2025

Hulmi, Juha J.; Halonen, Eeli J.; Sharples, Adam P.; O'Connell, Thomas M.; Kuikka, Lauri; Lappi, Veli‐Matti; Salokas, Kari; Keskitalo, Salla; Varjosalo, Markku; Ahtiainen, Juha P.

Investigating repeated resistance training (RT) separated by a training break enables exploration of the potential for a proteomic memory of RT-induced skeletal muscle growth, i.e. retained protein adaptations from the previous RT. Our aim was to examine skeletal muscle proteome response to 10-week RT (RT1) followed by 10-week training cessation (i.e. detraining, DT), and finally, 10-week retraining (RT2). Thirty healthy, untrained participants conducted either periodic RT (RT1-DT-RT2, n = 17) or a 10-week no-training control period (n = 13) followed by 20 weeks of RT (n = 11). RT included twice-weekly supervised whole-body RT sessions, and resting vastus lateralis biopsies were obtained every 10 weeks for proteomics analysis using high-end dia-PASEF's mass spectrometry. The first RT period altered 150 proteins (93% increased) involved in, for example, energy metabolism and protein processing compared to minor changes during the control period. The proteome adaptations were similar after the second RT compared to baseline demonstrating reproducibility in proteome adaptations to RT. Many of the proteins induced by RT1 were reversed towards baseline after detraining and increased again after retraining. These reversible proteins were especially involved in aerobic energy metabolism. Interestingly, several proteins which increased after RT1 remain elevated (i.e. retained) after detraining, including carbonyl reductase 1 (CBR1) and proteins involved in muscle contraction, cytoskeleton and calcium binding. Among the latter, calcium-activated protease calpain-2 (CAPN2) has been recently identified as an epigenetic muscle memory gene. We show that resistance training evokes retained protein levels even after 2.5 months of no training, which demonstrates a potential proteomic memory of resistance training-induced muscle growth in human skeletal muscle.