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GABA-b receptors and calcium homeostasis in medullo-spinal CSF-contacting neurons / Récepteurs GABA-b et homéostasie calcique dans les neurones qui contactent le LCR médullo-spinalJurcic, Nina 20 May 2019 (has links)
Au niveau du canal central (CC) du tronc cérébral et de la moelle épinière, on trouve des neurones au contact avec le liquide céphalorachidien (Nc-LCR). Les Nc-LCR sont GABAergiques et projettent une seule dendrite dans le CC qui se termine par une large protrusion. Ils expriment sélectivement le canal PKD2L1 pour lequel des fonctions de chimio- et mécanorécepteur ont été démontrées. Compte tenu de leur localisation, de leur morphologie et de l’expression sélective de PKD2L1, les Nc-LCR représenteraient une nouvelle population de neurones sensoriels dans le SNC. Au cours de ma thèse, je me suis concentrée sur la caractérisation des canaux Ca2+ et les mécanismes de signalisation Ca2+ dans les Nc-LCR bulbo-spinaux de souris. Je rapporte que les Nc-LCR expriment des canaux Ca2+ qui sont modulés par les récepteurs métabotropiques GABAB et muscarinique. Je montre aussi l'implication des stocks intracellulaires dans la régulation du Ca2+ intracellulaire. Ensuite, je démontre pour la première fois la relation fonctionnelle entre la protrusion et le soma et indique que la protrusion serait dépourvu de conductance ionique active. Enfin, pour aborder le rôle des Nc-LCR, j'ai développé des modèles chimiogénétiques (DREADDs) et optogénétiques (channelrhodopsin) chez la souris afin de manipuler sélectivement l'activité Nc-LCR. Dans l'ensemble, les résultats de mon étude de doctorat contribuent à mieux comprendre les Nc-LCR bulbo-spinaux des mammifères en en contribuant à la caractérisation de leur physiologie et modulation. Ils ouvrent également la voie à de futures études qui permettront de démontrer le rôle de cette population neuronale dans la régulation de l'activité du SNC. / Cerebrospinal fluid-contacting neurons (CSF-cNs) located in the ependymal region around the central canal (CC) in the brainstem and the spinal cord are GABAergic neurons that project a single dendrite to the CSF and ends with a large protrusion. They selectively express PKD2L1 channel suggested to act as chemo- and mechanoreceptor. Considering their localization, morphology and selective expression of PKD2L1 channel, CSF-cNs would represent a novel population of sensory neurons within the CNS. To better understand the role of CSF-cNs in mammals, it is necessary to describe the physiological properties and modulation of CFS-cNs. In the present study, I focused on Ca2+ channels and Ca2+ signaling mechanisms in mouse medullo-spinal CSF-cNs. I report that Ca2+ channels in CSF-cNs undergo modulation by metabotropic GABAB and muscarinic acetylcholine receptors. I further show the involvement of intracellular Ca2+ stores in the regulation of intracellular Ca2+. Next, I demonstrate for the first time functional relationship between bud and soma and indicate that the bud would be devoid of active ionic conductance. Finally, to address the role of CSF-cNs, I developed chemogenetic (DREADDs) and optogenetic (channelrhodopsin) mice models to be able to selectively manipulate CSF-cN activity. Altogether, the results of my PhD study contribute to better understanding mammalian medullo-spinal CSF-cNs by providing valuable information on their physiology and modulation. They also set ground for further studies carried out in ex-vivo preparation or in vivo models to demonstrate their role in the regulation of CNS activity.
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Neuron-glial Interaction in the Developing Peripheral Nervous SystemCorell, Mikael January 2011 (has links)
The nervous system, including the brain, is the most sophisticated organ in the mammalian body. In such a complex network, neuron-glial interaction is essential and controls most developmental processes, such as stem cell fate determination, migration, differentiation, synapse formation, ensheathment and myelination. Many of these events are critical for the developmental process and small errors can lead to growth retardation, malformation or disease. The understanding of the normal progress of nervous system development is fundamental and will help the discovery of new treatments for disease. This thesis discusses three types of neuron-glia interactions at different developmental stages; neural stem/progenitor cell (NSPC) differentiation, building and maintaining the structure of the sciatic nerve, and myelin formation. In Paper I we show that NSPCs, based upon their morphology and expression of specific protein markers, have the capacity to differentiate into cells of either the peripheral nervous system (PNS) or enteric nervous system (ENS) when grown with PNS or ENS primary cell cultures, or fed with conditioned medium from these. This indicates that soluble factors secreted from the PNS or ENS cultures are important for stem cell differentiation and fate determination. The adhesion protein neuronal cadherin (N-cadherin) is implicated in migration, differentiation and nerve outgrowth in the developing PNS. In Paper II N-cadherin was exclusively found in ensheathing glia (nonmyelinating Schwann cells, satellite cells and enteric glia) in contact with each other or with axons. Functional blocking of N-cadherin in dissociated fetal dorsal root ganglia (DRG) cultures led to a decrease in attachment between Schwann cells. N-cadherin-mediated adhesion of nonmyelinating Schwann cells may be important in encapsulating thin calibre axons and provide support to myelinating Schwann cells. In Paper III the inhibitory gamma aminobutyric acid (GABA) and GABAB receptors were studied in the Schwann cell of the adult sciatic nerve and DRG cultures. GABAB receptors were primarily expressed in nonmyelinating Schwann cells and protein levels decreased during development and myelination. Blocking the GABAB receptor in long-term DRG cultures led to decreased levels of mRNA markers for myelin. These results indicate that the GABA and GABAB receptors may be involved in Schwann cell myelination.
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