Genomic Instability in Mice Lacking Histone H2AX

Arkady Celeste; Simone Petersen; Peter Romanienko; Óscar Fernández-Capetillo; Hua Tang Chen; Olga A. Sedelnikova; Bernardo Reina‐San‐Martin; Vincenzo Coppola; Eric Meffre; Michael J. Difilippantonio; Christophe E. Redon; Duane R. Pilch; Alexandru Olaru; Michael Eckhaus; R. Daniel Camerini‐Otero; Lino Tessarollo; Ferenc Livák; Katia Manova; William M. Bonner; Michel C. Nussenzweig; André Nussenzweig

doi:10.1126/science.1069398

Genomic Instability in Mice Lacking Histone H2AX

Arkady Celeste(National Cancer Institute), Simone Petersen(National Cancer Institute), Peter Romanienko(National Institute of Diabetes and Digestive and Kidney Diseases), Óscar Fernández-Capetillo(National Cancer Institute), Hua Tang Chen(National Cancer Institute), Olga A. Sedelnikova(National Institutes of Health), Bernardo Reina‐San‐Martin(Howard Hughes Medical Institute), Vincenzo Coppola(Frederick National Laboratory for Cancer Research), Eric Meffre(Howard Hughes Medical Institute), Michael J. Difilippantonio(National Cancer Institute), Christophe E. Redon(National Institutes of Health), Duane R. Pilch(National Institutes of Health), Alexandru Olaru(University of Maryland, Baltimore), Michael Eckhaus(Office of Research Services), R. Daniel Camerini‐Otero(National Institute of Diabetes and Digestive and Kidney Diseases), Lino Tessarollo(Frederick National Laboratory for Cancer Research), Ferenc Livák(University of Maryland, Baltimore), Katia Manova(Memorial Sloan Kettering Cancer Center), William M. Bonner(National Institutes of Health), Michel C. Nussenzweig(Howard Hughes Medical Institute), André Nussenzweig(National Cancer Institute)

Science

May 3, 2002

10.1126/science.1069398

Cited by 1,360Open Access

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Abstract

Higher order chromatin structure presents a barrier to the recognition and repair of DNA damage. Double-strand breaks (DSBs) induce histone H2AX phosphorylation, which is associated with the recruitment of repair factors to damaged DNA. To help clarify the physiological role of H2AX, we targeted H2AX in mice. Although H2AX is not essential for irradiation-induced cell-cycle checkpoints, H2AX-/- mice were radiation sensitive, growth retarded, and immune deficient, and mutant males were infertile. These pleiotropic phenotypes were associated with chromosomal instability, repair defects, and impaired recruitment of Nbs1, 53bp1, and Brca1, but not Rad51, to irradiation-induced foci. Thus, H2AX is critical for facilitating the assembly of specific DNA-repair complexes on damaged DNA.

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