ERK1/2 signaling induces skeletal muscle slow fiber-type switching and reduces muscular dystrophy disease severity
Justin G. Boyer, Vikram Prasad, Taejeong Song, Donghoon Lee, Xing Fu, Kelly M. Grimes, Michelle A. Sargent, Sakthivel Sadayappan, Jeffery D. Molkentin
Justin G. Boyer, Vikram Prasad, Taejeong Song, Donghoon Lee, Xing Fu, Kelly M. Grimes, Michelle A. Sargent, Sakthivel Sadayappan, Jeffery D. Molkentin
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Research Article Muscle biology

ERK1/2 signaling induces skeletal muscle slow fiber-type switching and reduces muscular dystrophy disease severity

Abstract

MAPK signaling consists of an array of successively acting kinases. ERK1 and -2 (ERK1/2) are major components of the greater MAPK cascade that transduce growth factor signaling at the cell membrane. Here, we investigated ERK1/2 signaling in skeletal muscle homeostasis and disease. Using mouse genetics, we observed that the muscle-specific expression of a constitutively active MEK1 mutant promotes greater ERK1/2 signaling that mediates fiber-type switching to a slow, oxidative phenotype with type I myosin heavy chain expression. Using a conditional and temporally regulated Cre strategy, as well as Mapk1 (ERK2) and Mapk3 (ERK1) genetically targeted mice, MEK1-ERK2 signaling was shown to underlie this fast-to-slow fiber-type switching in adult skeletal muscle as well as during development. Physiologic assessment of these activated MEK1-ERK1/2 mice showed enhanced metabolic activity and oxygen consumption with greater muscle fatigue resistance. In addition, induction of MEK1-ERK1/2 signaling increased dystrophin and utrophin protein expression in a mouse model of limb-girdle muscle dystrophy and protected myofibers from damage. In summary, sustained MEK1-ERK1/2 activity in skeletal muscle produces a fast-to-slow fiber-type switch that protects from muscular dystrophy, suggesting a therapeutic approach to enhance the metabolic effectiveness of muscle and protect from dystrophic disease.

Authors

Justin G. Boyer, Vikram Prasad, Taejeong Song, Donghoon Lee, Xing Fu, Kelly M. Grimes, Michelle A. Sargent, Sakthivel Sadayappan, Jeffery D. Molkentin

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Figure 3

Induction of activated MEK1 expression in mature myofibers induces a slow, oxidative phenotype.

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Induction of activated MEK1 expression in mature myofibers induces a slo...
(A) Schematic of the MerCreMer cDNA driven by the human skeletal α-actin promoter in generating tamoxifen inducible and muscle-specific transgenic mice. (B) Tamoxifen dosing regimen to induce constitutive active MEK1 expression for the experiments shown in this figure. (C) Western blot analysis for total MEK1/2 and ERK1/2 protein using lysate from the gastroc muscle of mice of the indicated genotypes. n = 3 per group. β-Tubulin is shown as a loading control. (D) Representative image of the gastroc muscle from 6-month-old mice of the indicated genotypes. (E) Relative muscle weight/tibia length (MW/TL) at 6 months of age for the quad, gastroc, and TA from Ska-MCM (n = 4), Rosa26-MEK1 (n = 6), and Rosa26-MEK1Ska–MCM (n = 9) mice. One-way ANOVA with Tukey’s multiple comparisons test was used for statistical analysis. *P < 0.05 versus controls. Data represent mean ± SEM. (F) mRNA levels determined by qPCR for the indicated genes from the gastroc muscle of 6-month-old mice of the indicated genotypes. Data are presented as the mean ΔCt for each group, error bars represent SEM. Fold differences calculated using the ΔΔCt method are indicated for each transcript tested. n = 4 per group. Significance was determined using a 1-tailed Student’s t test, *P < 0.05. Fold-change ranges are provided in Supplemental Table 2.