Dynamic proteome profiling uncovers age-related impairments in proteostasis and the protective effects of resistance exercise in human skeletal muscle

A loss of proteostasis is a primary hallmark of ageing that has emerged from mechanistic studies in model organisms, but little is currently known about changes to proteostasis in the muscle of older humans. We used stable isotope labelling (deuterium oxide; D2O) in vivo, and peptide mass spectrometry of muscle samples to investigate differences in proteome dynamics between the muscle of younger (28 ± 5 y; n=4) and older (69 ± 3 y; n=4) men during either habitual activity or resistance exercise training. We quantified the abundance of 1787 proteins and the turnover rate of 1046 proteins in bi-lateral samples of vastus lateralis (n=32 samples total) taken before and after a 15-day program including 5 sessions of unilateral leg-press exercise (3 sets of 10 repetitions at 90% of 10 RM). Our protein abundance profiling revealed a stoichiometric imbalance within the proteostasis network in aged skeletal muscle, including subunits of eIF3, subunits of 40S and 60S ribosomal proteins. The rate of bulk, mixed-protein synthesis was not different between younger and older men, but most ribosomal proteins were less abundant in the muscle of older participants, suggesting ribosomes in older muscle may exhibit increased translational efficiency to maintain similar levels of protein turnover compared to ribosomes in younger muscle. Resistance exercise partially restored age-related disruptions to the proteostasis network. In older skeletal muscle, resistance exercise specifically increased the absolute turnover rate (ATR) of mixed mitochondrial proteins, with increased fractional turnover rate (FTR) of prohibitin 1 (PHB1) and profilin-1 (PROF1), and increased abundance of prohibitin 2 (PHB2). These adaptations may suggest resistance exercise promotes mitochondrial proteostasis by facilitating the synthesis and maintenance of key mitochondrial proteins. Thus, our Dynamic Proteome Profiling data provide an impetus for further exploration of the role of proteostasis in maintaining skeletal muscle quality and supports resistance exercise as a potential therapeutic strategy to promote healthy skeletal muscle ageing in humans.