Abstract
Werner syndrome (WS) is a cancer-prone disease caused by deficiency of Werner protein (WRN). WRN maintains genome integrity by promoting replication-fork stability after various forms of replication stress. Under mild replication stress, WS cells show impaired ATR-mediated CHK1 activation. However, it remains unclear if WS cells elicit other repair pathway. We demonstrate that loss of WRN leads to enhanced ATM phosphorylation upon prolonged exposure to aphidicolin, a specific inhibitor of DNA polymerases, resulting in CHK1 activation. Moreover, we find that loss of WRN sensitises cells to replication-transcription collisions and promotes accumulation of R-loops, which undergo XPG-dependent cleavage responsible for ATM signalling activation. Importantly, we observe that ATM pathway limits chromosomal instability in WS cells. Finally, we prove that, in WS cells, genomic instability enhanced upon chemical inhibition of ATM kinase activity is counteracted by direct or indirect suppression of R-loop formation or by XPG abrogation. Together, these findings suggest a potential role of WRN as regulator of R-loop-associated genomic instability, strengthening the notion that conflicts between replication and transcription can affect DNA replication, leading to human disease and cancer.
Highlights
The maintenance of genome integrity relies on accurate DNA duplication in all organisms
We investigated whether ATM or ATR was responsible for CHK1 activation after prolonged treatment with Aph in Werner syndrome (WS) cells
We proposed a novel role for Werner protein (WRN) in preventing aberrant R-loop formation in human cells
Summary
The maintenance of genome integrity relies on accurate DNA duplication in all organisms. How precisely such replication-transcription collisions are managed is not completely understood, the fact that unscheduled R-loops severely distress the ongoing forks raised the possibility that some DNA replication associated factors can participate in preventing their accumulation or processing With this hypothesis, it is emerging that defects in DNA repair factors, including BRCA1 and 2 [11,12,13,14], the Fanconi anaemia pathway [15,16], RECQ5 DNA helicase [17], Bloom syndrome helicase [18] and RNA/DNA helicase senataxin [19], or in the apical activator of the DDR, the ATM kinase [20], might directly or indirectly stabilize R-loops, potentially blocking replication fork progression [21]
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