Cells, Vol. 14, Pages 1517: Revealing the Specific Contributions of Mitochondrial CB1 Receptors to the Overall Function of Skeletal Muscle in Mice

Cells doi: 10.3390/cells14191517

Authors:
Zoltán Singlár
Péter Szentesi
Nyamkhuu Ganbat
Barnabás Horváth
László Juhász
Mónika Gönczi
Anikó Keller-Pintér
Attila Oláh
Zoltán Máté
Ferenc Erdélyi
László Csernoch
Mónika Sztretye

Skeletal muscle, constituting 40–50% of total body mass, is vital for mobility, posture, and systemic homeostasis. Muscle contraction heavily relies on ATP, primarily generated by mitochondrial oxidative phosphorylation. Mitochondria play a key role in decoding intracellular calcium signals. The endocannabinoid system (ECS), including CB1 receptors (CB1Rs), broadly influences physiological processes and, in muscles, regulates functions like energy metabolism, development, and repair. While plasma membrane CB1Rs (pCB1Rs) are well-established, a distinct mitochondrial CB1R (mtCB1R) population also exists in muscles, influencing mitochondrial oxidative activity and quality control. We investigated the role of mtCB1Rs in skeletal muscle physiology using a novel systemic mitochondrial CB1 deletion murine model. Our in vivo studies showed no changes in motor function, coordination, or grip strength in mtCB1 knockout mice. However, in vitro force measurements revealed significantly reduced specific force in both fast-twitch (EDL) and slow-twitch (SOL) muscles following mtCB1R ablation. Interestingly, knockout EDL muscles exhibited hypertrophy, suggesting a compensatory response to reduced force quality. Electron microscopy revealed significant mitochondrial morphological abnormalities, including enlargement and irregular shapes, correlating with these functional deficits. High-resolution respirometry further demonstrated impaired mitochondrial respiration, with reduced oxidative phosphorylation and electron transport system capacities in knockout mitochondria. Crucially, mitochondrial membrane potential dissipated faster in mtCB1 knockout muscle fibers, whilst mitochondrial calcium levels were higher at rest. These findings collectively establish that mtCB1Rs are critical for maintaining mitochondrial health and function, directly impacting muscle energy production and contractile performance. Our results provide new insights into ECS-mediated regulation of skeletal muscle function and open therapeutic opportunities for muscle disorders and aging.

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Zoltán Singlár www.mdpi.com