Pulsatile GnRH secretion: Roles of G protein-coupled receptors,second messengers and ion channels

The pulsatile secretion of GnRH from normal and immortalized hypothalamic GnRH neurons is highly calcium-dependent and is stimulated by cAMP. It is also influenced by agonist activation of the endogenous GnRH receptor (GnRH-R), which couples to multiple G proteins. This autocrine mechanism could serve as a timer to determine the frequency of pulsatile GnRH release by regulating Ca²⁺- and cAMP-dependent signaling and GnRH neuronal firing. The firing of individual and/or bursts of action potentials (APs) in spontaneously active GnRH neurons is followed by afterhyperpolarization (AHP) that lasts from several milliseconds to several seconds. GnRH-induced activation of GnRH neurons causes a significant increase in medium AHP that is partially sensitive to apamin. GnRH-induced modulation of Ca²⁺ influx and the consequent changes in AHP current suggest that the GnRH receptors expressed in hypothalamic GnRH neurons are important modulators of their neuronal excitability. The coexistence of multiple regulatory mechanisms could provide a high degree of redundancy in the maintenance of this crucial component of the reproductive process. It is also conceivable that this multifactorial system could reflect the gradation from simple to more complex neuroendocrine control systems for regulating hypothalamo-pituitary function and gonadal activity during the evolution of the GnRH pulse generator.     

Whole-cell recordings from preoptic/hypothalamic slices reveal burst firing in gonadotropin-releasing hormone neurons identified with green fluorescent protein in transgenic mice

Central control of reproduction is governed by a neuronal pulse generator that underlies the activity of hypothalamic neuroendocrine cells that secrete GnRH. Bursts and prolonged episodes of repetitive action potentials have been associated with hormone secretion in this and other neuroendocrine systems. To begin to investigate the cellular mechanisms responsible for the GnRH pulse generator, we used transgenic mice in which green fluorescent protein was genetically targeted to GnRH neurons. Whole-cell recordings were obtained from 21 GnRH neurons, visually identified in 200-microm preoptic/hypothalamic slices, to determine whether they exhibit high frequency bursts of action potentials and are electrically coupled at or near the somata. All GnRH neurons fired spontaneous action potentials, and in 15 of 21 GnRH neurons, the action potentials occurred in single bursts or episodes of repetitive bursts of high frequency spikes (9.77 +/- 0.87 Hz) lasting 3-120 sec. Extended periods of quiescence of up to 30 min preceded and followed these periods of repetitive firing. Examination of 92 GnRH neurons (including 32 neurons that were located near another green fluorescent protein-positive neuron) revealed evidence for coupling in only 1 pair of GnRH neurons. The evidence for minimal coupling between these neuroendocrine cells suggests that direct soma to soma transfer of information, through either cytoplasmic bridges or gap junctions, has a minor role in synchronization of GnRH neurons. The pattern of electrical activity observed in single GnRH neurons within slices is temporally consistent with observations of GnRH release and multiple unit electrophysiological correlates of LH release. Episodes of burst firing of individual GnRH neurons may represent a component of the GnRH pulse generator.     

Calcium signaling and episodic secretion of gonadotropin-releasing hormone in hypothalamic neurons.

Gonadotropin-releasing hormone (GnRH) is released episodically into the pituitary portal vessels and from hypothalamic tissue of male and female rats in vitro. Perifused primary cultures of rat hypothalamic neurons, as well as the GT1-1 GnRH neuronal cell line, spontaneously exhibited episodic GnRH secretion of comparable frequency to that observed with perifused hypothalami. Such pulsatile GnRH release from GT1 cells indicates that GnRH neurons generate rhythmic secretory activity in the absence of input from other cell types. In primary hypothalamic cultures, the frequency of GnRH pulses increased with the duration of culture. The spontaneous pulsatility in GnRH release was abolished in Ca(2+)-deficient medium and was markedly attenuated in the presence of nifedipine, an antagonist of voltage-sensitive Ca2+ channels. The basal intracellular Ca2+ level of perifused GT1-1 cells cultured on coverslips was also dose-dependently reduced by nifedipine. Conversely, depolarization with high K+ increased intracellular Ca2+ and GnRH release in an extracellular Ca(2+)-dependent and nifedipine-sensitive manner. The dihydropyridine Ca2+ channel agonist Bay K 8644 increased basal and K(+)-induced elevations of intracellular Ca2+ concentration and GnRH secretion. These findings demonstrate that pulsatile neuropeptide secretion is an intrinsic property of GnRH neuronal networks and is dependent on voltage-sensitive Ca2+ influx for its maintenance.     

Estradiol and the inhibition of hypothalamic gonadotropin-releasing hormone pulse generator activity in the rhesus monkey.

In mammals, gonadal function is controlled by a hypothalamic signal generator that directs the pulsatile release of gonadotropin-releasing hormone (GnRH) and the consequent pulsatile secretion of luteinizing hormone. In female rhesus monkeys, the electrophysiological correlates of GnRH pulse generator activity are abrupt, rhythmic increases in hypothalamic multiunit activity (MUA volleys), which represent the simultaneous increase in firing rate of individual neurons. MUA volleys are arrested by estradiol, either spontaneously at midcycle or after the administration of the steroid. Multiunit recordings, however, provide only a measure of total neuronal activity, leaving the behavior of the individual cells obscure. This study was conducted to determine the mode of action of estradiol at the level of single neurons associated with the GnRH pulse generator. Twenty-three such single units were identified by cluster analysis of multiunit recordings obtained from a total of six electrodes implanted in the mediobasal hypothalamus of three ovariectomized rhesus monkeys, and their activity was monitored before and after estradiol administration. The bursting of all 23 units was arrested within 4 h of estradiol administration although their baseline activity was maintained. The bursts of most units reappeared at the same time as the MUA volleys, the recovery of some was delayed, and one remained inhibited for the duration of the study (43 days). The results indicate that estradiol does not desynchronize the bursting of single units associated with the GnRH pulse generator but that it inhibits this phenomenon. The site and mechanism of action of estradiol in this regard remain to be determined.     

Disruption of GnRH pulses by anti-GnRH serum and phentolamine obliterates pulsatile LH but not FSH secretion in ovariectomized rabbits

It has been hypothesized that the secretion of gonadotropins, i.e. luteinizing hormone (LH) and follicle-stimulating hormone (FSH), is driven by a synchronized neural network ('pulse generator'). This network, regulated in part by alpha-adrenergic activity, ultimately generates bursts of hypothalamic gonadotropin-releasing hormone (GnRH) release. In this study, we used the push-pull (PP) perfusion technique in ovariectomized rabbits to investigate three aspects of the ('GnRH/gonadotropin pulse generator') hypothesis. The objectives were to determine: (1) if plasma LH and FSH pulses occur concomitantly with mediobasal hypothalamic (MBH-) GnRH pulses, (2) changes in the patterns of pulsatile LH and FSH secretion when pulsatile MBH GnRH signals are interrupted by either local immunoneutralization of GnRH or intravenous infusion of the alpha-adrenergic antagonist phentolamine (PHEN, 4 mg/kg BW), and (3) whether third cerebroventricular (3VT-) GnRH patterns reflect neuronal GnRH release from the MBH. We found that while both plasma LH and FSH patterns were pulsatile, MBH GnRH pulses were significantly coupled only with LH pulses (94% coincidence). Both the local immunoneutralization of MBH GnRH pulses and the PHEN-induced suppression of MBH GnRH pulses obliterated the pulsatile secretion of LH, but not FSH. Neither MBH GnRH nor plasma LH or plasma FSH pulses were concurrent with 3VT GnRH pulses. However, the PP perfusion of the 3VT appeared to alter the pulsatile release of MBH GnRH and pituitary LH. The results support the hypothesis that in the absence of ovarian signals, the 'pulse generator' is maintained by tonic alpha-adrenergic input and that a 'cellular unity' of MBH GnRH release (GnRH pulses) drives the gonadotrophs to secrete LH in pulses. In contrast, the pulsatile release of FSH appears to involve additional nonovarian regulatory events to those controlling LH secretion.     

Optogenetic activation of GnRH neurons reveals minimal requirements for pulsatile luteinizing hormone secretion

The mechanisms responsible for generating the pulsatile release of gonadotropins from the pituitary gland are unknown. We develop here a methodology in mice for controlling the activity of the gonadotropin-releasing hormone (GnRH) neurons in vivo to establish the minimal parameters of activation required to evoke a pulse of luteinizing hormone (LH) secretion. Injections of Cre-dependent channelrhodopsin (ChR2)-bearing adeno-associated virus into the median eminence of adult GnRH-Cre mice resulted in the selective expression of ChR2 in hypophysiotropic GnRH neurons. Acute brain slice experiments demonstrated that ChR2-expressing GnRH neurons could be driven to fire with high spike fidelity with blue-light stimulation frequencies up to 40 Hz for periods of seconds and up to 10 Hz for minutes. Anesthetized, ovariectomized mice had optical fibers implanted in the vicinity of GnRH neurons within the rostral preoptic area. Optogenetic activation of GnRH neurons for 30-s to 5-min time periods over a range of different frequencies revealed that 10 Hz stimulation for 2 min was the minimum required to generate a pulse-like increment of LH. The same result was found for optical activation of GnRH projections in the median eminence. Increases in LH secretion were compared with endogenous LH pulse parameters measured from ovariectomized mice. Driving GnRH neurons to exhibit simultaneous burst firing was ineffective at altering LH secretion. These observations provide an insight into how GnRH neurons generate pulsatile LH secretion in vivo.Reproductive functioning in all mammals is critically dependent upon pulsatile gonadotropin secretion (1). Experiments undertaken in the 1980s clearly established that pulsatile luteinizing hormone (LH) and follicle-stimulating hormone secretion were generated by the episodic release of gonadotropin-releasing hormone (GnRH) into the pituitary portal vasculature (2–6). However, a quarter of a century since those experiments were performed, the components and mechanisms responsible for this episodic release of GnRH remain unknown and represent one of the most important unanswered questions in reproductive biology (7).Key parameters such as the number of GnRH neurons involved in a pulse and their patterns of electrical firing are unknown. An important insight into the dynamics of a GnRH pulse has come from fast portal blood sampling in ovariectomized sheep where each GnRH pulse is reported to approximate a square wave beginning sharply over 2 min, remaining elevated for ∼5 min, and then falling to baseline over the next 3 min (8). This allowed speculation that a subgroup of GnRH neurons may fire coordinately for a period of 2–7 min to generate a pulse of GnRH (7). Disappointingly, however, direct electrical recordings of adult GnRH neurons in acute brain slices in vitro have provided no clear correlate of pulsatile hormone secretion (7, 9). Recent investigations into GnRH neuron firing in vivo in anesthetized GnRH-green fluorescent protein (GFP) mice have similarly been unable to shed light on the pulse-generating properties of these cells (10). The most promising insights into the nature of GnRH pulsatility have come from studies of embryonic GnRH neurons in vitro where episodes of burst firing, represented by calcium transients, are found to synchronize occasionally in subpopulations of GnRH neurons in a time frame similar to that of pulsatile GnRH/LH secretion (11, 12).The best way of determining the patterns of GnRH neuron firing that generate an LH pulse would be to record the activity of hypophysiotropic GnRH neurons while simultaneously measuring LH secretion in vivo. At present this remains impossible. An alternative approach that might shed light on this issue would be to determine the minimal patterns of GnRH neuron firing that are capable of generating an LH pulse in vivo. This is now possible using optogenetic approaches, and we report here a strategy that allows hypophysiotropic GnRH neurons to be transfected with channelrhodopsins (ChR2) and subsequently activated in vivo to generate pulses of LH secretion. This reveals that GnRH neurons need only be activated at either their cell bodies or distal projections within the median eminence (ME) for 2 min at a constant 10-Hz firing rate to generate an LH pulse. Surprisingly, synchronizing burst firing among GnRH neurons is ineffective.     

Selective optogenetic activation of arcuate kisspeptin neurons generates pulsatile luteinizing hormone secretion

Normal reproductive functioning in mammals depends upon gonadotropin-releasing hormone (GnRH) neurons generating a pulsatile pattern of gonadotropin secretion. The neural mechanism underlying the episodic release of GnRH is not known, although recent studies have suggested that the kisspeptin neurons located in the arcuate nucleus (ARN) may be involved. In the present experiments we expressed channelrhodopsin (ChR2) in the ARN kisspeptin population to test directly whether synchronous activation of these neurons would generate pulsatile luteinizing hormone (LH) secretion in vivo. Characterization studies showed that this strategy targeted ChR2 to 70% of all ARN kisspeptin neurons and that, in vitro, these neurons were activated by 473-nm blue light with high fidelity up to 30 Hz. In vivo, the optogenetic activation of ARN kisspeptin neurons at 10 and 20 Hz evoked high amplitude, pulse-like increments in LH secretion in anesthetized male mice. Stimulation at 10 Hz for 2 min was sufficient to generate repetitive LH pulses. In diestrous female mice, only 20-Hz activation generated significant increments in LH secretion. In ovariectomized mice, 5-, 10-, and 20-Hz activation of ARN kisspeptin neurons were all found to evoke LH pulses. Part of the sex difference, but not the gonadal steroid dependence, resulted from differential pituitary sensitivity to GnRH. Experiments in kisspeptin receptor-null mice, showed that kisspeptin was the critical neuropeptide underlying the ability of ARN kisspeptin neurons to generate LH pulses. Together these data demonstrate that synchronized activation of the ARN kisspeptin neuronal population generates pulses of LH.Reproduction is critically dependent upon pulsatile patterns of luteinizing hormone (LH) secretion driven by the episodic release of gonadotropin-releasing hormone (GnRH) into the pituitary portal vasculature (1–3). How the scattered population of GnRH neurons within the basal forebrain of mammals is able to generate an episodic pattern of GnRH release remains unknown. Early observations from immortalized GnRH-secreting cell lines indicated that periodic secretion was an intrinsic property of the GnRH neurons themselves (4, 5). However, it seems increasingly unlikely that this is the principal mechanism underling the episodic secretion of GnRH in adult mammals (6). As such, attention has shifted to the elucidation of an extrinsic “pulse generator” within the GnRH neuronal network that entrains GnRH neurons to release GnRH in an episodic manner (6–9).Based upon early lesioning and deafferentation studies, it was suggested that the GnRH pulse generator may exist in the mediobasal hypothalamus (10–12). Within this region, particular attention has been focused on the arcuate nucleus (ARN) (13, 14), where studies have also recorded multiunit activity that correlates with pulsatile LH secretion in a variety of mammals (15–18). Although the identity of the neural elements giving rise to multiunit activity are unknown, it has been suggested that they may represent the activity of kisspeptin neurons within the ARN (19). These cells, also known as KNDy neurons—because they coexpress a range of neurotransmitters, including kisspeptin, neurokinin B, dynorphin, and glutamate—are thought to represent an afferent input within the GnRH neuronal network involved in several aspects of fertility control (20–22). In particular, speculation that these cells may generate synchronized oscillatory patterns of activity through shared excitatory and inhibitory inputs has raised the possibility that they may play a role in GnRH pulse generation (19, 20, 23, 24).In the present study we have tested directly whether the selective and synchronous activation of KNDy neurons in vivo can generate pulsatile LH secretion in mice. We demonstrate that the synchronous activation of ARN KNDy neurons at ≥10 Hz is remarkably effective at generating repetitive pulses of LH secretion. The efficacy of ARN kisspeptin neurons to generate LH pulses is sexually differentiated and modulated by the gonadal steroid milieu. We also show that, among the various neurotransmitters used by KNDy neurons, the activation of LH pulses results from kisspeptin activation of the kisspeptin receptor GPR54.     

Transplanted gonadotropin-releasing hormone neurons promote pulsatile luteinizing hormone secretion in congenitally hypogonadal (hpg) male mice

Congenitally hypogonadal (hpg) male mice are unable to synthesize biologically active gonadotropin-releasing hormone (GnRH). Implantation of normal fetal preoptic area tissue containing GnRH neurons into the third ventricle of adult hpg males significantly elevates pituitary levels of luteinizing hormone (LH) and corrects their hypogonadism. In all responding animals, immunoreactive GnRH neurons within the transplant innervate the median eminence of the host. To assess whether gonadal recovery in hpg hosts results from pulsatile secretion of GnRH from grafted neurons, we compared the pattern of variation in plasma LH levels in 19 hpg graft recipients with testicular growth to that of 10 normal adult mice. All animals were castrated prior to receiving an indwelling catheter in the jugular vein. Sequential blood samples were collected (t = 10 min) and assayed for LH. Pulsatile LH secretion was seen in 11 of 19 hpg hosts and in all control mice. While there was great variability between individual animals, measures of baseline LH, LH pulse amplitude and duration, interpulse interval, and LH pulse frequency revealed no difference between hpg graft recipients and normal castrates in their LH pulse pattern. Immunocytochemical analysis of the brain in hpg hosts suggested no correlation between any parameter of pulse activity and individual differences in GnRH cell number or GnRH fiber outgrowth into the median eminence. Sources of variation in LH secretion among graft recipients, and between hpg hosts and normal mice, are discussed. We suggest that transplanted GnRH neurons are capable of integration into a GnRH 'pulse generator' which can support a near-normal pattern of pulsatile LH secretion, leading to testicular growth and steroid production.     

Overexpression of glutamic acid decarboxylase-67 (GAD-67) in gonadotropin-releasing hormone neurons disrupts migratory fate and female reproductive function in mice

gamma-Aminobutyric acid (GABA) inhibits the embryonic migration of GnRH neurons and regulates hypothalamic GnRH release. A subset of GnRH neurons expresses GABA along their migratory route in the nasal compartment before entering the brain, suggesting that GABA produced by GnRH neurons may help regulate the migratory process. To examine this hypothesis and the possibility that persistence of GABA production by GnRH neurons may affect subsequent reproductive function, we generated transgenic mice in which the expression of glutamic acid decarboxylase-67 (GAD-67), a key enzyme in GABA synthesis, is targeted to GnRH neurons under the control of the GnRH gene promoter. On embryonic d 15, when GnRH neurons are still migrating, the transgenic animals had more GnRH neurons in aberrant locations in the cerebral cortex and fewer neurons reaching the hypothalamic-preoptic region, whereas migration into the brain was not affected. Hypothalamic GnRH content in mutant mice was low during the first week of postnatal life, increasing to normal values during infantile development (second week after birth) in the presence of increased pulsatile GnRH release. Consistent with these changes, serum LH and FSH levels were also elevated. Gonadotropin release returned to normal values by the time steroid negative feedback became established (fourth week of life). Ovariectomy at this time demonstrated an enhanced gonadotropin response in transgenic animals. Although the onset of puberty, as assessed by the age at vaginal opening and first ovulation, was not affected in the mutant mice, estrous cyclicity and adult reproductive capacity were disrupted. Mutant mice had reduced litter sizes, increased time intervals between deliveries of litters, and a shorter reproductive life span. Thus, GABA produced within GnRH neurons does not delay GnRH neuronal migration, but instead serves as a developmental cue that increases the positional diversity of these neurons within the basal forebrain. In addition, the results suggest that the timely termination of GABA production within the GnRH neuronal network is a prerequisite for normal reproductive function. The possibility arises that similar abnormalities in GABA homeostasis may contribute to syndromes of hypothalamic amenorrhea/oligomenorrhea in humans.     

An agonist-induced switch in G protein coupling of the gonadotropin-releasing hormone receptor regulates pulsatile neuropeptide secretion

The pulsatile secretion of gonadotropin-releasing hormone (GnRH) from normal and immortalized hypothalamic GnRH neurons is highly calcium-dependent and is stimulated by cAMP. It is also influenced by agonist activation of the endogenous GnRH receptor (GnRH-R), which couples to G(q/11) as indicated by release of membrane-bound alpha(q/11) subunits and increased inositol phosphate/Ca(2+) signaling. Conversely, GnRH antagonists increase membrane-associated alpha(q/11) subunits and abolish pulsatile GnRH secretion. GnRH also stimulates cAMP production but at high concentrations has a pertussis toxin-sensitive inhibitory effect, indicative of receptor coupling to G(i). Coupling of the agonist-activated GnRH-R to both G(s) and G(i) proteins was demonstrated by the ability of nanomolar GnRH concentrations to reduce membrane-associated alpha(s) and alpha(i3) levels and of higher concentrations to diminish alpha(i3) levels. Conversely, alpha(i3) was increased during GnRH antagonist and pertussis toxin treatment, with concomitant loss of pulsatile GnRH secretion. In cholera toxin-treated GnRH neurons, decreases in alpha(s) immunoreactivity and increases in cAMP production paralleled the responses to nanomolar GnRH concentrations. Treatment with cholera toxin and 8-bromo-cAMP amplified episodic GnRH pulses but did not affect their frequency. These findings suggest that an agonist concentration-dependent switch in coupling of the GnRH-R between specific G proteins modulates neuronal Ca(2+) signaling via G(s)-cAMP stimulatory and G(i)-cAMP inhibitory mechanisms. Activation of G(i) may also inhibit GnRH neuronal function and episodic secretion by regulating membrane ion currents. This autocrine mechanism could serve as a timer to determine the frequency of pulsatile GnRH release by regulating Ca(2+)- and cAMP-dependent signaling and GnRH neuronal firing.     

Episodic gonadotropin-releasing hormone gene expression revealed by dynamic monitoring of luciferase reporter activity in single, living neurons

The existence of an intrinsic oscillator for pulsatile gonadotropin-releasing hormone (GnRH) secretion in normal and transformed GnRH neurons raises the question of whether the corresponding gene also is expressed in an episodic manner. To resolve this question, we used a modification of conventional luciferase technology, which enabled continuous monitoring of GnRH gene activity in single, living neurons. With this method, the relative rate of endogenous gene expression is estimated by quantification of photons emitted by individual neurons microinjected with a GnRH promoter-driven luciferase reporter construct. Immortalized GT1–1 neurons, which secrete the decapeptide GnRH in a pulsatile manner conceptually identical to that of their nontransformed counterparts in vivo, were chosen as the model for these studies. First, we injected individual cells with purified luciferase protein and established that the reporter half-life was sufficiently short (50 min) to enable detection of transient changes in gene expression. Next, we subjected transfected GT1–1 cells to continuous monitoring of reporter activity for 16 h and found that the majority of them exhibited spontaneous fluctuations of photonic activity over time. Finally, we established that photonic activity accurately reflected endogenous GnRH gene expression by treating transfected GT1–1 cells with phorbol 12-myristate 13 acetate (a consensus inhibitor of GnRH gene expression) and observing a dramatic suppression of photonic emissions from continuously monitored cells. Taken together, these results demonstrate the validity of our “real-time” strategy for dynamically monitoring GnRH gene activity in living neurons. Moreover, our findings indicate that GnRH gene expression as well as neuropeptide release can occur in an intermittent manner.     

Immortalized gonadotropin-releasing hormone neurons (GT1-7 cells) exhibit synchronous bursts of action potentials

Although it has been assumed that synchronized firing of gonadotropin-releasing hormone (GnRH) neurons is necessary for pulsatile GnRH secretion, there is no clear evidence for this. In the present study we simultaneously recorded spontaneous action potentials from multiple cells. Immortalized GnRH neurons (GT1-7 cells) were cultured on a multi-electrode dish (MED) and action potentials recorded by an extracellular recording method. One to two weeks after the beginning of culture, spontaneous action potentials appeared, exhibiting bursts composed of 5-10 action potentials. Burst activity was intermittent and periodic with mean burst intervals of 13.3 s. Furthermore, burst activity was recorded almost simultaneously from several micro-electrodes, suggesting that electrical activities of GT1-7 cells were synchronized with each other. Periodic bursts were completely and reversibly blocked by 1-5 microM tetrodotoxin, indicating that voltage-dependent Na(+) channels are involved in their generation. gamma-Aminobutyric acid (GABA) given at a 10-microM concentration shortened inter-burst intervals, whereas 10 microM bicuculline lengthened them. Finally, the gap junctional blockers n-octyl alcohol (1 mM) and carbenoxolone (100 microM) reversibly blocked periodic burst activity. The present study provides direct evidence that the electrical activity of GT1-7 cells exhibits synchronous and periodic bursts composed of action potentials. In addition, endogenous GABA is involved in GT1-7 cells in determining burst frequency. Although the precise mechanism of synchronized burst activities needs to be clarified, gap junctional communications among GT1-7 cells are at least partially involved.     

Age affects spontaneous activity and depolarizing afterpotentials in isolated gonadotropin-releasing hormone neurons

Neuronal activity underlying the pulsatile secretion of GnRH remains poorly understood, as does the endogenous generation of such activity. It is clear that changes at the level of the hypothalamus are taking place during reproductive aging, yet virtually nothing is known about GnRH neuronal physiology in aging and postreproductive animals. In these studies, we performed cell-attached and whole-cell recordings in GnRH-enhanced green fluorescent protein neurons dissociated from young (3 months), middle-aged (10 months), and old (15-18 months) female mice. All mice were ovariectomized; half were estradiol replaced. Neurons from all ages fired spontaneously, most in a short-burst pattern that is characteristic of GnRH neuronal firing. Membrane characteristics were not affected by age. However, firing frequency was significantly reduced in neurons from old animals, as was spike patterning. The amplitude of the depolarizing afterpotential, evoked by a 200-msec current pulse, was significantly smaller in aged animals. In addition, inward whole-cell currents were reduced in estradiol-treated animals, although they were not significantly affected by age. Because depolarizing afterpotentials have been shown to contribute to prolonged discharges of activity after a very brief excitatory input, a decreased depolarizing afterpotential could lead to attenuated pulses in older animals. In addition, decreases in frequency and pattern generation could lead to improper information coding. Therefore, changes in the GnRH neuron during aging could lead to dysregulated activity, potentially resulting in the attenuated LH pulses observed in the transition to reproductive senescence.     

Electrophysiological studies on the hypothalamic GnRH pulse generator]

Gonadal function in mammals depends on gonadotropins secreted from the pituitary gland in a pulsatile manner. This pulsatility is governed by the periodic activation of the hypothalamic GnRH pulse generator. By means of multiple unit activity (MUA) recording techniques, characteristics increases in the neuronal activity, each of which is associated with the initiation of pulsatile LH secretion, have been recorded in the medial basal hypothalamus of the monkey, rat and goat. An unambiguous unitary relationship between the increased electrical activity (volley) and the LH pulse under a variety of physiological and experimental conditions indicates that the MUA volleys represent the electrical activity of the GnRH pulse generator. Hypothalamic MUA recordings provide direct access to the central component of the neuroendocrine control system which governs reproductive function.     

Evidence of a corticotropin-releasing hormone pulse generator in the macaque hypothalamus.

The secretion of hormones from the hypothalamic-pituitary axis is, in general, characterized by an episodic pattern of release. In the adrenal axis, ACTH and cortisol levels in peripheral blood display irregularly pulsatile ultradian patterns that are superimposed on the well characterized circadian rhythm. While it is generally accepted that CRH is released from the hypothalamus in a similar manner, very few studies have actually examined the temporal release of CRH. To examine the temporal release of CRH directly, we have established an in vitro perifusion system using the hemisectioned macaque hypothalamus. Perifusate samples were collected at 10-min intervals for 20 h and assayed for CRH by RIA. In control animals, a very regular, pulsatile pattern of hormone release was present, with a pulse interval of 90 +/- 11 min. Although this interval closely approximates the average pulse interval of ACTH and cortisol in the human, the regular pattern revealed in our study has not been demonstrated previously in the adrenal axis in vivo and suggests that factors outside the hypothalamus play a major role in controlling adrenal hormone levels. When hypothalami were perifused with dexamethasone added to the culture medium, no change in pulsatile activity was detected, indicating that a site outside of the hypothalamus may function as the primary center of feedback inhibition by adrenal glucocorticoids in the central nervous system. Because the very regular pulses of CRH that we observed bear striking similarity to the circhoral pulses of GnRH, we speculate that CRH may play a more subordinate role in regulating the adrenal axis and that other releasing factors and/or feedback effects at the pituitary level may be more important in the generation of the irregularly pulsatile, circadian patterns of ACTH and cortisol seen in peripheral blood.     

Subcutaneous pulsatile glucocorticoid replacement therapy

The glucocorticoid hormone cortisol is released in pulses resulting in a complex and dynamic ultradian rhythm of plasma cortisol that underlies the classical circadian rhythm. These oscillating levels are also seen at the level of tissues such as the brain and trigger pulses of gene activation and downstream signalling. Different patterns of glucocorticoid presentation (constant vs pulsatile) result not only in different patterns of gene regulation but also in different neuroendocrine and behavioural responses. Current ‘optimal’ glucocorticoid replacement therapy results in smooth hormone blood levels and does not replicate physiological pulsatile cortisol secretion. Validation of a novel portable pulsatile continuous subcutaneous delivery system in healthy volunteers under dexamethasone and metyrapone suppression. Pulsatile subcutaneous hydrocortisone more closely replicates physiological circadian and ultradian rhythmicity.