Literature DB >> 27908935

Posttranslational Regulation of Smads.

Pinglong Xu1, Xia Lin2, Xin-Hua Feng1,2,3.   

Abstract

Transforming growth factor β (TGF-β) family signaling dictates highly complex programs of gene expression responses, which are extensively regulated at multiple levels and vary depending on the physiological context. The formation, activation, and destruction of two major functional complexes in the TGF-β signaling pathway (i.e., the TGF-β receptor complexes and the Smad complexes that act as central mediators of TGF-β signaling) are direct targets for posttranslational regulation. Dysfunction of these complexes often leads or contributes to pathogenesis in cancer and fibrosis and in cardiovascular, and autoimmune diseases. Here we discuss recent insights into the roles of posttranslational modifications in the functions of the receptor-activated Smads in the common Smad4 and inhibitory Smads, and in the control of the physiological responses to TGF-β. It is now evident that these modifications act as decisive factors in defining the intensity and versatility of TGF-β responsiveness. Thus, the characterization of posttranslational modifications of Smads not only sheds light on how TGF-β controls physiological and pathological processes but may also guide us to manipulate the TGF-β responses for therapeutic benefits.
Copyright © 2016 Cold Spring Harbor Laboratory Press; all rights reserved.

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Year:  2016        PMID: 27908935      PMCID: PMC5131773          DOI: 10.1101/cshperspect.a022087

Source DB:  PubMed          Journal:  Cold Spring Harb Perspect Biol        ISSN: 1943-0264            Impact factor:   10.005


  180 in total

1.  Smad4 protein stability is regulated by ubiquitin ligase SCF beta-TrCP1.

Authors:  Mei Wan; Yi Tang; Ewan M Tytler; Chongyuan Lu; Bingwen Jin; Selwyn M Vickers; Lei Yang; Xingming Shi; Xu Cao
Journal:  J Biol Chem       Date:  2004-02-26       Impact factor: 5.157

2.  Hematopoiesis controlled by distinct TIF1gamma and Smad4 branches of the TGFbeta pathway.

Authors:  Wei He; David C Dorn; Hediye Erdjument-Bromage; Paul Tempst; Malcolm A S Moore; Joan Massagué
Journal:  Cell       Date:  2006-06-02       Impact factor: 41.582

3.  PPM1A functions as a Smad phosphatase to terminate TGFbeta signaling.

Authors:  Xia Lin; Xueyan Duan; Yao-Yun Liang; Ying Su; Katharine H Wrighton; Jianyin Long; Min Hu; Candi M Davis; Jinrong Wang; F Charles Brunicardi; Yigong Shi; Ye-Guang Chen; Anming Meng; Xin-Hua Feng
Journal:  Cell       Date:  2006-06-02       Impact factor: 41.582

4.  The DNA binding activities of Smad2 and Smad3 are regulated by coactivator-mediated acetylation.

Authors:  Maria Simonsson; Meena Kanduri; Eva Grönroos; Carl-Henrik Heldin; Johan Ericsson
Journal:  J Biol Chem       Date:  2006-10-30       Impact factor: 5.157

5.  Integrating patterning signals: Wnt/GSK3 regulates the duration of the BMP/Smad1 signal.

Authors:  Luis C Fuentealba; Edward Eivers; Atsushi Ikeda; Cecilia Hurtado; Hiroki Kuroda; Edgar M Pera; Edward M De Robertis
Journal:  Cell       Date:  2007-11-30       Impact factor: 41.582

6.  Sustained activation of SMAD3/SMAD4 by FOXM1 promotes TGF-β-dependent cancer metastasis.

Authors:  Jianfei Xue; Xia Lin; Wen-Tai Chiu; Yao-Hui Chen; Guanzhen Yu; Mingguang Liu; Xin-Hua Feng; Raymond Sawaya; René H Medema; Mien-Chie Hung; Suyun Huang
Journal:  J Clin Invest       Date:  2014-01-02       Impact factor: 14.808

7.  SCF(beta-TrCP1) controls Smad4 protein stability in pancreatic cancer cells.

Authors:  Mei Wan; Jin Huang; Nirag C Jhala; Ewan M Tytler; Lei Yang; Selwyn M Vickers; Yi Tang; Chongyuan Lu; Ning Wang; Xu Cao
Journal:  Am J Pathol       Date:  2005-05       Impact factor: 4.307

8.  Hypoxia-activated Smad3-specific dephosphorylation by PP2A.

Authors:  Pekka T Heikkinen; Marika Nummela; Suvi-Katri Leivonen; Jukka Westermarck; Caroline S Hill; Veli-Matti Kähäri; Panu M Jaakkola
Journal:  J Biol Chem       Date:  2009-12-01       Impact factor: 5.157

9.  Ligand-dependent ubiquitination of Smad3 is regulated by casein kinase 1 gamma 2, an inhibitor of TGF-beta signaling.

Authors:  X Guo; D S Waddell; W Wang; Z Wang; N T Liberati; S Yong; X Liu; X-F Wang
Journal:  Oncogene       Date:  2008-09-15       Impact factor: 9.867

10.  Overexpression of Smurf1 negatively regulates mouse embryonic lung branching morphogenesis by specifically reducing Smad1 and Smad5 proteins.

Authors:  Wei Shi; Hui Chen; Jianping Sun; Cheng Chen; Jingsong Zhao; Yan-Ling Wang; Kathryn D Anderson; David Warburton
Journal:  Am J Physiol Lung Cell Mol Physiol       Date:  2004-02       Impact factor: 5.464
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  32 in total

1.  Redirecting RNA splicing by SMAD3 turns TGF-β into a tumor promoter.

Authors:  Veenu Tripathi; Ying E Zhang
Journal:  Mol Cell Oncol       Date:  2016-12-07

Review 2.  Specificity, versatility, and control of TGF-β family signaling.

Authors:  Rik Derynck; Erine H Budi
Journal:  Sci Signal       Date:  2019-02-26       Impact factor: 8.192

Review 3.  TGF-β Family Signaling in Mesenchymal Differentiation.

Authors:  Ingo Grafe; Stefanie Alexander; Jonathan R Peterson; Taylor Nicholas Snider; Benjamin Levi; Brendan Lee; Yuji Mishina
Journal:  Cold Spring Harb Perspect Biol       Date:  2018-05-01       Impact factor: 10.005

4.  Protein arginine methyltransferase 1 mediates renal fibroblast activation and fibrogenesis through activation of Smad3 signaling.

Authors:  Yu Zhu; Chao Yu; Shougang Zhuang
Journal:  Am J Physiol Renal Physiol       Date:  2019-12-09

5.  PTPN3 acts as a tumor suppressor and boosts TGF-β signaling independent of its phosphatase activity.

Authors:  Bo Yuan; Jinquan Liu; Jin Cao; Yi Yu; Hanchenxi Zhang; Fei Wang; Yezhang Zhu; Mu Xiao; Sisi Liu; Youqiong Ye; Le Ma; Dewei Xu; Ningyi Xu; Yi Li; Bin Zhao; Pinglong Xu; Jianping Jin; Jianming Xu; Xi Chen; Li Shen; Xia Lin; Xin-Hua Feng
Journal:  EMBO J       Date:  2019-06-14       Impact factor: 11.598

Review 6.  Pathological implication of protein post-translational modifications in cancer.

Authors:  Sheng Pan; Ru Chen
Journal:  Mol Aspects Med       Date:  2022-04-07

7.  Arginine methylation of SMAD7 by PRMT1 in TGF-β-induced epithelial-mesenchymal transition and epithelial stem-cell generation.

Authors:  Yoko Katsuno; Jian Qin; Juan Oses-Prieto; Hongjun Wang; Olan Jackson-Weaver; Tingwei Zhang; Samy Lamouille; Jian Wu; Alma Burlingame; Jian Xu; Rik Derynck
Journal:  J Biol Chem       Date:  2018-06-15       Impact factor: 5.157

Review 8.  Intracellular and extracellular TGF-β signaling in cancer: some recent topics.

Authors:  Kohei Miyazono; Yoko Katsuno; Daizo Koinuma; Shogo Ehata; Masato Morikawa
Journal:  Front Med       Date:  2018-07-24       Impact factor: 4.592

9.  ALK phosphorylates SMAD4 on tyrosine to disable TGF-β tumour suppressor functions.

Authors:  Mu Xiao; Shuchen Gu; Yongxian Xu; Qianting Zhang; Ting Liu; Hao Li; Yi Yu; Lan Qin; Yezhang Zhu; Fenfang Chen; Yulong Wang; Chen Ding; Hongxing Wu; Hongbin Ji; Zhe Chen; Youli Zu; Stephen Malkoski; Yi Li; Tingbo Liang; Junfang Ji; Jun Qin; Pinglong Xu; Bin Zhao; Li Shen; Xia Lin; Xin-Hua Feng
Journal:  Nat Cell Biol       Date:  2019-01-21       Impact factor: 28.824

10.  Wip1 regulates Smad4 phosphorylation and inhibits TGF-β signaling.

Authors:  Dong-Seok Park; Gang-Ho Yoon; Eun-Young Kim; Taehyeong Lee; Kyuhee Kim; Peter Cw Lee; Eun-Ju Chang; Sun-Cheol Choi
Journal:  EMBO Rep       Date:  2020-02-27       Impact factor: 8.807
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