Life Span Extension via eIF4G Inhibition Is Mediated by Posttranscriptional Remodeling of Stress Response Gene Expression in C. elegans

Rogers, Aric N.; Chen, Di; McColl, Gawain; Czerwieniec, Gregg; Felkey, Krysta; Gibson, Bradford W.; Hubbard, Alan; Melov, Simon; Lithgow, Gordon J.; Kapahi, Pankaj

doi:10.1016/j.cmet.2011.05.010

Cited by 127 publications

(148 citation statements)

References 60 publications

(88 reference statements)

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“…MDT‐15 is required as a coactivator for SKN‐1, promoting SKN‐1‐dependent gene expression and/or longevity in several contexts, for example in long‐lived glp‐1 mutants (Goh et al., 2014; Rogers et al., 2011; Wei & Kenyon, 2016). Thus, mdt‐15 may promote both NHR‐49 and SKN‐1‐dependent gene expression in germline‐deficient glp‐1 mutant animals, including different subsets of lipid metabolic and cytoprotective genes.…”

Section: Discussionmentioning

confidence: 99%

NHR‐49/HNF4 integrates regulation of fatty acid metabolism with a protective transcriptional response to oxidative stress and fasting

et al. 2018

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SummaryEndogenous and exogenous stresses elicit transcriptional responses that limit damage and promote cell/organismal survival. Like its mammalian counterparts, hepatocyte nuclear factor 4 (HNF4) and peroxisome proliferator‐activated receptor α (PPARα), Caenorhabditis elegans NHR‐49 is a well‐established regulator of lipid metabolism. Here, we reveal that NHR‐49 is essential to activate a transcriptional response common to organic peroxide and fasting, which includes the pro‐longevity gene fmo‐2/flavin‐containing monooxygenase. These NHR‐49‐dependent, stress‐responsive genes are also upregulated in long‐lived glp‐1/notch receptor mutants, with two of them making critical contributions to the oxidative stress resistance of wild‐type and long‐lived glp‐1 mutants worms. Similar to its role in lipid metabolism, NHR‐49 requires the mediator subunit mdt‐15 to promote stress‐induced gene expression. However, NHR‐49 acts independently from the transcription factor hlh‐30/TFEB that also promotes fmo‐2 expression. We show that activation of the p38 MAPK, PMK‐1, which is important for adaptation to a variety of stresses, is also important for peroxide‐induced expression of a subset of NHR‐49‐dependent genes that includes fmo‐2. However, organic peroxide increases NHR‐49 protein levels, by a posttranscriptional mechanism that does not require PMK‐1 activation. Together, these findings establish a new role for the HNF4/PPARα‐related NHR‐49 as a stress‐activated regulator of cytoprotective gene expression.

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Section: Discussionmentioning

confidence: 99%

NHR‐49/HNF4 integrates regulation of fatty acid metabolism with a protective transcriptional response to oxidative stress and fasting

et al. 2018

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“…Thus, only a subset of mRNAs are up-or down-regulated based largely on properties of individual mRNAs such as mRNA length or the secondary structure of the 5′ UTR (32). This mechanism of translational control is also conserved in flies and worms (33,34), where dietary restriction or modulation of insulin signaling promoted differential translation of genes important for growth, stress responses, and aging (33,34). We therefore propose that the main consequence of increased tRNA i…”

Section: Discussionmentioning

confidence: 99%

Drosophila RNA polymerase III repressor Maf1 controls body size and developmental timing by modulating tRNA _i ^Met synthesis and systemic insulin signaling

Rideout

Marshall

Grewal

2012

Proc. Natl. Acad. Sci. U.S.A.

102

117

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The target-of-rapamycin pathway couples nutrient availability with tissue and organismal growth in metazoans. The key effectors underlying this growth are, however, unclear. Here we show that Maf1, a repressor of RNA polymerase III-dependent tRNA transcription, is an important mediator of nutrient-dependent growth in Drosophila. We find nutrients promote tRNA synthesis during larval development by inhibiting Maf1. Genetic inhibition of Maf1 accelerates development and increases body size. These phenotypes are due to a non-cell-autonomous effect of Maf1 inhibition in the fat body, the main larval endocrine organ. Inhibiting Maf1 in the fat body increases growth by promoting the expression of brain-derived insulin-like peptides and consequently enhanced systemic insulin signaling. Remarkably, the effects of Maf1 inhibition are reproduced in flies carrying one extra copy of the initiator methionine tRNA, tRNA i Met . These findings suggest the stimulation of tRNA iMet synthesis via inhibition of dMaf1 is limiting for nutrition-dependent growth during development.metabolism | physiology | endocrinology | amino acids | adipose tissue

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“…The remainder is most likely due to post-transcriptional regulation, including mRNA transcript-specific regulation of translation and protein degradation (Cho et al 2006;Brockmann et al 2007;Sutton et al 2007;Sonenberg and Hinnebusch 2009;Rogers et al 2011). While translational regulation occurs largely during initiation (Richter and Sonenberg 2005), recent experimental and computational studies have discovered that regulation of elongation also plays an important role, by means of cis-regulatory elements on the transcripts, codon bias, or mRNA structure (Arava et al 2005;Dittmar et al 2006;Kudla et al 2009;Tuller et al 2010;Leprivier et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Detecting translational regulation by change point analysis of ribosome profiling data sets

Županič

Méplan

Grellscheid

et al. 2014

RNA

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Ribo-Seq maps the location of translating ribosomes on mature mRNA transcripts. While during normal translation, ribosome density is constant along the length of the mRNA coding region, this can be altered in response to translational regulatory events. In the present study, we developed a method to detect translational regulation of individual mRNAs from their ribosome profiles, utilizing changes in ribosome density. We used mathematical modeling to show that changes in ribosome density should occur along the mRNA at the point of regulation. We analyzed a Ribo-Seq data set obtained for mouse embryonic stem cells and showed that normalization by corresponding RNA-Seq can be used to improve the Ribo-Seq quality by removing bias introduced by deep-sequencing and alignment artifacts. After normalization, we applied a change point algorithm to detect changes in ribosome density present in individual mRNA ribosome profiles. Additional sequence and gene isoform information obtained from the UCSC Genome Browser allowed us to further categorize the detected changes into different mechanisms of regulation. In particular, we detected several mRNAs with known post-transcriptional regulation, e.g., premature termination for selenoprotein mRNAs and translational control of Atf4, but also several more mRNAs with hitherto unknown translational regulation. Additionally, our approach proved useful for identification of new transcript isoforms.

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Life Span Extension via eIF4G Inhibition Is Mediated by Posttranscriptional Remodeling of Stress Response Gene Expression in C. elegans

Cited by 127 publications

References 60 publications

NHR‐49/HNF4 integrates regulation of fatty acid metabolism with a protective transcriptional response to oxidative stress and fasting

NHR‐49/HNF4 integrates regulation of fatty acid metabolism with a protective transcriptional response to oxidative stress and fasting

Drosophila RNA polymerase III repressor Maf1 controls body size and developmental timing by modulating tRNA _i ^Met synthesis and systemic insulin signaling

Detecting translational regulation by change point analysis of ribosome profiling data sets

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Life Span Extension via eIF4G Inhibition Is Mediated by Posttranscriptional Remodeling of Stress Response Gene Expression in C. elegans

Cited by 127 publications

References 60 publications

NHR‐49/HNF4 integrates regulation of fatty acid metabolism with a protective transcriptional response to oxidative stress and fasting

NHR‐49/HNF4 integrates regulation of fatty acid metabolism with a protective transcriptional response to oxidative stress and fasting

Drosophila RNA polymerase III repressor Maf1 controls body size and developmental timing by modulating tRNA i Met synthesis and systemic insulin signaling

Detecting translational regulation by change point analysis of ribosome profiling data sets

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Drosophila RNA polymerase III repressor Maf1 controls body size and developmental timing by modulating tRNA _i ^Met synthesis and systemic insulin signaling