Project description:Background: Of the many types of DNA damage, DNA double-strand breaks (DSB) are probably the most deleterious. Mounting evidence points to an intricate relationship between DSBs and transcription. A cell system in which the impact on transcription can be investigated at precisely mapped genomic DSBs is essential to study this relationship. Methods: Here in a human cell line, we map genome-wide and at high-resolution the DSBs induced by a restriction enzyme and we characterize their impact on gene expression by four independent approaches by monitoring steady-state RNA levels, rates of RNA synthesis, transcription initiation and RNA polymerase II elongation. Results: We consistently observe transcriptional repression in proximity to DSBs. Downregulation of transcription depends on ATM kinase activity and it is sensitive to the distance from the DSB. Conclusions: Our study couples for the first time high-resolution mapping of DSBs with multilayered transcriptomics to dissect the events shaping gene expression after DSB induction at multiple endogenous sites.

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Project description:Chromatin acts as a key regulator of DNA related processes such as DNA damage repair. While ChIP-chip is a powerful technique to provide high-resolution maps of protein-genome interactions, its use to study DNA Double Strand Break (DSB) repair has been hindered by the limitations of the available damage induction methods. We have developed a human cell line that permits induction of multiple DSBs randomly distributed and unambiguously positioned within the genome. Using this system, we have generated the first genome-wide mapping of gammaH2AX around DSBs. We found that all DSBs trigger large gammaH2AX domains, which extend from the DSB in a bidirectional, discontinuous and not necessarily symmetrical manner. Strikingly we uncovered that, within domains, gammaH2AX distribution is highly influenced by gene transcription since parallel mapping of RNA Polymerase II and strand specific expression revealed that ?H2AX does not propagate on active genes. In addition, we demonstrate that transcription is accurately maintained within gammaH2AX domains, indicating that mechanisms may exist to protect genes transcription from gammaH2AX spreading and from the chromatin rearrangements induced by DSBs.

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