TY - JOUR
T1 - Skeletal muscle mitochondrial fragmentation predicts age-associated decline in physical capacity
AU - Goulding, Richie
AU - Charlton, Braeden
AU - Breedveld, Ellen
AU - van der Laan, Matthijs
AU - Strating, Anne
AU - Noort, Wendy
AU - Kolodyazhna, Aryna
AU - Appelman, Brent
AU - van Vugt, Michele
AU - Grootemaat, Anita
AU - van der Wel, Nicole N
AU - de Koning, Jos
AU - Bloemers, Frank W.
AU - Wust, Rob
PY - 2024
Y1 - 2024
N2 - Ageing substantially impairs skeletal muscle metabolic and physical function. Skeletal muscle mitochondrial health is also impaired with ageing, but the role of skeletal muscle mitochondrial fragmentation in age-related functional decline remains imprecisely characterized. Here, using a cross-sectional study design, we performed a detailed comparison of skeletal muscle mitochondrial characteristics in relation to in vivo markers of exercise capacity between young and middle-aged individuals. Despite similar overall oxidative phosphorylation capacity (young: 99±17 vs. middle-aged: 99±27 pmol O2.s-1.mg-1, P=0.95) and intermyofibrillar mitochondrial density (young: 5.86±0.57 vs. middle-aged: 5.68±1.48%, P=0.25), older participants displayed a more fragmented intermyofibrillar mitochondrial network (young: 1.15±0.17 vs. middle-aged: 1.55±0.15 A.U., P<0.0001), a lower mitochondrial cristae density (young: 23.40±7.12 vs. middle-aged: 13.55±4.10%, P=0.002), and a reduced subsarcolemmal mitochondrial density (young: 22.39±6.50 vs. middle-aged: 13.92±4.95%, P=0.005). Linear regression analysis showed that 87% of the variance associated with maximal oxygen uptake could be explained by skeletal muscle mitochondrial fragmentation and cristae density alone, whereas subsarcolemmal mitochondrial density was positively associated with the capacity for oxygen extraction during exercise. Intramuscular lipid accumulation was positively associated with mitochondrial fragmentation and negatively associated with cristae density. Collectively, our work highlights the critical role of skeletal muscle mitochondria in age-associated declines in physical function.
AB - Ageing substantially impairs skeletal muscle metabolic and physical function. Skeletal muscle mitochondrial health is also impaired with ageing, but the role of skeletal muscle mitochondrial fragmentation in age-related functional decline remains imprecisely characterized. Here, using a cross-sectional study design, we performed a detailed comparison of skeletal muscle mitochondrial characteristics in relation to in vivo markers of exercise capacity between young and middle-aged individuals. Despite similar overall oxidative phosphorylation capacity (young: 99±17 vs. middle-aged: 99±27 pmol O2.s-1.mg-1, P=0.95) and intermyofibrillar mitochondrial density (young: 5.86±0.57 vs. middle-aged: 5.68±1.48%, P=0.25), older participants displayed a more fragmented intermyofibrillar mitochondrial network (young: 1.15±0.17 vs. middle-aged: 1.55±0.15 A.U., P<0.0001), a lower mitochondrial cristae density (young: 23.40±7.12 vs. middle-aged: 13.55±4.10%, P=0.002), and a reduced subsarcolemmal mitochondrial density (young: 22.39±6.50 vs. middle-aged: 13.92±4.95%, P=0.005). Linear regression analysis showed that 87% of the variance associated with maximal oxygen uptake could be explained by skeletal muscle mitochondrial fragmentation and cristae density alone, whereas subsarcolemmal mitochondrial density was positively associated with the capacity for oxygen extraction during exercise. Intramuscular lipid accumulation was positively associated with mitochondrial fragmentation and negatively associated with cristae density. Collectively, our work highlights the critical role of skeletal muscle mitochondria in age-associated declines in physical function.
KW - Ageing
KW - Maximal oxygen uptake
KW - Mitochondrial morphology
KW - Mitochondrial respiration
KW - Skeletal muscle
U2 - 10.1111/ acel.14386
DO - 10.1111/ acel.14386
M3 - Article
SN - 1474-9718
JO - Aging Cell
JF - Aging Cell
ER -