Reduction of gonadotropin-releasing hormone pulse frequency is associated with subsequent selective follicle-stimulating hormone secretion in women with polycystic ovarian disease

Polycystic ovarian disease (PCO) is characterized by hyperandrogenism, ovulatory dysfunction, and altered gonadotropin secretion. Mean plasma FSH concentrations are low, while LH is elevated in a majority of patients. LH pulsatile secretion has been shown to occur at rapid follicular phase frequencies (approximately one pulse per h) in PCO, suggesting persistent rapid frequency GnRH secretion in this disorder. Anovulatory women with PCO were given estradiol (E2; Estraderm skin patches) and progesterone (P; vaginal suppositories) to produce midluteal concentrations for 21 days. The aim was to determine if E2 and P would slow LH (GnRH) pulse frequency and if this would result in augmented FSH secretion and follicular development after withdrawal of E2 and P. Plasma LH was measured every 10 min for 8 h before, during (days 10 and 20), and 7 days after withdrawal of E2 and P (day 28). On each of these study days FSH was measured hourly, and E2 and P were measured every 2 h. After sampling, GnRH (25 and 250 ng/kg, iv) was given to assess pituitary responsiveness. Follicular development was monitored by vaginal ultrasound through day 34 of the study. Basal LH frequency was 8.5 +/- 0.5 pulses/8 h (mean +/- SEM). During E2 and P, LH pulse frequency fell to 3.3 +/- 1.0 (10 days) and 2.3 +/- 0.8 (20 days), 39% and 27% of the basal value, respectively, and subsequently increased to 5.6 +/- 0.7 (66% of basal) 7 days after withdrawal of E2 and P. LH pulse amplitude (basal, 7.2 +/- 1.5 IU/L) was not reduced until day 20, but remained suppressed (3.9 +/- 1.1 IU/L) on day 28. As a result, mean LH (basal, 21.0 +/- 3.5 IU/L) fell progressively during E2 and P, to 3.8 +/- 1.2 IU/L on day 20, and remained low (39% of basal) 7 days after steroid withdrawal. Mean plasma FSH (basal, 7.1 +/- 0.9 IU/L) also fell during steroid administration, but in contrast to LH, had risen to 93% of the basal value by 7 days after E2 and P. LH release in response to exogenous GnRH revealed marked initial responses which did not decrease until day 20, but remained suppressed (8% of basal) after withdrawal of E2 and P. FSH responses were also suppressed on day 20, but had increased to 75% of the basal value by day 28. Initiation of follicular development occurred in all patients, and the lead follicle measured 12.3 +/- 0.8 mm 13 days post-E2 and P. Ovulation occurred in one patient.(ABSTRACT TRUNCATED AT 400 WORDS)     

Gonadotropin-releasing hormone (GnRH) analog suppression renders polycystic ovarian disease patients more susceptible to ovulation induction with pulsatile GnRH

Pulsatile GnRH administration consistently restores normal reproductive hormone levels and ovulation in women with hypogonadotropic hypogonadism, but is less effective in those with polycystic ovarian disease (PCOD). We pharmacologically created a hypogonadotropic condition with a GnRH analog (GnRH-A) in six women with PCOD to investigate the role of deranged gonadotropin secretion in PCOD and to improve the response to pulsatile GnRH ovulation induction. Before GnRH and GnRH-A treatment the women with PCOD had increased LH pulse frequency [one pulse every 55 +/- 2 (+/- SE) min; P less than 0.05] and LH pulse amplitude (10.9 +/- 1.4 U/L; P less than 0.05) compared to normal women in the follicular phase of their menstrual cycle. Each PCOD woman completed one cycle of pulsatile GnRH administration for ovulation induction before (pre-A cycles; n = 6) and one or two cycles after (post-A cycles; n = 9) GnRH-A administration [D-Ser(tBu)6-Des,Gly10-GnRH; 300 micrograms, sc, twice daily for 8 weeks]. Pulsatile GnRH (5 micrograms/bolus) was given at 60-min intervals using a Zyklomat pump. Daily blood samples were drawn during the pulsatile GnRH ovulation induction cycles for the determination of serum LH, FSH, estradiol (E2), progesterone, and testosterone, and pelvic ultrasonography was done at 1- to 4-day intervals. Mean (+/- SE) serum LH levels were elevated during the pre-A cycle (49.2 +/- 3.1 IU/L) and decreased to normal levels during the post-A cycles (19.6 +/- 1.4 IU/L; P less than 0.0001). Mean testosterone concentrations were lower during the post-A cycles [88 +/- 2 ng/dL (3.1 +/- 0.1 nmol/L)] than during the pre-A cycles [122 +/- 3 ng/dL (4.2 +/- 0.1 nmol/L); P less than 0.0001]. In the follicular phase of the post-A cycles E2 levels were significantly lower [81 +/- 5 pg/mL (300 +/- 20 pmol/L) vs. 133 +/- 14 pg/mL (490 +/- 50 pmol/L); P less than 0.0001], preovulatory ovarian volume was smaller (24.6 +/- 2.0 vs. 31.4 +/- 2.4 cm3; P less than 0.01), and the FSH to LH ratio was higher (0.56 +/- 0.03 vs. 0.16 +/- 0.01) than in the pre-A cycle, suggesting more appropriate function of the pituitary-gonadal axis. Excessive LH and E2 responses to pulsatile GnRH administration in the early follicular phase of the pre-A cycle were abolished in the post-A cycles.(ABSTRACT TRUNCATED AT 400 WORDS)     

Role of endogenous opioid peptides in the initiation of the midcycle luteinizing hormone surge in normal cycling women

While compelling evidence indicates a pivotal role for endogenous opioids in the regulation of GnRH-LH pulsatile activity during the late follicular and luteal phases of the menstrual cycle, the participation, if any, of the opioidergic mechanism in the initiation of the midcycle surge has not been examined. Accordingly, we measured serum LH, FSH, estradiol (E2) and progesterone (P4) levels daily during 2 consecutive cycles in 12 normal cycling women. After a control cycle, each woman was infused with naloxone (30 micrograms/kg.h) for 24 h starting 3 days before the anticipated spontaneous midcycle surge. Blood samples were obtained at 15-min intervals for 8 h before, during, and 16 h after the naloxone infusion. Serum LH and FSH concentrations were measured in all samples, and serum E2 and P4 concentrations at 2-h intervals. Pulsatile LH secretion was analyzed using the cluster program. The opioidergic blockade elicited a robust increase in LH pulsatile activity and a 3-fold rise in serum FSH levels in 6 of the 12 women. This increased gonadotropin secretion lasted more than 24 h and was characterized by a progressive increase in LH pulse amplitude, which was 9-fold greater during the last 8 h of naloxone infusion [mean LH pulse amplitude, 36.5 +/- 4.5 (+/- SE) vs. 4.1 +/- 0.4 IU/L; P less than 0.001]. This increase was accompanied by a corresponding increase in transverse mean serum LH levels (83.3 +/- 13 vs. 20.7 +/- 3.2 IU/L; P less than 0.001), but no alteration of the interpulse interval (93 +/- 11 vs. 85 +/- 4 min). The peak serum LH concentrations exceeded 100 IU/L in all 6 of these women. This naloxone-advanced gonadotropin surge, resembling closely the spontaneous midcycle surge, resulted in a significantly shortened (P less than 0.001) follicular phase and a more than 2-fold elevation of serum P4, followed by assumed ovulation and normal luteal function. These 6 women had serum E2 levels immediately before naloxone infusion that were comparable to those during the preovulatory peak during the control cycle. In the 6 women who did not have a naloxone-induced increase in gonadotropin secretion the preinfusion serum E2 levels were substantially lower (P less than 0.001) than the values during the control cycle. These findings suggest that a transient decrease in opioidergic activity may contribute to the initiation of the midcycle gonadotropin surge in women.     

Five-day pulsatile gonadotropin-releasing hormone administration unveils combined hypothalamic-pituitary-gonadal defects underlying profound hypoandrogenism in men with prolonged critical illness.

Central hyposomatotropism and hypothyroidism have been inferred in long-stay intensive care patients. Pronounced hypoandrogenism presumably also contributes to the catabolic state of critical illness. Accordingly, the present study appraises the mechanism(s) of failure of the gonadotropic axis in prolonged critically ill men by assessing the effects of pulsatile GnRH treatment in this unique clinical context. To this end, 15 critically ill men (mean +/- SD age, 67 +/- 12 yr; intensive care unit stay, 25 +/- 9 days) participated, with baseline values compared with those of 50 age- and BMI-matched healthy men. Subjects were randomly allocated to 5 days of placebo or pulsatile iv GnRH administration (0.1 microg/kg every 90 min). LH, GH, and TSH secretion was quantified by deconvolution analysis of serum hormone concentration-time series obtained by sampling every 20 min from 2100-0600 h at baseline and on nights 1 and 5 of treatment. Serum concentrations of gonadal and adrenal steroids, T(4), T(3), insulin-like growth factor I (IGF), and IGF-binding proteins as well as circulating levels of cytokines and selected metabolic markers were measured. During prolonged critical illness, pulsatile LH secretion and mean LH concentrations (1.8 +/- 2.2 vs. 6.0 +/- 2.2 IU/L) were low in the face of extremely low circulating total testosterone (0.27 +/- 0.18 vs. 12.7 +/- 4.07 nmol/L; P < 0.0001) and relatively low estradiol (E(2); 58.3 +/- 51.9 vs. 85.7 +/- 18.6 pmol/L; P = 0.009) and sex hormone-binding globulin (39.1 +/- 11.7 vs. 48.6 +/- 27.8 nmol/L; P = 0.01). The molar ratio of E(2)/T was elevated 37-fold in ill men (P < 0.0001) and correlated negatively with the mean serum LH concentrations (r = -0.82; P = 0.0002). Pulsatile GH and TSH secretion were suppressed (P < or = 0.0004), as were mean serum IGF-I, IGF-binding protein-3, and acid-labile subunit concentrations; thyroid hormone levels; and dehydroepiandrosterone sulfate. Morning cortisol was within the normal range. Serum interleukin-1beta concentrations were normal, whereas interleukin-6 and tumor necrosis factor-alpha were elevated. Serum tumor necrosis factor-alpha was positively correlated with the molar E(2)/testosterone ratio and with type 1 procollagen; the latter was elevated, whereas osteocalcin was decreased. Ureagenesis and breakdown of bone were increased. C-Reactive protein and white blood cell counts were elevated; serum lactate levels were normal. Intermittent iv GnRH administration increased pulsatile LH secretion compared with placebo by an increment of +8.1 +/- 8.1 IU/L at 24 h (P = 0.001). This increase was only partially maintained after 5 days of treatment. GnRH pulses transiently increased serum testosterone by +174% on day 2 (P = 0.05), whereas all other endocrine parameters remained unaltered. GnRH tended to increase type 1 procollagen (P = 0.06), but did not change serum osteocalcin levels or bone breakdown. Ureagenesis was suppressed (P < 0.0001), and white blood cell count (P = 0.0001), C-reactive protein (P = 0.03), and lactate level (P = 0.01) were increased by GnRH compared with placebo infusions. In conclusion, hypogonadotropic hypogonadism in prolonged critically ill men is only partially overcome with exogenous iv GnRH pulses, pointing to combined hypothalamic-pituitary-gonadal origins of the profound hypoandrogenism evident in this context. In view of concomitant central hyposomatotropism and hypothyroidism, evaluating the effectiveness of pulsatile GnRH intervention together with GH and TSH secretagogues will be important.     

Sex steroid control of gonadotropin secretion in the human male. II. Effects of estradiol administration in normal and gonadotropin-releasing hormone-deficient men

Although prior studies have suggested that estrogens exert their negative feedback effect at the pituitary level in men, these conclusions have been based on models that evaluate changes in LH pulse amplitude and frequency and, therefore, only provide indirect information concerning the site of action of estrogens. To assess whether estradiol (E2) inhibits gonadotropin secretion directly and solely at the pituitary level in men, we determined the pituitary responses to physiological doses of GnRH in six men with complete GnRH deficiency, whose pituitary-gonadal function had been normalized with long term pulsatile GnRH delivery, before and during a 4-day continuous E2 infusion (90 micrograms/day). To deduce whether E2 has an additional inhibitory effect on hypothalamic GnRH secretion, their responses were compared with the effects of identical E2 infusions on spontaneous gonadotropin secretion and the responses to a 100-micrograms GnRH bolus in six normal men. Both groups were monitored with 15 h of frequent blood sampling before and during the last day of the E2 infusion. In the GnRH-deficient men, the first three GnRH doses were identical and chosen to produce LH pulses with amplitudes in the midphysiological range of values in our normal men (i.e. a physiological dose), while the last four doses spanned 1.5 log orders (7.5, 25, 75, and 250 ng/kg). The 250-ng/kg dose was always administered last because it is known to be pharmacological. In the GnRH-deficient men, mean LH and FSH levels as well as LH pulse amplitude all decreased significantly (P less than 0.02) during E2 infusion, demonstrating a direct pituitary-suppressive effect of E2. Mean LH (P less than 0.01) and FSH (P less than 0.05) levels and LH pulse amplitude (P less than 0.01) also decreased significantly in the normal men. The degree of suppression of mean LH (52 +/- 3% vs. 42 +/- 12%) and FSH (49 +/- 10% vs. 37 +/- 10%) levels was similar in the two groups. These results provide direct evidence that E2 inhibits gonadotropin secretion at the pituitary level in men and suggest that the pituitary is the most important, and possibly the sole, site of negative feedback of estrogens in men.     

Increased luteinizing hormone pulse frequency during sleep in early to midpubertal boys: effects of testosterone infusion

Gonadotropin secretion is pulsatile in prepubertal and early pubertal boys, and the onset of puberty is characterized by a sleep-associated rise in LH pulse amplitude. To determine whether an augmentation in LH pulse frequency as well as amplitude occurs at the onset of puberty, we studied gonadotropin secretion in 21 early to midpubertal boys. Blood samples were taken every 20 min (every 15 min in 4 boys) for LH determinations. A 2-fold increase in LH pulse frequency occurred during the nighttime sampling period (2200-0400 h) compared to that in the hours when the boys were awake (1000-2200 h). The maximum frequency (0.7 pulses/h) occurred between 2400 and 0200 h. The mean plasma LH concentration increased during the night from 2.3 +/- 0.2 (+/- SE) mIU/mL (2.3 +/- 0.2 IU/L) between 2000-2200 h to a maximum of 6.2 +/- 0.4 (6.2 +/- 0.4 IU/L) between 0200-0400 h. The mean plasma LH decreased to 5.5 +/- 0.4 mIU/mL (5.5 +/- 0.4 IU/L) between 0400-0600 h and to 4.2 +/- 0.5 (4.2 +/- 0.5 IU/L) between 0600-0800 h. Plasma testosterone rose during the night to a mean maximum value of 2.4 +/- 0.5 (+/- SE) ng/mL (8.3 +/- 1.7 nmol/L). This finding suggested that the rise in testosterone might play a role in decreasing LH secretion during the later hours of sleep (after 0400 h). To address this question and to study further the effects of testosterone in early puberty, we measured plasma LH concentrations every 10 min from 2000-0800 h in 8 early to mid-pubertal boys before and during short term testosterone administration. Saline or testosterone at a concentration of 9.33 micrograms/mL (32 mumol/L) was infused at a rate of 10 mL/h from 2100-1200 h to shift the nighttime testosterone rise 3 h earlier than would occur spontaneously. Blood samples were obtained every 10 min for LH and every 30 min for testosterone determinations from 2000-0800 h. Pituitary responsiveness was assessed by administering sequential doses of synthetic GnRH (25 and 250 ng/kg) at 1000 and 1200 h, respectively. The nighttime increase in LH pulse frequency and mean plasma LH concentration occurred between 2300 and 0200 h despite testosterone infusion. However, testosterone infusion was associated with significantly lower mean plasma LH concentrations from 0200-0800 h compared to those on the night of the saline infusion. Pituitary responsiveness to synthetic GnRH was unaltered by testosterone administration.(ABSTRACT TRUNCATED AT 400 WORDS)     

Combined hypothalamic-pituitary-gonadal defect in a hypogonadic man with a novel mutation in the DAX-1 gene.

We have studied a 20-yr-old male patient with adrenal hypoplasia congenita and hypogonadotropic hypogonadism (HH) due to a C to A transversion at nucleotide 825 in the DAX-1 gene, resulting in a stop codon at position 197. The same mutation was detected in his affected first cousin (adrenal hypoplasia congenita and HH) and in a heterozygous state in their carrier mothers. The patient had had acute adrenal insufficiency at the age of 2 yr and 6 months, bilateral cryptorchidism corrected surgically at the age of 12 yr, and failure of spontaneous puberty. Plasma testostereone (T) was undetectable (<0.30 nmol/L), gonadotropin levels were low (LH, <0.4 IU/L; FSH, 1.5 IU/L) and not stimulated after i.v. injection of 100 microg GnRH. The endogenous LH secretory pattern was apulsatile, whereas free alpha-subunit (FAS) levels depicted erratic pulses, suggesting an incomplete deficiency of hypothalamic GnRH secretion. During i.v. pulsatile GnRH administration (10 microg/pulse every 90 min for 40 h), each GnRH pulse induced a LH response of low amplitude (0.54 +/- 0.05 UI/L), whereas mean LH (0.45 +/- 0.01 IU/L) and FAS (63 +/- 8 mU/L) levels remained low. Amplitude of LH peaks (0.83 +/- 0.09 IU/L), mean LH (0.53 +/- 0.02 IU/L), and FAS (161 +/- 18 mU/L) levels increased (P < 0.01), whereas the T concentration remained low (0.75 nmol/L) when the pulsatile GnRH regimen was raised to 20 microg/pulse for a 40-h period, suggesting a partial pituitary resistance to GnRH. Thereafter, plasma T levels remained in prepubertal value after three daily im injections of 5000 IU hCG (3.6 nmol/L) and after 1-yr treatment with weekly i.m. injections of 1500 IU hCG (1.2 nmol/L), implying Leydig cell resistance to hCG. The patient had a growth spurt, bone maturation, progression of genital and pubic hair stages, and normalization of plasma T level (15.8 nmol/L) after a 12-month treatment with twice weekly injections of hCG and human menopausal gonadotropin (75 IU International Reference Preparation 2) preparations, suggesting that, in presence of FSH, a Sertoli cell-secreted factor stimulated Leydig cell production of T. In conclusion, we report a novel mutation in the DAX-1 gene in patients with AHC and HH. Our results suggest that the hypogonadism is due to a combined hypothalamic-pituitary-gonadal defect and imply that the DAX-1 gene may play a critical role in human testicular function.     

Effect of improved assay sensitivity on luteinizing hormone pulse detection after gonadotropin-releasing hormone antagonist treatment in man.

When serum levels of a hormone are at or below the detection limit of the measurement system, accurate characterization and quantitation of pulsatile hormone secretion may be difficult. This point is well illustrated in this study, which used two immunoassays with markedly different assay sensitivities to quantitate pulsatile LH secretion in men in whom serum LH levels had been suppressed by the administration of a GnRH antagonist. Five normal men received 5 mg Nal-Glu, sc, daily for 21 days. Blood was drawn at 10-min intervals over 8 h on days 0 and 21. Samples were assayed in triplicate in both a conventional LH RIA with a sensitivity of 0.6-1.0 IU/L and a two-site-directed ultrasensitive immunofluorometric assay (IFMA) with assay sensitivity ranging from 0.05-0.125 IU/L. LH pulses were analyzed by Cluster analysis (C) and were corroborated by the Detect algorithm (D). Nal-Glu suppressed LH (C) pulse amplitude from 4.0 +/- 0.7 to 0.40 +/- 0.03 IU/L by LH RIA and from 7.8 +/- 2.1 to 0.21 +/- 0.04 IU/L by LH IFMA. An apparent reduction in LH pulse number was observed in the RIA data on day 21 by both pulse detection methods [4.2 +/- 0.4 vs 2.4 +/- 0.2/8 h on days 0 and 21 by C (P < 0.005); 5.8 +/- 0.8 vs. 2.8 +/- 0.7 by D (P < 0.05)]. However, the IFMA measurements in the same samples using the more sensitive LH IFMA showed no difference in pulse number between days 0 and 21. The RIA data correlated well with the IFMA data, with a concordance coefficient ranging from 0.66-0.9. In summary, the Nal-Glu GnRH antagonist markedly decreases LH pulse amplitude, but not pulse frequency. These observations are consistent with competitive inhibition of GnRH action at the pituitary site by the Nal-Glu antagonist; they indicate that assay characteristics can significantly affect quantitation of hormone pulse pattern and underscore the need for ultrasensitive LH assays for accurate assessment of LH pulse characteristics when LH levels are low or suppressed.     

Corpus luteum insufficiency induced by a rapid gonadotropin-releasing hormone-induced gonadotropin secretion pattern in the follicular phase

The pulse frequency of LH and FSH (and by inference, GnRH) is a major determinant of the relative baseline plasma levels of LH and FSH. Luteal phase deficiency has been reported to be associated with increased gonadotropin pulse frequency and inadequate preovulatory follicular development. In this study we induced in normal women a supraphysiological gonadotropin pulse frequency in the follicular phase to determine its effect on follicular development and corpus luteum function. Specifically, we tested the hypothesis that a supraphysiological GnRH pulse frequency would result in deficient luteal phase production of progesterone. The subjects were six normal ovulatory women (age range, 23-35 yr). They were initially studied during a control cycle (cycle 1). Then, 25 ng/kg GnRH was administered iv every 30 min from the early follicular phase of the next cycle (cycle 2) until ovulation occurred. GnRH administration resulted in increased follicular phase plasma LH and FSH levels and LH to FSH ratios, multiple preovulatory follicles (mean, 2.8) with increased mean integrated estradiol [1302 (pg/mL)day (cycle 1) vs. 2550 (pg/mL)day (cycle 2); P less than 0.05; 4780 vs. 9360 (pmol/L)day, Systeme International units], spontaneous ovulation, decreased luteal phase plasma immunoreactive and bioactive LH levels, decreased luteal phase length [13.5 days (cycle 1) vs. 8.8 days (cycle 2); P less than 0.05], and decreased mean integrated progesterone secretion [152 (ng/mL)day (cycle 1) vs. 66 (ng/mL)day (cycle 2); P less than 0.01; 482 vs. 209 (nmol/L)day, Systeme International units]. We conclude that high frequency LH and FSH secretion during the follicular phase can induce inadequate progesterone secretion during the subsequent luteal phase, and we infer that the pathophysiological basis for this induced luteal phase deficiency is decreased LH support of corpus luteum function.     

Cosecretion of estrogen and inhibin B by a feminizing adrenocortical adenoma: impact on gonadotropin secretion

We describe the first reported case of a feminizing adrenocortical adenoma cosecreting estrogens and inhibin B. A 39-yr-old man, with no previous history of disease and free of treatment, complained of gynecomastia without any clinical abnormality. Plasma E2 and T were 496 pmol/liter and 8.7 nmol/liter, respectively. Testicular echography was normal, and abdominal computed tomography scan showed a 28-mm right adrenal tumor. hCG (5000 IU, im) induced a rise in plasma T levels (20.7 nmol/liter) without any change in plasma E2 levels. Basal plasma LH and FSH levels were undetectable. GnRH (100 microg, i.v.) induced an increase in plasma LH levels without a change in plasma FSH levels. The mean plasma inhibin B level was 330 +/- 45 pg/ml (normal range, 94-327). Pulsatile GnRH administration (20 microg/pulse every 90 min for 3 d) stimulated LH secretion, whereas FSH secretion remained blunted. The patient underwent surgery to remove a 12-g adrenal adenoma. Six months later, plasma E2 and T levels were normalized. LH showed a spontaneous pulsatile pattern, and the mean plasma FSH level was 4.8 U/liter. The secretion of both gonadotropins was stimulated during a pulsatile GnRH administration performed in the same manner as before surgery. The mean plasma inhibin B level was 210 +/- 25 pg/ml. Immunohistochemical studies revealed the presence of aromatase in clusters of tumor cells. Incubation of tumor sections with anti-beta(B)-inhibin antibody revealed intense staining in groups of cells that were also labeled with anti-alpha-inhibin antibody. These data show that the tumor cosecreted E2 and inhibin B, which were both responsible for inhibition of gonadotropin secretion. Tumor secretions appeared to be much more potent in suppressing FSH than LH levels.     

Testosterone administration inhibits gonadotropin secretion by an effect directly on the human pituitary

Testosterone (T) administration slows LH pulse frequency in man, presumably by an effect on the hypothalamic GnRH pulse generator, but it also may have a direct action on the pituitary. To determine if T does indeed affect gonadotropin secretion by acting directly on the pituitary, we studied the effect of T on GnRH-stimulated gonadotropin secretion. Six men with hypogonadotropic hypogonadism were treated with physiological doses of GnRH (5 micrograms every 2 h, sc by automatic infusion pump) for 6 weeks. Once their gonadotropin levels were normal, the men received a supraphysiological dosage of T enanthate (200 mg, im, weekly for 8 weeks) in addition to GnRH. They then received GnRH alone for a final 8-week period. Blood sampling was performed every 10 min for 8 h at the end of each of the three study periods. T administration suppressed the mean serum LH level to about 50% of the value during GnRH alone [18 +/- 2 (+/- SE) vs. 37 +/- 2 micrograms/L; P less than 0.05] and suppressed the mean serum FSH level to about 30% of the value during GnRH alone (39 +/- 6 vs. 128 +/- 28 micrograms/L; P less than 0.05). Eight weeks after stopping T, while continuing GnRH alone, serum LH and FSH levels were similar to those at the end of the first period of GnRH administration. The mean LH response to GnRH was reduced during T administration (17 +/- 3 micrograms/L) compared to that during the initial period of GnRH alone (31 +/- 4 micrograms/L; P less than 0.05). Serum T and estradiol levels were in the low normal range after GnRH alone before T administration (11 +/- 2 nmol/L and 105 +/- 17 pmol/L, respectively) and increased to just above the normal adult ranges after 8 weeks of T administration (36 +/- 5 nmol/L and 264 +/- 49 pmol/L, respectively). These results demonstrate that T and/or its metabolites inhibit LH and FSH secretion by a GnRH-independent mechanism, probably directly on the pituitary gland, in man.     

Diurnal patterns of pulsatile luteinizing hormone secretion in hypothalamic amenorrhea: reproducibility and responses to opiate blockade and an alpha 2-adrenergic agonist

The pattern of pulsatile GnRH secretion is abnormal in some women with hypothalamic amenorrhea (HA) consequent to previous exercise or weight loss. Both diminished frequency pulsatile LH secretion, and by inference GnRH secretion, and normal LH pulsatility have been reported. We assessed whether the patterns of GnRH secretion varied with time by measuring plasma LH every 15 or 20 min for 24 h on 1-3 occasions during a 10-month period in 14 women with HA (a total of 24 studies). During the day, mean LH pulse frequency [1.0 +/- 0.1 (+/- SE) pulses/8 h] was lower than that in normal women in the early follicular phase of their cycles (5.1 +/- 0.6), and the frequency in individual HA patients was lower than early follicular phase values in 16 of 17 studies. The slow daytime LH pulse frequency also was a consistent finding, in that the values in repeat studies varied by less than 2 pulses/8 h in all but 1 patient. LH pulse frequency (2.0 +/- 0.4 pulses/8 h) was higher and more variable during sleep, and normal early follicular phase frequencies were found in 20% of patients with HA. The mechanisms whereby GnRH pulse frequency is reduced are not known. alpha-Adrenergic agonist drugs stimulate GnRH pulsatile secretion in rodents, but administration of the alpha 2-agonist clonidine (0.15 mg, orally, at 0800 and 2000 h) did not increase the frequency of LH pulses in 7 women (1.7 +/- 0.4 pulses/8 h). In contrast, administration of naloxone (1 mg/m2 X h, iv) for 8 h during the day to 14 patients, increased LH pulse frequency (3.3 +/- 0.5 pulses/8 h). In 8 of these 14 women, LH pulse frequency (4.9 +/- 0.4 pulses/8 h) increased into the range found during the normal early follicular phase, while in the other 6 women pulse frequency was not significantly increased (1.4 +/- 0.4 pulses/8 h). Plasma estradiol levels were similar in naloxone-responsive and unresponsive women, but spontaneous LH pulse frequency was higher at night in naloxone-responsive patients (2.9 +/- 0.6 vs. 1.4 +/- 0.3 pulses/8 h). The presence of nocturnal LH pulses did not predict responsiveness to naloxone, however, and LH pulse frequency was less than 2 pulses/8 h in 4 of the women who responded to naloxone. These data indicate that slow frequency GnRH secretion is a common finding during the day in women with HA. GnRH secretion is more variable at night, suggesting that the mechanisms involved in reducing pulsatile GnRH secretion are less effective during sleep.(ABSTRACT TRUNCATED AT 400 WORDS)     

Naloxone increases the frequency of pulsatile luteinizing hormone secretion in women with hyperprolactinemia

The ability to change the frequency and amplitude of pulsatile GnRH secretion may be an important mechanism in maintaining regular ovulatory cycles. Hyperprolactinemia is associated with anovulation and slow frequency LH (GnRH) secretion in women. To assess whether the slow frequency of LH (GnRH) secretion is due to increased opioid activity, we examined the effect of naloxone infusions in eight amenorrheic hyperprolactinemic women (mean +/- SE, serum PRL, 160 +/- 59 micrograms/L). After a baseline period, either saline or naloxone was infused for 8 h on separate days, and LH was measured in blood obtained at 15-min intervals. Additional samples were obtained for plasma FSH, PRL, estradiol, and progesterone. Responses to exogenous GnRH were assessed at the end of the infusions. LH pulse frequency increased in all subjects from a mean of 4.0 +/- 0.5 pulses/10 h (mean +/- SE) during saline infusion to 8.0 +/- 1.0 pulses/10 h during naloxone infusion (P less than 0.01). LH pulse amplitude did not change, and mean plasma LH increased from 7.4 +/- 0.8 IU/L (+/- SE) to 11.2 +/- 1.5 IU/L during naloxone (P less than 0.01). A small but significant increase was seen in mean plasma FSH. Plasma PRL, estradiol, and progesterone were unchanged by naloxone infusion. These data suggest that elevated serum PRL reduces the frequency of LH (GnRH) secretion by increasing hypothalamic opioid activity and suggest that the anovulation in hyperprolactinemia is consequent upon persistent slow frequency LH (GnRH) secretion.     

The roles of estradiol and progesterone in decreasing luteinizing hormone pulse frequency in the luteal phase of the menstrual cycle

During the luteal phase of the menstrual cycle, plasma progesterone (P) and estradiol (E2) concentrations are elevated, and LH (and by inference GnRH) pulse frequency is slow. In contrast, LH pulse frequency increases during the early follicular phase when plasma E2 and P are lower. To examine the mechanism(s) responsible for the slower GnRH pulse frequency in the luteal phase, we maintained plasma P, E2, or both at midluteal concentrations from the midluteal phase to the time of the next early follicular phase and measured the effects on LH secretion. Thirteen normal women with regular menstrual cycles were studied during two or three cycles. Blood was obtained every 10 min during 10-h studies. Control cycle luteal and early follicular studies were followed by a second control study in the luteal phase of the treatment cycle. P (six women), E2 (seven women), or both (five women) then were given twice daily by im injection for 6-12 days until the day corresponding to the early follicular study of the control cycle (EF + P, EF + E2, or EF + E2 + P). A final study was performed 1 week after the injections were discontinued (F). LH pulse frequency was low in the midluteal phase [3.2 +/- 0.2 (+/- SE) pulses/10 h] and increased by the early follicular phase (8.0 +/- 0.8 pulses/10 h) in the control cycles. The increase in LH pulse frequency was not significantly inhibited by administration of P (6.7 +/- 0.7 pulses/10 h; EF + P). However, during both E2 alone and E2 + P, LH pulse frequency remained low (EF + E2, 3.6 +/- 0.8; EF + E2 + P, 2.0 +/- 0.7 pulses/10 h). The mean plasma FSH concentrations paralleled changes in LH pulse frequency, increasing from the luteal to the early follicular phase in the control cycles and during P injections and remaining low during E2 and E2 + P injections. We conclude that continued exposure to P alone does not maintain GnRH pulse frequency at midluteal phase values and that any effect of P requires the presence of E2. As E2 alone maintained lower LH pulse frequency, E2 may act directly to decrease the pulsatile GnRH secretion or it may potentiate the effects of low (less than 3.2 nmol/L) P concentrations.     

Follicular arrest during the midfollicular phase of the menstrual cycle: a gonadotropin-releasing hormone antagonist imposed follicular-follicular transition

The functional dependency of the dominant follicle on pulsatile gonadotropin inputs was evaluated by using a GnRH antagonist as a probe. Hormonal dynamics, particularly the relationship of FSH, estradiol, and inhibin, during and after the withdrawal of GnRH receptor blockade achieved by treatment with Nal-Glu GnRH antagonist (50 micrograms/kg, im) for 3 days in the midfollicular phase of the cycle (days 7-9) were ascertained. Daily blood samples were obtained for LH, FSH, estradiol (E2), progesterone, and immunoreactive inhibin (i-INH) measurements by RIA during 2 consecutive (control and treatment) cycles in 12 women. In 5 women, LH pulsatility was assessed by 10-min blood sampling for 12 h before, during, and after Nal-Glu treatment. The administration of Nal-Glu prolonged both follicular phase (14.0 +/- 0.5 vs. 19.7 +/- 0.8 days; P less than 0.0001) and total cycle length (28.1 +/- 0.5 vs. 34.1 +/- 1.2 days; P less than 0.0001). Gonadotropin suppression (50-60%) was achieved, as reflected by a marked decrease in mean LH levels (14.3 +/- 1.9 to 5.4 +/- 0.5; P less than 0.01) and LH pulse amplitude (5.5 +/- 0.7 to 2.4 +/- 0.3 IU/L; P less than 0.01) in response to Nal-Glu antagonist. The number of LH pulses was reduced (36%), but pulses remained discernible. Concentrations of FSH (10.8 +/- 1.4 to 5.9 +/- 0.4 IU/L; P less than 0.05), E2 (322.7 +/- 71.9 to 84.8 +/- 7.7 pmol/L; P less than 0.01) and i-INH (284.0 +/- 25.9 to 164.4 +/- 7.5 U/L; P less than 0.01) decreased concomitantly. Within 24-48 h of the last injection of Nal-Glu, all hormones had returned to pretreatment levels. This was followed by normal functional expression of follicular growth and maturation, as reflected by an increase in E2 and i-INH levels, timely ovulation, and normal luteal function. These findings indicate that an approximately 50% decline in gonadotropin support to the dominant follicle leads to functional arrest, but not demise, of the developing follicle(s) without triggering new folliculogenesis. The follicular apparatus retained its ability to reinitiate its original functionality once appropriate gonadotropin inputs were reinstated.     

Acute effects of testosterone infusion and naloxone on luteinizing hormone secretion in normal men.

To evaluate the role of endogenous opioid pathways in the acute suppression of LH secretion by testosterone (T) infusion in men, we studied eight normal healthy volunteers who received a saline infusion, followed 1 week later by a T infusion (960 nmol/h) starting at 1000 h and lasting for 33 h. After 2 h of infusion (both saline and T), four iv boluses of saline were given hourly, and after 26 h of infusion, four hourly iv boluses of naloxone were given. Blood was obtained every 15 min for LH and every 30 min for T. T infusion increased the mean plasma T concentration 2.1-fold (18.7 +/- 2.1 to 39.5 +/- 3.5 nmol/L, saline vs. T infusion, P < 0.01). The mean plasma LH concentration was 7.9 +/- 0.5 IU/L during the saline control study and was decreased to 6.9 +/- 0.6 IU/L by the infusion of T (P < 0.05). LH pulse frequency was similar during both saline and T infusions (0.48 +/- 0.02 vs. 0.43 +/- 0.04 pulses/man.h, saline vs. T infusion). The mean LH pulse amplitude decreased from 4.3 +/- 0.4 IU/L during saline infusion to 3.3 +/- 0.2 IU/L during T infusion (P < 0.05). The administration of naloxone increased the mean plasma LH concentration significantly during saline infusion (7.6 +/- 0.4 to 10.0 +/- 0.9 IU/L, saline vs. naloxone boluses, P < 0.01), but not during T infusion (6.9 +/- 0.6 vs. 7.3 +/- 0.6 IU/L). LH pulse frequency increased significantly after the administration of naloxone during both saline and T infusions (0.54 +/- 0.04 to 0.71 +/- 0.08 pulses/man.h, saline vs. naloxone boluses during saline infusion, and 0.46 +/- 0.08 to 0.60 +/- 0.07 pulses/man.h during T infusion; P < 0.05). LH pulse amplitude was suppressed by T infusion, but administration of naloxone did not reverse this suppression. The mean amplitude of the LH response to exogenous GnRH (250 ng/kg) was decreased by T infusion from 48 +/- 13.5 to 31.2 +/- 8.5 IU/L (P < 0.01). Therefore, in men, the administration of naloxone increases LH pulse frequency during both saline and T infusions, but the acute suppression of LH pulse amplitude seen with T infusion was not reversed by naloxone. This pattern contrasts sharply with the effects of T infusion in pubertal boys, as elucidated by our earlier studies. The negative feedback effects of T on LH secretion are primarily hypothalamic in early pubertal boys and change to pituitary suppression in men.     

Longitudinal evaluation of the different gonadotropin pulsatile patterns in anovulatory cycles of young girls.

We studied 13 adolescents (mean gynecological age 29.2 +/- 14.1 months) with anovulatory cycles and 7 women with ovulatory cycles (mean gynecological age 33.1 +/- 15.3 months) as a control group. Adolescents with anovulatory cycles were grouped on the basis of mean plasma LH values: group 1 (n = 7) with high LH values, and group 2 (n = 6) with normal LH values. In all women plasma gonadotropin concentrations were measured at 10-min intervals for 8 h on day 4 of the cycle. Pulsatile gonadotropin secretion was also studied in each subject a second time 40 months later, to establish the outcome of the different pulsatile patterns. Group 1 had more frequent and greater LH pulses than the other two groups (which were similar) and had the highest plasma 17 beta estradiol, testosterone, androstenedione, and 17 hydroxyprogesterone concentrations. Longitudinal control showed that: in group 1, three subjects out of seven acquired ovulatory cycles and there was a fall in mean LH plasma levels (30 +/- 5 vs. 9 +/- 4 IU/L; P less than 0.01), number of pulses (8.3 +/- 1.5 vs. 5 +/- 0; P less than 0.025), mean amplitude (13 +/- 3 vs. 5 +/- 2 IU/L; P less than 0.02) and an increase in interpulse interval (56 +/- 10 vs. 91 +/- 6 min; P less than 0.01). In four subjects anovulatory cycles persisted and the LH pulsatile profile remained unchanged. In group 2, five subjects out of six acquired ovulatory cycles, but there were no significant changes in the number of pulses (6 +/- 1 vs. 6 +/- 2; P = NS), interpulse interval (97 +/- 30 vs. 85 +/- 30 min; P = NS), or amplitude (5 +/- 2 vs. 4 +/- 2 IU/L; P = NS). The results indicate that: 1) anovulatory young women with early normal plasma LH values have an adequate GnRh pulsatile pattern which will easily lead to ovulation; 2) anovulatory young women with high LH plasma values may have a reproductive system blocked in a pathological condition, similar to that observed in polycystic ovary syndrome; 3) only few subjects with high plasma LH values are able to achieve ovulation and normalize LH pulsatile pattern as a consequence of a new mode of GnRh release.     

Decrease in gonadotropin-releasing hormone (GnRH) pulse frequency with aging in postmenopausal women

Increasing evidence suggests that aging is associated with dynamic changes in the hypothalamic and pituitary components of the reproductive axis that are independent of changes in gonadal hormone secretion. This study was designed to determine the effect of age on GnRH pulse frequency in women in the absence of gonadal feedback using gonadotropin free alpha-subunit (FAS) and LH as neuroendocrine markers of endogenous GnRH secretion. All studies were performed in healthy, euthyroid postmenopausal women (PMW) during daytime hours. The impact of sampling interval and duration on assessment of pulse frequency in PMW was first examined in 10 women with a mean age of 61.6 +/- 8 yr (mean +/- SD), in whom blood was sampled every 5 min for 12 h. Each 5-min series was then reduced to simulate a 10-min series and then a 15-min series for pulse analysis, and the effect of 8 h compared with 12 h of sampling was determined. To define the changes in the frequency and amplitude of pulsatile hormone secretion with aging, 11 younger (45-55 yr) and 11 older (70-80 yr) PMW were then studied over 8 h at a 5-min sampling interval. In the initial series, the mean interpulse intervals (IPIs) for FAS were 53.8 +/- 3.6, 69.2 +/- 3.9, and 87.6 +/- 7.3 min at sampling intervals of 5, 10, and 15 min, respectively (P < 0.0005). The LH IPI also increased progressively with sampling intervals of 5, 10, and 15 min (54.4 +/- 2.5, 70.4 +/- 2.3, and 91.1 +/- 4.4 min; P < 0.0001). At the 5-min sampling interval, the calculated number of pulses/24 h was not different between a 12-h series compared with an 8-h series for either FAS or LH. In the second series of studies, the older PMW had lower gonadotropin levels (LH, 86.5 +/- 8.8 vs. 51.3 +/- 7.7 IU/L, P < 0.01; FSH, 171.6 +/- 16.9 vs. 108.2 +/- 10.5 IU/L, P < 0.005; FAS, 1021.5 +/- 147.4 vs. 425.6 +/- 89.6 ng/L, P < 0.005, in younger and older PMW, respectively) despite no differences in estrone or estradiol levels. The older PMW also demonstrated a slower FAS pulse frequency compared with their younger counterparts, as reflected in an increased FAS IPI (52.6 +/- 3.1 and 70.6 +/- 5.9 min; P < 0.002). The difference in IPIs between younger and older PMW was not statistically significant for LH (65.4 +/- 5.6 and 71.8 +/- 6.6 min for younger and older PMW, respectively). FAS pulse amplitude was decreased in older PMW compared with younger PMW (431.7 +/- 66.2 vs. 224.6 +/- 81.9 ng/L; P < 0.01), whereas the decrease in LH pulse amplitude with age was of borderline statistical significance (23.2 +/- 3.1 vs. 15.9 +/- 2.1 IU/L; P = 0.09). In conclusion: 1) the use of a 5-min sampling interval and measurement of FAS as the primary marker of GnRH pulse generator activity indicate that GnRH pulse frequency in younger PMW is faster than previously reported, but not increased over that seen in the late follicular phase and midcycle surge in women with intact ovarian function; and 2) the marked decrease in FAS pulse frequency with age provides evidence of age-related changes in the hypothalamic component of the reproductive axis that are independent of changes in gonadal function.     

Inhibition of endogenous catecholamine synthesis augments early follicular phase luteinizing hormone secretion.

The physiological role of catecholamines, particularly dopamine and norepinephrine, in the regulation of gonadotropin secretion in humans is unclear. We administered the tyrosine hydroxylase inhibitor alpha-methyl-p-tyrosine (AMPT, 500 mg at 800 and 1000 h) to five women in the early follicular phase of the menstrual cycle and compared LH secretion patterns to those in five untreated controls. Commencing at 800 h, blood was drawn every 15 min for LH and PRL measurements until 1600 h. AMPT elevated PRL concentrations (mean +/- SEM) from a baseline of 14.72 +/- 2.51 micrograms/L to a peak of 102.2 +/- 24 micrograms/L. LH concentrations [21.97 +/- 0.56 (AMPT) vs. 13.51 +/- 0.16 IU/L (control), P less than 0.0001], LH area under the curve [11014 +/- 1815 (AMPT) vs. 7009 +/- 404 IU.min/L (control), P = 0.05] and LH pulse amplitude [9.99 +/- 2.38 (AMPT) vs. 4.03 +/- 0.61 IU/L (control), P = 0.04] were all greater in the group in which catecholamine synthesis was inhibited. There was no difference in pulse frequency between the groups (7.4 +/- 0.51 vs. 6.6 +/- 0.24 pulses/8 h, P greater than 0.05). We conclude 1) inhibition of endogenous catecholamine synthesis augments LH levels in the early follicular phase, and 2) increased LH secretion during catecholamine synthesis inhibition is due, at least in part, to increased LH pulse amplitude but not increased LH pulse frequency.     

Poorly controlled type I diabetes mellitus in young men selectively suppresses luteinizing hormone secretory burst mass

Alterations in the reproductive axis function are present to a variable extent in patients with type 1 diabetes mellitus (IDDM). Results from studies in IDDM men have yielded discrepant findings, which may reflect nonuniform patient selection criteria, age, diabetic status, duration of the disease and differences in sampling protocols. To more clearly define the impact of early diabetic alterations in the male reproductive axis, we applied a combined strategy of patient selection restricted to young men with relatively short duration of IDDM, dual control groups, multiparameter deconvolution analysis to assess LH secretory activity, and assessment of time-dependent changes in human chorionic gonadotropin (hCG)-stimulated serum testosterone concentrations. Three groups of subjects were studied: 11 young men with poorly controlled IDDM, 9 well controlled diabetics, and 9 healthy men. All volunteers underwent blood sampling at 10-min intervals before and after 2 consecutive iv pulses of 10 micro g GnRH. On a separate day, 40 IU/kg hCG were given im, and blood samples were collected before hCG administration, every 60 min thereafter for 6 h, and then 24, 48, and 72 h after the injection. Mean serum LH concentrations across the basal 6-h sampling period were significantly (P < 0.05) decreased in men with poorly controlled IDDM (11 +/- 1.6 IU/liter) compared with those in well controlled diabetics (19 +/- 1.8 IU/liter) and healthy controls (19 +/- 1.5 IU/liter). Multiple parameter deconvolution analysis revealed a 50% reduction in the mass of LH secreted per burst and the pulsatile LH secretion rate in poorly controlled IDDM (mass of LH secreted/burst, 7 +/- 1.1 vs. 12 +/- 2.1 and 13 +/- 1.5 IU/liter; LH secretion rate, 47 +/- 6.3 vs. 78 +/- 10 and 87 +/- 11 IU/liter.6 h; poorly controlled vs. well controlled IDDM and healthy controls, respectively; P < 0.05 for both parameters). Uncontrolled IDDM patients had significantly (P < 0.05) lower integrated serum LH concentrations after the first and second GnRH pulses (first GnRH pulse, 4460 +/- 770 vs. 7250 +/- 1200 and 5120 +/- 910 IU/liter; second pulse, 4700 +/- 615 vs. 7640 +/- 881 and 7100 +/- 1230 IU/liter; poorly controlled vs. well controlled IDDM and healthy men, respectively) and markedly attenuated LH secretory burst mass after the second GnRH stimulus (49 +/- 8.8 vs. 90 +/- 13 and 83 +/- 19 IU/liter; poorly controlled vs. well controlled IDDM and healthy controls, respectively). The biological to immunological ratio of LH released in baseline conditions was higher in uncontrolled IDDM patients (0.81 +/- 0.10) than in controlled IDDM (0.37 +/- 0.08) and healthy controls (0.48 +/- 0.06; P < 0.01), whereas LH released in response to exogenous GnRH exhibited comparable ratios among the three study cohorts. Baseline serum testosterone levels as well as absolute and incremental responses to exogenous hCG did not differ by degree of metabolic control. Collectively, these results indicate that the function of the hypothalamic-gonadotrope axis is compromised in young men with poorly controlled IDDM, such that the amplitude of spontaneous pulsatile and exogenous GnRH-stimulated LH secretion is attenuated. This central hypogonadotropism is paradoxically associated with the presence in the circulation of gonadotropin molecules with enriched biological activity, which is evidently sufficient to temporarily maintain normal total testosterone concentrations in the earlier stages of IDDM.