The luteinizing hormone surge regulates circadian clock gene expression in the chicken ovary

The molecular circadian clock mechanism is highly conserved between mammalian and avian species. Avian circadian timing is regulated at multiple oscillatory sites, including the retina, pineal, and hypothalamic suprachiasmatic nucleus (SCN). Based on the authors' previous studies on the rat ovary, it was hypothesized that ovarian clock timing is regulated by the luteinizing hormone (LH) surge. The authors used the chicken as a model to test this hypothesis, because the timing of the endogenous LH surge is accurately predicted from the time of oviposition. Therefore, tissues can be removed before and after the LH surge, allowing one to determine the effect of LH on specific clock genes. The authors first examined the 24-h expression patterns of the avian circadian clock genes of Bmal1, Cry1, and Per2 in primary oscillatory tissues (hypothalamus and pineal) as well as peripheral tissues (liver and ovary). Second, the authors determined changes in clock gene expression after the endogenous LH surge. Clock genes were rhythmically expressed in each tissue, but LH influenced expression of these clock genes only in the ovary. The data suggest that expression of ovarian circadian clock genes may be influenced by the LH surge in vivo and directly by LH in cultured granulosa cells. LH induced rhythmic expression of Per1 and Bmal1 in arrhythmic, cultured granulosa cells. Furthermore, LH altered the phase and amplitude of clock gene rhythms in serum-shocked granulosa cells. Thus, the LH surge may be a mechanistic link for communicating circadian timing information from the central pacemaker to the ovary.     

The Luteinizing Hormone Surge Regulates Circadian Clock Gene Expression in the Chicken Ovary

The molecular circadian clock mechanism is highly conserved between mammalian and avian species. Avian circadian timing is regulated at multiple oscillatory sites, including the retina, pineal, and hypothalamic suprachiasmatic nucleus (SCN). Based on the authors’ previous studies on the rat ovary, it was hypothesized that ovarian clock timing is regulated by the luteinizing hormone (LH) surge. The authors used the chicken as a model to test this hypothesis, because the timing of the endogenous LH surge is accurately predicted from the time of oviposition. Therefore, tissues can be removed before and after the LH surge, allowing one to determine the effect of LH on specific clock genes. The authors first examined the 24-h expression patterns of the avian circadian clock genes of Bmal1, Cry1, and Per2 in primary oscillatory tissues (hypothalamus and pineal) as well as peripheral tissues (liver and ovary). Second, the authors determined changes in clock gene expression after the endogenous LH surge. Clock genes were rhythmically expressed in each tissue, but LH influenced expression of these clock genes only in the ovary. The data suggest that expression of ovarian circadian clock genes may be influenced by the LH surge in vivo and directly by LH in cultured granulosa cells. LH induced rhythmic expression of Per1 and Bmal1 in arrhythmic, cultured granulosa cells. Furthermore, LH altered the phase and amplitude of clock gene rhythms in serum-shocked granulosa cells. Thus, the LH surge may be a mechanistic link for communicating circadian timing information from the central pacemaker to the ovary. (Author correspondence: stischkau@siumed.edu)     

Regulation of the pulsatile releases of luteinizing and follicle-stimulating hormones in ovariectomized hamsters

We have combined for modifications of common radioimmunoassay (RIA) techniques to increase the sensitivity of the gonadotropin assays by an order of magnitude compared with those generated according to the instructions provided by the National Pituitary Agency. The four modifications are: a) enzymatic radioiodination, b) purification of radiolabeled hormones by Sephadex and concanavalin A chromatography, c) reduced first antibody concentration, and d) a prolonged incubation time. These methods increase the sensitivities of the RIAs and allow for the quantitation of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) levels in small volumes of plasma. We have used these methods to measure the changes in pulse frequency and amplitude of LH and FSH in ovariectomized hamsters after a variety of neuroendocrine manipulations. Alterations in catecholaminergic neurotransmission affect the frequency and amplitude of LH but not FSH release, and suggest that the hypothalamic mechanisms responsible for LH releasing hormone (LHRH)-mediated LH release are distinct from those that regulate FSH secretion. Further, alterations in LHRH-pituitary interactions (elicited by injections of LHRH antisera or a potent LHRH agonist), suggest the existence of separate control mechanisms responsible for LH and FSH release at the level of the adenohypophysis. Combined, these studies provide further evidence for complex and separate neuroendocrine regulatory control over the secretion of each gonadotropin.     

Effect of alterations in pulsatile luteinizing hormone release on ovarian follicular atresia and steroid secretion on diestrus 1 in the rat estrous cycle

This study examined the importance of pulsatile luteinizing hormone (LH) release on diestrus 1 (D1; metestrus) in the rat estrous cycle to ovarian follicular development and estradiol (E2) secretion. Single injections of a luteinizing hormone-releasing hormone (LHRH) antagonist given at -7.5 h prior to the onset of a 3-h blood sampling period on D1 reduced mean blood LH levels by decreasing LH pulse amplitude, while frequency was not altered. Sequential injections at -7.5 and -3.5 h completely eliminated pulsatile LH secretion. Neither treatment altered the total number of follicles/ovary greater than 150 mu in diameter, the number of follicles in any size group between 150 and 551 mu, or plasma E2, progesterone, or follicle-stimulating hormone (FSH) levels. However, both treatments with LHRH antagonist significantly increased the percentage of atretic follicles in the ovary. These data indicate that: 1) pulsatile LH release is an important factor in determining the rate at which follicles undergo atresia on D1; 2) reductions in LH pulse amplitude alone are sufficient to increase the rate of follicular atresia on D1; 3) an absence of pulsatile LH release for a period of up to 10 h on D1 is not sufficient to produce a decline in ovarian E2 secretion, most likely because the atretic process was in its early stages and had not yet affected a sufficient number of E2-secreting granulosa cells to reduce the follicle's capacity to secrete E2; and 4) suppression or elimination of pulsatile LH release on D1 is not associated with diminished FSH secretion.     

Nutritional influences on sexual maturation in the rat

The effect of altered nutrition on sexual maturation may depend in part on the nature and timing of the dietary change. The data are conflicting as to whether rats undernourished before weaning but normally fed after weaning have delayed puberty, but such undernourished rats clearly weigh less at vaginal opening than do normally fed animals. Altered nutrition after weaning can change the timing of puberty, and in such cases the body weight at puberty of the animals given the modified diet is frequently abnormal. The factors regulating the age and weight at puberty of rats fed altered diets seem to include the degree of underfeeding, as reflected in the growth rate, and the composition of the diet. Undernourished immature male rats have low serum testosterone secondary to gonadotropin deficiency. Basal luteinizing hormone (LH) in these animals is either low or "inappropriately normal" relative to their hypoandrogenic state (low serum testosterone and sexual accessory gland weights), and serum LH increases after luteinizing hormone-releasing hormone (LHRH) or castration are normal or minimally reduced. Serum follicle-stimulating hormone (FSH) in undernourished rats is subnormal basally and after administration of LHRH, but not after castration, which suggests that the low basal serum FSH is due to inhibition of FSH output by a testicular factor. Spermatogenesis may be unaltered by dietary changes severe enough to cause hypoandrogenism, although very severe under-nutrition will impair sperm production.     

Effect of food deprivation on the pulsatile LH release in the cycling and ovariectomized female rat

The effect of food deprivation on the pulsatile release of LH was examined in the normal cycling and the ovariectomized (OVX) adult female rat. In the cycling animals, there were significant decreases in the mean plasma LH levels as well as the frequency and amplitude of the LH pulse 48 h after the onset of food deprivation. On the other hand, food deprivation for up to 72 h did not cause any changes in pulsatile LH release in the OVX animals. No difference in the changes in body weight and blood glucose concentration were found between the cycling and OVX rats throughout the period of food deprivation for up to 96 h. These findings suggest that ovarian factors play an important role in the early manifestation of the effect of food deprivation on pulsatile LH release and that metabolic changes as expressed by decreases in body weight and blood glucose level per se were not the direct causes in the decrease of LH release during the period of food deprivation.     

Changing frequency of pulsatile luteinizing hormone and progesterone secretion during the luteal phase of the menstrual cycle of rhesus monkeys

Experiments were conducted to examine the pulsatile nature of biologically active luteinizing hormone (LH) and progesterone secretion during the luteal phase of the menstrual cycle in rhesus monkeys. As the luteal phase progressed, the pulse frequency of LH release decreased dramatically from a high of one pulse every 90 min during the early luteal phase to a low of one pulse every 7-8 h during the late luteal phase. As the pulse frequency decreased, there was a corresponding increase in pulse amplitude. During the early luteal phase, progesterone secretion was not episodic and there were increments in LH that were not associated with elevations in progesterone. However, during the mid-late luteal phase, progesterone was secreted in a pulsatile fashion. During the midluteal phase (Days 6-7 post-LH surge), 67% of the LH pulses were associated with progesterone pulses, and by the late luteal phase (Days 10-11 post-LH surge), every LH pulse was accompanied by a dramatic and sustained release of progesterone. During the late luteal phase, when the LH profile was characterized by low-frequency, high-amplitude pulses, progesterone levels often rose from less than 1 ng/ml to greater than 9 ng/ml and returned to baseline within a 3-h period. Thus, a single daily progesterone determination is unlikely to be an accurate indicator of luteal function. These results suggest that the changing pattern of mean LH concentrations during the luteal phase occurs as a result of changes in frequency and amplitude of LH release. These changes in the pulsatile pattern of LH secretion appear to have profound effects on secretion of progesterone by the corpus luteum, especially during the mid-late luteal phase when the patterns of LH concentrations are correlated with those of progesterone.     

Metabolic cues for the onset of puberty.

The hypothesis that the timing of puberty is at least in part stimulated by some 'metabolic signal' that tells the central control system of the reproductive axis that the body is becoming large enough, and that there are enough metabolic fuel stores, to support reproductive function has received considerable attention over the past several decades. However, direct experimental support for the hypothesis that mild metabolic changes, such as those that occur slowly during development, are actually capable of modulating reproductive function has been lacking. Our recent studies have shown that very brief periods of fasting in both male rhesus monkeys and men can modify the pulsatile release of LH and testosterone. In monkeys, missing a single meal is associated with a suppression of mean plasma LH, FSH and testosterone concentrations, and with a slowing of the frequency of pulsatile LH secretion. Current studies are aimed at identifying the specific metabolic signals which cause these changes. It is hoped that the results of these studies will eventually help to answer the question of whether normal metabolic changes occurring during development play a role in timing puberty onset.     

Pulse sensitivity of the luteinizing hormone beta promoter is determined by a negative feedback loop Involving early growth response-1 and Ngfi-A binding protein 1 and 2

The hypothalamic-pituitary-gonadal endocrine axis regulates reproduction through estrous phase-dependent release of the heterodimeric gonadotropic glycoprotein hormones, LH and FSH, from the gonadotropes of the anterior pituitary. Gonadotropin synthesis and release is dependent upon pulsatile stimulation by the hypothalamic neuropeptide GnRH. Alterations in pulse frequency and amplitude alter the relative levels of gonadotropin synthesis and release. The mechanism of interpretation of GnRH pulse frequency and amplitude by gonadotropes is not understood. We have examined gene expression in LbetaT2 gonadotropes under various pulse regimes in a cell perifusion system by microarray and identified 1127 genes activated by tonic or pulsatile GnRH. Distinct patterns of expression are associated with each pulse frequency, but the greatest changes occur at a 60-min or less interpulse interval. The immediate early gene mRNAs encoding early growth response (Egr)1 and Egr2, which activate the gonadotropin LH beta-subunit gene promoter, are stably induced at high pulse frequency. In contrast, mRNAs for the Egr corepressor genes Ngfi-A binding protein Nab1 and Nab2 are stably induced at low pulse frequency. We show that Ngfi-A binding protein members inhibit Egr-mediated frequency-dependent induction of the LH beta-subunit promoter. This pattern of expression suggests a model of pulse frequency detection that acts by suppressing activation by Egr family members at low frequency and allowing activation at sustained high-frequency pulses.     

Fos-induction in gonadotropin-releasing hormone neurons receiving vasoactive intestinal polypeptide innervation is reduced in middle-aged female rats

A hallmark of reproductive aging in rats is a delay in the initiation and peak, and a decrease in the amplitude, of both proestrous and steroid-induced surges of LH and a decrease in the number of GnRH neurons that express Fos during the surge. The altered timing of the LH surge and the decline in Fos expression in GnRH neurons may be due to changes in the rhythmic expression of vasoactive intestinal polypeptide (VIP), a neuropeptide that carries time-of-day information from the circadian pacemaker, located in the suprachiasmatic nuclei (SCN), to GnRH neurons. The goals of our study were to determine if aging alters 1) the innervation of GnRH neurons by VIP and 2) the ability of VIP to activate GnRH neurons by examining the effects of aging on the number of GnRH neurons apposed by VIP fibers and the number of GnRH neurons that receive VIP input that express Fos. Immunocytochemistry for GnRH and VIP; or GnRH, VIP, and Fos was performed on tissue sections collected from young (2-4 mo), regularly cycling females and middle-aged (10-12 mo) females in constant estrus. The number of GnRH neurons, GnRH neurons apposed by VIP fibers, and GnRH neurons that express Fos and apposed by VIP fibers were counted in both age groups. Our results clearly demonstrate that aging does not alter the number of GnRH neurons that receive VIP innervation. However, the number of GnRH neurons that receive VIP innervation and coexpress Fos decreases significantly. We conclude that the age-related delay in the timing of the LH surge is not due to a change in VIP innervation of GnRH neurons, but instead may result from a decreased sensitivity of GnRH neurons to VIP input.     

Interrelationships between the hypothalamus, pituitary gland, ovary, adrenal gland, and the open period for LH release in the hen (Gallus domesticus)

The asynchronous ovulatory cycle of the hen is believed to be the consequence of two interacting systems, one of which is circadian and regulates the timing of the preovulatory LH surge. In support of this proposition, the open period for LH release was shown to oscillate with the same periodicity as the photoschedule when the hens were exposed to 14 L:7 D, 14 L:10 D, and 14 L:14 D. In addition, it was demonstrated that follicular maturation is not affected by or synchronized with the photoperiod. The physiological system that transduces the light/dark cycle into an open period for LH release has not been identified although circumstantial evidence supports the idea that the adrenal gland plays a role in this function. This evidence includes the anatomical juxtaposition of the left ovary and adrenal gland, innervation of steroid-producing cells within the follicle by nerve tracts passing through the adrenal glands, the ability of injections of metyrapone to alter the timing of preovulatory LH release, the ability of injections of corticosterone to induce ovulation when a mature follicle is present in the ovary, and the ability of dexamethasone or infusions of corticosterone to block ovulation. Recently we have also shown that infusions of corticosterone will block the gonadotropic effect of PMSG, will inhibit the photoperiodic response, and do not affect the release of LH in response to injections of GnRH. The addition of corticosterone to incubations of dispersed granulosa cells does not affect their response to LH. These data suggest that corticosterone may modulate the responsiveness of the hypothalamus to tropic stimuli and demonstrate that exposure to corticosterone can alter the responsiveness of some ovarian tissues to gonadotropins.     

Direct pituitary effects of estradiol and progesterone on luteinizing hormone release, stores, and subunit messenger ribonucleic acids

To determine the direct, chronic actions of progesterone (P4) and estrogen (estradiol, E2) on anterior pituitary synthesis and release of LH, 24 western range ewes underwent hypothalamic-pituitary disconnection (HPD) and ovariectomy (OVX) during the breeding season and were pulsed with exogenous GnRH with or without steroid replacement. Sequential blood samples were collected before infusion of GnRH and on Days 7 and 14 of GnRH infusion. Silastic capsules of P4 and/or E2 were implanted s.c. on Day 7 and remained in place throughout the experiment. Control ewes received only GnRH infusion. Blood sampling was centered around three exogenous GnRH pulses. After the final blood sampling, pituitaries were collected and stored at -70 degrees C. Concentrations of LH in serum and pituitaries were determined by RIA. Relative concentrations of LH subunit mRNAs were determined by Fast Blot analysis. Simultaneous implantation of P4 and E2 lowered LH pulse amplitude 70% and mean serum levels 30% compared with controls. Neither steroid alone affected LH release. E2 alone or in combination with P4 lowered LH-beta subunit mRNA concentrations 40% compared with controls while alpha-subunit levels were unchanged. Only E2 alone altered the pituitary content of LH, causing a 60% decrease. We conclude that the combination of P4 and E2 is necessary for inhibition of GnRH-stimulated LH secretion. E2 inhibits GnRH-stimulated LH-beta subunit mRNA concentrations but does not affect alpha-subunit mRNA concentrations. The control of pituitary LH content by P4 and E2 is the result of changes in both LH-beta subunit mRNA concentrations and LH secretion.     

Centrally applied somatostatin inhibits the estrogen-induced luteinizing hormone surge via hypothalamic gonadotropin-releasing hormone cell activation in female rats

Overexpression of growth hormone (GH) as well as GH-deficiency dramatically impairs reproductive function. Decreased reproductive function as a result of altered GH release is, at least partially, due to changes at the hypothalamic-pituitary level. We hypothesize that hypothalamic somatostatin (SOM), the inhibiting factor of GH release from the pituitary, may play a central role in the "crosstalk" between the somatotropic and gonadotropic axes. In the present study we investigated the possible effects of a centrally applied SOM analog on the LH surge and the concurrent activation of hypothalamic GnRH neurons in female rats. To this end, female rats were treated with estradiol 2 wk after ovariectomy and were given a single central injection with either the SOM analog, octreotide, or saline just prior to surge onset, after which hourly blood samples were taken to measure LH. Two weeks later, the experimental setup was randomly repeated to collect brains during the anticipated ascending phase of the LH surge. Vibratome sections were subsequently double-stained for GnRH and cFos peptide. Following octreotide treatment, LH surges were significantly attenuated compared to those in saline-treated control females. Also, octreotide treatment significantly decreased the activation of hypothalamic GnRH neurons. These results clearly demonstrate that SOM is able to inhibit LH release, at least in part by decreasing the activation of GnRH neurons. Based on these results, we hypothesize that hypothalamic SOM may be critically involved in the physiological regulation of the proestrus LH surge.     

Opioid regulation of luteinizing hormone secretion in the male rat

Current evidence suggests that endogenous opioid peptides (EOPs) tonically inhibit secretion of luteinizing hormone (LH) by modulating the release of gonadotropin-releasing hormone (GnRH). Because of their apparent inhibitory actions, EOPs have been assumed to alter both pulse frequency and amplitude of LH in the rat; and it has been hypothesized that EOP pathways mediate the negative feedback actions of steroids on secretion of GnRH. In order to better delineate the role of EOPs in regulating secretion of LH in the male rat, we assessed the effects of a sustained blockade of opiate receptors by naloxone on pulsatile LH release in four groups: intact male rats, acutely castrated male rats implanted for 20 h with a 30-mm capsule made from Silastic and filled with testosterone, acutely castrated male rats implanted for 20 h with an osmotic minipump dispensing 10 mg morphine/24 h, and male rats castrated approximately 20 h before treatment with naloxone. We hypothesized that if EOPs tonically inhibited pulsatile LH secretion, a sustained blockade of opiate receptors should result in a sustained increase in LH release. We found that treatment with naloxone resulted in an immediate but transient increase in LH levels in intact males compared to controls treated with saline. Even though mean levels of LH increased from 0.15 +/- 0.04 to a high of 0.57 +/- 0.14 ng/ml, no significant difference was observed between the groups in either frequency or amplitude of LH pulses across the 4-h treatment period. The transient increase in LH did result in a 3- to 4-fold elevation in levels of plasma testosterone over baseline. This increase in testosterone appeared to correspond with the waning of the LH response to naloxone. The LH response to naloxone was eliminated in acutely castrated rats implanted with testosterone. Likewise, acutely castrated rats treated with morphine also failed to respond to naloxone with an increase in LH. These observations suggest that chronic morphine and chronic testosterone may act through the same mechanism to modulate secretion of LH, or once shut down, the GnRH pulse-generating system becomes refractory to stimulation by naloxone. In acutely castrated male rats, levels of LH were significantly increased above baseline throughout the period of naloxone treatment; this finding supports the hypothesis that the acute elevation in testosterone acting through mechanism independent of opioid is responsible for the transient response of LH to naloxone in the intact rat.     

Adrenal gland involvement in synchronizing the preovulatory release of LH in rats.

In this study we have demonstrated that acute adrenalectomy (1000 hr proestrus) has no effect on the release of LH on proestrous afternoon. However, chronic adrenalectomy results in the loss of some factor responsible for synchronizing the preovulatory LH surge. Since this investigator has shown previously (15) that progesterone can influence the timing of LH release in ovariectomized and ovariectomized-adrenalectomized animals, it is most likely that adrenal progesterone is involved in synchronizing this event.     

Naloxone enhances LH but not FSH release during various phases of the estrous cycle in the ewe

Suffolk x whiteface ewes were infused with 0.5 mg/kg/hr naloxone hydrochloride (NAL) for 6 hrs during the early, mid and late luteal and early follicular phases of the estrous cycle. Basal serum luteinizing hormone (LH) concentration was increased by NAL during each trial in the luteal phase and LH pulse amplitude was proportionately increased by 158%, 164% and 350% during the early luteal, mid luteal and early follicular phases, respectively. The apparent NAL induced increase (92%) in LH pulse amplitude during the late luteal phase was not significant. NAL only affected LH pulse frequency during the early follicular phase, when it was decreased. Mean serum follicle stimulating hormone (FSH) concentration was not affected by NAL. The results of this study indicate that endogenous opioid peptides (EOPs) may partially mediate the suppressive influence of estradiol-17 beta (E2) on LH pulse amplitude and also the stimulatory effect of E2 on LH pulse frequency in the early follicular phase. The data may suggest that NAL enhances the amplitude of pulses of gonadotropin releasing hormone (GnRH) by counteracting E2 inhibitory effects on LH release at the level of the pituitary. Alternately, some component of E2 feedback may be an EOP mediated component at the level of the hypothalamus.     

Estrogen and leptin have differential effects on FSH and LH release in female rats

Prior experiments have shown that the adipocyte hormone leptin can advance puberty in mice. We hypothesized that it would also stimulate gonadotrophin secretion in adults. Since the secretion of follicle stimulating hormone (FSH) and luteinizing hormone (LH) is drastically affected by estrogen, we hypothesized that leptin might have different actions dependent on the dose of estrogen. Consequently in these experiments, we tested the effect of injection of leptin into the third cerebral ventricle of ovariectomized animals injected with either the oil diluent, 10 microg or 50 microg of estradiol benzoate 72 hr prior to the experiment. The animals were ovariectomized 3-4 weeks prior to implantation of a cannula into the third ventricle 1 week before the experiments. The day after implantation of an external jugular catheter, blood samples (0. 3 ml) were collected just before and every 10 min for 2 hr after 3V injection of 5 microl of diluent or 10 microg of leptin. Both doses of estradiol benzoate equally decreased plasma LH concentrations and pulse amplitude, but there was a graded decrease in pulse frequency. In contrast, only the 50-microg dose of estradiol benzoate significantly decreased mean plasma FSH concentrations without significantly changing other parameters of FSH release. The number of LH pulses alone and pulses of both hormones together decreased as the dose of estrogen was increased, whereas the number of pulses of FSH alone significantly increased with the higher dose of estradiol benzoate, demonstrating differential control of LH and FSH secretion by estrogen, consistent with alterations in release of luteinizing hormone releasing hormone (LHRH) and the putative FSH-releasing factor (FSHRF), respectively. The effects of intraventricularly injected leptin were drastically altered by increasing doses of estradiol benzoate. There was no significant effect of intraventricular injection of leptin (10 microg) on the various parameters of either FSH or LH secretion in ovariectomized, oil-injected rats, whereas in those injected with 10 microg of estradiol benzoate there was an increase in the first hr in mean plasma concentration, area under the curve, pulse amplitude, and maximum increase of LH above the starting value (Deltamax) on comparison with the results in the diluent-injected animals in which there was no alteration of these parameters during the 2 hr following injection. The pattern of FSH release was opposite to that of LH and had a different time-course. In the diluent-injected animals, probably because of the stress of injection and frequent blood sampling, there was an initial significant decline in plasma FSH at 20 min after injection, followed by a progressive increase with a significant elevation above the control values at 110 and 120 min. In the leptin-injected animals, mean plasma FSH was nearly constant during the entire experiment, coupled with a significant decrease below values in diluent-injected rats, beginning at 30 min after injection and progressing to a maximal difference at 120 min. Area under the curve, pulse amplitude, and Deltamax of FSH was also decreased in the second hour compared to values in diluent-injected rats. In contrast to the stimulatory effects of intraventricular injection of leptin on pulsatile LH release manifest during the first hour after injection, there was a diametrically opposite, delayed significant decrease in pulsatile FSH release. This differential effect of leptin on FSH and LH release was consistent with differential effects of leptin on LHRH and FSHRF release. Finally, the higher dose of E2 (50 microg) suppressed release of both FSH and LH, but there was little effect of leptin under these conditions, the only effect being a slight (P < 0.04) increase in pulse amplitude of LH in this group of rats. The results indicate that the central effects of leptin on gonadotropin release are strongly dependent on plasma estradiol levels. These effects are consistent w     

Orchidectomy unleashes pulsatile luteinizing hormone secretion in the rat

We charted the development of pulsatile luteinizing hormone (LH) secretion as a function of the time elapsed after removal of the testes. On seven occasions between the moment of castration and 80 days afterwards, we obtained consecutive blood samples at frequent (2.5- to 5-min) intervals from cannulated male rats. Orchidectomy increased both the amplitude and frequency of LH release within 1 day after surgery. Amplitude: From 19 h through 80 days postcastration, peak LH levels rose steadily, and LH pulses grew progressively more pronounced in nadir-to-peak amplitude. Frequency: Our findings offer new evidence establishing an increase in LH pulse frequency from less than 1 per h to 2-3 per h within 1 day after orchidectomy. Once deprived of testicular influences, the frequency of pulsatile LH discharges remained static through 80 days. The sudden onset (less than 1 day after castration) and temporal uniformity of high-frequency LH pulses demonstrate that LH release is governed by an intrinsic, 20- to 30-min neural periodicity in castrate rats. Most important, these findings imply that the testes mask or modulate the expression of an intrinsic, 20- to 30-min neural generator directing the periodic discharge of LH in the intact male rat.     

Role of ovarian secretion in the development of dysfunction in the regulation of luteinizing hormone secretion in female rats exposed to constant illumination.

Female rats in constant illumination (LL) fail to show the facilitation of LH release following steroid administration that is characteristic of animals in normal lighting. To determine whether this effect is mediated through changes in ovarian function, rats were spayed either at the time of placement into different lighting schedules (LL or a 14:10 light-dark (LD) schedule) or 10 weeks later, and their plasma LH responses to steroids were compared after an additional 3-week exposure to the experimental lighting conditions. To test the LH response, estradiol benzoate (EB) was injected at 12.00 h and followed 72 h later by injection of progesterone (P) or a second injection of EB. Neither steroid regime revealed differences in LH release between animals ovariectomized at the time of placement into LL and those spayed 10 weeks later. The duration of castration in animals in LD affected the LH response to a priming dose of EB, but not to a second dose of EB or to P. It is concluded that altered ovarian activity is not the factor which mediates the loss of a facilitatory response of LH release following administration of gonadal steroids to rats under constant illumination.     

DynPeak: an algorithm for pulse detection and frequency analysis in hormonal time series

The endocrine control of the reproductive function is often studied from the analysis of luteinizing hormone (LH) pulsatile secretion by the pituitary gland. Whereas measurements in the cavernous sinus cumulate anatomical and technical difficulties, LH levels can be easily assessed from jugular blood. However, plasma levels result from a convolution process due to clearance effects when LH enters the general circulation. Simultaneous measurements comparing LH levels in the cavernous sinus and jugular blood have revealed clear differences in the pulse shape, the amplitude and the baseline. Besides, experimental sampling occurs at a relatively low frequency (typically every 10 min) with respect to LH highest frequency release (one pulse per hour) and the resulting LH measurements are noised by both experimental and assay errors. As a result, the pattern of plasma LH may be not so clearly pulsatile. Yet, reliable information on the InterPulse Intervals (IPI) is a prerequisite to study precisely the steroid feedback exerted on the pituitary level. Hence, there is a real need for robust IPI detection algorithms. In this article, we present an algorithm for the monitoring of LH pulse frequency, basing ourselves both on the available endocrinological knowledge on LH pulse (shape and duration with respect to the frequency regime) and synthetic LH data generated by a simple model. We make use of synthetic data to make clear some basic notions underlying our algorithmic choices. We focus on explaining how the process of sampling affects drastically the original pattern of secretion, and especially the amplitude of the detectable pulses. We then describe the algorithm in details and perform it on different sets of both synthetic and experimental LH time series. We further comment on how to diagnose possible outliers from the series of IPIs which is the main output of the algorithm.