Literature DB >> 31186373

AMPK directly activates mTORC2 to promote cell survival during acute energetic stress.

Dubek Kazyken1, Brian Magnuson1, Cagri Bodur1, Hugo A Acosta-Jaquez1, Deqiang Zhang2, Xin Tong2, Tammy M Barnes3, Gabrielle K Steinl3, Nicole E Patterson1, Christopher H Altheim1, Naveen Sharma4, Ken Inoki2, Gregory D Cartee4, Dave Bridges5, Lei Yin2, Steven M Riddle6, Diane C Fingar7.   

Abstract

AMP-activated protein kinase (AMPK) senses energetic stress and, in turn, promotes catabolic and suppresses anabolic metabolism coordinately to restore energy balance. We found that a diverse array of AMPK activators increased mTOR complex 2 (mTORC2) signaling in an AMPK-dependent manner in cultured cells. Activation of AMPK with the type 2 diabetes drug metformin (GlucoPhage) also increased mTORC2 signaling in liver in vivo and in primary hepatocytes in an AMPK-dependent manner. AMPK-mediated activation of mTORC2 did not result from AMPK-mediated suppression of mTORC1 and thus reduced negative feedback on PI3K flux. Rather, AMPK associated with and directly phosphorylated mTORC2 (mTOR in complex with rictor). As determined by two-stage in vitro kinase assay, phosphorylation of mTORC2 by recombinant AMPK was sufficient to increase mTORC2 catalytic activity toward Akt. Hence, AMPK phosphorylated mTORC2 components directly to increase mTORC2 activity and downstream signaling. Functionally, inactivation of AMPK, mTORC2, and Akt increased apoptosis during acute energetic stress. By showing that AMPK activates mTORC2 to increase cell survival, these data provide a potential mechanism for how AMPK paradoxically promotes tumorigenesis in certain contexts despite its tumor-suppressive function through inhibition of growth-promoting mTORC1. Collectively, these data unveil mTORC2 as a target of AMPK and the AMPK-mTORC2 axis as a promoter of cell survival during energetic stress.
Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.

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Year:  2019        PMID: 31186373      PMCID: PMC6935248          DOI: 10.1126/scisignal.aav3249

Source DB:  PubMed          Journal:  Sci Signal        ISSN: 1945-0877            Impact factor:   8.192


  95 in total

1.  Rictor phosphorylation on the Thr-1135 site does not require mammalian target of rapamycin complex 2.

Authors:  Delphine Boulbes; Chien-Hung Chen; Tattym Shaikenov; Nitin K Agarwal; Timothy R Peterson; Terri A Addona; Hasmik Keshishian; Steven A Carr; Mark A Magnuson; David M Sabatini; Dos D Sarbassov
Journal:  Mol Cancer Res       Date:  2010-05-25       Impact factor: 5.852

Review 2.  Stress and mTORture signaling.

Authors:  J H Reiling; D M Sabatini
Journal:  Oncogene       Date:  2006-10-16       Impact factor: 9.867

3.  Metformin inhibits hepatic gluconeogenesis in mice independently of the LKB1/AMPK pathway via a decrease in hepatic energy state.

Authors:  Marc Foretz; Sophie Hébrard; Jocelyne Leclerc; Elham Zarrinpashneh; Maud Soty; Gilles Mithieux; Kei Sakamoto; Fabrizio Andreelli; Benoit Viollet
Journal:  J Clin Invest       Date:  2010-06-23       Impact factor: 14.808

4.  SIN1/MIP1 maintains rictor-mTOR complex integrity and regulates Akt phosphorylation and substrate specificity.

Authors:  Estela Jacinto; Valeria Facchinetti; Dou Liu; Nelyn Soto; Shiniu Wei; Sung Yun Jung; Qiaojia Huang; Jun Qin; Bing Su
Journal:  Cell       Date:  2006-09-07       Impact factor: 41.582

5.  AICAR induces apoptosis independently of AMPK and p53 through up-regulation of the BH3-only proteins BIM and NOXA in chronic lymphocytic leukemia cells.

Authors:  Antonio F Santidrián; Diana M González-Gironès; Daniel Iglesias-Serret; Llorenç Coll-Mulet; Ana M Cosialls; Mercè de Frias; Clara Campàs; Eva González-Barca; Esther Alonso; Verena Labi; Benoit Viollet; Adalberto Benito; Gabriel Pons; Andreas Villunger; Joan Gil
Journal:  Blood       Date:  2010-07-27       Impact factor: 22.113

Review 6.  A complex interplay between Akt, TSC2 and the two mTOR complexes.

Authors:  Jingxiang Huang; Brendan D Manning
Journal:  Biochem Soc Trans       Date:  2009-02       Impact factor: 5.407

Review 7.  Growing knowledge of the mTOR signaling network.

Authors:  Kezhen Huang; Diane C Fingar
Journal:  Semin Cell Dev Biol       Date:  2014-09-19       Impact factor: 7.727

Review 8.  The Dawn of the Age of Amino Acid Sensors for the mTORC1 Pathway.

Authors:  Rachel L Wolfson; David M Sabatini
Journal:  Cell Metab       Date:  2017-08-01       Impact factor: 27.287

9.  Quantitative studies of the growth of mouse embryo cells in culture and their development into established lines.

Authors:  G J TODARO; H GREEN
Journal:  J Cell Biol       Date:  1963-05       Impact factor: 10.539

10.  Localization of mTORC2 activity inside cells.

Authors:  Michael Ebner; Benjamin Sinkovics; Magdalena Szczygieł; Daniela Wolfschoon Ribeiro; Ivan Yudushkin
Journal:  J Cell Biol       Date:  2017-01-31       Impact factor: 10.539
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  56 in total

Review 1.  mTOR in Lung Neoplasms.

Authors:  Ildiko Krencz; Anna Sebestyen; Andras Khoor
Journal:  Pathol Oncol Res       Date:  2020-02-03       Impact factor: 3.201

Review 2.  Regulation of mTOR signaling by long non-coding RNA.

Authors:  Karam Aboudehen
Journal:  Biochim Biophys Acta Gene Regul Mech       Date:  2019-11-18       Impact factor: 4.490

Review 3.  mTOR at the nexus of nutrition, growth, ageing and disease.

Authors:  Grace Y Liu; David M Sabatini
Journal:  Nat Rev Mol Cell Biol       Date:  2020-01-14       Impact factor: 94.444

4.  The GATOR2-mTORC2 axis mediates Sestrin2-induced AKT Ser/Thr kinase activation.

Authors:  Allison Ho Kowalsky; Sim Namkoong; Eric Mettetal; Hwan-Woo Park; Dubek Kazyken; Diane C Fingar; Jun Hee Lee
Journal:  J Biol Chem       Date:  2020-01-08       Impact factor: 5.157

5.  Histone Acetyltransferase MOF Blocks Acquisition of Quiescence in Ground-State ESCs through Activating Fatty Acid Oxidation.

Authors:  Le Tran Phuc Khoa; Yao-Chang Tsan; Fengbiao Mao; Daniel M Kremer; Peter Sajjakulnukit; Li Zhang; Bo Zhou; Xin Tong; Natarajan V Bhanu; Chunaram Choudhary; Benjamin A Garcia; Lei Yin; Gary D Smith; Thomas L Saunders; Stephanie L Bielas; Costas A Lyssiotis; Yali Dou
Journal:  Cell Stem Cell       Date:  2020-06-30       Impact factor: 24.633

Review 6.  The complex network of mTOR signalling in the heart.

Authors:  Sebastiano Sciarretta; Maurizio Forte; Giacomo Frati; Junichi Sadoshima
Journal:  Cardiovasc Res       Date:  2022-01-29       Impact factor: 10.787

7.  Disruption of FOXO3a-miRNA feedback inhibition of IGF2/IGF-1R/IRS1 signaling confers Herceptin resistance in HER2-positive breast cancer.

Authors:  Liyun Luo; Zhijie Zhang; Ni Qiu; Li Ling; Xiaoting Jia; Ying Song; Hongsheng Li; Jiansheng Li; Hui Lyu; Hao Liu; Zhimin He; Bolin Liu; Guopei Zheng
Journal:  Nat Commun       Date:  2021-05-11       Impact factor: 14.919

Review 8.  mTOR Signaling in Metabolic Stress Adaptation.

Authors:  Cheng-Wei Wu; Kenneth B Storey
Journal:  Biomolecules       Date:  2021-05-01

Review 9.  AICAr, a Widely Used AMPK Activator with Important AMPK-Independent Effects: A Systematic Review.

Authors:  Dora Višnjić; Hrvoje Lalić; Vilma Dembitz; Barbara Tomić; Tomislav Smoljo
Journal:  Cells       Date:  2021-05-04       Impact factor: 6.600

Review 10.  Influence of Age on Skeletal Muscle Hypertrophy and Atrophy Signaling: Established Paradigms and Unexpected Links.

Authors:  Eun-Joo Lee; Ronald L Neppl
Journal:  Genes (Basel)       Date:  2021-05-03       Impact factor: 4.096
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