1. Hypoxia Resistance Is an Inherent Phenotype of the Mouse Flexor Digitorum Brevis Skeletal Muscle.
- Author
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Amorese, Adam J, Minchew, Everett C, Tarpey, Michael D, Readyoff, Andrew T, Williamson, Nicholas C, Schmidt, Cameron A, McMillin, Shawna L, Goldberg, Emma J, Terwilliger, Zoe S, Spangenburg, Quincy A, Witczak, Carol A, Brault, Jeffrey J, Abel, E Dale, McClung, Joseph M, Fisher-Wellman, Kelsey H, and Spangenburg, Espen E
- Subjects
SKELETAL muscle ,HINDLIMB ,SOLEUS muscle ,HYPOXEMIA ,PHENOTYPES ,GLUCOSE transporters ,EIGENFUNCTIONS - Abstract
The various functions of skeletal muscle (movement, respiration, thermogenesis, etc.) require the presence of oxygen (O
2 ). Inadequate O2 bioavailability (ie, hypoxia) is detrimental to muscle function and, in chronic cases, can result in muscle wasting. Current therapeutic interventions have proven largely ineffective to rescue skeletal muscle from hypoxic damage. However, our lab has identified a mammalian skeletal muscle that maintains proper physiological function in an environment depleted of O2 . Using mouse models of in vivo hindlimb ischemia and ex vivo anoxia exposure, we observed the preservation of force production in the flexor digitorum brevis (FDB), while in contrast the extensor digitorum longus (EDL) and soleus muscles suffered loss of force output. Unlike other muscles, we found that the FDB phenotype is not dependent on mitochondria, which partially explains the hypoxia resistance. Muscle proteomes were interrogated using a discovery-based approach, which identified significantly greater expression of the transmembrane glucose transporter GLUT1 in the FDB as compared to the EDL and soleus. Through loss-and-gain-of-function approaches, we determined that GLUT1 is necessary for the FDB to survive hypoxia, but overexpression of GLUT1 was insufficient to rescue other skeletal muscles from hypoxic damage. Collectively, the data demonstrate that the FDB is uniquely resistant to hypoxic insults. Defining the mechanisms that explain the phenotype may provide insight towards developing approaches for preventing hypoxia-induced tissue damage. Graphical Abstract Mouse models of in vivo hindlimb ischemia and ex vivo anoxia exposure were employed to demonstrate the ability of the FDB to function without oxygen. Discovery-based proteomics identified significantly higher expression of the glucose transporter GLUT1 in the FDB as compared to the hypoxia-sensitive EDL and soleus muscles. Loss-and-gain-of-function approaches revealed that GLUT1 is necessary for the FDB phenotype, but insufficient to rescue other skeletal muscles from hypoxic damage. [ABSTRACT FROM AUTHOR]- Published
- 2023
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