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.     

Studies on the feedback regulation of pulsatile luteinizing hormone secretion: effect of ovarian steroid implantation into the forebrain and basal hypothalamus on pulsatile LH secretion in ovariectomized rats

Recent studies have demonstrated that ovarian steroids are involved in the regulation of pulsatile LH secretion. In order to identify the site of action of ovarian steroids in modulating pulsatile LH secretion, the effect of local administration of estradiol benzoate (EB) or progesterone (P) into various brain regions on the characteristic of LH pulses was investigated in ovariectomized rats. Female rats of the Wistar strain were ovariectomized about 3-4 weeks before the experiment. Blood samples were obtained at 6-min intervals for 4h without anesthesia through the indwelling atrial catheter. The steroid was implanted into the brain via the chronically-implanted cannula 1h after the initiation of the bleeding. Serum LH concentrations were determined by radioimmunoassay. The following results were obtained. Pulsatile LH secretion occurred at intervals of approximately 20-30 min and mean LH pulse amplitude was 4.85-5.27 ng/ml h in intact ovariectomized rats. Implantation of cholesterol, as a control, in various brain areas did not induce any changes in the pattern of pulsatile LH secretion. Implantation of EB into the preoptic suprachiasmatic area (POSC) rapidly decreased the mean serum concentration of LH within 1h as compared to the pre-implantation value. The LH pulse frequency, but not the amplitude, was also decreased rapidly and significantly within 1h after EB was implanted into the POSC. In rats with EB implanted into the diagonal band of Broca (DBB), LH pulse frequency began to decrease with 2h, followed by a decline in the mean LH concentration within 3h after the implantation. Implantation of EB into the medial part of the amygdala (m-AMYG) decreased the pulse frequency within 2h, and lowered the average LH level within 3h. The mean amplitude of LH pulses did not change after the implantation. Mean LH concentrations and LH pulse amplitudes began to decrease 1-2h after EB was implanted into the medial basal hypothalamus (MBH), whereas there was no change in the pulse frequency. Rats with the EB implant in the bed nucleus of the stria terminaris, the medial preoptic area, the medial septal nucleus or the anterior hypothalamic area did not show any changes in either the amplitude or the frequency of pulsatile LH secretion. Implantation of P into the DBB, POSC or MBH of ovariectomized rats did not induce any significant change in the pattern of pulsatile LH secretion. These results suggest that the sites of estradiol action in modulating characteristics of pulsatile Lh secretion are not widespread but rather concentrated within the specific brain regions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ontogeny of hypothalamus-pituitary function in the fetal pig: gonadotropin release in response to electrical and electrochemical stimulation of the hypothalamus

The ontogeny of hypothalamic control of anterior pituitary gonadotropin secretion was studied in anesthetized fetal pigs at different gestational ages (60, 80, and 105 days gestation; term, 114 days). Three or four fetuses from one mother simultaneously received either no treatment (control), sham operation, electrical stimulation (EL), or electrochemical stimulation (EC). Electrodes were implanted unilaterally into the hypothalamus. Fetuses remained in utero during surgery. A distinct difference in the development of basal LH and FSH secretion was observed. Basal plasma LH concentrations almost doubled (P less than or equal to 0.001) between days 60 and 80, with no further significant increase between 80 and 105. Plasma FSH concentrations did not change significantly between days 60 and 80, but increased more than 5-fold (P less than or equal to 0.001) between days 80 and 105. EL or EC did not affect LH secretion at 60 days. At 80 days, EL and EC significantly (P less than or equal to 0.05) elevated plasma LH concentrations 30 and 50 min after the onset of stimulation. At 105 days, EL and EC caused a rise in plasma LH levels within 10 min; the maximum level, reached 30 min after the onset of stimulation, was double that in 80-day-old fetuses. Plasma FSH values were not significantly affected by EL or EC in any age group. The results indicate that the fetal pig hypothalamus is able to influence pituitary LH secretion by day 80 (70% of gestation). Further, maturation of hypothalamic control of LH secretion becomes demonstrable between days 80 and 105. The development of hypothalamic control of FSH secretion is delayed relative to LH.     

Escape from chronic estrogenic suppression of ovarian function in the adult rhesus monkey: evidence for changing sensitivity of gonadotropin secretion to estrogen inhibition

Regularly menstruating female rhesus monkeys were implanted sc with Silastic tubing packed with estrone. The implants were replaced every 6-8 months to maintain the serum estrone and estradiol concentrations constantly elevated 1.5-2.5-fold, i.e. in the midfollicular phase range, for 4 yr. Increasing the estrone and estradiol concentrations initially led to anovulation which persisted for 6 to 15 months after which three of four of the estrogen-treated animals resumed ovulatory cycles. These animals then waxed and waned between anovulation and ovulatory cycles for the remainder of the study period. The resumption of ovulatory cycles were attributed to an escape of the central nervous system-pituitary axis from the suppressive effect of the elevated estrogen concentrations, since serum estradiol concentrations did not change. During anovulatory and ovulatory months the basal LH concentration was not significantly increased in the estrogen-treated monkeys compared to the control animals, but it was significantly reduced during anovulatory months compared to ovulatory months. Furthermore, LH secretion in response to a bolus of GnRH was attenuated in the monkeys chronically exposed to the acyclic elevation of blood estrogen levels. As the sensitivity to estrogen decreased, sufficient basal concentrations of FSH and LH were achieved to support ovulatory cycles with associated midcycle surges of LH and FSH secretion and apparently normal luteal patterns of progesterone secretion. Since the daily FSH concentrations of these ovulatory cycles of the estrone-treated animals were significantly lower than that of ovulatory cycles of the control monkeys, the ovulatory cycles of the estrogen animals may not have been normal, but this was not directly documented. These studies suggest that elevated basal estrogen levels do not lead to elevated basal LH secretion in the female primate; and also in the intact adult primate the central nervous system-pituitary axis has the potential to change its sensitivity to the negative feedback effects of estrogen on gonadotropin secretion.     

Evidence that changes in tonic luteinizing hormone secretion determine the growth of preovulatory follicles in the rat

Physiological concentrations of progesterone (20-100 ng/ml), maintained by the insertion of implants into 30-day-old rats, delayed first ovulation, and withdrawal of progesterone on day 47 of age synchronized first ovulation in rats. Inhibition of ovulation involved negative feedback regulation of tonic LH and FSH secretion, blockage of gonadotropin surges, and suppression of preovulatory, but not antral, follicular growth. Removal of implants resulted in a rapid decline in serum progestrone from 100 to 5 ng/ml within 0-12 h. Between 0-36 h there were progressive increases in serum concentrations of LH and FSH, enhanced accumulation of estradiol by individual follicles incubated in vitro with or without exogenous substrate, and marked progressive increases in the content of LH (but not FSH) receptors in both thecal and granulosa cells. These events were followed by gonadotropin surges at 48 h (1800 h on day 49), ovulation, and morphological and biochemical signs of luteinization, including decreases in follicular gonadotropin receptor content and estradiol accumulation, evident by 60 h. With the exception of changes in basal LH, this sequence of events is remarkably similar in time and pattern to that after the decline of progesterone on diestrous day 2 and ovulation on proestrus of a 5-day cycle. Although a direct effect of progesterone on ovarian follicular cell function cannot be excluded, the data suggest that subtle but sustained increases in LH (and possibly FSH) are required for the enhanced follicular accumulation of estradiol and LH-binding activity occurring between diestrus and proestrus of the rat estrous cycle. Thus, perhaps some of the mystery surrounding the endocrine events between diestrus and proestrus can be ascribed to changes in serum LH that have been too small and/or variable for current nonserial sampling methods and RIAs to detect reliably.     

Steroid control of gonadotropin secretion and ovarian function in heifers

The failure of anti-steroid treatments to induce multiple ovulations in cattle in a repeatable way, prompted us to examine the role of the gonadal steroids in the control of gonadotropin secretion in this species. A better understanding of the control of gonadotropin secretion in the cow would assist in the development of treatments to control prolificacy. Groups of six heifers were implanted with one of three sizes of estradiol (E2) implant on day 9 of a synchronized estrous cycle, and five control heifers received empty implants. All heifers were ovariectomized during the luteal phase of the subsequent estrous cycle and given progesterone-releasing intravaginal devices (PRID). Blood samples were taken every 10 min for 12 h with PRIDs and for 6 h after PRID withdrawal, for the measurement of LH and FSH concentrations. The two larger implant sizes (increasing E2 concentrations to 7.4 and 18.7 pg/ml plasma during the luteal phase of the cycle) decreased ovulation rate, the number of large follicles, and luteal weight. After ovariectomy, the three implant sizes produced E2 concentrations comparable with those during the luteal and follicular phases of the estrous cycle and at estrus (1.5, 4.4, and 10.5 pg/ml, respectively). E2 alone decreased mean LH and FSH concentrations and LH pulse amplitude, whereas progesterone alone reduced mean gonadotropin concentrations and LH pulse frequency. Only in the presence of progesterone did E2 decrease LH pulse frequency. Steroid concentrations which mimicked those of the luteal and follicular phases of the cycle produced luteal- and follicular-phase patterns of LH and FSH secretion. These results confirm that E2 and progesterone are important regulators of gonadotropin secretion in cattle, and question the role of inhibin in this respect.     

Effect of inhibitors of prostaglandin synthesis on gonadotropin release in the rat.

To study the effect of blockade of prostaglandin (PG) synthesis on gonadotropin release in the rat, inhibitors of PG synthesis were injected by various routes in various experimental conditions. The injection of 5-, 8-, 11-, 14-eicosatetraynoic acid (TYA) into the third ventricle (3rd V) significantly decreased plasma LH of ovariectomized (OVX) rats 1, 2, and 4 h following its injection; however, TYA failed to alter plasma LH in OVX rats when administered as a single sc injection and also failed to prevent the post-castration rise in plasma LH when administered sc once daily for 4 days to short-term OVX rats. None of these treatments altered plasma FSH concentrations. Indomethacin (Id) injected into the 3rd V or implanted into the medial basal hypothalamus (MBH) of OVX rats depressed plasma LH 1--6 h later. This effect was no longer observed 24--72 h following its implantation in the MBH. When different doses of Id were administered as single sc injections to OVX rats, plasma LH titers were depressed 24--32 h later, whereas plasma FSH remained either unaltered or was slightly increased. Similarly, the post-castration rise of plasma LH but not that of FSH in male rats was suppressed by a single sc injection of Id given 6 h before orchidectomy. Id administered acutely iv failed to modify the pulsatile release of LH in OVX rats, but it effectively inhibited this release when injected sc 20--30 h before the initiation of blood collection. Moreover, Id blocked the progesterone-induced LH and FSH release in OVX estrogen-primed rats when given sc 24 h before progesterone, but not when it was injected either sc or iv shortly (2 h) before or shortly after (1--3 h) progesterone treatment. Rats treated with Id showed a decrease in BW 24--32 h afters its sc injection. However, the effects of Id on LH release could not be explained by lack of food intake since fasted controls showed LH titers similar to fed rats. Id did not significantly inhibit the LH release in response to synthetic LH-releasing hormone (LHRH) in OVX rats, but partially blocked the response in OVX estrogen, progesterone-treated (OEP) rats. Surprisingly, in OEP rats, Id appeared to potentiate the FSH release in response to LHRH. The results of this study indicate that inhibitors of PG synthesis administered at high doses can inhibit LH release in the rat and that this effect is mainly due to a direct effect of the drug or drugs on the central nervous systen. Consequently, the results of this study give further support to the hypothesis that PGs play a physiological role in the control of gonadotropin secretion.     

Increased sensitivity to the negative feedback effects of testosterone induced by hyperprolactinemia in the adult male rat

High plasma levels of PRL induced by transplants of two donor pituitaries under the kidney capsule of adult male rats resulted in a prolonged suppression of plasma levels of LH and FSH although testosterone levels were maintained within normal limits. Castration of rats with pituitary transplants resulted in a normal though delayed rise in serum levels of both LH and FSH to levels equivalent to those in normal castrated controls. This increase in gonadotropin levels occurred in spite of maintenance of elevated PRL levels. Two experiments were carried out in which testosterone was restored after castration by Silastic testosterone-containing implants of various lengths (Exp 1:60, 30, and 10 mm; Exp 2: 30, 20, 10, 5, and 2 mm). In both experiments 60- and 30-mm testosterone implants prevented the postcastration rise in LH and FSH in both control and hyperprolactinemic rats. However, although the shorter testosterone implants delayed this rise in control rats, levels of LH and FSH increased by 4 days and were not significantly different from castrated rats without testosterone implants by 15 days after castration. In contrast, this rise in gonadotropins was abolished or considerably delayed by the shorter implants in hyperprolactinemic rats, demonstrating an increase in sensitivity of the hypothalamic pituitary axis to the negative feedback effects of testosterone in these animals. These results suggest that 1) to maintain suppression of gonadotropin secretion in hyperprolactinemia high levels of PRL alone are insufficient and gonadal steroids are required, and 2) high levels of PRL appear to sensitize the hypothalamic-pituitary axis to the negative feedback effects of gonadal steroids.     

Actions of pregnant mare serum gonadotropin in the immature female rat: correlative changes in blood steroids, gonadotropins, and cytoplasmic estradiol receptors of the anterior pituitary and hypothalamus.

Several blood steroids, serum gonadotropins and cytosol estradiol receptors of the anterior pituitary and hypothalamus were quantified in immature female rats which were induced to ovulate with pregnant mare's serum gonadotropin (PMSG). Studies revealed that serum levels of progesterone, 17-hydroxyprogesterone, testosterone, androstenedione and estradiol were initially elevated at 6 PM (day 30) after administration of 8 IU of PMSG at 10 AM day 30. Serum levels of estradiol and testosterone rose progressively from day 30 through the AM of day 32. A further increase in serum concentrations of progesterone, 17-hydroxyprogesterone, androstenedione, testosterone, and dehydroepiandrosterone occurred on the PM of day 32 whereas serum estradiol levels declined. Serum levels of all steroids declined on the day of estrus (33) and only progesterone levels were further elevated on day 34 (diestrus). Dihydrotestosterone concentrations were minimally altered by PMSG treatment. Saline administration resulted in no significant alterations in levels of any steroid quantified from day 29 to 34 in control animals. A progressive decline in cytosol estradiol receptor content of the anterior pituitary and hypothalamus was documented following PMSG treatment of intact female rats; there was no depletion of receptors following PMSG administration to ovariectomized immature rats. Maximal depletion of cytosol estradiol receptors occurred on day 32 with replenishment of cytosol estradiol receptor levels on estrus (day 33). The preovulatory gonadotropin surge was found to occur on the PM of day 32 after maximal receptor depletion. The cycle of depletion and replenishment of receptors was repeated during a second spontaneous estrous cycle four days later which coincided with a rise and fall in serum estradiol levels. It is suggested that the depletion of cytosol estradiol receptors of the anterior pituitary/hypothalamic unit may be causally related to the preovulatory gonadotropin surge resulting from PMSG administration to immature female rats. In addition, changes in blood steroids and gonadotropins after PMSG treatment are similar to those reported for proestrus-estrus-diestrus I of the normal adult estrous cycle. These findings further demonstrate the validity of the PMSG-primed immature female rat preparation as a model for the estrous cycle of the adult rat.     

Differential regulation of anterior pituitary prodynorphin and gonadotropin-subunit gene expression by steroid hormones.

Prodynorphin is expressed by neurons of the hypothalamus and gonadotrophs of the anterior pituitary gland (AP) and plays a role in the negative feedback regulation of the reproductive neuroendocrine axis. The present study examined whether gonadal steroid hormones are capable of modulating pituitary prodynorphin expression in immature, female rats. Steroids were administered via subcutaneous Silastic implants and rats were killed at 29 days of age. Northern blot analysis was used to measure AP prodynorphin, luteinizing hormone-beta (LH beta), follicle-stimulating hormone-beta (FSH beta), and common alpha-subunit mRNA levels (normalized to 18S ribosomal RNA). Treatment groups (n = 5-6) consisted of control (CNT; empty implants), estradiol (E2; 4 days), E2 + progesterone (E2 + P4; 8 days and 4 days, respectively), and dihydrotestosterone (DHT; 4 days). Pituitary prodynorphin mRNA was significantly suppressed in only the DHT-treated animals (26 +/- 10% of CNT, p < 0.01). LH beta mRNA was suppressed by all steroid treatments (p < 0.01), FSH beta was lower in only the E2 group, and alpha-subunit was reduced in both the E2 + P4 and DHT groups (p < 0.01). Serum LH was suppressed by all steroid treatments but FSH was reduced in only the E2 and E2 + P4 groups (p < 0.01). Treatment of prepubescent rats with continuous high levels of gonadal steroids is known to severely reduce endogenous hypothalamic gonadotropin releasing hormone (GnRH) release and this is supported by our observation of reduced gonadotropin-subunit gene expression.(ABSTRACT TRUNCATED AT 250 WORDS)     

Direct pituitary effects of estrogen and progesterone on gonadotropin secretion in the ovariectomized ewe

The direct pituitary effects of estrogen and progesterone on the secretion of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) were studied in ovariectomized (OVX) ewes in which the pituitary had been disconnected surgically from the hypothalamus (hypothalamo-pituitary disconnection, HPD). Gonadotropin secretion was restored with hourly pulses of 500 ng gonadotropin-releasing hormone (GnRH) via intra-atrial cannulae. Intramuscular injections of 50 micrograms estradiol benzoate (EB) to 5 sheep initially caused reductions (approximately 50%) in plasma LH baseline, peak values and LH pulse amplitude. Thereafter all parameters of plasma LH concentration increased 2- to 3-fold above starting values. After these 5 sheep had received 2 subcutaneous progesterone implants (mean +/- SEM plasma levels 5.3 +/- 1.5 nmol/l), the biphasic LH response to EB was still apparent and increases in LH peak values (267 +/- 19%) and LH pulse amplitudes (262 +/- 23%) were greater (p less than 0.05) than those seen with EB alone (195 +/- 11 and 172 +/- 14%, respectively). The presence of 2 progesterone implants alone did not change plasma LH baseline, peak values or pulse amplitude, or plasma FSH values. In the second experiment, where 4 OVX-HPD ewes were given 4 progesterone implants (plasma progesterone 27.7 +/- 3.4 nmol/l), there were no effects on basal plasma LH or plasma FSH values. The LH responses to EB were more marked in 4 OVX-HPD ewes given 4 progesterone implants than in the animals given EB alone. Also, the estrogen-induced LH surge occurred earlier in the ewes given 4 progesterone implants than in those given estrogen alone.(ABSTRACT TRUNCATED AT 250 WORDS)     

Progesterone blocks the estradiol-induced gonadotropin discharge in the ewe by inhibiting the surge of gonadotropin-releasing hormone.

Previous studies indicate an elevation of circulating progesterone blocks the positive feedback effect of a rise in circulating estradiol. This explains the absence of gonadotropin surges in the luteal phase of the menstrual or estrous cycle despite occasional rises in circulating estradiol to a concentration sufficient for surge induction. Recent studies demonstrate estradiol initiates the LH surge in sheep by inducing a large surge of GnRH secretion, measurable in the hypophyseal portal vasculature. We tested the hypothesis that progesterone blocks the estradiol-induced surge of LH and FSH in sheep by preventing this GnRH surge. Adult Suffolk ewes were ovariectomized, treated with Silastic implants to produce and maintain midluteal phase concentrations of circulating estradiol and progesterone, and an apparatus was surgically installed for sampling of pituitary portal blood. One week later the ewes were allocated to two groups: a surge-induction group (n = 5) in which the progesterone implants were removed to simulate luteolysis, and a surge-block group (n = 5) subjected to a sham implant removal such that the elevation in progesterone was maintained. Sixteen hours after progesterone-implant removal (or sham removal), all animals were treated with additional estradiol implants to produce a rise in circulating estradiol as seen in the follicular phase of the estrous cycle. Hourly samples of pituitary portal and jugular blood were obtained for 24 h, spanning the time of the expected hormone surges, after which an iv bolus of GnRH was injected to test for pituitary responsiveness to the releasing hormone. All animals in the surge-induction group exhibited vigorous surges of GnRH, LH, and FSH, but failed to show a rise in gonadotropin secretion in response to the GnRH challenge given within hours of termination of the gonadotropin surges. The surges of GnRH, LH, and FSH were blocked in all animals in which elevated levels of progesterone were maintained. These animals in the surge-block group, however, did secrete LH in response to the GnRH challenge. We conclude progesterone blocks the estradiol-induced gonadotropin discharge in the ewe by acting centrally to inhibit the surge of GnRH secreted into the hypophyseal portal vasculature.     

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 estradiol-17beta on the induction of gonadotropin release by electrical stimulation of the hypothalamus in rhesus monkeys.

Serum LH and FSH were measured at 60, 30, and 0 min before, at 5, 15, and 30 min during, and at 10, 45, and 90 min after bilateral electrical stimulation (ES) of various hypothalamic regions in 12 unanesthetized ovariectomized rhesus monkeys. ES of the arcuate-ventromedial nuclei (medial basal hypothalamus; MBH) induced a prompt increase in serum LH that persisted throughout stimulation and returned to basal levels within 90 min thereafter. FSH was also released, but the release was slower and less dramatic than that of LH. Sham stimulation (0muA) caused no change in serum gonadotropins. The amount of LH released after MBH-ES depended upon current strength (1.0 mA greater than 0,5 or 0.7 mA). Three sequential 30-min MBH-ES trials at 90-min intervals induced comparable LH responses and 3 h of continuous MBH-ES maintained elevated serum LH levels throughout the stimulation period, suggesting that these stimulation period, suggesting that these stimulation parameters did not completely deplete pituitary stores of releasable LH. The character of the LH response was similar in individual monkeys through 3 to 24 trials during 4 to 18 months. Comparisons were made of the effects of estradiol-17beta (E2) treatment at different doses and for different intervals of time before MBH-ES. ES-induced LH release was not affected by low levels (25 and 55 pg/ml) ofE2 for 48 h, but was reduced by higher E2 concentrations (100 or 230 pg/ml). E2 concentrations of 100 pg/ml had no effect at 24 h, but reduced MBH-ES-activated LH release at 48 to 96 h; the degree of depression was time-related (48 h less than 72 h less than 96 h). ES of the preoptic-suprachiasmatic region (rostral hypothalamus; RH) in non-E2-treated monkeys also released LH, but this increase was less than after MBH-ES. FSH release was not measurable after RH-ES. In contrast to the depressed LH response to MBH-ES after 48 h of E2 (100 pg/ml), the response to RH-ES was not inhibited by this E2 regimen. These data suggest that ES of an area extending caudally from the rostral hypothalamus to the arcurate-median eminence region will evoke LH release in rhesus monkeys. This electrically induced gonadotropin release was affected by administration of physiological levels of E2 but the nature of effect depended on the specific region stimulated: distinct inhibition of the gonadotropic response to MBH-ES and slight facilitation of the response to RH-ES.     

Annual cycle of pituitary and plasma gonadotropins and plasma sex steroids in a wild population of the toad, Bufo japonicus

Pituitary and plasma gonadotropins and plasma sex steroids of free-living toads, Bufo japonicus, were measured monthly from March 1981 to February 1982 and examined in relation to gonadal cycles. Toads were captured at Mizuno, Saitama Prefecture. Individual blood samples were collected by cardiac puncture within 3 min of capture in the field. In males, testicular weight was maximal in August. Plasma follicle-stimulating hormone (FSH) levels changed in association with testicular weight. Plasma androgen levels showed a small peak in November and a large peak in March just prior to breeding. Plasma luteinizing hormone (LH) levels changed in parallel with plasma androgen levels. In females, neither plasma FSH nor LH alone were correlated significantly with ovarian weight. However, ovarian and oviductal weights both correlated significantly with plasma steroid levels. Plasma estradiol levels showed a sharp peak in March, followed by a rapid decrease to the minimum in April. A gradual increase of estradiol occurred from July to November in parallel with an increase in ovarian weight. Changes in plasma progesterone and androgen levels in females resembled those for estradiol. However, the changes in progesterone were not so marked as in estradiol. Plasma androgen levels in females were especially high between January and March. In both sexes, the pituitary gonadotropin contents changed in parallel with plasma levels of both FSH and LH. The pituitary almost always contained more LH than FSH, while the reverse was true in the plasma in both sexes. In addition, plasma FSH levels increased markedly in early summer when plasma LH remained unchanged (males) or increased only slightly (females). These results indicate that the toad may serve as excellent material for the study of differential control of FSH and LH secretion.     

Effects of progesterone on estrogen-induced gonadotropin release in male rhesus macaques

The effects of progesterone (P) on estrogen (E)-induced gonadotropin release were studied in 10 adult male rhesus macaques castrated more than 2 yr earlier. The intent was to determine whether physiological levels of P (approximately 400 pg/ml) found in the systemic circulation of intact males would block E-induced gonadotropin release and whether the responses of castrated males were similar to those of castrated females with and without pretreatment with 17 beta-estradiol (E2). Different doses of P were administered in Silastic capsules (0.3, 4.0, and 5.0 cm) implanted sc. A 0.3-cm implant maintained serum P levels at about 400 pg/ml (equivalent to physiological levels in intact males); 5.0-cm implants produced serum levels of about 4.0 ng/ml (similar to luteal phase levels in females). In male monkeys treated for approximately 3 weeks with E2, only the highest dose (approximately 4.0 ng/ml) of P blocked FSH induced by estradiol benzoate (E2B). LH was blocked in one third of the animals thus treated. The same P dose was ineffective in blocking E2-induced LH release in spayed females pretreated with E2, but did block FSH release. Gonadectomized males and females not treated beforehand with E2 released LH in response to an E2B challenge, but FSH was not elevated in the peripheral circulation under these experimental conditions. These results suggest that luteal phase levels of P block E2-induced FSH release in gonadectomized males and females. With the same treatment regimens, P blocks E2 action in some males, but all females responded to E2B by releasing LH. These data also suggest that estrogen priming is necessary for FSH, but not LH, release in adult rhesus macaques of both sexes. The prerequisite of E treatment for the induction of positive feedback appears to be associated with the level of gonadotropin suppression before E2B treatment.     

The physiological significance of the hippocampus on the inhibitory effects of corticosterone upon the estradiol-induced LH and FSH surges in rats

The effects of corticosterone (CS) on the gonadotropin surge induced by estradiol-benzoate (E2) were studied in adrenalectomized and ovariectomized (ADRX-OVEX) rats. The results are as follows. In ADRX-OVEX rats implanted with E2-tablets in the bilateral axillae, LH and FSH surges occurred 4 days after the implantation of E2, peaking at 17:00 h. The levels of these surges were markedly higher than those in OVEX rats similarly treated but were attenuated significantly by the subcutaneous injection of CS (25 micrograms in sesame oil) given at 12:00 h. The CS implantation (0.5 micrograms in 2 microliters sesame oil) into the dorsal hippocampus at 15:00 h significantly inhibited the levels of LH and FSH surges in ADRX-OVEX rats with E2-tablets. The effect of the CS implant in the lateral septal nucleus was also inhibitory but not statistically significant. The CS administration in the ventral part of the midbrain tegmentum did not elicit any change in the surge of LH and FSH. In animals with the dorsal fornix-section at the post-anterior-commissural level, surges of LH and FSH also occurred in the afternoon of the 4th day after the E2-tablets implantation, but the levels of LH and FSH were not significantly altered by an intravenous injection of CS (5 micrograms in saline) at 15:30 h. It was suggested the CS circulating in the blood would induce a rise of hippocampal activity which would exert a suppressive influence on the gonadotropin release.     

In men, peripheral estradiol levels directly reflect the action of estrogens at the hypothalamo-pituitary level to inhibit gonadotropin secretion

CONTEXT: Estradiol inhibits gonadotropin release in men by an action at the hypothalamus and pituitary. Because of the tissue-specific regulation of aromatase, peripheral estradiol levels may not reflect brain estradiol concentrations. OBJECTIVE: We evaluated whether local aromatization of testosterone in the hypothalamus or pituitary is important for gonadotropin release and to what extent circulating estrogens affect gonadotropin levels and peripheral testosterone levels. DESIGN, SUBJECTS, AND INTERVENTIONS: We suppressed aromatase activity in 10 young healthy men with letrozole 2.5 mg once daily, restored plasma estradiol levels with estradiol patches (100 microg/d for the first week, 50 microg/d the second week, 25 microg/d the third week, and no estradiol patch the fourth week) and measured plasma testosterone, estradiol, LH, FSH, and SHBG levels. RESULTS: The mean estradiol and testosterone levels during the study ranged between 68.6 +/- 38.3 and 12.6 +/- 7.21 pg/ml for estradiol and 179 +/- 91 and 955 +/- 292 ng/dl (mean +/- sd) for testosterone. Levels of testosterone, LH, and FSH were inversely related to peripheral estradiol levels. During letrozole use, the mean plasma estradiol level needed to restore testosterone, LH, and FSH levels to baseline levels was not significantly different from the baseline mean estradiol level. CONCLUSIONS: Local aromatization of testosterone in the hypothalamo-pituitary compartment is not a prerequisite for expression of the inhibitory action of estrogens on gonadotropin secretion in men. Peripheral estradiol levels directly reflect the inhibitory tone exerted by estrogens on gonadotropin release and are a major determinant of peripheral testosterone, LH, and FSH levels.     

Effect of progesterone and its 5 alpha-reduced metabolites on gonadotropin levels in estrogen-primed ovariectomized rats.

In an effort to determine whether the metabolic conversion of progestrone may be important in the feedback effects of this steroid, serum LH and FSH levels were measured after administration of progesterone, 5 alpha-dihydroprogesterone or 3 alpha-hydroxy-5 alpha-pregnan-20-one to estrogen-primed ovariectomized rats. A single injection of 2 or 4 mg progesterone, 4 mg 5 alpha-dihydroprogesterone, or 4 mg 3 alpha-hydroxy-5 alpha-pregnan-20-one 72 h (Day 3) after estrogen pretreatment induced a highly significant increase in serum LH and FSH 6 h later (1800 h). Although serum gonadotropin levels had begun to decrease 12 h after administration of the progestins, they were still significantly higher than control values and did not return to baseline levels until noon on Day 4. When either progesterone or 3 alpha-hydroxy-5 alpha-pregnan-20-one was administered at noon on Days 3 and 4, there was a significant reduction in LH levels 6 h after the second injection. In contrast, serum LH levels were slightly elevated 3 to 6 h (1500 to 1800 h) after the second injection of 5 alpha-dihydroprogesterone and did not decrease until 2100 h. There was no effect on FSH concentrations after a second injection of any of the progestins. Loss of uterine luminal fluid was observed within 24 h after a single injection of progesterone. Neither of the 5 alpha-reduced metabolites had an effect on uterine ballooning until after the second injection, and, even then, nonfluid-filled uteri were observed in only 20 to 30% of the animals. The results suggest that the conversion of progesterone to 5 alpha-dihydroprogesterone and 3 alpha-hydroxy-5 alpha-pregnan-20-one by neuroendocrine tissues may be necessary for the positive and negative feedback effects of progesterone on gonadotropin secretion. Thus, the diverse effects of progesterone may be due to progesterone per se (e.g., in the uterus) and/or its metabolites (e.g., in the hypothalamus and pituitary).     

Immunocytochemical localization of beta endorphin and gonadal steroid regulation of proopiomelanocortin messenger ribonucleic acid in the ewe.

In the ewe, estradiol and progesterone inhibit luteinizing hormone (LH) secretion during the breeding season. Endogenous opioid peptides (EOP) are also inhibitory to LH secretion, and both estrogen and progesterone have been reported to enhance EOP inhibition of LH release. Which EOP are involved in this inhibition is unclear. In this study, we concentrated on beta-endorphin because evidence for its ability to inhibit LH secretion exists in ewes. We first studied the distribution of beta-endorphin-immunoreactive neurons in 4 cycling ewes using immunocytochemistry. Cell bodies were found only within the medial basal hypothalamus (MBH) and were concentrated in arcuate nucleus and mammillary recess of the third ventricle, with a few in the median eminence. Extensive fiber tracts were seen in preoptic area (POA) and median eminence. We next tested the hypothesis that gonadal steroids increase the synthesis of EOP by measuring levels of mRNA for proopiomelanocortin (POMC), the precursor to beta-endorphin. Ovariectomized ewes were treated with no steroids (n = 7) or given subcutaneous Silastic implants containing either estradiol (n = 6) or progesterone (n = 6). After 4 days of treatment, EOP inhibition of LH secretion was measured by determining the LH response to WIN 44,441-3 (WIN), an EOP antagonist. LH pulse frequency and pulse amplitude were determined in blood samples collected at 12-min intervals for 3 h before and after intravenous administration of 12.5 mg WIN. WIN injection increased (p < 0.01) the LH pulse-frequency only in progesterone-treated and pulse amplitude only in estradiol-treated ewes. After blood sampling, the ewes were killed, and POA, MBH, and pituitary gland were removed. Total RNA was extracted from these tissues and dot blotted onto nitrocellulose membranes for hybridization with a DNA probe complementary to the POMC mRNA. The resulting autoradiographs were quantified densitometrically. Levels of POMC mRNA in the MBH were increased (p < 0.01) by both estradiol and progesterone as compared with the no steroid group. There was no detectable POMC mRNA in the POA. These results suggest that estrogen and progesterone enhance EOP inhibition of LH secretion by increasing POMC mRNA levels and thus synthesis of beta-endorphin.