Litcius/Paper detail

XRCC1 protects transcription from toxic PARP1 activity during DNA base excision repair

Marek Adamowicz, Richard Hailstone, Annie Albert Demin, Emilia Komulainen, Hana Hanzlíková, Jan Bražina, Amit Gautam, Sophie E. Wells, Keith W. Caldecott

2021Nature Cell Biology73 citationsDOIOpen Access PDF

Abstract

Abstract Genetic defects in the repair of DNA single-strand breaks (SSBs) can result in neurological disease triggered by toxic activity of the single-strand-break sensor protein PARP1. However, the mechanism(s) by which this toxic PARP1 activity triggers cellular dysfunction are unclear. Here we show that human cells lacking XRCC1 fail to rapidly recover transcription following DNA base damage, a phenotype also observed in patient-derived fibroblasts with XRCC1 mutations and Xrcc1 −/− mouse neurons. This defect is caused by excessive/aberrant PARP1 activity during DNA base excision repair, resulting from the loss of PARP1 regulation by XRCC1. We show that aberrant PARP1 activity suppresses transcriptional recovery during base excision repair by promoting excessive recruitment and activity of the ubiquitin protease USP3, which as a result reduces the level of monoubiquitinated histones important for normal transcriptional regulation. Importantly, inhibition and/or deletion of PARP1 or USP3 restores transcriptional recovery in XRCC1 −/− cells, highlighting PARP1 and USP3 as possible therapeutic targets in neurological disease.

Topics & Concepts

XRCC1PARP1Base excision repairDNA repairDNA damageBiologyDNA polymerase betaCell biologyTranscription (linguistics)Transcription factorNucleotide excision repairHistoneDNAPoly ADP ribose polymeraseCancer researchMolecular biologyGeneticsPolymeraseGeneGenotypeLinguisticsSingle-nucleotide polymorphismPhilosophyDNA Repair MechanismsPARP inhibition in cancer therapyGenomics and Chromatin Dynamics