The synthesis and release of gonadotropins in response to gonadotropin-releasing hormone of the rat anterior pituitary gland during weight reduction

It is well recognized that weight reduction produces the suppression of serum LH but not FSH level in rodents. In order to clarify the mechanism by which the discrepancy between LH and FSH levels is brought about, the influence of weight loss on the pituitary function was explored using female rats. The changes of the pituitary response to GnRH and the basal secretion of gonadotropins with progressive weight loss were investigated by in vitro short-term incubation of the pituitary gland after prolonged weight loss in female Wistar rats. On the first day of diestrous and until day 14 of the diet, GnRH induced LH and FSH release from the pituitary and a decrease in pituitary content of them, but the total amount of gonadotropin in culture medium and pituitary tissue was not affected. On day 30 of the diet, the decrease in pituitary content disappeared. On day 60 LH release disappeared, whereas pituitary FSH and the total amount of gonadotropins were increased by GnRH. Non-stimulated FSH but not LH secretion per mg of pituitary was augmented during dieting. The data indicate that pituitary responsiveness to GnRH and non-stimulated FSH release were modified by weight loss: the LH-releasing action of GnRH was diminished, the gonadotropin-synthesizing action of GnRH was augmented, and non-stimulated FSH release was increased.     

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.     

Simultaneous effect of gonadotropin-releasing hormone (GnRH) on the expression of two gonadotropin beta genes by passive immunization to GnRH

In order to reveal the action of gonadotropin-releasing hormone (GnRH) on the synthesis of gonadotropins in the pituitary gland of castrated rats, passive immunization to GnRH designed to block the activity of GnRH was performed. The levels of prolactin mRNA in castrated and rabbit anti-GnRH serum (RAGnRH)-treated rats decreased, whereas TSH beta mRNA showed no statistically significant change. In contrast, mRNAs encoding common alpha, LH beta and FSH beta were increased 2.7-, 1.7- and 1.5-fold, respectively, by castration. These elevated mRNA levels of gonadotropin subunits in castrated rats well explain the increased hormone levels in serum and in the pituitary. Two days later, a single administration of RAGnRH to the castrated rats significantly suppressed the mRNA levels to 2.0-fold for alpha, 1.2-fold for LH beta and 1.1-fold for FSH beta relative to the respective control values. These results showed that the two gonadotropin beta genes respond more rapidly to GnRH action that the common alpha gene.     

Effects of gonadectomy on the in vitro and in vivo gonadotropin responses to gonadotropin-releasing hormone in male and female rats

Pituitary gonadotropin responses to GnRH were measured using both in vitro and in vivo methods to investigate the contribution of increased pituitary responsiveness to GnRH in generating the rise in serum gonadotropin levels after gonadectomy. We compared in vitro GnRH-stimulated secretion rates of LH and FSH of perifused pituitaries obtained from intact female (metestrous) and male rats, and rats gonadectomized 2 or 6 days earlier. GnRH pulses (peak amplitude, 50, 500, or 5000 ng/ml; frequency, one per h) caused significant dose-dependent increases in gonadotropin secretion rates. However, gonadectomy resulted in decreased secretion rates of LH and FSH. Similar findings were observed for in vivo serum gonadotropin responses to a single iv injection of GnRH (males received 250 or 1000 ng; females received 1000 or 4000 ng). These results indicate that increases in serum LH and FSH levels 2 or 6 days after gonadectomy are not mediated by increased responses of the rat anterior pituitary to GnRH. We have also shown that perifused pituitaries from proestrous and diestrous rats exhibit significantly higher GnRH-stimulated gonadotropin secretion rates than pituitaries from metestrous and estrous rats. Therefore, we tested the effect of in vivo pretreatment with 17 beta-estradiol (E2) or testosterone (T) in both female and male rats on the in vitro secretion of LH and FSH. Rats were gonadectomized and received a sc Silastic implant containing E2, T, or no steroid as a control 6 days before perifusion. Perifused pituitaries received pulses of GnRH (peak amplitude, 50 ng/ml; frequency, one per h). In vivo pretreatment with E2, but not T, caused significant increases of in vitro LH and FSH secretion rates for pituitaries of both sexes. Overall, our data demonstrate that gonadectomy does not cause increases in LH and FSH secretory responses to GnRH, and that prior exposure to E2 in vivo has a major stimulatory influence on the in vitro secretion of both gonadotropins regardless of sex.     

Acute inhibitory effects of 17 beta-estradiol are observed on gonadotropin secretion from perifused pituitary fragments of metestrous, but not proestrous, rats

The in vivo suppression of LH by 17 beta-estradiol (E2) has been documented frequently. However, the demonstration of a direct inhibitory action of E2, in contrast to a stimulatory action, on the secretion of LH from the anterior pituitary has been inconsistent. The aim of this study was to determine if E2 can suppress either basal (unstimulated) or GnRH-stimulated gonadotropin secretion directly at the level of the anterior pituitary gland. Anterior pituitaries were obtained from metestrous and proestrous females rats at 0900 h, and trunk blood was collected for serum measurements of LH, FSH, E2, and progesterone (P). Each anterior pituitary was cut into eighths and placed into a microchamber for perifusion. Pituitary fragments were perifused at a rate of 10 ml/h using medium 199 (without phenol red) that contained E2 (1 nM) or ethanol as a control. Six pulses of GnRH (peak amplitude, 50 ng/ml; duration, 2 min) were administered one per h starting at 60 min. Fractions of perfusate were collected every 5 min for measurement of LH and FSH. The total amounts of LH and FSH secreted during the 1-h interval after each GnRH pulse or corresponding basal hour were calculated. Both basal and LH and FSH responses to GnRH were significantly greater from pituitaries of proestrous compared to metestrous rats. The selective suppression of LH secretion by in vitro treatment with E2 was demonstrated using pituitaries from metestrous rats receiving GnRH pulses, but not using pituitaries from proestrous rats. Thus, a negative feedback effect of E2 on LH secretion was observed only in pituitaries from donors with low serum levels of E2 and high P, but not from donors with high serum levels of E2 and low P. We believe that the in vivo steroid environment determined the subsequent responses to in vitro treatment with E2 on GnRH-stimulated gonadotropin secretion from the isolated pituitary gland.     

Inhibition of pituitary gonadotropin secretion by the gonadotropin-releasing hormone antagonist antide. I. In vitro studies on mechanism of action

The GnRH antagonist antide is among the most promising "third generation" compounds available for clinical evaluation. In primates, antide manifests prolonged (several weeks) and reversible inhibition of pituitary gonadotropin secretion after a single high dose injection. In the present study, we have examined the effects of antide on pituitary gonadotropin secretion in vitro. Dispersed anterior pituitary cells from adult female rats were plated (48 h; 5 x 10(5) cells/well), washed, and exposed to increasing concentrations of antide for up to 48 h. Media were removed, and cells were washed twice and then incubated with GnRH (1 x 10(-8) M) plus antide for 4 h. Media and cell lysates were assayed for LH/FSH by RIA. Antide had no effect on basal LH/FSH secretion at any dose tested (10(-6)-10(-12) M). In contrast, GnRH-stimulated LH/FSH secretion was inhibited by this GnRH antagonist in a dose- and time-dependent manner. When incubated simultaneously, antide blocked GnRH-stimulated gonadotropin secretion, with a maximal effect at 10(-6) M (ED50, 10(-7) M). Preincubation of pituitary cells with antide for 6-48 h before GnRH exposure shifted the dose-response curve to the left; the maximally effective dose was 10(-8) M; the ED50 was 10(-10) M antide after 48-h preincubation. Intracellular LH/FSH levels increased concomitant with the decrease in secreted gonadotropins. Total LH/FSH levels (secreted plus cell content) remained unchanged. The inhibition of LH secretion by antide was specific for GnRH-stimulated gonadotropin secretion; antide had no effect on K(+)-stimulated LH secretion. Moreover, antide had little or no residual effect on LH secretion; full recovery of GnRH responsiveness in vitro occurred within 4 h after removal of antide. Lineweaver-Burke analysis of antide inhibition of GnRH-stimulated LH secretion indicated that antide is a direct competitor of GnRH at the level of the pituitary GnRH receptor. In summary, antide is a pure antagonist of GnRH stimulation of gonadotropin secretion; no agonistic actions of antide were manifest in vitro. Moreover, antide has no apparent noxious or toxic effect on pituitary cells in culture; the actions of antide are immediately reversible upon removal of antide from pituitary gonadotropes. We conclude that the long term inhibition of gonadotropin secretion by antide in vivo is not due to deleterious effects of this compound at the level of the pituitary gonadotrope.     

Gonadal regulation of gonadotropin subunit gene expression: evidence for regulation of follicle-stimulating hormone-beta messenger ribonucleic acid by nonsteroidal hormones in female rats

Gonadectomy results in a rise in gonadotropin secretion and subunit gene expression, although the relative contributions of declining gonadal hormones or increasing hypothalamic GnRH secretion are uncertain. To further delineate the roles of the hypothalamus and gonads in regulation of gonadotropin gene expression, male and female rats were castrated and gonadotropin subunit messenger RNA (mRNA) concentrations measured 2, 7, 14, or 21 days (d) later. In males, FSH beta mRNA was maximal (2-fold increase) by 7 d while peak levels of alpha (3-fold) and LH beta (3-fold) were seen by 14 d. Testosterone (T) replacement restored all three subunit mRNA concentrations to intact values. In females, FSH beta mRNA also reached plateau levels (8-fold increase) earlier than alpha (3-fold) or LH beta (11-fold). When female rats ovariectomized 7 days earlier were given estradiol (E2) and progesterone (P) implants for up to 14 d, suppression of alpha and LH beta to intact levels was observed. However, FSH beta mRNA concentrations only decreased to 67% of castrate values, and remained 2- to 3-fold higher than levels in intact female rats. Female rats were also given E2 replacement at the time of ovariectomy. LH beta mRNA was maintained at intact levels for 14 days while alpha and FSH beta showed partial castration responses (2-fold and 3-fold, respectively). Finally, to determine whether E2 and P regulate gonadotropin subunit expression directly or by reducing GnRH secretion, female rats were ovariectomized and immediately replaced with E2, P, or E2 + P in the presence or absence of a GnRH antagonist (A) for 2 d. alpha mRNA was increased (2-fold) by E2 but not by E2 + A suggesting that E2 requires the presence of GnRH to increase alpha mRNA. P alone was ineffective, but both E2 and A prevented the LH beta mRNA response to ovariectomy. The effects of E2 and A were not additive, suggesting that E suppresses LH beta mRNA by inhibiting the increase in GnRH secretion. In contrast, the FSH beta mRNA response to ovariectomy was only partially suppressed by E2, E2 + P, or E2 + P + A. These data indicate that in castrate males, replacement of T suppresses all three subunit mRNAs to intact levels. However, replacement of E2 to ovariectomized females did not prevent the increase in alpha and FSH beta mRNAs. In female rats, LH beta mRNA is predominantly regulated by GnRH. alpha mRNA expression is also mainly regulated by GnRH, and E2 appears to augment GnRH action on alpha mRNA expression.(ABSTRACT TRUNCATED AT 400 WORDS)     

Dopamine agonist- and antagonist-induced modulation of pituitary gonadotrophin releasing hormone receptors are independent of changes in serum prolactin

The effect of drug-induced hypo- and hyperprolactinaemia on pituitary gonadotrophin releasing hormone receptors (GnRH-R), serum and pituitary gonadotrophins (LH and FSH) and prolactin was investigated in intact adult male and female rats. Hypoprolactinaemia (serum prolactin less than 20% of control values) resulting from dopamine agonist (bromocriptine) infusion (4 mg/kg per day for 7 days) was accompanied by a 40-50% increase in GnRH-R in both male and female animals, though this was not accompanied by any major change in serum or pituitary LH and FSH. Hyperprolactinaemia (serum prolactin greater than ten times control values) induced by the dopamine receptor antagonist metoclopramide (65 mg/kg per day for 7 days) increased GnRH-R between 35 and 45% in both male and female rats without altering serum gonadotrophins. Domperidone (1 mg twice daily for 14 days) also increased GnRH-R by 50% but only in female rats. Both dopamine antagonists significantly increased pituitary prolactin content. Pituitary FSH increased in female rats treated with both metoclopramide and domperidone. The stimulatory effects of bromocriptine and metoclopramide on GnRH-R in male rats were prevented by concurrent treatment with a GnRH antiserum, suggesting that the drug effects were mediated through alteration in endogenous GnRH secretion. Induction of massive (serum prolactin greater than 2000 micrograms/l) hyperprolactinaemia in male and female rats with a transplantable prolactin-secreting pituitary tumour did not reduce GnRH-R concentration, although serum gonadotrophins were suppressed and pituitary gonadotrophin content was increased.(ABSTRACT TRUNCATED AT 250 WORDS)     

A detailed examination of the in vivo and in vitro effects of ACTH on gonadotropin secretion in the adult rat

These studies were designed to: (1) determine the effects of continuous infusion of synthetic ACTH(1-24) on postcastration changes in serum and pituitary LH, FSH and prolactin in the male rat; (2) assess the effects of adrenalectomy on the gonadotropin and prolactin response to ACTH, and (3) test the hypothesis that ACTH may directly (not via adrenal factors) alter gonadotropin secretion at the brain and/or pituitary level. Adult male rats were either orchidectomized (ORX) or orchidectomized-adrenalectomized (ORX-ADX), and were treated continuously for 6 days with ACTH(1-24) (10 micrograms/day) or saline using an osmotic minipump. Animals were killed on day 6 following castration. ACTH treatment reduced serum LH and prolactin levels in ORX rats to mean values +/- SE of 204 +/- 25 and 37 +/- 3 ng/ml respectively, compared to 366 +/- 72 and 62 +/- 7 ng/ml in saline-treated ORX animals. Serum FSH concentrations were not altered by ACTH administration. Pituitary concentrations of LH and FSH, but not prolactin were enhanced by ACTH treatment. Adrenalectomy had no effect on serum and pituitary gonadotropin and prolactin levels, but abolished the effects of ACTH on these parameters. Central (intracerebroventricular) infusion of ACTH(1-24) (6 micrograms/day X 4 days) failed to alter the rise in serum LH in male rats following orchidectomy. Acute treatment with large doses of ACTH of perifused anterior pituitary glands from male rats and chronic treatment with ACTH of enzymatically dispersed anterior pituitary cells from female rats did not influence basal or GnRH-stimulated LH secretion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hypothalamic-pituitary function in the old irregularly cycling rat

Older irregularly cycling and younger regularly cycling rats exhibited similar increases in LH levels 1, 2 and 3 wks after ovariectomy, but FSH reached higher levels in the older than in the younger rats after ovariectomy. Neither the ability of 5 μg/kg estrogen to suppress gonadotropin levels nor the capability of larger doses of estrogen (250 μg/kg) and/or progesterone (10 mg/kg to trigger an LH release were altered with age. LH release from the pituitary in response to exogenous gonadotropin releasing hormone (GnRH) was attenuated in ovariectomized older rats, but was partially restored after estrogen and/or progesterone priming. The FSH levels after GnRH treatment were greater in the estrogen primed aged that in estrogen-primed younger rats. The disruption of regular cycles in older rats may be due to a lack of a neural signal for gonadotropin release rather than a failure of the hypothalamus to respond to the positive feedback effect of estrogen or the failure of the pituitary to respond to GnRH.     

Development of gonadal feedback regulation of gonadotropin gene expression and secretion in female rats.

The postnatal development of the gonadal negative feedback control of gonadotropins was studied in female rats. Neonatal (5-day-old) and randomly cycling young (60-day-old) and more mature (180-day-old) adult rats were ovariectomized, and half of them received Silastic implants containing the synthetic estrogen, diethylstilbestrol. The neonatal rats were killed 5, 10 or 15 days, and the adult rats 7 days after the operation. Age-matched and sham-operated animals served as controls. There were no statistically significant responses of serum LH or FSH concentrations or of the pituitary gonadotropin subunit mRNA levels to ovariectomy at any of the neonatal ages. A marked increase (p < 0.01) after ovariectomy was seen in serum gonadotropins and in the cognate mRNA levels at both adult ages. In spite of the weak feedback response of the neonatal rats to ovariectomy, diethylstilbestrol suppressed the basal pituitary gonadotropin concentrations and the specific LH and FSH beta-chain mRNAs (p < 0.01-0.05). These results demonstrate that the gonadal negative feedback regulation of gonadotropin synthesis and secretion is not fully developed in neonatal and prepubertal female rats before 20 days of age. This is probably due to the steroidogenic quiescence of the ovaries in early life. However, the capability of the pituitary to respond to negative estrogen feedback has developed in the neonatal female, as demonstrated by the suppressive effects of diethylstilbestrol treatment on gonadotropin secretion.     

Pulsatile luteinizing hormone and follicle-stimulating hormone secretion and gonadotropin subunit mRNA levels in the ovariectomized GPR-4 transgenic rat

Genetic targeting of the cAMP-specific phosphodiesterase 4D1 (PDE4D1) to gonadotropin-releasing hormone (GnRH) neurons in the GPR-4 transgenic rat resulted in decreased luteinizing hormone (LH) pulse frequency in castrated female and male rats. A similar decrease in the intrinsic GnRH pulse frequency was observed in GT1 GnRH cells expressing the PDE4D1 phosphodiesterase. We have extended these findings in ovariectomized (OVX) GPR-4 rats by asking what effect transgene expression had on pulsatile LH and follicle-stimulating hormone (FSH) secretion, plasma and pituitary levels of LH and FSH, and levels of the alpha-glycoprotein hormone subunit (alpha-GSU), LH-beta and FSH-beta subunit mRNAs. In OVX GPR-4 rats the LH pulse frequency but not pulse amplitude was decreased by 50% compared to wild-type littermate controls. Assaying the same samples for FSH, the FSH pulse frequency and amplitude were unchanged. The plasma and anterior pituitary levels of LH in the GPR-4 rats were significantly decreased by approximately 45%, while the plasma but not anterior pituitary level of FSH was significantly decreased by 25%. As measured by real-time RT-PCR, the mRNA levels for the alpha-GSU in the GPR-4 rats were significantly decreased by 41%, the LH-beta subunit by 38% and the FSH-beta subunit by 28%. We conclude that in the castrated female GPR-4 rats the decreased GnRH pulse frequency results in decreased levels of LH and FSH and in the alpha- and beta-subunit mRNA levels.     

Effects of ovarian steroids on the gonadotropin response to N-methyl-D-aspartate and on hypothalamic excitatory amino acid levels during sexual maturation in female rats.

In order to evaluate the involvement of estrogen-progesterone (EP) in the effects of N-methyl-D-aspartate (NMDA) receptor stimulation on gonadotropin secretion during sexual development in female rats, NMDA (30 mg/kg sc) was administered to 16- and 30-day-old female rats pretreated with EP. NMDA administration induced increases in plasma LH concentration that were 13.6-fold and 94.5-fold higher, respectively, than those found after NMDA alone. The increase of LH levels induced by NMDA was accompanied by a significant enhancement of the content of GnRH in the anterior and preoptic hypothalamic areas and in the medial basal hypothalamus (APOA/MBH). EP potentiated this increase of GnRH induced by NMDA. NMDA increased plasma FSH levels at 16 days of age, and this increase was inhibited by EP treatment. In 30-day-old rats EP induced FSH release in response to NMDA. This release was not observed in rats treated only with NMDA. In 16-day-old rats EP induced an increase in the concentrations of aspartate, glutamate, and glycine in the anterior and preoptic hypothalamic areas and in the medial basal hypothalamus, the excitatory amino acids involved in NMDA neurotransmission. This effect was not observed in rats of 30 days of age. In summary, the present results show that during sexual maturation ovarian steroids potentiated the LH-releasing response to NMDA probably by acting at the hypothalamic level; furthermore, during sexual maturation there are changes in the response to EP of the hypothalamic concentrations of excitatory amino acids. These findings could be related to the neuroendocrine mechanisms regulating the onset of puberty and the sexual cycle in female rats.     

Effects of leptin on gonadotropin secretion in juvenile female rat pituitary cells

OBJECTIVE: Leptin is an adipocyte-derived hormone, which is the product of the obese gene and it is thought to play important roles in pubertal development and maintenance of reproductive function in the female. In a study using adult male or female rats, it was found that leptin stimulated the secretion of gonadotropin directly from the pituitary in a dose-related manner. However, there is no study in juvenile female rats before puberty. METHODS: In this study, we cultured pituitary cells from 4-, 6- and 8-week-old female Wistar rats with leptin (0-10(-7)mol/l) and gonadotropin-releasing hormone (GnRH) (0 or 10(-8) mol/l). Basal or GnRH-stimulated secretion of luteinizing hormone (LH) and follicle-stimulating hormone (FSH), and their synthesis within cells were determined by radioimmunoassay (RIA). RESULTS: Leptin induced bell-shaped dose--response curves of basal LH and FSH secretion from cultured cells of every age-group of rats studied. The most effective concentration of leptin on the basal secretion of LH and FSH from 6- and 8-week-old cultured pituitary cells was 10(-10) mol/l. This leptin concentration was consistent with circulating physiological serum leptin levels at each age. As for juvenile 4-week-old pituitary cells, the most effective concentration was 10(-11) mol/l which was lower than that of 6- and 8-week-old rats. It was consistent with the circulating serum leptin levels of 4-week-old rats. Also, the synthesis and the GnRH-stimulated secretion of LH and FSH were effectively controlled by leptin at concentrations similar to the serum leptin levels of given ages. CONCLUSIONS: Leptin induced pituitary cells to synthesize and secrete both LH and FSH regardless of the presence or absence of GnRH. The concentration of leptin that induced the greatest synthesis and secretion of gonadotropins from pituitary cells changed around the pubertal period. The most effective leptin concentrations in each experiment were similar to the physiological serum leptin level at each animal age. These results indicate that leptin stimulates gonadotrophs not only in the pubertal and the mature period but also in the juvenile period before puberty. It is also conceivable that leptin may modulate the sensitivity of gonadotrophs until the appearance of GnRH stimulation, and may be the factor that brings about puberty onset.     

Hypothalamic-pituitary function in the old irregularly cycling rat.

Older irregularly cycling and younger regularly cycling rats exhibited similar increases in LH levels 1, 2 and 3 wks after ovariectomy, but FSH reached higher levels in the older than in the younger rats after ovariectomy. Neither the ability of 5 microgram/kg estrogen to suppress gonadotropin levels nor the capability of larger doses of estrogen (250 micrograms/kg) and/or progesterone (10 mg/kg to trigger an LH release were altered with age. LH release from the pituitary in response to exogenous gonadotropin releasing hormone (GnRH) was attenuated in ovariectomized older rats, but was partially restored after estrogen and/or progesterone priming. The FSH levels after GnRH treatment were greater in the estrogen primed aged that in estrogen-primed younger rats. The disruption of regular cycles in older rats may be due to a lack of a neural signal for gonadotropin release rather than a failure of the hypothalamus to respond to the positive feedback effect of estrogen or the failure of the pituitary to respond to GnRH.     

The bi-modal effects of estradiol on gonadotropin synthesis and secretion in female mice are dependent on estrogen receptor-alpha

Depending on the estrous/menstrual cycle stage in females, ovarian-derived estradiol (E(2)) exerts either a negative or a positive effect on the hypothalamic-pituitary axis to regulate the synthesis and secretion of pituitary gonadotropins, LH, and FSH. To study the role of estrogen receptor-alpha (ERalpha) mediating these effects, we assessed the relevant parameters in adult wild-type (WT) and ERalpha-null (alphaERKO) female mice in vivo and in primary pituitary cell cultures. The alphaERKO mice exhibited significantly higher plasma and pituitary LH levels relative to WT females despite possessing markedly high levels of circulating E(2). In contrast, hypothalamic GnRH content and circulating FSH levels were comparable between genotypes. Ovariectomy led to increased plasma LH in WT females but no further increase in alphaERKO females, while plasma FSH levels increased in both genotypes. E(2) treatment suppressed the high plasma LH and pituitary Lhb mRNA expression in ovariectomized WT females but had no effect in alphaERKO. In contrast, E(2) treatments only partially suppressed plasma FSH in ovariectomized WT females, but this too was lacking in alphaERKO females. Therefore, negative feedback on FSH is partially E(2)/ERalpha mediated but more dependent on ovarian-derived inhibin, which was increased threefold above normal in alphaERKO females. Together, these data indicate that E(2)-mediated negative feedback is dependent on functional ERalpha and acts to primarily regulate LH synthesis and secretion. Studies in primary cultures of pituitary cells from WT females revealed that E(2) did not suppress basal or GnRH-induced LH secretion but instead enhanced the latter response, indicating that the positive influence of E(2) on gonadotropin secretion may occur at the level of the pituitary. Once again this effect was lacking in alphaERKO gonadotropes in culture. These data indicate that the aspects of negative and positive effects of E(2) on gonadotropin secretion are ERalpha dependent and occur at the level of the hypothalamus and pituitary respectively.     

Pituitary gonadotropin-releasing hormone (GnRH) receptor responses to GnRH in hypothalamus-lesioned rats: inhibition of responses by hyperprolactinemia and evidence that testosterone and estradiol modulate gonadotropin secretion at postreceptor sites

Increased hypothalamic GnRH secretion appears to influence positively the number of pituitary GnRH receptors (GnRH-R). GnRH-R increase after castration in male rats, and this rise can be prevented by testosterone (T), anti-GnRH sera, or hypothalamic lesions. GnRH also increases serum LH and GnRH-R in hypothalamus-lesioned rats, and these animals injected with exogenous GnRH are, therefore, a good model in which to study the site of steroid feedback at the pituitary level. Adult male and female rats were gonadectomized, and radiofrequency lesions were placed in the hypothalamus. Males received T implants, and females received estradiol implants at the time of surgery. Empty capsules were placed in the control animals. Beginning 3-5 days later, animals in each group were injected every 8 h with vehicle (BSA) or GnRH (0.002-200 micrograms/day) for 2 days. After these GnRH injections, all rats received 6.6 micrograms GnRH, sc, 1 h before decapitation to determine acute LH and FSH responses. GnRH-R were determined by saturation analysis using 125I-D-Ala6-GnRH ethylamide as ligand. In males, GnRH injections increased GnRH-R. T inhibited acute LH and FSH responses to GnRH in all groups, but had little effect on GnRH-R, indicating that T inhibits gonadotropin secretion at a post-GnRH receptor site. In females, the GnRH-R response to GnRH was less marked, and only the 200 micrograms/day dose of GnRH increased GnRH-R, indicating that the positive feedback effects of estradiol at the pituitary level are also exerted at a site distal to the GnRH receptor. There was no positive correlation between the number of GnRH-R and GnRH-stimulated gonadotropin release in males or females. Female rats with hypothalamic lesions had markedly elevated serum PRL levels (greater than 300 ng/ml). Suppression of PRL secretion by bromocryptine resulted in augmented GnRH-R responses to GnRH, and GnRH-R concentrations rose to the same values induced in males. This suggests that hyperprolactinemia inhibits GnRH-R responses to GnRH in females by a direct action on the pituitary gonadotroph.     

Effects of testosterone on gonadotropin subunit messenger ribonucleic acids in the presence or absence of gonadotropin-releasing hormone.

There is accumulating evidence that the negative feedback actions of testosterone on the pituitary may contribute to the differential regulation of FSH and LH secretion in males. In the present study we measured steady state levels of the mRNAs encoding the gonadotropin subunits in pituitary cell cultures treated with 10 nM testosterone (T) as well as in T-treated pituitary cells perifused with pulses of GnRH to explore further the direct actions of T on the pituitary. T treatment of pituitary cells in monolayer culture for 72 h increased FSH beta mRNA 1.5-fold (P less than 0.05), decreased alpha-subunit mRNA to 45% of the control level (P less than 0.05), and decreased LH beta mRNA to 75% of the control level (P less than 0.05). FSH and uncombined alpha-subunit secretion were increased and decreased by T, respectively, whereas basal LH secretion was unchanged. Treatment with 0.1 nM estradiol, a physiological concentration for males, did not change gonadotropin secretion or subunit mRNA concentrations. Between days 2 and 5 in culture in the absence of steroid treatment, steady state levels of LH beta and alpha-subunit mRNA declined (P less than 0.01) 52% and 61%, respectively, but FSH beta mRNA levels were unchanged. Pulsatile stimulation with 2.5 nM GnRH every 1 h for 10 h increased FSH beta mRNA 2.8-fold (P less than 0.05) and increased (P less than 0.05) alpha-subunit mRNA to 117% of the control level. When cell cultures were pretreated with T for 48 h and then perifused with pulses of GnRH, FSH beta, LH beta, and alpha-subunit mRNA levels were 66%, 74%, and 70% of the value during GnRH alone (P less than 0.05). T treatment also reduced (P less than 0.01) the amplitudes of FSH, LH, and alpha-subunit secretory pulses by 18%, 26%, and 41%, respectively. These data indicate that a portion of the negative feedback action of T is at the pituitary to regulate gonadotropin subunit gene expression. Our data reveal two opposing effects of T on FSH beta mRNA: a stimulatory action, which is GnRH independent, and an inhibitory effect, which is related to the actions of GnRH. These divergent actions of T represent one mechanism through which FSH and LH are differentially regulated.     

Influence of pinealectomy on the suppression of gonadotropin secretion induced by hyperprolactinaemia in the adult male rat

To investigate the role of the pineal gland in the long-term suppression of gonadotrophin secretion induced by prolactin, the effects of pinealectomy were studied in adult male rats with hyperprolactinaemia produced by the transplantation of two pituitary glands under the kidney capsule. Pinealectomy had no effect on basal levels of LH, FSH or prolactin. The presence of pituitary transplants induced a significant twofold increase in prolactin levels and a prolonged suppression in both LH and FSH. These changes were not affected by pinealectomy. Castration resulted in a similar rise in plasma levels of LH and FSH in rats with and without pituitary transplants. In control rats this rise in LH and FSH was reduced by testosterone-containing silicone elastomer implants (s.c) of 10 mm in length and delayed by implants of 30 mm. These rises in LH and FSH were significantly delayed (10-mm implant) or abolished (30-mm implant) in rats with pituitary transplants indicating an increase in sensitivity of the hypothalamic-pituitary axis to the negative feedback effects of testosterone in these animals compared to controls. These responses were not affected by pinealectomy. These results suggest that the pineal gland is not involved in the mechanism whereby pituitary grafts, possibly through their secretion of prolactin, cause long-term suppression of gonadotrophin secretion.     

In vivo administration of a GnRH antagonist to male mice: effects on pituitary gonadotropin secretion in vitro

The potent luteinizing hormone-releasing hormone antagonist [N-Ac-D-p-Cl-Phe1,2,D-Trp3,D-Arg6,D-Ala10]GnRH (4 mg/kg) was administered sc once or daily for 21 days to immune-deficient (nude) and normal immune-competent (NIC) male mice derived from the same genetic background. Effects of in vivo pretreatment with the antagonist on gonadotropin secretion from hemipituitary glands from both types of mice were studied in vitro in the presence or absence of synthetic GnRH. Treatment with the GnRH antagonist caused differential effects on release of FSH and LH from and amounts of FSH and LH in hemipituitary glands. Pituitary FSH secretion was effectively inhibited, whereas effects on pituitary LH were less evident or nonsignificant under these experimental conditions. Long-term treatment with the antagonist caused larger effects on pituitary secretion and content of FSH, when compared with short-term treatment. No significant effects of duration of treatment on secretion or pituitary content of LH were detected. Addition of synthetic GnRH to the incubation medium caused stimulation of gonadotropin release. Therefore, it was concluded that the high doses of this GnRH antagonist were not able to block GnRH receptors effectively in the pituitary glands of nude and NIC male mice. The incomplete suppression of LH secretion by this high dose of the GnRH antagonist may partly explain the inability of the antagonist to suppress plasma testosterone levels and the growth of androgen-dependent tumours in male mice.