Effects of SM-20550, a selective Na+-H+ exchange inhibitor,on the ion transport of myocardial mitochondria

The study investigated the influence of L-carnitine on the formation of malondialdehyde, an indicator of lipid peroxidation, in isolated Langendorff rat hearts. Earlier investigations of hemodynamic parameters and the recovery of ATP and creatine phosphate, carried out by means of ³¹P-NMR spectroscopy, had demonstrated that, depending on the composition of the perfusates (content of glucose, fatty acids, and carnitine), quite strong differences may occur in the reperfusion period after ischemia.In order to determine a possible relationship between these differences and the addition of carnitine, the study investigated whether carnitine penetrated into the tissue during the experiments, and whether it was able to reduce the concentration of detrimental substances. The concentrations of free and total carnitine as well as the malondialdehyde content as an indicator of ischemia/reperfusion damage were determined in different parts of the cardiac tissue as follows: After the Langendorff-experiments the hearts were dissected, homogenized and reconditioned; then carnitine and malondialdehyde were determined. The study included 63 hearts, which were divided into 8 different perfusion groups.Carnitine concentrations in heart tissue perfused with L-carnitine were much higher than those of the controls. Since exogenous L-carnitine and formed esters could be found in the tissue after the experiment, they must have permeated the cellular membrane rapidly. The concentrations of malondialdehyde behaved in an inverted way; as expected they were lower in carnitine-perfused hearts. The favourable effects of L-carnitine, expressed both by improved cardiac dynamics and ATP and CrP recovery in the reperfusion period, are obviously due to the fact that L-carnitine reduces ischemic damage.     

Effects of L-carnitine and its derivatives on postischemic cardiac function,ventricular fibrillation and necrotic and apoptotic cardiomyocyte death in isolated rat hearts

The study aimed to examine whether L-carnitine and its derivatives, acetyl-L-carnitine and propionyl-L-carnitine, were equally effective and able to improve postischemic cardiac function, reduce the incidence of reperfusion-induced ventricular fibrillation, infarct size, and apoptotic cell death in ischemic/reperfused isolated rat hearts. There are several studies indicating that L-carnitine, a naturally occurring amino acid and an essential cofactor, can improve mechanical function and substrate metabolism not only in hypertrophied or failing myocardium but also in ischemic/reperfused hearts. The effects of L-carnitine, acetyl-L-carnitine, and propionyl-L-carnitine, on the recovery of heart function, incidence of reperfusion-induced ventricular fibrillation (VF), infarct size, and apoptotic cell death after 30 min ischemia followed by 120 min reperfusion were studied in isolated working rat hearts. Hearts were perfused with various concentrations of L-carnitine (0.5 and 5 mM), acetyl-L-carnitine (0.5 and 5 mM), and propionyl-L-carnitine (0.05, 0.5, and 5 mM), respectively, for 10 min before the induction of ischemia. Postischemic recovery of CF, AF, and LVDP was significantly improved in all groups perfused with 5 mM of L-carnitine, acetyl-L-carnitine, and propionyl-L-carnitine. Significant postischemic ventricular recovery was noticed in the hearts perfused with 0.5 mM of propionyl-L-carnitine, but not with the same concentration of L-carnitine or L-acetyl carnitine. The incidence of reperfusion VF was reduced from its control value of 90 to 10% (p < 0.05) in hearts perfused with 5 mM of propionyl-L-carnitine only. Other doses of various carnitines failed to reduce the incidence of VF. The protection in CF, AF, LVDP, and VF reflected in a reduction in infarct size and apoptotic cell death in hearts treated with various concentrations of carnitine derivatives. The difference between effectiveness of various carnitines on the recovery of postischemic myocardium may be explained by different membrane permeability properties of carnitine and its derivatives.     

In vivo and in vitro intervention with L-carnitine prevents abnormal energy metabolism in isolated diabetic rat heart: chemical and phosphorus-31 NMR evidence

The beneficial effects of in vivo injections (200 mg/kg, twice daily) or in vitro perfusion (5.0 mM) of L-carnitine on an intrinsic abnormality in energy metabolism was investigated in isolated, perfused diabetic rat heart. Hearts were aerobically perfused for 60 min with elevated fatty acid substrate to simulate diabetic conditions. Phosphorus-31 nuclear magnetic resonance spectroscopy revealed a temporal decline in myocardial ATP levels (to approx 82%) during perfusion of diabetic hearts, but not in control hearts. This reduction was prevented by prior treatment in vivo with L-carnitine or by providing L-carnitine acutely in the perfusion medium. Chemical analysis of tissue extracts indicated that L-carnitine injections were effective in replenishing the decrease in total myocardial carnitine content which was present in diabetic hearts and in preventing the accumulation of long chain fatty acyl CoA. Perfusion with L-carnitine also attenuated the elevation of long chain fatty acyl CoA in diabetic hearts. This study gives additional support to the hypothesis that decreases in ATP which occur in the isolated, perfused diabetic heart are correlated with a concomitant elevation in long chain fatty acyl CoA, a known inhibitor of adenine nucleotide translocase. In the presence of elevated exogenous fatty acids, a primary deficiency in the total myocardial carnitine pool would result in elevations in tissue concentrations of long chain fatty acyl CoA since carnitine is a required carrier for transport of fatty acids into mitochondria. Replenishment of the carnitine in vivo was shown to be sufficient to prevent subsequent alteration in long chain fatty acyl CoA and ATP in isolated perfused diabetic hearts despite the burden of elevated fatty acid substrates.     

Effects of L-carnitine and its acetyl and propionyl esters on ATP and PCr levels of isolated rat hearts perfused without fatty acids and investigated by means of 31P-NMR spectroscopy

³¹P-NMR in vivo spectroscopy is a non-invasive and non-hazardous technique which investigates chemical composition and metabolism of living objects, for example by determining phosphocreatine (PCr) and ATP concentrations. In the present study we investigated the influence of L-carnitine, acetyl-L-carnitine and propionyl-L-carnitine on the energetic state of the Langendorff rat heart subjected to an ischemic period of 20 min followed by a reperfusion period of 60 min. To avoid an overlapping of the effects of fatty acids and glucose, the hearts were perfused with a Tyrode solution containing no fatty acids. Ischemia causes a rapid decrease in the PCr signal, followed by a decrease in the ATP signal after a prolonged period of ischemia. At the same time, a drastic increase in the P_i signal was observed. A partial recovery of the ATP and PCr signals was observed in the reperfusion period. With L-carnitine a markedly improved recovery of the high energy phosphates (e.g. increased PCr/P_i ratios) was found. With acetyl-L-carnitine this effect was enhanced in the first postischemic phase. It was followed, however, by a more rapid decrease in the PCr/P_i ratio in the late reperfusion period. The effect of propionyl-L-carnitine was not significantly improved in the first minutes of the reperfusion period, but during the whole reperfusion phase a stabilization of the PCr/P_i ratio was observed. Intracellular pH can be calculated from determination of the P_i-chemical shift. This shows that L-carnitine and its derivatives have a protective effect against intracellular pH decrease during ischemia. L-carnitine improves the energetic state of the heart, which leads to increased ischemia tolerance. Hearts under L-carnitine were able to tolerate up to four ischemia-reperfusion periods in succession, whereas the controls were not able to do so. These NMR results confirm the hypothesis that L-carnitine and its esters have a protective effect in the reperfusion period of the ischemic rat heart. This could be of importance for the treatment of ischemic cardiac diseases.     

The relative contribution of glucose and fatty acids to ATP production in hearts reperfused following ischemia

High levels of fatty acids decrease the extent of mechanical recovery of hearts reperfused following a transient period of severe ischemia. Glucose oxidation rates during reperfusion are low under these conditions, which can result in a decreased recovery of mechanical function. Stimulation of glucose oxidation with the carnitine palmitoyl transferase I inhibitor, Etomoxir, or by directly stimulating pyruvate dehydrogenase activity with dichloroacetate (DCA) results in an improvement in mechanical function during reperfusion of previously ischemic hearts. Addition of DCA (1 mM) to hearts perfused with 11 mM glucose and 1.2 mM palmitate results in an increase in contribution of glucose oxidation to overall ATP production from 6 to 23%, with a parallel decrease in that of fatty acid oxidation from 90 to 69%. In aerobic hearts, endogenous myocardial triglycerides are an important source of fatty acids for -oxidation. Using hearts in which the myocardial triglycerides were pre-labeled, the contribution of both endogenous and exogenous fatty acid oxidation to myocardial ATP production was determined in hearts perfused with 11 mM glucose, 1.2 mM palmitate and 500 µU/ml insulin. In hearts reperfused following a 30 min period of global no flow ischemia, 91.9% of ATP production was derived from endogenous and exogenous fatty acid oxidation, compared to 87.7% in aerobic hearts. This demonstrates that fatty acid oxidation quickly recovers following a transient period of severe ischemia. Furthermore, therapy aimed at overcoming fatty acid inhibition of glucose oxidation during reperfusion of ischemic hearts appears to be beneficial to recovery of mechanical function.     

Postischemic recovery of heart metabolism and function: role of mitochondrial fatty acid transfer.

Postischemic recovery of contractile function is better in hearts from fasted rats than in hearts from fed rats. In this study, we examined whether feeding-induced inhibition of palmitate oxidation at the level of carnitine palmitoyl transferase I is involved in the mechanism underlying impaired recovery of contractile function. Hearts isolated from fasted or fed rats were submitted to no-flow ischemia followed by reperfusion with buffer containing 8 mM glucose and either 0.4 mM palmitate or 0.8 mM octanoate. During reperfusion, oxidation of palmitate was higher after fasting than after feeding, whereas oxidation of octanoate was not influenced by the nutritional state. In the presence of palmitate, recovery of left ventricular developed pressure was better in hearts from fasted rats. Substitution of octanoate for palmitate during reperfusion enhanced recovery of left ventricular developed pressure in hearts from fed rats. However, the chain length of the fatty acid did not influence diastolic contracture. The results suggest that nutritional variation of mitochondrial fatty acid transfer may influence postischemic recovery of contractile function.     

Carnitine transport and exogenous palmitate oxidation in chronically volume-overloaded rat hearts

L-Carnitine transport and free fatty acid oxidation have been studied in hearts of rats with 3-month-old aorto-caval fistula. For carnitine transport experiments, the hearts were perfused via the ascending aorta with a bicarbonate buffer containing 11 mM glucose and variable concentrations L-[14C]carnitine (10-200 microM). In some experiments, the active component of carnitine transport was suppressed by the adjunction of 0.05 mM mersalyl acid. The subtraction of passive from total transport allowed reconstruction of the saturation curves of the carrier-mediated transport of L-carnitine. Our data suggest that at a physiological carnitine concentration (50 microM), the rate of [14C]carnitine accumulation was significantly depressed in mechanically overloaded hearts. In addition, according to Lineweaver-Burk analysis, the affinity of the membrane carrier for L-carnitine was considerably diminished (Km carnitine 125 instead of 83 microM, Vmax unchanged). The above alterations of L-carnitine transport did not result from a decrease of the transmembrane gradient of sodium, since the intracellular Na+ content of the hypertrophied hearts was quite similar to that of control hearts. The ability of atrially perfused, working hearts to oxidize the exogenous free fatty acids was assessed from 14CO2 production obtained in the presence of [U-14C]palmitate or [1-14C]octanoate. The total 14CO2 production, expressed per min per g dry weight, was significantly diminished in hearts from rats with the aorto-caval fistula if 1.2 mM palmitate was used. On the other hand, in the presence of 2.4 mM octanoate, a substrate which circumvents the carnitine-acylcarnitine translocase, no such reduction of the 14CO2 production could be detected. Our results suggest that the decrease of L-carnitine transport, resulting in a significant depression of tissue carnitine, may impair long-chain fatty acid activation and/or translocation into mitochondria. In contrast, the oxidation of short-chain fatty acids, the activation of which takes place directly in mitochondrial matrix, is not limited in volume-overloaded hearts.     

Palmitate oxidation by the mitochondria from volume-overloaded rat hearts

In this work, an attempt was made to identify the reasons of impaired long-chain fatty acid utilization that waspreviously described in volume-overloaded rat hearts. The most significant data are the following: (1) The slowing down of long-chain fatty acid oxidation in severely hypertrophied hearts cannot be related to a feedback inhibition of carnitine palmitoyltransferase I from an excessive stimulation of glucose oxidation since, because of decreased tissue levels of L-carnitine, glucose oxidation also declines in volume-overloaded hearts. (2) While, in control hearts, the estimated intracellular concentrations of free carnitine are in the range of the respective K_m of mitochondrial CPT I, a kinetic limitation of this enzyme could occur in hypertrophied hearts due to a 40% decrease in free carnitine. (3) However, the impaired palmitate oxidation persists upon the isolation of the mitochondria from these hearts even in presence of saturating concentrations of L-carnitine. In contrast, the rates of the conversion of both palmitoyl-CoA and palmitoylcarnitine into acetyl-CoA are unchanged. (4) The kinetic analyses of palmitoyl-CoA synthase and carnitine palmitoyltransferase I reactions do not reveal any differences between the two mitochondrial populations studied. On the other hand, the conversion of palmitate into palmitoylcarnitine proves to be substrate inhibited already at physiological concentrations of exogenous palmitate. The data presented in this work demonstrate that, during the development of a severe cardiac hypertrophy, a fragilization of the mitochondrial outer membrane may occur. The functional integrity of this membrane seems to be further deteriorated by increasing concentrations of free fatty acids which gives rise to an impaired functional cooperation between palmitoyl-CoA synthase and carnitine palmitoyltransferase I. In intact myocardium, the utilization of the generated in situ palmitoyl-CoA can be further slowed down by decreased intracellular concentrations of free carnitine.     

Antiradical effects in L-propionyl carnitine protection of the heart against ischemia-reperfusion injury: the possible role of iron chelation.

L-Propionyl carnitine has been shown to improve the heart's mechanical recovery and other metabolic parameters after ischemia-reperfusion. However, the mechanism of protection is unknown. The two dominating hypotheses are: (i) L-propionyl carnitine can serve as an energy source for heart muscle cells by being enzymatically converted to propionyl-CoA and subsequently utilized in the Krebs cycle (a metabolic hypothesis), and (ii) it can act as an antiradical agent, protecting myocardial cells from oxidative damage (a free radical hypothesis). To test the two possible pathways, we compared the protection afforded to the ischemia-reperfused hearts by L-propionyl carnitine and its optical isomer, D-propionyl carnitine. The latter cannot be enzymatically utilized as an energy source. The Langendorff perfusion technique was used and the hearts were subjected to 40 min of ischemia and 20 min of reperfusion. In analysis of ischemia-reperfused hearts, a strong correlation was found between the recovery of mechanical function and the presence of protein oxidation products (protein carbonyls). Both propionyl carnitines efficiently prevented protein oxidation but L-propionyl carnitine-perfused hearts had two times greater left ventricular developed pressure. The results indicate that both metabolic and antiradical pathway are involved in the protective mechanism of L-propionyl carnitine. To obtain a better insight of the antiradical mechanism of L-propionyl carnitine, we compared the ability of L- and D-propionyl carnitines, L-carnitine, and deferoxamine to interact with: (i) peroxyl radicals, (ii) oxygen radicals, and (iii) iron. We found that none of the carnitine derivatives were able to scavenge peroxyl radicals or superoxide radicals. L- and D-propionyl carnitine and deferoxamine (not L-carnitine) suppressed hydroxyl radical production in the Fenton system, probably by chelating the iron required for the generation of hydroxyl radicals. We suggest that L-propionyl carnitine protects the heart by a dual mechanism: it is an efficient fuel source and an antiradical agent.     

Carnitine stimulation of glucose oxidation in the fatty acid perfused isolated working rat heart.

The effects of L-carnitine on myocardial glycolysis, glucose oxidation, and palmitate oxidation were determined in isolated working rat hearts. Hearts were perfused under aerobic conditions with perfusate containing either 11 mM [2-3H/U-14C]glucose in the presence or absence of 1.2 mM palmitate or 11 mM glucose and 1.2 mM [1-14C]palmitate. Myocardial carnitine levels were elevated by perfusing hearts with 10 mM L-carnitine. A 60-min perfusion period resulted in significant increases in total myocardial carnitine from 4376 +/- 211 to 9496 +/- 473 nmol/g dry weight. Glycolysis (measured as 3H2O production) was unchanged in carnitine-treated hearts perfused in the absence of fatty acids (4418 +/- 300 versus 4547 +/- 600 nmol glucose/g dry weight.min). If 1.2 mM palmitate was present in the perfusate, glycolysis decreased almost 2-fold compared with hearts perfused in the absence of fatty acids. In carnitine-treated hearts this drop in glycolysis did not occur (glycolytic rates were 2911 +/- 231 to 4629 +/- 460 nmol glucose/g dry weight.min, in control and carnitine-treated hearts, respectively. Compared with control hearts, glucose oxidation rates (measured as 14CO2 production from [U-14C]glucose) were unaltered in carnitine-treated hearts perfused in the absence of fatty acids (1819 +/- 169 versus 2026 +/- 171 nmol glucose/g dry weight.min, respectively). In the presence of 1.2 mM palmitate, glucose oxidation decreased dramatically in control hearts (11-fold). In carnitine-treated hearts, however, glucose oxidation was significantly greater than control hearts under these conditions (158 +/- 21 to 454 +/- 85 nmol glucose/g dry weight.min, in control and carnitine-treated hearts, respectively). Palmitate oxidation rates (measured as 14CO2 production from [1-14C]palmitate) decreased in the carnitine-treated hearts from 728 +/- 61 to 572 +/- 111 nmol palmitate/g dry weight.min. This probably occurred secondary to an increase in overall ATP production from glucose oxidation (from 5.4 to 14.5% of steady state myocardial ATP production). The results reported in this study provide direct evidence that carnitine can stimulate glucose oxidation in the intact fatty acid perfused heart. This probably occurs secondary to facilitating the intramitochondrial transfer of acetyl groups from acetyl-CoA to acetylcarnitine, thereby relieving inhibition of the pyruvate dehydrogenase complex.     

Palmitic and erucic acid metabolism in isolated perfused hearts from weanling pigs

Hearts from 4 week-old weanling pigs were capable of continuous work output when perfused with Krebs-Henseleit buffer containing 11 mM glucose. Perfused hearts metabolized either glucose or fatty acids, but optimum work output was achieved by a combination of glucose plus physiological concentrations (0.1 mM) of either palmitate or erucate. Higher concentrations of free fatty acids increased their rate of oxidation but also resulted in a large accumulation of neutral lipids in the myocardium, as well as a tendency to increased acetylation and acylation of coenzyme A and carnitine. When hearts were perfused with 1 mM fatty acids, the work output declined below control values. Erucic acid is known to be poorly oxidized by isolated rat heart mitochondria and, to a lesser degree, by perfused rat hearts. In addition, it has been reported that erucic acid acts as an uncoupler of oxidative phosphorylation. In isolated perfused pig hearts used in the present study, erucic acid oxidation rates were as high as palmitate oxidation rates. When energy coupling was measured by 31P-NMR, the steady-state levels of ATP and phosphocreatine during erucic acid perfusion did not change noticeably from those during glucose perfusion. It was concluded that the severe decrease in oxidation rates and ATP production resulting from the exposure of isolated pig and heart mitochondria to erucic acid are not replicated in the intact pig heart.     

Responses to oleic,linoleic and α-linolenic acids in high-carbohydrate,high-fat diet-induced metabolic syndrome in rats

We investigated the changes in adiposity, cardiovascular and liver structure and function, and tissue fatty acid compositions in response to oleic acid-rich macadamia oil, linoleic acid-rich safflower oil and α-linolenic acid-rich flaxseed oil (C18 unsaturated fatty acids) in rats fed either a diet high in simple sugars and mainly saturated fats or a diet high in polysaccharides (cornstarch) and low in fat. The fatty acids induced lipid redistribution away from the abdomen, more pronounced with increasing unsaturation; only oleic acid increased whole-body adiposity. Oleic acid decreased plasma total cholesterol without changing triglycerides and nonesterified fatty acids, whereas linoleic and α-linolenic acids decreased plasma triglycerides and nonesterified fatty acids but not cholesterol. α-Linolenic acid improved left ventricular structure and function, diastolic stiffness and systolic blood pressure. Neither oleic nor linoleic acid changed the left ventricular remodeling induced by high-carbohydrate, high-fat diet, but both induced dilation of the left ventricle and functional deterioration in low fat-diet-fed rats. α-Linolenic acid improved glucose tolerance, while oleic and linoleic acids increased basal plasma glucose concentrations. Oleic and α-linolenic acids, but not linoleic acid, normalized systolic blood pressure. Only oleic acid reduced plasma markers of liver damage. The C18 unsaturated fatty acids reduced trans fatty acids in the heart, liver and skeletal muscle with lowered stearoyl-CoA desaturase-1 activity index; linoleic and α-linolenic acids increased accumulation of their C22 elongated products. These results demonstrate different physiological and biochemical responses to primary C18 unsaturated fatty acids in a rat model of human metabolic syndrome.     

The effects of pantothenic acid,cysteine and dithiothreitol in intact,reperfused pig hearts

The objective of this study was to augment myocardial tissue levels of amphiphiles using a treatment protocol of pantothenic acid, cysteine and dithiothreitol (DTT) in 24hr fasted pigs and to test their influence on mechanical recovery in reperfusion. Eighteen pig hearts were extracorporeally perfused aerobically, subjected to regionally reversible ischemia in the left anterior descending perfusion system and reperfused. Nine hearts served as a placebo group; nine hearts were treated. All hearts received trace-labeled palmitate to measure fatty acid oxidation and were perfused with an infusion of 20% Intralipid to augment perfusate levels of fatty acids. Fasting alone in the presence of carbon substrates in the coronary perfusate was not sufficient to de-inhibit pantothenic acid kinase such that CoA synthesis was not enhanced. Tissue contents of triacylglycerols and phospholipids in reperfused myocardium were no different than in aerobic heart muscle but free CoA and free and total carnitine were reduced, suggesting a leakage of cytosolic contents across injured sarcolemma. Treatment significantly impaired mechanical recovery during reflow, presumable due to the noxious properties of DTT whose reported effects in heart muscle are wide ranging, difficult to predict in intact hearts and may be harmful.     

Plasma carnitine levels as a marker of impaired left ventricular functions

L-Carnitine plays a role in the utilization of fatty acids and glucose in the myocardium. Previous studies have indicated carnitine deficiency in patients with congestive heart failure. However, the extent of altered carnitine metabolism and left ventricular function is not fully determined. This study is designed to determine if plasma L-carnitine levels can serve as a marker for impaired left ventricular function in patients with congestive heart failure.To test this hypothesis, plasma and urinary levels of L-carnitine were measured in 30 patients with congestive heart failure (CHF) and in 10 control subjects. CHF was due to dilated cardiomyopathy (DCM) and rheumatic heart disease (RHD). Cardiac functions such as percentage of fractional shortening (%FS), ejection fraction (EF), left ventricular mass index (LVMI), were determined by echocardiography. All patients and control subjects had normal renal functions.Plasma carnitine was significantly higher in patients with DCM (37.05 ± 7.62, p < 0.0001) and with RHD (47.2 ± 8.04, p < 0.0001) vs. the control subjects (14.4 ± 5.30 mg/L). Urinary carnitine was significantly higher in DCM (49.13 ± 14.11, p < 0.0001) and in RHD 43.53 ± 15.5, p < 0.0001), than the control (25.1 ± 5.78 mg/L). Plasma carnitine level correlated significantly with impaired left ventricular systolic functions in these patients: %FS < 25% (r = -0.38 and p = 0.038), EF < 0.55 (r = -0.502 and p = 0.005) and LMVI > 124 gm/m² (r = 0.436, and p = 0.016). These data suggest that elevated plasma and urinary carnitine levels in patients with CHF could serve as a marker for myocardial damage and impaired left ventricular functions.     

Effects of chronic caloric restriction on mitochondrial respiration in the ischemic reperfused rat heart

Dietary restriction increases life span and delays the development of age-related diseases in rodents. We have recently demonstrated that chronic dietary restriction is beneficial on recovery of heart function following ischemia. We studied whether the metabolic basis of this benefit is associated with alterations in mitochondrial respiration. Male Wistar rats were assigned to an ad libitum-fed (AL) group and a food restricted (FR) group, in which food intake was reduced to 55% of the amount consumed by the AL group. Following an 8-month period of restricted caloric intake, isolated working hearts perfused with glucose and high levels of fatty acids were subjected to global ischemia followed by reperfusion. At the end of reperfusion, total heart mitochondria was respiration was assessed in the presence of pyruvate, tricarboxylic acid intermediates, and palmitoylcarnitine. Recovery of heart function following ischemia was greater in FR hearts compared to AL hearts. Paralleling these changes in heart function was in increase in state 3 respiration with pyruvate. The respiratory control ratios in the presence of pyruvate and tricarboxylic acid intermediates were higher in FR hearts compared to AL hearts, indicating well-coupled mitochondria. Overall energy production, expressed as the ADP:O ratio and the oxidative phosphorylation rate, was also improved in FR hearts. Our results indicate that the beneficial effect of FR on recovery of heart function following ischemia is associated with changes in mitochondrial respiration.     

Myocardial triglyceride turnover during reperfusion of isolated rat hearts subjected to a transient period of global ischemia.

Triglyceride turnover in reperfused/ischemic rat hearts was investigated. Hearts were initially perfused under aerobic conditions for a 1-h "pulse" perfusion with 1.2 mM [1-14C]palmitate to label the endogenous lipid pools, followed by a 30-min period of no-flow ischemia or a 10-min period of retrograde perfusion (control). Hearts were then reperfused under aerobic conditions with buffer containing 1.2 mM [9,10-3H]palmitate. All buffers contained 11 mM glucose and 500 microunits/ml insulin. Rates of endogenous triglyceride lipolysis and synthesis were measured during reperfusion, whereas rates of exogenous palmitate oxidation were measured both prior to ischemia and during reperfusion following ischemia. During reperfusion of ischemic hearts, a 20% increase in exogenous fatty acid oxidation rates was seen compared with pre-ischemic rates. Despite an initial burst of endogenous fatty acid oxidation, no acceleration of steady state endogenous triglyceride lipolysis was seen compared with their nonischemic hearts. In contrast, a significant increase in triglyceride synthesis was observed. Triglyceride turnover was also measured in a series of hearts reperfused following ischemia in the absence of exogenous fatty acids. A significant enhancement of functional recovery was seen compared with hearts reperfused with 1.2 mM palmitate. In addition, a significant increase in fatty acid oxidation from endogenous triglyceride lipolysis was observed. We conclude that the heart quickly recovers its ability to oxidize exogenous fatty acids during reperfusion and that although triglyceride lipolysis is not accelerated during reperfusion of ischemic hearts in the presence of 1.2 mM palmitate, a significant increase in triglyceride synthesis does occur.     

Lack of effect of oral L-carnitine treatment on lipid metabolism and cardiac function in chronically diabetic rats

L-Carnitine is necessary for the transfer of long-chain fatty acids into the mitochondrial matrix where energy production occurs. In the absence of L-carnitine, the accumulation of free fatty acids and related intermediates could produce myocardial subcellular alterations and cardiac dysfunction. Diabetic hearts have a deficiency in the total carnitine pool and develop cardiac dysfunction. This suggested that carnitine therapy may ameliorate alteration in cardiac contractile performance seen during diabetes. In this study, heart function was studied in streptozotocin diabetic rats given L-carnitine orally. Oral L-carnitine treatment (50-250 mg.kg-1.day-1) of 1- and 3-week diabetic rats increased plasma free and total carnitine and decreased plasma acyl carnitine levels. In both groups, myocardial total carnitine levels were increased. However, L-carnitine (200 mg.kg-1.day-1) treatment of diabetic rats for 6 weeks had no effect on plasma carnitine levels. Similarly, plasma lipids remained elevated whereas cardiac function was still depressed. These studies suggest that in the chronically diabetic rat, the route of administration of L-carnitine is an important factor in determining an effect.     

Regulation of the activity of caspases by L-carnitine and palmitoylcarnitine

L-Carnitine facilitates the transport of fatty acids into the mitochondrial matrix where they are used for energy production. Recent studies have shown that L-carnitine is capable of protecting the heart against ischemia/reperfusion injury and has beneficial effects against Alzheimer's disease and AIDS. The mechanism of action, however, is not yet understood. In the present study, we found that in Jurkat cells, L-carnitine inhibited apoptosis induced by Fas ligation. In addition, 5 mM carnitine potently inhibited the activity of recombinant caspases 3, 7 and 8, whereas its long-chain fatty acid derivative palmitoylcarnitine stimulated the activity of all the caspases. Palmitoylcarnitine reversed the inhibition mediated by carnitine. Levels of carnitine and palmitoyl-CoA decreased significantly during Fas-mediated apoptosis, while palmitoylcarnitine formation increased. These alterations may be due to inactivation of beta-oxidation or to an increase in the activity of the enzyme that converts carnitine to palmitoylcarnitine, carnitine palmitoyltransferase I (CPT I). In support of the latter possibility, fibroblasts deficient in CPT I activity were relatively resistant to staurosporine-induced apoptosis. These observations suggest that caspase activity may be regulated in part by the balance of carnitine and palmitoylcarnitine.     

Effects of L-carnitine in acute myocardial ischaemia

Data in the literature suggest that exogenous L-carnitine improves the metabolic function of ischaemic heart cells: it enhances the transport of long-chain fatty acids into the mitochondria, stimulates the slowed beta-oxidation, and moderates the accumulation of amphiphilic acyl esters. A study has therefore been made of the cardiac effects of L-carnitine in dog experiments (n = 8). The left anterior descending coronary artery (LAD) was isolated in anaesthetized, thoracotomized animals in situ. After a control occlusion and equilibration period, the LAD was again ligated at the time of L-carnitine infusion (100 mg/kg iv. during 10 min). The agent diminished the maximal conduction delay and the degree of epicardial ST-segment elevation in the ischaemic myocardial region, and the free fatty acid concentration of the arterial blood, but it did not influence the frequency of ventricular extrasystoles. The anti-ischaemic effect of L-carnitine was manifest only during the infusion, and its discontinuation was immediately followed by an enhanced ST-segment elevation. In the dose applied, the substance did not affect the heart rate, systemic mean arterial pressure, left ventricular end-diastolic pressure (LVEDP), or left ventricular contractility (LV dP/dtmax). In the canine myocardial infarction model employed it was observed that the duration of the anti-ischaemic effect of L-carnitine (100 mg/kg iv.) is very short, and it has no significant antiarrhythmic action.     

Glucose oxidation is stimulated in reperfused ischemic hearts with the carnitine palmitoyltransferase 1 inhibitor,Etomoxir

Summary The effect of the carnitine palmitoyltransferase 1(CPT1) inhibitor, Etomoxir, on glucose oxidation rates was determined in ischemic hearts reperfused in the presence of fatty acids. Isolated working rat hearts were perfused with 11 mM (¹⁴C)-glucose and 1.2 mM palmitate at a 15 cm H₂O preload, 80 mm Hg afterload. Hearts were subjected to either 60 min aerobic perfusion, or 15 min work followed by 25 min global ischemia then 60 min of aerobic reperfusion. Steady state glucose oxidation rates in reperfused ischemic hearts were not significantly different from non-ischemic hearts. If 10^–9 M Etomoxir was added immediately prior to reperfusion no significant change in glucose oxidation occurred. Addition of 10^–8 M and 10^–6 M Etomoxir, however, significantly increased glucose oxidation. Etomoxir also significantly improved recovery of mechanical function at a concentration of 10^i–8 M or greater. As we previously reported, no significant improvement of function was seen when 10^–9 M Etomoxir was added to the perfusate (Lopaschuk GD et al., Circ Res 63: 1036–1043, 1988). Long chain acylcarnitine levels were significantly reduced in the presence of both 10^–9 M and 10^–8 M Etomoxir. These data demonstrate that the beneficial effect of Etomoxir on reperfusion recovery of ischemic hearts is not due to a lowering of long chain acylcarnitine levels. Etomoxir may improve recovery of function by overcoming fatty acid inhibition of glucose oxidation.