PHD2 mediated loss of hypoxia signaling limits skeletal muscle regeneration and exercise response in aging
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PROJECT SUMMARY/ABSTRACT I am interested in developing novel treatment strategies for maintaining muscle mass and function in the elderly population. My lab utilizes murine models of aging to investigate mechanisms on how aging-associated loss of hypoxia signaling in skeletal muscle affects two key factors in maintenance of muscle mass and function: (1) skeletal muscle regeneration and (2) adaptation to aerobic exercise. Prolyl hydroxylase domain enzyme (PHD)2 increases profoundly in skeletal muscle with aging and is a key regulator of the hypoxia signaling pathway. This increase in skeletal muscle PHD2 leads to loss of hypoxia inducible factor (HIF)-1, a central transcription factor responsible for downstream hypoxia pathway signaling. Using a murine model of aging and genetically modified mice, we have demonstrated that a muscle specific increase in PHD2 recapitulates diminished skeletal muscle regeneration and loss of aerobic exercise adaptation as seen in aging. Building on these intriguing pilot data, the central goals of this project are to (1) mechanistically define the role of PHD2 and its impact on muscle regeneration in aging, (2) determine whether PHD2 inhibition preserves skeletal muscle myogenic potential with aging, and (3) evaluate if increased skeletal muscle PHD2 in aging limits muscle adaptation in response to aerobic exercise. Importantly, transcriptome analysis in humans also demonstrates decreased hypoxia signaling in old skeletal muscle, suggesting translational potential for hypoxia signaling targets. As FDA approved PHD2 inhibitors are available, an improved mechanistic understanding of hypoxia signaling as it relates to skeletal muscle regeneration and exercise response may offer therapeutic opportunities for elderly patients suffering from loss of muscle function with aging.
