Transcriptomic meta-analysis of disuse muscle atrophy vs. resistance exercise-induced hypertrophy in young and older humans
Transcriptomic meta-analysis of disuse muscle atrophy vs. resistance exercise-induced hypertrophy in young and older humans
Background: skeletal muscle atrophy manifests across numerous diseases; however, the extent of similarities/differences in causal mechanisms between atrophying conditions in unclear. Ageing and disuse represent two of the most prevalent and costly atrophic conditions, with resistance exercise training (RET) being the most effective lifestyle countermeasure. We employed gene-level and network-level meta-analyses to contrast transcriptomic signatures of disuse and RET, plus young and older RET to establish a consensus on the molecular features of, and therapeutic targets against, muscle atrophy in conditions of high socio-economic relevance.
Methods: integrated gene-level and network-level meta-analysis was performed on publicly available microarray data sets generated from young (18-35 years) m. vastus lateralis muscle subjected to disuse (unilateral limb immobilization or bed rest) lasting ≥7 days or RET lasting ≥3 weeks, and resistance-trained older (≥60 years) muscle.
Results: disuse and RET displayed predominantly separate transcriptional responses, and transcripts altered across conditions were mostly unidirectional. However, disuse and RET induced directly inverted expression profiles for mitochondrial function and translation regulation genes, with COX4I1, ENDOG, GOT2, MRPL12, and NDUFV2, the central hub components of altered mitochondrial networks, and ZMYND11, a hub gene of altered translation regulation. A substantial number of genes (n = 140) up-regulated post-RET in younger muscle were not similarly up-regulated in older muscle, with young muscle displaying a more pronounced extracellular matrix (ECM) and immune/inflammatory gene expression response. Both young and older muscle exhibited similar RET-induced ubiquitination/RNA processing gene signatures with associated PWP1, PSMB1, and RAF1 hub genes.
Conclusions: despite limited opposing gene profiles, transcriptional signatures of disuse are not simply the converse of RET. Thus, the mechanisms of unloading cannot be derived from studying muscle loading alone and provides a molecular basis for understanding why RET fails to target all transcriptional features of disuse. Loss of RET-induced ECM mechanotransduction and inflammatory profiles might also contribute to suboptimal ageing muscle adaptations to RET. Disuse and age-dependent molecular candidates further establish a framework for understanding and treating disuse/ageing atrophy.
629–645
Deane, Colleen S.
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Willis, Craig R.G.
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Phillips, Bethan E.
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Atherton, Philip J.
c777bf46-a14b-420b-9278-d5935acd818f
Harries, Lorna W.
f578eb4b-21bf-4bb1-bdf5-31655828a901
Ames, Ryan M.
b4509923-155a-4026-88f0-9e116ece7f0f
Szewczyk, Nathaniel J.
e0310853-8847-46b8-8694-50d248af114d
Etheridge, Timothy
7e2a840e-e28f-4b54-ba02-dcad0561dfc4
5 May 2021
Deane, Colleen S.
3320532e-f411-4ea8-9a14-4a9f248da898
Willis, Craig R.G.
bef6e91c-2762-4363-92cb-3eefebe73487
Phillips, Bethan E.
1d492d19-9b7f-4515-8982-5d2f16bc8b59
Atherton, Philip J.
c777bf46-a14b-420b-9278-d5935acd818f
Harries, Lorna W.
f578eb4b-21bf-4bb1-bdf5-31655828a901
Ames, Ryan M.
b4509923-155a-4026-88f0-9e116ece7f0f
Szewczyk, Nathaniel J.
e0310853-8847-46b8-8694-50d248af114d
Etheridge, Timothy
7e2a840e-e28f-4b54-ba02-dcad0561dfc4
Deane, Colleen S., Willis, Craig R.G., Phillips, Bethan E., Atherton, Philip J., Harries, Lorna W., Ames, Ryan M., Szewczyk, Nathaniel J. and Etheridge, Timothy
(2021)
Transcriptomic meta-analysis of disuse muscle atrophy vs. resistance exercise-induced hypertrophy in young and older humans.
Journal of Cachexia, Sarcopenia and Muscle, 12, .
(doi:10.1002/jcsm.12706).
Abstract
Background: skeletal muscle atrophy manifests across numerous diseases; however, the extent of similarities/differences in causal mechanisms between atrophying conditions in unclear. Ageing and disuse represent two of the most prevalent and costly atrophic conditions, with resistance exercise training (RET) being the most effective lifestyle countermeasure. We employed gene-level and network-level meta-analyses to contrast transcriptomic signatures of disuse and RET, plus young and older RET to establish a consensus on the molecular features of, and therapeutic targets against, muscle atrophy in conditions of high socio-economic relevance.
Methods: integrated gene-level and network-level meta-analysis was performed on publicly available microarray data sets generated from young (18-35 years) m. vastus lateralis muscle subjected to disuse (unilateral limb immobilization or bed rest) lasting ≥7 days or RET lasting ≥3 weeks, and resistance-trained older (≥60 years) muscle.
Results: disuse and RET displayed predominantly separate transcriptional responses, and transcripts altered across conditions were mostly unidirectional. However, disuse and RET induced directly inverted expression profiles for mitochondrial function and translation regulation genes, with COX4I1, ENDOG, GOT2, MRPL12, and NDUFV2, the central hub components of altered mitochondrial networks, and ZMYND11, a hub gene of altered translation regulation. A substantial number of genes (n = 140) up-regulated post-RET in younger muscle were not similarly up-regulated in older muscle, with young muscle displaying a more pronounced extracellular matrix (ECM) and immune/inflammatory gene expression response. Both young and older muscle exhibited similar RET-induced ubiquitination/RNA processing gene signatures with associated PWP1, PSMB1, and RAF1 hub genes.
Conclusions: despite limited opposing gene profiles, transcriptional signatures of disuse are not simply the converse of RET. Thus, the mechanisms of unloading cannot be derived from studying muscle loading alone and provides a molecular basis for understanding why RET fails to target all transcriptional features of disuse. Loss of RET-induced ECM mechanotransduction and inflammatory profiles might also contribute to suboptimal ageing muscle adaptations to RET. Disuse and age-dependent molecular candidates further establish a framework for understanding and treating disuse/ageing atrophy.
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J cachexia sarcopenia muscle - 2021 - Deane - Transcriptomic meta‐analysis of disuse muscle atrophy vs resistance
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Accepted/In Press date: 29 March 2021
Published date: 5 May 2021
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Local EPrints ID: 483346
URI: http://eprints.soton.ac.uk/id/eprint/483346
ISSN: 2190-5991
PURE UUID: 6cee62e6-5ac8-488f-9d3c-efe059c75949
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Date deposited: 30 Oct 2023 07:58
Last modified: 17 Mar 2024 04:15
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Contributors
Author:
Colleen S. Deane
Author:
Craig R.G. Willis
Author:
Bethan E. Phillips
Author:
Philip J. Atherton
Author:
Lorna W. Harries
Author:
Ryan M. Ames
Author:
Nathaniel J. Szewczyk
Author:
Timothy Etheridge
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