Chromatin dynamics and the repair of DNA double strand breaks

DNA double-strand breaks (DSBs) arise through both replication errors and from exogenous events such as exposure to ionizing radiation. DSBs are potentially lethal, and cells have evolved a highly conserved mechanism to detect and repair these lesions. This mechanism involves phosphorylation of histone H2AX (γH2AX) and the loading of DNA repair proteins onto the chromatin adjacent to the DSB. It is now clear that the chromatin architecture in the region surrounding the DSB has a critical impact on the ability of cells to mount an effective DNA damage response. DSBs promote the formation of open, relaxed chromatin domains which are spatially confined to the area surrounding the break. These relaxed chromatin structures are created through the coupled action of the p400 SWI/SNF ATPase and histone acetylation by the Tip60 acetyltransferase. The resulting destabilization of nucleosomes at the DSB by Tip60 and p400 is required for ubiquitination of the chromatin by the RNF8 ubiquitin ligase, and for the subsequent recruitment of the brca1 complex. Chromatin dynamics at DSBs can therefore exert a powerful influence on the process of DSB repair. Further, there is emerging evidence that the different chromatin structures in the cell, such as heterochromatin and euchromatin, utilize distinct remodeling complexes and pathways to facilitate DSB. The processing and repair of DSB is therefore critically influenced by the nuclear architecture in which the lesion arises.Key words: p400, chromatin remodeling, DNA repair, NuA4, H2AX, acetylation, nucleosome, tip60Damage to cellular DNA can occur through multiple pathways, including exposure to genotoxic agents, the production of endogenous reactive oxygen species or errors which arise during DNA replication. To combat this continuous assault on the genome, mammalian cells have evolved multiple DNA repair pathways. The most challenging lesions to repair are DSBs, which physically cleave the DNA strand. DSBs can occur through exposure to IR, the collapse of replication forks or during the processing of certain types of DNA damage. Over the last 20 years, a clear picture of how the cell detects and repairs DSBs has emerged.^1,2 The earliest event in the cell''s response to DSBs is the rapid recruitment of the ATM kinase, followed by the phosphorylation of histone H2AX (termed γH2AX) on large chromatin domains which extend for 100''s of kilobases on either side of the DSB.³ The mdc1 scaffold protein is then recruited to γH2AX,⁴ providing a docking platform for the recruitment and retention of additional DNA repair proteins, including the MRN complex, the RNF8 ubiquitin ligase and the brca1 and 53BP1 proteins, onto the chromatin at DSBs.^5–7 Eventually, this spreading of DNA repair proteins along the chromatin from the DSB leads to the formation of IRIF, which can be visualized by immunofluorescent techniques. DSBs are then repaired by NHEJ, in which broken DNA ends are directly religated, or by HR, using the undamaged sister chromatid (present during S-phase) as a template. A defining characteristic of DSB repair is the dominant role that chromatin structure plays in the detection and repair of these lesions. In this review, we will examine recent work exploring how remodeling of the chromatin structure adjacent to DSBs plays a key role in the repair of DSBs.