Control of mitochondrial metabolism and systemic energy homeostasis by microRNAs 378 and 378*

Obesity and metabolic syndrome are associated with mitochondrial dysfunction and deranged regulation of metabolic genes. Peroxisome proliferator-activated receptor γ coactivator 1β (PGC-1β) is a transcriptional coactivator that regulates metabolism and mitochondrial biogenesis through stimulation of nuclear hormone receptors and other transcription factors. We report that the PGC-1β gene encodes two microRNAs (miRNAs), miR-378 and miR-378*, which counterbalance the metabolic actions of PGC-1β. Mice genetically lacking miR-378 and miR-378* are resistant to high-fat diet-induced obesity and exhibit enhanced mitochondrial fatty acid metabolism and elevated oxidative capacity of insulin-target tissues. Among the many targets of these miRNAs, carnitine O-acetyltransferase, a mitochondrial enzyme involved in fatty acid metabolism, and MED13, a component of the Mediator complex that controls nuclear hormone receptor activity, are repressed by miR-378 and miR-378*, respectively, and are elevated in the livers of miR-378/378* KO mice. Consistent with these targets as contributors to the metabolic actions of miR-378 and miR-378*, previous studies have implicated carnitine O-acetyltransferase and MED13 in metabolic syndrome and obesity. Our findings identify miR-378 and miR-378* as integral components of a regulatory circuit that functions under conditions of metabolic stress to control systemic energy homeostasis and the overall oxidative capacity of insulin target tissues. Thus, these miRNAs provide potential targets for pharmacologic intervention in obesity and metabolic syndrome.

[1]  Chi V Dang,et al.  Links between metabolism and cancer. , 2012, Genes & development.

[2]  Chad E. Grueter,et al.  A Cardiac MicroRNA Governs Systemic Energy Homeostasis by Regulation of MED13 , 2012, Cell.

[3]  A. Näär,et al.  MicroRNAs in metabolism and metabolic disorders , 2012, Nature Reviews Molecular Cell Biology.

[4]  J. Mendell,et al.  MicroRNAs in Stress Signaling and Human Disease , 2012, Cell.

[5]  I. Knezevic,et al.  A Novel Cardiomyocyte-enriched MicroRNA, miR-378, Targets Insulin-like Growth Factor 1 Receptor , 2012, The Journal of Biological Chemistry.

[6]  C. Carlberg,et al.  Dataset integration identifies transcriptional regulation of microRNA genes by PPARγ in differentiating mouse 3T3-L1 adipocytes , 2012, Nucleic acids research.

[7]  U. Fischer,et al.  Intronic miR-26b controls neuronal differentiation by repressing its host transcript, ctdsp2. , 2012, Genes & development.

[8]  E. Olson,et al.  Control of glucose homeostasis and insulin sensitivity by the Let-7 family of microRNAs , 2011, Proceedings of the National Academy of Sciences.

[9]  Ayellet V. Segrè,et al.  The Lin28/let-7 Axis Regulates Glucose Metabolism , 2011, Cell.

[10]  A. Näär,et al.  MiRs with a sweet tooth. , 2011, Cell metabolism.

[11]  M. Zavolan,et al.  MicroRNAs 103 and 107 regulate insulin sensitivity , 2011, Nature.

[12]  Ryan M. Layer,et al.  MicroRNA-378 Targets the Myogenic Repressor MyoR during Myoblast Differentiation* , 2011, The Journal of Biological Chemistry.

[13]  Ali Nahvi,et al.  A Parsimonious Model for Gene Regulation by miRNAs , 2011, Science.

[14]  E. Olson,et al.  Pervasive roles of microRNAs in cardiovascular biology , 2011, Nature.

[15]  S. Young,et al.  Heart-type Fatty Acid-binding Protein Is Essential for Efficient Brown Adipose Tissue Fatty Acid Oxidation and Cold Tolerance* , 2010, The Journal of Biological Chemistry.

[16]  Sohail Malik,et al.  The metazoan Mediator co-activator complex as an integrative hub for transcriptional regulation , 2010, Nature Reviews Genetics.

[17]  P. Sharp,et al.  MicroRNA functions in stress responses. , 2010, Molecular cell.

[18]  Nicholas Bertos,et al.  miR-378(∗) mediates metabolic shift in breast cancer cells via the PGC-1β/ERRγ transcriptional pathway. , 2010, Cell metabolism.

[19]  Christopher J Lynch,et al.  Cardiolipin remodeling by ALCAT1 links oxidative stress and mitochondrial dysfunction to obesity. , 2010, Cell metabolism.

[20]  I. Gérin,et al.  Roles for miRNA-378/378* in adipocyte gene expression and lipogenesis. , 2010, American journal of physiology. Endocrinology and metabolism.

[21]  T. Shioda,et al.  MicroRNA-33 and the SREBP Host Genes Cooperate to Control Cholesterol Homeostasis , 2010, Science.

[22]  J. Eubanks,et al.  Fate , 2010, Annals of Internal Medicine.

[23]  L. Heilbronn,et al.  Toll-like receptor 4 modulates skeletal muscle substrate metabolism. , 2010, American journal of physiology. Endocrinology and metabolism.

[24]  E. Olson,et al.  Redundant Control of Adipogenesis by Histone Deacetylases 1 and 2* , 2010, The Journal of Biological Chemistry.

[25]  Karin Aumayr,et al.  Drosophila Genome-wide Obesity Screen Reveals Hedgehog as a Determinant of Brown versus White Adipose Cell Fate , 2010, Cell.

[26]  C. Folmes,et al.  Myocardial fatty acid metabolism in health and disease. , 2010, Physiological reviews.

[27]  E. Olson,et al.  A family of microRNAs encoded by myosin genes governs myosin expression and muscle performance. , 2009, Developmental cell.

[28]  O. Ilkayeva,et al.  Carnitine Insufficiency Caused by Aging and Overnutrition Compromises Mitochondrial Performance and Metabolic Control* , 2009, The Journal of Biological Chemistry.

[29]  P. Neufer,et al.  Mitochondrial H2O2 emission and cellular redox state link excess fat intake to insulin resistance in both rodents and humans. , 2009, The Journal of clinical investigation.

[30]  Jeffrey E. Thatcher,et al.  Dysregulation of microRNAs after myocardial infarction reveals a role of miR-29 in cardiac fibrosis , 2008, Proceedings of the National Academy of Sciences.

[31]  John McAnally,et al.  The endothelial-specific microRNA miR-126 governs vascular integrity and angiogenesis. , 2008, Developmental cell.

[32]  S. Sookoian,et al.  A Decreased Mitochondrial DNA Content Is Related to Insulin Resistance in Adolescents , 2008, Obesity.

[33]  B. Morio,et al.  Mitochondrial dysfunction results from oxidative stress in the skeletal muscle of diet-induced insulin-resistant mice. , 2008, The Journal of clinical investigation.

[34]  W. Filipowicz,et al.  Mechanisms of post-transcriptional regulation by microRNAs: are the answers in sight? , 2008, Nature Reviews Genetics.

[35]  R. Heine,et al.  Fatty acid-induced mitochondrial uncoupling in adipocytes as a key protective factor against insulin resistance and beta cell dysfunction: a new concept in the pathogenesis of obesity-associated type 2 diabetes mellitus , 2007, Diabetologia.

[36]  R. Evans,et al.  PGC-1β controls mitochondrial metabolism to modulate circadian activity, adaptive thermogenesis, and hepatic steatosis , 2007, Proceedings of the National Academy of Sciences.

[37]  L. Scorrano,et al.  Organelle isolation: functional mitochondria from mouse liver, muscle and cultured filroblasts , 2007, Nature Protocols.

[38]  D. Moller,et al.  Modulation of fatty acid metabolism as a potential approach to the treatment of obesity and the metabolic syndrome , 2006, Endocrine.

[39]  Jiandie D. Lin,et al.  Hypomorphic mutation of PGC-1beta causes mitochondrial dysfunction and liver insulin resistance. , 2006, Cell metabolism.

[40]  Barbara Cannon,et al.  Ablation of PGC-1β Results in Defective Mitochondrial Activity, Thermogenesis, Hepatic Function, and Cardiac Performance , 2006, PLoS biology.

[41]  B. Spiegelman,et al.  Peroxisome proliferator-activated receptor gamma coactivator 1 coactivators, energy homeostasis, and metabolism. , 2006, Endocrine reviews.

[42]  D. Kelly,et al.  PGC-1 coactivators: inducible regulators of energy metabolism in health and disease. , 2006, The Journal of clinical investigation.

[43]  E. Hoffman,et al.  Elevated stearoyl-CoA desaturase-1 expression in skeletal muscle contributes to abnormal fatty acid partitioning in obese humans. , 2005, Cell metabolism.

[44]  Ping Li,et al.  Peroxisome Proliferator-activated Receptor-γ Co-activator 1α-mediated Metabolic Remodeling of Skeletal Myocytes Mimics Exercise Training and Reverses Lipid-induced Mitochondrial Inefficiency* , 2005, Journal of Biological Chemistry.

[45]  R. Roeder,et al.  Structural and Functional Organization of TRAP220, the TRAP/Mediator Subunit That Is Targeted by Nuclear Receptors , 2004, Molecular and Cellular Biology.

[46]  Antonio G. Cordente,et al.  Redesign of Carnitine Acetyltransferase Specificity by Protein Engineering* , 2004, Journal of Biological Chemistry.

[47]  D. Bartel MicroRNAs Genomics, Biogenesis, Mechanism, and Function , 2004, Cell.

[48]  Qianben Wang,et al.  A Coregulatory Role for the TRAP-Mediator Complex in Androgen Receptor-mediated Gene Expression* , 2002, The Journal of Biological Chemistry.

[49]  B. Spiegelman,et al.  Transcription coactivator TRAP220 is required for PPARγ2-stimulated adipogenesis , 2002, Nature.

[50]  N. Alpert,et al.  Coupling of mitochondrial fatty acid uptake to oxidative flux in the intact heart. , 2002, Biophysical journal.

[51]  B. Spiegelman,et al.  Transcription coactivator TRAP220 is required for PPAR gamma 2-stimulated adipogenesis. , 2002, Nature.

[52]  R. Roeder,et al.  The TRAP/SMCC/Mediator complex and thyroid hormone receptor function , 2001, Trends in Endocrinology & Metabolism.

[53]  H. Esterbauer,et al.  Human peroxisome proliferator activated receptor gamma coactivator 1 (PPARGC1) gene: cDNA sequence, genomic organization, chromosomal localization, and tissue expression. , 1999, Genomics.