R31C GNRH1 mutation and congenital hypogonadotropic hypogonadism

Normosmic congenital hypogonadotropic hypogonadism (nCHH) is a rare reproductive disease leading to lack of puberty and infertility. Loss-of-function mutations of GNRH1 gene are a very rare cause of autosomal recessive nCHH. R31C GNRH1 is the only missense mutation that affects the conserved GnRH decapeptide sequence. This mutation was identified in a CpG islet in nine nCHH subjects from four unrelated families, giving evidence for a putative “hot spot”. Interestingly, all the nCHH patients carry this mutation in heterozygosis that strikingly contrasts with the recessive inheritance associated with frame shift and non-sense mutations. Therefore, after exclusion of a second genetic event, a comprehensive functional characterization of the mutant R31C GnRH was undertaken. Using different cellular models, we clearly demonstrate a dramatic reduction of the mutant decapeptide capacity to bind GnRH-receptor, to activate MAPK pathway and to trigger inositol phosphate accumulation and intracellular calcium mobilization. In addition it is less able than wild type to induce lh-beta transcription and LH secretion in gonadotrope cells. Finally, the absence of a negative dominance in vitro offers a unique opportunity to discuss the complex in vivo patho-physiology of this form of nCHH

Nanoparticules et fonction de reproduction: Nanoparticules et fonction de reproduction, impact des nanoparticules de noir de carbone sur les fonctions endocrines ovariennes et gonadotropes hypophysaires

L’essor des nanotechnologies entraîne un accroissement de l’exposition des populations aux nanoparticules manufacturées issues de matériaux variés, qui s’ajoutent à celles produites non intentionnellement. Parmi les nanoparticules, celles de noir de carbone sont largement utilisées dans l’industrie (ex. pneumatiques et autres caoutchoucs, plastiques, encres d’imprimerie). Même si leur impact sur la santé nécessite d’être mieux compris, elles ont été associées en particulier à des inflammations du tissu pulmonaire, à des bronchopathies ainsi qu’à un risque accru de cancer pulmonaire. La question traitée dans le projet "NANOVHYP" est la recherche d’une possible action des nanoparticules de noir de carbone sur la fonction de reproduction

Estradiol Signaling at the Heart of Folliculogenesis: Its Potential Deregulation in Human Ovarian Pathologies

International audienceEstradiol (E2) is a major hormone controlling women fertility, in particular folliculogenesis. This steroid, which is locally produced by granulosa cells (GC) within ovarian follicles, controls the development and selection of dominant preovulatory follicles. E2 effects rely on a complex set of nuclear and extra-nuclear signal transduction pathways principally triggered by its nuclear receptors, ER alpha and ER beta. These transcription factors are differentially expressed within follicles, with ER beta being the predominant ER in GC. Several ER beta splice isoforms have been identified and display specific structural features, which greatly complicates the nature of ER beta-mediated E2 signaling. This review aims at providing a concise overview of the main actions of E2 during follicular growth, maturation, and selection in human. It also describes the current understanding of the various roles of ER beta splice isoforms, especially their influence on cell fate. We finally discuss how E2 signaling deregulation could participate in two ovarian pathogeneses characterized by either a follicular arrest, as in polycystic ovary syndrome, or an excess of GC survival and proliferation, leading to granulosa cell tumors. This review emphasizes the need for further research to better understand the molecular basis of E2 signaling throughout folliculogenesis and to improve the efficiency of ovarian-related disease therapies

microARN et inactivation de la fonction gonadotrope hypophysaire

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FSH inhibits AMH to support ovarian estradiol synthesis in infantile mice

International audienceAnti-Mullerian hormone (AMH) regulates ovarian function in cyclic females, notably by preventing premature follicle-stimulating hormone (FSH)-mediated follicular growth and steroidogenesis. Its expression in growing follicles is controlled by FSH and by estradiol (E2). In infantile females, there is a transient increase in the activity of the gonadotrope axis, as reflected by elevated levels of both gonadotropins and E2. We previously demonstrated in mice that elevated FSH concentrations are necessary to induce E2 production by preantral/early antral follicles through the stimulation of aromatase expression without supporting their growth. However, whether this action of FSH could involve AMH is unknown. Here, we show that Amh mRNA and protein abundance and serum AMH levels are elevated in infantile mouse females, compared with those in adults. By experimentally manipulating FSH and E2 levels in infantile mice, we demonstrate that high FSH concentrations lower Amh expression specifically in preantral/early antral follicles, whereas E2 has no effect. Importantly, treatment of infantile ovaries in organotypic cultures with AMH decreases FSH-mediated expression of Cyp19a1 aromatase, but it does not alter the expression of cyclin D2-mediating granulosa cell proliferation. Overall, our data indicate that the infantile elevation in FSH levels suppresses Amh expression in preantral/early antral follicles, thereby favoring Cyp19a1 aromatase expression and E2 production. Together with recent discoveries that AMH can act on both the hypothalamus and the pituitary to increase gonadotropin levels, this work suggests that AMH is a critical regulator of the gonadotrope axis during the infantile period, thereby contributing to adult reproductive function programming

Age-dependent vulnerability of the ovary to AhR-mediated TCDD action before puberty: Evidence from mouse models

International audienceIn female mammals, puberty and fertility are regulated by the synthesis of estradiol (E2) by the ovaries at the infantile stage and at the approach of puberty, a process which may be affected by endocrine disrupting chemicals (EDC)s acting through the Aryl hydrocarbon receptor (AhR). However, there is no information on AhR-mediated regulation of ovarian estrogenic activity during these developmental periods. Here, we assessed in mouse models, the intrinsic and exogenous ligand-induced AhR action on E2 synthesis at the infantile stage (14 days postnatal (dpn)) and at the approach of puberty (28 dpn). Intrinsic AhR pathway became activated in the ovary at the approach of puberty, as suggested by the decreased intra-ovarian expression in prototypical and steroidogenesis-related AhR targets and E2 contents in Ahr knockout (Ahr(-/-)) mice versus Ahr(+/+) mice exclusively at 28 dpn. Accordingly, AhR nuclear localization in granulosa cells, reflecting its activity in cells responsible for E2 synthesis, was much lower at 14 dpn than at 28 dpn in C57BL/6 mice. However, AhR signaling could be activated by exogenous ligands at both ages, as revealed by FICZ- and TCDD-induced Ahrr and Cyp1a1 expression in C57BL/6 mice. Nevertheless, TCDD impacted ovarian estrogenic activity only at 28 dpn. This age-related AhR action may be ligand-dependent, since FICZ had no effect on E2 synthesis at 28 dpn. In conclusion, AhR would not regulate ovarian estrogenic activity before the approach of puberty. Its activation by EDCs may be more detrimental to reproductive health at this stage than during infancy. (C) 2020 Elsevier Ltd. All rights reserved

Antibody against AMH blocks AMH regulatory effect on SF1-mediated StAR and aromatase expression in mouse granulosa cells

Antibody against AMH blocks AMH regulatory effect on SF1-mediated StAR and aromatase expression in mouse granulosa cells . 2. Journées scientifiques GDR 3606 REPRO: ReproSciences 201

Aberrant granulosa cell-fate related to inactivated p53/Rb signaling contributes to granulosa cell tumors and to FOXL2 downregulation in the mouse ovary

International audienceOvarian granulosa cell tumors (GCTs) are indolent tumors of the ovary affecting women at all ages and potentially displaying late recurrence. Even if there is still little information regarding the mechanisms involved in GCT development and progression, FOXL2 would be a major tumor suppressor gene in granulosa cells. We analyzed the mechanisms underlying GCT initiation and progression by using mice with targeted expression of SV40 large T-antigen in granulosa cells (AT mouse), which develop GCTs. Consistent with patients, AT mice with developing GCTs displayed increased levels in circulating anti-Mullerian hormone (AMH), estradiol and androgens, as well as decreased FOXL2 protein abundance. Very few mice developed metastases (1 out of 30). In situ analyses revealed that GCT initiation resulted from both increased granulosa cell survival and proliferation in large antral follicles. Tumorigenesis was associated with the combined inactivation of p53 and Rb pathways, as shown by the impaired expression of respective downstream targets regulating cell apoptosis and proliferation, i.e., Bax, Bak, Gadd45a, Ccna2, Ccne1, E2f1, and Orc1. Importantly, the expression of FOXL2 was still present in newly developed GCTs and its downregulation only started during GCT growth. Collectively, our experiments provide evidence that disrupted p53/Rb signaling can drive tumor initiation and growth. This model challenges the current paradigm that impaired FOXL2 signaling is a major switch of granulosa cell tumorigenesis, albeit possibly contributing to tumor growth

The Goto-Kakizaki rat is a spontaneous prototypical rodent model of polycystic ovary syndrome

International audiencePolycystic ovary syndrome (PCOS) is characterized by an oligo-anovulation, hyperandrogenism and polycystic ovarian morphology combined with major metabolic disturbances. However, despite the high prevalence and the human and economic consequences of this syndrome, its etiology remains unknown. In this study, we show that female Goto-Kakizaki (GK) rats, a type 2 diabetes mellitus model, encapsulate naturally all the reproductive and metabolic hallmarks of lean women with PCOS at puberty and in adulthood. The analysis of their gestation and of their fetuses demonstrates that this PCOS-like phenotype is developmentally programmed. GK rats also develop features of ovarian hyperstimulation syndrome. Lastly, a comparison between GK rats and a cohort of women with PCOS reveals a similar reproductive signature. Thus, this spontaneous rodent model of PCOS represents an original tool for the identification of the mechanisms involved in its pathogenesis and for the development of novel strategies for its treatment