Literature DB >> 23142079

The deacetylase Sirt6 activates the acetyltransferase GCN5 and suppresses hepatic gluconeogenesis.

John E Dominy1, Yoonjin Lee, Mark P Jedrychowski, Helen Chim, Michael J Jurczak, Joao Paulo Camporez, Hai-Bin Ruan, Jessica Feldman, Kerry Pierce, Raul Mostoslavsky, John M Denu, Clary B Clish, Xiaoyong Yang, Gerald I Shulman, Steven P Gygi, Pere Puigserver.   

Abstract

Hepatic glucose production (HGP) maintains blood glucose levels during fasting but can also exacerbate diabetic hyperglycemia. HGP is dynamically controlled by a signaling/transcriptional network that regulates the expression/activity of gluconeogenic enzymes. A key mediator of gluconeogenic gene transcription is PGC-1α. PGC-1α's activation of gluconeogenic gene expression is dependent upon its acetylation state, which is controlled by the acetyltransferase GCN5 and the deacetylase Sirt1. Nevertheless, whether other chromatin modifiers-particularly other sirtuins-can modulate PGC-1α acetylation is currently unknown. Herein, we report that Sirt6 strongly controls PGC-1α acetylation. Surprisingly, Sirt6 induces PGC-1α acetylation and suppresses HGP. Sirt6 depletion decreases PGC-1α acetylation and promotes HGP. These acetylation effects are GCN5 dependent: Sirt6 interacts with and modifies GCN5, enhancing GCN5's activity. Lepr(db/db) mice, an obese/diabetic animal model, exhibit reduced Sirt6 levels; ectopic re-expression suppresses gluconeogenic genes and normalizes glycemia. Activation of hepatic Sirt6 may therefore be therapeutically useful for treating insulin-resistant diabetes.
Copyright © 2012 Elsevier Inc. All rights reserved.

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Year:  2012        PMID: 23142079      PMCID: PMC3534905          DOI: 10.1016/j.molcel.2012.09.030

Source DB:  PubMed          Journal:  Mol Cell        ISSN: 1097-2765            Impact factor:   17.970


  33 in total

1.  Crystal structure of a binary complex between human GCN5 histone acetyltransferase domain and acetyl coenzyme A.

Authors:  Anja Schuetz; Galina Bernstein; Aiping Dong; Tatiana Antoshenko; Hong Wu; Peter Loppnau; Alexey Bochkarev; Alexander N Plotnikov
Journal:  Proteins       Date:  2007-07-01

2.  The genetic ablation of SRC-3 protects against obesity and improves insulin sensitivity by reducing the acetylation of PGC-1{alpha}.

Authors:  Agnès Coste; Jean-Francois Louet; Marie Lagouge; Carles Lerin; Maria Cristina Antal; Hamid Meziane; Kristina Schoonjans; Pere Puigserver; Bert W O'Malley; Johan Auwerx
Journal:  Proc Natl Acad Sci U S A       Date:  2008-10-28       Impact factor: 11.205

3.  A continuous microplate assay for sirtuins and nicotinamide-producing enzymes.

Authors:  Brian C Smith; William C Hallows; John M Denu
Journal:  Anal Biochem       Date:  2009-07-16       Impact factor: 3.365

4.  AMPK regulates energy expenditure by modulating NAD+ metabolism and SIRT1 activity.

Authors:  Carles Cantó; Zachary Gerhart-Hines; Jerome N Feige; Marie Lagouge; Lilia Noriega; Jill C Milne; Peter J Elliott; Pere Puigserver; Johan Auwerx
Journal:  Nature       Date:  2009-04-23       Impact factor: 49.962

5.  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

6.  Akt/PKB regulates hepatic metabolism by directly inhibiting PGC-1alpha transcription coactivator.

Authors:  Xinghai Li; Bobby Monks; Qingyuan Ge; Morris J Birnbaum
Journal:  Nature       Date:  2007-06-06       Impact factor: 49.962

7.  Cdc2-like kinase 2 is an insulin-regulated suppressor of hepatic gluconeogenesis.

Authors:  Joseph T Rodgers; Wilhelm Haas; Steven P Gygi; Pere Puigserver
Journal:  Cell Metab       Date:  2010-01       Impact factor: 27.287

8.  SCFCdc4 acts antagonistically to the PGC-1alpha transcriptional coactivator by targeting it for ubiquitin-mediated proteolysis.

Authors:  Brian L Olson; M Benjamin Hock; Susanna Ekholm-Reed; James A Wohlschlegel; Kumlesh K Dev; Anastasia Kralli; Steven I Reed
Journal:  Genes Dev       Date:  2008-01-15       Impact factor: 11.361

9.  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

10.  A fasting inducible switch modulates gluconeogenesis via activator/coactivator exchange.

Authors:  Yi Liu; Renaud Dentin; Danica Chen; Susan Hedrick; Kim Ravnskjaer; Simon Schenk; Jill Milne; David J Meyers; Phil Cole; John Yates; Jerrold Olefsky; Leonard Guarente; Marc Montminy
Journal:  Nature       Date:  2008-10-05       Impact factor: 49.962
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  115 in total

Review 1.  Protein acetylation in metabolism - metabolites and cofactors.

Authors:  Keir J Menzies; Hongbo Zhang; Elena Katsyuba; Johan Auwerx
Journal:  Nat Rev Endocrinol       Date:  2015-10-27       Impact factor: 43.330

Review 2.  The importance of NAMPT/NAD/SIRT1 in the systemic regulation of metabolism and ageing.

Authors:  S Imai; J Yoshino
Journal:  Diabetes Obes Metab       Date:  2013-09       Impact factor: 6.577

Review 3.  Maintaining ancient organelles: mitochondrial biogenesis and maturation.

Authors:  Rick B Vega; Julie L Horton; Daniel P Kelly
Journal:  Circ Res       Date:  2015-05-22       Impact factor: 17.367

Review 4.  Sirtuins and the Metabolic Hurdles in Cancer.

Authors:  Natalie J German; Marcia C Haigis
Journal:  Curr Biol       Date:  2015-06-29       Impact factor: 10.834

Review 5.  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

Review 6.  SIRT1 and SIRT6 Signaling Pathways in Cardiovascular Disease Protection.

Authors:  Nunzia D'Onofrio; Luigi Servillo; Maria Luisa Balestrieri
Journal:  Antioxid Redox Signal       Date:  2017-06-29       Impact factor: 8.401

7.  Sirtuin 6 regulates glucose-stimulated insulin secretion in mouse pancreatic beta cells.

Authors:  Xiwen Xiong; Gaihong Wang; Rongya Tao; Pengfei Wu; Tatsuyoshi Kono; Kevin Li; Wen-Xing Ding; Xin Tong; Sarah A Tersey; Robert A Harris; Raghavendra G Mirmira; Carmella Evans-Molina; X Charlie Dong
Journal:  Diabetologia       Date:  2016-01       Impact factor: 10.122

Review 8.  Chromatin and beyond: the multitasking roles for SIRT6.

Authors:  Sita Kugel; Raul Mostoslavsky
Journal:  Trends Biochem Sci       Date:  2014-01-14       Impact factor: 13.807

Review 9.  Sirtuins and NAD+ in the Development and Treatment of Metabolic and Cardiovascular Diseases.

Authors:  Alice E Kane; David A Sinclair
Journal:  Circ Res       Date:  2018-09-14       Impact factor: 17.367

10.  Obesity-induced lysine acetylation increases cardiac fatty acid oxidation and impairs insulin signalling.

Authors:  Osama Abo Alrob; Sowndramalingam Sankaralingam; Cary Ma; Cory S Wagg; Natasha Fillmore; Jagdip S Jaswal; Michael N Sack; Richard Lehner; Mahesh P Gupta; Evangelos D Michelakis; Raj S Padwal; David E Johnstone; Arya M Sharma; Gary D Lopaschuk
Journal:  Cardiovasc Res       Date:  2014-06-25       Impact factor: 10.787
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