Myc controls transcriptional regulation of cardiac metabolism and mitochondrial biogenesis in response to pathological stress in mice
Preeti Ahuja, … , Michael Portman, W. Robb MacLellan
Preeti Ahuja, … , Michael Portman, W. Robb MacLellan
Published April 1, 2010
Citation Information: J Clin Invest. 2010;120(5):1494-1505. https://doi.org/10.1172/JCI38331.
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Research Article Cardiology

Myc controls transcriptional regulation of cardiac metabolism and mitochondrial biogenesis in response to pathological stress in mice

Abstract

In the adult heart, regulation of fatty acid oxidation and mitochondrial genes is controlled by the PPARγ coactivator–1 (PGC-1) family of transcriptional coactivators. However, in response to pathological stressors such as hemodynamic load or ischemia, cardiac myocytes downregulate PGC-1 activity and fatty acid oxidation genes in preference for glucose metabolism pathways. Interestingly, despite the reduced PGC-1 activity, these pathological stressors are associated with mitochondrial biogenesis, at least initially. The transcription factors that regulate these changes in the setting of reduced PGC-1 are unknown, but Myc can regulate glucose metabolism and mitochondrial biogenesis during cell proliferation and tumorigenesis in cancer cells. Here we have demonstrated that Myc activation in the myocardium of adult mice increases glucose uptake and utilization, downregulates fatty acid oxidation by reducing PGC-1α levels, and induces mitochondrial biogenesis. Inactivation of Myc in the adult myocardium attenuated hypertrophic growth and decreased the expression of glycolytic and mitochondrial biogenesis genes in response to hemodynamic load. Surprisingly, the Myc-orchestrated metabolic alterations were associated with preserved cardiac function and improved recovery from ischemia. Our data suggest that Myc directly regulates glucose metabolism and mitochondrial biogenesis in cardiac myocytes and is an important regulator of energy metabolism in the heart in response to pathologic stress.

Authors

Preeti Ahuja, Peng Zhao, Ekaterini Angelis, Hongmei Ruan, Paavo Korge, Aaron Olson, Yibin Wang, Eunsook S. Jin, F. Mark Jeffrey, Michael Portman, W. Robb MacLellan

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Figure 7

Myc directly regulates genes involved in mitochondrial replication and biogenesis.

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Myc directly regulates genes involved in mitochondrial replication and b...
(A) RT-PCR analysis performed for TFAM, POLG, POLG2, TOM20, and TOM70 on total RNA prepared from ventricular tissue from NTg and MycER mice with or without 4-OHT treatment. β-Actin was used as a loading control. (B) Myc binds to the TFAM, POLG, and POLG2 promoters in situ. ChIP analysis was performed with anti-Myc antibody and PCR primers to the TFAM, POLG, and POLG2 promoters. Ventricular tissue obtained from MycER mice 24 hours after vehicle or 4-OHT treatment was analyzed. Input lanes show PCR product derived from chromatin before immunoprecipitation to verify equal loading. (C and D) Endogenous Myc binds to the TFAM promoter in response to pathologic stress. Ventricular tissue obtained from wild-type mice subjected to sham operation or TAC (1 day) and after I/R injury (30 minutes of ischemia and 24 hours of reperfusion) were analyzed with anti-Myc antibody and PCR primers to the TFAM promoter. Input lanes show PCR product derived from chromatin before immunoprecipitation to verify equal loading. (E) Myc-null mice demonstrate attenuated stress-induced increase in mitochondrial replication and biogenesis genes. Total ventricular RNA from MCM;Mycfl/fl mice with or without 4-OHT treatment subjected to sham or TAC operation was assayed using quantitative real-time PCR for TFAM, POLG, and POLG2 (n = 3/group). *P < 0.05, **P < 0.001 for vehicle- versus 4-OHT–treated MCM;Mycfl/fl mice after TAC operation.