Literature DB >> 25174396

ATR inhibition preferentially targets homologous recombination-deficient tumor cells.

M Krajewska1, R S N Fehrmann1, P M Schoonen1, S Labib1, E G E de Vries1, L Franke2, M A T M van Vugt1.   

Abstract

Homologous recombination (HR) is required for faithful repair of double-strand DNA breaks. Defects in HR repair cause severe genomic instability and challenge cellular viability. Paradoxically, various cancers are HR defective and have apparently acquired characteristics to survive genomic instability. We aimed to identify these characteristics to uncover therapeutic targets for HR-deficient cancers. Cytogenetic analysis of 1143 ovarian cancers showed that the degree of genomic instability was correlated to amplification of replication checkpoint genes ataxia telangiectasia and Rad3-related kinase (ATR) and CHEK1. To test whether genomic instability leads to increased reliance on replication checkpoint signaling, we inactivated Rad51 to model HR-related genomic instability. Rad51 inactivation caused defective HR repair and induced aberrant replication dynamics. Notably, inhibition of Rad51 led to increased ATR/checkpoint kinase-1 (Chk1)-mediated replication stress signaling. Importantly, inhibition of ATR or Chk1 preferentially killed HR-deficient cancer cells. Combined, our data show that defective HR caused by Rad51 inhibition results in differential sensitivity for ATR and Chk1 inhibitors, implicating replication checkpoint kinases as potential drug targets for HR-defective cancers.

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Year:  2014        PMID: 25174396     DOI: 10.1038/onc.2014.276

Source DB:  PubMed          Journal:  Oncogene        ISSN: 0950-9232            Impact factor:   9.867


  37 in total

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Journal:  Genes Dev       Date:  1999-10-15       Impact factor: 11.361

2.  Exploiting oncogene-induced replicative stress for the selective killing of Myc-driven tumors.

Authors:  Matilde Murga; Stefano Campaner; Andres J Lopez-Contreras; Luis I Toledo; Rebeca Soria; Maria F Montaña; Luana D' Artista; Thomas Schleker; Carmen Guerra; Elena Garcia; Mariano Barbacid; Manuel Hidalgo; Bruno Amati; Oscar Fernandez-Capetillo
Journal:  Nat Struct Mol Biol       Date:  2011-11-27       Impact factor: 15.369

3.  ATR prohibits replication catastrophe by preventing global exhaustion of RPA.

Authors:  Luis Ignacio Toledo; Matthias Altmeyer; Maj-Britt Rask; Claudia Lukas; Dorthe Helena Larsen; Lou Klitgaard Povlsen; Simon Bekker-Jensen; Niels Mailand; Jiri Bartek; Jiri Lukas
Journal:  Cell       Date:  2013-11-21       Impact factor: 41.582

4.  Double-strand break repair-independent role for BRCA2 in blocking stalled replication fork degradation by MRE11.

Authors:  Katharina Schlacher; Nicole Christ; Nicolas Siaud; Akinori Egashira; Hong Wu; Maria Jasin
Journal:  Cell       Date:  2011-05-13       Impact factor: 41.582

5.  Duplication of ATR inhibits MyoD, induces aneuploidy and eliminates radiation-induced G1 arrest.

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Journal:  Nat Genet       Date:  1998-05       Impact factor: 38.330

6.  The tumor suppressor gene Brca1 is required for embryonic cellular proliferation in the mouse.

Authors:  R Hakem; J L de la Pompa; C Sirard; R Mo; M Woo; A Hakem; A Wakeham; J Potter; A Reitmair; F Billia; E Firpo; C C Hui; J Roberts; J Rossant; T W Mak
Journal:  Cell       Date:  1996-06-28       Impact factor: 41.582

7.  A mutation in mouse rad51 results in an early embryonic lethal that is suppressed by a mutation in p53.

Authors:  D S Lim; P Hasty
Journal:  Mol Cell Biol       Date:  1996-12       Impact factor: 4.272

8.  Hydroxyurea-stalled replication forks become progressively inactivated and require two different RAD51-mediated pathways for restart and repair.

Authors:  Eva Petermann; Manuel Luís Orta; Natalia Issaeva; Niklas Schultz; Thomas Helleday
Journal:  Mol Cell       Date:  2010-02-26       Impact factor: 17.970

9.  Cyclin E1 deregulation occurs early in secretory cell transformation to promote formation of fallopian tube-derived high-grade serous ovarian cancers.

Authors:  Alison M Karst; Paul M Jones; Natalie Vena; Azra H Ligon; Joyce F Liu; Michelle S Hirsch; Dariush Etemadmoghadam; David D L Bowtell; Ronny Drapkin
Journal:  Cancer Res       Date:  2013-12-23       Impact factor: 12.701

10.  BRCA1 mutations in primary breast and ovarian carcinomas.

Authors:  P A Futreal; Q Liu; D Shattuck-Eidens; C Cochran; K Harshman; S Tavtigian; L M Bennett; A Haugen-Strano; J Swensen; Y Miki
Journal:  Science       Date:  1994-10-07       Impact factor: 47.728
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  35 in total

1.  RNF126 as a Biomarker of a Poor Prognosis in Invasive Breast Cancer and CHEK1 Inhibitor Efficacy in Breast Cancer Cells.

Authors:  Xiaosong Yang; You Pan; Zhaojun Qiu; Zhanwen Du; Yao Zhang; Pengyan Fa; Shashank Gorityala; Shanhuai Ma; Shunqiang Li; Ceshi Chen; Hongbing Wang; Yan Xu; Chunhong Yan; Keri Ruth; Zhefu Ma; Junran Zhang
Journal:  Clin Cancer Res       Date:  2018-01-11       Impact factor: 12.531

2.  Targeting the ATR/CHK1 Axis with PARP Inhibition Results in Tumor Regression in BRCA-Mutant Ovarian Cancer Models.

Authors:  Hyoung Kim; Erin George; Ryan Ragland; Stavros Rafail; Rugang Zhang; Clemens Krepler; Mark Morgan; Meenhard Herlyn; Eric Brown; Fiona Simpkins
Journal:  Clin Cancer Res       Date:  2016-12-19       Impact factor: 12.531

3.  Temozolomide Sensitizes MGMT-Deficient Tumor Cells to ATR Inhibitors.

Authors:  Christopher B Jackson; Seth I Noorbakhsh; Ranjini K Sundaram; Aravind N Kalathil; Sachita Ganesa; Lanqi Jia; Hank Breslin; Danielle M Burgenske; Oren Gilad; Jann N Sarkaria; Ranjit S Bindra
Journal:  Cancer Res       Date:  2019-07-04       Impact factor: 12.701

4.  Enhanced efficacy of combined HDAC and PARP targeting in glioblastoma.

Authors:  Rikke D Rasmussen; Madhavsai K Gajjar; Kamilla E Jensen; Petra Hamerlik
Journal:  Mol Oncol       Date:  2016-01-08       Impact factor: 6.603

5.  ZEB1 inhibition sensitizes cells to the ATR inhibitor VE-821 by abrogating epithelial-mesenchymal transition and enhancing DNA damage.

Authors:  Na Song; Wei Jing; Ce Li; Ming Bai; Yu Cheng; Heming Li; Kezuo Hou; Yanrong Li; Kai Wang; Zhi Li; Yunpeng Liu; Xiujuan Qu; Xiaofang Che
Journal:  Cell Cycle       Date:  2018-04-02       Impact factor: 4.534

Review 6.  ATR/CHK1 inhibitors and cancer therapy.

Authors:  Zhaojun Qiu; Nancy L Oleinick; Junran Zhang
Journal:  Radiother Oncol       Date:  2017-10-18       Impact factor: 6.280

7.  ATR Inhibition Is a Promising Radiosensitizing Strategy for Triple-Negative Breast Cancer.

Authors:  Xinyi Tu; Mohamed M Kahila; Qin Zhou; Jia Yu; Krishna R Kalari; Liewei Wang; William S Harmsen; Jian Yuan; Judy C Boughey; Matthew P Goetz; Jann N Sarkaria; Zhenkun Lou; Robert W Mutter
Journal:  Mol Cancer Ther       Date:  2018-08-30       Impact factor: 6.261

8.  Radiosensitization by the ATR Inhibitor AZD6738 through Generation of Acentric Micronuclei.

Authors:  Martin McLaughlin; Kevin J Harrington; Magnus T Dillon; Holly E Barker; Malin Pedersen; Hind Hafsi; Shreerang A Bhide; Kate L Newbold; Christopher M Nutting
Journal:  Mol Cancer Ther       Date:  2016-11-09       Impact factor: 6.261

9.  TrapSeq: An RNA Sequencing-Based Pipeline for the Identification of Gene-Trap Insertions in Mammalian Cells.

Authors:  Cristina Mayor-Ruiz; Orlando Dominguez; Oscar Fernandez-Capetillo
Journal:  J Mol Biol       Date:  2017-08-04       Impact factor: 5.469

10.  Targeting the kinase activities of ATR and ATM exhibits antitumoral activity in mouse models of MLL-rearranged AML.

Authors:  Isabel Morgado-Palacin; Amanda Day; Matilde Murga; Vanesa Lafarga; Marta Elena Anton; Anthony Tubbs; Hua Tang Chen; Aysegul Ergan; Rhonda Anderson; Avinash Bhandoola; Kurt G Pike; Bernard Barlaam; Elaine Cadogan; Xi Wang; Andrew J Pierce; Chad Hubbard; Scott A Armstrong; André Nussenzweig; Oscar Fernandez-Capetillo
Journal:  Sci Signal       Date:  2016-09-13       Impact factor: 8.192
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