Expression of the GnRH and GnRH receptor (GnRH-R) genes in the hypothalamus and of the GnRH-R gene in the anterior pituitary gland of anestrous and luteal phase ewes

Data exists showing that seasonal changes in the innervations of GnRH cells in the hypothalamus and functions of some neural systems affecting GnRH neurons are associated with GnRH release in ewes. Consequently, we put the question as to how the expression of GnRH gene and GnRH-R gene in the hypothalamus and GnRH-R gene in the anterior pituitary gland is reflected with LH secretion in anestrous and luteal phase ewes. Analysis of GnRH gene expression by RT-PCR in anestrous ewes indicated comparable levels of GnRH mRNA in the preoptic area, anterior and ventromedial hypothalamus. GnRH-R mRNA at different concentrations was found throughout the preoptic area, anterior and ventromedial hypothalamus, stalk/median eminence and in the anterior pituitary gland. The highest GnRH-R mRNA levels were detected in the stalk/median eminence and in the anterior pituitary gland.During the luteal phase of the estrous cycle in ewes, the levels of GnRH mRNA and GnRH-R mRNA in all structures were significantly higher than in anestrous ewes. Also LH concentrations in blood plasma of luteal phase ewes were significantly higher than those of anestrous ewes.In conclusion, results from this study suggest that low expression of the GnRH and GnRH-R genes in the hypothalamus and of the GnRH-R gene in the anterior pituitary gland, amongst others, may be responsible for a decrease in LH secretion and the anovulatory state in ewes during the long photoperiod.     

Effects of GABA(A) receptor modulation on the expression of GnRH gene and GnRH receptor (GnRH-R) gene in the hypothalamus and GnRH-R gene in the anterior pituitary gland of follicular-phase ewes

The effect of prolonged, intermittent infusion of GABA(A) receptor agonist (muscimol) or GABA(A) receptor antagonist (bicuculline) into the third cerebral ventricle on the expression of GnRH gene and GnRH-R gene in the hypothalamus and GnRH-R gene in the anterior pituitary gland was examined in follicular-phase ewes by real-time PCR. The activation or inhibition of GABA(A) receptors in the hypothalamus decreased or increased the expression of GnRH and GnRH-R genes and LH secretion, respectively. The present results indicate that the GABAergic system in the hypothalamus of follicular-phase ewes may suppress, via hypothalamic GABA(A) receptors, the expression of GnRH and GnRH-R genes in this structure. The decrease or increase of GnRH-R mRNA in the anterior pituitary gland and LH secretion in the muscimol- or bicuculline-treated ewes, respectively, is probably a consequence of parallel changes in the release of GnRH from the hypothalamus activating GnRH-R gene expression. It is suggested that GABA acting through the GABA(A) receptor mechanism on the expression of GnRH gene and GnRH-R gene in the hypothalamus may be involved in two processes: the biosynthesis of GnRH and the release of this neurohormone in the hypothalamus.     

Pituitary gonadotropin-releasing hormone (GnRH) receptor: structure, distribution and regulation of expression

Reproduction in mammals is controlled by interactions between the hypothalamus, anterior pituitary and gonads. Interaction of GnRH with its cognate receptor is essential to regulating reproduction. Characterization of the structure, distribution and expression of GnRH receptors (GnRH-R) has furthered our understanding of the physiological consequences of GnRH stimulation of pituitary gonadotropes. Based on the putative topology of the amino acid sequence of the GnRH-R and point mutation studies, key elements of the GnRH-R have been identified to play a role in ligand recognition and binding, G-protein activation and internalization. Normally, reproductive function is mediated by GnRH-R expressed only on the membranes of pituitary gonadotropes. The density of GnRH-R on gonadotropes determines their ability to respond to GnRH. This density is highest just prior to ovulation and likely is important for complete expression of the pre-ovulatory surge of LH. Therefore, knowledge regarding what regulates the density of GnRH-R is essential to understanding changes in pituitary sensitivity to GnRH and ultimately, to expression of the LH surge. Regulation of GnRH-R gene expression is influenced by a multitude of factors including gonadal steroid hormones, inhibin, activin and perhaps most importantly GnRH itself.     

Regulation of LH beta subunit mRNA in immature female rats during GnRH agonist treatment

In order to determine the changes in the expression of LH beta messenger ribonucleic acid (mRNA) during GnRH agonist (GnRHa) treatment (0.94 mg/28 days), the concentration of the mRNA of LH beta was assessed together with the serum LH concentration, pituitary LH content and LH response to GnRH at various times during long-acting GnRHa treatment in immature female rats. The serum LH concentration was increased at hour 1, gradually decreased starting at approximately hour 3 and had returned to the control level on day 28. Pituitary LH began to decrease at hour 3. The concentrations of LH beta mRNA were not significantly different from those in the control group from hour 1 to hour 18, but were lower from day 3 to day 28. Serum LH response to native GnRH (1 micrograms) began to be inhibited on day 7. These results indicate that the short term treatment with GnRHa stimulates the release of preformed LH rather than synthesis of LH beta mRNA and that the long term treatment inhibited the expression of LH beta mRNA in a time dependent manner.     

The GnRH precursor is present in the anterior pituitary gland and an important increase of its content precedes serum LH surge induced by estradiol-17 beta in female primates

Estradiol-17 beta (E2 17 beta) is well known to evoke a preovulatory-like LH surge in ovariectomized monkeys even in the absence of the integrity of the hypothalamo-pituitary connections. LH release from the anterior pituitary (AP) is reliant on stimulation by hypothalamic GnRH which is derived from proteolytic cleavage of a precursor (designated Pro-GnRH-GAP) which also results in the production of an associated peptide (GAP). The present study examined the effects of E2 17 beta on the hypothalamic content of Pro-GnRH-GAP, GnRH and GAP while incidental observations revealed the presence of Pro-GnRH-GAP and its products in the AP. Changes in GnRH and GAP were closely related at all times after E2 17 beta treatment. However, the pattern of change in the hypothalamus and AP was inversely related. Pro-GnRH-GAP levels remained unchanged in the hypothalamus whereas in the AP the peptide increased markedly (48 hrs. post E2 17 beta) prior to the LH surge and declined to low levels (72 hrs. post E2 17 beta) at the time of the LH surge. The increase in Pro-GnRH-GAP in the AP that precedes the rise in GnRH and accompanying LH surge by 24 hrs. strongly indicates that AP GnRH is more important than hypothalamic GnRH for the mediation of the E2 17 beta-induced LH surge in female primate.     

Effects of intracerebroventricular infusion of genistein on the secretory activity of the GnRH/LH axis in ovariectomized ewes

Phytoestrogens, plant derived estrogen like-compounds exert numerous effects on the reproductive functions of animals. The present study was designed to demonstrate if exogenous genistein infused during the breeding season into the third ventricle of the brain of ovariectomized ewes could affect the secretory activity of the GnRH/LH axis. Two-year-old ovariectomized ewes (n=8) were infused with vehicle (control, n=3) or genistein (10 microg/100 microl/h, n=5) into the third ventricle. The infusions were done from 10.00 to 14.00 h and blood samples collection was performed this day up to 20.00 h and next day from 8.00 to 10.00 h. The animals were slaughtered, thereafter. Immunoreactive (IR) GnRH neurons in the hypothalamus and LH cells in the adenohypophysis were localized by immunohistochemistry. Messenger RNA analyses were performed by nonisotope in situ hybridization using sense and anti-sense riboprobes produced from beta subunits of LH cDNA clones. Plasma LH concentrations were measured by radioimmunoassay. Immunohistochemical analysis revealed that genistein infusion affected the morphology of GnRH neurons evoking a visualization of long axons in the GnRH perikarya and visibly diminished IR GnRH stores in the median eminence. The number of IR LH cells and IR material stored in the adenohypophyses increased in genistein-infused animals, which was confirmed by statistical analysis (P<0.001). The in situ hybridization analyses showed in these ewes the increase of mRNA LHbeta hybridization signal. The changes in LH release in response to genistein infusion had a biphasic character: it decreased within 6 h after infusion and increased 24 h later. Mean concentration of LH and amplitude of pulses measured from the beginning of infusion up to end of the experiment were significantly higher (P<0.05) in genistein-infused ewes compared to vehicle-treatment. In conclusion, our data show that genistein, a phytoestrogen, may effectively modulate GnRH and LH secretion in OVX ewes by acting directly on the CNS. The biphasic character of the LH response is similar to that of estradiol during the breeding season in the ewes.     

Induction of PER1 mRNA expression in immortalized gonadotropes by gonadotropin-releasing hormone (GnRH): involvement of protein kinase C and MAP kinase signaling

The initiation and maintenance of reproductive function in mammals is critically dependent on the pulsatile secretion of gonadotropin-releasing hormone (GnRH). This peptide drives the pulsatile release of FSH and LH from the pituitary pars distalis via signaling pathways that are activated by the type I GnRH receptor (GnRH-R). Recently, a microarray analysis study reported that a number of genes, including mPer1, are induced by GnRH in immortalized gonadotrope cells. In view of these data, we have begun to analyze in detail the signaling pathways mediating the action of GnRH on mPer1 expression in these cells. Using quantitative real-time polymprose cho read (PCR), we could confirm that exposure of immortalized gonadotropes (LbetaT2 cells) to the GnRH analog, buserelin, markedly induces mPer1 (but not mPer2) expression. Consistent with GnRH receptor signaling via the protein kinase (PK)-C pathway, exposure of the cells to phorbol 12,13-dibutyrate rapidly elevates both mPer1 and LHbeta subunit mRNA levels, while pharmacological inhibition of PKC prevents the mPer1 and LHbeta response to buserelin. As GnRH is known to regulate gonadotropin synthesis via activation of p42/44 mitogen-activated protein kinase (MAPK) signaling pathways, we then examined the involvement of this pathway in regulating mPer1 expression in gonadotropes. Our data reveal that GnRH-induced mPer1 expression is blocked following acute exposure to a MAPK kinase inhibitor. Although the involvement of this signaling mechanism in the regulation of mPer1 is known in neurons, e.g., in the suprachiasmatic nuclei, the induction of mPer1 in gonadotropes represents a novel mechanism of GnRH signaling, whose functional significance is still under investigation.     

Induction of PER1 mRNA expression in immortalized gonadotropes by gonadotropin-releasing hormone (GnRH): Involvement of protein kinase C and MAP kinase signaling

The initiation and maintenance of reproductive function in mammals is critically dependent on the pulsatile secretion of gonadotropin-releasing hormone (GnRH). This peptide drives the pulsatile release of FSH and LH from the pituitary pars distalis via signaling pathways that are activated by the type I GnRH receptor (GnRH-R). Recently, a microarray analysis study reported that a number of genes, including mPer1, are induced by GnRH in immortalized gonadotrope cells. In view of these data, we have begun to analyze in detail the signaling pathways mediating the action of GnRH on mPer1 expression in these cells. Using quantitative real-time polymprose cho read (PCR), we could confirm that exposure of immortalized gonadotropes (LβT2 cells) to the GnRH analog, buserelin, markedly induces mPer1 (but not mPer2) expression. Consistent with GnRH receptor signaling via the protein kinase (PK)-C pathway, exposure of the cells to phorbol 12,13-dibutyrate rapidly elevates both mPer1 and LHβ subunit mRNA levels, while pharmacological inhibition of PKC prevents the mPer1 and LHβ response to buserelin. As GnRH is known to regulate gonadotropin synthesis via activation of p42/44 mitogen-activated protein kinase (MAPK) signaling pathways, we then examined the involvement of this pathway in regulating mPer1 expression in gonadotropes. Our data reveal that GnRH-induced mPer1 expression is blocked following acute exposure to a MAPK kinase inhibitor. Although the involvement of this signaling mechanism in the regulation of mPer1 is known in neurons, e.g., in the suprachiasmatic nuclei, the induction of mPer1 in gonadotropes represents a novel mechanism of GnRH signaling, whose functional significance is still under investigation.     

Social dominance regulates androgen and estrogen receptor gene expression

In Astatotilapia burtoni, dominant males have higher levels of sex steroid hormones than subordinate males. Because of the complex regulatory interactions between steroid hormones and receptors, we asked whether dominance is also associated with variation in sex steroid receptor gene expression. Using quantitative PCR, we compared the expression of specific subtypes of androgen (AR) and estrogen (ER) receptor genes between dominant and subordinated males in 3 divisions of the brain, the pituitary, and the testes. We measured mRNA levels of AR-alpha, AR-beta, ER-alpha, ER-betaa, and ER-betab, gonadotropin-releasing hormone 1 (GnRH1), and GnRH receptor 1 (GnRH-R1) relative to 18S rRNA. In the anterior part of the brain, we found that dominant males had higher mRNA expression of AR-alpha, AR-beta, ER-betaa, and ER-betab, but not ER-alpha, compared to subordinate males. This effect of dominance was reflected in a positive correlation between testes size and AR-alpha, AR-beta, ER-betaa, and ER-betab in the anterior brain. In addition, mRNA levels of all ARs and ERs in the anterior brain were positively correlated with mRNA level of GnRH1. In the middle and posterior portions of the brain, as well as the testes, steroid receptor mRNA levels were similar among dominants and subordinates. In the pituitary, ER-alpha mRNA level was positively correlated with testes size and AR-alpha mRNA was positively correlated with GnRH-R1 mRNA level. These data suggest that dominant male brains could be more sensitive to sex steroids, which may contribute to the increased complexity of the behavioral repertoires of dominant males.     

Differential actions of GnRH and rat hypothalamic extracts in release of hypophysial FSH and LH in vitro.

A study was made of the separate patterns of luteinizing hormone (LH) and follicle stimulating hormone (FSH) release from isolated rat pituitary tissue evoked by synthetic gonadotropin releasing hormone (GnRH) or female hypothalamic extracts (HE), respectively, in a continuous perifusion system. Under defined conditions, gonadotropin release from hemipituitaries was relatively stable and reproducible. Absolute levels of LH and FSH release evoked by HE in terms of their GnRH content were always greater than those following exposure to synthetic GnRH at varying doses. Synthetic GnRH released more FSH than LH. In contrast, the HE released slightly higher levels of LH than FSH. The data suggest that the female rat hypothalamus contains substances other than GnRH, capable of releasing both LH and FSH. It is possible that such unidentified components can modify the hypophysial action of GnRH, resulting in particular circumstances in a differential release of LH and FSH.     

Progesterone stimulation of in vitro GnRH release from the hypothalamus of the estrogen-primed, ovariectomized rat: serotoninergic role

The ability of ovarian steroids to affect luteinizing hormone secretion is closely related to the influence of these steroids on the activities of several neurotransmitter systems within specific areas of the hypothalamus and associated brain areas. The purpose of this study was to characterize in vitro progestagenic effects on serotonin (5-hydroxytryptamine, 5-HT) and gonadotropin-releasing hormone (GnRH) release from hypothalamic slices from estrogen-primed, ovariectomized rats. Results of this study show that (1) progesterone can stimulate in vitro GnRH and 5-HT release from hypothalamic tissue slices of ovariectomized rats primed with estrogen and (2) the 5-HT receptor antagonist mianserin blocks the ability of progesterone to augment in vitro GnRH release from these tissue slices. This suggests that the influence of progesterone on the estrogen-induced LH surge is, at least in part, via progestagenic release of 5-HT and the subsequent effect of this neurotransmitter on the release of GnRH within the hypothalamus.     

No evidence for pituitary priming to gonadotropin-releasing hormone in relation to luteinizing hormone (LH) secretion prior to the preovulatory LH surge in ewes

The purpose of this study was to determine the occurrence of and the regulatory mechanisms involved in priming of the pituitary to GnRH before the preovulatory LH surge in sheep. Experiment 1: Forty-two ewes had progestagen devices removed after 14 days and were assigned to luteal (Lut) or follicular (Foll) groups. Fifteen days later, blood sampling was initiated either immediately or 36 h after induced luteolysis in groups Lut and Foll, respectively. After 4 h, ewes were administered either saline (n = 5) or 250 ng (n = 8) or 10 microg (n = 8) of GnRH. Five ewes per treatment group were killed 1 h later, while remaining animals were blood sampled for a further 7 h. Experiment 2: Eighteen ewes were allocated to Lut and Foll groups (described above). Blood samples were collected from 2 h before GnRH (10 microg) treatment until 7 h after. Despite up-regulated GnRH-R mRNA levels in Foll ewes, pituitary content and plasma levels of LH and LHbeta mRNA levels were similar between groups. Mean FSHbeta mRNA and plasma FSH levels were elevated in Lut ewes but declined after GnRH treatment. Inversely, plasma estradiol and inhibin-A concentrations were higher in Foll ewes and declined after GnRH treatment. Fewer LH(+ve)/secretogranin II(-ve) (SgII(-ve)) granules were present in gonadotropes of Foll ewes, coincident with increased basal LH levels. Fewer smaller sized granules were present after GnRH treatment. In conclusion, there was no evidence of self-priming before onset of the preovulatory LH surge. Constitutive release of LH(+ve)/SgII(-ve) granules may maintain basal LH levels while smaller sized, presumably mature granules may be preferentially released after GnRH stimulation.     

Effect of inhibin from primate Sertoli cells and GnRH on gonadotropin subunit mRNA in rat pituitary cell cultures

Partially purified inhibin from primate Sertoli cell culture medium (pSCl) suppresses both LH and FSH secretion from cultured rat pituitary cells stimulated with GnRH. To examine the mechanism of action of pSCl, we have measured steady state levels of mRNAs for the gonadotropin subunits in pituitary cell cultures exposed to 10 nM GnRH for 6 h in control or pSCl-containing medium (short term) and after 72-h pretreatment with pSCl or control medium (long term). Messenger RNA levels were determined by Northern analysis using specific cDNA probes for rat FSH beta, LH beta, and the common alpha-subunit. In the long term experiments, pSCl inhibited GnRH-stimulated release of FSH (47.4 +/- 3.3% of control), LH (69.2 +/- 2.3%), and free glycoprotein alpha-subunit (74.2 +/- 4.5%), and intracellular FSH declined to 88.4 +/- 3.5% of control. Concentrations of the subunit mRNAs were all decreased: FSH beta to 54.4 +/- 5.0%, LH beta to 79.6 +/- 9.4%, and alpha to 70.8 +/- 8.7% of control. In the short-term experiments, pSCl also suppressed FSH, LH, and alpha-subunit secretion to 75.9 +/- 3.6%, 79.5 +/- 2.1%, and 90.9 +/- 1.8% of control, respectively. Intracellular LH and alpha-subunit levels were significantly increased in cells treated for 6 h with GnRH and pSCl (155 +/- 18%, 145 +/- 14% of control), while FSH was comparable to control. After 6 h, pSCl selectively reduced the level of mRNA for FSH beta (56.5 +/- 5.8% of control).(ABSTRACT TRUNCATED AT 250 WORDS)     

The regulatory mechanism of neuromedin S on luteinizing hormone in pigs

Neuromedin S (NMS) has been implicated in the regulation of luteinizing hormone (LH) secretion. However, the regulatory mechanism of NMS on LH in pigs remains unexplored. In the present study, we confirmed the hypothesis that the effect of NMS on LH could be mediated via hypothalamic melanocyte-stimulating hormones (MSH) neurons of ovariectomized pigs. In an immunohistological experiment, NMS receptor NMU2R-positive neurons were found in the paraventricular nucleus of hypothalamus, widely distributed in the anterior pituitary, and sparsely observed in the posterior pituitary. We also found that serum LH level was declined at between 12 and 60 min with the lowest level at 24 min after NMS injection. The decreased LH secretion induced by NMS could be completely abolished by pretreatment with melanocortin receptor-4 antagonist SHU9119, while a signal injection of 1.0 nM SHU9119 per se did not affect the serum LH level. Real time quantitative RT-PCR results showed that the expression of GnRH and LH mRNAs were down-regulated by NMS treatment, but their reduction was restored to normal level by SHU9119 treatments. The expression of NMU2R and PR mRNAs were up-regulated by NMS treatment, but their effects were blocked by SHU9119 treatments. The expression of the estrogen receptor mRNA in the pig hypothalamus and pituitary was unchanged under the NMS and SHU9119+NMS treatments. In summary, all results suggest that the inhibitory effect of NMS on LH is at least in part through its receptor NMU2R and mediated via MSH neurons in hypothalamus-pituitary axis of ovariectomized pigs.     

Pituitary luteinizing hormone responses to single doses of exogenous GnRH in female social Cape ground squirrels exhibiting low reproductive skew

The Cape ground squirrel Xerus inauris is unusual among social mammals as it exhibits a low reproductive skew, being a facultative plural breeder with not all females breeding within a group. We investigated pituitary function to assess whether there was reproductive inhibition at the level of the pituitary and potentially the hypothalamus in breeding and non-breeding female Cape ground squirrels. We did so during the summer and winter periods by measuring luteinizing hormone (LH) responses to single doses of 2 g exogenous gonadotropin-releasing hormone (GnRH) and physiological saline administered to 42 females from 11 colonies. Basal LH concentrations of females increased in response to the GnRH challenge. Basal plasma LH concentrations were greater during winter, when most oestrus events are observed. However, we found no differences in plasma LH concentrations between breeding and non-breeding females. We showed that the anterior pituitary of non-breeding female ground squirrels is no less sensitive to exogenously administered GnRH than that of breeding females. We therefore concluded that the pituitary is no more active in breeding than non-breeding females. The lack of differentiation in response to GnRH suggests that either non-breeding females have ovaries that are less sensitive to LH or that they refrain from sexual activity with males through an alternative mechanism of self-restraint.