Literature DB >> 32890402

Clinical PARP inhibitors do not abrogate PARP1 exchange at DNA damage sites in vivo.

Zhengping Shao1, Brian J Lee1, Élise Rouleau-Turcotte2, Marie-France Langelier2, Xiaohui Lin1, Verna M Estes1, John M Pascal2, Shan Zha1,3.   

Abstract

DNA breaks recruit and activate PARP1/2, which deposit poly-ADP-ribose (PAR) to recruit XRCC1-Ligase3 and other repair factors to promote DNA repair. Clinical PARP inhibitors (PARPi) extend the lifetime of damage-induced PARP1/2 foci, referred to as 'trapping'. To understand the molecular nature of 'trapping' in cells, we employed quantitative live-cell imaging and fluorescence recovery after photo-bleaching. Unexpectedly, we found that PARP1 exchanges rapidly at DNA damage sites even in the presence of clinical PARPi, suggesting the persistent foci are not caused by physical stalling. Loss of Xrcc1, a major downstream effector of PAR, also caused persistent PARP1 foci without affecting PARP1 exchange. Thus, we propose that the persistent PARP1 foci are formed by different PARP1 molecules that are continuously recruited to and exchanging at DNA lesions due to attenuated XRCC1-LIG3 recruitment and delayed DNA repair. Moreover, mutation analyses of the NAD+ interacting residues of PARP1 showed that PARP1 can be physically trapped at DNA damage sites, and identified H862 as a potential regulator for PARP1 exchange. PARP1-H862D, but not PARylation-deficient PARP1-E988K, formed stable PARP1 foci upon activation. Together, these findings uncovered the nature of persistent PARP1 foci and identified NAD+ interacting residues involved in the PARP1 exchange.
© The Author(s) 2020. Published by Oxford University Press on behalf of Nucleic Acids Research.

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Year:  2020        PMID: 32890402      PMCID: PMC7515702          DOI: 10.1093/nar/gkaa718

Source DB:  PubMed          Journal:  Nucleic Acids Res        ISSN: 0305-1048            Impact factor:   16.971


  62 in total

1.  Purification of DNA Damage-Dependent PARPs from E. coli for Structural and Biochemical Analysis.

Authors:  Marie-France Langelier; Jamin D Steffen; Amanda A Riccio; Michael McCauley; John M Pascal
Journal:  Methods Mol Biol       Date:  2017

2.  Inhibitors of poly(adenosine diphosphate ribose) polymerase induce sister chromatid exchanges.

Authors:  A Oikawa; H Tohda; M Kanai; M Miwa; T Sugimura
Journal:  Biochem Biophys Res Commun       Date:  1980-12-31       Impact factor: 3.575

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Journal:  Nat Rev Cancer       Date:  2006-10       Impact factor: 60.716

4.  Nonhomologous end joining drives poly(ADP-ribose) polymerase (PARP) inhibitor lethality in homologous recombination-deficient cells.

Authors:  Anand G Patel; Jann N Sarkaria; Scott H Kaufmann
Journal:  Proc Natl Acad Sci U S A       Date:  2011-02-07       Impact factor: 11.205

5.  Rationale for poly(ADP-ribose) polymerase (PARP) inhibitors in combination therapy with camptothecins or temozolomide based on PARP trapping versus catalytic inhibition.

Authors:  Junko Murai; Yiping Zhang; Joel Morris; Jiuping Ji; Shunichi Takeda; James H Doroshow; Yves Pommier
Journal:  J Pharmacol Exp Ther       Date:  2014-03-20       Impact factor: 4.030

6.  Identification of the ADP-ribosylation sites in the PARP-1 automodification domain: analysis and implications.

Authors:  Zhihua Tao; Peng Gao; Hung-wen Liu
Journal:  J Am Chem Soc       Date:  2009-10-14       Impact factor: 15.419

7.  Spatial and temporal cellular responses to single-strand breaks in human cells.

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Review 8.  A Mighty "Protein Extractor" of the Cell: Structure and Function of the p97/CDC48 ATPase.

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Journal:  Front Mol Biosci       Date:  2017-06-13

9.  Feedback-regulated poly(ADP-ribosyl)ation by PARP-1 is required for rapid response to DNA damage in living cells.

Authors:  Oliver Mortusewicz; Jean-Christophe Amé; Valérie Schreiber; Heinrich Leonhardt
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10.  Genome-wide and high-density CRISPR-Cas9 screens identify point mutations in PARP1 causing PARP inhibitor resistance.

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Journal:  Nat Commun       Date:  2018-05-10       Impact factor: 14.919
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  12 in total

1.  The BRCT domain of PARP1 binds intact DNA and mediates intrastrand transfer.

Authors:  Johannes Rudolph; Uma M Muthurajan; Megan Palacio; Jyothi Mahadevan; Genevieve Roberts; Annette H Erbse; Pamela N Dyer; Karolin Luger
Journal:  Mol Cell       Date:  2021-12-16       Impact factor: 17.970

2.  Captured snapshots of PARP1 in the active state reveal the mechanics of PARP1 allostery.

Authors:  Élise Rouleau-Turcotte; Dragomir B Krastev; Stephen J Pettitt; Christopher J Lord; John M Pascal
Journal:  Mol Cell       Date:  2022-07-05       Impact factor: 19.328

3.  The Cancer-Associated ATM R3008H Mutation Reveals the Link between ATM Activation and Its Exchange.

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Journal:  Cancer Res       Date:  2020-11-25       Impact factor: 12.701

Review 4.  Avoid the trap: Targeting PARP1 beyond human malignancy.

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Journal:  Cell Chem Biol       Date:  2021-03-02       Impact factor: 8.116

Review 5.  PARP1: Structural insights and pharmacological targets for inhibition.

Authors:  Jacob O Spiegel; Bennett Van Houten; Jacob D Durrant
Journal:  DNA Repair (Amst)       Date:  2021-04-14

Review 6.  Rapid Detection and Signaling of DNA Damage by PARP-1.

Authors:  Nootan Pandey; Ben E Black
Journal:  Trends Biochem Sci       Date:  2021-03-03       Impact factor: 14.264

7.  Histone Parylation factor 1 contributes to the inhibition of PARP1 by cancer drugs.

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8.  The ubiquitin-dependent ATPase p97 removes cytotoxic trapped PARP1 from chromatin.

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Journal:  Nat Cell Biol       Date:  2022-01-10       Impact factor: 28.213

9.  Serine-linked PARP1 auto-modification controls PARP inhibitor response.

Authors:  Evgeniia Prokhorova; Florian Zobel; Rebecca Smith; Siham Zentout; Ian Gibbs-Seymour; Kira Schützenhofer; Alessandra Peters; Joséphine Groslambert; Valentina Zorzini; Thomas Agnew; John Brognard; Michael L Nielsen; Dragana Ahel; Sébastien Huet; Marcin J Suskiewicz; Ivan Ahel
Journal:  Nat Commun       Date:  2021-07-01       Impact factor: 14.919

10.  XRCC1 prevents toxic PARP1 trapping during DNA base excision repair.

Authors:  Annie A Demin; Kouji Hirota; Masataka Tsuda; Marek Adamowicz; Richard Hailstone; Jan Brazina; William Gittens; Ilona Kalasova; Zhengping Shao; Shan Zha; Hiroyuki Sasanuma; Hana Hanzlikova; Shunichi Takeda; Keith W Caldecott
Journal:  Mol Cell       Date:  2021-06-07       Impact factor: 17.970
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