Stage Master 2 - Equipe "Central Nervous system: from regeneration to repair"
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Stage / Eq H.Nawabi
Objectifs
The project aims to characterize the molecular and cellular mechanisms regulating the brain development during mammalian and human embryogenesis. More specifically, we focus on the development of the cerebral cortex to shed light on the etiology of neurodevelopmental disorders.
Résumé
The cerebral cortex is a six-layered brain structure that ensures higher motor, sensory and cognitive functions. Its laminar organization reflects the fine regulation of developmental processes which, if altered, can lead to malformations of cortical development. These malformations are associated with clinical manifestations combining intellectual and/or motor deficits. Therefore, understanding how the cortex develops in utero is a sine qua non condition for deciphering neurodevelopmental disorders and their associated pathophysiological mechanisms. The cortical layers, holding a well-defined number and subtype of excitatory neurons, arise the sequential differentiation of progenitors into neurons that subsequently migrate to reach their final location. Using a combination of multi-scale approaches, we aim to study the developmental mechanisms that regulate the acquisition of neuronal identity and the orderly build-up of cortex with a special focus on crosstalk between the different cell types populating the developing cortex.
Méthodes
Murine lines (crossing, genotyping), confocal microscopy, primary culture (embryonic brain slices, cortical neuroprogenitor cells), histology (embryonic and post-natal brain sections), immunohistochemistry and immunocytochemistry, molecular biology techniques.
Références
Wennagel D, et al. Huntingtin coordinates dendritic spine morphology and function through cofilin-mediated control of the actin cytoskeleton. Cell Rep. (2022). 40(9):111261.
Barnat M, et al.. Huntington's disease alters human neurodevelopment. Science (2020). 369(6505):787-793.
Barnat M, et al. Huntingtin-mediated multipolar-bipolar transition of newborn cortical neurons is critical for their postnatal neuronal morphology. Neuron (2017). 93(1):99-114.
Domaines d'expertise requis
Neurobiology, Cortical development, Cellular biology, Cell adhesion and dynamics, Molecular biology
Contact
Monia BARNAT, CR Inserm
Email : monia.barnat
univ-grenoble-alpes.fr (monia[dot]barnat[at]univ-grenoble-alpes[dot]fr)
Téléchargement
Offre de stage M2 2026-2027 (PDF, 146.18 Ko)
Venir au GIN
Contacts
Pour les stages (master, licence, 3ème), envoyer directement un email au responsable de l'équipe que vous avez identifiée.
Pour une candidature spontanée pour un emploi, utilisez le formulaire de contact.
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