Increased ionizing radiation sensitivity and genomic instability in the absence of histone H2AX

Craig H. Bassing(Beth Israel Deaconess Medical Center), Katrin F. Chua(Beth Israel Deaconess Medical Center), JoAnn Sekiguchi(Beth Israel Deaconess Medical Center), Heikyung Suh(Beth Israel Deaconess Medical Center), Scott Whitlow(Beth Israel Deaconess Medical Center), James C. Fleming(Beth Israel Deaconess Medical Center), Brianna Monroe(Beth Israel Deaconess Medical Center), David Ciccone(Beth Israel Deaconess Medical Center), Catherine T. Yan(Beth Israel Deaconess Medical Center), Kateřina Vlasáková(Beth Israel Deaconess Medical Center), David M. Livingston(Beth Israel Deaconess Medical Center), David O. Ferguson(Beth Israel Deaconess Medical Center), Ralph Scully(Beth Israel Deaconess Medical Center), Frederick W. Alt(Beth Israel Deaconess Medical Center)
Proceedings of the National Academy of Sciences
May 28, 2002
10.1073/pnas.122228699
Cited by 528

Abstract

In mammalian cells, DNA double-strand breaks (DSBs) cause rapid phosphorylation of the H2AX core histone variant (to form gamma-H2AX) in megabase chromatin domains flanking sites of DNA damage. To investigate the role of H2AX in mammalian cells, we generated H2AX-deficient (H2AX(Delta)/Delta) mouse embryonic stem (ES) cells. H2AX(Delta)/Delta ES cells are viable. However, they are highly sensitive to ionizing radiation (IR) and exhibit elevated levels of spontaneous and IR-induced genomic instability. Notably, H2AX is not required for NHEJ per se because H2AX(Delta)/Delta ES cells support normal levels and fidelity of V(D)J recombination in transient assays and also support lymphocyte development in vivo. However, H2AX(Delta)/Delta ES cells exhibit altered IR-induced BRCA1 focus formation. Our findings indicate that H2AX function is essential for mammalian DNA repair and genomic stability.

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