Acute suppression of FSH secretion by oestradiol in the ovariectomized rhesus monkey

Using long-term ovariectomized rhesus monkeys, we examined the ability of oestradiol to decrease circulating FSH concentrations in the absence of other ovarian factors. Daily blood samples were obtained from untreated monkeys for 8 days, followed by insertion of oestradiol capsules after the Day-8 sample was taken. Samples were then taken on Days 9-15, the capsules were removed after the Day-15 sample, and samples were obtained on Days 16-19. Serum was assayed for concentration of oestradiol, FSH and LH by RIA. The concentration of FSH (ng/ml) in serum did not change during the first 8 days before oestradiol treatment (overall mean = 356 +/- 55) but decreased from the Day-8 value of 320 +/- 8 to 190 +/- 42 on Day 9 and by Day 15, after 7 days of oestradiol treatment, had reached a nadir of 20 +/- 5. By Day 17, i.e. 2 days after removal of the oestradiol capsules, serum FSH had increased (P less than 0.05) to 92 +/- 23 with a further increase (P less than 0.05) on Day 19 (171 +/- 16). This study demonstrates that, unlike in rats, mice, and sheep, administration of oestradiol alone to ovariectomized rhesus monkeys reduces immunoreactive serum FSH to concentrations measured in intact animals.     

Changes in gonadotrope responsivity to gonadotropin releasing hormone during development of the rhesus monkey

To assess the changing responsiveness of pituitary gonadotropes to gonadotropin releasing hormone (GnRH) during development, 5 male and 5 female rhesus monkeys were studied. Three monkeys of each sex were tested periodically with a subcutaneous injection of 500 micrograms of GnRH dissolved in 50% polyvinylpyrrolidone (PVP) beginning at 2 to 4 weeks of age and continuing into young adulthood. The remaining 4 monkeys received injections of the vehicle (PVP) alone and served as controls. Serum concentrations of bioactive luteinizing hormone (LH) were determined by an interstitial cell testosterone bioassay, and follicle-stimulating hormone (FSH) levels were measured by radioimmunoassay. Baseline FSH levels in the 5 female neonatal monkeys were higher than those of the 5 male neonatal monkeys during the first 2 months of life. In both sexes, FSH concentrations decreased with age, and FSH was barely detectable by 6 months. Baseline LH values in the 5 female monkeys declined during the first 6 months of the study and were undetectable (less than 0.5 micrograms/ml) at 6 months of age. Baseline LH levels in 4 of the 5 neonatal males also declined to undetectable concentrations by 6 months of age. During the first 3 months of life, there was a striking increase in the serum concentrations of both LH and FSH following GnRH. Although the LH responses to GnRH (delta LH) were similar in males and females of comparable ages, the FSH responses (delta FSH) were considerably greater in the female monkeys. In the males, the delta LH exceeded the delta FSH, whereas in the females, the delta FSH were greater than the delta FSH. In both sexes, the delta LH and delta FSH generally were greatest in the youngest monkeys and decreased gradually with increasing age. By 6 months, the gonadotropin responses to GnRH either were undetectable (males) or very small (females). After 6 months there was no longer an increase in serum gonadotropins after GnRH in either sex until 1.5-4 years (females) or 3 years (males) of age. The delta LH in response to GnRH in the male monkeys 3-5 years of age were comparable to the responses during the first month after birth. Serum concentrations of FSH in the adult males, however, did not increase after GnRH. In the female monkeys, serum levels of LH and FSH increased after GnRH at 1.5 years (1 monkey) and 4 years (2 monkeys) of age. The delta LH were similar to those of the 1- to 2-month-old female monkeys. The delta FSH, however, were variable and were approximately 20% of the neonatal response. In these young adult female monkeys the delta LH exceeded the delta FSH.(ABSTRACT TRUNCATED AT 400 WORDS)     

A suppression of gonadotropin secretion by cortisol in castrated male rhesus monkeys (Macaca mulatta) mediated by the interruption of hypothalamic gonadotropin-releasing hormone release

Four orchidectomized rhesus monkeys (3-3.5 yr of age) were treated for 62 days with daily i.m. injections of hydrocortisone acetate (HCA) at a dose of 10-20 mg/(kg BW X day), and blood samples were obtained daily or every other day before, during, and after treatment. Hydrocortisone acetate injections resulted in a progressive rise in mean plasma cortisol from basal concentrations of 17-35 micrograms/100 ml prior to initiation of steroid treatment to approximately 150 micrograms/100 ml 5 wk later. When serum cortisol concentrations reached 100 micrograms/100 ml, 3-4 wk after the initiation of HCA treatment, circulating luteinizing hormone (LH) and follicle-stimulating hormone (FSH) began to decline, reaching nondetectable concentrations 35 days later. Withdrawal of HCA resulted in a return in plasma cortisol concentrations to pretreatment control levels, which was associated with a complete restoration of gonadotropin secretion. In 2 animals, administration of an intermittent i.v. infusion of gonadotropin-releasing hormone (GnRH) (0.1 micrograms/min for 3 min once every hour), which appears to stimulate the gonadotropes in a physiologic manner, reversed the cortisol-induced inhibition of gonadotropin secretion, restoring circulating LH and FSH concentrations to within 80-100% of control. These results suggest that, in the rhesus monkey, the major site of the inhibitory action of cortisol on gonadotropin release resides at a suprapituitary level and is mediated by interruption of hypothalamic GnRH release.     

Depletion of tuberoinfundibular dopamine does not restore gonadotropin secretion in ovariectomized hyperprolactinemic rats

The effect of depleting tuberoinfundibular dopamine (TIDA) on gonadotropin secretion was studied in rats made hyperprolactinemic by implantation of the prolactin and growth hormone secreting Furth MtTW15 tumor. Implants of the pituitary tumor prevented gonadotropin release in response to castration. Daily injection of 100 mg dl-alpha-methyl-para-tyrosine/kg bw which reduced TIDA levels in tumor bearing rats more than 90% did not restore gonadotropin release. It seems likely that the increased activity of the TIDA system does not mediate the suppression of gonadotropins during chronic hyperprolactinemia.     

Progesterone administration prolongs the inhibitory effects of hyperprolactinemia on luteinizing hormone secretion in acutely ovariectomized rats

Several studies have shown that hyperprolactinemia in rats inhibits the post-gonadectomy rise in plasma luteinizing hormone (LH) for a limited period only. In intact rats the suppression of plasma LH during hyperprolactinemia is more prolonged. In the present study we have examined the possibility that the elevated levels of progesterone brought about by the raised plasma prolactin levels in intact rats are involved in the maintenance of LH inhibition. We have observed the effect of exogenous progesterone administration during the early post-ovariectomy period on plasma LH levels in female rats made hyperprolactinemic by administration of the dopamine antagonist, domperidone. Following ovariectomy of virgin, female rats, plasma LH was determined on each day from Day 3 to Day 10 after ovariectomy. In control rats plasma LH had increased by approximately 5-fold during the period of the experiment. In control rats treated with progesterone the rise in plasma LH was inhibited temporarily but LH had increased to similar levels to the controls by Day 10. In hyperprolactinemic rats LH was suppressed until Day 7, after which significant rises were observed. However, in hyperprolactinemic rats treated with progesterone, LH did not rise in a similar fashion, and remained low throughout the experiment. We conclude that a combination of hyperprolactinemia and raised plasma progesterone concentrations is necessary for the continued inhibition of LH release after ovariectomy.     

Galanin in adrenocorticotropic hormone cells is decreased by castration

Galanin (GAL) is a neuropeptide that is widely expressed in neuroendocrine tissues, including the adenohypophysis. Since GAL is expressed at higher levels in females, little attention has been paid to the regulation of GAL secretion in males. Here, we show that testosterone regulates GAL secretion in the adenohypophysis of male rats. Using double immunoelectron microscopy, we demonstrate that GAL cells possess three types of secretory granule: those with colocalization of GAL and adrenocorticotropic hormone (ACTH), those with GAL only, and those with ACTH only. The predominant granule type was that containing both GAL and ACTH, suggesting that GAL and ACTH are secreted at the same time. Indeed, adrenalectomy induced an acute decrease in the number of both GAL cells and ACTH cells. In contrast, castration resulted in a decrease in the proportion of GAL cells, while the proportion of ACTH cells remained unchanged. In addition, ACTH-strongly positive and GAL-positive cells were decreased while ACTH-weakly positive and GAL-negative cells were increased after castration. Testosterone treatment of castrated animals resulted in restoration of these levels to those of intact and sham operated animals. These results indicated that testosterone regulates GAL secretion in male animals.     

Effect of cortisol or adrenocorticotropic hormone on luteinizing hormone secretion by pig pituitary cells in vitro

The effect of cortisol or adrenocorticotropic hormone (ACTH) on basal and gonadotropin-releasing hormone (GnRH)-induced secretion of luteinizing hormone (LH) was studied in vitro using dispersed pig pituitary cells. Pig pituitary cells were dispersed with collagenase and DNAase and then grown in McCoy's 5a medium containing 10% dextran charcoal-pretreated horse serum and 2.5% fetal calf serum for 3 days. Cells were preincubated with cortisol or ACTH before GnRH was added. When pituitary cells were incubated with 400 micrograms cortisol/ml medium for 6 h or longer, increase basal secretion of LH was observed. However, GnRH-induced LH release was reduced by cortisol. The degree of this reduction was dependent on cortisol, and a concentration of cortisol higher than 100 micrograms/ml was needed. Cortisol also inhibited the 17 beta-estradiol-induced increase in GnRH response. ACTH-(1-24), ACTH-(1-39), or porcine ACTH had no influence on GnRH-induced LH secretion. Our results show that cortisol can act directly on pig pituitary to inhibit both normal and estradiol-sensitized LH responsiveness to GnRH.     

Age and the effect of adrenocorticotropic hormone on aldosterone secretion in rats

Age-related changes in functional activity of the glomerular zone were studied in the adrenal cortex of Wistar rats. It was shown that secretion of the basic mineralocorticoid hormone aldosterone was decreased with age. The glomerular zone of old rats showed the reduced sensitivity to the stimulant action of corticotropin, marked by the pronounced reaction to less doses of the hormone administered. At the same time the reactivity and the range of shifts in the course of ACTH dosage build-up decrease with aging.     

Responses of luteinizing hormone (LH) and follicle-stimulating hormone levels to exogenous gonadotropin-releasing hormone during the estrogen-induced LH surge in the ovariectomized rhesus monkey

Experiments were performed to study the responsiveness of the pituitary to gonadotropin-releasing hormone (GnRH) during the dynamic changes in gonadotropin secretion associated with the estrogen-induced luteinizing hormone (LH) surge in the ovariectomized (OVX) rhesus monkey. Silastic capsules filled with estradiol-17-beta were implanted subcutaneously in ovariectomized rhesus monkeys, resulting in an initial lowering of circulating LH and follicle-stimulating hormone (FSH) concentrations followed by an LH-FSH surge. GnRH was injected intravenously just before estrogen implantation, during the negative feedback response and during the rising, the peak, and the declining phases of the LH surge. The LH and FSH responses during the negative feedback phase were as large as those before estrogen treatment (control responses). During the rising phase of the LH surge, the acute response to GnRH injection did not differ significantly from the control response, but the responses 60 and 120 min after injection were somewhat increased. During the declining phase of the LH surge, the pituitary was not responsive to exogenous GnRH, although LH probably continued to be secreted at this time since the LH surge decreased more slowly than predicted by the normal rate of disappearance of LH in the monkey. We conclude that an increased duration of response to GnRH may be an important part of the mechanism by which estrogen induces the LH surge, but we do not see evidence of increased sensitivity of the pituitary to GnRH as an acute releasing factor at that time.