Literature DB >> 25381821

Wip1 phosphatase in breast cancer.

A Emelyanov1, D V Bulavin1,2.   

Abstract

Understanding the factors contributing to tumor initiation, progression and evolution is of paramount significance. Among them, wild-type p53-induced phosphatase 1 (Wip1) is emerging as an important oncogene by virtue of its negative control on several key tumor suppressor pathways. Originally discovered as a p53-regulated gene, Wip1 has been subsequently found amplified and more recently mutated in a significant fraction of human cancers including breast tumors. Recent development in the field further uncovered the utility of anti-Wip1-directed therapies in delaying tumor onset or in reducing the tumor burden. Furthermore, Wip1 could be an important factor that contributes to tumor heterogeneity, suggesting that its inhibition may decrease the rate of cancer evolution. These effects depend on several signaling pathways modulated by Wip1 phosphatase in a spatial and temporal manner. In this review we discuss the recent development in understanding how Wip1 contributes to tumorigenesis with its relevance to breast cancer.

Entities:  

Mesh:

Substances:

Year:  2014        PMID: 25381821     DOI: 10.1038/onc.2014.375

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


  169 in total

Review 1.  Keeping abreast of the mammary epithelial hierarchy and breast tumorigenesis.

Authors:  Jane E Visvader
Journal:  Genes Dev       Date:  2009-11-15       Impact factor: 11.361

2.  Distinct phosphatases antagonize the p53 response in different phases of the cell cycle.

Authors:  Indra A Shaltiel; Melinda Aprelia; Adrian T Saurin; Dipanjan Chowdhury; Geert J P L Kops; Emile E Voest; René H Medema
Journal:  Proc Natl Acad Sci U S A       Date:  2014-04-07       Impact factor: 11.205

3.  A small molecule inhibitor of p53-inducible protein phosphatase PPM1D.

Authors:  Hiroaki Yagi; Yoshiro Chuman; Yuuki Kozakai; Toshiaki Imagawa; Yu Takahashi; Fumihiko Yoshimura; Keiji Tanino; Kazuyasu Sakaguchi
Journal:  Bioorg Med Chem Lett       Date:  2011-10-31       Impact factor: 2.823

4.  The oncogenic phosphatase PPM1D confers cisplatin resistance in ovarian carcinoma cells by attenuating checkpoint kinase 1 and p53 activation.

Authors:  A Y Ali; M R Abedini; B K Tsang
Journal:  Oncogene       Date:  2011-09-19       Impact factor: 9.867

5.  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

6.  Stat5a is mandatory for adult mammary gland development and lactogenesis.

Authors:  X Liu; G W Robinson; K U Wagner; L Garrett; A Wynshaw-Boris; L Hennighausen
Journal:  Genes Dev       Date:  1997-01-15       Impact factor: 11.361

7.  Comprehensive genomic analysis of desmoplastic medulloblastomas: identification of novel amplified genes and separate evaluation of the different histological components.

Authors:  A Ehrbrecht; U Müller; M Wolter; A Hoischen; A Koch; B Radlwimmer; B Actor; A Mincheva; T Pietsch; P Lichter; G Reifenberger; R G Weber
Journal:  J Pathol       Date:  2006-03       Impact factor: 7.996

8.  MicroRNA expression analysis of mammospheres cultured from human breast cancers.

Authors:  Nan Feifei; Zhang Mingzhi; Zhang Yanyun; Zhang Huanle; Ren Fang; Huang Mingzhu; Cao Mingzhi; Shi Yafei; Zhang Fengchun
Journal:  J Cancer Res Clin Oncol       Date:  2012-07-03       Impact factor: 4.553

9.  Notch2 genetic fate mapping reveals two previously unrecognized mammary epithelial lineages.

Authors:  Sanja Šale; Daniel Lafkas; Spyros Artavanis-Tsakonas
Journal:  Nat Cell Biol       Date:  2013-04-21       Impact factor: 28.824

Review 10.  The DNA damage response and cancer therapy.

Authors:  Christopher J Lord; Alan Ashworth
Journal:  Nature       Date:  2012-01-18       Impact factor: 49.962
View more
  17 in total

1.  Role of wild-type p53-induced phosphatase 1 in cancer.

Authors:  Zhi-Peng Wang; Ye Tian; Jun Lin
Journal:  Oncol Lett       Date:  2017-07-27       Impact factor: 2.967

2.  Integrative Proteomic and Phosphoproteomic Profiling of Testis from Wip1 Phosphatase-Knockout Mice: Insights into Mechanisms of Reduced Fertility.

Authors:  Yinghui Wei; Qian Gao; Pengxia Niu; Kui Xu; Yiqing Qiu; Yanqing Hu; Shasha Liu; Xue Zhang; Miaoying Yu; Zhiguo Liu; Bingyuan Wang; Yulian Mu; Kui Li
Journal:  Mol Cell Proteomics       Date:  2018-10-25       Impact factor: 5.911

3.  Systematic characterization of mutations altering protein degradation in human cancers.

Authors:  Collin Tokheim; Xiaoqing Wang; Richard T Timms; Boning Zhang; Elijah L Mena; Binbin Wang; Cynthia Chen; Jun Ge; Jun Chu; Wubing Zhang; Stephen J Elledge; Myles Brown; X Shirley Liu
Journal:  Mol Cell       Date:  2021-02-09       Impact factor: 19.328

Review 4.  Targeting the Checkpoint to Kill Cancer Cells.

Authors:  Jan Benada; Libor Macurek
Journal:  Biomolecules       Date:  2015-08-18

5.  Wip1 is associated with tumorigenity and metastasis through MMP-2 in human intrahepatic cholangiocarcinoma.

Authors:  Sulai Liu; Bo Jiang; Hao Li; Zili He; Pin Lv; Chuang Peng; Yonggang Wang; Wei Cheng; Zhengquan Xu; Wei Chen; Zhengkai Liu; Bao Zhang; Shengqian Shen; Shuanglin Xiang
Journal:  Oncotarget       Date:  2017-05-23

6.  Wip1 Deficiency Promotes Neutrophil Recruitment to the Infection Site and Improves Sepsis Outcome.

Authors:  Xiao-Fei Shen; Yang Zhao; Ke Cao; Wen-Xian Guan; Xue Li; Qian Zhang; Yong Zhao; Yi-Tao Ding; Jun-Feng Du
Journal:  Front Immunol       Date:  2017-08-22       Impact factor: 7.561

7.  Wip1-dependent modulation of macrophage migration and phagocytosis.

Authors:  Yiting Tang; Bing Pan; Xin Zhou; Kai Xiong; Qian Gao; Lei Huang; Ying Xia; Ming Shen; Shulin Yang; Honglin Liu; Tao Tan; Jianjie Ma; Xuehong Xu; Yulian Mu; Kui Li
Journal:  Redox Biol       Date:  2017-08-12       Impact factor: 11.799

8.  Inhibition of WIP1 phosphatase sensitizes breast cancer cells to genotoxic stress and to MDM2 antagonist nutlin-3.

Authors:  Sona Pechackova; Kamila Burdova; Jan Benada; Petra Kleiblova; Gabriela Jenikova; Libor Macurek
Journal:  Oncotarget       Date:  2016-03-22

Review 9.  Wip1 phosphatase: between p53 and MAPK kinases pathways.

Authors:  Anastasia R Goloudina; Elena Y Kochetkova; Tatyana V Pospelova; Oleg N Demidov
Journal:  Oncotarget       Date:  2016-05-24

10.  MicroRNA16 regulates glioma cell proliferation, apoptosis and invasion by targeting Wip1-ATM-p53 feedback loop.

Authors:  Xiao-Hong Zhan; Qiu-Yan Xu; Rui Tian; Hong Yan; Min Zhang; Jing Wu; Wei Wang; Jie He
Journal:  Oncotarget       Date:  2017-06-16
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.