Network analysis of human muscle adaptation to aging and contraction
Network analysis of human muscle adaptation to aging and contraction
Resistance exercise (RE) remains a primary approach for minimising aging muscle decline. Understanding muscle adaptation to individual contractile components of RE (eccentric, concentric) might optimise RE-based intervention strategies. Herein, we employed a network-driven pipeline to identify putative molecular drivers of muscle aging and contraction mode responses. RNA-sequencing data was generated from young (21±1 y) and older (70±1 y) human skeletal muscle before and following acute unilateral concentric and contralateral eccentric contractions. Application of weighted gene co-expression network analysis identified 33 distinct gene clusters ('modules') with an expression profile regulated by aging, contraction and/or linked to muscle strength. These included two contraction 'responsive' modules (related to 'cell adhesion' and 'transcription factor' processes) that also correlated with the magnitude of post-exercise muscle strength decline. Module searches for 'hub' genes and enriched transcription factor binding sites established a refined set of candidate module-regulatory molecules (536 hub genes and 60 transcription factors) as possible contributors to muscle aging and/or contraction responses. Thus, network-driven analysis can identify new molecular candidates of functional relevance to muscle aging and contraction mode adaptations.
740-755
Willis, Craig R.G.
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Ames, Ryan M.
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Deane, Colleen S.
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Phillips, Bethan E.
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Boereboom, Catherine L.
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Abdulla, Haitham
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Bukhari, Syed S.I.
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Lund, Jonathan N.
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Williams, J.P.
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Wilkinson, Daniel J.
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Smith, Kenneth
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Kadi, Fawzi
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Szewczyk, Nathaniel
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Atherton, Philip J.
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Etheridge, Timothy
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Willis, Craig R.G.
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Ames, Ryan M.
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Deane, Colleen S.
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Phillips, Bethan E.
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Boereboom, Catherine L.
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Abdulla, Haitham
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Bukhari, Syed S.I.
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Lund, Jonathan N.
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Williams, J.P.
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Wilkinson, Daniel J.
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Smith, Kenneth
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Kadi, Fawzi
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Szewczyk, Nathaniel
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Atherton, Philip J.
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Etheridge, Timothy
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Willis, Craig R.G., Ames, Ryan M., Deane, Colleen S., Phillips, Bethan E., Boereboom, Catherine L., Abdulla, Haitham, Bukhari, Syed S.I., Lund, Jonathan N., Williams, J.P., Wilkinson, Daniel J., Smith, Kenneth, Kadi, Fawzi, Szewczyk, Nathaniel, Atherton, Philip J. and Etheridge, Timothy
(2020)
Network analysis of human muscle adaptation to aging and contraction.
Aging, 12 (1), .
(doi:10.18632/aging.102653).
Abstract
Resistance exercise (RE) remains a primary approach for minimising aging muscle decline. Understanding muscle adaptation to individual contractile components of RE (eccentric, concentric) might optimise RE-based intervention strategies. Herein, we employed a network-driven pipeline to identify putative molecular drivers of muscle aging and contraction mode responses. RNA-sequencing data was generated from young (21±1 y) and older (70±1 y) human skeletal muscle before and following acute unilateral concentric and contralateral eccentric contractions. Application of weighted gene co-expression network analysis identified 33 distinct gene clusters ('modules') with an expression profile regulated by aging, contraction and/or linked to muscle strength. These included two contraction 'responsive' modules (related to 'cell adhesion' and 'transcription factor' processes) that also correlated with the magnitude of post-exercise muscle strength decline. Module searches for 'hub' genes and enriched transcription factor binding sites established a refined set of candidate module-regulatory molecules (536 hub genes and 60 transcription factors) as possible contributors to muscle aging and/or contraction responses. Thus, network-driven analysis can identify new molecular candidates of functional relevance to muscle aging and contraction mode adaptations.
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aging-v12i1-102653
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Accepted/In Press date: 24 December 2019
e-pub ahead of print date: 7 January 2020
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Local EPrints ID: 483355
URI: http://eprints.soton.ac.uk/id/eprint/483355
ISSN: 1945-4589
PURE UUID: f8ae8961-e290-4926-a068-6daeb535b395
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Date deposited: 30 Oct 2023 07:58
Last modified: 17 Mar 2024 04:15
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Contributors
Author:
Craig R.G. Willis
Author:
Ryan M. Ames
Author:
Colleen S. Deane
Author:
Bethan E. Phillips
Author:
Catherine L. Boereboom
Author:
Haitham Abdulla
Author:
Syed S.I. Bukhari
Author:
Jonathan N. Lund
Author:
J.P. Williams
Author:
Daniel J. Wilkinson
Author:
Kenneth Smith
Author:
Fawzi Kadi
Author:
Nathaniel Szewczyk
Author:
Philip J. Atherton
Author:
Timothy Etheridge
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