Regulation of myocardial substrate metabolism during increased energy expenditure: insights from computational studies.

In response to exercise, the heart increases its metabolic rate severalfold while maintaining energy species (e.g., ATP, ADP, and Pi) concentrations constant; however, the mechanisms that regulate this response are unclear. Limited experimental studies show that the classic regulatory species NADH and NAD+ are also maintained nearly constant with increased cardiac power generation, but current measurements lump the cytosol and mitochondria and do not provide dynamic information during the early phase of the transition from low to high work states. In the present study, we modified our previously published computational model of cardiac metabolism by incorporating parallel activation of ATP hydrolysis, glycolysis, mitochondrial dehydrogenases, the electron transport chain, and oxidative phosphorylation, and simulated the metabolic responses of the heart to an abrupt increase in energy expenditure. Model simulations showed that myocardial oxygen consumption, pyruvate oxidation, fatty acids oxidation, and ATP generation were all increased with increased energy expenditure, whereas ATP and ADP remained constant. Both cytosolic and mitochondrial NADH/NAD+ increased during the first minutes (by 40% and 20%, respectively) and returned to the resting values by 10-15 min. Furthermore, model simulations showed that an altered substrate selection, induced by either elevated arterial lactate or diabetic conditions, affected cytosolic NADH/NAD+ but had minimal effects on the mitochondrial NADH/NAD+, myocardial oxygen consumption, or ATP production. In conclusion, these results support the concept of parallel activation of metabolic processes generating reducing equivalents during an abrupt increase in cardiac energy expenditure and suggest there is a transient increase in the mitochondrial NADH/NAD+ ratio that is independent of substrate supply.

[1]  H. Taegtmeyer,et al.  Regulation of Energy Metabolism of the Heart during Acute Increase in Heart Work* , 1998, The Journal of Biological Chemistry.

[2]  R. Balaban,et al.  Effects of afterload and heart rate on NAD(P)H redox state in the isolated rabbit heart. , 1993, The American journal of physiology.

[3]  M. Chandler,et al.  Regulation of pyruvate dehydrogenase activity and citric acid cycle intermediates during high cardiac power generation , 2005, The Journal of physiology.

[4]  A. Bonen,et al.  Preferential inhibition of lactate oxidation relative to glucose oxidation in the rat heart following diabetes. , 1999, Cardiovascular research.

[5]  Satoshi Matsuoka,et al.  Regulation of oxidative phosphorylation in intact mammalian heart in vivo. , 2005, Biophysical chemistry.

[6]  J. Mccormack,et al.  Regulation of energy substrate metabolism in the diabetic heart. , 1997, Cardiovascular research.

[7]  R S Balaban,et al.  Relation between work and phosphate metabolite in the in vivo paced mammalian heart. , 1986, Science.

[8]  G. Salama,et al.  Effects of cardiac work on electrical potential gradient across mitochondrial membrane in perfused rat hearts. , 1993, The American journal of physiology.

[9]  William C Stanley,et al.  Myocardial substrate metabolism in the normal and failing heart. , 2005, Physiological reviews.

[10]  B Korzeniewski,et al.  Regulation of ATP supply in mammalian skeletal muscle during resting state-->intensive work transition. , 2000, Biophysical chemistry.

[11]  A. L. Kerbey,et al.  Diabetes and the control of pyruvate dehydrogenase in rat heart mitochondria by concentration ratios of adenosine triphosphate/adenosine diphosphate, of reduced/oxidized nicotinamide-adenine dinucleotide and of acetyl-coenzyme A/coenzyme A. , 1977, The Biochemical journal.

[12]  P. J. Randle,et al.  Regulation of Glucose Uptake by Muscle , 1962 .

[13]  R. Balaban,et al.  Simulation of cardiac work transitions, in vitro: effects of simultaneous Ca2+ and ATPase additions on isolated porcine heart mitochondria. , 2001, Cell calcium.

[14]  B. Korzeniewski Regulation of oxidative phosphorylation in different muscles and various experimental conditions. , 2003, The Biochemical journal.

[15]  Niels van Haarlem There is work to be done , 2002 .

[16]  W. Stanley,et al.  Myocardial lactate metabolism during exercise. , 1991, Medicine and science in sports and exercise.

[17]  Control of Mitochondrial Respiration in the Heart In Vivo , 1990 .

[18]  P. J. Randle Fuel selection in animals. , 1986, Biochemical Society transactions.

[19]  E. C. Slater THE RESPIRATORY CHAIN AND OXIDATIVE PHOSPHORYLATION , 1972 .

[20]  E. Newsholme,et al.  Regulation of glucose uptake by muscle. 7. Effects of fatty acids, ketone bodies and pyruvate, and of alloxan-diabetes, starvation, hypophysectomy and adrenalectomy, on the concentrations of hexose phosphates, nucleotides and inorganic phosphate in perfused rat heart. , 1964, The Biochemical journal.

[21]  T. Scholz,et al.  Mitochondrial F1-ATPase activity of canine myocardium: effects of hypoxia and stimulation. , 1994, The American journal of physiology.

[22]  V. Mootha,et al.  Ca2+ activation of heart mitochondrial oxidative phosphorylation: role of the F0/F1-ATPase , 2000 .

[23]  W. Stanley,et al.  Myocardial interstitial purine metabolites and lactate with increased work in swine. , 1995, Cardiovascular research.

[24]  J. Spitzer Effect of lactate infusion on canine myocardial free fatty acid metabolism in vivo. , 1974, The American journal of physiology.

[25]  G. Saidel,et al.  Regulation of Cardiac Energetics: Role of Redox State and Cellular Compartmentation during Ischemia , 2005, Annals of the New York Academy of Sciences.

[26]  M. Chandler,et al.  Regulation of cardiac malonyl-CoA content and fatty acid oxidation during increased cardiac power. , 2005, American journal of physiology. Heart and circulatory physiology.

[27]  F. Cerny,et al.  Studies on the regulation of myocardial blood flow in man , 1976, Basic Research in Cardiology.

[28]  J. Mccormack,et al.  Impaired pyruvate oxidation but normal glucose uptake in diabetic pig heart during dobutamine-induced work. , 1996, The American journal of physiology.

[29]  A. Avogaro,et al.  Myocardial Metabolism in Type 1 Diabetic Patients Without Coronary Artery Disease , 1991, Diabetic medicine : a journal of the British Diabetic Association.

[30]  Lufang Zhou,et al.  Regulation of lactate production at the onset of ischaemia is independent of mitochondrial NADH/NAD+: insights from in silico studies , 2005, The Journal of physiology.

[31]  I. Fearnley,et al.  The Phosphorylation of Subunits of Complex I from Bovine Heart Mitochondria* , 2004, Journal of Biological Chemistry.

[32]  J. Brosnan,et al.  Competition between fatty acids and carbohydrate or ketone bodies as metabolic fuels for the isolated perfused heart. , 1987, Canadian journal of physiology and pharmacology.

[33]  C Cobelli,et al.  Myocardial metabolism in insulin-deficient diabetic humans without coronary artery disease. , 1990, The American journal of physiology.

[34]  G A Brooks,et al.  Systemic lactate kinetics during graded exercise in man. , 1985, The American journal of physiology.

[35]  M. Weiner,et al.  Myocardial metabolism during increased work states in the porcine left ventricle in vivo. , 1994, Circulation research.

[36]  D. E. Gregg,et al.  Effect of Exercise on Cardiac Output, Left Coronary Flow and Myocardial Metabolism in the Unanesthetized Dog , 1965, Circulation research.

[37]  Daniel A. Beard,et al.  A Biophysical Model of the Mitochondrial Respiratory System and Oxidative Phosphorylation , 2005, PLoS Comput. Biol..

[38]  J. Wisneski,et al.  Myocardial substrate utilization during exercise in humans. Dual carbon-labeled carbohydrate isotope experiments. , 1988, The Journal of clinical investigation.

[39]  R. Winslow,et al.  An integrated model of cardiac mitochondrial energy metabolism and calcium dynamics. , 2003, Biophysical journal.

[40]  R. Bünger,et al.  Energy utilization and pyruvate as determinants of pyruvate dehydrogenase in norepinephrine-stimulated heart , 1983, Pflügers Archiv.

[41]  Lufang Zhou,et al.  Mechanistic model of cardiac energy metabolism predicts localization of glycolysis to cytosolic subdomain during ischemia. , 2005, American journal of physiology. Heart and circulatory physiology.

[42]  J. Mccormack,et al.  Role of calcium ions in regulation of mammalian intramitochondrial metabolism. , 1990, Physiological reviews.

[43]  R. Balaban,et al.  Metabolic Network Control of Oxidative Phosphorylation , 2003, Journal of Biological Chemistry.

[44]  G. Lopaschuk,et al.  beta-Hydroxybutyrate inhibits myocardial fatty acid oxidation in vivo independent of changes in malonyl-CoA content. , 2003, American journal of physiology. Heart and circulatory physiology.

[45]  R. Balaban,et al.  Role of calcium in metabolic signaling between cardiac sarcoplasmic reticulum and mitochondria in vitro. , 2003, American journal of physiology. Cell physiology.

[46]  G. Lopaschuk,et al.  Epinephrine increases ATP production in hearts by preferentially increasing glucose metabolism. , 1994, The American journal of physiology.

[47]  R S Balaban,et al.  Regulation of oxidative phosphorylation in the mammalian cell. , 1990, The American journal of physiology.