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

The precise sites of action of the negative feed-back effects of gonadal steroids in men remain unclear. To determine whether testosterone (T) administration can suppress gonadotropin secretion directly at the level of the pituitary, the pituitary responses to physiological doses of GnRH were assessed 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 T infusion (15 mg/day). Their responses were compared with the effects of identical T infusions on spontaneous gonadotropin secretion and the response 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 T infusion. In the GnRH-deficient men, the first three GnRH doses were identical and were chosen to produce LH pulses with amplitudes in the midphysiological range of 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 (P less than 0.02) and FSH (P less than 0.01) levels as well as LH pulse amplitude (P less than 0.05) decreased significantly during T infusion, demonstrating a direct pituitary-suppressive effect of T and/or its metabolites. Mean LH levels were suppressed to a greater extent in the normal than in the GnRH-deficient men (58 +/- 15% vs. 28 +/- 7%; P less than 0.05). In addition, LH frequency decreased significantly (P less than 0.01) during T administration in the normal men. These latter two findings suggest that T administration also suppresses hypothalamic GnRH release. T was unable to suppress gonadotropin secretion in one GnRH-deficient and one normal man. In both groups, the suppressive effect of T administration was present only in response to physiological doses of GnRH. Because the pituitary- and hypothalamus-suppressive effects of T could be mediated by its aromatization to estrogens, five GnRH-deficient and five normal men underwent identical T infusions with concomitant administration of the aromatase inhibitor testolactone (TL; 500 mg, orally, every 6 h). As an additional control, four GnRH-deficient and four normal men received TL alone. TL administration completely prevented the effect of T administration to suppress gonadotropin secretion in both the normal and GnRH-deficient men, and mean LH levels increased significantly in both the GnRH-deficient (P less than 0.01) and the normal (P less than 0.001) men who received TL alone. The increase in mean LH levels was greater (P less than 0.01) in the normal men who received TL alone than in the normal men who received T plus TL, thus revealing a direct effect of androgens in normal men. Measurements of T and estradiol production rates in three men demonstrated that TL effectively blocked aromatization.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effects of long-term testosterone administration on gonadotropin secretion in agonadal female to male transsexuals compared with hypogonadal and normal women

We investigated the effects of long term testosterone (T) administration on pulsatile gonadotropin secretion in agonadal women and the effects of estradiol (E2) on gonadotropin secretion in eugonadal women in the follicular phase of the menstrual cycle. We studied 4 groups: A) 28 eugonadal women in the early follicular phase of the menstrual cycle, B) 11 hypogonadal women, C) 13 agonadal female to male (f-t-m) transsexuals treated for at least 3 months with 120-160 mg T undecanoate (TU)/day, orally, and D) 5 agonadal f-to-m transsexuals treated for at least 6 months with 250 mg of a mixture of testosterone esters, im (im T-esters), every 2 weeks. The eugonadal women in the early follicular phase had a mean serum E2 level of 193 +/- 94 (+/- SD) pmol/L, significantly higher (P less than 0.01) than that in the hypogonadal women (60 +/- 24 pmol/L), whereas there was no difference in the mean serum T levels (1.8 +/- 0.7 vs. 2.3 +/- 1.5 nmol/L). the higher serum E2 level in the eugonadal women was associated with a significantly lower mean serum LH level (6.9 +/- 2.6 vs. 44.6 +/- 17.6 U/L; P less than 0.01) and LH pulse amplitude (2.8 +/- 1.0 vs. 12.6 +/- 4.8 U/L; P less than 0.01), whereas the mean nadir LH interval did not differ between the two groups (75 +/- 29 vs. 81 +/- 49 min). The mean serum T level in the agonadal f-to-m transsexuals treated with oral TU was significantly higher (P less than 0.01) than that in the hypogonadal women (9.7 +/- 4.7 vs. 2.3 +/- 1.5 nmol/L). In spite of this elevated T level there was no difference in the mean serum LH level (38.4 +/- 14.7 vs. 44.6 +/- 17.6 U/L), LH pulse amplitude (14.3 +/- 5.7 vs. 12.6 +/- 4.8 U/L), or nadir LH interval (72 +/- 27 vs. 81 +/- 49 min) in these groups. Also, the mean serum E2 (64 +/- 16 vs. 60 +/- 24 pmol/L and FSH levels (62 +/- 17 vs. 64 +/- 28 U/L) did not differ between these groups. Treatment of the agonadal f-to-m transsexuals with im T-esters resulted in mean serum T and E2 levels of 34.4 +/- 27.0 nmol/L and 121 +/- 54 pmol/L, respectively, both significantly higher (P less than 0.01) than those in groups B and C.(ABSTRACT TRUNCATED AT 400 WORDS)     

Seventy-two hour infusions of LHRH in normal men: gonadotropin and testicular steroid responses.

Four normal male subjects received LHRH by continuous infusion for 72 hrs at 1.4 microgram/min. Mean basal LH was 7.7 +/- 1.0 mIU/ml, increased to a maximum of 120 +/- 22.7 mIU/ml, and then declined to levels between 28--34 mIU/ml for the last 30 hrs of infusion; FSH rose from 3.7 to 11.4 mIU/ml (p less than 0.05) at 16 hrs and then returned to baseline. Testosterone levels rose by 50% at 12 hrs, and remained elevated throughout with maximum values between 6.6 and 12 ng/ml. Estradiol-17beta levels were 26.2 +/- 4.7 pg/ml basally, rose to 104 +/- 8 pg/ml and while levels declined therafter, they were significantly above baseline throughout the 72 hrs. Plasma androstenedione and dehydroepiandrosterone levels also showed significant increases. By contrast, transient elevations in pregnenolone and 17-hydroxypregnenolone levels probably corresponded to the nomral morning rise in plasma levels of these steroids; 17-hydroxyprogesterone rose from 1.3 +/- 0.15 to 3.9 +/- 0.26 ng/ml at 12 hrs and remained elevated through the infusion. An increase in 17-hydroxyprogesterone:testosterone ratio was observed in all subjects. Thus, chronic LHRH infusion effected a persistent increase in endogenous LH with, in turn, prolonged stimulation of gonadal steroid secretion.     

Dopaminergic control of gonadotropin secretion in male senescence]

To verify the role of the dopaminergic mechanism in the control of gonadotropin secretion and aging of this mechanism in men, we studied serum gonadotropin response to LH-RH (100 micrograms i.v.) in basal condition and during dopamine infusion (DA 4 micrograms/kg/min). Seven young males (24-29yr.) and twenty aged males (50-80yr.) without endocrinological diseases were included in the present study. Aged male subjects were divided into hyperresponders, in whom maximal LH response to LH-RH without DA infusion exceeded 153.5mIU/ml (mean + 2SD of young male subjects), and non-hyperresponders, in whom maximal LH responses to LH-RH without DA infusion were less than 153.5mIU/ml. In hyperresponders, serum LH response at 30 minutes after LH-RH administration was significantly (p less than 0.05) suppressed by DA infusion. In non-hyperresponders and young male subjects, however, serum LH response to LH-RH was not affected by DA infusion. Basal levels of serum LH and FSH in hyperresponders tended to be higher than that of non-hyperresponders. Total serum testosterone, free testosterone and estradiol levels of hyper and non-hyperresponders failed to reveal any significant differences. These observations suggest that 1) DA directly suppresses gonadotroph responsiveness to LH-RH, 2) in aging men, inhibitory tone imposed on gonadotrophs by DA is decreased, and 3) this decline of DA system can cause hypergonadotropism in aging men, independent of serum sex steroids levels.     

Pulsatile gonadotropin secretion after discontinuation of long term gonadotropin-releasing hormone (GnRH) administration in a subset of GnRH-deficient men

Normal pituitary and gonadal function can be maintained with long term pulsatile GnRH administration in men with idiopathic hypogonadotropic hypogonadism (IHH), and both pituitary and gonadal priming occur during the process of GnRH-induced sexual maturation. Still, the long term effects of discontinuing GnRH therapy in IHH men have not been examined. Therefore, we evaluated the patterns of gonadotropin and alpha-subunit secretion before and after a prolonged period of pulsatile GnRH administration in 10 IHH men. Before exogenous GnRH stimulation, no patient had any detectable LH pulsations. In 6 of these men, who were typical of most of our IHH patients (group I), no LH pulsations were detectable after cessation of GnRH administration. However, in the other 4 men (group II), LH pulsations were easily detectable despite cessation of exogenous GnRH stimulation, and the amplitude (9.3 +/- 3.5 IU/L) and frequency (13.8 +/- 1.7 pulses/day) of these LH pulses were similar to those in 20 normal men (10.6 +/- 0.7 IU/L and 11.0 +/- 0.7 pulses/day). Three of these 4 men in group II maintained normal serum testosterone levels after discontinuation of GnRH delivery. To determine if there were any characteristics that might be useful in predicting which IHH men could maintain normal pituitary-gonadal function after long term GnRH administration, we evaluated various clinical and hormonal parameters at the time of initial presentation. Mean alpha-subunit levels (P less than 0.01) and alpha-subunit pulse amplitude (P less than 0.02) were significantly higher in the group II than the group I men, suggesting that the group II patients had partial, rather than complete, deficiency of endogenous GnRH secretion. None of the other parameters that were assessed distinguished the two groups. We conclude that gonadotropin and sex steroid levels return to their pretreatment state in the majority of IHH men when long term GnRH administration is discontinued. Normal pituitary-gonadal function can be maintained after discontinuation of long term GnRH administration in a rare subset of IHH men who present with higher levels of alpha-subunit. We hypothesize that these latter IHH men have an incomplete GnRH deficiency and that long term exogenous GnRH administration induces pituitary and gonadal priming, which subsequently enables them to sustain normal pituitary and gonadal function in response to their own enfeebled GnRH secretion.     

Effects of recombinant human inhibin and testosterone on gonadotropin secretion and subunit mRNA in superfused male rat pituitary cell cultures stimulated with pulsatile gonadotropin-releasing hormone.

Effects of recombinant human inhibin (rh inhibin) and testosterone on follicle-stimulating hormone (FSH) and luteinizing hormone (LH) secretion and mRNA levels of gonadotropin subunits were investigated in superfused male rat pituitary cell cultures. During superfusion, the cells were stimulated with gonadotropin-releasing hormone (GnRH) pulses (10 nM, 6 min/h) and exposed to rh inhibin (2 ng/ml) and/or testosterone (10 nM) for up to 20 h. The concentrations of FSH and LH were measured in effluent media by radioimmunoassay (RIA), and subunit mRNAs were determined by Northern blot hybridizations using rat FSH beta, LH beta and alpha genomic and cDNA probes. Rh inhibin suppressed the secretion of FSH (30-40% of control) and the secretion of LH to 50-60% of control, but inhibited only FSH beta mRNA (to non-detectable levels). Testosterone alone suppressed the release of LH to 50% of control, whereas FSH release was increased to 130-160% (P less than 0.05) of control. This increase was due to higher interpulse values without significant changes in the pulse amplitude. Also FSH beta mRNA level was increased (1.5-fold, P less than 0.05) but only after 17-20 h of treatment. On the other hand, testosterone had no effect on LH beta and alpha subunit mRNA levels. Testosterone in combination with rh inhibin showed an inhibitory effect on LH beta mRNA; however, the pattern of LH release was not significantly different from that observed with rh inhibin or testosterone alone. Combined effects of testosterone and rh inhibin on FSH secretion and FSH beta mRNA were similar to those observed with rh inhibin alone.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of increasing the frequency of low doses of gonadotropin-releasing hormone (GnRH) on gonadotropin secretion in GnRH-deficient men

The effects of increasing the frequency of pulsatile GnRH administration on LH and FSH responsiveness were studied in five GnRH-deficient men who had achieved normal sex steroid levels during prior long term GnRH replacement. Intravenous doses of GnRH were employed that had previously been demonstrated to produce LH and FSH levels in each subject similar to those in normal men. Both acute and chronic changes in pituitary responses were studied after progressive increases in GnRH frequency (from every 120 to 60 min, from 60 to 30 min, and from 30 to 15 min) during three 12-h admissions, each separated by 7 days. During the two intervals between the studies GnRH frequency was 60 and 30 min, respectively. Pituitary responses were characterized by determining the mean serum LH and FSH levels, LH pulse amplitudes, and mean LH and FSH levels which were normalized for the frequency of GnRH administration (nLH and nFSH). As the frequency of GnRH stimulation was increased acutely, mean serum LH levels rose progressively, in contrast to both LH pulse amplitude and nLH levels which decreased, while serum testosterone (T) concentrations remained constant. No further evidence of gonadotroph desensitization occurred after chronic GnRH administration at either 60- or 30-min intervals. At higher frequencies of GnRH stimulation, discrete pulses of LH were not always apparent after injections of GnRH, and in two men, marked destabilization of the gonadotroph responses occurred. Even without detectable LH pulses, serum T levels did not decline during administration of GnRH at intervals as rapid as 15 min. In contrast, there was no change in mean FSH concentrations, although nFSH values decreased progressively as the GnRH frequency was increased. nFSH levels fell to a greater degree than nLH after each increase in GnRH frequency. Thus, pituitary gonadotroph responsiveness to a fixed dose of GnRH decreased as the frequency of GnRH stimulation increased. FSH responsiveness decreased to a greater degree than did LH. Gonadotropin secretory responses are destabilized at higher frequencies of GnRH administration. Pulsatile LH stimulation of the testes does not appear necessary to maintain T secretion.     

Dissociated responses of plasma testosterone and estradiol to human chorionic gonadotropin in adult men.

Plasma testosterone (T), dihydrotestosterone (DHT) and estradiol (E2) were determined by radioimmunoassay in 10 normal males receiving hCG im 5000 IU on days 1, 2 and 3. The mean increase of plasma steroid on days 2, 3 and 1, respectively, was: 1.42, 1.79 and 1.87 times for T; 1.17, 1.56 and 1.49 times for DHT; 4.04, 3.29 and 2.33 times for E2. While T was still significantly increasing from day 2 to day 4, E2 significantly decreased. A positive correlation (P less than 0.01) was found between the basal T and the E2 peak after hCG, suggesting a release of E2 from a storage compartment in the testis. No significant change of either steroid was detected 4 h after the first hCG injection. In 6 cases of primary male hypogonadism, the mean basal values of T to hCG was defective, despite considerable individual variations. In 14 males with gonadotropin deficiency, basal values of T and E2 were very low; the T response to hCG ranged from undetectable to dramatic, and was correlated with the degree and duration of previous exposure to gonadotropin; and impaired response of E2 in all cases porvides a better estimate of the actual gonadotropin deficiency.     

Inhibition of luteinizing hormone secretion by testosterone in men requires aromatization for its pituitary but not its hypothalamic effects: evidence from the tandem study of normal and gonadotropin-releasing hormone-deficient men

CONTEXT: Studies on the regulation of LH secretion by sex steroids in men are conflicting. OBJECTIVE: Our aims were to determine the relative contributions of testosterone (T) and estradiol (E2) to LH regulation and localize their sites of negative feedback. DESIGN: This was a prospective study with three arms. SETTING: The study was conducted at a General Clinical Research Center. PATIENTS OR OTHER PARTICIPANTS: Twenty-two normal (NL) men and 11 men with GnRH deficiency due to idiopathic hypogonadotropic hypogonadism (IHH) participated. INTERVENTION: Medical castration and inhibition of aromatase were achieved using high-dose ketoconazole (KC) for 7 d with 1) no sex steroid add-back; 2) T enanthate 125 mg im starting on d 4; or 3) E2 patch 37.5 microg/d starting on d 4. Blood sampling was performed every 10 min for 12 h at baseline, overnight on d 3-4 and d 6-7. MAIN OUTCOME MEASURES: Mean LH levels, LH pulse amplitude, and GnRH pulse frequency were assessed at baseline, d 3-4, and d 6-7. RESULTS: In NL men, KC caused a 3-fold increase in mean LH on d 3-4, which was stable on d 6-7 with no add-back. Addition of T reduced LH levels (34.6+/-3.9 to 17.4+/-3.6 IU/liter, P<0.05) by slowing GnRH pulse frequency (13.3+/-0.4 to 6.7+/-1.0 pulses/12 h, P<0.005). LH amplitude increased (6.9+/-1.0 to 12.1+/-1.4 IU/liter, P<0.005). E2 add-back suppressed LH levels (36.4+/-5.6 to 19.0+/-2.4 IU/liter, P<0.005), by slowing GnRH pulse frequency (11.4+/-0.2 to 8.6+/-0.4 pulses/12 h, P<0.05) and had no impact on LH pulse amplitude. In IHH men, restoring normal T levels caused no suppression of mean LH levels or LH amplitude. E2 add-back normalized mean LH levels and decreased LH amplitude from 14.7+/-1.7 to 12+/-1.5 IU/liter (P<0.05). CONCLUSIONS: 1) T and E2 have independent effects on LH. 2) Inhibition of LH by T requires aromatization for its pituitary, but not hypothalamic effects. 3) E2 negative feedback on LH occurs at the hypothalamus.     

Interactions of estradiol with gonadotropin-releasing hormone and thyrotropin-releasing hormone in the control of growth hormone secretion in the goldfish.

The effects of testosterone (T) and estradiol (E2) on serum growth hormone (GH) concentrations were investigated throughout the seasonal reproductive cycle of the female goldfish. Gonad-intact female goldfish were implanted intraperitoneally for 5 days with silastic pellets containing no steroid (blank), T(100 micrograms/g) or E2 (25-100 micrograms/g). In blank-implanted females, seasonal variations in serum GH were evident; maximal serum GH levels were found in spring while minimal GH levels were found in summer and early autumn. Implantation of E2-containing silastic capsules stimulated increases (2-4 times control) in serum GH levels throughout the reproductive cycle. Implantation of T did not affect serum GH at any time of the year. One possible mechanism by which E2 could exert its effects may be through alteration of pituitary sensitivity to GH-releasing factors. The decapeptide salmon gonadotropin-releasing hormone (sGnRH) is found in the brain and pituitary of goldfish and stimulates gonadotropin (GTH) and GH secretion. In contrast, thyrotropin-releasing hormone (TRH) stimulates GH, but not GTH, release from pars distalis fragments obtained from sexually regressed (ED50 = 5.7 +/- 3.8 nM; August) or sexually mature (ED50 = 0.53 +/- 0.28 nM; March) fish; in vivo E2 treatment resulted in a 3-fold increase in the in vitro GH response to TRH. Furthermore, E2 treatment increased sGnRH-stimulated GH release by approximately 4-fold. These results demonstrate that E2 but not T stimulates GH secretion throughout the reproductive cycle of female goldfish. Furthermore, sGnRH and TRH stimulate GH release in a teleost, and these stimulatory responses are enhanced by physiological levels of E2.     

Gonadotropin gene expression and secretion in gonadotropin-releasing hormone antagonist-treated male rats: effect of sex steroid replacement.

The possibility of direct pituitary effects of sex steroids on gonadotropin gene expression and synthesis was studied in male rats. The animals were treated with a potent GnRH antagonist, Ac-D-pClPhe-D-pClPhe-D-Trp-Ser-Tyr-D-Arg-Leu-Arg-Pro-D-Ala-+ ++NH2CH3COOH (Org 30276; 0.5 mg/kg BW, sc, twice daily) for 10 days. Groups of the antagonist-treated rats were implanted at the beginning of the injections with Silastic capsules containing testosterone (T), 5 alpha-dihydrotestosterone (DHT), or diethylstilbestrol (DES). Groups treated with the antagonist alone or vehicle served as controls. The antagonist treatment decreased unoccupied pituitary receptors of GnRH by 93% (P less than 0.001), serum LH by 34% (P less than 0.01), and serum FSH by 30% (P less than 0.05), and serum T became undetectable (less than 0.10 nmol/liter). Compared to antagonist treatment alone, no further effects on serum or pituitary LH levels found after steroid replacements. In contrast, the antagonist-induced decreases in serum and pituitary FSH (30% and 70%, respectively; P less than 0.05-0.01) were totally reversed by the T and DHT implants, but not by DES. Pituitary levels of the LH beta-subunit mRNA were decreased by 60% (P less than 0.01) after antagonist treatment. Combination treatment with androgens had no further effect on this mRNA, whereas DES partially reversed this suppression (P less than 0.05). In contrast, the pituitary mRNA level of the FSH beta-subunit, which decreased with antagonist treatment by 90% (P less than 0.01), returned to the control level with T and DHT replacements, but only partially with DES. The pituitary mRNA level of the common alpha-subunit was significantly suppressed only by combined antagonist plus DHT treatment (P less than 0.01). However, combination of DES with the antagonist increased alpha-subunit mRNA levels 2.4-fold (P less than 0.05) compared to antagonist treatment alone. It is concluded that the suppression of gonadotropin secretion by GnRH antagonist treatment is accompanied in male rats by a parallel reduction in mRNA levels of the gonadotropin beta-subunits. Sex steroid replacement of the antagonist-treated animals selectively reverses some of the mRNA changes. Androgens (T and DHT) increase the mRNA of FSH beta-subunit, but have no effect on the LH beta-subunit. Estrogen increases the mRNA levels of common alpha- and LH beta-subunits and slightly increases that of FSH beta.(ABSTRACT TRUNCATED AT 400 WORDS)     

Age-related changes in secretion of adrenocortical steroid hormones in normal healthy men

The influence of aging on the steroid secretory capacity of the adrenal gland was evaluated by comparing data on young (age 20 to 21 years) with elderly (age 77 to 86 years) healthy male subjects. After the administration of ACTH-Z (1 mg, im) during the treatment of dexamethasone (1 mg/day, for 2 days), blood samples were taken at time 0, 1, 2, 3, 6, 12 and 24 h. The mean basal levels of pregnenolone (P5), 17-hydroxypregnenolone (170HP5), dehydroepiandrosterone (DHEA), progesterone (P4), 17-hydroxyprogesterone (170HP4), androstenedione (A-dione) and aldosterone (Ald) gradually decreased with advance in age. Dexamethasone administration to the elderly men produced no significant fall in plasma P4 and Ald. Plasma ACTH levels after ACTH-Z administration were significantly higher in the elderly men than the comparable levels in the young men. The apparent half-life of ACTH-Z in plasma was prolonged in the elderly men. For 3 hours after ACTH-Z injection, the responses of all plasma steroids, such as P5, 170HP5, DHEA, P4, 170HP4, A-dione, Ald and cortisol (F), were significantly lower in the elderly men. When the 24-hour secretion rates of steroid hormones were compared by delta area, which indicated the increased area for 24 hours after ACTH-Z administration, the secretion rate of F showed no significant difference between the two groups, but that of DHEA was significantly low in the elderly men. The 24-hour secretion rates of P5 and P4 were not impaired and that of 170HP4 was significantly high in the elderly men. These results indicate that the steroidogenic response to ACTH decreases with aging, and that, in the elderly men, an apparent decrease in C17,20 lyase efficiency may be related in part to the decreased secretion of adrenal androgens.     

Influence of norepinephrine administration upon pituitary hormone secretion in normal men

This study has investigated the effects of 6.2, 12.5, 25, 50 and 100 ng/kg/min/60 min of NE infused to normal men. Blood samples were obtained every 10 min, before, during and after drug administration for 3 consecutive h. Plasma levels on NE, LH, FSH, PRL, and GH were measured in all samples. The administration of 12.5 ng/kg/min over 60 min of NE induced a significant increase (p less than 0.001) in plasma NE levels (n = 5) from a mean (+/- SE) baseline of 239 +/- 14 ng/L to 706 +/- 54 ng/L which peaked and plateaued at 40 min. The calculated area under the curve was 18562 +/- 3537 ng/L/h of NE and significantly higher (p less than 0.001) than during the h before the infusion (2358 +/- 780 ng/L/h). This increase in plasma NE correlated well with the rise in plasma LH which showed a steady increase from baseline of 7.4 +/- 1.3 mIU/ml to a significant (p less than 0.05) peak of 11 +/- 1.9 mIU/ml at the end of the infusion. Furthermore, analysis of the area under the curve revealed a greater (p less than 0.05) LH release during the NE infusion (180 +/- 18 mIU/ml/h) than before the infusion (92 +/- 17 mIU/ml/h). With the exception of the studies utilizing 12.5 ng/kg/min/60 min, all other doses of NE resulted in no significant and/or consistent changes in plasma concentration of LH, FSH, GH and PRL. Thus, the direct participation of NE in the control of LH secretion in humans seems to occur in a very narrow window.     

Effect of recombinant human inhibin on gonadotropin secretion by the male rat

We have examined the effect of recombinant human inhibin-A on basal and GnRH-induced gonadotropin secretion by male rats or cultured anterior pituitary cells. Inhibin, administered sc 6 h before the experiment, induced dose- and time-related decreases in plasma FSH, but not LH, levels in both intact and castrated male rats. Inhibin also significantly interfered with the in vivo stimulatory effect of 20-500 ng GnRH on FSH release, but had inconsistent and usually modest effects on the LH response. While exposure of cultured pituitary cells to inhibin for 72 h has been reported to interfere with GnRH-induced gonadotropin release, we examined here the effects of shorter exposure periods relevant to in vivo experiments. Exposure of the cells to inhibin (31.3-312.5 pM) for 2-6 h measurably (P less than or equal to 0.01) decreased the ability of 10 nM GnRH to stimulate both FSH and LH released by cultured cells. In contrast, lower (3.1 and 9.4 pM) doses of inhibin had little or no effect. Longer exposures to inhibin (10, 24, and 72 h) increased the inhibitory effect of 31.3-312.5 pM inhibin, while 3.1 and 9.4 pM remained ineffective at all times. These results indicate that exposure of the male rat to inhibin for 6 h decreases FSH secretion, and that this effect is at least partially mediated through blunting of the pituitary response to GnRH. In contrast, the ability of inhibin to interfere with LH release, which is readily apparent in cultured pituitary cells, appears to be of lesser importance in the intact male rat.     

Chronic human chorionic gonadotropin administration in normal men: evidence that follicle-stimulating hormone is necessary for the maintenance of quantitatively normal spermatogenesis in man

The role of FSH in the maintenance of spermatogenesis in man is poorly understood. To determine whether normal serum levels of FSH are necessary for the maintenance of quantitatively normal spermatogenesis, we first studied the effect on sperm production of selective FSH deficiency induced by chronic administration of hCG in normal men. Then, we determined the effect of FSH replacement in some of these men. After a 3-month control period, eight normal men (aged 30-39 yr) received 5000 IU hCG, im, twice weekly for 7 months. Then while continuing the same dosage of hCG, subjects simultaneously received 200 mg testosterone enanthate (T), im, weekly for an additional 6 months. hCG administration alone resulted in partial suppression of the mean sperm concentration from 88 +/- 24 (+/-SEM) million/ml during the control period to 22 +/- 7 million/ml during the last 4 months of hCG treatment (P less than 0.001 compared to control values). With the addition of T to hCG, sperm counts remained suppressed to the same degree. Except for one man who became azoospermic while receiving hCG plus T, sperm motilities and morphologies remained normal in all subjects throughout the entire study. During both the hCG alone and hCG plus T periods, serum FSH levels were undetectable (less than 25 ng/ml), and urinary FSH levels were comparable to those in prepubertal children and hypogonadotropic hypogonadal adults. We replaced FSH activity in four of the eight men in whom prolonged selective FSH deficiency and partial suppression of sperm production were induced by hCG administration. Immediately after the period of hCG plus T administration, T was stopped in four men who continued to receive hCG alone (5000 IU, im, twice weekly) for 3 months. Then, while continuing the same dosage of hCG, these men received 100 IU human FSH, sc, daily (n = 2) or 75 IU human menopausal gonadotropin, sc, daily (n = 2) for 5-8 months. During the second period of hCG administration alone, serum FSH levels were undetectable (less than 25 ng/ml), and sperm concentrations were suppressed (34 +/- 13 million/ml) compared to the control values for these four men (125 +/- 39 million/ml; P less than 0.001). With the addition of FSH to hCG, FSH levels increased (213 +/- 72 ng/ml) and sperm concentrations rose significantly, reaching a mean of 103 +/- 30 million/ml (P less than 0.03 compared to hCG alone).(ABSTRACT TRUNCATED AT 400 WORDS)     

Sex steroids and odorants modulate gonadotropin-releasing hormone secretion in primary cultures of human olfactory cells

Olfactory neurons and GnRH neurons share a common origin during development. In the nasal epithelia, GnRH neurons persist throughout fetal life and adulthood. The fate and function of these neurons in vivo have remained unknown. In a previous in vitro study, we isolated, cloned, and propagated primary long term cell cultures from the olfactory neuroepithelium of 8- to 12-week-old human fetuses. These cells expressed both neural proteins as well as olfactory genes and were responsive to odorant stimuli. We now report that these human olfactory cells also express the GnRH gene and protein. Combined HPLC and RIA studies have indicated that these cells release authentic GnRH in spent media. The release of GnRH was time dependent and was positively affected by sex steroids and odorants. Immunohistochemical data demonstrated the presence of sex steroid receptors in these cells. The presence of the alpha- and beta-subtypes of the estrogen receptor was also demonstrated by RT-PCR and Western blot analysis. When the cells were stimulated with increasing concentrations of 17beta-estradiol in the presence of a fixed concentration of progesterone (10(-7) mol/L), the combination of the two steroids induced a 3- to 4-fold increase in GnRH secretion. This stimulatory effect was completely blunted by tamoxifen. Neither 17beta-estradiol nor progesterone was effective when tested separately. Treatment with increasing concentrations of the odorant, l-carvone, induced a time- and dose-dependent dramatic increase in GnRH protein release (1000-fold increase) and gene expression. Repeated application of the stimulus resulted in a progressive lower responsiveness of the cells. To our knowledge, this is the first time that primary cell cultures from human fetal olfactory neuroepithelium have been shown to express and release GnRH. Our results also demonstrate that these cultures, which are sensitive to sex steroids and odorants, can be useful models in the study of the complex array of regulatory factors that finely tune GnRH secretion in humans.