Terje S. Larsen

Activation of a HIF1alpha-PPARgamma axis underlies the integration of glycolytic and lipid anabolic pathways in pathologic cardiac hypertrophy

Development of cardiac hypertrophy and progression to heart failure entails profound changes in myocardial metabolism, characterized by a switch from fatty acid utilization to glycolysis and lipid accumulation. We report that hypoxia-inducible factor (HIF)1alpha and PPARgamma, key mediators of glycolysis and lipid anabolism, respectively, are jointly upregulated in hypertrophic cardiomyopathy and cooperate to mediate key changes in cardiac metabolism. In response to pathologic stress, HIF1alpha activates glycolytic genes and PPARgamma, whose product, in turn, activates fatty acid uptake and glycerolipid biosynthesis genes. These changes result in increased glycolytic flux and glucose-to-lipid conversion via the glycerol-3-phosphate pathway, apoptosis, and contractile dysfunction. Ventricular deletion of Hif1alpha in mice prevents hypertrophy-induced PPARgamma activation, the consequent metabolic reprogramming, and contractile dysfunction. We propose a model in which activation of the HIF1alpha-PPARgamma axis by pathologic stress underlies key changes in cell metabolism that are characteristic of and contribute to common forms of heart disease.

Interval Training Normalizes Cardiomyocyte Function, Diastolic Ca2+ Control, and SR Ca2+ Release Synchronicity in a Mouse Model of Diabetic Cardiomyopathy

Rationale: In the present study we explored the mechanisms behind excitation–contraction (EC) coupling defects in cardiomyocytes from mice with type-2 diabetes (db/db). Objective: We determined whether 13 weeks of aerobic interval training could restore cardiomyocyte Ca2+ cycling and EC coupling. Methods and Results: Reduced contractility in cardiomyocytes isolated from sedentary db/db was associated with increased diastolic sarcoplasmic reticulum (SR)-Ca2+ leak, reduced synchrony of Ca2+ release, reduced transverse (T)-tubule density, and lower peak systolic and diastolic Ca2+ and caffeine-induced Ca2+ release. Additionally, the rate of SR Ca2+ ATPase–mediated Ca2+ uptake during diastole was reduced, whereas a faster recovery from caffeine-induced Ca2+ release indicated increased Na+/Ca2+-exchanger activity. The increased SR-Ca2+ leak was attributed to increased Ca2+-calmodulin–dependent protein kinase (CaMKII&dgr;) phosphorylation, supported by the normalization of SR-Ca2+ leak on inhibition of CaMKII&dgr; (AIP). Exercise training restored contractile function associated with restored SR Ca2+ release synchronicity, T-tubule density, twitch Ca2+ amplitude, SR Ca2+ ATPase and Na+/Ca2+-exchanger activities, and SR-Ca2+ leak. The latter was associated with reduced phosphorylation of cytosolic CaMKII&dgr;. Despite normal contractile function and Ca2+ handling after the training period, phospholamban was hyperphosphorylated at Serine-16. Protein kinase A inhibition (H-89) in cardiomyocytes from the exercised db/db group abolished the differences in SR-Ca2+ load when compared with the sedentary db/db mice. EC coupling changes were observed without changes in serum insulin or glucose levels, suggesting that the exercise training–induced effects are not via normalization of the diabetic condition. Conclusions: These data demonstrate that aerobic interval training almost completely restored the contractile function of the diabetic cardiomyocyte to levels close to sedentary wild type.

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 (GIKIR) received saline or GIK, respectively, throughout the whole experimental period, whereas a third group (GIKR) received GIK from the onset of reperfusion only. Infarct size was significantly reduced in the GIK-treated groups, compared with controls (GIKIR 44 ± 5% and GIKR 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.

Glucose and fatty acid metabolism in the isolated working mouse heart

Although isolated perfused mouse heart models have been developed to study mechanical function, energy substrate metabolism has not been examined despite the expectation that the metabolic rate for a heart from a small mammal should be increased. Consequently, glucose utilization (glycolysis, oxidation) and fatty acid oxidation were measured in isolated working mouse hearts perfused with radiolabeled substrates, 11 mM glucose, and either 0.4 or 1.2 mM palmitate. Heart rate, coronary flow, cardiac output, and cardiac power did not differ significantly between hearts perfused at 0.4 or 1.2 mM palmitate. Although the absolute values obtained for glycolysis and glucose oxidation and fatty acid oxidation are significantly higher than those reported for rat hearts, the pattern of substrate metabolism in mouse hearts is similar to that observed in hearts from larger mammals. The metabolism of mouse hearts can be altered by fatty acid concentration in a manner similar to that observed in larger animals; increasing palmitate concentration altered the balance of substrate metabolism to increase overall energy derived from fatty acids from 64 to 92%.

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

Abstract 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 (MVO2) 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-γ (PPARγ) 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; MVO2 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 MVO2, while contractile efficiency was unchanged. Rosiglitazone treatment also improved functional recovery after low-flow ischemia. In conclusion, the present study demonstrates that in vivo PPARγ-treatment restores cardiac efficiency and improves ventricular function in perfused hearts from type 2 diabetic mice.

Triacylglycerol metabolism in hypoxic, glucose-deprived rat cardiomyocytes

We have recently shown that a triacylglycerol (TG)-fatty acid cycle is operating in rat myocardial cells incubated in a hypoxic, glucose-containing incubation medium (Myrmel et al., 1991a). In the present study we investigated whether this cycle occurred in hypoxic, glucose-deprived myocytes, and whether high TG levels would increase TG-fatty acid cycling and thereby energy consumption. Myocytes with elevated contents of TG were obtained from the hearts of streptozotocin-induced diabetic rats (diabetic myocytes) and from normal rat myocytes prepared in the presence of oleic acid (TG-loaded myocytes). The TG content of diabetic and TG-loaded myocytes prior to hypoxic incubations was more than two times higher (P < 0.05) than that of their respective controls (123.8 +/- 20.6 and 125.3 +/- 12.7 vs 56.8 +/- 6.0 and 58.6 +/- 9.4 nmol/10(6) cells, mean +/- S.E., n = 7). Only diabetic and TG-loaded myocytes expressed marked reductions in TG content during glucose free incubations. There were no differences in TG-fatty acid cycling between the various myocyte groups, calculated as the difference between glycerol output and the concomitant decrease in TG (range: 36.7 +/- 8.1- 48.9 +/- 9.7 nmol TG/10(6) cells.2h). Apparently, the cycle was continuous throughout the whole incubation period despite falling ATP levels, contracture (rounding up) of myocytes, as well as cessation of glycogenolysis after about 40 min incubation. The cellular content of glycerol-3-phosphate, known to control TG-fatty acid cycling, increased continuously and to the same extent throughout the 2 h incubation period. Futile energy consumption associated with TG-fatty acid cycling, amounted to approximately 30% of total cellular energy consumption for the whole incubation period. In conclusion, hypoxic glucose deprived rat myocytes show TG-fatty-acid cycling, even after cessation of glycogenolysis. The extent of cycling, and thus the energy cost associated with it, was not influenced by the initial level of TG in the myocytes. We propose that glycerol-3-phosphate needed to fuel the TG-fatty acid cycle after exhaustion of the glycolytic supply is derived from phospholipid degradation.

Cardiac peroxisome proliferator-activated receptor-α activation causes increased fatty acid oxidation, reducing efficiency and post-ischaemic functional loss

AIMS Myocardial fatty acid (FA) oxidation is regulated acutely by the FA supply and chronically at the transcriptional level owing to FA activation of peroxisome proliferator-activated receptor-alpha (PPARalpha). However, in vivo administration of PPARalpha ligands has not been shown to increase cardiac FA oxidation. In this study we have examined the cardiac response to in vivo administration of tetradecylthioacetic acid (TTA, 0.5% w/w added to the diet for 8 days), a PPAR agonist with primarily PPARalpha activity. METHODS AND RESULTS Despite the fact that TTA treatment decreased plasma concentrations of lipids [FA and triacylglycerols (TG)], hearts from TTA-treated mice showed increased mRNA expression of PPARalpha target genes. Cardiac substrate utilization, ventricular function, cardiac efficiency, and susceptibility to ischaemia-reperfusion were examined in isolated perfused hearts. In accordance with the mRNA changes, myocardial FA oxidation was increased 2.5-fold with a concomitant reduction in glucose oxidation. This increase in FA oxidation was abolished in PPARalpha-null mice. Thus, it appears that the metabolic effects of TTA on the heart must be owing to a direct stimulatory effect on cardiac PPARalpha. Hearts from TTA-treated mice also showed a marked reduction in cardiac efficiency (because of a two-fold increase in unloaded myocardial oxygen consumption) and decreased recovery of ventricular contractile function following low-flow ischaemia. CONCLUSION This study for the first time observed that in vivo administration of a synthetic PPARalpha ligand elevated FA oxidation, an effect that was also associated with decreased cardiac efficiency and reduced post-ischaemic functional recovery.

High- and Moderate-Intensity Training Normalizes Ventricular Function and Mechanoenergetics in Mice With Diet-Induced Obesity

Although exercise reduces several cardiovascular risk factors associated with obesity/diabetes, the metabolic effects of exercise on the heart are not well-known. This study was designed to investigate whether high-intensity interval training (HIT) is superior to moderate-intensity training (MIT) in counteracting obesity-induced impairment of left ventricular (LV) mechanoenergetics and function. C57BL/6J mice with diet-induced obesity (DIO mice) displaying a cardiac phenotype with altered substrate utilization and impaired mechanoenergetics were subjected to a sedentary lifestyle or 8–10 weeks of isocaloric HIT or MIT. Although both modes of exercise equally improved aerobic capacity and reduced obesity, only HIT improved glucose tolerance. Hearts from sedentary DIO mice developed concentric LV remodeling with diastolic and systolic dysfunction, which was prevented by both HIT and MIT. Both modes of exercise also normalized LV mechanical efficiency and mechanoenergetics. These changes were associated with altered myocardial substrate utilization and improved mitochondrial capacity and efficiency, as well as reduced oxidative stress, fibrosis, and intracellular matrix metalloproteinase 2 content. As both modes of exercise equally ameliorated the development of diabetic cardiomyopathy by preventing LV remodeling and mechanoenergetic impairment, this study advocates the therapeutic potential of physical activity in obesity-related cardiac disorders.

Increased O2 cost of basal metabolism and excitation-contraction coupling in hearts from type 2 diabetic mice

We have reported previously that hearts from type 2 diabetic (db/db) mice show decreased cardiac efficiency due to increased work-independent myocardial O(2) consumption (unloaded MVo(2)), indicating higher O(2) use for nonmechanical processes such as basal metabolism (MVo(2)(BM)) and excitation-contraction coupling (MVo(2)(ECC)). Although alterations in cardiac metabolism and/or Ca(2+) handling may contribute to increased energy expenditure in diabetic hearts, direct measurements of the O(2) cost for these individual processes have not been determined. In this study, we 1) validate a procedure for measuring unloaded MVo(2) directly (MVo(2)(unloaded)) and for determining MVo(2)(BM) and MVo(2)(ECC) separately in isolated perfused mouse hearts and 2) determine O(2) cost for these processes in hearts from db/db mice. Unloaded MVo(2), extrapolated from the relationship between cardiac work (measured as pressure-volume area, PVA) and MVo(2), was found to correspond with MVo(2) measured directly in unloaded retrograde perfused hearts (MVo(2)(unloaded)). MVo(2) in K(+)-arrested hearts was defined as MVo(2)(BM); the difference between MVo(2)(unloaded) and MVo(2)(BM) represented MVo(2)(ECC). This procedure was validated by demonstrating that elevations in perfusate fatty acid (FA) and/or Ca(2+) concentrations resulted in changes in either MVo(2)(BM) and/or MVo(2)(ECC). The higher MVo(2)(unloaded) in db/db mice was due to both a higher MVo(2)(BM) and MVo(2)(ECC). Elevation of glucose and insulin decreased FA oxidation and reduced both MVo(2)(unloaded) and MVo(2)(BM). In conclusion, this study provides direct evidence that MVo(2)(BM) and MVo(2)(ECC) are elevated in diabetes and that acute metabolic interventions can have a therapeutic benefit in diabetic hearts due to a MVo(2)-lowering effect.