Michael Selmanoff

Hormonal and neurotransmitter regulation of GnRH gene expression and related reproductive behaviors

Gonadotropin-releasing hormone (GnRH), having a highly conserved structure across mammalian species, plays a pivotal role in the control of the neuroendocrine events and the inherent sexual behaviors essential for reproductive function. Recent advances in molecular genetic technology have contributed greatly to the investigation of several aspects of GnRH physiology, particularly steroid hormone and neurotransmitter regulation of GnRH gene expression. Behavioral studies have focused on the actions of GnRH in steroid-sensitive brain regions to understand better its role in the facilitation of mating behavior. To date, however, there are no published reports which directly correlate GnRH gene expression and reproductive behavior. The intent of this article is to review the current understanding of the way in which changes in GnRH gene expression, and modifications of GnRH neuronal activity, may ultimately influence reproductive behavior.

A role for hypothalamic catecholamines in the regulation of gonadotropin secretion

Publisher Summary This chapter discusses the role of the hypothalamic catecholaminergic system in regulating Luteinizing-hormone-releasing hormone (LHRH) secretion. The functional activity of the LHRH neuron can be affected by numerous putative neurotransmitters that stimulate or inhibit LHRH release. Some neurotransmitters may also activate or inhibit other primary inputs to affect the activity of the LHRH neuron. Coupled with these complex controls are modulatory influences exerted within the brain by changing serum levels of sex steroids on input circuitry, on genomic functions, and on ionic transport properties of the LHRH neuronal membrane. The entire sequence of neuroendocrine events that ultimately leads to ovulation depends on the maturation of ovarian follicles which, under the influence of basal concentrations of LH and follicle-stimulating hormone FSH, increase their secretion of estrogen into blood during the second day of diestrous and morning of proestrous. Estrogen may not only increase the releasable pool size of median eminence but it also is essential for the increased release of norepinephrine during the early afternoon of proestrus.

Decreased dopamine turnover in the median eminence in response to suckling in the lactating rat

The effects of suckling on the turnover of dopamine (DA) and norepinephrine (NE) were studied in terminal projection fields of the tuberoinfundibular (median eminence, ME), nigrostriatal (caudate nucleus, CN), incertohypothalamic (medial preoptic nucleus, MPN) and mesolimbic (nucleus accumbens, NA) dopaminergic neurons. Decreased dopamine turnover in the median eminence was found in suckled compared with nonsuckled rats at 10 days postpartum. This effect was specific as dopamine turnover in the CN, NA and MPN and norepinephrine turnover in the ME, NA and MPN were not affected by suckling. The suckling-induced prolactin response is markedly blunted in rats 20 days postpartum. In these rats, median eminence dopamine turnover did not decrease significantly in response to suckling. These results are consistent with the hypothesis that median eminence dopamine is a physiological prolactin inhibitory factor mediating suckling-induced prolactin release.

GABAergic neuronal activity and mRNA levels for both forms of glutamic acid decarboxylase (GAD65 and GAD67) are reduced in the diagonal band of Broca during the afternoon of proestrus

There is considerable evidence that GABAergic neurons play an important role in the regulation of gonadotropin-releasing hormone (GnRH) secretion, and that these neurons may mediate the feedback actions of gonadal steroids on GnRH neurons. The aim of the present study was to investigate whether endogenous changes in ovarian steroid secretion during the estrous cycle influenced GABAergic neuronal activity in the preoptic region of the hypothalamus, and in other steroid-sensitive brain regions. Intact, adult female rats were sacrificed at various times during the days of metestrus or proestrus. GABAergic neuronal activity was estimated by measuring the rate of accumulation of GABA in microdissected brain regions after pharmacological inhibition of GABA degradation. Concentrations of mRNA for both forms of glutamic acid decarboxylase (GAD65 and GAD67) were quantified in microdissected brain regions by a microlysate ribonuclease protection assay. In the diagonal band of Broca at the level of the organum vasculosum of the lamina terminalis (DBB(ovlt)), GABAergic neuronal activity was significantly reduced during the afternoon of proestrus compared with the morning of either proestrus or metestrus. In the lateral septal nucleus, GABAergic neuronal activity was significantly increased in the afternoon of proestrus compared with the morning. There were no significant effects of time of day or day of estrous cycle in the medial preoptic nucleus, median eminence, ventromedial nucleus, suprachiasmatic nucleus, medial septal nucleus, hippocampus (CA1 region), or cingulate cortex. In the DBB(ovlt), mRNA levels for both GAD65 and GAD67 were significantly reduced in the afternoon of proestrus compared with the afternoon of metestrus. By contrast, there was no change in GAD65 and GAD67 mRNA levels in the cingulate cortex at any of the times examined. These results demonstrate that GABAergic neuronal activity, and mRNA levels for both GAD65 and GAD67, are reduced in the DBB(ovlt) during the afternoon of proestrus. These results support the hypothesis that decreased GABAergic neuronal activity in this region plays a major permissive role in the generation and maintenance of the estrogen-induced LH surge.

Hyperprolactinemia Alters the Frequency and Amplitude of Pulsatile Luteinizing Hormone Secretion in the Ovariectomized Rat

Studies were undertaken to examine the effects of hyperprolactinemia on the frequency and amplitude of pulses of LH, and determine if changes in pituitary sensitivity to LHRH were involved in the prolactin-induced suppression of LH secretion. Rats were bilaterally ovariectomized (day 0). Ovine prolactin (4 mg/kg body weight, subcutaneously) or vehicle was administered every 8 h beginning at 09.00 h on day 4 after ovariectomy and continuing until 09.00 h on day 6. On day 6, between 07.00 and 09.00 h all animals received a right atrial cannula, using ether anesthesia. In experiment I blood samples were taken at 10-min intervals beginning at 12.00 h on day 6, for a total of 180 min. To test the effect of hyperprolactinemia on pituitary responsiveness (experiment II) animals received an intravenous injection of LHRH (25 ng/100 g body weight) after the 180-min and again after the 240-min sample. Blood was drawn every 10 min for a total of 300 min. Serum was assayed for LH. Hyperprolactinemia altered the pattern of pulsatile secretion of LH. Treatment with ovine prolactin produced a decrease in both the frequency and amplitude of the LH pulses compared to values found in control animals. However, no differences in pituitary responsiveness between hyperprolactinemic and control animals were found at the dose of LHRH given. Thus, the prolactin-induced suppression of pulsatile secretion of LH was not apparently a result of alterations in the sensitivity of the pituitary to LHRH. From these studies we suggest that hyperprolactinemia directly affects a hypothalamic site which ultimately alters the LHRH pulse generator, thereby changing the secretion of LHRH.

Suckling-induced prolactin release is suppressed by naloxone and simulated by β-endorphin

The role that opiate peptides play in suckling-induced prolactin (PRL) release was examined in 10-day postpartum lactating rats. The opiate receptor antagonist naloxone (NAL) suppressed suckling-induced PRL release in a dose-dependent manner and a large dose abolished the response. These results suggest either that opiate neurons are situated in the neuronal pathway mediating this neuroendocrine response, or alternatively, that opiate neurons are situated such that they can modulate neuronal transmission in this pathway. It is suggested that NAL blocks a tonic, inhibitory beta-endorphinergic input to the tuberoinfundibular dopaminergic (TIDA) neurons, hence, NAL administration in effect stimulates the TIDA neurons and in this way overrides the suckling response. Intravenous, bolus administration of beta-endorphin (beta-END) produced a PRL response that was similar to the suckling response in terms of latency of onset and duration while the magnitude of the beta-END-induced response was 2-fold greater than that produced by the suckling stimulus. NAL abolished beta-END-induced PRL release at a much lower dose than that required to inhibit suckling-induced PRL release. This suggests that the neural mediation of the suckling response involves a mechanism in addition to the one inhibited by opiate receptor blockade.

Gonadal hormones alter hypothalamic GABA and glutamate levels

GABA and glutamate levels were measured in brain sites important for lordotic responding and in other hypothalamic sites after gonadal hormone treatments sufficient to activate lordosis. Estradiol increased GABA and glutamate in the ventromedial nucleus and the vertical diagonal bands. Progesterone administration to estradiol primed females led to a rapid decline of the transmitters in these areas. Results are discussed in relation to neuroendocrine regulation.

Castration-induced decrease in the activity of medial preoptic and tuberoinfundibular GABAergic neurons is prevented by testosterone

We recently determined that castration specifically decreased GABA turnover in discrete rostral and mediobasal hypothalamic structures. This study aimed to investigate whether testosterone could stimulate GABAergic neuronal activity in these hypothalamic GABAergic neurons in the castrate rat, and to compare the effects of episodic testosterone replacement with the constant levels provided by subcutaneous testosterone implants. Animals were divided into 4 experimental groups: intact, 48 h castrate, 48 h castrate+testosterone capsules (2 x 30 mm Silastic implants, 1.57 mm ID, 3.18 mm OD) and 48 h castrate+testosterone injections (100 micrograms/injection s.c., every 8 h). GABA concentrations were measured in 4 microdissected brain regions either before or 60 min after inhibition of the GABA degrading enzyme, GABA transaminase, by injection of aminooxyacetic acid (AOAA, 100 mg/kg i.p.). The rate of GABA accumulation in the tissue following injection of AOAA was used as an index of GABAergic neuronal activity. Castration resulted in a 10-fold increase in serum LH concentrations compared with intact rats. Either mode of testosterone administration completely prevented this castration-induced LH rise. In the diagonal band of Broca at the level of the organum vasculosum of the lamina terminalis, the medial preoptic nucleus and in the median eminence, GABA turnover was significantly reduced by castration to approximately 50% that of intact rats. Either testosterone implants or testosterone injections prevented this castration-induced decrease in GABA turnover, such that the turnover rates were not significantly different from intact rats. There was no effect of castration with or without testosterone replacement in the cingulate cortex.(ABSTRACT TRUNCATED AT 250 WORDS)

Regional variation in γ-aminobutyric acid turnover : effect of castration on γ-aminobutyric acid turnover in microdissected brain regions of the male rat

Abstract: This study compared the turnover of GABA neurons in different brain areas of the male rat and examined the effect of castration on GABA turnover in regions of the brain associated with the control of gonadotropin secretion. To estimate GABA turnover, GABA was quantified by HPLC in microdissected brain regions 0,30,60,90, and 120 min after inhibition of GABA degradation by aminooxyacetic acid (100 mg/kg, i.p.). GABA accumulation was linear in all areas for 90 min (p < 0.01), and GABA turnover was estimated as the slope of the line formed by increased GABA concentration versus time, determined by linear regression. There was considerable regional variation both in the initial steady‐state concentrations of GABA and in the rates of GABA turnover. Of 10 discrete brain structures, GABA turnover was highest in the medial preoptic nucleus and lowest in the caudate nucleus. Turnover times in the terminal fields of known GABAergic projection neurons ranged sevenfold, from 2.6 h in the substantia nigra to 0.4 h in the lateral vestibular nucleus. The effect of castration on GABA turnover in 13 microdissected brain regions was investigated by measuring regional GABA concentrations before and 30 min after injection of aminooxyacetic acid in intact rats or 2 or 6 days postcastration. Following castration, steady‐state GABA concentrations were increased, and GABA turnover decreased in the diagonal band of Broca, the medial preoptic area, and the median eminence. GABA turnover increased in the medial septal nucleus and was unaffected in the cortex, striatum, and hindbrain. These results are consistent with the hypothesis that testosterone negative‐feedback control of luteinizing hormone‐releasing hormone involves steroid‐sensitive GABAergic neurons in the rostral and medial basal hypothalamus.

Castration Decreases Single Cell Levels of mRNA Encoding Glutamic Acid Decarboxylase in the Diagonal Band of Broca and the Sexually Dimorphic Nucleus of the Preoptic Area

Using quantitative in situ hybridization histochemistry (ISHH), we determined the effect of castration on single cell levels of glutamic acid decarboxylase (GAD) mRNA in discrete hypothalamic regions of the male rat brain associated with the control of gonadotropin secretion. A 48‐base oligodeoxynucleotide probe was used to detect with equal affinity the two isoforms of GAD message, GAD65 and GAD67. GAD message also was quantitated in a number of selected areas of the brain to contrast GAD gene expression amongst several populations of GABAergic neurons. Comparison of 11 brain regions demonstrated a 9.3‐fold range in the quantity of single cell GAD mRNA with levels being highest in the amygdala and the diagonal band of Broca, moderate in the piriform cortex, caudate nucleus, substantia innominata, globus pallidus, cingulate cortex and medial septal nucleus, and lowest in the lateral septal nucleus and the medial preoptic nucleus (MPN). Castration markedly reduced single cell GAD mRNA levels in the DBB and the MPN, two discrete hypothalamic structures known to contain dendritic fields, cell bodies, and axons of GnRH neurons projecting to the median eminence. A striking finding was a dense core of steroid‐sensitive GABAergic neurons within the MPN comprising the sexually dimorphic nucleus of the preoptic area (SDN‐POA). Similar to the MPN as a whole, the amount of GAD mRNA expressed by cells in the SDN‐POA of sham operated control rats was greater than in castrated animals. GAD mRNA levels were inversely related to serum LH titers, suggesting a role for these neurons in the mechanism controlling gonadal steroid negative feedback on LH secretion. This report provides the basis for future work to determine if GAD65, GAD67 or whether both isoforms are affected by gonadal steroid input.