Literature DB >> 26456828

Identification of and Molecular Basis for SIRT6 Loss-of-Function Point Mutations in Cancer.

Sita Kugel1, Jessica L Feldman2, Mark A Klein2, Dafne M Silberman3, Carlos Sebastián1, Craig Mermel4, Stephanie Dobersch5, Abbe R Clark1, Gad Getz4, John M Denu6, Raul Mostoslavsky7.   

Abstract

Chromatin factors have emerged as the most frequently dysregulated family of proteins in cancer. We have previously identified the histone deacetylase SIRT6 as a key tumor suppressor, yet whether point mutations are selected for in cancer remains unclear. In this manuscript, we characterized naturally occurring patient-derived SIRT6 mutations. Strikingly, all the mutations significantly affected either stability or catalytic activity of SIRT6, indicating that these mutations were selected for in these tumors. Further, the mutant proteins failed to rescue sirt6 knockout (SIRT6 KO) cells, as measured by the levels of histone acetylation at glycolytic genes and their inability to rescue the tumorigenic potential of these cells. Notably, the main activity affected in the mutants was histone deacetylation rather than demyristoylation, pointing to the former as the main tumor-suppressive function for SIRT6. Our results identified cancer-associated point mutations in SIRT6, cementing its function as a tumor suppressor in human cancer.
Copyright © 2015 The Authors. Published by Elsevier Inc. All rights reserved.

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Year:  2015        PMID: 26456828      PMCID: PMC4618237          DOI: 10.1016/j.celrep.2015.09.022

Source DB:  PubMed          Journal:  Cell Rep            Impact factor:   9.423


  19 in total

1.  On the origin of cancer cells.

Authors:  O WARBURG
Journal:  Science       Date:  1956-02-24       Impact factor: 47.728

2.  Genomic instability and aging-like phenotype in the absence of mammalian SIRT6.

Authors:  Raul Mostoslavsky; Katrin F Chua; David B Lombard; Wendy W Pang; Miriam R Fischer; Lionel Gellon; Pingfang Liu; Gustavo Mostoslavsky; Sonia Franco; Michael M Murphy; Kevin D Mills; Parin Patel; Joyce T Hsu; Andrew L Hong; Ethan Ford; Hwei-Ling Cheng; Caitlin Kennedy; Nomeli Nunez; Roderick Bronson; David Frendewey; Wojtek Auerbach; David Valenzuela; Margaret Karow; Michael O Hottiger; Stephen Hursting; J Carl Barrett; Leonard Guarente; Richard Mulligan; Bruce Demple; George D Yancopoulos; Frederick W Alt
Journal:  Cell       Date:  2006-01-27       Impact factor: 41.582

3.  Silent information regulator 2 family of NAD- dependent histone/protein deacetylases generates a unique product, 1-O-acetyl-ADP-ribose.

Authors:  K G Tanner; J Landry; R Sternglanz; J M Denu
Journal:  Proc Natl Acad Sci U S A       Date:  2000-12-19       Impact factor: 11.205

4.  Functional dissection of SIRT6: identification of domains that regulate histone deacetylase activity and chromatin localization.

Authors:  Ruth I Tennen; Elisabeth Berber; Katrin F Chua
Journal:  Mech Ageing Dev       Date:  2010-02-01       Impact factor: 5.432

5.  Mechanism of sirtuin inhibition by nicotinamide: altering the NAD(+) cosubstrate specificity of a Sir2 enzyme.

Authors:  José L Avalos; Katherine M Bever; Cynthia Wolberger
Journal:  Mol Cell       Date:  2005-03-18       Impact factor: 17.970

6.  Deacetylase activity is required for STAT5-dependent GM-CSF functional activity in macrophages and differentiation to dendritic cells.

Authors:  Carlos Sebastián; Maria Serra; Andrée Yeramian; Neus Serrat; Jorge Lloberas; Antonio Celada
Journal:  J Immunol       Date:  2008-05-01       Impact factor: 5.422

7.  SIRT6 is a histone H3 lysine 9 deacetylase that modulates telomeric chromatin.

Authors:  Eriko Michishita; Ronald A McCord; Elisabeth Berber; Mitomu Kioi; Hesed Padilla-Nash; Mara Damian; Peggie Cheung; Rika Kusumoto; Tiara L A Kawahara; J Carl Barrett; Howard Y Chang; Vilhelm A Bohr; Thomas Ried; Or Gozani; Katrin F Chua
Journal:  Nature       Date:  2008-03-12       Impact factor: 49.962

8.  Investigating the ADP-ribosyltransferase activity of sirtuins with NAD analogues and 32P-NAD.

Authors:  Jintang Du; Hong Jiang; Hening Lin
Journal:  Biochemistry       Date:  2009-04-07       Impact factor: 3.162

9.  SIRT6 links histone H3 lysine 9 deacetylation to NF-kappaB-dependent gene expression and organismal life span.

Authors:  Tiara L A Kawahara; Eriko Michishita; Adam S Adler; Mara Damian; Elisabeth Berber; Meihong Lin; Ron A McCord; Kristine C L Ongaigui; Lisa D Boxer; Howard Y Chang; Katrin F Chua
Journal:  Cell       Date:  2009-01-09       Impact factor: 41.582

10.  The histone deacetylase Sirt6 regulates glucose homeostasis via Hif1alpha.

Authors:  Lei Zhong; Agustina D'Urso; Debra Toiber; Carlos Sebastian; Ryan E Henry; Douangsone D Vadysirisack; Alexander Guimaraes; Brett Marinelli; Jakob D Wikstrom; Tomer Nir; Clary B Clish; Bhavapriya Vaitheesvaran; Othon Iliopoulos; Irwin Kurland; Yuval Dor; Ralph Weissleder; Orian S Shirihai; Leif W Ellisen; Joaquin M Espinosa; Raul Mostoslavsky
Journal:  Cell       Date:  2010-01-22       Impact factor: 41.582
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  29 in total

Review 1.  SIRT6, a Mammalian Deacylase with Multitasking Abilities.

Authors:  Andrew R Chang; Christina M Ferrer; Raul Mostoslavsky
Journal:  Physiol Rev       Date:  2019-08-22       Impact factor: 37.312

2.  Mammalian target of rapamycin complex 2 (mTORC2) controls glycolytic gene expression by regulating Histone H3 Lysine 56 acetylation.

Authors:  Raghavendra Vadla; Devyani Haldar
Journal:  Cell Cycle       Date:  2018-01-08       Impact factor: 4.534

Review 3.  Metabolic programming of the epigenome: host and gut microbial metabolite interactions with host chromatin.

Authors:  Kimberly A Krautkramer; Rashpal S Dhillon; John M Denu; Hannah V Carey
Journal:  Transl Res       Date:  2017-09-01       Impact factor: 7.012

4.  Inhibition of Sirt6 suppresses tumor growth by inducing G1/S phase arrest in renal cancer cells.

Authors:  Yu Ding; Sisi Wu; Yuwei Huo; Xuemei Chen; Li Chai; Yan Wang; Xiangxiu Wang; Guonian Zhu; Wei Jiang
Journal:  Int J Clin Exp Pathol       Date:  2019-07-01

5.  SIRT6 deacetylates PKM2 to suppress its nuclear localization and oncogenic functions.

Authors:  Abhishek Bhardwaj; Sanjeev Das
Journal:  Proc Natl Acad Sci U S A       Date:  2016-01-19       Impact factor: 11.205

6.  SIRT6 is a DNA double-strand break sensor.

Authors:  Lior Onn; Miguel Portillo; Stefan Ilic; Gal Cleitman; Daniel Stein; Shai Kaluski; Ido Shirat; Zeev Slobodnik; Monica Einav; Fabian Erdel; Barak Akabayov; Debra Toiber
Journal:  Elife       Date:  2020-01-29       Impact factor: 8.140

7.  Identification of TRA2B-DNAH5 fusion as a novel oncogenic driver in human lung squamous cell carcinoma.

Authors:  Fei Li; Zhaoyuan Fang; Jian Zhang; Chen Li; Hongyan Liu; Jufeng Xia; Hongwen Zhu; Chenchen Guo; Zhen Qin; Fuming Li; Xiangkun Han; Yuetong Wang; Yan Feng; Ye Wang; Wenjing Zhang; Zuoyun Wang; Yujuan Jin; Yihua Sun; Wenyi Wei; Rong Zeng; Haiquan Chen; Hongbin Ji
Journal:  Cell Res       Date:  2016-09-27       Impact factor: 25.617

8.  SIRT6 Suppresses Pancreatic Cancer through Control of Lin28b.

Authors:  Sita Kugel; Carlos Sebastián; Julien Fitamant; Kenneth N Ross; Supriya K Saha; Esha Jain; Adrianne Gladden; Kshitij S Arora; Yasutaka Kato; Miguel N Rivera; Sridhar Ramaswamy; Ruslan I Sadreyev; Alon Goren; Vikram Deshpande; Nabeel Bardeesy; Raul Mostoslavsky
Journal:  Cell       Date:  2016-05-12       Impact factor: 41.582

Review 9.  NAD+ homeostasis in health and disease.

Authors:  Mario Romani; Dina Hofer; Elena Katsyuba; Johan Auwerx
Journal:  Nat Metab       Date:  2020-01-20

Review 10.  NAD+ metabolism: pathophysiologic mechanisms and therapeutic potential.

Authors:  Na Xie; Lu Zhang; Wei Gao; Canhua Huang; Peter Ernst Huber; Xiaobo Zhou; Changlong Li; Guobo Shen; Bingwen Zou
Journal:  Signal Transduct Target Ther       Date:  2020-10-07
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