Short loop feedback system for the control of follicle-stimulating hormone in the rabbit

Studies were designed to assess whether a short loop feedback control for FSH existed in the rabbit. Castrated adult female animals bearing chronically implanted Silastic catheters to permit frequent blood sampling were studied without anesthesia. Ovine FSH was administered as an iv bolus in doses ranging between 0.1-500 micrograms. Endogenous rabbit FSH was quantified using a RIA that did not cross-react with ovine FSH. Blood samples were obtained before and 5, 10, 15, 30, 60, 120, 180, 240, and 300 min after the injection. Each animal was tested at two or more dose levels on different days. Ovine FSH produced suppression of rabbit FSH secretion within 5 min after injection. The minimum effective dose was 1 microgram; maximal suppression occurred with 50-100 micrograms ovine FSH. This short loop feedback control system was specific for FSH; ovine FSH, even at high doses, failed to suppress endogenous rabbit LH. This is the first direct demonstration of a negative short loop feedback control for FSH and the first entirely specific control for the FSH system to be described.     

Absence of an estradiol-induced surge of luteinizing hormone in pigs receiving unvarying pulsatile gonadotropin-releasing hormone stimulation

The goal of this study was to pharmacologically block central nervous system (CNS) input to gonadotropes in mature ovariectomized gilts to determine the direct actions of estradiol (E2) on pituitary LH release when given at a dose sufficient to elicit a gonadotropin surge. Feeding AIMAX [N-methyl-N'-(1-methyl-2-propenyl)1,2-hydrazinedicarbothioamide; 125 mg/day] for 7 days reduced serum LH concentrations from 1.25 +/- 0.13 (mean +/- SE) to less than 0.18 ng/ml, abolished LH pulses, but did not compromise LH release in response to exogenous GnRH. Serum FSH concentrations were reduced by 27%, whereas serum concentrations of PRL, GH, thyroid hormones and cortisol were not affected after 7 days of AIMAX treatment. Behavior was not altered, aside from a slightly reduced appetite. The LH surge that peaked 48-80 h after injecting E2 benzoate (E2B) into control gilts was blocked in five of eight gilts given AIMAX. Giving GnRH pulses (1 microgram every 45 min) to AIMAX-treated gilts restored mean serum LH concentrations as well as the frequency and amplitude of LH pulses to those of untreated ovariectomized gilts. E2B suppressed the LH response to these GnRH pulses by 88% at 12 h, whereas from 24-96 h after E2B treatment, the LH response to GnRH and mean serum concentrations of LH were again similar to those of controls not given estradiol. These data indicate that induction of the gonadotropin surge by E2 in the gilt requires CNS input. The action of E2 on the pituitary in the presence of unvarying GnRH pulsation may, however, be limited to an early transient inhibition of responsiveness to GnRH, with no subsequent direct stimulation during the period of the surge.     

The luteinizing hormone surge is preceded by an estrogen-induced increase of hypothalamic progesterone in ovariectomized and adrenalectomized rats

As circulating estrogen levels rise on the afternoon of proestrus, they stimulate the hypothalamo-pituitary axis. This estrogen positive feedback is pivotal to stimulate the luteinizing hormone (LH) surge required for ovulation and luteinization of ovarian follicles. In addition to estrogen, pre-LH surge progesterone is critical for an LH surge as was demonstrated by blocking progesterone synthesis. In ovariectomized (OVX) rats treated with trilostane, a blocker of the enzyme 3beta-hydroxysteroid dehydrogenase (3beta-HSD) that catalyzes the conversion of pregnenolone to progesterone, estrogen did not induce an LH surge. Further, estrogen induced an LH surge in OVX and adrenalectomized (ADX) rats, indicating that the source of progesterone was neither the ovary nor adrenal gland. This estrogen-only LH surge was inhibited by pretreatment with trilostane, indicating that although the adrenal gland and ovary were not necessary for positive feedback, progesterone synthesis was critical for estrogen-induced positive feedback in an OVX/ADX rat. This suggested that the LH surge is dependent on the pre-LH surge synthesis of progesterone. Estrogen-induced progesterone receptors in the hypothalamus are vital for the LH surge, so a potential location for progesterone synthesis is the hypothalamus. OVX/ADX female rats were treated with 17beta-estradiol (50 microg) and progesterone levels were assayed by RIA. Progesterone levels were elevated in hypothalamic tissue following estrogen treatment. No increases in tissue progesterone levels were found in parietal cortex, cerebellum, medulla, pituitary or plasma. Additionally, male rats that do not have an estrogen positive feedback-induced LH surge were examined. Castrated/ADX male rats had no increase in hypothalamic progesterone levels after estrogen treatment. Together, these data strongly suggest that estrogen enhances neuroprogesterone synthesis in the hypothalamus that is involved in the positive feedback regulating the LH surge.     

Ultrashort feedback control of luteinizing hormone-releasing hormone secretion in vitro

The present experiments were performed to clarify whether LHRH might inhibit its own secretion via an ultrashort feedback mechanism acting directly on the hypothalamus. Using an in vitro system, mediobasal hypothalami (MBHs) of adult male rats were perifused in either the presence or absence of a LHRH agonistic analog [D-Ser(TBU)6,Des-Gly10] LHRH ethylamide shown not to cross-react in the LHRH RIA. In the first series of experiments, six MBHs per chamber were initially perifused with control medium and submitted to two K+ stimulations (110 mM) for 5 min every 30 min; the control medium was then replaced by medium containing the LHRH analog (5 microM), and three additional K+ pulses were applied. In the second series of experiments, a single MBH per chamber was exposed for the duration of the experiments to either control medium or medium containing the LHRH analog (5 microM). In both cases, pulses of K+ were applied to the tissue. The amounts of endogenous LHRH released both under basal conditions and after K+ stimulation were measured in the effluent (1 ml every 5 min) with a specific RIA. The results show that the LHRH analog inhibits basal secretion of endogenous LHRH from the MBH, and diminishes or abolishes the response to K+ stimulations. The specificity of the inhibitory effect exerted by the LHRH analog on LHRH secretion was shown by the inability of TRH to mimic the effect of the LHRH analog. The data are consistent with the hypothesis that LHRH, acting at a hypothalamic level, might participate in the control of its own release via an ultrashort feedback mechanism.     

Inability to demonstrate an ultrashort loop feedback mechanism for luteinizing hormone in humans

hCG has biological properties similar to those of LH, but can be measured separately from LH by current radioimmunometric assays. To investigate the possible existence of an autoregulatory mechanism for LH in humans, we compared the basal LH concentrations and the LH response to a GnRH stimulus with and without prior administration of hCG. On two separate occasions, at least 1 week apart, six normal (eugonadal) males and six normal postmenopausal females were given, in random order, either 10,000 IU hCG or saline followed by iv injection of a 200-micrograms bolus of GnRH. Blood samples were then taken 30, 60, 90, 120, 180, 240, and 300 min after GnRH. Serum concentrations of LH and hCG were measured at each time by two monoclonal antibody sandwich assays developed in our laboratory. After exogenous hCG, serum hCG concentrations rose rapidly to 200-500 IU/L (15,000-35,000 pg/mL) in both the men and women, remaining at this high level throughout the study. In the men, sex steroid concentrations did not change in response to the hCG during the 9 study hours. Compared to saline-treated controls, hCG had no significant effect in either men or postmenopausal women on the basal LH concentration or the response to a GnRH bolus, as determined by peak response and area under the LH/time curve between 0-300 min after GnRH. We conclude that an ultrashort loop feedback mechanism for LH on its own secretion does not exist in humans, as assessed by the present protocol.     

Steroidal control of the release of the preovulatory surge of luteinizing hormone in the rat

Experiments were carried out on 4 day cyclic rats or immature rats induced to ovulate by administration of pregnant mare serum gonadotrophin. Removal of the ovaries and adrenal glands at 17.00 h of pro-oestrus, i.e. after the critical period, prevented the appearance of the surge of LH. Sham-operation or removal of only one of the sets of glands had no effect. This indicates that the preovulatory increase in the concentration of oestradiol is not solely responsible for the surge of LH; the presence of a steroid, secreted by the ovaries and adrenal glands in the late afternoon of pro-oestrus, is also required. Attempts were made to reinstate the surge of LH in ovariectomized, adrenalectomized rats by administration of one of the steroids normally secreted in late pro-oestrus. Corticosterone, 20alpha- and 20beta-hydroxy-4-pregnen-3-one and 17alpha-hydroxyprogesterone all had no effect. Progesterone injected at the time of the operation stimulated the release of LH but only after the plasma concentration had reached its maximum 3--5 hr after injection. Testosterone also stimulated the release of LH some hours after administration.     

Progesterone enhances the surge of luteinizing hormone by increasing the activation of luteinizing hormone-releasing hormone neurons

The ability of progesterone (P) to enhance the surge of LH in the rat is well documented, but whether its primary site of action is on the pituitary or brain is unclear. To determine whether P can alter the activation of LHRH neurons, 1) intact female rats were treated with the P antagonist RU486 (5 mg) at 1230 h on proestrus and killed at specified times during the afternoon and evening for comparison of plasma LH levels and cFos expression in LHRH neurons with untreated proestrous rats. RU486 treatment greatly reduced both the magnitude of the LH surge and the degree of cFos induction (numbers of cells expressing cFos and intensity of cFos staining) in LHRH neurons during proestrus. 2) Ovariectomized (OVX) rats were primed with estradiol benzoate (EB, 1 microgram) and then were treated with EB alone (50 microgram) or EB plus P (5 mg). Treatment with EB without P resulted in significantly lower peak LH levels and a reduced cFos response in LHRH neurons than the EB-P treated rats. These data suggest that the actions of P eventuate in an enhanced activation of LHRH neurons that may be responsible for the increased magnitude of the LH surge.     

Failure of estrogen-induced discharge of luteinizing hormone in lactating women.

Pituitary-ovarian relationships were studied in seven lactating women by measuring the basal plasma concentrations of pituitary and ovarian hormones and their responses to an estrogen provocation test at 7, 30, and 100 days after delivery. The results were compared to a similar group of seven women who did not breast feed. The first ovulation occurred in five of the nonlactating women beteen 43-87 days after delivery, as judged by the urinary excretion of total estrogen and pregnanediol. In all lactating women, ovarian cyclicity was suppressed for at least 150 days after delivery or until weaning. The basal concentration of PRL in lactating women was significantly higher than in the nonlactating women at all three times measured. At 30 and 100 days, the concentration of estradiol was significantly lower in the lactating women, although the basal concentrations of FSH were similar in the two groups. After an injection of 1 mg estradiol benzoate, the concentrations of FSH and LH in plasma were suppressed to a greater extent in lactating than in nonlactating women. In addition, fewer of the lactating group (one of seven and none of seven at 30 and 100 days, respectively) than the nonlactating group (two of seven and five of seven) subsequently showed a rise in the concentration of LH 58--96 h after the estrogen injection (positive feedback). These results suggest that during lactation the hypothalamic-pituitary system is more sensitive to the negative feedback and relatively insensitive to the positive feedback of estrogen.     

Interleukin-1 inhibits the ovarian steroid-induced luteinizing hormone surge and release of hypothalamic luteinizing hormone-releasing hormone in rats

Interleukin-1 (IL-1), a polypeptide cytokine secreted by activated macrophages, has been postulated as a chemical messenger between the immune and endocrine systems. IL-1-immunopositive neurons and fibers have been visualized in the human and rat hypothalamus, and IL-1 receptors are present in the rat brain. We have examined the effects of human recombinant IL-1 (alpha- and beta-subtypes) on LH release in vivo and hypothalamic LHRH release in vitro. Ovariectomized rats were primed with estradiol benzoate, and progesterone was injected 48 h later to elicit a LH surge in the afternoon. IL-1 alpha and IL-1 beta were injected either intracerebroventricularly (icv) via a preimplanted cannula in the third ventricle of the brain or iv. Systemic injection of IL-1 alpha or IL-1 beta (58.8 pmol at 1300 and 1500 h) failed to influence the afternoon LH surge seen in saline-injected control rats. However, IL-1 beta (1.76 pmol) administered icv at 1300 and 1500 h or a single icv injection at 1300 h blocked the progesterone-induced LH surge. Similar icv injections of IL-1 alpha also significantly suppressed the afternoon LH surge compared to that in saline-injected control rats. However, IL-1 alpha was relatively less effective than the beta-subtype, since the LH surge was detected in some rats. To ascertain whether suppression of the LH surge was due to inhibition of LHRH release, the medial basal hypothalamus-preoptic area of estradiol benzoate-progesterone-treated ovariectomized rats was incubated with and without IL-1. Both IL-1 alpha and IL-1 beta, at concentrations of 0.1 nM and higher, significantly suppressed LHRH release in vitro from the medial basal hypothalamus-preoptic area. In contrast, IL-1 (10 nM) was completely ineffective in suppressing LHRH release from the microdissected median eminence. These results demonstrated an overall inhibitory effect of icv IL-1 on the LHRH-LH axis and suggest that suppression of the steroid-induced LH surge by IL-1 may primarily be due to inhibition of LHRH release at hypothalamic sites located within the blood-brain barrier.     

Circadian control of kisspeptin and a gated GnRH response mediate the preovulatory luteinizing hormone surge

In spontaneously ovulating rodents, the preovulatory LH surge is initiated on the day of proestrus by a timed, stimulatory signal originating from the circadian clock in the suprachiasmatic nucleus (SCN). The present studies explored whether kisspeptin is part of the essential neural circuit linking the SCN to the GnRH system to stimulate ovulation in Syrian hamsters (Mesocricetus auratus). Kisspeptin neurons exhibit an estrogen-dependent, daily pattern of cellular activity consistent with a role in the circadian control of the LH surge. The SCN targets kisspeptin neurons via vasopressinergic (AVP), but not vasoactive intestinal polypeptide-ergic, projections. Because AVP administration can only stimulate the LH surge during a restricted time of day, we examined the possibility that the response to AVP is gated at the level of kisspeptin and/or GnRH neurons. Kisspeptin and GnRH activation were assessed after the administration of AVP during the morning (when AVP is incapable of initiating the LH surge) and the afternoon (when AVP injections stimulate the LH surge). Kisspeptin, but not GnRH, cellular activity was up-regulated after morning injections of AVP, suggesting that time-dependent sensitivity to SCN signaling is gated within GnRH but not kisspeptin neurons. In support of this possibility, we found that the GnRH system exhibits pronounced daily changes in sensitivity to kisspeptin stimulation, with maximal sensitivity in the afternoon. Together these studies reveal a novel mechanism of ovulatory control with interactions among the circadian system, kisspeptin signaling, and a GnRH gating mechanism of control.     

Increased gonadotropin-releasing hormone pulse frequency associated with estrogen-induced luteinizing hormone surges in ovariectomized ewes

Hypophyseal portal blood samples were taken from ovariectomized (OVX) ewes given 50 micrograms estradiol benzoate. This estrogen treatment elicited a biphasic alteration (decrease then increase) in LH secretion. During the negative feedback phase, pulsatile GnRH secretion continued; at this time the interpulse interval for the GnRH pulses (49.5 +/- 5.7 min, mean +/- SE, n = 6) was similar to that in 7 control OVX ewes (53.4 +/- 8.7 min). During the positive feedback phase the GnRH interpulse interval (26.8 +/- 9.8 min; n = 6) was significantly (P less than 0.05) less than in the controls. In 3/7 cases the GnRH pulse frequency in OVX controls was within the range observed for estrogen-treated sheep during the positive feedback phase. These data suggest that, in most cases, the LH surge that can be induced by estrogen in OVX ewes, is associated with an increased GnRH pulse frequency. In some animals the inherent GnRH pulse frequency may already be at a rate that is high enough to permit an LH surge by action of estrogen on the pituitary. In general, the mean concentrations of GnRH in portal blood during the LH surge were higher than those in untreated animals, suggesting an overall increase in GnRH output during the LH surge. Pulsatile GnRH secretion continues throughout the early negative feedback phase, suggesting that the predominant effect of estrogen at this time is at the pituitary level.     

Y2 receptor-selective agonist delays the estrogen-induced luteinizing hormone surge in ovariectomized ewes, but y1-receptor-selective agonist stimulates voluntary food intake

Neuropeptide Y (NPY) plays a major role in the regulation of food intake, regulation of homeostasis, and neuroendocrine function. We have previously shown that third ventricular infusion of this peptide delays the estradiol benzoate-induced surge in LH secretion in ovariectomized ewes. To determine the receptor subtype that transmits this effect, we have now used the same model to infuse a Y1 receptor agonist [NPY Leu31 Pro34], a Y2 receptor agonist (PYY3-36), and a Y4 receptor agonist (pancreatic polypeptide). We monitored the surges in animals given these agonists or artificial cerebrospinal fluid by measuring plasma LH levels, and we also measured daily voluntary food intake (VFI). A low (7 microg/h) dose of Y2 agonist delayed the surge but did not affect VFI, whereas a higher dose (14 microg/h) stimulated VFI. A dose of 18 microg/h of the Y1 agonist did not affect surge generation but also stimulated VFI. A dose of 24 microg/h of Y4 agonist affected neither surge generation nor VFI. These specificities are different from those reported for the rat and human (in which a Y2 agonist causes reduction in VFI). We conclude that, in sheep, the negative regulation of the reproductive axis by NPY and Y-receptor agonists is effected via the Y2 receptors, whereas the orexigenic effects are most likely effected via the Y1 receptors.     

Evidence for a negative ultrashort loop feedback mechanism operating on the luteinizing hormone-releasing hormone neuronal system

The present studies were designed to determine whether an ultrashort loop feedback mechanism is involved in the regulation of LHRH secretion. Daily administration of a highly potent LHRH agonist (LHRH-AGO; [D-Ala6,Des-Gly10] LHRH ethylamide) immediately after orchidectomy (ORDX) significantly attenuated the rise of plasma LH from days 2 through 10 after ORDX. Concomitantly with the diminished LH rise after ORDX, a significant increase in LHRH content in the arcuate nucleus was observed in LHRH-AGO-treated rats. Measurement of LHRH levels in hypophyseal portal blood in rats 10 days after ORDX combined with daily agonist treatment revealed a significant decrease in LHRH values in portal plasma compared with those in orchidectomized controls. Arcuate nuclei-median eminence (ME) fragments obtained from ORDX rats treated in vivo with LHRH-AGO for 5 days showed a decreased basal secretion of LHRH and a diminished response to K+ stimulation compared with the release from fragments obtained from ORDX saline-treated controls. To evaluate whether a tonic LHRH inhibitory activity operates within the ME, additional experiments were performed in which ME fragments were incubated in vitro in the presence of a potent LHRH antagonist [( D-pGlu1,D-Phe2,D-Trp3,6]LHRH). The antagonist significantly enhanced the basal secretion of LHRH in a dose-dependent manner. The latter results suggest that LHRH antagonists may enhance LHRH release, perhaps by interacting with LHRH receptors playing an inhibitory role on the endogenous secretion of the decapeptide. These observations strongly suggest a tonic inhibitory or modulatory role of LHRH neurons in the regulation of their own function.     

Follicle-stimulating hormone induced ovarian hyperstimulation in monkeys: blockade of the luteinizing hormone surge

The availability of a pure human FSH preparation for studies of the primate ovarian/menstrual cycle permitted novel experiments on gonadotropic stimulation of follicular growth in monkeys. Administration of pure FSH on days 1 through 12 of the menstrual cycle resulted in significant ovarian hyperstimulation, as manifested by the development of multiple (bilateral) ovarian follicles and sustained high serum estradiol levels (approximately 400 pg/ml). In spite of overt follicular development and concurrent increases in serum estradiol, timely LH surges were not elicited. Similarly, during FSH-induced ovarian hyperstimulation, GnRH effects on LH secretion were blunted. Equivalent FSH treatments of long term ovariectomized monkeys had no discernible effects on estrogen-induced LH surges or GnRH responses. Our interpretation is that when supraphysiological FSH levels persist into the late follicular phase, thereby overriding selection of the single dominant follicle of the natural cycle, secretion of an ovarian factor(s) blocks estrogen-induced LH surges.     

Differential control of luteinizing hormone and follicle-stimulating hormone by luteinizing hormone releasing hormone in the ram.

Adult Soay rams with low concentrations of gonadotrophins in the circulation as a result of 12 weeks of exposure to long daylengths (16 h light : 8 h darkness) were given small doses (100 ng) of synthetic luteinizing hormone releasing hormone (LH-RH) into the jugular vein two, four or seven times/day for 10 days. Each injection of LH-RH induced a transitory increase in the concentration of LH and testosterone in the plasma, whereas the concentration of FSH showed little immediate change. After repeated treatment with pulses of LH-RH, the responses of LH and testosterone became slightly enhanced and the plasma concentration of FSH became permanently raised; these changes were most conspicuous in the animals receiving the most frequent injections. At the end of the study when the injections of LH-RH were stopped, the concentrations of LH and testosterone remained low but the concentrations of FSH continued to be maintained at a high level for at least 24 h.     

Endogenous opioids participate in the regulation of the hypothalamus-pituitary-luteinizing hormone axis and testosterone's negative feedback control of luteinizing hormone.

Two narcotic antagonists, naloxone and naltrexone, significantly elevated serum LH levels in male rats within minutes after their sc injection. The peak increase in serum LH occurred 20 min after the injection. Naloxone increased LH levels up to a dose of 1 mg/kg, after which no further increases were found. A dose of 0.35 mg/kg produced a half-maximal response. The exogenous opioid morphine blocked the increase in LH produced by naloxone in a dose-dependent fashion, suggesting that the specific receptor-blocking effects of the antagonist could account for its enhancement of serum LH levels. The locus of action of naloxone within the hypothalamic-pituitary-LH axis appeared to be at the level of the hypothalamus since the drug had no effect on LHRH-stimulated release of LH by the anterior pituitary and did not block dihydrotestosterone's suppression of pituitary LH release in vitro. Naloxone also prevented testosterone's negative feedback inhibition of serum LH in the castrated male rat. The results of these studies suggest that endogenous opioids exist in brain tissue which normally inhibit activity in the hypothalamic-pituitary-LH axis and participate in the androgen-dependent feedback control of LH elaboration by this axis.     

Similarity of an estrogen-induced protein and a luteinizing hormone releasing hormone-induced protein

Estradiol induces a 70 kDa protein ('EI70') which is synthesized in vivo in the female rat ventromedial hypothalamus (VMH) and transported to the midbrain central gray, suggesting a role for EI70 in the female mating behavior, lordosis. Luteinizing hormone releasing hormone (LHRH), in addition to stimulating gonadotropin release, potentiates pituitary responsiveness to subsequent exposure to LHRH (the 'priming' effect), facilitates lordosis and induces the synthesis of a 70 kDa protein ('LHRH70') in pituitary in vitro. We now report that EI70 precisely co-migrates on two-dimensional (2-D) gels with the pituitary protein induced by LHRH both in vitro and in vivo. Furthermore, both proteins migrate on 2-D gels in the vicinity of a protein recognized after immunoblotting by antibodies to the heat-shock-70 kDa protein family. The induction of a common protein by estrogen or LHRH could represent a common mechanism by which these hormones facilitate secretion, and by which these hormones interact.