The mitochondrial calcium uniporter underlies metabolic fuel preference in skeletal muscle
Jennifer Q. Kwong, Jiuzhou Huo, Michael J. Bround, Justin G. Boyer, Jennifer A. Schwanekamp, Nasab Ghazal, Joshua T. Maxwell, Young C. Jang, Zaza Khuchua, Kevin Shi, Donald M. Bers, Jennifer Davis, Jeffery D. Molkentin
Jennifer Q. Kwong, Jiuzhou Huo, Michael J. Bround, Justin G. Boyer, Jennifer A. Schwanekamp, Nasab Ghazal, Joshua T. Maxwell, Young C. Jang, Zaza Khuchua, Kevin Shi, Donald M. Bers, Jennifer Davis, Jeffery D. Molkentin
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Research Article Cardiology Muscle biology

The mitochondrial calcium uniporter underlies metabolic fuel preference in skeletal muscle

Abstract

The mitochondrial Ca2+ uniporter (MCU) complex mediates acute mitochondrial Ca2+ influx. In skeletal muscle, MCU links Ca2+ signaling to energy production by directly enhancing the activity of key metabolic enzymes in the mitochondria. Here, we examined the role of MCU in skeletal muscle development and metabolic function by generating mouse models for the targeted deletion of Mcu in embryonic, postnatal, and adult skeletal muscle. Loss of Mcu did not affect muscle growth and maturation or otherwise cause pathology. Skeletal muscle–specific deletion of Mcu in mice also did not affect myofiber intracellular Ca2+ handling, but it did inhibit acute mitochondrial Ca2+ influx and mitochondrial respiration stimulated by Ca2+, resulting in reduced acute exercise performance in mice. However, loss of Mcu also resulted in enhanced muscle performance under conditions of fatigue, with a preferential shift toward fatty acid metabolism, resulting in reduced body fat with aging. Together, these results demonstrate that MCU-mediated mitochondrial Ca2+ regulation underlies skeletal muscle fuel selection at baseline and under enhanced physiological demands, which affects total homeostatic metabolism.

Authors

Jennifer Q. Kwong, Jiuzhou Huo, Michael J. Bround, Justin G. Boyer, Jennifer A. Schwanekamp, Nasab Ghazal, Joshua T. Maxwell, Young C. Jang, Zaza Khuchua, Kevin Shi, Donald M. Bers, Jennifer Davis, Jeffery D. Molkentin

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Figure 1

Loss of Mcu during skeletal muscle embryonic development does not cause growth impairment.

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Loss of Mcu during skeletal muscle embryonic development does not cause ...
(A) Strategy to generate the Mcufl/fl-MyoD-Cre mice. (B) Western blot analysis of MCU expression from muscle mitochondria isolated from 2-month-old animals. The voltage-dependent anion channel (VDAC) was used as the protein loading control. (C) Quantification of total Ca2+ content in isolated muscle mitochondria (mito) from the indicated groups; n = 5 (Mcufl/fl), n = 4 (Mcufl/fl-MyoD-Cre). Student’s t-test was used to analyze groups for statistical significance. (D) Stimulated Ca2+ uptake in saponin permeabilized FDB myofibers challenged with a 20 μM Ca2+ bolus (arrow); average axial mitochondrial Rhod-2 fluorescence (relative units, RU) was tracked from the given genotypes. Mcufl/fl-MyoD-Cre, n = 24 cells from 4 isolations/mice; Mcufl/fl n = 24 cells from 4 isolations/mice. Data are plotted as mean ± SEM. *P ≤ 0.05 by 2-way ANOVA with Bonferroni’s post hoc test. Average peak data are shown in Supplemental Figure 1B. (E) Mitochondrial Ca2+ uptake from isolated muscle mitochondria of the genotypes shown measured using the Calcium Green-5N uptake assay. Calcium Green-5N signal was a ratio to baseline fluorescence values (F/F0). Mitochondria were challenged with 10 μM CaCl2 (red arrows). (F) Body weights of mice (g) from the indicated groups at 2 and 4 months of age. For animals at 2 months of age, n = 3 (MyoD-Cre), n = 5 (Mcufl/fl), and n = 5 (Mcufl/fl-MyoD-Cre). For animals at 4 months of age, n = 3 (MyoD-Cre), n = 5 (Mcufl/fl), and n = 8 (Mcufl/fl-MyoD-Cre). One-way ANOVA with Dunnett’s multiple comparisons test was used for statistical analysis. (G) Muscle weight normalized to tibia length (MW/TL) at 4 months of age. Muscles analyzed are shown, and heart weight was normalized to tibia length; n = 5 (MyoD-Cre), n = 8 (Mcufl/fl), and n = 8 (Mcufl/fl-MyoD-Cre). One-way ANOVA with Dunnett’s test was used for statistical analysis. (H) Quantification of myofiber cross-sectional area from 4-month-old animals from the indicated genotypes; n = 3 per group; Student’s 2-tailed t-test was used to analyze groups. (I) Transverse H&E-stained quadriceps histological sections from 4-month-old mice. (J) Representative electron micrographs of quadriceps sections at ×4,000 magnification. Scatter plots show individual values and mean ± SEM.