Metabolic Mechanisms Associated With Antianginal Therapy
2000; Lippincott Williams & Wilkins; Volume: 86; Issue: 5 Linguagem: Inglês
10.1161/01.res.86.5.487
ISSN1524-4571
Autores Tópico(s)Mitochondrial Function and Pathology
ResumoHomeCirculation ResearchVol. 86, No. 5Metabolic Mechanisms Associated With Antianginal Therapy Free AccessEditorialPDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessEditorialPDF/EPUBMetabolic Mechanisms Associated With Antianginal Therapy E. Douglas Lewandowski E. Douglas LewandowskiE. Douglas Lewandowski From the Metabolic Research Laboratory, Department of Radiology, Massachusetts General Hospital and Harvard Medical School, Boston, Mass. Originally published17 Mar 2000https://doi.org/10.1161/01.RES.86.5.487Circulation Research. 2000;86:487–489Laboratory investigations into preserving viability of the ischemic myocardium or to promote recovery during reperfusion have often focused on the intermediary pathways of energy metabolism. However, in the clinical treatment of angina, the application of metabolic therapies has generally lagged behind or has been incidental to other approaches, such as a vasodilators, calcium antagonists, and negative inotropes. A study published in this issue of Circulation Research has demonstrated that the antianginal agent trimetazidine (1-[2,3,4-trimethoxybenzyl] piperazine dihydrochloride [TMZ]) inhibits the activity of one of the enzymes of the β-oxidation pathway in cardiac mitochondria with direct increases in glucose oxidation.1 These findings confirm in an intact, functioning heart model the well-documented, anti-ischemic properties of TMZ234 and the inhibitory effects of TMZ on long-chain fatty acid oxidation5 with reciprocal enhancement of glucose uptake.6 The study localizes the inhibition of β-oxidation to a specific enzyme, the mitochondrial long-chain 3-ketoacyl coenzyme A (CoA) thiolase. The suggestion by the authors is that the effectiveness of TMZ as an antianginal agent is directly linked to this inhibitory effect on long-chain fatty acid oxidation.Although studies on the isolated heart preparation can neither specifically nor conclusively identify an antianginal mechanism, the findings of the University of Alberta group1 are consistent with the known effectiveness of TMZ as an antianginal agent789 that reduces long-chain fatty acid oxidation, while lacking both vasodilator activity and negative inotropic effects.9 The inhibitory effects of TMZ on long-chain fatty acid transport into rat heart mitochondria, via inhibition of carnitine palmitoyltransferase 1 (CPT 1) enzyme, have already been demonstrated, but TMZ was also found to be much less potent than two other proven antianginal drugs, perhexiline and amiodarone.510 However, TMZ does not induce the confounding vasoactive, inotropic and chronotropic responses of these other agents. Thus, the data suggesting that TMZ inhibits the long-chain 3-ketoactyl CoA thiolase, downstream from CPT 1, add to the argument for a purely metabolic mechanism of antianginal therapy. The implied effectiveness of pharmacological changes in the oxidative pathways of mitochondria in treating stable angina warrants a heightened awareness of metabolic enzyme activity and mitochondrial function as targets for clinical therapeutics.Shifting the Balance of Fuels for Energy ProductionThe ischemic and reperfused myocardium benefits from a shift away from fatty acid oxidation to that of carbohydrates.111213 The ability of anaerobic glycolysis to support the ischemic myocardium is well established,14 but the benefits of glucose oxidation over that of fatty acid oxidation in the flow-limited myocardium are only now being realized.1 A shift toward glucose oxidation, which is a more efficient mode of ATP production per mole of oxygen used, is likely to benefit hypoperfused myocardium.An agent that promotes carbohydrate oxidation via activation of pyruvate dehydrogenase (PDH), dichloroacetate, has improved left ventricular function in patients with coronary artery disease.15 Other agents, such as oxfenecine, etomoxir, and methylplamoxirate inhibit the oxidation of fatty acids. Among the inhibitors of long-chain fatty acid oxidation, TMZ and ranolazine, both have antianginal effects. Despite a growing body of evidence that enhancing carbohydrate oxidation, but not necessarily glycolysis, and reducing fatty acid oxidation are beneficial to the ischemic and reperfused heart, clinical studies of such metabolic protocols remain limited.Noting the paucity of clinical data on metabolic support strategies is not to imply that the notion has not been a longstanding consideration. The use of glucose-insulin-potassium (GIK) solution as an adjunctive therapy for acute myocardial infarction is one of the first examples of an approach to intervene on cardiac substrate utilization.16 The bottom line to this approach is to maintain high-energy phosphate stores in ischemic myocardium. However, even on revascularization and the restoration of cellular energy charge, the postischemic heart remains abnormal and benefits from additional metabolic interventions that are shown experimentally to counter myocardial stunning. Thus, the observed changes in fatty acid and carbohydrate oxidation induced by TMZ, and related antianginal compounds, aid recovery during myocardial reperfusion.Mechanisms of Substrate UtilizationThe effectiveness of direct strategies to shift the balance from fatty acid oxidation toward glucose oxidation in the reperfused myocardium now appears to be linked to both the recovery of intracellular pH and the cytosolic redox state of the myocytes.1117 These two factors, pH and redox state, are linked to proton production due to the counterbalance between coupling of glycolysis to the oxidation rate of glycolytic end products and the production and oxidation of lactate.111718 However, beneficial effects of a more carbohydrate-based, oxidative energy metabolism are not uniquely dependent on glycolytic flux. Indeed, improved contractile recovery during reperfusion is more associated with the stimulation of pyruvate oxidation, as opposed to the nonoxidative metabolism of glycolytic end products that forms alanine and lactate in the cytosol.19 This balance between oxidative and nonoxidative pyruvate metabolism is central to the recovery of pH and cytosolic redox state that are both associated with postischemic contractile function.Regulating the balance between the oxidation of fatty acids and pyruvate is the enzyme complex PDH. During early reperfusion, PDH is primarily in the inactive, phosphorylated state.20 Activating PDH is effective in improving the recovery of reperfused myocardium.11171921 However, such protocols on animal models have not proven effective during conditions of low-flow ischemia,22 when PDH remains in the active form.The activity of PDH is also influenced by fatty acid oxidation rates. Thus, reductions in fatty acid oxidation, such as those produced by TMZ, increase the fraction of active PDH to produce an increase in carbohydrate oxidation. On the reciprocal end, when PDH activity is stimulated, as with inhibitors of PDH kinase, fatty acid oxidation becomes reduced.Other mechanisms for reducing fatty acid oxidation hold potential for therapeutic use. A strong influence on the reduction in fatty acid oxidation is the inhibitory effect of malonyl CoA on CPT 1.23 Malonyl CoA is produced in the cytosol from the action of the enzyme acetyl CoA carboxylase on acetyl CoA. Thus, increased production of acetyl CoA has the effect of reducing long-chain fatty acid oxidation. Different isoform distributions of CPT 1 have the potential to mediate its responsiveness to malonyl CoA, in particular during pathophysiological changes.24 However, at different fatty acid oxidation rates in the heart, changes in CPT 1 activity have not yet been noted in the absence of a change in malonyl CoA level. This finding suggests that the modulation of CPT 1 responsiveness to malonyl CoA is not a strong regulatory factor in the normal myocyte.13 Thus, beyond pharmacological strategies, it remains to be seen whether differential expression of enzyme isoforms will prove effective in inducing similar therapeutic changes in cardiac metabolism.Ischemic Stress and Protein ActivationCan the activity of one single enzyme, or the flux rate through one specific metabolic pathway be responsible for angina? Such an overly simplified scenario is unlikely the case, but the necessity of minimizing confounding variables in an experimental protocol may suggest such oversimplification. On the other hand, a less direct, but intriguing, notion is to target stress-activated proteins. The increased production and activation of enzymes that respond to pathophysiology can trigger a cascade of events, including metabolic changes that influence cell function and viability (Figure).Such an example is the activation of stress proteins during ischemia, which leads to changes in glucose uptake and fatty acid oxidation. As a specific example, the glucose transporters GLUT-4 and GLUT-1 are translocated from the intracellular membranes to the sarcolemma in response to the low-energy, state-linked activation of 5′ AMP-activated protein kinase (AMPK) in the ischemic heart.2526 Interestingly, the activity of AMPK also inactivates acetyl CoA carboxylase, with the net result of decreasing malonyl CoA levels.27 Thus, other regulating factors upstream from the enzymes of the metabolic pathways are potential targets for therapeutic approaches to improving the energy balance of the ischemic myocardium.The efficacy of antianginal drugs, such as TMZ, that invoke a direct metabolic effect underscores the need for further elucidation of metabolic regulatory mechanisms that influence myocyte function and viability. Many of these mechanisms can be induced by protein production responses to ischemic stress, which is, in part, the product of impaired energy metabolism. Thus, we come full circle in the intervention of cardiac metabolism in ischemic and reperfused myocardium. The challenge then is to detect these metabolic changes in the functioning organ, where the physiological consequences can be elucidated.The opinions expressed in this editorial are not necessarily those of the editors or of the American Heart Association.Download figureDownload PowerPoint Figure 1. Schematic of regulatory pathways as metabolic targets for drug action. Solid lines are metabolic pathways. Dashed lines are regulatory effects, with − for inhibition and + for stimulation. TMZ indicates trimetazidine (1-[2,3,4-trimethoxybenzyl] piperazine dihydrochloride); DCA, dichloroacetate; LCFA, long-chain fatty acid; ACC, acetyl CoA carboxylase; AMPK, 5′ AMP-activated protein kinase; PDH, pyruvate dehydrogenase; PDHK, pyruvate dehydrogenase kinase; CPT 1, carnitine palmitoyltransferase 1; and GLUT, glucose transporter.FootnotesCorrespondence to E. Douglas Lewandowski, PhD, Department of Radiology, Room 2301, Massachusetts General Hospital, Bldg 149, 13th St, Charlestown, MA 02129. E-mail [email protected] References 1 Kantor PF, Lucien A, Kozak R, Lopaschuk GD. The antianginal drug trimetazidine shifts cardiac energy metabolism from fatty acid oxidation to glucose oxidation by inhibiting mitochondrial long-chain 3-ketoacyl coenzyme A thiolase. Circ Res.2000; 86:580–588.CrossrefMedlineGoogle Scholar2 Lavanchy N, Martin J, Rossi A. Anti-ischemic effects of trimetazidine: 31P-NMR spectroscopy in the isolated rat heat. Arch Int Pharmacodyn Ther.1987; 286:97–110.MedlineGoogle Scholar3 Opie LH, Boucher F. Trimetazidine and myocardial ischemic contracture in isolated rat heart. Am J Cardiol.1995; 75:38B–40B.Google Scholar4 Veitch K, Maisin L, Hue L. Trimetazidine effects on the damage to mitochondrial functions caused by ischemia and reperfusion. Am J Cardiol.1995; 76:25B–30B.CrossrefMedlineGoogle Scholar5 Kennedy JA, Horowitz JD. 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Biochim Biophys Acta.1996; 1301:67–75.CrossrefMedlineGoogle Scholar Previous Back to top Next FiguresReferencesRelatedDetailsCited By Kudej R, Fasano M, Zhao X, Lopaschuk G, Fischer S, Vatner D, Vatner S and Lewandowski E (2011) Second window of preconditioning normalizes palmitate use for oxidation and improves function during low-flow ischaemia, Cardiovascular Research, 10.1093/cvr/cvr215, 92:3, (394-400), Online publication date: 1-Dec-2011. Tritto I, Wang P, Kuppusamy P, Giraldez R, Zweier J and Ambrosio G (2005) The Anti-Anginal Drug Trimetazidine Reduces Neutrophil-Mediated Cardiac Reperfusion Injury, Journal of Cardiovascular Pharmacology, 10.1097/01.fjc.0000164091.81198.a3, 46:1, (89-98), Online publication date: 1-Jul-2005. Stanley W, Recchia F and Lopaschuk G (2005) Myocardial Substrate Metabolism in the Normal and Failing Heart, Physiological Reviews, 10.1152/physrev.00006.2004, 85:3, (1093-1129), Online publication date: 1-Jul-2005. 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Masuda Y (2001) Suppression of the Cardiac Performance during Recovery after Strenuous Sympathetic Nerve Activity, Journal of Cardiovascular Pharmacology, 10.1097/00005344-200110001-00008, 38, (S33-S38), Online publication date: 1-Oct-2001. Stanley W (2000) In vivo models of myocardial metabolism during ischemia, Journal of Pharmacological and Toxicological Methods, 10.1016/S1056-8719(00)00097-6, 43:2, (133-140), Online publication date: 1-Mar-2000. March 17, 2000Vol 86, Issue 5 Advertisement Article InformationMetrics © 2000 American Heart Association, Inc.https://doi.org/10.1161/01.RES.86.5.487 Originally publishedMarch 17, 2000 Keywordsmyocardial ischemiametabolismfatty acidsmitochondriaglycolysisPDF download Advertisement
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