Molecular networks of human muscle adaptation to exercise and age

Physical activity and molecular ageing presumably interact to precipitate musculoskeletal decline in humans with age. Herein, we have delineated molecular networks for these two major components of sarcopenic risk using multiple independent clinical cohorts. We generated genome-wide transcript profi...

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Veröffentlicht in:	PLoS genetics 2013-03, Vol.9 (3), p.e1003389-e1003389
Hauptverfasser:	Phillips, Bethan E, Williams, John P, Gustafsson, Thomas, Bouchard, Claude, Rankinen, Tuomo, Knudsen, Steen, Smith, Kenneth, Timmons, James A, Atherton, Philip J
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Schlagworte:	Adaptation, Physiological - genetics Adolescent Adult Aged Aging Aging - genetics Aging - metabolism Aging - physiology Biology Down-Regulation Exercise Exercise - physiology Female Gene Expression Profiling Gene Regulatory Networks - physiology Genetic transcription Humans Kinases Male Medicine Middle Aged Molecular genetics Muscle, Skeletal - metabolism Muscle, Skeletal - physiology Muscular system Proteins Ribosome Subunits - genetics Ribosome Subunits - metabolism Ribosome Subunits - physiology Signal Transduction TOR Serine-Threonine Kinases - genetics TOR Serine-Threonine Kinases - metabolism
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creator	Phillips, Bethan E Williams, John P Gustafsson, Thomas Bouchard, Claude Rankinen, Tuomo Knudsen, Steen Smith, Kenneth Timmons, James A Atherton, Philip J
description	Physical activity and molecular ageing presumably interact to precipitate musculoskeletal decline in humans with age. Herein, we have delineated molecular networks for these two major components of sarcopenic risk using multiple independent clinical cohorts. We generated genome-wide transcript profiles from individuals (n = 44) who then undertook 20 weeks of supervised resistance-exercise training (RET). Expectedly, our subjects exhibited a marked range of hypertrophic responses (3% to +28%), and when applying Ingenuity Pathway Analysis (IPA) up-stream analysis to ~580 genes that co-varied with gain in lean mass, we identified rapamycin (mTOR) signaling associating with growth (P = 1.4 × 10(-30)). Paradoxically, those displaying most hypertrophy exhibited an inhibited mTOR activation signature, including the striking down-regulation of 70 rRNAs. Differential analysis found networks mimicking developmental processes (activated all-trans-retinoic acid (ATRA, Z-score = 4.5; P = 6 × 10(-13)) and inhibited aryl-hydrocarbon receptor signaling (AhR, Z-score = -2.3; P = 3 × 10(-7))) with RET. Intriguingly, as ATRA and AhR gene-sets were also a feature of endurance exercise training (EET), they appear to represent "generic" physical activity responsive gene-networks. For age, we found that differential gene-expression methods do not produce consistent molecular differences between young versus old individuals. Instead, utilizing two independent cohorts (n = 45 and n = 52), with a continuum of subject ages (18-78 y), the first reproducible set of age-related transcripts in human muscle was identified. This analysis identified ~500 genes highly enriched in post-transcriptional processes (P = 1 × 10(-6)) and with negligible links to the aforementioned generic exercise regulated gene-sets and some overlap with ribosomal genes. The RNA signatures from multiple compounds all targeting serotonin, DNA topoisomerase antagonism, and RXR activation were significantly related to the muscle age-related genes. Finally, a number of specific chromosomal loci, including 1q12 and 13q21, contributed by more than chance to the age-related gene list (P = 0.01-0.005), implying possible epigenetic events. We conclude that human muscle age-related molecular processes appear distinct from the processes regulated by those of physical activity.
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Herein, we have delineated molecular networks for these two major components of sarcopenic risk using multiple independent clinical cohorts. We generated genome-wide transcript profiles from individuals (n = 44) who then undertook 20 weeks of supervised resistance-exercise training (RET). Expectedly, our subjects exhibited a marked range of hypertrophic responses (3% to +28%), and when applying Ingenuity Pathway Analysis (IPA) up-stream analysis to ~580 genes that co-varied with gain in lean mass, we identified rapamycin (mTOR) signaling associating with growth (P = 1.4 × 10(-30)). Paradoxically, those displaying most hypertrophy exhibited an inhibited mTOR activation signature, including the striking down-regulation of 70 rRNAs. Differential analysis found networks mimicking developmental processes (activated all-trans-retinoic acid (ATRA, Z-score = 4.5; P = 6 × 10(-13)) and inhibited aryl-hydrocarbon receptor signaling (AhR, Z-score = -2.3; P = 3 × 10(-7))) with RET. Intriguingly, as ATRA and AhR gene-sets were also a feature of endurance exercise training (EET), they appear to represent "generic" physical activity responsive gene-networks. For age, we found that differential gene-expression methods do not produce consistent molecular differences between young versus old individuals. Instead, utilizing two independent cohorts (n = 45 and n = 52), with a continuum of subject ages (18-78 y), the first reproducible set of age-related transcripts in human muscle was identified. This analysis identified ~500 genes highly enriched in post-transcriptional processes (P = 1 × 10(-6)) and with negligible links to the aforementioned generic exercise regulated gene-sets and some overlap with ribosomal genes. The RNA signatures from multiple compounds all targeting serotonin, DNA topoisomerase antagonism, and RXR activation were significantly related to the muscle age-related genes. Finally, a number of specific chromosomal loci, including 1q12 and 13q21, contributed by more than chance to the age-related gene list (P = 0.01-0.005), implying possible epigenetic events. We conclude that human muscle age-related molecular processes appear distinct from the processes regulated by those of physical activity.</description><identifier>ISSN: 1553-7404</identifier><identifier>ISSN: 1553-7390</identifier><identifier>EISSN: 1553-7404</identifier><identifier>DOI: 10.1371/journal.pgen.1003389</identifier><identifier>PMID: 23555298</identifier><language>eng</language><publisher>United States: Public Library of Science</publisher><subject>Adaptation, Physiological - genetics ; Adolescent ; Adult ; Aged ; Aging ; Aging - genetics ; Aging - metabolism ; Aging - physiology ; Biology ; Down-Regulation ; Exercise ; Exercise - physiology ; Female ; Gene Expression Profiling ; Gene Regulatory Networks - physiology ; Genetic transcription ; Humans ; Kinases ; Male ; Medicine ; Middle Aged ; Molecular genetics ; Muscle, Skeletal - metabolism ; Muscle, Skeletal - physiology ; Muscular system ; Proteins ; Ribosome Subunits - genetics ; Ribosome Subunits - metabolism ; Ribosome Subunits - physiology ; Signal Transduction ; TOR Serine-Threonine Kinases - genetics ; TOR Serine-Threonine Kinases - metabolism</subject><ispartof>PLoS genetics, 2013-03, Vol.9 (3), p.e1003389-e1003389</ispartof><rights>COPYRIGHT 2013 Public Library of Science</rights><rights>2013 Phillips et al 2013 Phillips et al</rights><rights>2013 Phillips et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited: Phillips BE, Williams JP, Gustafsson T, Bouchard C, Rankinen T, et al. (2013) Molecular Networks of Human Muscle Adaptation to Exercise and Age. 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Herein, we have delineated molecular networks for these two major components of sarcopenic risk using multiple independent clinical cohorts. We generated genome-wide transcript profiles from individuals (n = 44) who then undertook 20 weeks of supervised resistance-exercise training (RET). Expectedly, our subjects exhibited a marked range of hypertrophic responses (3% to +28%), and when applying Ingenuity Pathway Analysis (IPA) up-stream analysis to ~580 genes that co-varied with gain in lean mass, we identified rapamycin (mTOR) signaling associating with growth (P = 1.4 × 10(-30)). Paradoxically, those displaying most hypertrophy exhibited an inhibited mTOR activation signature, including the striking down-regulation of 70 rRNAs. Differential analysis found networks mimicking developmental processes (activated all-trans-retinoic acid (ATRA, Z-score = 4.5; P = 6 × 10(-13)) and inhibited aryl-hydrocarbon receptor signaling (AhR, Z-score = -2.3; P = 3 × 10(-7))) with RET. Intriguingly, as ATRA and AhR gene-sets were also a feature of endurance exercise training (EET), they appear to represent "generic" physical activity responsive gene-networks. For age, we found that differential gene-expression methods do not produce consistent molecular differences between young versus old individuals. Instead, utilizing two independent cohorts (n = 45 and n = 52), with a continuum of subject ages (18-78 y), the first reproducible set of age-related transcripts in human muscle was identified. This analysis identified ~500 genes highly enriched in post-transcriptional processes (P = 1 × 10(-6)) and with negligible links to the aforementioned generic exercise regulated gene-sets and some overlap with ribosomal genes. The RNA signatures from multiple compounds all targeting serotonin, DNA topoisomerase antagonism, and RXR activation were significantly related to the muscle age-related genes. Finally, a number of specific chromosomal loci, including 1q12 and 13q21, contributed by more than chance to the age-related gene list (P = 0.01-0.005), implying possible epigenetic events. We conclude that human muscle age-related molecular processes appear distinct from the processes regulated by those of physical activity.</description><subject>Adaptation, Physiological - genetics</subject><subject>Adolescent</subject><subject>Adult</subject><subject>Aged</subject><subject>Aging</subject><subject>Aging - genetics</subject><subject>Aging - metabolism</subject><subject>Aging - physiology</subject><subject>Biology</subject><subject>Down-Regulation</subject><subject>Exercise</subject><subject>Exercise - physiology</subject><subject>Female</subject><subject>Gene Expression Profiling</subject><subject>Gene Regulatory Networks - physiology</subject><subject>Genetic transcription</subject><subject>Humans</subject><subject>Kinases</subject><subject>Male</subject><subject>Medicine</subject><subject>Middle Aged</subject><subject>Molecular genetics</subject><subject>Muscle, Skeletal - metabolism</subject><subject>Muscle, Skeletal - physiology</subject><subject>Muscular system</subject><subject>Proteins</subject><subject>Ribosome Subunits - genetics</subject><subject>Ribosome Subunits - metabolism</subject><subject>Ribosome Subunits - physiology</subject><subject>Signal Transduction</subject><subject>TOR Serine-Threonine Kinases - genetics</subject><subject>TOR Serine-Threonine Kinases - metabolism</subject><issn>1553-7404</issn><issn>1553-7390</issn><issn>1553-7404</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2013</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><sourceid>D8T</sourceid><sourceid>DOA</sourceid><recordid>eNqVk11r1EAUhoMotlb_gWhAEHux63xmkhthKWoXqgW_boezk5NstklmnZnY-u-d7aZlA14oucjh5Hlf5j2ZkyTPKZlTrujbjR1cD-18W2M_p4RwnhcPkmMqJZ8pQcTDg_ooeeL9JjIyL9Tj5IhxKSUr8uNk8cm2aIYWXNpjuLbuyqe2StdDB33aDd60mEIJ2wChsX0abIo36EzjY7svU6jxafKogtbjs_F9knz_8P7b2fns4vLj8mxxMTM5YWFG85wyyApFFZUmZxXJhcipAC4rvgJZKAAliyKWclUVpJCAKAkrFSdAspKfJC_3vtvWej2m95pyplQmqMgisdwTpYWN3rqmA_dbW2j0bcO6WoMLTYykZQEyDhFMZUrBCMlVWUmeSTTCVCWq6DXbe_lr3A6ridvYuopVdOKEMxH5d-PphlWHpcE-OGgnsumXvlnr2v7SPCOSEhoN3owGzv4c0AfdNd5g20KPdrjNKXicIWURfbVHa4hRmr6y0dHscL3gLJNEKrZLMP8LFZ8Su8bYHqsm9ieC04kgMgFvQg2D93r59ct_sJ__nb38MWVfH7BrhDasvW2H3eXzU1DsQeOs9w6r-1FTonf7cXdD9G4_9LgfUfbi8Dfdi-4Wgv8B9VsJPw</recordid><startdate>20130301</startdate><enddate>20130301</enddate><creator>Phillips, Bethan E</creator><creator>Williams, John P</creator><creator>Gustafsson, Thomas</creator><creator>Bouchard, Claude</creator><creator>Rankinen, Tuomo</creator><creator>Knudsen, Steen</creator><creator>Smith, Kenneth</creator><creator>Timmons, James A</creator><creator>Atherton, Philip J</creator><general>Public Library of Science</general><general>Public Library of Science (PLoS)</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>IOV</scope><scope>ISN</scope><scope>ISR</scope><scope>7X8</scope><scope>5PM</scope><scope>ADTPV</scope><scope>AOWAS</scope><scope>D8T</scope><scope>ZZAVC</scope><scope>DOA</scope></search><sort><creationdate>20130301</creationdate><title>Molecular networks of human muscle adaptation to exercise and age</title><author>Phillips, Bethan E ; 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Herein, we have delineated molecular networks for these two major components of sarcopenic risk using multiple independent clinical cohorts. We generated genome-wide transcript profiles from individuals (n = 44) who then undertook 20 weeks of supervised resistance-exercise training (RET). Expectedly, our subjects exhibited a marked range of hypertrophic responses (3% to +28%), and when applying Ingenuity Pathway Analysis (IPA) up-stream analysis to ~580 genes that co-varied with gain in lean mass, we identified rapamycin (mTOR) signaling associating with growth (P = 1.4 × 10(-30)). Paradoxically, those displaying most hypertrophy exhibited an inhibited mTOR activation signature, including the striking down-regulation of 70 rRNAs. Differential analysis found networks mimicking developmental processes (activated all-trans-retinoic acid (ATRA, Z-score = 4.5; P = 6 × 10(-13)) and inhibited aryl-hydrocarbon receptor signaling (AhR, Z-score = -2.3; P = 3 × 10(-7))) with RET. Intriguingly, as ATRA and AhR gene-sets were also a feature of endurance exercise training (EET), they appear to represent "generic" physical activity responsive gene-networks. For age, we found that differential gene-expression methods do not produce consistent molecular differences between young versus old individuals. Instead, utilizing two independent cohorts (n = 45 and n = 52), with a continuum of subject ages (18-78 y), the first reproducible set of age-related transcripts in human muscle was identified. This analysis identified ~500 genes highly enriched in post-transcriptional processes (P = 1 × 10(-6)) and with negligible links to the aforementioned generic exercise regulated gene-sets and some overlap with ribosomal genes. The RNA signatures from multiple compounds all targeting serotonin, DNA topoisomerase antagonism, and RXR activation were significantly related to the muscle age-related genes. Finally, a number of specific chromosomal loci, including 1q12 and 13q21, contributed by more than chance to the age-related gene list (P = 0.01-0.005), implying possible epigenetic events. We conclude that human muscle age-related molecular processes appear distinct from the processes regulated by those of physical activity.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>23555298</pmid><doi>10.1371/journal.pgen.1003389</doi><oa>free_for_read</oa></addata></record>
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subjects	Adaptation, Physiological - genetics Adolescent Adult Aged Aging Aging - genetics Aging - metabolism Aging - physiology Biology Down-Regulation Exercise Exercise - physiology Female Gene Expression Profiling Gene Regulatory Networks - physiology Genetic transcription Humans Kinases Male Medicine Middle Aged Molecular genetics Muscle, Skeletal - metabolism Muscle, Skeletal - physiology Muscular system Proteins Ribosome Subunits - genetics Ribosome Subunits - metabolism Ribosome Subunits - physiology Signal Transduction TOR Serine-Threonine Kinases - genetics TOR Serine-Threonine Kinases - metabolism
title	Molecular networks of human muscle adaptation to exercise and age
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