GnRH regulates the reproductive system by stimulating synthesis and release of gonadotropins. GnRH acts through a receptor coupled to multiple intracellular events including a rapid phosphoinositide turnover. Although the cAMP pathway is essential for gonadotrope function, the ability of GnRH to induce cAMP, as well as the coupling mechanisms involved, remain controversial. In this study, we established that GnRH increases intracellular cAMP levels in a concentration-dependent manner in LbetaT2 gonadotrope cells (maximal increase, 2.5-fold; EC(50), 0.30 nm), and this was further evidenced by GnRH activation of a cAMP-sensitive reporter gene. The GnRH effect was Ca(2+) independent, mimicked by the phorbol ester phorbol 12-myristate 13-acetate, and blocked by the protein kinase C (PKC) inhibitor bisindolylmaleimide, indicating that the GnRH effect was mediated by PKC. Pharmacological inhibition of conventional PKC isoforms with Gö6976 did not prevent GnRH-induced cAMP production, whereas down-regulation of novel PKCdelta, -epsilon, and -theta by a long-term treatment with GnRH markedly reduced it. Expression of dominant-negative (DN) mutants of PKCdelta or -epsilon but not PKCtheta impaired GnRH activation of a cAMP-sensitive promoter, demonstrating that PKCdelta and -epsilon are the two endogenous isoforms mediating GnRH activation of the adenylyl cyclase (AC) pathway in LbetaT2 cells. Accordingly, we identified by RT-PCR and immunocytochemical analysis, two PKC-sensitive AC isoforms, i.e. AC5 and AC7 as potential targets for GnRH. Lastly, we showed that only sustained stimulation of GnRH receptor significantly increased cAMP, suggesting that in vivo, the cAMP signaling pathway may be selectively recruited under intense GnRH release such as the preovulatory GnRH surge.
Previous studies dealing with the mechanisms underlying the tissue-specific and regulated expression of the GnRH receptor (GnRH-R) gene led us to define several cis-acting regulatory sequences in the rat GnRH-R gene promoter. These include functional sites for steroidogenic factor 1, activator protein 1, and motifs related to GATA and LIM homeodomain response elements as demonstrated primarily in transient transfection assays in mouse gonadotrope-derived cell lines. To understand these mechanisms in more depth, we generated transgenic mice bearing the 3.3-kb rat GnRH-R promoter linked to the human placental alkaline phosphatase reporter gene. Here we show that the rat GnRH-R promoter drives the expression of the reporter gene in pituitary cells expressing the LHbeta and/or FSHbeta subunit but not in TSHbeta- or GH-positive cells. Furthermore, the spatial and temporal pattern of the transgene expression during the development of the pituitary was compatible with that characterizing the emergence of the gonadotrope lineage. In particular, transgene expression is colocalized with the expression of the glycoprotein hormone alpha-subunit at embryonic day 13.5 and with that of steroidogenic factor 1 at later stages of pituitary development. Transgene expression was also found in specific brain areas, such as the lateral septum and the hippocampus. A single promoter is thus capable of directing transcription in highly diverse tissues, raising the question of the different combinations of transcription factors that lead to such a multiple, but nevertheless cell-specific, expressions of the GnRH-R gene.
GnRH plays a key role in the vertebrate reproductive system by stimulating biosynthesis and secretion of pituitary gonadotropins. However, the potential involvement of microRNAs (miRNAs) on this activation has still to be explored. In this study, we investigated the role of miRNA-132 and miRNA-212, two tandemly expressed miRNAs that target the same transcripts, on GnRH-induced FSH expression. We first showed that the GnRH stimulation of FSH secretion was reduced and Fshb mRNA abolished by blocking miR-132/212 action in rat pituitary cells. In mouse LβT2 gonadotrope cells, the GnRH stimulation of Fshb mRNA was also demonstrated to be dependent on miR-132/212 and reproduced by overexpressing one or both miRNAs. We then showed that the miR-132/212-mediated action of GnRH involved a posttranscriptional decrease of sirtuin 1 (SIRT1) deacetylase. The lower level of SIRT1 deacetylase correlated with an increase in the acetylated form of Forkhead Box O1 (FOXO1), a transcriptional repressor of Fshb. Interestingly, we show that the acetylated mimicking mutant of FOXO1 was localized outside the nucleus, thus alleviating its repressive effect on Fshb transcription. Overall, we demonstrate that the GnRH stimulation of Fshb expression is dependent on miR-132/212 and involves a SIRT1-FOXO1 pathway. This is the first demonstration of an obligatory microRNA pathway in the GnRH-regulated expression of a gonadotropin gene.
Specific type I receptors for pituitary adenylate cyclase-activating polypeptide (PACAP) are present in gonadotrope cells of the anterior pituitary gland. By transient transfection of mouse gonadotrope-derived ␣T3-1 cells, which are direct targets for PACAP and express gonadotropin-releasing hormone receptor (GnRH-R), a marker of the gonadotrope lineage, we provide the first evidence that PACAP stimulates rat GnRH-R gene promoter activity. The EC 50 of this stimulation is compatible with a mediation via activation of the cyclic AMP-dependent signaling pathway and, consistently, co-transfection of an expression vector expressing the protein kinase A inhibitor causes reduction in PACAP as well as cholera toxin-stimulated promoter activity. Deletion and mutational analyses indicate that PACAP activation necessitates a bipartite response element that consists of a first region (؊272/؊237) termed PACAP response element (PARE) I that includes a steroidogenic factor-1 (SF-1)-binding site and a second region (؊136/ ؊101) referred to as PARE II that contains an imperfect cyclic AMP response element. Gel shift experiments indicate the specific binding of the SF-1 and a potential SF-1-interacting factor to PARE I while a protein immunologically related to the cyclic AMP response elementbinding protein interacts with PARE II. These findings suggest that PACAP might regulate the GnRH-R gene at the transcriptional level, providing novel insights into the regulation of pituitary-specific genes by hypothalamic hypophysiotropic signals.The hypothalamic neuropeptide gonadotropin-releasing hormone stimulates the synthesis and release of gonadotropins, luteinizing hormone, and follicle-stimulating hormone, acting through a specific membrane receptor belonging to the family of heptahelical G protein-coupled receptors. The pituitary gonadotropins then enter the systemic circulation to regulate gonadal function, including steroid hormone synthesis and gametogenesis. The responsiveness of gonadotrope cells to GnRH 1 is dependent on the number of cell surface GnRH-R, and changes in the number of these receptors often correlate with changes in the level of receptor mRNA (1-3). To investigate this issue at the transcriptional level, namely the tissuespecific and regulated expression of the GnRH-R gene, the promoter regions of the mouse, rat, human, and ovine genes have been isolated and characterized (4 -8).Transient transfection assays in the mouse gonadotropederived ␣T3-1 cell line have provided evidence that gonadotrope-specific activity of the mouse promoter is mediated by a tripartite basal enhancer that includes an SF-1-binding site, a consensus AP-1 element, and a novel element termed GnRH-R-activating sequence (GRAS) (9). Similarly, the interaction of SF-1 with a gonadotrope-specific element motif in the human gene has been shown to mediate gonadotrope-specific expression (10). Regarding the rat promoter, we and others have reported that full gonadotrope specific activity required a distal regulatory domain in addition to the SF-1...
-Normal gametogenesis and steroidogenesis is highly dependent on the pulsatile release of hypothalamic GnRH that binds high-affinity receptors present at the surface of pituitary gonadotrophs thereby triggering the synthesis and release of the gonadotropins LH and FSH. The mammalian GnRH receptor displays the classical heptahelical structure of G protein-coupled receptors with, however, a unique feature, the lack of a C-terminal tail. Accordingly, it does not desensitise sensu stricto, and internalises very poorly. It is now well established that GnRH stimulation induces the activation of a complex network of transduction pathways involved in the control of gonadotropin release and subunit gene expression. Other authors and ourselves have demonstrated that the GnRH action is associated with an increased complexity regarding gene regulation/cell function. Indeed GnRH affects the GnRH receptor gene itself and a number of additional genes that include some involved in cell signalling and auto-/paracrine regulation. The fact that GnRH regulates the expression of its own receptor, together with a host of other genes typically involved in its signal transduction cascades implies alteration/auto-adaptation in gonadotropic responsiveness. Furthermore, some of these genes respond differentially depending on whether the GnRH stimulation is intermittent or permanent suggesting specific roles in the dual process of activation/desensitisation. Thus, it can be assumed that the importance of pulsatility of GnRH action is closely related to, or dependent on, the inability of the GnRH receptor to desensitise. Moreover, multiple post-receptor events are crucial for both the regulation/plasticity of gonadotropic function and the maintenance of cell integrity.
In the pituitary of mammals, the GnRH receptor (GnRHR) plays a primary role in the control of reproductive function. It is further expressed in the hippocampus, where its function, however, is not well defined. By quantitative RT-PCR analyses, we demonstrate herein that the onset of GnRHR gene (Gnrhr) expression in the rat hippocampus was unexpectedly delayed as compared to the pituitary and only occurred after birth. Using a previously described transgenic mouse model bearing the human placental alkaline phosphatase reporter gene under the control of the rat Gnrhr promoter, we established a positive correlation between the temporal pattern of Gnrhr mRNA levels and promoter activity in the hippocampal formation. The gradual appearance of human placental alkaline phosphatase transgene expression occurred simultaneously in the hippocampus and interconnected structures such as the lateral septum and the amygdala, coinciding with the establishment of hippocampo-septal projections. Analysis of transcription factors together with transient transfection assays in hippocampal neurons indicated that the combinatorial code governing the hippocampus-specific expression of the Gnrhr is distinct from the pituitary, likely involving transactivating factors such as NUR77, cyclic AMP response element binding protein, and Finkel-Biskis-Jinkins murine osteosarcoma virus oncogene homolog. A silencing transcription factor acting via the -3255/-1135 promoter region of the Gnrhr may be responsible for the transcriptional repression observed around birth. Finally, GnRH directly stimulated via activation of its receptor the expression of several marker genes of neuronal plasticity such as Egr1, synaptophysin, and spinophilin in hippocampal primary cultures, suggesting a role for GnRHR in neuronal plasticity. Further characterization of these mechanisms may help unravel important functions of GnRH/GnRHR signaling in the brain.
Nitric-oxide synthase type I (NOS I) is expressed primarily in gonadotrophs and in folliculo-stellate cells of the anterior pituitary. In gonadotrophs, the expression and the activity of NOS I are stimulated by gonadotropin-releasing hormone (GnRH) under both experimental and physiological conditions. In the present study, we show that pituitary adenylate cyclase-activating polypeptide (PACAP) is twice as potent as GnRH at increasing NOS I levels in cultured rat anterior pituitary cells. The action of PACAP is detectable after 4 -6 h and maximal at 24 h, this effect is mimicked by 8-bromocAMP and cholera toxin and suppressed by H89 suggesting a mediation through the cAMP pathway. Surprisingly, NADPH diaphorase staining revealed that these changes occurred in gonadotrophs exclusively although PACAP and cAMP, in contrast to GnRH, have the potential to target several types of pituitary cells including folliculo-stellate cells. There was no measurable alteration in NOS I mRNA levels after cAMP or PACAP induction. PACAP also stimulated cGMP synthesis, which was maximal within 15 min and independent of cAMP, however, only part resulted from NOS I/soluble guanylate cyclase activation implying that in contrast to GnRH, PACAP has a dual mechanism in cGMP production. Interestingly, induction of NOS I by PACAP markedly enhanced the capacity of gonadotrophs to produce cGMP in response to GnRH. The fact that PACAP may act on gonadotrophs to alter NOS I levels, generate cGMP, and potentiate the cGMP response to GnRH, suggests that cGMP could play important cellular functions.
TRH induces two separate events in pituitary PRL cells. It increases the release of stored PRL and enhances the rate of PRL gene transcription, which results in an increased steady state concentration of PRL messenger RNA (mRNA) and a concomitant augmentation of PRL production. The mechanisms underlying the release process involve the activation of phosphatidylinositol turnover which generates inositol 1,4,5-trisphosphate and 1,2-diacylglycerol. In order to determine whether these intracellular messengers also mediate the stimulation of PRL gene expression by TRH, we have correlated the level of receptor occupancy with the rate of gene transcription and investigated the action of drugs which increase cytosolic calcium or activate protein kinase C. We have determined that sustained stimulation of transcription requires the persistent occupancy of a limited number of TRH receptor sites and that the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA), calcium ionophores (A23187, ionomycin), and the calcium channel agonist BAY K 8644 enhance PRL gene transcription. However, TPA is less potent and ionomycin requires a low concentration of TPA to fully mimic TRH action, whereas BAY K 8644 alone displays the same potency as TRH. The effects of BAY K 8644 and TRH are not additive and thus suggest that the influx of calcium plays a predominant role in the regulation of PRL gene transcription by TRH.
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