Literature DB >> 22665267

Dysfunction of nucleus accumbens-1 activates cellular senescence and inhibits tumor cell proliferation and oncogenesis.

Yi Zhang1, Yan Cheng, Xingcong Ren, Tsukasa Hori, Kathryn J Huber-Keener, Li Zhang, Kai Lee Yap, David Liu, Lisa Shantz, Zheng-Hong Qin, Suping Zhang, Jianrong Wang, Hong-Gang Wang, Ie-Ming Shih, Jin-Ming Yang.   

Abstract

Nucleus accumbens-1 (NAC1), a nuclear factor belonging to the BTB/POZ gene family, has emerging roles in cancer. We report here that NAC1 acts as a negative regulator of cellular senescence in transformed and nontransformed cells, and dysfunction of NAC1 induces senescence and inhibits its oncogenic potential. We show that NAC1 deficiency markedly activates senescence and inhibits proliferation in tumor cells treated with sublethal doses of γ-irradiation. In mouse embryonic fibroblasts from NAC1 knockout mice, following infection with a Ras virus, NAC1-/- cells undergo significantly more senescence and are either nontransformed or less transformed in vitro and less tumorigenic in vivo when compared with NAC1+/+ cells. Furthermore, we show that the NAC1-caused senescence blunting is mediated by ΔNp63, which exerts its effect on senescence through p21, and that NAC1 activates transcription of ΔNp63 under stressful conditions. Our results not only reveal a previously unrecognized function of NAC1, the molecular pathway involved and its impact on pathogenesis of tumor initiation and development, but also identify a novel senescence regulator that may be exploited as a potential target for cancer prevention and treatment. ©2012 AACR.

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Year:  2012        PMID: 22665267      PMCID: PMC3614094          DOI: 10.1158/0008-5472.CAN-12-0139

Source DB:  PubMed          Journal:  Cancer Res        ISSN: 0008-5472            Impact factor:   12.701


  37 in total

1.  Skp2 targeting suppresses tumorigenesis by Arf-p53-independent cellular senescence.

Authors:  Hui-Kuan Lin; Zhenbang Chen; Guocan Wang; Caterina Nardella; Szu-Wei Lee; Chia-Hsin Chan; Chan-Hsin Chan; Wei-Lei Yang; Jing Wang; Ainara Egia; Keiichi I Nakayama; Carlos Cordon-Cardo; Julie Teruya-Feldstein; Pier Paolo Pandolfi
Journal:  Nature       Date:  2010-03-18       Impact factor: 49.962

2.  PTEN status switches cell fate between premature senescence and apoptosis in glioma exposed to ionizing radiation.

Authors:  J-J Lee; B C Kim; M-J Park; Y-S Lee; Y-N Kim; B L Lee; J-S Lee
Journal:  Cell Death Differ       Date:  2010-11-12       Impact factor: 15.828

Review 3.  Cellular senescence in the development and treatment of cancer.

Authors:  Gabriele Saretzki
Journal:  Curr Pharm Des       Date:  2010-01       Impact factor: 3.116

4.  Biological role and prognostic significance of NAC1 in ovarian cancer.

Authors:  Kentaro Nakayama; Mohammed Tanjimur Rahman; Munmun Rahman; Shamima Yeasmin; Masako Ishikawa; Atsuko Katagiri; Kouji Iida; Naomi Nakayama; Kohji Miyazaki
Journal:  Gynecol Oncol       Date:  2010-09-24       Impact factor: 5.482

5.  ΔNp63α is an oncogene that targets chromatin remodeler Lsh to drive skin stem cell proliferation and tumorigenesis.

Authors:  William M Keyes; Matteo Pecoraro; Victoria Aranda; Emma Vernersson-Lindahl; Wangzhi Li; Hannes Vogel; Xuecui Guo; Elvin L Garcia; Tatyana V Michurina; Grigori Enikolopov; Senthil K Muthuswamy; Alea A Mills
Journal:  Cell Stem Cell       Date:  2011-02-04       Impact factor: 24.633

6.  Repression of human papillomavirus oncogenes in HeLa cervical carcinoma cells causes the orderly reactivation of dormant tumor suppressor pathways.

Authors:  E C Goodwin; D DiMaio
Journal:  Proc Natl Acad Sci U S A       Date:  2000-11-07       Impact factor: 11.205

7.  IGF1 activates cell cycle arrest following irradiation by reducing binding of ΔNp63 to the p21 promoter.

Authors:  G C Mitchell; J L Fillinger; S Sittadjody; J L Avila; R Burd; K H Limesand
Journal:  Cell Death Dis       Date:  2010       Impact factor: 8.469

8.  Dysregulated ΔNp63α inhibits expression of Ink4a/arf, blocks senescence, and promotes malignant conversion of keratinocytes.

Authors:  Linan Ha; Roshini M Ponnamperuma; Steven Jay; M Stacey Ricci; Wendy C Weinberg
Journal:  PLoS One       Date:  2011-07-15       Impact factor: 3.240

9.  NAC1 modulates sensitivity of ovarian cancer cells to cisplatin by altering the HMGB1-mediated autophagic response.

Authors:  Y Zhang; Y Cheng; X Ren; L Zhang; K L Yap; H Wu; R Patel; D Liu; Z-H Qin; I-M Shih; J-M Yang
Journal:  Oncogene       Date:  2011-07-11       Impact factor: 9.867

10.  Amplification of the ch19p13.2 NACC1 locus in ovarian high-grade serous carcinoma.

Authors:  Ie-Ming Shih; Kentaro Nakayama; Gang Wu; Naomi Nakayama; Jinghui Zhang; Tian-Li Wang
Journal:  Mod Pathol       Date:  2011-01-14       Impact factor: 7.842
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  18 in total

1.  Identification of the NAC1-regulated genes in ovarian cancer.

Authors:  Min Gao; Ren-Chin Wu; Alice L Herlinger; Kailee Yap; Jung-Won Kim; Tian-Li Wang; Ie-Ming Shih
Journal:  Am J Pathol       Date:  2013-11-06       Impact factor: 4.307

2.  Identification of a small-molecule compound that inhibits homodimerization of oncogenic NAC1 protein and sensitizes cancer cells to anticancer agents.

Authors:  XiaoHui Wang; Cheng Ji; HongHan Zhang; Yu Shan; YiJie Ren; YanWei Hu; LiangRong Shi; LingChuan Guo; WeiDong Zhu; YuJuan Xia; BeiJia Liu; ZiYun Rong; BiLian Wu; ZhiJun Ming; XingCong Ren; JianXun Song; JinMing Yang; Yi Zhang
Journal:  J Biol Chem       Date:  2019-05-17       Impact factor: 5.157

3.  miR-339-5p inhibits migration and invasion in ovarian cancer cell lines by targeting NACC1 and BCL6.

Authors:  Weiwei Shan; Jun Li; Yang Bai; Xin Lu
Journal:  Tumour Biol       Date:  2015-11-09

4.  NAC1 promotes the migration of prostate cancer cells and participates in osteoclastogenesis by negatively regulating IFNβ.

Authors:  Fang Chen; Yinghao Yin; Zhifeng Yan; Ke Cao; Kuangbiao Zhong
Journal:  Oncol Lett       Date:  2017-12-20       Impact factor: 2.967

5.  Nucleus accumbens-associated protein-1 promotes glycolysis and survival of hypoxic tumor cells via the HDAC4-HIF-1α axis.

Authors:  Y Zhang; Y-J Ren; L-C Guo; C Ji; J Hu; H-H Zhang; Q-H Xu; W-D Zhu; Z-J Ming; Y-S Yuan; X Ren; J Song; J-M Yang
Journal:  Oncogene       Date:  2017-03-20       Impact factor: 9.867

6.  Overexpression of NAC1 confers drug resistance via HOXA9 in colorectal carcinoma cells.

Authors:  Tongfa Ju; Huicheng Jin; Rongchao Ying; Qi Xie; Chunhua Zhou; Daquan Gao
Journal:  Mol Med Rep       Date:  2017-07-14       Impact factor: 2.952

7.  Nac1 promotes self-renewal of embryonic stem cells through direct transcriptional regulation of c-Myc.

Authors:  Yan Ruan; Jianrong He; Wei Wu; Ping He; Yanping Tian; Lan Xiao; Gaoke Liu; Jiali Wang; Yuda Cheng; Shuo Zhang; Yi Yang; Jiaxiang Xiong; Ke Zhao; Ying Wan; He Huang; Junlei Zhang; Rui Jian
Journal:  Oncotarget       Date:  2017-07-18

8.  Loss of NAC1 expression is associated with defective bony patterning in the murine vertebral axis.

Authors:  Kai Lee Yap; Polina Sysa-Shah; Brad Bolon; Ren-Chin Wu; Min Gao; Alice L Herlinger; Fengying Wang; Francesco Faiola; David Huso; Kathleen Gabrielson; Tian-Li Wang; Jianlong Wang; Ie-Ming Shih
Journal:  PLoS One       Date:  2013-07-26       Impact factor: 3.240

9.  Nac1 interacts with the POZ-domain transcription factor, Miz1.

Authors:  Mark A Stead; Stephanie C Wright
Journal:  Biosci Rep       Date:  2014-06-05       Impact factor: 3.840

10.  Effect of taxol on the expression of FoxM1 ovarian cancer-associated gene.

Authors:  Zeng Liu; Y U Xiao; Siqing Ning; Zhao Yuan Li; Yuanyuan Zhu; Gang Hu
Journal:  Oncol Lett       Date:  2016-04-22       Impact factor: 2.967
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