Literature DB >> 29143563

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

Raghavendra Vadla1,2, Devyani Haldar1.   

Abstract

Metabolic reprogramming is a hallmark of cancer cells, but the mechanisms are not well understood. The mammalian target of rapamycin complex 2 (mTORC2) controls cell growth and proliferation and plays a critical role in metabolic reprogramming in glioma. mTORC2 regulates cellular processes such as cell survival, metabolism, and proliferation by phosphorylation of AGC kinases. Components of mTORC2 are shown to localize to the nucleus, but whether mTORC2 modulates epigenetic modifications to regulate gene expression is not known. Here, we identified histone H3 lysine 56 acetylation (H3K56Ac) is regulated by mTORC2 and show that global H3K56Ac levels were downregulated on mTORC2 knockdown but not on mTORC1 knockdown. mTORC2 promotes H3K56Ac in a tuberous sclerosis complex 1/2 (TSC1/2) mediated signaling pathway. We show that knockdown of sirtuin6 (SIRT6) prevented H3K56 deacetylation in mTORC2 depleted cells. Using glioma model consisting of U87EGFRvIII cells, we established that mTORC2 promotes H3K56Ac in glioma. Finally, we show that mTORC2 regulates the expression of glycolytic genes by regulating H3K56Ac levels at the promoters of these genes in glioma cells and depletion of mTOR leads to increased recruitment of SIRT6 to these promoters. Collectively, these results identify mTORC2 signaling pathway positively promotes H3K56Ac through which it may mediate metabolic reprogramming in glioma.

Entities:  

Keywords:  Cancer cells; EGFR; Glioma; Histone acetylation; Histone deacetylases; SIRT6; TSC1/2; growth factors; mTOR; metabolic reprogramming; metabolism; signal transduction

Mesh:

Substances:

Year:  2018        PMID: 29143563      PMCID: PMC5815439          DOI: 10.1080/15384101.2017.1404207

Source DB:  PubMed          Journal:  Cell Cycle        ISSN: 1551-4005            Impact factor:   4.534


  78 in total

1.  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

2.  Acetylated histone H3K56 interacts with Oct4 to promote mouse embryonic stem cell pluripotency.

Authors:  Yuliang Tan; Yong Xue; Chunying Song; Michael Grunstein
Journal:  Proc Natl Acad Sci U S A       Date:  2013-06-24       Impact factor: 11.205

Review 3.  TORC2 Structure and Function.

Authors:  Christl Gaubitz; Manoel Prouteau; Beata Kusmider; Robbie Loewith
Journal:  Trends Biochem Sci       Date:  2016-05-05       Impact factor: 13.807

4.  SIRT6 stabilizes DNA-dependent protein kinase at chromatin for DNA double-strand break repair.

Authors:  Ronald A McCord; Eriko Michishita; Tao Hong; Elisabeth Berber; Lisa D Boxer; Rika Kusumoto; Shenheng Guan; Xiaobing Shi; Or Gozani; Alma L Burlingame; Vilhelm A Bohr; Katrin F Chua
Journal:  Aging (Albany NY)       Date:  2009-01-15       Impact factor: 5.682

5.  Cell cycle-dependent deacetylation of telomeric histone H3 lysine K56 by human SIRT6.

Authors:  Eriko Michishita; Ronald A McCord; Lisa D Boxer; Matthew F Barber; Tao Hong; Or Gozani; Katrin F Chua
Journal:  Cell Cycle       Date:  2009-08-26       Impact factor: 4.534

6.  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

Review 7.  The TSC1-TSC2 complex: a molecular switchboard controlling cell growth.

Authors:  Jingxiang Huang; Brendan D Manning
Journal:  Biochem J       Date:  2008-06-01       Impact factor: 3.857

Review 8.  Non-canonical functions of the tuberous sclerosis complex-Rheb signalling axis.

Authors:  Nicole A Neuman; Elizabeth Petri Henske
Journal:  EMBO Mol Med       Date:  2011-03-16       Impact factor: 12.137

9.  Target of rapamycin signaling regulates high mobility group protein association to chromatin, which functions to suppress necrotic cell death.

Authors:  Hongfeng Chen; Jason J Workman; Alexa Tenga; R Nicholas Laribee
Journal:  Epigenetics Chromatin       Date:  2013-09-02       Impact factor: 4.954

10.  Evidence that TSC2 acts as a transcription factor and binds to and represses the promoter of Epiregulin.

Authors:  Shalmali Avinash Pradhan; Mohammad Iqbal Rather; Ankana Tiwari; Vishwanath Kumble Bhat; Arun Kumar
Journal:  Nucleic Acids Res       Date:  2014-04-19       Impact factor: 16.971
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  14 in total

Review 1.  Metabolic choreography of gene expression: nutrient transactions with the epigenome.

Authors:  Babukrishna Maniyadath; U S Sandra; Ullas Kolthur-Seetharam
Journal:  J Biosci       Date:  2020       Impact factor: 1.826

2.  Critical role of mTOR, PPARγ and PPARδ signaling in regulating early pregnancy decidual function, embryo viability and feto-placental growth.

Authors:  Sabrina L Roberti; Romina Higa; Verónica White; Theresa L Powell; Thomas Jansson; Alicia Jawerbaum
Journal:  Mol Hum Reprod       Date:  2018-06-01       Impact factor: 4.025

3.  Cellular environment controls the dynamics of histone H3 lysine 56 acetylation in response to DNA damage in mammalian cells.

Authors:  Raghavendra Vadla; Nirupama Chatterjee; Devyani Haldar
Journal:  J Biosci       Date:  2020       Impact factor: 1.826

Review 4.  Functional implications of neutrophil metabolism during ischemic tissue repair.

Authors:  Enzo B Piccolo; Edward B Thorp; Ronen Sumagin
Journal:  Curr Opin Pharmacol       Date:  2022-03-08       Impact factor: 5.547

5.  KPT-9274, an Inhibitor of PAK4 and NAMPT, Leads to Downregulation of mTORC2 in Triple Negative Breast Cancer Cells.

Authors:  Emma Cordover; Janet Wei; Chadni Patel; Naing Lin Shan; John Gionco; Davit Sargsyan; Renyi Wu; Li Cai; Ah-Ng Kong; Estela Jacinto; Audrey Minden
Journal:  Chem Res Toxicol       Date:  2020-01-09       Impact factor: 3.973

Review 6.  Regulation and metabolic functions of mTORC1 and mTORC2.

Authors:  Angelia Szwed; Eugene Kim; Estela Jacinto
Journal:  Physiol Rev       Date:  2021-02-18       Impact factor: 46.500

Review 7.  H3K18Ac as a Marker of Cancer Progression and Potential Target of Anti-Cancer Therapy.

Authors:  Marta Hałasa; Anna Wawruszak; Alicja Przybyszewska; Anna Jaruga; Małgorzata Guz; Joanna Kałafut; Andrzej Stepulak; Marek Cybulski
Journal:  Cells       Date:  2019-05-22       Impact factor: 6.600

Review 8.  Nuclear Functions of TOR: Impact on Transcription and the Epigenome.

Authors:  R Nicholas Laribee; Ronit Weisman
Journal:  Genes (Basel)       Date:  2020-06-10       Impact factor: 4.096

Review 9.  Reciprocal Regulation of Metabolic Reprogramming and Epigenetic Modifications in Cancer.

Authors:  Xilan Yu; Rui Ma; Yinsheng Wu; Yansheng Zhai; Shanshan Li
Journal:  Front Genet       Date:  2018-09-19       Impact factor: 4.599

Review 10.  Signal Transduction Pathways in Breast Cancer: The Important Role of PI3K/Akt/mTOR.

Authors:  Miguel A Ortega; Oscar Fraile-Martínez; Ángel Asúnsolo; Julia Buján; Natalio García-Honduvilla; Santiago Coca
Journal:  J Oncol       Date:  2020-03-09       Impact factor: 4.375
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