Mobilisation post-lésionnelle des cellules de la zone sous-ventriculaire dans le cerveau adulte : le rôle de la Reeline / Post lesional mobilization of subventricular zone cells in the adult brain : the role of Reelin

Courtès, Sandrine

01 October 2010

La migration des cellules souches / progénitrices neurales (CSPN) dans le cerveau adulte est cruciale pour la réparation cérébrale. Reeline (Rln) est une protéine de la matrice extracellulaire, régulant le positionnement des neurones pendant la croticogénèse. Nous révélons un rôle nouveau de Rln chez l'adulte. In vitro, Rln est chémocinétique mais pas chémoattractante. In vivo, Rln induit le détachement et la dispersion des CSNP de la zone sousventriculaire (SVZ) hors du courant rostral de migration (RMS) où elles sont sinon confinées. Rln potentialise le recrutement spontané des CSPN vers les lésions démyélinisantes où un tiers deviennent oligodendrocytaires. L'expression endogène de Rln est stimulée après lésion. Les animaux sans voie de signalisation Rln ont un recrutement réduit des CSPN vers les lésions.Ces résultats révèlent que Rln est un arbitre clef de la migration post-lésionnelle des CSPN et que permettre au CSPN de sortir du RMS est une stratégie thérapeutique prometteuse. / Neural stem/ progenitor cell (NSPC) migration in the adult brain is crucial for brain repair. Reelin (Rln) is an extracellular matrix protein regulating neuron positioning during coricogenesis. We reveal new roles of Rln in adult NSPC migration. In vitro, Rln promotes detachment, is chemokinetic but not chemoattractant. After Rln ectopic overexpression in the healthly brain, subventricular zone (SVZ) NSPC detach from the rostal migratory stream (RMS) in which they are normally restricted, and disperse in adjacent fiber tracts. Rln over-expression potentiates spontaneous cell recruitment to demyelinated lesion and one third of the NSPC recruited adopt an oligodendrocytic phenotype. Rln expression is spontaneously upregulated after lesion, and disruption of its signaling pathway results in reduced NSPC recruitment toward lesion. Our study reveals that Rln is a key player of post-lesional NSPC migration and that allowing NSPC to escape from RMS is a promising therapeutic approach

Reelin

Zone sous ventriculaire

Lesion

Migration

Adult brain

Endogenous repair

Myelin

Subventricular zone

Rostral Migratory Steam

The Regulation of Adult Neurogenesis by Rb Family Proteins

Fong, Bensun Cambell

02 May 2022

A complex regulatory framework underlies the generation of newborn neurons in the adult mammalian brain, including the lifelong maintenance of neural stem cell (NSC) quiescence and instructing NSC entry to and exit from quiescence. Future therapies targeting endogenous repair of the aging or afflicted brain, including neurodegenerative pathologies, rely on present efforts to define and characterize the mechanisms underlying the regulation of adult NSC fate. In this dissertation, we demonstrate a requirement for the Rb/E2F axis in the regulation of the molecular program instructing adult NSC quiescence and activation, with a potential role in the impaired hippocampal function observed in Alzheimer's disease pathology. While Rb plays a role in the production and survival of hippocampal newborn neurons, we identify a collective requirement for Rb family proteins — pRb, p107 and p130 — as well as their targets, E2F family transcriptional activators E2F1 and E2F3, in the regulation of NSC quiescence and activation. We further demonstrate that this is mediated through pivotal factors REST and ASCL1, identified as direct molecular targets of the Rb/E2F axis, and that REST inactivation can partially rescue NSC depletion following Rb family loss. We finally demonstrate impaired NSC activation and a return to quiescence in the 3xTG-AD model of Alzheimer's disease, with altered expression of Rb/E2F genes observed within cell population-specific defects. Ultimately, this work addresses the key issue of how transcriptional signatures of quiescence and activation among adult NSCs are co- ordinated with cell cycle control, and demonstrates that Rb family proteins serve as master regulators of the molecular program instructing adult NSC exit from and re-entry into quiescence.

NSC

neural stem cell

neurogenesis

adult neurogenesis

neural cell fate

cell fate

Rb family proteins

pocket proteins

quiescence

activation

REST

ASCL1

transcriptional regulation

endogenous repair

Contusive Spinal Cord Injury: Endogenous Responses of Descending Systems and Effects of Acute Transplantion of Glial Restricted Precursor Cells

Hill, Caitlin E.

18 October 2002

No description available.

Spinal cord injury

contusion

precursor cells

GRP cells

Glial restricted precursor cells

regeneration

corticospinal tract

reticulospinal tract

serotonin

proteoglycans

CSPG

histology

gliosis

astrocytes

anterograde tracer

endogenous repair