Literature DB >> 24390428

Allosteric Wip1 phosphatase inhibition through flap-subdomain interaction.

Aidan G Gilmartin1, Thomas H Faitg1, Mark Richter1, Arthur Groy1, Mark A Seefeld1, Michael G Darcy1, Xin Peng1, Kelly Federowicz1, Jingsong Yang1, Shu-Yun Zhang1, Elisabeth Minthorn1, Jon-Paul Jaworski2, Michael Schaber2, Stan Martens2, Dean E McNulty2, Robert H Sinnamon2, Hong Zhang2, Robert B Kirkpatrick2, Neysa Nevins2, Guanglei Cui2, Beth Pietrak2, Elsie Diaz2, Amber Jones2, Martin Brandt2, Benjamin Schwartz2, Dirk A Heerding1, Rakesh Kumar1.   

Abstract

Although therapeutic interventions of signal-transduction cascades with targeted kinase inhibitors are a well-established strategy, drug-discovery efforts to identify targeted phosphatase inhibitors have proven challenging. Herein we report a series of allosteric, small-molecule inhibitors of wild-type p53-induced phosphatase (Wip1), an oncogenic phosphatase common to multiple cancers. Compound binding to Wip1 is dependent on a 'flap' subdomain located near the Wip1 catalytic site that renders Wip1 structurally divergent from other members of the protein phosphatase 2C (PP2C) family and that thereby confers selectivity for Wip1 over other phosphatases. Treatment of tumor cells with the inhibitor GSK2830371 increases phosphorylation of Wip1 substrates and causes growth inhibition in both hematopoietic tumor cell lines and Wip1-amplified breast tumor cells harboring wild-type TP53. Oral administration of Wip1 inhibitors in mice results in expected pharmacodynamic effects and causes inhibition of lymphoma xenograft growth. To our knowledge, GSK2830371 is the first orally active, allosteric inhibitor of Wip1 phosphatase.

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Year:  2014        PMID: 24390428     DOI: 10.1038/nchembio.1427

Source DB:  PubMed          Journal:  Nat Chem Biol        ISSN: 1552-4450            Impact factor:   15.040


  32 in total

Review 1.  The therapeutic potential of phosphatase inhibitors.

Authors:  Viktor V Vintonyak; Andrey P Antonchick; Daniel Rauh; Herbert Waldmann
Journal:  Curr Opin Chem Biol       Date:  2009-05-04       Impact factor: 8.822

2.  The role of the MKK6/p38 MAPK pathway in Wip1-dependent regulation of ErbB2-driven mammary gland tumorigenesis.

Authors:  O N Demidov; C Kek; S Shreeram; O Timofeev; A J Fornace; E Appella; D V Bulavin
Journal:  Oncogene       Date:  2006-10-02       Impact factor: 9.867

3.  PPM1D is a potential target for 17q gain in neuroblastoma.

Authors:  Fumiko Saito-Ohara; Issei Imoto; Jun Inoue; Hajime Hosoi; Akira Nakagawara; Tohru Sugimoto; Johji Inazawa
Journal:  Cancer Res       Date:  2003-04-15       Impact factor: 12.701

4.  An alternate conformation and a third metal in PstP/Ppp, the M. tuberculosis PP2C-Family Ser/Thr protein phosphatase.

Authors:  Kristi E Pullen; Ho-Leung Ng; Pei-Yi Sung; Matthew C Good; Stephen M Smith; Tom Alber
Journal:  Structure       Date:  2004-11       Impact factor: 5.006

5.  Wip1 phosphatase-deficient mice exhibit defective T cell maturation due to sustained p53 activation.

Authors:  Marco L Schito; Oleg N Demidov; Shin'ichi Saito; Jonathan D Ashwell; Ettore Appella
Journal:  J Immunol       Date:  2006-04-15       Impact factor: 5.422

6.  The Wip1 phosphatase PPM1D dephosphorylates SQ/TQ motifs in checkpoint substrates phosphorylated by PI3K-like kinases.

Authors:  Hiroshi Yamaguchi; Stewart R Durell; Deb K Chatterjee; Carl W Anderson; Ettore Appella
Journal:  Biochemistry       Date:  2007-10-16       Impact factor: 3.162

7.  PPM1D gene amplification and overexpression in breast cancer: a qRT-PCR and chromogenic in situ hybridization study.

Authors:  Maryou B Lambros; Rachael Natrajan; Felipe C Geyer; Maria A Lopez-Garcia; Konstantin J Dedes; Kay Savage; Magali Lacroix-Triki; Robin L Jones; Christopher J Lord; Spiros Linardopoulos; Alan Ashworth; Jorge S Reis-Filho
Journal:  Mod Pathol       Date:  2010-06-11       Impact factor: 7.842

Review 8.  Regulation of the Wip1 phosphatase and its effects on the stress response.

Authors:  Julie Lowe; Hyukjin Cha; Mi-Ok Lee; Sharlyn J Mazur; Ettore Appella; Albert J Fornace
Journal:  Front Biosci (Landmark Ed)       Date:  2012-01-01

9.  PPM1D is a potential therapeutic target in ovarian clear cell carcinomas.

Authors:  David S P Tan; Maryou B K Lambros; Sydonia Rayter; Rachael Natrajan; Radost Vatcheva; Qiong Gao; Caterina Marchiò; Felipe C Geyer; Kay Savage; Suzanne Parry; Kerry Fenwick; Narinder Tamber; Alan Mackay; Tim Dexter; Charles Jameson; W Glenn McCluggage; Alistair Williams; Ashley Graham; Dana Faratian; Mona El-Bahrawy; Adam J Paige; Hani Gabra; Martin E Gore; Marketa Zvelebil; Christopher J Lord; Stanley B Kaye; Alan Ashworth; Jorge S Reis-Filho
Journal:  Clin Cancer Res       Date:  2009-03-17       Impact factor: 12.531

10.  A chemical inhibitor of PPM1D that selectively kills cells overexpressing PPM1D.

Authors:  S Rayter; R Elliott; J Travers; M G Rowlands; T B Richardson; K Boxall; K Jones; S Linardopoulos; P Workman; W Aherne; C J Lord; A Ashworth
Journal:  Oncogene       Date:  2007-08-13       Impact factor: 9.867
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  67 in total

1.  Enter the nucleus to exit the cycle.

Authors:  Lenno Krenning; René H Medema
Journal:  Cell Cycle       Date:  2014       Impact factor: 4.534

Review 2.  Exploiting replicative stress to treat cancer.

Authors:  Matthias Dobbelstein; Claus Storgaard Sørensen
Journal:  Nat Rev Drug Discov       Date:  2015-05-08       Impact factor: 84.694

Review 3.  DNA-encoded chemistry: enabling the deeper sampling of chemical space.

Authors:  Robert A Goodnow; Christoph E Dumelin; Anthony D Keefe
Journal:  Nat Rev Drug Discov       Date:  2016-12-09       Impact factor: 84.694

4.  DNA-Compatible [3 + 2] Nitrone-Olefin Cycloaddition Suitable for DEL Syntheses.

Authors:  Christopher J Gerry; Zhenhua Yang; Michele Stasi; Stuart L Schreiber
Journal:  Org Lett       Date:  2019-02-14       Impact factor: 6.005

5.  Phosphatases reverse p53-mediated cell cycle checkpoints.

Authors:  Lawrence A Donehower
Journal:  Proc Natl Acad Sci U S A       Date:  2014-05-07       Impact factor: 11.205

6.  DNA Barcoding a Complete Matrix of Stereoisomeric Small Molecules.

Authors:  Christopher J Gerry; Mathias J Wawer; Paul A Clemons; Stuart L Schreiber
Journal:  J Am Chem Soc       Date:  2019-06-25       Impact factor: 15.419

Review 7.  Oncogene addiction: pathways of therapeutic response, resistance, and road maps toward a cure.

Authors:  Raymond Pagliarini; Wenlin Shao; William R Sellers
Journal:  EMBO Rep       Date:  2015-02-13       Impact factor: 8.807

8.  Inhibition of mutant PPM1D enhances DNA damage response and growth suppressive effects of ionizing radiation in diffuse intrinsic pontine glioma.

Authors:  Mwangala Precious Akamandisa; Kai Nie; Rita Nahta; Dolores Hambardzumyan; Robert Craig Castellino
Journal:  Neuro Oncol       Date:  2019-06-10       Impact factor: 12.300

9.  Allosteric inhibition of SHP2 phosphatase inhibits cancers driven by receptor tyrosine kinases.

Authors:  Ying-Nan P Chen; Matthew J LaMarche; Ho Man Chan; Peter Fekkes; Jorge Garcia-Fortanet; Michael G Acker; Brandon Antonakos; Christine Hiu-Tung Chen; Zhouliang Chen; Vesselina G Cooke; Jason R Dobson; Zhan Deng; Feng Fei; Brant Firestone; Michelle Fodor; Cary Fridrich; Hui Gao; Denise Grunenfelder; Huai-Xiang Hao; Jaison Jacob; Samuel Ho; Kathy Hsiao; Zhao B Kang; Rajesh Karki; Mitsunori Kato; Jay Larrow; Laura R La Bonte; Francois Lenoir; Gang Liu; Shumei Liu; Dyuti Majumdar; Matthew J Meyer; Mark Palermo; Lawrence Perez; Minying Pu; Edmund Price; Christopher Quinn; Subarna Shakya; Michael D Shultz; Joanna Slisz; Kavitha Venkatesan; Ping Wang; Markus Warmuth; Sarah Williams; Guizhi Yang; Jing Yuan; Ji-Hu Zhang; Ping Zhu; Timothy Ramsey; Nicholas J Keen; William R Sellers; Travis Stams; Pascal D Fortin
Journal:  Nature       Date:  2016-06-29       Impact factor: 49.962

10.  Identification of PPM1D as an essential Ulk1 phosphatase for genotoxic stress-induced autophagy.

Authors:  Satoru Torii; Tatsushi Yoshida; Satoko Arakawa; Shinya Honda; Akira Nakanishi; Shigeomi Shimizu
Journal:  EMBO Rep       Date:  2016-09-26       Impact factor: 8.807
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