Network Analysis of Human Muscle Adaptation to Aging and Contraction

Overview

Journal Aging (Albany NY)

Specialty Geriatrics

Date 2020 Jan 8

PMID 31910159

Citations 11

Authors

Craig R G Willis

Ryan M Ames

Colleen S Deane

Bethan E Phillips

Catherine L Boereboom

Haitham Abdulla

Syed S I Bukhari

Jonathan N Lund

John P Williams

Daniel J Wilkinson

Kenneth Smith

Fawzi Kadi

Nathaniel J Szewczyk

Philip J Atherton

Timothy Etheridge

Affiliations

Soon will be listed here.

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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