PFKFB3-mediated glycolysis rescues myopathic outcomes in the ischemic limb
Terence E. Ryan, Cameron A. Schmidt, Michael D. Tarpey, Adam J. Amorese, Dean J. Yamaguchi, Emma J. Goldberg, Melissa M.R. Iñigo, Reema Karnekar, Allison O’Rourke, James M. Ervasti, Patricia Brophy, Thomas D. Green, P. Darrell Neufer, Kelsey Fisher-Wellman, Espen E. Spangenburg, Joseph M. McClung
Terence E. Ryan, Cameron A. Schmidt, Michael D. Tarpey, Adam J. Amorese, Dean J. Yamaguchi, Emma J. Goldberg, Melissa M.R. Iñigo, Reema Karnekar, Allison O’Rourke, James M. Ervasti, Patricia Brophy, Thomas D. Green, P. Darrell Neufer, Kelsey Fisher-Wellman, Espen E. Spangenburg, Joseph M. McClung
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Research Article Muscle biology Vascular biology

PFKFB3-mediated glycolysis rescues myopathic outcomes in the ischemic limb

Abstract

Compromised muscle mitochondrial metabolism is a hallmark of peripheral arterial disease, especially in patients with the most severe clinical manifestation — critical limb ischemia (CLI). We asked whether inflexibility in metabolism is critical for the development of myopathy in ischemic limb muscles. Using Polg mtDNA mutator (D257A) mice, we reveal remarkable protection from hind limb ischemia (HLI) due to a unique and beneficial adaptive enhancement of glycolytic metabolism and elevated ischemic muscle PFKFB3. Similar to the relationship between mitochondria from CLI and claudicating patient muscles, BALB/c muscle mitochondria are uniquely dysfunctional after HLI onset as compared with the C57BL/6 (BL6) parental strain. AAV-mediated overexpression of PFKFB3 in BALB/c limb muscles improved muscle contractile function and limb blood flow following HLI. Enrichment analysis of RNA sequencing data on muscle from CLI patients revealed a unique deficit in the glucose metabolism Reactome. Muscles from these patients express lower PFKFB3 protein, and their muscle progenitor cells possess decreased glycolytic flux capacity in vitro. Here, we show supplementary glycolytic flux as sufficient to protect against ischemic myopathy in instances where reduced blood flow–related mitochondrial function is compromised preclinically. Additionally, our data reveal reduced glycolytic flux as a common characteristic of the failing CLI patient limb skeletal muscle.

Authors

Terence E. Ryan, Cameron A. Schmidt, Michael D. Tarpey, Adam J. Amorese, Dean J. Yamaguchi, Emma J. Goldberg, Melissa M.R. Iñigo, Reema Karnekar, Allison O’Rourke, James M. Ervasti, Patricia Brophy, Thomas D. Green, P. Darrell Neufer, Kelsey Fisher-Wellman, Espen E. Spangenburg, Joseph M. McClung

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Figure 5

AAV-mediated expression of PFKFB3 decreases ischemic muscle necrosis and improves muscle function in BALB/c mice.

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AAV-mediated expression of PFKFB3 decreases ischemic muscle necrosis and...
BALB/c mice are known to respond poorly to hind limb ischemia, exhibiting significant muscle necrosis and — in some cases — limb loss. BALB/c mice were given intramuscular injections of AAV-GFP or AAV-PFKFB3 to the hind limb musculature at 1 × 1011 vg/muscle 3 weeks before HLI. (A and B) AAV expression was validated at both the mRNA (A; n = 3/group) and protein (B) level for PFKFB3. (C and D) AAV-PFKFB3 treatment significantly improved perfusion recovery (n = 10/group), measured by laser Doppler perfusion imaging. (E and F) AAV-PFKFB3–treated mice also displayed less limb necrosis (E, n = 10/group) and improved muscle histology (F). Scale bar: 200 µm. (G) Importantly, AAV-PFKFB3 also increased muscle force production, which was undetectable in all AAV-GFP mice. n = 10/group. **P < 0.01 versus control (AAV-GFP or DMSO) using 2-way ANOVA with Tukey’s post hoc for comparisons (D) and Student’s t test (A and G). Data in E were analyzed by nonparametric Mann-Whitney U test. Values are presented as mean ± SEM.