Literature DB >> 27133166

Mitochondrial Stress Induces Chromatin Reorganization to Promote Longevity and UPR(mt).

Ye Tian1, Gilberto Garcia1, Qian Bian2, Kristan K Steffen1, Larry Joe1, Suzanne Wolff1, Barbara J Meyer2, Andrew Dillin3.   

Abstract

Organisms respond to mitochondrial stress through the upregulation of an array of protective genes, often perpetuating an early response to metabolic dysfunction across a lifetime. We find that mitochondrial stress causes widespread changes in chromatin structure through histone H3K9 di-methylation marks traditionally associated with gene silencing. Mitochondrial stress response activation requires the di-methylation of histone H3K9 through the activity of the histone methyltransferase met-2 and the nuclear co-factor lin-65. While globally the chromatin becomes silenced by these marks, remaining portions of the chromatin open up, at which point the binding of canonical stress responsive factors such as DVE-1 occurs. Thus, a metabolic stress response is established and propagated into adulthood of animals through specific epigenetic modifications that allow for selective gene expression and lifespan extension.
Copyright © 2016 Elsevier Inc. All rights reserved.

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Year:  2016        PMID: 27133166      PMCID: PMC4889216          DOI: 10.1016/j.cell.2016.04.011

Source DB:  PubMed          Journal:  Cell        ISSN: 0092-8674            Impact factor:   41.582


  42 in total

1.  Role of histone H3 lysine 9 methylation in epigenetic control of heterochromatin assembly.

Authors:  J Nakayama ; J C Rice; B D Strahl; C D Allis; S I Grewal
Journal:  Science       Date:  2001-03-15       Impact factor: 47.728

2.  Composite macroH2A/NRF-1 Nucleosomes Suppress Noise and Generate Robustness in Gene Expression.

Authors:  Matthieu D Lavigne; Giannis Vatsellas; Alexander Polyzos; Evangelia Mantouvalou; George Sianidis; Ioannis Maraziotis; Marios Agelopoulos; Dimitris Thanos
Journal:  Cell Rep       Date:  2015-05-07       Impact factor: 9.423

3.  Direct observation of stress response in Caenorhabditis elegans using a reporter transgene.

Authors:  C D Link; J R Cypser; C J Johnson; T E Johnson
Journal:  Cell Stress Chaperones       Date:  1999-12       Impact factor: 3.667

4.  The cell-non-autonomous nature of electron transport chain-mediated longevity.

Authors:  Jenni Durieux; Suzanne Wolff; Andrew Dillin
Journal:  Cell       Date:  2011-01-07       Impact factor: 41.582

5.  Mitochondrial and nuclear accumulation of the transcription factor ATFS-1 promotes OXPHOS recovery during the UPR(mt).

Authors:  Amrita M Nargund; Christopher J Fiorese; Mark W Pellegrino; Pan Deng; Cole M Haynes
Journal:  Mol Cell       Date:  2015-03-12       Impact factor: 17.970

6.  The intrinsic apoptosis pathway mediates the pro-longevity response to mitochondrial ROS in C. elegans.

Authors:  Callista Yee; Wen Yang; Siegfried Hekimi
Journal:  Cell       Date:  2014-05-08       Impact factor: 41.582

7.  Tissue-specific nuclear architecture and gene expression regulated by SATB1.

Authors:  Shutao Cai; Hye-Jung Han; Terumi Kohwi-Shigematsu
Journal:  Nat Genet       Date:  2003-05       Impact factor: 38.330

8.  Two C. elegans histone methyltransferases repress lin-3 EGF transcription to inhibit vulval development.

Authors:  Erik C Andersen; H Robert Horvitz
Journal:  Development       Date:  2007-07-18       Impact factor: 6.868

9.  Polyglutamine proteins at the pathogenic threshold display neuron-specific aggregation in a pan-neuronal Caenorhabditis elegans model.

Authors:  Heather R Brignull; Finola E Moore; Stephanie J Tang; Richard I Morimoto
Journal:  J Neurosci       Date:  2006-07-19       Impact factor: 6.709

Review 10.  C. elegans epigenetic regulation in development and aging.

Authors:  Cristina González-Aguilera; Francesca Palladino; Peter Askjaer
Journal:  Brief Funct Genomics       Date:  2013-12-10       Impact factor: 4.241
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  142 in total

1.  Physiology: Stressed-out chromatin promotes longevity.

Authors:  Siu Sylvia Lee; Jessica K Tyler
Journal:  Nature       Date:  2016-06-30       Impact factor: 49.962

2.  A microRNA switch controls dietary restriction-induced longevity through Wnt signaling.

Authors:  Yunpeng Xu; Zhidong He; Mengjiao Song; Yifei Zhou; Yidong Shen
Journal:  EMBO Rep       Date:  2019-03-14       Impact factor: 8.807

Review 3.  The mitochondrial unfolded protein response: Signaling from the powerhouse.

Authors:  Mohammed A Qureshi; Cole M Haynes; Mark W Pellegrino
Journal:  J Biol Chem       Date:  2017-07-07       Impact factor: 5.157

Review 4.  Mitochondrial homeostasis in adipose tissue remodeling.

Authors:  Svetlana Altshuler-Keylin; Shingo Kajimura
Journal:  Sci Signal       Date:  2017-02-28       Impact factor: 8.192

Review 5.  Mitochondrial dysfunction in cancer: Potential roles of ATF5 and the mitochondrial UPR.

Authors:  Pan Deng; Cole M Haynes
Journal:  Semin Cancer Biol       Date:  2017-05-10       Impact factor: 15.707

6.  The mitokine quest(ion).

Authors:  Pan Deng; Cole M Haynes
Journal:  Cell Res       Date:  2016-11-25       Impact factor: 25.617

Review 7.  The role of mitochondria in aging.

Authors:  Ji Yong Jang; Arnon Blum; Jie Liu; Toren Finkel
Journal:  J Clin Invest       Date:  2018-07-30       Impact factor: 14.808

8.  More than a powerplant: the influence of mitochondrial transfer on the epigenome.

Authors:  Alexander N Patananan; Alexander J Sercel; Michael A Teitell
Journal:  Curr Opin Physiol       Date:  2017-12-13

9.  Alcohol induces mitochondrial fragmentation and stress responses to maintain normal muscle function in Caenorhabditis elegans.

Authors:  Kelly H Oh; Seema Sheoran; Janet E Richmond; Hongkyun Kim
Journal:  FASEB J       Date:  2020-04-15       Impact factor: 5.191

Review 10.  MOTS-c: A Mitochondrial-Encoded Regulator of the Nucleus.

Authors:  Bérénice A Benayoun; Changhan Lee
Journal:  Bioessays       Date:  2019-08-05       Impact factor: 4.345
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