Inactivity and exercise training differentially regulate abundance of Na + -K + -ATPase in human skeletal muscle

• Published in: Journal of applied physiology (1985) Vol. 127; no. 4; pp. 905 - 920
• Main Authors: Wyckelsma, V L, Perry, B D, Bangsbo, J, McKenna, M J
• Format: Journal Article
• Language: English
• Published: United States American Physiological Society 01.10.2019
• Subjects: Adaptability; Binding sites; Depolarization; Exercise; Fatigue; Fitness training programs; Global health; Health risks; Injury prevention; Isoforms; Membrane potential; Muscles; Muscular fatigue; Musculoskeletal system; Na+/K+-exchanging ATPase; Ouabain; Physical activity; Physical fitness; Physical training; Proteins; Skeletal muscle; Na+-K+ pump; disuse; physical activity
• ISSN: 8750-7587; 1522-1601
• DOI: 10.1152/japplphysiol.01076.2018

Physical inactivity is a global health risk that can be addressed through application of exercise training suitable for an individual's health and age. People's willingness to participate in physical activity is often limited by an initially poor physical capability and early onset of fatigue. One factor associated with muscle fatigue during intense contractions is an inexcitability of skeletal muscle cells, reflecting impaired transmembrane Na /K exchange and membrane depolarization, which are regulated via the transmembranous protein Na -K -ATPase (NKA). This short review focuses on the plasticity of NKA in skeletal muscle in humans after periods of altered usage, exploring NKA upregulation with exercise training and downregulation with physical inactivity. In human skeletal muscle, the NKA content quantified by [ H]ouabain binding site content shows robust, yet tightly constrained, upregulation of 8-22% with physical training, across a broad range of exercise training types. Muscle NKA content in humans undergoes extensive downregulation with injury that involves substantial muscular inactivity. Surprisingly, however, no reduction in NKA content was found in the single study that investigated short-term disuse. Despite clear findings that exercise training and injury modulate NKA content, the adaptability of the individual NKA isoforms in muscle (α and β ) and of the accessory and regulatory protein FXYD1 are surprisingly inconsistent across studies, for exercise training as well as for injury/disuse. Potential reasons for this are explored. Finally, we provide suggestions for future studies to provide greater understanding of NKA regulation during exercise training and inactivity in humans.