Although the effects of training have been studied for decades, data on muscle proteome signature remodelling induced by high intensity training in relation to functional changes in humans remains incomplete. Likewise, β2-agonists are frequently used to counteract exercise-induced bronchoconstriction, but the effects β2-agonist treatment on muscle remodelling and adaptations to training are unknown. In a placebo-controlled parallel study, we randomly assigned 21 trained men to 4 weeks of high intensity training with (HIT+β2A) or without (HIT) daily inhalation of β2-agonist (terbutaline, 4 mg dose−1). Of 486 proteins identified by mass-spectrometry proteomics of muscle biopsies sampled before and after the intervention, 32 and 85 were changing (false discovery rate (FDR) ≤5%) with the intervention in HIT and HIT+β2A, respectively. Proteome signature changes were different in HIT and HIT+β2A (P = 0.005), wherein β2-agonist caused a repression of 25 proteins in HIT+β2A compared to HIT, and an upregulation of 7 proteins compared to HIT. β2-Agonist repressed or even downregulated training-induced enrichment of pathways related to oxidative phosphorylation and glycogen metabolism, but upregulated pathways related to histone trimethylation and the nucleosome. Muscle contractile phenotype changed differently in HIT and HIT+β2A (P ≤ 0.001), with a fast-to-slow twitch transition in HIT and a slow-to-fast twitch transition in HIT+β2A. β2-Agonist attenuated training-induced enhancements in maximal oxygen consumption (P ≤ 0.01) and exercise performance (6.1 vs. 11.6%, P ≤ 0.05) in HIT+β2A compared to HIT. These findings indicate that daily β2-agonist treatment attenuates the beneficial effects of high intensity training on exercise performance and oxidative capacity, and causes remodelling of muscle proteome signature towards a fast-twitch phenotype.
History
Publication title
Journal of Physiology
Volume
596
Pagination
231-252
ISSN
0022-3751
Department/School
School of Pharmacy and Pharmacology
Publisher
Cambridge Univ Press
Place of publication
United States
Rights statement
Copyright 2017 The Authors. Copyright 2017 The Physiological Society