Synaptic fluctuations in cerebellar interneurons connected by a single synaptic contact / Fluctuations synaptiques dans interneurones cérébelleux connectées par un contact synaptique unique.

Pulido Puentes, María Camila

11 March 2016

L’élément constitutif des synapses centrales est le site synaptique individuel, comprenant une zone active du côté présynaptique et une densité postsynaptique associée. Du fait de limitations techniques nos connaissances sur le mode de fonctionnement d’un site synaptique restent insuffisantes. Pour faire progresser cette question nous projetons d’effectuer des enregistrements en paires entre interneurones de la couche moléculaire du cervelet. Ces neurones forment des synapses qui ont des signaux élémentaires quantiques de grande taille, et les synapses comprennent parfois un seul site synaptique, ce qui fait qu’ils offrent des avantages décisifs pour ce projet. Les réponses postsynaptiques à des trains de potentiels d’action seront étudiées dans différentes conditions expérimentales. Les résultats seront interprétés par un modèle supposant que les vésicules synaptiques doivent se lier à un petit groupe de sites d’arrimage avant l’exocytose. / The unitary element of central synaptic transmission is a single synaptic site, with one active zone as presynaptic component and the postsynaptic density as postsynaptic partner. Due to technical limitations there is much uncertainty on the mode of functioning of a single synaptic site. To address this issue it is planned to perform paired recordings between interneurons of the molecular layers of the cerebellum. These neurons form synapses with a large quantal size, and occasionally displaying a single release site, and are thus favorable for this study. Postsynaptic responses will be studied in response to trains of presynaptic action potentials under various conditions. The results will be compared to a model supposing the obligatory binding of vesicles to a small complement of docking sites prior to exocytosis.

Docking Sites

Contact synaptique unique

GABAergic interneurons

Docking Sites

Single synaptic contacts

GABAergic interneurons

571.96

Multiple tasks of Glycogen synthase kinase-3beta (GSK-3£] ) and its partners

Lin, Ching-chih

10 September 2007

Glycogen synthase kinase-3 (GSK-3) is a serine/threonine protein kinase which plays a key role in several signaling pathways and its homologues have been identified in most eukaryotes. Since GSK3£]is an essential protein kinase that regulates numerous functions within the cell, an effort to survey possible GSK3£]- interacting proteins from a human testis cDNA library using the yeast two-hybrid system is made. Two interesting candidates are chosen to characterize their functions in this study. One is a centrosomal protein, hNinein, and the other is a novel inhibitor of GSK3£], designated as GSKIP (GSK3£] interaction protein). In the first part of the present thesis we describe the identification of four diverse CCII-termini of human hNinein isoforms, including a novel isoform 6, by differential expression in a tissue-specific manner. In a kinase assay, the CCII region of hNinein isoforms provides a differential phosphorylation site by GSK3£]. In addition, either N-terminal or CCIIZ domain disruption may cause hNinein conformational change which recruits £^-tubulin to centrosomal or non-centrosomal hNinein-containing sites. Further, depletion of all hNinein isoforms caused a significant decrease in the £^-tubulin signal in the centrosome. In domain swapping, it clearly shows that the CCIIX-CCIIY region provides docking sites for £^-tubulin. Moreover, nucleation of microtubules from the centrosome is significantly affected by the overexpression of either the full-length hNinein or CCIIX-CCIIY region. Taken together, these results show that the centrosomal targeting signals of hNinein have a role not only in regulating hNinein conformation, resulting in localization change, but also provide docking sites to recruit £^-tubulin at centrosomal and non-centrosomal sites. In the second part of the thesis we describe another candidate, GSK3£]interaction protein (GSKIP), to characterize its functions in neuron differentiation. We use human neuroblastoma SH-SY5Y cells as a model of neuronal cell differentiation. When overexpression of GSKIP prevents neurite outgrowth from RA-mediated differentiation, this result is similar to the presence of LiCl or SB415286, an inhibitor of GSK3£]. Further, GSKIP regulates the activity of GSK3£] through protein-protein interactions rather than post-modulation and GSKIP may affect GSK3£] on neurite outgrowth via inhibiting the specific phosphorylation site of tau. In addition to inhibition of neurite outgrowth, GSKIP overexpressed in SH-SY5Y cells also promotes cell cycle progression by analyzing cell proliferation with cell growth and MTT assay. Furthermore, GSKIP raises the level of £]-catenin and cyclin D1 through inhibition of GSK3£] activity in RA-mediated differentiation SH-SY5Y cells. Taken together, the data suggest that GSKIP, a dual functional molecule, is able to inhibit neurite outgrowth and promote cell proliferation via negative regulation of GSK3£] activity in RA-mediated differentiation of SH-SY5Y cells.

neurite

Glycogen synthase kinase-3

neuroblastoma

centrosomal protein

GSKIP

gamma-tubulin docking sites