Exercise induces anti-inflammatory reprogramming in macrophages via Hsp60

Physical activity exerts systemic anti-inflammatory effects and reduces the risk for multiple non-communicable diseases, with 7.2% of all-cause deaths globally being attributed to physical inactivity. However, the cellular and molecular components of the exercise-induced anti-inflammatory effects remain only partly understood. Herein we show that moderate-intensity exercise promotes anti-inflammatory reprograming of macrophages orchestrated by the skeletal muscle cells secretome. Primary bone marrow-derived macrophages (BMDMs) exposed to the secretome of mechanically-loaded myotubes (exercise-conditioned medium, exCM) acquire an anti-inflammatory transcriptional profile and increased reliance on oxidative phosphorylation, as shown by Seahorse real-time cell metabolic analysis, compatible with an M2-like phenotypic switch. Using an unbiased proteomic analysis of the exCM we identify the chaperonin Hsp60 as a key mediator of the anti-inflammatory effects of exercise. Hsp60 expression increases in mechanically loaded myotubes in vitro, in the quadriceps muscle and serum of mice following an 8-week program of moderate-intensity aerobic exercise, as well as in human muscle after resistance training. Importantly, treatment of BMDMs with Hsp60 in vitro recapitulates the exCM-induced transcriptional reprograming, promoting an M2-like phenotype. Taken together, our data highlight Hsp60 as a novel component of the skeletal muscle cell-macrophage crosstalk, providing mechanistic insights into the anti-inflammatory effects of exercise.