Abstract
It is controversial whether mitochondrial dysfunction in skeletal muscle is the cause or consequence of metabolic disorders. Herein, we demonstrate that in vivo inhibition of mitochondrial ATP synthase in muscle alters whole‐body lipid homeostasis. Mice with restrained mitochondrial ATP synthase activity presented intrafiber lipid droplets, dysregulation of acyl‐glycerides, and higher visceral adipose tissue deposits, poising these animals to insulin resistance. This mitochondrial energy crisis increases lactate production, prevents fatty acid β‐oxidation, and forces the catabolism of branched‐chain amino acids (BCAA) to provide acetyl‐CoA for de novo lipid synthesis. In turn, muscle accumulation of acetyl‐CoA leads to acetylation‐dependent inhibition of mitochondrial respiratory complex II enhancing oxidative phosphorylation dysfunction which results in augmented ROS production. By screening 702 FDA‐approved drugs, we identified edaravone as a potent mitochondrial antioxidant and enhancer. Edaravone administration restored ROS and lipid homeostasis in skeletal muscle and reinstated insulin sensitivity. Our results suggest that muscular mitochondrial perturbations are causative of metabolic disorders and that edaravone is a potential treatment for these diseases.
Highlights
Obesity is a complex chronic condition that affects all organ systems and increases the rate of premature mortality (Spiegelman & Flier, 2001; Stefan et al, 2017)
In order to assess the role of oxidative phosphorylation (OXPHOS) on the pathophysiology of skeletal muscle (Skm) lipid metabolism, we generated an inducible and tissue-specific mouse model that expressed the active form (Boreikaite et al, 2019) of the human ATP synthase inhibitor ATPIF1H49K (Formentini et al, 2014) in striatal muscle
O2 consumption rate (OCR) in isolated mitochondria from Skm confirmed that state 3 (ADP-stimulated) but not uncoupled (FCCP-induced) respiration was significantly inhibited in ATPIF1H49K|T/H mice when compared to that in control mice (Fig 1E), suggesting that the ATPIF1H49K effect was specific to ATP synthase
Summary
Obesity is a complex chronic condition that affects all organ systems and increases the rate of premature mortality (Spiegelman & Flier, 2001; Stefan et al, 2017). WAT and Skm are endocrine organs that release and respond to hormones, a function that contributes to chronic inflammation associated with metabolic diseases (Pedersen & Febbraio, 2012; Stanford et al, 2015; Ciaraldi et al, 2016). Mitochondria are essential in maintaining cell homeostasis by controlling bioenergetics, immunity, intracellular signaling, and cell death (Spinelli & Haigis, 2018). These organelles are involved in coordinating cellular adaptation to stressors and nutrient availability, and regulating glucose, amino acid, and lipid metabolism (Liesa & Shirihai, 2013; Vyas et al, 2016; Garcia-Bermudez et al, 2018). Since Skm is the largest oxidative and insulin-sensitive organ in mammals, understanding this mitochondrial-mediated metabolic flexibility may reveal new therapeutic strategies for diseases characterized by whole-body dysregulation of glucose and lipid metabolism
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
