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Pathogenic ARH3 mutations result in ADP-ribose chromatin scars during DNA strand break repair

Hana Hanzlíková, Evgeniia Prokhorova, Kateřina Krejčíková, Zuzana Cihlářová, Ilona Kalasová, Jan Kubovčiak, Jana Šáchová, Richard Hailstone, Jan Bražina, Shereen G. Ghosh, Sebahattin Çırak, Joseph G. Gleeson, Ivan Ahel, Keith W. Caldecott

2020Nature Communications45 citationsDOIOpen Access PDF

Abstract

Neurodegeneration is a common hallmark of individuals with hereditary defects in DNA single-strand break repair; a process regulated by poly(ADP-ribose) metabolism. Recently, mutations in the ARH3 (ADPRHL2) hydrolase that removes ADP-ribose from proteins have been associated with neurodegenerative disease. Here, we show that ARH3-mutated patient cells accumulate mono(ADP-ribose) scars on core histones that are a molecular memory of recently repaired DNA single-strand breaks. We demonstrate that the ADP-ribose chromatin scars result in reduced endogenous levels of important chromatin modifications such as H3K9 acetylation, and that ARH3 patient cells exhibit measurable levels of deregulated transcription. Moreover, we show that the mono(ADP-ribose) scars are lost from the chromatin of ARH3-defective cells in the prolonged presence of PARP inhibition, and concomitantly that chromatin acetylation is restored to normal. Collectively, these data indicate that ARH3 can act as an eraser of ADP-ribose chromatin scars at sites of PARP activity during DNA single-strand break repair.

Topics & Concepts

ChromatinHistonePoly ADP ribose polymeraseDNA repairAcetylationBiologyDNACell biologyDNA damageMolecular biologyGeneticsPolymeraseGenePARP inhibition in cancer therapyDNA Repair MechanismsIntegrated Circuits and Semiconductor Failure Analysis