The chromatin-remodeling protein ATRX is critical for neuronal survival during corticogenesis
Nathalie G. Bérubé, … , Ruth S. Slack, David J. Picketts
Nathalie G. Bérubé, … , Ruth S. Slack, David J. Picketts
Published February 1, 2005
Citation Information: J Clin Invest. 2005;115(2):258-267. https://doi.org/10.1172/JCI22329.
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Article Neuroscience

The chromatin-remodeling protein ATRX is critical for neuronal survival during corticogenesis

Abstract

Mutations in genes encoding chromatin-remodeling proteins, such as the ATRX gene, underlie a number of genetic disorders including several X-linked mental retardation syndromes; however, the role of these proteins in normal CNS development is unknown. Here, we used a conditional gene-targeting approach to inactivate Atrx, specifically in the forebrain of mice. Loss of ATRX protein caused widespread hypocellularity in the neocortex and hippocampus and a pronounced reduction in forebrain size. Neuronal “birthdating” confirmed that fewer neurons reached the superficial cortical layers, despite normal progenitor cell proliferation. The loss of cortical mass resulted from a 12-fold increase in neuronal apoptosis during early stages of corticogenesis in the mutant animals. Moreover, cortical progenitors isolated from Atrx-null mice undergo enhanced apoptosis upon differentiation. Taken together, our results indicate that ATRX is a critical mediator of cell survival during early neuronal differentiation. Thus, increased neuronal loss may contribute to the severe mental retardation observed in human patients.

Authors

Nathalie G. Bérubé, Marie Mangelsdorf, Magdalena Jagla, Jackie Vanderluit, David Garrick, Richard J. Gibbons, Douglas R. Higgs, Ruth S. Slack, David J. Picketts

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Figure 9

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Increased apoptosis in AtrxFoxg1Cre embryonic cortex and postnatal hippo...
Increased apoptosis in AtrxFoxg1Cre embryonic cortex and postnatal hippocampus. (AI) The TUNEL assay was performed on embryos at E11.5 (A and B) and E13.5 (C and D) and at P0.5 in the hippocampus (H and I). AtrxFoxg1Cre sections (B, D, G, and I) are compared with littermate controls (A, C, F, and H). A substantial increase in the number of TUNEL-positive cells is observed in AtrxFoxg1Cre E11.5 neuroepithelial layer (compare A with B). This increase persists in the cortex of E13.5 embryos (C and D) and is not restricted to the proliferative ventricular layer. (E) Graph depicting the increased number of apoptotic cells in ATRX-deficient embryos detected by TUNEL assay. TUNEL-positive cells were counted and data expressed as a percentage of total number of cells (DAPI-positive; E11.5, n = 3, P = 0.045; E13.5, n = 4, P < 0.001). At P0.5, increased levels of TUNEL-positive cells are detected in the subventricular zone of the CA1 field (F and G) and in the developing dentate gyrus (H and I). PL, pial layer; H, hippocampus; MS, migratory stream. Missing DG in I is indicated by an asterisk. Magnification, ×20 (A, B, and FI) and ×10 (C and D).