<scp>RPA</scp>
            activates the
            <scp>XPF</scp>
            ‐
            <scp>ERCC</scp>
            1 endonuclease to initiate processing of
            <scp>DNA</scp>
            interstrand crosslinks

Abdullah, Ummi B; McGouran, Joanna F.; Brolih, Sanja; Ptchelkine, Denis; El‐Sagheer, Afaf H.; Brown, Tom; McHugh, Peter J.

doi:10.15252/embj.201796664

Cited by 49 publications

(39 citation statements)

References 44 publications

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“…SNM1A is a DNA damage repair enzyme implicated in interstrand crosslink (ICL) repair. 1 It digests DNA with a 5′-to-3′ polarity past lesions by hydrolysing the phosphodiester backbone of DNA, producing predominantly mononucleotide products. 2 ICL repair factors are associated with the ageing process, 1 certain genetic diseases, 3 and resistance to cancer therapy.…”

Section: Introductionmentioning

confidence: 99%

A hydroxamic-acid-containing nucleoside inhibits DNA repair nuclease SNM1A

et al. 2019

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Section: Introductionmentioning

confidence: 99%

A hydroxamic-acid-containing nucleoside inhibits DNA repair nuclease SNM1A

et al. 2019

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“…Moreover, we were unable to co-immunoprecipitate FANCD2 with XPF, suggesting that these proteins do not interact directly. Because in vitro ERCC1-XPF activity in ICLR is stimulated by RPA [27,57], we also tested whether RPA directly interacts with wild-type or R689S or S786F mutant XPF. However, GFP-tagged XPF was unable to co-immunoprecipitate RPA70, the largest subunit of the heterotrimeric RPA complex, suggesting that stimulation of XPF activity by RPA is not via a direct physical interaction between the proteins.…”

Section: R689s and S786f Mutant Xpf Recruitment To Psoralen Adducts Imentioning

confidence: 99%

“…Experiments using Xenopus laevis egg extract and in vitro-modeled ICLcontaining replication structures suggest that ERCC1-XPF is then recruited, depending on its interaction with the scaffold protein SLX4 that stimulates its function [2,25,26]. ERCC1-XPF incises the lagging strand to unhook the ICL, possibly together with another endonuclease or together with the exonuclease SNM1A that digests past the ICL [27]. The resulting single-stranded gap is filled by TLS and is used as homology template for repair of the remaining doublestrand break by HR [28,29].…”

Section: Introductionmentioning

confidence: 99%

ERCC1–XPF targeting to psoralen–DNA crosslinks depends on XPA and FANCD2

Sabatella

Pines

Slyšková

et al. 2019

Cell. Mol. Life Sci.

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The effectiveness of many DNA-damaging chemotherapeutic drugs depends on their ability to form monoadducts, intrastrand crosslinks and/or interstrand crosslinks (ICLs) that interfere with transcription and replication. The ERCC1-XPF endonuclease plays a critical role in removal of these lesions by incising DNA either as part of nucleotide excision repair (NER) or interstrand crosslink repair (ICLR). Engagement of ERCC1-XPF in NER is well characterized and is facilitated by binding to the XPA protein. However, ERCC1-XPF recruitment to ICLs is less well understood. Moreover, specific mutations in XPF have been found to disrupt its function in ICLR but not in NER, but whether this involves differences in lesion targeting is unknown. Here, we imaged GFP-tagged ERCC1, XPF and ICLR-defective XPF mutants to investigate how in human cells ERCC1-XPF is localized to different types of psoralen-induced DNA lesions, repaired by either NER or ICLR. Our results confirm its dependence on XPA in NER and furthermore show that its engagement in ICLR is dependent on FANCD2. Interestingly, we find that two ICLR-defective XPF mutants (R689S and S786F) are less well recruited to ICLs. These studies highlight the differential mechanisms that regulate ERCC1-XPF activity in DNA repair.

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“…These might involve alternative initiating endonucleases (MUS81 or SLX1, for example [23]) leading to homologous recombination steps requiring XPF-ERCC1 for their successful completion. Moreover, the FAN1 (Fanconi-associated nuclease 1) nuclease, mismatch repair system, and the SNM1A (sensitive to nitrogen mustard 1A) exonuclease have all been implicated in ICL recognition and processing [24][25][26] and are candidates for mediating any XPF-ERCC1-dependent pathway, noting that the cell-cycle phase might be critical (the study of ICL repair outside the synthesis phase [S-phase] has been relatively neglected). Fortunately, the last decade has seen the development of elegant cell-free ICL-repair systems using Xenopus cell extracts [26,27] and structural-and biochemical-reconstitution approaches that will help accelerate our mechanistic understanding of new pathways as they are revealed.…”

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XPF–ERCC1: Linchpin of DNA crosslink repair

McHugh

2020

PLoS Genet

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A spectacularly toxic form of damage, the interstrand crosslink (ICL), arises when two strands of duplex DNA become covalently linked [1]. The cellular response to ICLs is of great interest because several antitumour drugs, including platinum agents and mitomycin C, kill cancer cells by inducing ICLs [2, 3]. More recently it has become apparent that metabolites continually burden cells with ICLs, which must be removed for cells to maintain function and viability. The importance of efficient ICL repair in development and health is illustrated by the clinical features of a devastating inherited syndrome, Fanconi anemia (FA), which is thought to be the result of defective ICL repair [4]. FA patients suffer from bone marrow failure, leukaemia, and solid malignancies. While the endogenous DNA-crosslinking agent, or agents, responsible for the damage that lies unrepaired in the cells of FA patients are unknown, suspects include the common metabolites formaldehyde and acetaldehyde (including that derived from ingested alcohol) and oxidised lipid species [5-7]. The machinery available to repair ICLs has expanded markedly through evolution. Both Escherichia coli and yeasts almost exclusively rely on a modified form of nucleotide excision repair (NER) [1, 8], a cut-and-paste pathway that is best known for its ability to remove UVlight-induced DNA photodimers (whose defects result in another human syndrome, Xeroderma pigmentosum [XP]). The details of how modified NER removes ICLs remain obscure and merit further investigation. Metazoans, meanwhile, have developed additional pathways for ICL repair-most significantly, an 'FA pathway' [4]. The functional characterization of genes and factors defective in FA patients (22 genes to date) have revealed a repair pathway that operates during DNA replication and possibly elsewhere in the cell cycle (although this aspect has yet to be explored systematically). Although how the FA pathway coordinates ICL repair is still subject to intense study, it appears to orchestrate initial responses to ICLs, some steps of the nucleolytic processing of ICLs, and the subsequent resolution of the incised intermediates through the sequential action of translesion-synthesis polymerases and homologous recombination reactions [9]. For mammalian cells, it is not clear whether there is a genetic or functional relationship between the NER and FA pathways in response to ICLs. Here, Mulderrig and Garaycoechea show that while both the FA and NER pathways both play important roles in response to ICLs, additional pathways also contribute to their repair [10]. At the heart of this uncertainty about the contributions of the FA and NER pathways to ICL repair is a dimeric endonuclease, XPF-ERCC1, required for both pathways and mutated in both FA (complementation group Q, FANCQ) and XP (complementation group F) [11, 12]. XPF-ERCC1 has received much attention, since it was realised several decades ago that XPF-ERCC1-deficient mammalian cells are exquisitely sensitive to ICL-inducing agents [13, 14], showing a sensit...

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RPA activates the XPF ‐ ERCC 1 endonuclease to initiate processing of DNA interstrand crosslinks

Cited by 49 publications

References 44 publications

A hydroxamic-acid-containing nucleoside inhibits DNA repair nuclease SNM1A

A hydroxamic-acid-containing nucleoside inhibits DNA repair nuclease SNM1A

ERCC1–XPF targeting to psoralen–DNA crosslinks depends on XPA and FANCD2

XPF–ERCC1: Linchpin of DNA crosslink repair

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