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Brain control of reproductive aging : GnRH neuroterminal, glia and portal capillary interactionsYin, Weiling 05 May 2015 (has links)
Reproductive function is essential to the survival of all species. In mammals and other vertebrates, the control of reproduction relies on the hypothalamic-pituitary-gonadal axis, with the primary driving force provided by hypothalamic GnRH neurons. In the median eminence, the decapeptide GnRH are released in a unique pattern from GnRH neuroterminals into the portal capillary system as part of reproductive cycle. During aging, the biological rhythms of GnRH release are altered in a species-specific manner, with a reduction of GnRH pulsatility and surge in aging female rats resulting in reproductive senescence, which happens much earlier than gonadal failure in rats. Relatively few studies have focused on regulation of GnRH release at the neuroterminal level in the median eminence during reproductive aging. Therefore, the aims of this dissertation are to 1) Study the regulation of GnRH secretion at the neuroterminal level, focusing on glutamate transmission; 2) Ascertain the interaction between GnRH neuroterminals and their surrounding microenvironment focused on glial cells and the portal capillary system in the median eminence; and 3) Analyze age and hormone effects on GnRH neuroterminals and their microenvironment. An aging ovariectomized female rat model was used to study the effects of age and hormones on GnRH neuroterminal system. Fluorescence microscopy, confocal microscopy and transmission electron microscopy were used in conjunction with several imaging analysis tools. I mastered the use of cryo-embedding multi-probe immunogold labeling electron microscopy, which was essential to visualize and quantify the ultrastructral changes in GnRH neuroterminals. I combined the serial electron microscopy with cryo-embedding immunogold electron microscopy preparation and developed a new technique to examine biological markers with a three-dimensional perspective at the cellular level. Results from a series of four research projects showed: 1) There is a novel glutermatergic pathway in GnRH neuroterminals, which may regulate GnRH secretion; 2) There are dramatic age related morphological changes in the GnRH neuroterminal /glia/ portal capillary system of the median eminence that may be involved in reproductive senescence and other neuroendocrine system impairments with age; 3) Serial electron microscopy combined with immunogold labeling technique is a useful method to study the regulation of neuronal signaling pathway. Although my studies were performed on a rat model, it seems reasonable to predict that some of these changes in the median eminence with age may apply to other species, including humans, relevant to some of the menopausal symptoms in women. / text
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Molecular characterization of NO-synthesizing neurons and assessment of their function in the maturation of the hypothalamic - pituitary - gonadal axis / Caractérisation moléculaire des neurones á nNOS et évaluation de leur rôle dans la maturation de l'axe hypothalamique impliqué dans la fonction de reproductionChachlaki, Konstantina 19 December 2016 (has links)
L’apparition de la puberté et la régulation de la fertilité chez les mammifères sont contrôlées par un réseau neuronal complexe, situé principalement dans l'hypothalamus, et qui converge vers les neurones synthétisant l'hormone de libération des gonadotrophines (GnRH). Ces neurones régulent la sécrétion des gonadotrophines, la croissance et le fonctionnement des gonades. Le développement correct du système à GnRH, incluant des changements rapides dans l'expression et la signalisation de l’hormone GnRH au sein de cette population clairsemée de quelques centaines de neurones, est essentiel pour la maturation sexuelle et le fonctionnement normal de l'axe hypothalamo-hypophyso-gonadique. Lors du développement embryonnaire, ces neurones migrent de la placode olfactive vers leur emplacement définitif, l’hypothalamus, pour y recevoir les connexions afférentes qui permettront une libération pulsatile de la GnRH et la libération subséquente des gonadotrophines (l'hormone de stimulation des follicules (FSH) et l'hormone lutéinisante (LH)). Dès les années 90, l'oxyde nitrique (NO) a été identifié comme molécule clé dans la décharge pré-ovulatoire de GnRH/LH. En effet, de nombreux travaux ont suggéré que des interactions entre les neurones exprimant la forme neuronale de l’enzyme de synthèse du NO (la nNOS) et le système GnRH étaient impliquées dans le contrôle central de la fonction de reproduction à l'âge adulte. De plus, si le NO est reconnu depuis longtemps comme un acteur majeur du contrôle central de l’ovulation à l’âge adulte, la possibilité qu’il soit aussi impliqué dans la maturation sexuelle en régulant l’activité des neurones à GnRH à des stades précoces précédant la puberté n’a pas été explorée auparavant. Cependant, même si nous avons progressé dans la connaissance des interactions entre les neurones à nNOS et des différents acteurs importants de l’axe gonadotrope, l’identité moléculaire de ces neurones reste mal connue. Au cours de cette étude, nous avons recherché 1) l'identité moléculaire des neurones á nNOS dans l'hypothalamus au cours de développement 2) si le NO régule la migration et l’intégration des neurones à GnRH dans l’hypothalamus et 3) si le NO régule la maturation sexuelle. Pendant ma thèse nous avons répertorié pour la première fois les différents neurotransmetteurs et les principaux récepteurs dans les neurones à nNOS au cours du développement post-natal. De plus, les résultats de ma thèse montrent pour la première fois une implication de la signalisation du NO dans la migration des neurones à GnRH vers l'hypothalamus et font échos à l'identification d'une série de mutations de la NOS1 chez des patients atteints du syndrome de Kallmann, une maladie génétique congénitale rare qui associe une carence en GnRH, due à un défaut de migration neuronale, et une anosmie. Enfin, mes travaux montrent que le NO est un nouveau protagoniste dans la maturation post-natale du système à GnRH, la survenue de la puberté et l’acquisition de la capacité à se reproduire. Plus généralement, les résultats de ce travail de thèse permettent d’identifier de nouveaux mécanismes potentiellement responsables de troubles développementaux dans la mise en place des circuits neuronaux contrôlant l’axe gonadotrope chez les mammifères en général et l’homme en particulier. Nous espérons que ces résultats élargiront notre compréhension de la régulation de l'axe reproducteur, offrant ainsi des possibilités nouvelles de stratégies thérapeutiques contre les troubles de la fertilité. / The onset of puberty and the regulation of fertility in mammals are governed by a complex neural network, primarily in the hypothalamus, that converges onto gonadotropin-releasing hormone (GnRH)-producing neurons, the master regulators of gonadotropin secretion and postnatal gonadal growth and function. The proper development of the GnRH system, including timely changes in GnRH expression and signaling by this sparse population of a few hundred neurons, is essential for sexual maturation and the normal functioning of the hypothalamic-pituitary-gonadal axis. As the brain develops during embryogenesis, these neurons should move from the olfactory placode into the correct brain location in adequate numbers, and then establish the afferent connections that will allow the pulsatile release of GnRH peptide, and the subsequent release of the gonadotropins (follicle stimulating hormone, i.e FSH and luteinizing hormone, ie. LH). As early as in the 90’s NO was presented as a key molecule in the preovulatory GnRH/LH surge, and results from different groups, have suggested the interaction of NOS-containing neurons with the GnRH system, and their involvement in the regulation of reproductive capacity. Even though nitric oxide has now been long recognized as a key player in the central hormonal regulation of ovulation during adulthood, no one has considered the possibility that it could act in an earlier stage as the master regulator of GnRH neurons before puberty, hence participating in the actual maturation of the neuroendocrine axis. The relationship of nNOS-expressing neurons with other important molecules of the hypothalamic axis has been well studied, whilst the molecular identity of this neuronal NOS-expressing population is poorly documented. . To this end, we address the hitherto unaddressed questions concerning 1) the molecular identity of nNOS-expressing neurons in the developing hypothalamus, 2) the putative involvement of the NO molecule in the migration of GnRH neurons and the proper establishment of their afferent connections in the hypothalamic region and 3) the plausible determinant role of NO signaling in the maturation of the reproductive system. During this study we identified for the first time the cohort of the principal neurotransmitters and important receptors expressed by these cells in the hypothalamic region during development. Additionally, our results reveal for the first time an involvement of NO signaling in the migration of GnRH neurons in the hypothalamus and are in line with the identification of a series of NOS1 mutations in Kallmann syndrome (KS), a rare congenital genetic condition presenting a unique combination of GnRH deficiency, arising from a faulty migration of the neuronal population, and anosmia. Lastly, our study identifies NO as a novel protagonist during postnatal development, in the regulation of the onset of puberty and the acquisition of reproductive competence. Overall, the results of my Phd thesis identify putative new targets causing alterations of developmental programming under pathophysiological gestational environment in mammals in general, and in humans in particular. Here we thus provide new insights into the mechanisms by which the alteration of GnRH neuronal function leads to hypogonadotropic hypogonadism and infertility. We are hopeful that our results will expand our understanding of how the neuroendocrine axis is regulated and will possibly provide opportunities for therapeutic strategies against debilitating conditions.
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A Mathematical Model for the Transition in Firing Patterns Across Puberty of a Gonadotropin-Releasing Hormone NeuronBanerjee, Sayanti P. 21 May 2013 (has links)
No description available.
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A Mathematical Model for the Luteinizing Hormone Surge in the Menstrual CycleLiu, Tang-Yu January 2016 (has links)
No description available.
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