Exercise training promotes cardioprotection through oxygen-sparing action in high fat-fed mice.

Although exercise training has been demonstrated to have beneficial cardiovascular effects in diabetes, the effect of exercise training on hearts from obese/diabetic models is unclear. In the present study, mice were fed a high-fat diet, which led to obesity, reduced aerobic capacity, development of mild diastolic dysfunction, and impaired glucose tolerance. Following 8 wk on high-fat diet, mice were assigned to 5 weekly high-intensity interval training (HIT) sessions (10 × 4 min at 85-90% of maximum oxygen uptake) or remained sedentary for the next 10 constitutive weeks. HIT increased maximum oxygen uptake by 13%, reduced body weight by 16%, and improved systemic glucose homeostasis. Exercise training was found to normalize diastolic function, attenuate diet-induced changes in myocardial substrate utilization, and dampen cardiac reactive oxygen species content and fibrosis. These changes were accompanied by normalization of obesity-related impairment of mechanical efficiency due to a decrease in work-independent myocardial oxygen consumption. Finally, we found HIT to reduce infarct size by 47% in ex vivo hearts subjected to ischemia-reperfusion. This study therefore demonstrated for the first time that exercise training mediates cardioprotection following ischemia in diet-induced obese mice and that this was associated with oxygen-sparing effects. These findings highlight the importance of optimal myocardial energetics during ischemic stress.

Impaired left ventricular mechanical and energetic function in mice after cardiomyocyte-specific excision of Serca2.

Sarco(endo)plasmic reticulum Ca2+ -ATPase (SERCA)2 transports Ca2+ from the cytosol into the sarcoplasmic reticulum of cardiomyocytes and is essential for maintaining myocardial Ca2+ handling and thus the mechanical function of the heart. SERCA2 is a major ATP consumer in excitation-contraction coupling but is regarded to contribute to energetically efficient Ca2+ handling in the cardiomyocyte. Previous studies using cardiomyocyte-specific SERCA2 knockout (KO) mice have demonstrated that decreased SERCA2 activity reduces the Ca2+ transient amplitude and induces compensatory Ca2+ transport mechanisms that may lead to more inefficient Ca2+ transport. In this study, we examined the relationship between left ventricular (LV) function and myocardial O2 consumption (MVo2) in ex vivo hearts from SERCA2 KO mice to directly measure how SERCA2 elimination influences mechanical and energetic features of the heart. Ex vivo hearts from SERCA2 KO hearts developed mechanical dysfunction at 4 wk and demonstrated virtually no working capacity at 7 wk. In accordance with the reported reduction in Ca2+ transient amplitude in cardiomyocytes from SERCA2 KO mice, work-independent MVo2 was decreased due to a reduced energy cost of excitation-contraction coupling. As these hearts also showed a marked impairment in the efficiency of chemomechanical energy transduction (contractile efficiency, i.e, work-dependent MVo2), hearts from SERCA2 KO mice were found to be mechanically inefficient. This ex vivo evaluation of mechanical and energetic function in hearts from SERCA2 KO mice brings together findings from previous experimental and mathematical modeling-based studies and demonstrates that reduced SERCA2 activity not only leads to mechanical dysfunction but also to energetic dysfunction.

High intensity interval training alters substrate utilization and reduces oxygen consumption in the heart.

AIMS: although exercise training induces hypertrophy with improved contractile function, the effect of exercise on myocardial substrate metabolism and cardiac efficiency is less clear. High intensity training has been shown to produce more profound effects on cardiovascular function and aerobic capacity than isocaloric low and moderate intensity training. The aim of the present study was to explore metabolic and mechanoenergetic changes in the heart following endurance exercise training of both high and moderate intensity. METHODS AND RESULTS: C57BL/6J mice were subjected to 10 wk treadmill running, either high intensity interval training (HIT) or distance-matched moderate intensity training (MIT), where HIT led to a pronounced increase in maximal oxygen uptake. Although both modes of exercise were associated with a 10% increase in heart weight-to-body weight ratio, only HIT altered cardiac substrate utilization, as revealed by a 36% increase in glucose oxidation and a concomitant reduction in fatty acid oxidation. HIT also improved cardiac efficiency by decreasing work-independent myocardial oxygen consumption. In addition, it increased cardiac maximal mitochondrial respiratory capacity. CONCLUSION: This study shows that high intensity training is required for induction of changes in cardiac substrate utilization and energetics, which may contribute to the superior effects of high compared with moderate intensity training in terms of increasing aerobic capacity.

Rosiglitazone treatment improves cardiac efficiency in hearts from diabetic mice.

Isolated perfused hearts from type 2 diabetic (db/db) mice show impaired ventricular function, as well as altered cardiac metabolism. Assessment of the relationship between myocardial oxygen consumption (MVO(2)) and ventricular pressure-volume area (PVA) has also demonstrated reduced cardiac efficiency in db/db hearts. We hypothesized that lowering the plasma fatty acid supply and subsequent normalization of altered cardiac metabolism by chronic treatment with a peroxisome proliferator-activated receptor-gamma (PPARgamma) agonist will improve cardiac efficiency in db/db hearts. Rosiglitazone (23 mg/kg body weight/day) was administered as a food admixture to db/db mice for five weeks. Ventricular function and PVA were assessed using a miniaturized (1.4 Fr) pressure-volume catheter; MVO(2) was measured using a fibre-optic oxygen sensor. Chronic rosiglitazone treatment of db/db mice normalized plasma glucose and lipid concentrations, restored rates of cardiac glucose and fatty acid oxidation, and improved cardiac efficiency. The improved cardiac efficiency was due to a significant decrease in unloaded MVO(2), while contractile efficiency was unchanged. Rosiglitazone treatment also improved functional recovery after low-flow ischemia. In conclusion, the present study demonstrates that in vivo PPARgamma-treatment restores cardiac efficiency and improves ventricular function in perfused hearts from type 2 diabetic mice.

Reduced coronary reserve in response to short-term ischaemia and vasoactive drugs in ex vivo hearts from diabetic mice.

AIM: The aim of the present study was to compare the coronary flow (CF) reserve of ex vivo perfused hearts from type 2 diabetic (db/db) and non-diabetic (db/+) mice. METHODS: The hearts were perfused in the Langendorff mode with Krebs-Henseleit bicarbonate buffer (37 degrees C, pH 7.4) containing 11 mmol L(-1) glucose as energy substrate. The coronary reserve was measured in response to three different interventions: (1) administration of nitroprusside (a nitric oxide donor), (2) administration of adenosine and (3) production of reactive hyperaemia by short-term ischaemia. RESULTS: Basal CF was approximately 15% lower in diabetic when compared with non-diabetic hearts (2.1 +/- 0.1 vs. 2.6 +/- 0.2 mL min(-1)). The maximum increase in CF rate in response to sodium nitroprusside and adenosine was significantly lower in diabetic (0.6 +/- 0.1 and 0.9 +/- 0.1 mL min(-1) respectively) than in non-diabetic hearts (1.2 +/- 0.1 and 1.4 +/- 0.1 mL min(-1) respectively). Also, there was a clear difference in the rate of return to basal CF following short-term ischaemia between diabetic and non-diabetic hearts. Thus, basal tone was restored 1-2 min after the peak hyperaemic response in non-diabetic hearts, whereas it took approximately 5 min in diabetic hearts. CONCLUSION: These results show that basal CF, as well as the CF reserve, is impaired in hearts from type 2 diabetic mice. As diabetic and non-diabetic hearts were exposed to the same (maximum) concentrations of NO or adenosine, it is suggested that the lower coronary reserve in type 2 diabetic hearts is, in part, because of a defect in the intracellular pathways mediating smooth muscle relaxation.

Measurement of coronary flow reserve in isolated hearts from mice.

AIM: Langendorff-perfused murine hearts are increasingly used in cardiovascular research, but coronary cardiovascular haemodynamics vary considerably from one research group to another. The aim of this study was to establish an isolated, retrogradely perfused mouse heart preparation for the simultaneous measurement of left ventricular haemodynamics and of coronary flow (CF). METHODS: Heart rate was controlled by right atrial pacing (480 beats min(-1)) and heart temperature was kept constant. Accurate flow values of <0.5 mL min(-1) could be determined, and this methodology was then used to study the stability of this preparation, as well as coronary response to vasoactive drugs and to short-term ischaemia. RESULTS: The CF and maximum systolic pressure were well maintained over a 2-h perfusion period, both showing a 10% decline per hour. Sodium-nitroprusside (endothelium-independent) and adenosine (endothelium-dependent) increased CF relatively modest (30-50% above baseline values). Short-term no-flow ischaemia caused a transient 40-50% increase in CF on reperfusion. Peak reflow occurred approximately 15 s after start of reperfusion and flow returned to baseline during the following 1-2 min. Increased coronary blood flow following infusion of vasoactive drugs (nitroprusside or adenosine) or short-term ischaemia were associated with minor changes in ventricular pressure development. CONCLUSIONS: Blood flow and haemodynamics can readily be determined in this isolated perfused mouse heart model, but CF reserve is relatively small, compared with blood-perfused organs.

Glucose-insulin-potassium reduces infarct size when administered during reperfusion.

Coronary reperfusion improves ventricular function and survival after infarction, but the metabolic conditions at this time may not be optimal to protect the heart. The objective of this study was to evaluate if metabolic support with glucose-insulin-potassium (GIK) administered at the time of coronary reperfusion could elicit the same cardioprotection as GIK infusion during the entire ischemia/reperfusion period. Three groups of anesthetized, open-chest rats were subjected to 30 minutes of regional ischemia and 180 minutes of reperfusion. Groups 1 (controls) and 2 (GIK(IR)) received saline or GIK, respectively, throughout the whole experimental period, whereas a third group (GIK(R)) received GIK from the onset of reperfusion only. Infarct size was significantly reduced in the GIK-treated groups, compared with controls (GIK(IR) 44 +/- 5% and GIK(R) 45 +/- 5% vs. control 66 +/- 4%; P < 0.05). Postischemic recovery of cardiac function improved when GIK was only administered during the reperfusion phase. Furthermore, infusion of GIK resulted in reduced plasma concentrations of free fatty acids and increased plasma glucose (both P < 0.05) compared with controls. This study demonstrates that glucose-insulin-potassium administration at the onset of the postischemic reperfusion period is as cardioprotective as administration of GIK during the entire ischemia/reperfusion period.

Different tolerance to hypothermia and rewarming of isolated rat and guinea pig hearts.

We examined the effect of hypothermia and rewarming on myocardial function and calcium control in Langendorff-perfused hearts from rat and guinea pig. Both rat and guinea pig hearts demonstrated a rise in myocardial calcium ([Ca]total) in response to hypothermic perfusion (40 min, 10 degrees C), which was accompanied by an increase in left ventricular end diastolic pressure (LVEDP). The elevation in [Ca]total was severalfold higher in guinea pig than in rat hearts, reaching 12.9 +/- 0.8 and 3.1 +/- 0.6 micromol.g dry wt-1, respectively. The rise in LVEDP, however, was comparable in the two species: 62.5 +/- 2.5 (guinea pig) and 52.5 +/- 5.1 mm Hg (rat). Following rewarming, [Ca]total remained elevated in guinea pig, whereas a moderate decline in [Ca]total was observed in the rat (13.6 +/- 1.9 and 2.2 +/- 0.3 micromol.g dry wt-1, respectively). Posthypothermic values of LVEDP were also significantly higher in guinea pig compared to rat hearts (42.5 +/- 6.8 vs 20.5 +/- 5.1 mm Hg, P < 0.027). Furthermore, whereas rat hearts demonstrated a 78 +/- 7% recovery of left ventricular developed pressure, there was only a 15 +/- 7% recovery in guinea pig hearts. Measurements of tissue levels of high energy phosphates and glycogen utilization indicated a higher metabolic requirement in guinea pig than in rat hearts in order to oppose the hypothermia-induced calcium load. Thus, we conclude that isolated guinea pig hearts are more sensitive to a hypothermic insult than rat hearts.

The role of glycolysis in myocardial calcium control.

Because glycolysis is thought to be important for maintenance of cellular ion homeostasis, the aim of the present study was to examine the role of glycolysis in the control of cytosolic calcium ([Ca2+]i) and cell shortening during conditions of increased calcium influx. Thus, [Ca2+]i and unloaded cell shortening were measured in fura-2/AM loaded rat ventricular myocytes. All cells were superfused with Tyrode's solution containing glucose and pyruvate (to preserve oxidative metabolism), and glycolysis was inhibited by iodoacetate (IAA, 100 microM). Calcium influx was increased, secondary to an increase in intracellular sodium, by addition of veratrine (1 microgram/ml), or directly by either elevating [Ca2+]o from 2 to 5 mM or by exposing the cells to isoproterenol (1 to 100 nm). Veratrine exposure caused a time-dependent increase in both diastolic and systolic [Ca2+]i that resulted in cellular calcium overload and hypercontraction. The rate of increase in [Ca2+]i was more rapid in IAA-treated than in untreated myocytes, leading to a 13+/-3 v 5+/-2% increase (P<0.05) in diastolic [Ca2+]i after 5 min of exposure. The corresponding increases in systolic [Ca2+]i were 43+/-6 and 24+/-5% (P<0.05). Elevated [Ca2+]o resulted in increased [Ca2+]i transient amplitudes and cell shortening. These responses were each attenuated by inhibiting glycolysis, so that the increase was 38+/-5 v 68+/-9% ([Ca2+]i transient amplitude, P<0.05) and 41+/-11 v 91+/-18% (cell shortening, P<0.05). Inhibition of glycolysis did not, however, affect the increase in calcium transient or cell shortening during addition of isoproterenol. We conclude that glycolysis plays an essential role in the maintenance of intracellular calcium homeostasis during severe calcium overload. Glycolysis was also essential for signalling the inotropic effect that accompanied elevation in extracellular calcium, while the changes in intracellular calcium following administration of isoproterenol were not influenced by glycolysis in the present model.

Pyruvate reverses fatty-acid-induced depression of ventricular function and calcium overload after hypothermia in guinea pig hearts.

OBJECTIVE: High levels of free fatty acids have been shown to impair mechanical recovery and calcium homeostasis of isolated rat hearts following hypothermic perfusion. The objective of the present study was to investigate whether inhibition of fatty acid oxidation through activation of pyruvate dehydrogenase by millimolar concentrations of pyruvate could influence functional recovery and Ca2+ homeostasis after a hypothermic insult. METHODS: Ventricular function and myocardial calcium ([Ca]total) were measured in 3 different groups of Langendorff-perfused guinea pig hearts exposed to 40 min hypothermic (15 degrees C) perfusion, followed by 30 min rewarming at 37 degrees C. The hearts were perfused with either 11.1 mM glucose (G), glucose and 1.2 mM palmitate (GP), or glucose, palmitate and 5 mM pyruvate (GPP) as energy substrates. RESULTS: All groups showed marked elevations in [Ca]total during hypothermia (from 0.6-0.7 mumol.g dry wt-1 to 9.3-12.2 mumol.g dry wt-1 at 40 min hypothermia, P < 0.05), associated with a pronounced increase in left ventricular end-diastolic pressure (LVEDP from 0-2 to 50-60 mmHg). Following rewarming, GP-perfused hearts showed significantly lower recovery of mechanical function compared to both G- and GPP-perfused hearts (% recovery of left ventricular developed pressure: 27 +/- 8 vs. 62 +/- 3 and 62 +/- 8%, respectively, P < 0.05). The reduced mechanical recovery of GP-perfused hearts was associated with elevated [Ca]total. In separate experiments we found that addition of 1.2 mM palmitate reduced glucose oxidation ([14C]glucose) from 1.77 +/- 0.28 mumol.min-1.g dry wt-1 (G-perfused hearts) to 0.15 +/- 0.04 mumol.min-1.g dry wt-1 (GP-perfused hearts, P < 0.05), implying that fatty acids had become the major substrate for oxidative phosphorylation. Fatty acid oxidation was, however, less pronounced after further addition of 5 mM pyruvate. Thus, palmitate oxidation ([3H]palmitate) was more than 40% lower in GPP-perfused than in GP-perfused hearts (0.83 +/- 0.22 vs. 1.41 +/- 0.12 mumol.min-1.g dry wt-1, P < 0.05). CONCLUSIONS: The present results demonstrate impaired ventricular function and calcium homeostasis after hypothermia in guinea pig hearts perfused with fatty acids in addition to glucose, as compared to hearts perfused with glucose alone. Furthermore, we show that these unfavourable effects of fatty acids can be overcome by an exogenous supply of pyruvate.

Stimulation of carbohydrate metabolism reduces hypothermia-induced calcium load in fatty acid-perfused rat hearts.

In the present study we examined the impact of glycolysis and glucose oxidation on myocardial calcium control and mechanical function of fatty acid-perfused rat hearts subjected to hypothermia rewarming. One group (control) was given glucose (11.1 mM) and palmitate (1.2 mM) as energy substrates. In a second group glycolysis was inhibited by iodoacetate (IAA, 100 microM) and replacement of glucose with pyruvate (5 mM), whereas in the third group glucose oxidation was stimulated by administration of dichloroacetate (DCA, 1 mM) and insulin (500 microU/ml). All groups showed a rise in myocardial calcium ([Ca]total in response to hypothermia (10 degrees C). However, [Ca]total was significantly lower both in IAA- and DCA-treated hearts, as compared to controls (2.20 +/- 0.22 and 2.94 +/- 0.20 v 3.83 +/- 0.29 nmol/mg dry wt., P < 0.025). The reduced calcium load in the treated hearts was correlated with higher levels of high energy phosphates. Following rewarming control and DCA-treated hearts still showed elevated [Ca]total, whereas IAA-treated hearts [Ca]total was not different from the pre-hypothermic value. All groups showed a reduction in cardiac output following rewarming. Furthermore, the control group, in contrast to both IAA- and DCA-treated hearts, showed a significant reduction in systolic pressure. These results show that hypothermia-induced calcium uptake in glucose and fatty acid-perfused rat hearts was reduced by two different metabolic approaches: (1) inhibition of glycolysis by IAA while simultaneously by-passing the glycolytic pathway by exogenous pyruvate: and (2) stimulation of glucose oxidation by DCA. Thus, glycolytic ATP is not an essential regulator of sarcolemmal calcium transport under the present experimental conditions. Instead, we suggest that a change in oxidative substrate utilization in favour of carbohydrates may improve myocardial calcium homeostasis during hypothermia and rewarming.

Effects of fatty acids on myocardial calcium control during hypothermic perfusion.

Although hypothermia is regarded as providing protection of the myocardium during cardiac operations, rapid cooling of the myocardium in the nonarrested state may have detrimental effects on the function of the myocardial cell membrane as a permeability barrier. We therefore measured total cellular calcium in isolated working rat hearts, receiving either glucose (11.1 mmol/L) or glucose plus palmitate (1.2 mmol/L), before, during, and after a 40-minute hypothermic arrest (10 degrees C, Langendorff perfusion). In both groups a rise in total cellular calcium, measured by 45Ca2+ technique, was observed during hypothermia, followed by a decline on rewarming. However, the rise in total cellular calcium during hypothermia was significantly (p < 0.05) higher in hearts perfused with palmitate (from 1.0 +/- 0.2 to 3.5 +/- 0.2 nmol/mg dry weight) compared with that in glucose-perfused hearts (from 1.1 +/- 0.13 to 2.6 +/- 0.2 nmol/mg dry weight). Palmitate-perfused, but not glucose-perfused, hearts showed arrhythmias and delayed pressure development 1 to 2 minutes after rewarming. In addition cardiac output of these hearts was significantly lower (p < 0.025) than that of glucose-perfused hearts 5 to 10 minutes after rewarming. These data show that hypothermia per se causes a net calcium uptake in isolated rat hearts and that this effect is aggravated by high concentrations of fatty acids. Thus the impaired recovery of myocardial function in palmitate-perfused hearts can possibly be related to a distorted calcium handling.