Literature DB >> 12192050

Chk2 is a tumor suppressor that regulates apoptosis in both an ataxia telangiectasia mutated (ATM)-dependent and an ATM-independent manner.

Atsushi Hirao1, Alison Cheung, Gordon Duncan, Pierre-Marie Girard, Andrew J Elia, Andrew Wakeham, Hitoshi Okada, Talin Sarkissian, Jorge A Wong, Takashi Sakai, Elisa De Stanchina, Robert G Bristow, Toshio Suda, Scott W Lowe, Penny A Jeggo, Stephen J Elledge, Tak W Mak.   

Abstract

In response to ionizing radiation (IR), the tumor suppressor p53 is stabilized and promotes either cell cycle arrest or apoptosis. Chk2 activated by IR contributes to this stabilization, possibly by direct phosphorylation. Like p53, Chk2 is mutated in patients with Li-Fraumeni syndrome. Since the ataxia telangiectasia mutated (ATM) gene is required for IR-induced activation of Chk2, it has been assumed that ATM and Chk2 act in a linear pathway leading to p53 activation. To clarify the role of Chk2 in tumorigenesis, we generated gene-targeted Chk2-deficient mice. Unlike ATM(-/-) and p53(-/-) mice, Chk2(-/-) mice do not spontaneously develop tumors, although Chk2 does suppress 7,12-dimethylbenzanthracene-induced skin tumors. Tissues from Chk2(-/-) mice, including those from the thymus, central nervous system, fibroblasts, epidermis, and hair follicles, show significant defects in IR-induced apoptosis or impaired G(1)/S arrest. Quantitative comparison of the G(1)/S checkpoint, apoptosis, and expression of p53 proteins in Chk2(-/-) versus ATM(-/-) thymocytes suggested that Chk2 can regulate p53-dependent apoptosis in an ATM-independent manner. IR-induced apoptosis was restored in Chk2(-/-) thymocytes by reintroduction of the wild-type Chk2 gene but not by a Chk2 gene in which the sites phosphorylated by ATM and ataxia telangiectasia and rad3(+) related (ATR) were mutated to alanine. ATR may thus selectively contribute to p53-mediated apoptosis. These data indicate that distinct pathways regulate the activation of p53 leading to cell cycle arrest or apoptosis.

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Year:  2002        PMID: 12192050      PMCID: PMC135625          DOI: 10.1128/MCB.22.18.6521-6532.2002

Source DB:  PubMed          Journal:  Mol Cell Biol        ISSN: 0270-7306            Impact factor:   4.272


  56 in total

Review 1.  The DNA damage response: putting checkpoints in perspective.

Authors:  B B Zhou; S J Elledge
Journal:  Nature       Date:  2000-11-23       Impact factor: 49.962

Review 2.  ATM and ATR: networking cellular responses to DNA damage.

Authors:  Y Shiloh
Journal:  Curr Opin Genet Dev       Date:  2001-02       Impact factor: 5.578

3.  ATR and ATRIP: partners in checkpoint signaling.

Authors:  D Cortez; S Guntuku; J Qin; S J Elledge
Journal:  Science       Date:  2001-11-23       Impact factor: 47.728

4.  The ATM-Chk2-Cdc25A checkpoint pathway guards against radioresistant DNA synthesis.

Authors:  J Falck; N Mailand; R G Syljuåsen; J Bartek; J Lukas
Journal:  Nature       Date:  2001-04-12       Impact factor: 49.962

5.  Threonine 68 phosphorylation by ataxia telangiectasia mutated is required for efficient activation of Chk2 in response to ionizing radiation.

Authors:  J Y Ahn; J K Schwarz; H Piwnica-Worms; C E Canman
Journal:  Cancer Res       Date:  2000-11-01       Impact factor: 12.701

6.  Targeted disruption of ATM leads to growth retardation, chromosomal fragmentation during meiosis, immune defects, and thymic lymphoma.

Authors:  Y Xu; T Ashley; E E Brainerd; R T Bronson; M S Meyn; D Baltimore
Journal:  Genes Dev       Date:  1996-10-01       Impact factor: 11.361

7.  Dual roles of ATM in the cellular response to radiation and in cell growth control.

Authors:  Y Xu; D Baltimore
Journal:  Genes Dev       Date:  1996-10-01       Impact factor: 11.361

8.  The combined functions of proapoptotic Bcl-2 family members bak and bax are essential for normal development of multiple tissues.

Authors:  T Lindsten; A J Ross; A King; W X Zong; J C Rathmell; H A Shiels; E Ulrich; K G Waymire; P Mahar; K Frauwirth; Y Chen; M Wei; V M Eng; D M Adelman; M C Simon; A Ma; J A Golden; G Evan; S J Korsmeyer; G R MacGregor; C B Thompson
Journal:  Mol Cell       Date:  2000-12       Impact factor: 17.970

9.  Atm-deficient mice: a paradigm of ataxia telangiectasia.

Authors:  C Barlow; S Hirotsune; R Paylor; M Liyanage; M Eckhaus; F Collins; Y Shiloh; J N Crawley; T Ried; D Tagle; A Wynshaw-Boris
Journal:  Cell       Date:  1996-07-12       Impact factor: 41.582

10.  cDNA cloning and gene mapping of a candidate human cell cycle checkpoint protein.

Authors:  K A Cimprich; T B Shin; C T Keith; S L Schreiber
Journal:  Proc Natl Acad Sci U S A       Date:  1996-04-02       Impact factor: 11.205
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  137 in total

1.  Degradation of p53, not telomerase activation, by E6 is required for bypass of crisis and immortalization by human papillomavirus type 16 E6/E7.

Authors:  H R McMurray; D J McCance
Journal:  J Virol       Date:  2004-06       Impact factor: 5.103

2.  Profile of Tak Wah Mak.

Authors:  Jennifer Viegas
Journal:  Proc Natl Acad Sci U S A       Date:  2011-11-11       Impact factor: 11.205

3.  Structural characterization of inhibitor complexes with checkpoint kinase 2 (Chk2), a drug target for cancer therapy.

Authors:  George T Lountos; Andrew G Jobson; Joseph E Tropea; Christopher R Self; Guangtao Zhang; Yves Pommier; Robert H Shoemaker; David S Waugh
Journal:  J Struct Biol       Date:  2011-09-22       Impact factor: 2.867

4.  Role of ATM and the damage response mediator proteins 53BP1 and MDC1 in the maintenance of G(2)/M checkpoint arrest.

Authors:  Atsushi Shibata; Olivia Barton; Angela T Noon; Kirsten Dahm; Dorothee Deckbar; Aaron A Goodarzi; Markus Löbrich; Penny A Jeggo
Journal:  Mol Cell Biol       Date:  2010-04-26       Impact factor: 4.272

5.  Activation of checkpoint kinase 2 by 3,3'-diindolylmethane is required for causing G2/M cell cycle arrest in human ovarian cancer cells.

Authors:  Prabodh K Kandala; Sanjay K Srivastava
Journal:  Mol Pharmacol       Date:  2010-05-05       Impact factor: 4.436

6.  Crystal structure of checkpoint kinase 2 in complex with NSC 109555, a potent and selective inhibitor.

Authors:  George T Lountos; Joseph E Tropea; Di Zhang; Andrew G Jobson; Yves Pommier; Robert H Shoemaker; David S Waugh
Journal:  Protein Sci       Date:  2009-01       Impact factor: 6.725

7.  Sporadic activation of an oxidative stress-dependent NRF2-p53 signaling network in breast epithelial spheroids and premalignancies.

Authors:  Elizabeth J Pereira; Joseph S Burns; Christina Y Lee; Taylor Marohl; Delia Calderon; Lixin Wang; Kristen A Atkins; Chun-Chao Wang; Kevin A Janes
Journal:  Sci Signal       Date:  2020-04-14       Impact factor: 8.192

8.  p53 Binding protein 53BP1 is required for DNA damage responses and tumor suppression in mice.

Authors:  Irene M Ward; Kay Minn; Jan van Deursen; Junjie Chen
Journal:  Mol Cell Biol       Date:  2003-04       Impact factor: 4.272

9.  Status of p53 phosphorylation and function in sensitive and resistant human cancer models exposed to platinum-based DNA damaging agents.

Authors:  Kalpana Mujoo; Masayuki Watanabe; Junichi Nakamura; Abdul R Khokhar; Zahid H Siddik
Journal:  J Cancer Res Clin Oncol       Date:  2003-09-26       Impact factor: 4.553

10.  The tumor suppressor axis p53/miR-34a regulates Axl expression in B-cell chronic lymphocytic leukemia: implications for therapy in p53-defective CLL patients.

Authors:  J Boysen; S Sinha; T Price-Troska; S L Warner; D J Bearss; D Viswanatha; T D Shanafelt; N E Kay; A K Ghosh
Journal:  Leukemia       Date:  2013-10-18       Impact factor: 11.528
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