Skeletal Muscle Cells Derived From Old Donors Show Altered Mitochondrial Morphology And Reduced Respiratory Capacity

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With age, skeletal muscle mitochondria lose their oxidative capacity and their ability to respond to energy demand. These phenomena can lead to a reduction in skeletal muscle oxygen consumption, atrophy, and increased risk of developing age-related diseases such as sarcopenia. Whether age-derived changes in mitochondrial function correspond to structural changes in the mitochondrial reticulum remains unknown. PURPOSE: Investigate age-related changes in mitochondrial morphology and function using primary skeletal muscle cells derived from healthy young and old men. METHODS: Primary skeletal muscle progenitor cells (SkM) derived from the Rectus abdominis muscle of healthy active 18-19-year-old men (SkM Young), and 66-69-year-old men (SkM Old) were obtained from Cook MyoSite Inc. (Pittsburgh, PA). The mitochondrial network was analyzed in live cells using confocal microscopy. Oxygen Consumption Rate (OCR) was measured in intact cells using extracellular flux assays and a Seahorse analyzer (Agilent Technologies; Santa Clara, CA). RESULTS: Primary cells derived from SkM Young revealed a higher Basal and Maximal OCR compared to SkM Old (Basal: 23.20 ± 1.49 vs. 11.34 ± 2.31; Maximal: 41.50 ± 4.72 vs. 18.36 ± 1.65 pmol/min/protein). SkM Young also had higher ATP production and Spare Respiratory Capacity (ATP: 19.08 ± 1.21 vs. 9.19 ± 2.10; SRC: 18.30 ± 3.47 vs. 7.03 ± 1.29 pmol/min/protein). No differences were revealed in morphology (Individuals: 37.80 ± 23.18 vs. 46.67 ± 22.43 counts; Networks: 10.20 ± 2.48 vs. 15.33 ± 5.75 counts; Mean Branches per Network: 15.52 ± 6.41 vs. 11.27 ± 3.67 counts). CONCLUSIONS: These preliminary results show primary skeletal muscle progenitor cells derived from healthy young donors have higher respiration, produce more ATP, and have a greater capacity to adapt to energy demands when compared to SkM derived from Old donors. Further analyses can give us an insight into human skeletal muscle-derived cellular physiological capacity. Technology to observe human muscle mitochondrial dysfunction in vitro helps us understand the effects of aging on skeletal muscle mitochondria and whole-body declines of resting and exercise metabolic rates. Additional studies will be required on aging individuals to determine if predicted decrements in energy coupling efficiency occur with aging in vivo.