Carnitine Palmitoyltransferase-I,a New Target for the Treatment of Heart Failure

Although the heart is capable of extracting energy from different types of substrates such as fatty acids and carbohydrates, fatty acids are the preferred fuel under physiological conditions. In view of the presence of diverse defects in myocardial metabolism in the failing heart, changes in metabolism of glucose and fatty acids are considered as viable targets for therapeutic modification in the treatment of heart failure. One of these changes involves the carnitine palmitoyltransferase (CPT) enzymes, which are required for the transfer of long chain fatty acids into the mitochondrial matrix for oxidation. Since CPT inhibitors have been shown to prevent the undesirable effects induced by mechanical overload, e.g. cardiac hypertrophy and heart failure, it was considered of interest to examine whether the inhibition of CPT enzymes represents a novel approach for the treatment of heart disease. A shift from fatty acid metabolism to glucose metabolism due to CPT-I inhibition has been reported to exert beneficial effects in both cardiac hypertrophy and heart failure. Since the inhibition of fatty acid oxidation is effective in controlling abnormalities in diabetes mellitus, CPT-I inhibitors may also prove useful in the treatment of diabetic cardiomyopathy. Accordingly, it is suggested that CPT-I may be a potential target for drug development for the therapy of heart disease in general and heart failure in particular.     

The role of amino acids in the modulation of cardiac metabolism during ischemia and heart failure

During ischemia and heart failure, myocardial cells suffer for chronic energy starvation resulting in metabolic and contractile dysfunction. In normal conditions fatty acids, glucose, and lactate are the principal oxidative fuels in myocardium, while amino acids serve a minor role as an oxidative fuel. However, in pathological conditions, myocardial uptake of several amino acids increases significantly as a consequence of a metabolic remodelling. Amino acids are involved in a variety of key biochemical and physiological activities, that counteract the deleterious cellular effects of reduced oxygen availability. Several amino acids are a direct source of substrate for energy production, and they modulate the activity of some enzymes involved in the glucose metabolism. They increase contractile performance both in isolated animal and human myocardium. Furthermore, amino acids improve the oxidative stress counteracting the action of radical oxygen species, being either precursors of glutathione synthesis, or of substrate of nitric oxide biosynthesis; they act on endothelial function and increase protein synthetic efficiency of myocardial cells by regulating gene expression and modulating hormonal activity. An amount of studies have demonstrated that amino acids administration, on patients with ischemic heart disease and heart failure, can improve several clinical endpoints. Here, we present an overview of the principal effects of the most experienced amino acids and of amino acid derivatives on ischemia and heart failure.     

Mitochondrial fatty acid oxidation alterations in heart failure,ischaemic heart disease and diabetic cardiomyopathy

Heart disease is a leading cause of death worldwide. In many forms of heart disease, including heart failure, ischaemic heart disease and diabetic cardiomyopathies, changes in cardiac mitochondrial energy metabolism contribute to contractile dysfunction and to a decrease in cardiac efficiency. Specific metabolic changes include a relative increase in cardiac fatty acid oxidation rates and an uncoupling of glycolysis from glucose oxidation. In heart failure, overall mitochondrial oxidative metabolism can be impaired while, in ischaemic heart disease, energy production is impaired due to a limitation of oxygen supply. In both of these conditions, residual mitochondrial fatty acid oxidation dominates over mitochondrial glucose oxidation. In diabetes, the ratio of cardiac fatty acid oxidation to glucose oxidation also increases, although primarily due to an increase in fatty acid oxidation and an inhibition of glucose oxidation. Recent evidence suggests that therapeutically regulating cardiac energy metabolism by reducing fatty acid oxidation and/or increasing glucose oxidation can improve cardiac function of the ischaemic heart, the failing heart and in diabetic cardiomyopathies. In this article, we review the cardiac mitochondrial energy metabolic changes that occur in these forms of heart disease, what role alterations in mitochondrial fatty acid oxidation have in contributing to cardiac dysfunction and the potential for targeting fatty acid oxidation to treat these forms of heart disease.

LINKED ARTICLES

This article is part of a themed issue on Mitochondrial Pharmacology: Energy, Injury & Beyond. To view the other articles in this issue visit http://dx.doi.org/10.1111/bph.2014.171.issue-8     

Partial fatty acid oxidation inhibitors for stable angina

Partial fatty acid oxidation inhibition is effective therapy for the treatment of chronic stable angina and is particularly useful in patients with persistent angina despite optimal traditional therapy. The heart derives most of its energy from the oxidation of fatty acids. Fatty acid oxidation strongly inhibits pyruvate oxidation in the mitochondria and the uptake and oxidation of glucose. The primary effect of demand-induced ischaemia is impaired aerobic formation of ATP in the mitochondria, resulting in activation of non-oxidative glycolysis and lactate production, despite a relatively high residual myocardial oxygen consumption and continued reliance on fatty acid oxidation. Traditional drugs for chronic stable angina act by reducing the use of ATP through suppression of heart rate and blood pressure or by increasing aerobic formation of ATP by increasing coronary blood flow. Partial inhibition of fatty acid oxidation increases glucose and pyruvate oxidation and decreases lactate production, resulting in higher pH and improved contractile function during ischaemia. These agents do not affect heart rate, coronary blood flow or arterial blood pressure. Clinical trials with ranolazine or trimetazidine, either alone or in combination with a Ca2+ channel antagonist or a beta-adrenergic receptor antagonist, have demonstrated reduced symptoms of exercise-induced angina.     

Ranolazine, a partial fatty acid oxidation inhibitor, its potential benefit in angina and other cardiovascular disorders

Chronic Angina resistant to medical treatment with hemodynamically acting agents is a major problem in clinical setup. For such patients, large number of clinical trials have documented the beneficial effect of Ranolazine. It acts as an anti-anginal agent that controls myocardial ischemia through intracellular metabolic changes. Ranolazine is a partial fatty acid oxidation inhibitor which shifts cardiac energy metabolism from fatty acid oxidation to glucose oxidation. Since the oxidation of glucose requires less oxygen than the oxidation of fatty acids, ranolazine can help maintain myocardial function in times of ischemia. In addition, ranolazine has minimal effect on blood pressure and heart rate. Ranolazine, by inhibiting cellular ionic channels, prolongs the corrected QT interval. However, ranolazine has not yet been associated with any incidences of ventricular arrhythmia. Other possible mechanism by which Ranolazine could act is by reducing the formation of reactive oxygen species (ROS) and improves reperfusion mechanical function. Ranolazine has been approved by US FDA for the treatment of chronic angina pectoris in combination with amlodipine, beta-blockers or nitrates in patients who do not show adequate response to other anti-anginals. Ranolazine is a metabolic modulator that is being developed by CV Therapeutics (CVT), under license from Roche (formerly Syntex), as a potential treatment for angina. Ranolazine is available as brand name 'Ranexa' as extended release oral tablets. This review focuses on the clinical effects, the mechanism of actions, drug interactions and beneficial effects of Ranolazine in chronic angina and other cardiometabolic disorders.     

Efficacy of metabolic modulators in ischemic heart disease: an overview

Myocardial ischemia results in a decrease in oxygen supply to the heart, leading to cardiac dysfunction. Present therapeutic strategies for treating myocardial ischemia or infarction focus on maintaining coronary artery patency by either fibrinolysis or primary percutaneous intervention. Although these approaches have dramatically improved the prognosis in patients with angina pectoris and myocardial infarction, the complication of myocardial ischemia remains a major cause of mortality and morbidity worldwide. A novel approach that entails improving and optimizing cardiac energy metabolism of the ischemic myocardium by pharmacologically manipulating different metabolic pathways in the heart holds promise in limiting myocardial damage. Metabolic support of the ischemic myocardium is aimed at increasing glycolysis and residual oxidative phosphorylation of glucose along with decreasing fatty acid oxidation. This review discusses the various metabolic modulators, both conventional and new, along with documented evidence in both acute and chronic angina.     

Aldose reductase: a novel target for cardioprotective interventions

Recanalization therapy remains the most effective way for treatment of evolving myocardial infarction and thereby salvaging jeopardized tissue. However, the efficacy of reperfusion in limiting infarction and improving recovery of contractile function depends on the amount of irreversible damage occurring prior to initiating reperfusion and is related to failure of energy production to meet the basal needs of the injured myocardium. In recent years, a variety of metabolic therapies that enhance myocardial metabolism and attenuate changes in sodium and calcium homeostasis during ischemia have been proposed. They focus on (a) increasing myocardial glucose metabolism during ischemia or (b) inhibiting fatty acid metabolism to increase glucose use, and (c) inhibiting sodium and calcium influx pathways that deplete high energy phosphates. Recent studies from our laboratory showed that inhibition of aldose reductase, a key regulatory enzyme in the substrate flux via polyol pathway, reduces ischemic injury and improves functional and metabolic recovery after ischemia-reperfusion in hearts. These and subsequent studies have generated considerable interest in the use of aldose reductase inhibitors as potential therapeutic adjuncts in treating evolving myocardial infarction in patients. This review will discuss the mechanisms by which aldose reductase inhibitors protect ischemic myocardium and provide rationale for their use as cardioprotective drugs.     

Role of Metabolically Active Drugs in the Management of Ischemic Heart Disease

This article reviews the fundamentals of myocardial energy metabolism and selectively outlines the use of several metabolically active drug therapies in the treatment of ischemic heart disease. These drugs — ranolazine, trimetazidine, dichloroacetate (DCA), glucose-insulin-potassium (GIK) solutions, and L-carnitine — have mechanisms of action distinct from traditional anti-ischemic drugs. These agents work by shifting myocardial energy metabolism away from fatty acids toward glucose as a source of fuel. Because these agents are well tolerated and do not affect heart rate or blood pressure, they conceivably could supplement traditional anti-ischemic drug therapy with little risk. The background, rationale for use, and published literature on each agent is reviewed, and the outcomes of pertinent clinical trials are discussed. In the case of ranolazine, data suggest benefit in the treatment of stable angina pectoris, particularly with sustained release formulations. Trimetazidine appears to have similar physiologic effects to ranolazine, and it is effective as monotherapy and as additive therapy in patients with chronic ischemic heart disease. DCA improves acidosis in critically ill patients and, likewise, improves myocardial hemodynamics in those with chronic coronary artery disease and congestive heart failure; however, its metabolism is variable and clinical data on its use in chronic ischemic heart disease are limited. GIK solutions have been shown to be beneficial in animal and human models of ischemia and acute myocardial infarction, and they offer an inexpensive means by which to improve the oxidation of glucose in the heart. Lastly, a large body of literature suggests a benefit with L-carnitine in a number of cardiovascular illnesses, including ischemic heart disease. Clinical trial data in acute myocardial infarction are promising and have prompted the initiation of a large-scale mortality trial.     

心肌脂肪酸氧化抑制剂的研究进展

随着人们对缺血心肌能量代谢改变的深入研究,发现抑制脂肪酸的氧化可改善组织氧利用的有效性,为缺血性心脏病的改善和预后提供了新的治疗措施。本文综述了心肌脂肪酸氧化抑制剂的药理效应、作用机制以及此类药物的研究进展。     

A Metabolic Approach to the Management of Ischemic Heart Disease

Myocardial ischemia occurs when there is a supply and demand imbalance between the delivery of oxygenated blood to the myocardium and the needs of the myocardium to maintain normal cardiac function at any level of activity. The commonest cause of the imbalance is obstructive coronary artery disease. A pharmacologic hemodynamic approach to therapy principally focuses on reducing demand (slowing heart rate, lowering blood pressure, reducing contractility and increasing peripheral venous and arterial vasodilatation), with a variable effect on supply (coronary vasodilatation).This is a proven and highly effective approach indirectly improving myocardial metabolism. An alternative and complementary strategy avoids any effect on hemodynamics, but by direct action at the cellular level minimizes the ischemic disruption of cardiac metabolism. Trimetazidine inhibits the fatty acid oxidation enzyme long-chain 3-ketoacyl-coenzyme A thiolase (3-KAT), thereby decreasing fatty acid oxidation and increasing the combustion of glucose and lactate. This switch back from ischemia-induced fatty acid oxidation to glucose oxidation has been shown to be of significant clinical benefit, both subjectively and objectively, independent of or in combination with conventional hemodynamic agents.     

The impact of fatty acid oxidation on energy utilization: targets and therapy

Utilization of fat as a long-term energy storage vehicle is crucial for the maintenance of cellular metabolism and is under intricate and many times redundant control mechanisms. Aberrations in the control of energy metabolism is apparent in diseases such as diabetes and obesity and is evident early on in patients with impaired glucose tolerance. Insulin resistance has been observed at the level of muscle, liver and adipose tissue. Hyperglycemia is the hallmark of diabetes and is characterized by decreased glucose disposal and increased glucose production, driven by enhanced and uncontrolled fatty acid oxidation (FAO). Mechanisms aimed at limiting the availability of substrates or the activity of processes involved in FAO should provide an immediate reduction in undesired glucose production in these individuals. Numerous targets are available which influence directly the metabolism of fat, including limiting availability of substrate to FAO, inhibiting oxidation of the fatty acid per se, and uncoupling the energy obtained during the oxidation of the fatty acid. These include antilipolytic agents which limit the availability of substrate, FAO inhibitors which limit fatty acid transport (carnitine palmitoyl transferase, CoA sequestration), FAO per se (beta oxidation), and agents which uncouple the energy of FAO (uncoupling proteins, beta3 agonists). These other targets which affect fatty acid metabolism indirectly will be discussed in this review with 184 references.     

Optimization of cardiac metabolism in diabetes mellitus

Cardiovascular disease is a major health problem in all over the world. The prevalence of type 2 diabetes mellitus has been rapidly increasing, together with the risk for cardiovascular events. Patients with diabetes, and/or with insulin resistance as well, have an impaired myocardial metabolism of glucose and free fatty acids (FFA) and accelerated and diffuse atherogenesis, with involvement of peripheral coronary segments. Significant metabolic alterations in diabetic patients are the decreased utilization of glucose and the increase in muscular and myocardial FFA uptake and oxidation, occurring as a consequence of the mismatch between blood supply and cardiac metabolic requirements. These metabolic changes are responsible both for the increased susceptibility of the diabetic heart to myocardial ischemia and for a greater decrease of myocardial performance for a given amount of ischemia, compared to non diabetic hearts. A therapeutic approach aimed at an improvement of cardiac metabolism, through manipulations of the utilization of metabolic substrates, may improve myocardial ischemia and left ventricular function. Modulation of myocardial FFA metabolism, in addition to optimal medical therapy, should be the key target for metabolic interventions in patients with coronary artery disease and diabetes. In diabetic patients the effects of modulation of FFA metabolism should be even greater than those observed in patients without diabetes.     

Metabolic therapy of heart failure

Alterations of cardiac metabolism can be present in several cardiac syndromes. Heart failure may itself promote metabolic changes such as insulin resistance, in part through neurohumoral activation, and determining an increased utilization of non-carbohydrate substrates for energy production. In fact, fasting blood ketone bodies as well as fat oxidation have been shown to be increased in patients with heart failure. The result is depletion of myocardial ATP, phosphocreatine and creatine kinase with decreased efficiency of mechanical work. A direct approach to manipulate cardiac energy metabolism consists in modifying substrate utilization by the failing heart. To date, the most effective metabolic treatments include several pharmacological agents, such as trimetazidine and perhexiline, that directly inhibit fatty acid oxidation. These agents have been originally adopted to increase the ischemic threshold in patients with effort angina. However, the results of current research is supporting the concept that shifting the energy substrate preference away from fatty acid metabolism and toward glucose metabolism could be an effective adjunctive treatment in patients with heart failure, in terms of left ventricular function and glucose metabolism improvement. In fact, these agents have also been shown to improve overall glucose metabolism in diabetic patients with left ventricular dysfunction. In this paper, the recent literature on the beneficial therapeutic effects of modulation of cardiac metabolic substrates utilization in patients with heart failure is reviewed and discussed.     

Optimization of cardiac metabolism in heart failure

The derangement of the cardiac energy substrate metabolism plays a key role in the pathogenesis of heart failure. The utilization of non-carbohydrate substrates, such as fatty acids, is the predominant metabolic pathway in the normal heart, because this provides the highest energy yield per molecule of substrate metabolized. In contrast, glucose becomes an important preferential substrate for metabolism and ATP generation under specific pathological conditions, because it can provide greater efficiency in producing high energy products per oxygen consumed compared to fatty acids. Manipulations that shift energy substrate utilization away from fatty acids toward glucose can improve the cardiac function and slow the progression of heart failure. However, insulin resistance, which is highly prevalent in the heart failure population, impedes this adaptive metabolic shift. Therefore, the acceleration of the glucose metabolism, along with the restoration of insulin sensitivity, would be the ideal metabolic therapy for heart failure. This review discusses the therapeutic potential of modifying substrate utilization to optimize cardiac metabolism in heart failure.     

Methodology for measuring in vitro/ex vivo cardiac energy metabolism

The high energy demands of the heart are met primarily by the metabolism of fatty acids and carbohydrates. These energy substrates are efficiently and rapidly metabolized in order to produce the high levels of adenosine triphosphate (ATP) necessary to sustain both contractile activity and other cellular functions. Alterations in energy metabolism contribute to abnormal heart function in many cardiac diseases. As a result, a number of techniques have been developed to directly measure energy metabolism in the heart in order to study energy metabolism. Two important variables that must be considered when making these measurements are energy substrate supply to the heart and the metabolic demand of the heart (i.e. contractile function). The use of the in vitro/ex vivo heart, perfused with relevant energy substrates, is a useful experimental approach that accounts for these variables. This paper overviews a number of the techniques that are used to measure energy substrate metabolism in the isolated perfused heart. Recently developed technology that allows for the direct measurement of energy metabolism in an isolated working mouse heart preparation are also described.     

Modulation of fatty acids oxidation in heart failure by selective pharmacological inhibition of 3-ketoacyl coenzyme-A thiolase

A direct approach to manipulate cardiac energy metabolism consists in modifying substrate utilization by the heart. Pharmacological agents that directly inhibit fatty acid oxidation include inhibitors of 3-ketoacyl coenzyme A thiolase (3-KAT), the last enzyme involved in ss-oxidation. The most extensively investigated agents of this group of drugs are trimetazidine and ranolazine. Clinical studies have shown that these agents can substantially increase the ischemic threshold in patients with effort angina. However, the results of current research is also supporting the concept that shifting the energy substrate preference away from fatty acid metabolism and toward glucose metabolism by 3-KAT inhibitors could be an effective adjunctive treatment in patients with heart failure, in terms of left ventricular function and glucose metabolism improvement. In fact, these agents have also been shown to improve overall glucose metabolism in diabetic patients with left ventricular dysfunction. In this paper, the recent literature on the beneficial effects of this new class of drugs on left ventricular dysfunction and glucose metabolism is reviewed and discussed.     

Cardioprotective effects of trimetazidine: a review

The efficacy of trimetazidine, an anti-ischaemic agent, has been largely assessed and presented in the international literature through its metabolic effects, selective and specific fatty acid oxidation inhibition and lack of haemodynamic effects in stable angina pectoris. As such, trimetazidine has opened up a new class of metabolic agents that reduce fatty acid oxidation: the 3-KAT (3-ketoacyl-CoA thiolase) inhibitors. The aim of this review article is to demonstrate the cardioprotective benefits of trimetazidine, and how this can be translated into positive effects in the treatment of cardiac disorders. Trimetazidine has been assessed in several double-blind randomised studies as a treatment of ischaemic heart disease or as an agent given prior to or during percutaneous transluminal coronary angioplasty, coronary artery bypass grafting and thrombolysis to prevent or limit ischaemia/reperfusion damage in the heart. All these studies demonstrate that trimetazidine protects the heart from the deleterious consequences of ischaemia by switching cardiac metabolism from fatty acid oxidation to glucose oxidation. Study results cast no doubts on the value of the cardioprotective effects of trimetazidine and support the fact that trimetazidine has a direct anti-ischaemic effect on human myocardial cells. Trimetazidine has proven antianginal efficacy, and can be also used in other cardiac diseases with ischaemic signs.     

Anti-anginal effects of partial fatty acid oxidation inhibitors

Angina pectoris can result in an imbalance between oxygen supply and demand of the heart muscle, resulting in a compromised energy supply to the heart muscle. Currently, the primary approach to treating angina is aimed either at decreasing muscle oxygen demand, or increasing oxygen supply to the muscle. An alternative approach is to increase cardiac efficiency by increasing the amount of cardiac work at a given level of oxygen consumed. This can be achieved by inhibiting myocardial fatty acid oxidation, which leads to an increase in glucose oxidation. Consequently, lactate and proton production decrease, and as a result cardiac efficiency is improved. The approach of partial fatty acid oxidation (pFOX) inhibition is beneficial in the treatment of angina pectoris, both as a monotherapy and when used in combination with conventional therapy. pFOX inhibitors not only lessen the severity and symptoms of an angina attack, they also decrease the incidence of angina attacks in patients with coronary artery disease. The approach of optimizing energy substrate preference in the heart is a new and effective approach to treating angina pectoris.