CDK4-E2F3 signals enhance oxidative skeletal muscle fiber numbers and function to affect myogenesis and metabolism
Young Jae Bahn, … , Alexandra C. McPherron, Sushil G. Rane
Young Jae Bahn, … , Alexandra C. McPherron, Sushil G. Rane
Published July 3, 2023
Citation Information: J Clin Invest. 2023;133(13):e162479. https://doi.org/10.1172/JCI162479.
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CDK4-E2F3 signals enhance oxidative skeletal muscle fiber numbers and function to affect myogenesis and metabolism

Abstract

Understanding how skeletal muscle fiber proportions are regulated is vital to understanding muscle function. Oxidative and glycolytic skeletal muscle fibers differ in their contractile ability, mitochondrial activity, and metabolic properties. Fiber-type proportions vary in normal physiology and disease states, although the underlying mechanisms are unclear. In human skeletal muscle, we observed that markers of oxidative fibers and mitochondria correlated positively with expression levels of PPARGC1A and CDK4 and negatively with expression levels of CDKN2A, a locus significantly associated with type 2 diabetes. Mice expressing a constitutively active Cdk4 that cannot bind its inhibitor p16INK4a, a product of the CDKN2A locus, were protected from obesity and diabetes. Their muscles exhibited increased oxidative fibers, improved mitochondrial properties, and enhanced glucose uptake. In contrast, loss of Cdk4 or skeletal muscle–specific deletion of Cdk4’s target, E2F3, depleted oxidative myofibers, deteriorated mitochondrial function, and reduced exercise capacity, while increasing diabetes susceptibility. E2F3 activated the mitochondrial sensor PPARGC1A in a Cdk4-dependent manner. CDK4, E2F3, and PPARGC1A levels correlated positively with exercise and fitness and negatively with adiposity, insulin resistance, and lipid accumulation in human and rodent muscle. All together, these findings provide mechanistic insight into regulation of skeletal muscle fiber–specification that is of relevance to metabolic and muscular diseases.

Authors

Young Jae Bahn, Hariom Yadav, Paolo Piaggi, Brent S. Abel, Oksana Gavrilova, Danielle A. Springer, Ioannis Papazoglou, Patricia M. Zerfas, Monica C. Skarulis, Alexandra C. McPherron, Sushil G. Rane

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Figure 6

Correlation of myofiber and mitochondrial gene expression with Cdk4 and E2F3 status.

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Correlation of myofiber and mitochondrial gene expression with Cdk4 and ...
(A) Venn diagram showing the overlap of differentially expressed genes (DEGs; P < 0.05) comparing both Cdk4WT (WT) and Cdk4R/R (RR) mice as well as E2F3WT and E2F3mKO mice (top), and GO analysis of 199 overlapping genes (bottom). (B) Scatterplot of DEGs comparing Cdk4WT and Cdk4R/R mice as well as E2F3WT and E2F3mKO mice. Blue dots represent type I fiber markers that are upregulated in Cdk4R/R muscle and downregulated in E2F3mKO muscle. (C) Log2 fold change values determined by RNA-Seq from groups of upregulated genes in Cdk4R/R muscle and downregulated genes in E2F3mKO muscle representing myofiber, ion transport, and muscle potential genes, including type I fiber markers. (D) Venn diagram showing the overlap of DEGs (P < 0.05) in Cdk4WT and Cdk4mKO (KO) muscle as well as E2F3WT and E2F3mKO muscle (top), and GO analysis of 483 overlapping genes (bottom). (E) Heatmap of the overlapped 483 genes defined in D and gene ontology (GO) analysis of co-upregulated (red) or codownregulated (green) genes with color intensities indicating Z score (n = 3 mice each group).