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Studies of Spinal Motor Control Networks in Genetically Modified Mouse ModelsGezelius, Henrik January 2009 (has links)
Spinal neurons are important in several aspects motor control. For example, the neurons essential for locomotor movements reside in the ventral spinal cord. In this thesis, different motor control functions are being related to neuronal populations defined by their common expression of a gene. First, a targeted disruption of the gene for vesicular glutamate transporter 2 (Vglut2/ Slc17a6) is described. The mutant animals die at birth because of their inability to breathe. The neuronal network in the brainstem, responsible for inspiration, was shown to become non-functional by the targeted deletion of Vglut2. To our surprise, it was still possible to induce rhythmic activity with normal left/right alternation in spinal cords isolated from VGLUT2-null embryos. Inconsistent reports of Vglut1 expression in the spinal cord made us re-evaluate the Vglut1 and Vglut2 expressions. While Vglut2 expression was widespread in the spinal cord, Vglut1 expression was restricted to a few cells dorsal to the central canal. Taken together, the data suggest that, glutamatergic signaling is mandatory to drive the bilateral breathing, but not needed for coordination of basal alternating spinal locomotor rhythm. Next, a screen for genes with restricted ventral expression was made. Some of the genes found could be connected to the characteristics of specific neuronal cell populations. For example, fast motor neurons were shown to express the genes Calca and Chodl. Further, we found the Chrna2 expression selectively in putative Renshaw cells. It seems likely that the gene product, the alpha2 subunit of the nicotinergic receptor, could be linked to the unique connection of motor neurons to Renshaw cells. We used the Chrna2 promoter to drive expression of Cre recombinase in a transgenic mouse. The Cre activity was present in most neurons labeled with Renshaw cell markers, which should make it a useful tool for functional studies of this population. The studies presented here show how the genes expressed in subsets of neurons can be used to target populations of neurons for functional studies of neuronal systems.
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Bases moléculaires et cellulaires d’un trouble neurodéveloppemental causé par l’haploinsuffisance de SYNGAP1Berryer, Martin, H 12 1900 (has links)
No description available.
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Interactions synaptiques entre les interneurones de la couche moléculaire du cervelet / Synaptic interactions among interneurons in the molecular layer of the cerebellumAlcami Ayerbe, José 30 April 2013 (has links)
Les interneurones de la couche moléculaire du cervelet (ICM: cellules en panier et cellules étoilées) sont connectés par des synapses électriques fréquentes et puissantes chez les jeunes rats et souris autour de la fin de la deuxième semaine postnatale. Les courants capacitifs des ICM montrent une composante lente qui reflète la charge des interneurones couplés électriquement. Leur analyse permet de quantifier le nombre de cellules directement couplées à une cellule et le nombre équivalent de cellules couplées (Alcami et Marty, soumis), et d'établir une difference de couplage entre les cellules en panier et les cellules étoilées pendant le développement postnatal. Elle a mené à proposer une topologie de réseau des cellules en panier. La force du couplage peut être modulée par les courants intrinsèques, dont Ih dans le domaine hyperpolarisant. Les synapses électriques modifient la propagation et les patrons d'activité dans le réseau des ICM en réponse à une excitation du réseau.L'étude de la connectivité des ICM par des synapses chimiques GABAergiques nous a mené à réexaminer les sources d'erreur des mesures d'activité électrique en configuration cellule attachée (Alcami et coll., 2012). Les mesures en cellule attachée peuvent modifier l'activité électrique des ICM en introduisant un couplage conductif entre la pipette d'enregistrement et l'intérieur cellulaire, résultant d'une combinaison de mécanismes de couplage passifs et actifs. / Molecular layer interneurons of the cerebellum (MLIs: basket cells and stellate cells) are connected by frequent and strong electrical synapses in young rats and mice around the end of the second postnatal week. Capacitive currents of MLIs show a slow component that reflects the charge of electrically-coupled MLIs. The analysis of capacitive currents makes it possible to quantify the number of directly connected cells and the equivalent number of coupled cells (Alcami and Marty, submitted). They were used to show a difference in coupling between basket and stellate cells and propose a model of the basket cell coupled network. Electrical coupling strength can be modulated by intrinsic currents, like the h current in the hyperpolarizing range. Electrical synapses modify the propagation and the patterns of activity in the MLI network, when the network is excited.The study of connectivity of MLIs by chemical GABAergic synapses led us to reevaluate the sources of error of cell-attached recordings (Alcami et al., 2012). Cell-attached measurements can modify cellular electrical activity of MLIs, by introducing a conductif coupling between the recording pipette and the cell interior, resulting from a combination of passive and active coupling.
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