and after the administration of 1.0 mg dexamethasone on the evening prior to testing. Total and free testosterone, androstenedione, dehydroepiandrosterone (DHEA), DHEA sulphate (DHEAS), cortisol, glucose and insulin were assessed during the 2 h OGTT. Women with PCOS had increased basal concentrations of free testosterone, total testosterone, androstenedione, and insulin compared to control women. In women with PCOS an acute decline in circulating concentrations of DHEAS occurred during the OGTT. In PCOS women there were no changes in other ovarian or adrenal androgens during OGTT before or following dexamethasone administration. In control women DHEA concentrations declined during the OGTT. Following overnight dexamethasone suppression in control women, circulating concentrations of DHEAS and testosterone also declined. It is concluded that: (i) in PCOS women only the concentration of circulating DHEAS decreased during glucose-induced hyperinsulinaemia and dexamethasone administration did not further alter androgen responses to an OGTT; (ii) it is possible that, in these hyperandrogenic patients, the insulin-related suppression of adrenocortical testosterone and DHEA is negated by their much greater ovarian secretion of these androgens; (iii) in control women DHEA concentrations acutely declined during the OGTT and the administration of dexamethasone resulted in the acute decline of DHEA, DHEAS, and testosterone; (iv) it appears that the stress related to testing impacts on the androgen response to OGTT, at least in healthy women.      

Inhibition of human adrenal androgen secretion by ketoconazole

Summary The effect of ketoconazole on adrenal androgen secretion was examined in 15 patients with elevated serum androgens. In a dose of 600 mg per day orally ketoconazole inhibited the biosynthesis of all measured androgens. The mean reduction in serum levels of dehydroepiandrosterone sulfate was 32%, of dehydroepiandrosterone 54%, of androstenedione 52%, and of testosterone 43%; mean serum levels of cortisol only fell by 19%. The reduction in serum androgen levels was first significant 24 h after beginning of treatment and persisted as long as the drug was administered. We conclude that ketoconazole inhibits adrenal androgen biosynthesis more pronouncedly than cortisol biosynthesis. This might be of clinical benefit in the treatment of hirsutism and other states of androgen hypersecretion.Abbreviations CV coefficient of variation - MV mean value - SEM standard error of the mean - f female - m male - K ketoconazole - ACTH adrenocorticotropic hormone - DHEA dehydroepiandrosterone - DHEAS dehydroepiandrosterone sulfate - A androstenedione - T testosterone - F cortisol - P progesterone - H hirsutism - C Cushing's disease - EAS ectopic ACTH syndrome - ATU adrenal tumor     

Serum testosterone response to low dose dexamethasone and combined contraceptive pill in subgroups of patients with polycystic ovary syndrome

Serum testosterone responses to the low dose dexamethasone and combined contraceptive pill were evaluated in a group of 42 patients with the polycystic ovary syndrome (PCOS) and in 10 normal-cycling women with idiopathic hirsutism. PCO patients were divided into subgroups according to their clinical presentation and hormonal characteristics. After the dexamethasone administration the serum testosterone levels remained significantly higher in all PCO patients compared to women with idiopathic hirsutism. Significant testosterone suppression was noticed in the subgroups with normal prolactin and normal LH levels (4.5 +/- 0.5 vs. 3.0 +/- 0.4 nmol/L, p less than 0.05 and 4.0 +/- 0.4 vs. 2.4 +/- 0.3 nmol/L, p less than 0.025 respectively), while it was not significant in any of the other subgroups studied. After a combined contraceptive pill administration a significant serum testosterone suppression was observed in all PCO subgroups (p less than 0.001), while it was not significant in women with idiopathic hirsutism. The results of this study show that ovaries are the main source of serum testosterone in PCO patients. This is particularly evident in patients with the highest LH/FSH ratio or hyperprolactinaemia.     

Late-onset adrenal hyperplasia in hirsutism

We studied the incidence of late-onset adrenal hyperplasia as a cause of hirsutism, its association with the major histocompatibility complex, and its clinical expression. Twenty-four of 400 women seen because of hirsutism were found to have late-onset adrenal hyperplasia, diagnosed on the basis of a high plasma level of 17-hydroxyprogesterone, and its marked increase after ACTH stimulation. The degree of hirsutism varied widely. Plasma antigen levels were high, especially the level of androstenedione, whereas 5 alpha-reductase activity, considered to be a good index of peripheral androgen utilization, showed frequent normal or low values. The 24 patients were genotyped, along with 84 family members, and plasma hormones were measured in the family members. We found a high correlation between late-onset adrenal hyperplasia and HLA antigens B14 and Aw33. Similar biologic profiles were observed in the patients and those of their siblings who were HLA identical (n = 9), confirming that late-onset adrenal hyperplasia is linked to the histocompatibility complex. These nine siblings had no hirsutism. We therefore conclude that the role of skin sensitivity to androgens is important in determining the clinical expression of this disorder.     

Detection of functional ovarian hyperandrogenism in women with androgen excess.

BACKGROUND. Distinguishing between ovarian and adrenal causes of androgen excess may be difficult. We have found that women with the polycystic ovary syndrome have supranormal plasma 17-hydroxyprogesterone responses to the gonadotropin-releasing hormone agonist nafarelin. We determined the usefulness of testing with nafarelin to distinguish ovarian causes of hyperandrogenism in women. METHODS. We studied 40 consecutive women with hyperandrogenism who had oligomenorrhea, hirsutism, or acne. All 40 underwent testing with nafarelin, dexamethasone, and corticotropin with measurement of circulating concentrations of gonadotropins and steroid hormones, and 19 underwent ovarian ultrasonography. RESULTS. The plasma 17-hydroxyprogesterone response to nafarelin was supranormal in 23 of the 40 women (58 percent), and the plasma androgen response to corticotropin was elevated in 23; 13 women had both abnormalities. Only one woman had conclusive evidence of a steroidogenic block; she had nonclassic adrenal 21-hydroxylase deficiency. Of the 23 women with abnormal responses to nafarelin, only 11 (48 percent) had elevated base-line serum luteinizing hormone concentrations. Of the 13 women with abnormal responses to nafarelin who underwent ultrasonography, 7 (54 percent) had polycystic ovaries. Peak plasma 17-hydroxyprogesterone concentrations after nafarelin administration correlated closely with plasma free testosterone concentrations after dexamethasone administration (r = 0.75, P less than 0.001). CONCLUSIONS. Approximately half of women with oligomenorrhea, hirsutism, or acne have an abnormal response to the gonadotropin-releasing hormone agonist nafarelin, suggesting an ovarian cause of their androgen excess.     

Androgen excess in women – A health hazard?

A significant body of evidence suggests that androgens in women may play a role in the genesis of central adiposity and type 2 diabetes. There are two principal sources of circulating androgens in females: the ovary and the adrenal gland. In hyperandrogenic women, there are elevated serum concentrations of androstenedione and testosterone and, in up to 50% of the women, dehydroepiandrosterone sulfate (DHEAS). The androgen precursor DHEAS is of exclusive adrenal origin, suggesting that hyperandrogenic women have an elevated proportion of adrenal androgen production and secretion. Another cause of androgen excess in reproductive-age women is a decreased conversion of testosterone to estradiol by the aromatase enzyme complex. In this review, we will discuss the hypothesized clinical sequel of elevated androgens in women - an aspect of women's health highly neglected. Furthermore, an attempt is made to appreciate what causes the androgens to initially rise from normal levels, allowing the onset of pathophysiological processes towards diseases.     

Girls with virilisation in childhood: a diagnostic protocol for investigation.

AIM: To analyse critically a protocol for the investigation of girls presenting with virilisation in childhood. METHODS: Twenty five girls aged 1.6-8.7 years with features of virilisation were evaluated. Twenty four had presented with pubic hair, eight with auxilliary hair, seven with facial acne, four with clitoromegaly, and 10 with tall stature. They underwent clinical assessment (height, weight, height velocity, staging of puberty, physical examination for acne, body odour, and clitoromegaly) and laboratory assessment comprising basal concentrations of cortisol, 17 OH-progesterone (17 OHP), androstenedione, dehydroepiandrosteronesulphate (DHEAS), testosterone, and oestradiol. The above steroids were also measured during the short synacthen test (0.25 mg intramuscularly) in 16 subjects and low dose dexamethasone suppression tests (0.5 mg at six hourly intervals over 48 hours). Pelvic ultrasound, computed tomography and magnetic resonance imaging of adrenals were carried out when the biochemical findings suggested that there might be an autonomous source of androgen secretion. RESULTS: Clinical and laboratory assessments differentiated the patients into three diagnostic categories: adrenarche (18 cases), congenital adrenal hyperplasia (five cases), and adrenocortical tumour (two cases). The last had elevated concentrations of DHEAS, 1.5 and 19.1 mumol/l (normal value < 0.5 mumol/l), androstenedione, 24.6 and 21.8 nmol/l (normal < 1 nmol/l), and testosterone, 4.5 and 2.4 nmol/l (normal < 0.8 nmol/l), with none suppressing on dexamethasone suppression. Congenital adrenal hyperplasia subjects had elevated basal serum concentrations of 17 OHP (n = 4): 250, 140, 14, and 14.1 nmol/l (normal < 10 nmol/l) and elevated peak values of 17 OHP after synacthen (n = 3): 76, 179.5, and 175 nmol/l. Adrenarche patients had elevated basal concentrations of DHEAS (median: 2.3 mumol/l; n = 17) and androstenedione (median 2.6 nmol/l; n = 17). Nine patients also had elevated basal serum testosterone concentrations (median 0.9 nmol/l). Peak values of 17 OHP after synacthen were significantly different from baseline (n = 12) and were < 50% of the lowest value in congenital adrenal hyperplasia. Serum DHEAS, androstenedione, and testosterone suppressed following dexamethasone suppression (n = 16), thereby distinguishing adrenarche patients from adrenal tumour patients. Clinical details did not distinguish patients, except for clitoromegaly which was present only in the tumour and congenital adrenal hyperplasia patients. CONCLUSIONS: This protocol proved useful and practical in cases of virilisation presenting particular diagnostic difficulty.     

Maternal serum androgens in human pregnancy: early increases within the cycle of conception

Previous studies have demonstrated elevations in testosterone and androstenedione initiated within the cycle of conception in pregnant non-human primates, and minimal data in the human support the same picture. In the present study we have investigated a group of patients scheduled for artificial insemination with regular menstrual cycles. For this study all patients provided blood samples at 5 days after the luteinizing hormone (LH) surges and daily through the luteal phase and into early pregnancy (n = 12). Patients who did not become pregnant served as normal controls (n = 9). We have measured 17- hydroxyprogesterone (17-OHP) as a marker of luteal activity not obscured by progesterone within the cycle of conception and testosterone and androstenedione as the major androgens. There were no significant changes in testosterone and androstenedione in the non- pregnant controls, but both testosterone and androstenedione were significantly elevated in the pregnant luteal phase, with the first increases occurring at 15 and 14 days respectively after the LH surge. Three of 12 pregnant patients did not demonstrate a dramatic increase in either testosterone or androstenedione and when examined more carefully a corresponding lack of increase in 17-OHP in those same subjects indicated less than optimal luteal activity, suggesting that these androgens were products of the corpus luteum. In three subjects in which consecutive non-pregnant and pregnant cycles were followed there was a dramatic increase from the non-pregnant luteal phase to the pregnant luteal phase indicating that the more important observation may be the concentrations of androgens in the conceptive luteal phase compared to some baseline, either previous luteal phase or even follicular phase. We have also studied changes in dehydroepiandrosterone sulphate and found that there was no significant contribution to this increase in androgens in early conception. These studies demonstrate a significant increase in both testosterone and androstenedione presumably of ovarian, specifically luteal, origin and that adrenal androgen production is not a factor in these changes.      

The prevalence of polycystic ovaries in women with infertility.

Polycystic ovaries (PCO) are highly prevalent in women presenting with hirsutism or recurrent miscarriage but the functional significance of PCO in ovulatory women presenting with infertility remains unclear. We examined the prevalence of PCO, on ultrasonography, among women presenting with infertility. Among 289 couples classified in four main diagnostic categories, PCO were found in 81 (83%) of 98 anovulatory patients, 40 (53%) of 76 patients whose partners had sperm dysfunction, 26 (50%) of 52 patients with tubal disease and in 28 (44%) of 63 patients with unexplained infertility. By comparison, in a control group of 67 parous volunteers, 19 (28%) were found to have PCO. PCO patients with unexplained infertility had higher midfollicular luteinizing hormone and testosterone compared with the group with normal ovaries. The prevalence of PCO was significantly higher in each of the infertility groups than in controls, and a similar tendency (not significant) was observed among women with unexplained infertility. Ovulatory PCO women with infertility had higher testosterone concentrations in comparison with PCO controls. In summary, the prevalence of PCO among ovulatory women with infertility is higher than that in the normal population, suggesting that PCO may, perhaps by virtue of an effect of hyperandrogenaemia, contribute to the causes of subfertility in women with regular menses.     

Therapie des Hirsutismus bei Frauen mit adrenalen Enzymdefekten der Steroidhormonbiosynthese: Vergleich von Dexamethason mit Cyproteronacetat

Summary In patients with adrenal hirsutism or enzyme deficiencies in steroidogenesis, elevated adrenal androgens could be normalized by dexamethasone. We were interested to see if dexamethasone would be as effective as cyproterone acetate in treating hirsutism in selected patients with adrenal pathogenesis. Therefore 28 patients with hirsutism of adrenal origin or enzyme deficiency were treated cyclically either with cyproterone acetate and ethinylestradiol (2 mg cyproterone acetate+0.035 mg ethinyl-estradiol days 1–21, +10mg cyproterone acetate days 1–15) (n=15) or with 0.25–0.5 mg dexamethasone daily at 10 pm (n=13). In the dexamethasone group there was a significant drop in dehydroepiandrosterone and dehydroepiandrosterone sulfate levels within 9 months, but there was a diminution in hirsutism in only four women (31%); in four out of seven menstrual irregularities decreased. In the cyproterone acetate group hirsutism diminished significantly in 66% (n=10) without suppression of adrenal androgens. Weight gain occurred in a few cases in both groups; other side effects developed in 33% in the cyproterone acetate group.Preselection of patients with hirsutism is useful with respect to diagnosis; adrenal pathogenesis should not generally indicate dexamethasone treatment of hirsutism unless there is a desire for pregnancy, because cyproterone acetate is a more powerful agent in reducing hair growth.

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Abkürzungsverzeichnis Dex Dexamethason - CPA Cyproteronacetat - 3-HSD-M 3-Hydroxysteroiddehydrogenase-Mangel - 21-OH-M 21-Hydroxylase-Mangel - T Testosteron - A Androstendion - DHEA Dehydroepiandrosteron - DHEA-S Dehydroepiandrosteron-Sulfat - 17-OH-Preg 17-Hydroxy-Pregnenolon - 17-OH-Prog 17-Hydroxy-Progesteron - 21-DF 21-Desoxycortisol Teile dieser Arbeit sind in der Dissertation Diagnostik und Therapie adrenaler Enzymdefekte der Steroidbiosynthese von Gerhard Junga, Universität Heidelberg, 1989, enthaltenFrau Dr. E. Richter, Schering AG/Berlin, sei vielmals für die freundliche Unterstützung der Studie gedankt.Wir danken Frau Doris Skalecki für die Mithilfe bei der Abfassung des Manuskriptes.     

The effect of circulating androgens on bone mineral density in postmenopausal women

BACKGROUND: Osteoporosis is a common problem in postmenopausal period. Recent studies have suggested that endogenous and exogenous androgens may influence the bone mineral density in women. There is limited data about the effect of circulating androgens on bone density in postmenopausal women. AIM: The aim of this study was to evaluate the effect of circulating androgens of ovarian and adrenal origin on bone mineral density in postmenopausal women. MATERIALS AND METHODS: This cross-sectional study included 178 postmenopausal women, who had never been treated with hormonal therapy or calciotropic agents. Serum free testosterone, dehydroepiandrosterone sulfate and androstenedione levels and their relationship with bone mass (dual X-ray absorptiometry) were evaluated. RESULTS: Serum free testosterone and DHEAS levels were correlated positively with bone mineral density at lumbar spine and femoral neck (P < 0.001). However, stepwise linear regression analyses revealed a differential effect of androgens on bone density. Serum free testosterone was among the independent predictor of bone density at lumbar spine (trabecular bone), whereas serum DHEAS level was of bone density at femoral neck (cortical bone). CONCLUSION: This study suggests that endogenous androgens are influential on bone density in postmenopausal women. However, regression analyses revealed a differential effect of androgens on different bone types.     

Polycystic ovary syndrome of extra-ovarian origin. Review

An established fact in the polycystic ovarian syndrome (POS) is an abnormal ovarian steroidogenesis. Though this suggest an intrinsic ovarian defect, the syndrome could also be influenced by factors outside the ovaries. Although of unknown etiology, the POS is one of the most frequent endocrine disorders in the gynecologic practice. The disorder is characterized by ultrasound findings of enlarged polycystic ovaries, hyperandrogenism, menstrual disorders, obesity and including the appearance of infertility. There are a series of mechanisms involved in the extraovarian androgen increase in patients with POS. Among these mechanisms are implicated those of central and peripheral origin, genetic factors and adrenocortical dysfunction. In the same way, the alterations produced could imply genetic, molecular biological, biochemical, physiological and endocrinological factors. Sometimes all these factors could interact at the same time. The high serum androgen level could stop the pituitary gonadotropin production, either as a direct mechanism or as a result of its peripheral conversion. The increased androgens also explain the manifestations of clinical acne, hirsutism, and the detention in follicular ovarian maturation. All these manifestations are related with the menstrual disorders, anovulation, and infertility that these patients develop. The characteristics of the extraovarian POS include the 17-hydroxyprogesterone elevation in response to the ACTH test and the dexamethasone suppression of adrenal androgens. It is possible to improve the ovarian function in some patients with POS. This could be achieved with clomiphene citrate associated with glucocorticoids to induce ovulation.     

Androgene für Frauen?

In women androgens are secreted by both the ovaries and the adrenal glands. Causes of androgen deficiency are ovarian or adrenal failure or therapy with estrogens or glucocorticosteroids. Women with androgen deficiency complain of fatigue and loss of well-being and libido. Replacement with DHEA or testosterone relieves the symptoms and, in the case of testosterone, increases bone density. Long-term effects on the cardiovascular system remain uncertain, as does any influence on breast cancer development. Masculinization and contraindications have to be considered. Widespread use of androgens in women is limited by the lack of data and the lack of suitable androgen preparations that result in physiological serum levels.     

Sex hormone status of the postmenopausal woman

Plasma levels of testosterone, androstenedione, dehydroepiandrosterone and its sulphate, and of androstenediol, as well as estrone and estradiol, were determined in several groups of postmenopausal women.The ovaries contribute to plasma estrogen levels only early in the postmenopause, but continue to secrete testosterone and minimal amounts of androstenedione throughout the postmenopause.With age there is a decreased secretion by the adrenal of dehydroepiandrosterone (sulphate) and of androstenediol.The levels of androstenedione and estrone and the androstenedione/estrone ratio remain unchanged with increasing age. The levels of estrone and estradiol, and the ratios, estrone/androstenedione and estradiol/testosterone, are correlated with fat mass. There is also an inverse curvilinear relationship with precursor concentration. This suggests either a progressive saturation of the tissular aromatase with increasing precursor level, or the existence of an unknown estrogen precursor.     

Clinical and hormonal effects of ketoconazole on hirsutism in women

Twelve women affected by functional postpuberal hirsutism were administered daily with 400 mg of ketoconazole. A significant reduction in the levels of concentration of circulating androgens (T, DEA-S, D4) was observed. A rapid clinical improvement of hirsutism and acne was noted and was even appreciable after treatment had been completed. This study is a further confirmation of the prevalent antiandrogenic action of ketoconazole, seen in its inhibiting effect on steroid synthesis in the adrenal and gonadal glands, and as such indicates that this drug is a useful alternative treatment of hirsutism in women.     

Ovarian and adrenal steroid production: regulatory role of LH/HCG

BACKGROUND: The contribution of the adrenal glands to the total circulating steroid pool in women is not well known. There is evidence that human adrenals express the LH receptor gene and that LH may affect adrenal androgen secretion. METHODS: HCG stimulation tests (a single dose of 5000 IU i.m.) were performed in women at reproductive age (group 1, n = 6, age 21--39 years) before and after treatment with a GnRH agonist for 3 weeks, and in oophorectomized post-menopausal women (group 2, n = 6, 47--59 years) during and after estrogen replacement therapy (ERT). RESULTS: HCG did not stimulate the secretion of cortisol, dehydroepiandrosterone (DHEA) and dehydroepiandrosterone sulphate (DHEAS) in group 2. In contrast, in group 1, the basal concentrations of serum 17-hydroxyprogesterone (17-OHP), androstenedione, testosterone and estradiol (E(2)) were stimulated significantly (17-OHP 105%, androstenedione 31%, testosterone 20%, E(2) 136%) by HCG, and the treatment with GnRH agonist decreased the responses. The basal serum concentrations of these steroids were significantly lower in oophorectomized women (17-OHP 57%, androstenedione 46%, testosterone 25%), and HCG did not increase these levels. It can be approximated that the ovarian contribution to the circulating levels of 17-OHP, androstenedione and testosterone is 25--30%, and that the adrenals are the primary source of cortisol, DHEA and DHEAS. CONCLUSION: LH/HCG does not have a major role in the regulation of adrenal steroid synthesis in endocrinologically healthy women.     

Secondary biosynthetic defects in women with late-onset congenital adrenal hyperplasia

BACKGROUND AND METHODS. Late-onset (non-classic) congenital adrenal hyperplasia is a cause of hirsutism, menstrual disorders, and infertility, but its frequency and the patterns of abnormalities in adrenal hormone secretion are not well understood. We investigated the frequency and ethnic distribution of nonclassic congenital adrenal hyperplasia due to deficiencies of 3 beta-hydroxy-delta 5-steroid dehydrogenase, 21-hydroxylase, or 11 beta-hydroxylase among 170 Israeli Jewish women with these clinical problems. All enzyme defects were identified by comparing the patients' hormonal responses to a 0.25-mg intravenous bolus dose of alpha 1-24-ACTH with those of 26 age-matched normal women. RESULTS. Twenty women (12 percent) had 3 beta-hydroxy-delta 5-steroid dehydrogenase deficiency, 18 (10 percent) 21-hydroxylase deficiency (14 homozygous), and 14 (8 percent) 11 beta-hydroxylase deficiency. All the homozygous women with 21-hydroxylase deficiency also had evidence of a partial deficiency in 11 beta-hydroxylase activity. Similarly, most of the women with 11 beta-hydroxylase deficiency also had evidence of a deficiency in 3 beta-hydroxy-delta 5-steroid dehydrogenase. Among the 118 women with no adrenal biosynthetic defect, 38 had high plasma androgen concentrations, and 80 had normal concentrations. CONCLUSIONS. About one third of Israeli Jewish women with hirsutism, menstrual disorders, or unexplained infertility had nonclassic congenital adrenal hyperplasia. Secondary adrenal biosynthetic defects were frequent in these women and were probably caused by intra-adrenal androgen excess rather than by dual inherited enzymatic deficiencies.     

Pulsatile gonadotrophin secretion in women with polycystic ovary syndrome after gonadotrophin-releasing hormone agonist treatment

In polycystic ovary syndrome (PCOS), increased luteinizing hormone (LH) pulse frequency has been attributed to either the hypothalamic gonadotrophin-releasing hormone (GnRH) pulse generator or ovarian oestrogen feedback. To address this issue, a detailed examination of pulsatile LH secretion was undertaken during recovery from GnRH agonist (GnRHa) suppression. Each of six women with PCOS and six normal ovulatory women received daily GnRHa treatment for 14 weeks. Frequent blood samples were collected and assayed for gonadotrophins, androgens and oestrogens before, during and up to 4 weeks after treatment. Women with PCOS had higher basal LH pulse frequency and amplitude and increased serum concentrations of LH, androstenedione, testosterone and oestrone than controls. After 3 months of GnRHa treatment, all these parameters were suppressed with no differences observed between the two groups. One week after cessation of GnRHa, LH pulse frequency promptly returned to pre-treatment range with no between-group differences noted, whereas LH pulse amplitude, serum gonadotrophins and ovarian steroids remained maximally suppressed and equivalent in the two groups. Subsequent LH pulse frequency remained constant while LH pulse amplitude and circulating concentrations gradually increased in parallel with a return of serum oestrogen to pre-treatment values. Despite comparable resumption of LH secretion in the two groups, corresponding androgen concentrations in women with PCOS were greater than those of normal ovulatory women. Thus, the immediate restoration of LH pulse frequency after discontinuing GnRHa treatment is largely independent of ovarian oestrogen production and reflects primacy of the GnRH pulse generator in determining basal LH pulse frequency. Equivalent LH pulse frequency rates in the two groups during the recovery period do not suggest an intrinsic hypothalamic-pituitary hyperactivity in PCOS.