Description

Mitochondrial dysfunction is a central contributor to skeletal muscle weakness, metabolic dysregulation, and reduced physical capacity in mitochondrial myopathies. Defects in mitochondrial oxidative phosphorylation impair energy production and trigger maladaptive cellular stress responses, contributing to progressive muscle deterioration. While structured exercise training has been shown to improve mitochondrial oxidative capacity and functional performance in individuals with mitochondrial myopathy, the cellular and molecular pathways driving these adaptations are not fully defined.

This study employs a within-subject, parallel-group, unilateral exercise training model to examine exercise-induced adaptations in skeletal muscle from adults with mitochondrial myopathy and matched healthy controls. Participants undergo a 3-4-week supervised unilateral aerobic interval training program consisting of 10 sessions, with the trained leg randomized and the contralateral leg serving as an internal untrained control. This design increases statistical power and allows direct comparison of trained versus untrained muscle within the same individual.

Comprehensive phenotyping is conducted before the intervention, including assessments of muscle strength, functional performance, body composition, physical activity, and maximal oxygen uptake. Skeletal muscle biopsies obtained from both legs following the intervention enable detailed evaluation of mitochondrial respiratory function, mitochondrial morphology, neuromuscular junction structure, protein synthesis, signaling pathways, and unbiased multi-omics analyses (proteomics, phosphoproteomics, metabolomics, lipidomics, and transcriptomics).

By integrating physiological, molecular, and structural outcomes, this study seeks to elucidate mechanisms by which exercise training may partially reverse mitochondrial and neuromuscular defects in mitochondrial myopathy and establish exercise as a targeted therapeutic strategy for mitochondrial dysfunction.