How Neural Stem Cells work part1(Neuroscience)

1. Quiescence of Adult Mammalian Neural Stem Cells: A Highly Regulated Rest(PubMed)

Author : Noelia Urbán 1, Isabelle Maria Blomfield 2, François Guillemot 3

Abstract : Neural stem cells in the adult mammalian brain are the source of new neurons that contribute to complex sensory and cognitive functions. Most adult neural stem cells are maintained in a state of reversible cell cycle arrest, also called quiescence. Quiescent neural stem cells present a low rate of metabolic activity and a high sensitivity to their local signaling environment, and they can be activated by diverse physiological stimuli. The balance between stem cell quiescence and activity determines not only the rate of neurogenesis but also the long-term maintenance of the stem cell pool and the neurogenic capacity of the aging brain. In recent years, significant progress has been made in characterizing quiescent stem cells thanks to the introduction of new genomic and imaging techniques. We discuss in this review our current understanding of neural stem cell quiescence and its regulation by intrinsic and systemic factors.

2. Embryonic Origin of Postnatal Neural Stem Cells(PubMed)

Author : Luis C Fuentealba 1, Santiago B Rompani 2, Jose I Parraguez 1, Kirsten Obernier 1, Ricardo Romero 1, Constance L Cepko 2, Arturo Alvarez-Buylla 3

Abstract : Adult neural stem/progenitor (B1) cells within the walls of the lateral ventricles generate different types of neurons for the olfactory bulb (OB). The location of B1 cells determines the types of OB neurons they generate. Here we show that the majority of mouse B1 cell precursors are produced between embryonic days (E) 13.5 and 15.5 and remain largely quiescent until they become reactivated postnatally. Using a retroviral library carrying over 100,000 genetic tags, we found that B1 cells share a common progenitor with embryonic cells of the cortex, striatum, and septum, but this lineage relationship is lost before E15.5. The regional specification of B1 cells is evident as early as E11.5 and is spatially linked to the production of neurons that populate different areas of the forebrain. This study reveals an early embryonic regional specification of postnatal neural stem cells and the lineage relationship between them and embryonic progenitor cells.