Myocardial Energy Homeostasis Research Articles

Age-Related Gut Microbiota Transplantation Disrupts Myocardial Energy Homeostasis and Induces Oxidative Damage

BackgroundAging-related energy homeostasis significantly affects normal heart function and disease development. The relationship between the gut microbiota and host energy metabolism has been well established. However, the influence of an aged microbiota on energy metabolism in the heart remains unclear. ObjectiveThe objective of this was to explore the effects of age-related microbiota composition on energy metabolism in the heart. MethodsIn this study, we used the fecal microbiota transplantation (FMT) method. The fecal microbiota from young (2–3 mo) and aged (18–22 mo) donor mice were transplanted into separate groups of young (2–3 mo) recipient mice. The analysis utilized whole 16S rRNA sequencing and plasma metabolomics to assess changes in the gut microbiota composition and metabolic potential. Energy changes were monitored by performing an oral glucose tolerance test, biochemical testing, body composition analysis, and metabolic cage measurements. Metabolic markers and markers of DNA damage were assessed in heart samples. ResultsFMT of an aged microbiota changed the composition of the recipient’s gut microbiota, leading to an elevated Firmicutes-to-Bacteroidetes ratio. It also affected overall energy metabolism, resulting in elevated plasma glucose concentrations, impaired glucose tolerance, and epididymal fat accumulation. Notably, FMT of an aged microbiota increased the heart weight and promoted cardiac hypertrophy. Furthermore, there were significant associations between heart weight and cardiac hypertrophy indicators, epididymal fat weight, and fasting glucose concentrations. Mechanistically, FMT of an aged microbiota modulated the glucose metabolic pathway and induced myocardial oxidative damage. ConclusionsOur findings suggested that an aged microbiota can modulate metabolism and induce cardiac injury. This highlights the possible role of the gut microbiota in age-related metabolic disorders and cardiac dysfunction.

Targeting Mitochondrial Metabolism to Save the Failing Heart.

Despite considerable progress in treating cardiac disorders, the prevalence of heart failure (HF) keeps growing, making it a global medical and economic burden. HF is characterized by profound metabolic remodeling, which mostly occurs in the mitochondria. Although it is well established that the failing heart is energy-deficient, the role of mitochondria in the pathophysiology of HF extends beyond the energetic aspects. Changes in substrate oxidation, tricarboxylic acid cycle and the respiratory chain have emerged as key players in regulating myocardial energy homeostasis, Ca2+ handling, oxidative stress and inflammation. This work aims to highlight metabolic alterations in the mitochondria and their far-reaching effects on the pathophysiology of HF. Based on this knowledge, we will also discuss potential metabolic approaches to improve cardiac function.

Abstract 12368: Results From the DoPING-HFpEF Trial: A Double Blind, Placebo-Controlled Randomized Cross-Over Trial Investigating Trimetazidine in Heart Failure With Preserved Ejection Fraction

Introduction: Due to mitochondrial dysfunction, cardiac energy homeostasis is compromised in heart failure with preserved ejection fraction. As left ventricular relaxation is an active and energy consuming process there is a clear relationship between the impaired cardiac metabolism and diastolic dysfunction. Here, we investigate whether trimetazidine, a fatty acid oxidation inhibitor, can improve cardiac energy homeostasis and consequently improve diastolic function. Methods: This was a single-center, double-blind, placebo-controlled randomized cross-over trial consisting of two treatment periods of three months with a 2 week washout period in between. Patients (N=25) were treated with 20mg trimetazidine or placebo t.i.d. or b.i.d. (based on kidney function). The primary endpoint was change in pulmonary capillary wedge pressure (PCWP) measured with right heart catheterization at multiple stages of exercise. Secondary endpoint was change in phosphocreatine (PCr)/adenosine triphosphate (ATP) ratio, an index of the myocardial energy status, measured with phosphorus-31 magnetic resonance (MR) spectroscopy. Results: All included patients had invasively proven heart failure with preserved ejection fraction. There was no effect on the primary outcome PCWP at multiple levels of exercise ( P =0.60). Myocardial PCr/ATP in the trimetazidine arm was similar to placebo ( P =0.08). There was no change by trimetazidine in the exploratory parameters 6-minute walking distance, NT-proBNP, overall quality of life, or other parameters for diastolic function measured with echocardiography and cardiac MR, or additional metabolic parameters. Trimetazidine plasma level are currently being assessed and will be available at the moment of presentation. Conclusion: Trimetazidine did not improve diastolic function or myocardial energy homeostasis in patients with HFpEF. Disclosure of unlabeled use: Trimetazidine was not labeled for use in HFpEF.

Trimetazidine in heart failure with preserved ejection fracton: a randomized, double-blind cross-over trial

Abstract Introduction Impaired myocardial mitochondrial function plays an import role in the pathophysiology of heart failure with preserved ejection fraction (HFpEF). Left ventricular relaxation has a high energy demand, and there is evidence indicative of a causal relationship between observed impaired energy homeostasis and diastolic dysfunction. Improvement of mitochondrial function with metabolism-modulating drugs may be a promising novel therapeutic approach in HFpEF. Trimetazidine – a fatty acid oxidation inhibitor – shifts mitochondrial metabolism towards glucose oxidation, which results in higher mitochondrial oxygen efficiency. In this study we investigated whether trimetazidine improves diastolic function during exercise in HFpEF by improving the myocardial energy homeostasis. Methods The DoPING-HFpEF trial was a phase II single-center, double-blind, placebo-controlled, randomized cross-over trial. The study consisted of two treatment periods of three months separated by a 2-week wash-out period (Figure 1). Patients were treated with placebo or trimetazidine three times a day (or twice daily in case of an impaired kidney function). The primary endpoint was change in pulmonary capillary wedge pressure (PCWP) measured with right heart catheterization at multiple stages of exercise. Secondary endpoint was change in phosphocreatine (PCr)/adenosine triphosphate (ATP) ratio, an index of the myocardial energy status, measured with phosphorus-31 magnetic resonance (MR) spectroscopy. Additional exploratory endpoints were 6-minute-walking-distance, diastolic and systolic parameters measured with echocardiography or cardiac MR, NT-proBNP levels, and quality of life. Results Twenty-five HFpEF patients were included and completed the trial, 80% of which were included based on previously established elevated (exercise) PCWP, and 20% were included based on diastolic dysfunction grade ≥II on echocardiography and elevated NT-proBNP levels. There was no effect on the primary outcome PCWP at multiple levels of exercise, with an average change in PCWP of 0±4 (SD) mmHg (Figure 2A, P=0.97). Myocardial PCr/ATP in the trimetazidine arm was similar to placebo (Figure 2B, P=0.08). There was no change by trimetazidine in the exploratory parameters 6-minute walking distance, NT-proBNP, overall quality of life, or other parameters for diastolic function measured with echocardiography and cardiac MR. There was no indication of period or cross over effect. Conclusion Trimetazidine did not improve diastolic function or myocardial energy homeostasis in patients with HFpEF. Funding Acknowledgement Type of funding sources: Foundation. Main funding source(s): Dutch Heart Foundation (DHF) and “Out-of-the-Box” grant from the Amsterdam Cardiovascular Sciences (ACS) Institute, Amsterdam, The Netherlands.

A phase 2a trial investigating ninerafaxstat – a novel cardiac mitotrope for the treatment of diabetic cardiomyopathy (IMPROVE-DiCE)

Abstract Background Type 2 diabetes (T2D) is a significant, independent contributor to the development of heart failure (HF), driven by energetic, metabolic, structural and functional myocardial changes. The T2D heart is characterised by over-reliance on fatty acid utilisation, shows reduced glucose oxidation and inhibition of pyruvate dehydrogenase (PDH). This results in a diminished myocardial energy reserve and blunted adenosine triphosphate (ATP) generation as well as cardiac steatosis, contributing to lipotoxicity, and diastolic dysfunction. Purpose We assessed the effects of ninerafaxstat – a novel cardiac mitotrope designed to shift myocardial substrate utilisation in favour of glucose and thus, restore myocardial energy homeostasis – on cardiac metabolism & diastolic function in patients with T2D and obesity. Methods In this open-label, mechanistic phase 2a trial, we enrolled 21 patients with T2D & obesity (HbA1c median 7.0% (IQR 6.6, 7.8), weight 97kg (90, 102)) and subsequently treated them with 200mg ninerafaxstat twice daily for 4 or 8 weeks; (Fig. 1). Cardiac metabolism and function were assessed pre- & post-treatment using magnetic resonance imaging (MRI), 31P-, 1H- and, in a subset of n=9, hyperpolarized [1-13C]pyruvate MR spectroscopy. Results T2D patients at baseline presented with impaired myocardial energetics with a markedly reduced PCr/ATP (1.6 [1.4, 2.1]), myocardial steatosis (myocardial triglycerides 2.2% [1.5, 3.2]) left ventricular (LV) hypertrophy (LV mass 130g [98, 152]), and diastolic dysfunction (peak diastolic strain rate 0.86 1/s [0.82, 1.06]). Ninerafaxstat significantly improved myocardial energetics (PCr/ATP median by 32%, p<0.01), reduced myocardial triglyceride content (by 34%, p=0.03) and improved LV diastolic function (peak circumferential diastolic strain rate by 10%, peak LV filling rate by 11%, both p<0.05) (Fig. 2). PDH flux was increased in 7/9 subjects (mean 45%, p=0.08), consistent with improved glucose utilisation. Left ventricular volumes and mass, heart rate and blood pressure remained unchanged. Conclusions Treatment with ninerafaxstat significantly improves myocardial energetics, reduces myocardial steatosis and improves diastolic function in patients with T2D and obesity. Funding Acknowledgement Type of funding sources: Private company. Main funding source(s): Imbria Pharmaaceuticals

Breviscapine remodels myocardial glucose and lipid metabolism by regulating serotonin to alleviate doxorubicin-induced cardiotoxicity.

Aims: The broad-spectrum anticancer drug doxorubicin (Dox) is associated with a high incidence of cardiotoxicity, which severely affects the clinical application of the drug and patients’ quality of life. Here, we assess how Dox modulates myocardial energy and contractile function and this could aid the development of relevant protective drugs. Methods: Mice were subjected to doxorubicin and breviscapine treatment. Cardiac function was analyzed by echocardiography, and Dox-mediated signaling was assessed in isolated cardiomyocytes. The dual cardio-protective and anti-tumor actions of breviscapine were assessed in mouse breast tumor models. Results: We found that Dox disrupts myocardial energy metabolism by decreasing glucose uptake and increasing fatty acid oxidation, leading to a decrease in ATP production rate, an increase in oxygen consumption rate and oxidative stress, and further energy deficits to enhance myocardial fatty acid uptake and drive DIC development. Interestingly, breviscapine increases the efficiency of ATP production and restores myocardial energy homeostasis by modulating the serotonin-glucose-myocardial PI3K/AKT loop, increasing glucose utilization by the heart and reducing lipid oxidation. It enhances mitochondrial autophagy via the PINK1/Parkin pathway, eliminates damaged mitochondrial accumulation caused by Dox, reduces the degree of cardiac fibrosis and inflammation, and restores cardiac micro-environmental homeostasis. Importantly, its low inflammation levels reduce myeloid immunosuppressive cell infiltration, and this effect is synergistic with the anti-tumor effect of Dox. Conclusion: Our findings suggest that disruption of the cardiac metabolic network by Dox is an important driver of its cardiotoxicity and that serotonin is an important regulator of myocardial glucose and lipid metabolism. Myocardial energy homeostasis and timely clearance of damaged mitochondria synergistically contribute to the prevention of anthracycline-induced cardiotoxicity and improve the efficiency of tumor treatment.

Animal Models of Dysregulated Cardiac Metabolism.

As a muscular pump that contracts incessantly throughout life, the heart must constantly generate cellular energy to support contractile function and fuel ionic pumps to maintain electrical homeostasis. Thus, mitochondrial metabolism of multiple metabolic substrates such as fatty acids, glucose, ketones, and lactate is essential to ensuring an uninterrupted supply of ATP. Multiple metabolic pathways converge to maintain myocardial energy homeostasis. The regulation of these cardiac metabolic pathways has been intensely studied for many decades. Rapid adaptation of these pathways is essential for mediating the myocardial adaptation to stress, and dysregulation of these pathways contributes to myocardial pathophysiology as occurs in heart failure and in metabolic disorders such as diabetes. The regulation of these pathways reflects the complex interactions of cell-specific regulatory pathways, neurohumoral signals, and changes in substrate availability in the circulation. Significant advances have been made in the ability to study metabolic regulation in the heart, and animal models have played a central role in contributing to this knowledge. This review will summarize metabolic pathways in the heart and describe their contribution to maintaining myocardial contractile function in health and disease. The review will summarize lessons learned from animal models with altered systemic metabolism and those in which specific metabolic regulatory pathways have been genetically altered within the heart. The relationship between intrinsic and extrinsic regulators of cardiac metabolism and the pathophysiology of heart failure and how these have been informed by animal models will be discussed.

Energy metabolism homeostasis in cardiovascular diseases.

Cardiovascular disease (CVD) is the leading cause of morbidity and mortality in the general population. Energy metabolism disturbance is one of the early abnormalities in CVDs, such as coronary heart disease, diabetic cardiomyopathy, and heart failure. To explore the role of myocardial energy homeostasis disturbance in CVDs, it is important to understand myocardial metabolism in the normal heart and their function in the complex pathophysiology of CVDs. In this article, we summarized lipid metabolism/lipotoxicity and glucose metabolism/insulin resistance in the heart, focused on the metabolic regulation during neonatal and ageing heart, proposed potential metabolic mechanisms for cardiac regeneration and degeneration. We provided an overview of emerging molecular network among cardiac proliferation, regeneration, and metabolic disturbance. These novel targets promise a new era for the treatment of CVDs.

Lycopene Regulates Dietary Dityrosine-Induced Mitochondrial-Lipid Homeostasis by Increasing Mitochondrial Complex Activity.

Dityrosine (DT), a marker of protein oxidation, is widely found in many high-protein foods. Dietary intake of DT induces myocardial oxidative stress injury and impairs energy metabolism. Lycopene is a common dietary supplement with antioxidant and mitochondrial-lipid homeostasis modulating abilities. This study aimed to examine the effects of lycopene on DT-induced disturbances in myocardial function and energy metabolism. Four-week-old C57BL/6J mice received intragastric administration of either tyrosine (420µg kg-1 BW), DT (420µg kg-1 BW), or lycopene at high (10mg kg-1 BW) and low (5mg kg-1 BW) doses for 35 days. Lycopene administration effectively reduced oxidative stress, cardiac fatty acid accumulation, and cardiac hypertrophy and improved mitochondrial performance in DT-induced mice. In vitro experiments in H9c2 cells showed that DT directly inhibited the activity of the respiratory chain complex, whereas oxidative phosphorylation and β-oxidation gene expression is upregulated. Lycopene enhanced the activity of the complexes and inhibited ROS production caused by compensatory regulation. Lycopene improves DT-mediated myocardial energy homeostasis disorder by promoting the activity of respiratory chain complexes I and IV and alleviates the accumulation of cardiac fatty acids and myocardial hypertrophy.

Subtle Role for Adenylate Kinase 1 in Maintaining Normal Basal Contractile Function and Metabolism in the Murine Heart.

AimsAdenylate kinase 1 (AK1) catalyses the reaction 2ADP ↔ ATP + AMP, extracting extra energy under metabolic stress and promoting energetic homeostasis. We hypothesised that increased AK1 activity would have negligible effects at rest, but protect against ischaemia/reperfusion (I/R) injury.Methods and ResultsCardiac-specific AK1 overexpressing mice (AK1-OE) had 31% higher AK1 activity (P = 0.009), with unchanged total creatine kinase and citrate synthase activities. Male AK1-OE exhibited mild in vivo dysfunction at baseline with lower LV pressure, impaired relaxation, and contractile reserve. LV weight was 19% higher in AK1-OE males due to higher tissue water content in the absence of hypertrophy or fibrosis. AK1-OE hearts had significantly raised creatine, unaltered total adenine nucleotides, and 20% higher AMP levels (P = 0.05), but AMP-activated protein kinase was not activated (P = 0.85). 1H-NMR revealed significant differences in LV metabolite levels compared to wild-type, with aspartate, tyrosine, sphingomyelin, cholesterol all elevated, whereas taurine and triglycerides were significantly lower. Ex vivo global no-flow I/R, caused four-of-seven AK1-OE hearts to develop terminal arrhythmia (cf. zero WT), yet surviving AK1-OE hearts had improved functional recovery. However, AK1-OE did not influence infarct size in vivo and arrhythmias were only observed ex vivo, probably as an artefact of adenine nucleotide loss during cannulation.ConclusionModest elevation of AK1 may improve functional recovery following I/R, but has unexpected impact on LV weight, function and metabolite levels under basal resting conditions, suggesting a more nuanced role for AK1 underpinning myocardial energy homeostasis and not just as a response to stress.

Human Cardiac 31P-MR Spectroscopy at 3 Tesla Cannot Detect Failing Myocardial Energy Homeostasis during Exercise.

Phosphorus-31 magnetic resonance spectroscopy (31P-MRS) is a unique non-invasive imaging modality for probing in vivo high-energy phosphate metabolism in the human heart. We investigated whether current 31P-MRS methodology would allow for clinical applications to detect exercise-induced changes in (patho-)physiological myocardial energy metabolism. Hereto, measurement variability and repeatability of three commonly used localized 31P-MRS methods [3D image-selected in vivo spectroscopy (ISIS) and 1D ISIS with 1D chemical shift imaging (CSI) oriented either perpendicular or parallel to the surface coil] to quantify the myocardial phosphocreatine (PCr) to adenosine triphosphate (ATP) ratio in healthy humans (n = 8) at rest were determined on a clinical 3 Tesla MR system. Numerical simulations of myocardial energy homeostasis in response to increased cardiac work rates were performed using a biophysical model of myocardial oxidative metabolism. Hypertrophic cardiomyopathy was modeled by either inefficient sarcomere ATP utilization or decreased mitochondrial ATP synthesis. The effect of creatine depletion on myocardial energy homeostasis was explored for both conditions. The mean in vivo myocardial PCr/ATP ratio measured with 3D ISIS was 1.57 ± 0.17 with a large repeatability coefficient of 40.4%. For 1D CSI in a 1D ISIS-selected slice perpendicular to the surface coil, the PCr/ATP ratio was 2.78 ± 0.50 (repeatability 42.5%). With 1D CSI in a 1D ISIS-selected slice parallel to the surface coil, the PCr/ATP ratio was 1.70 ± 0.56 (repeatability 43.7%). The model predicted a PCr/ATP ratio reduction of only 10% at the maximal cardiac work rate in normal myocardium. Hypertrophic cardiomyopathy led to lower PCr/ATP ratios for high cardiac work rates, which was exacerbated by creatine depletion. Simulations illustrated that when conducting cardiac 31P-MRS exercise stress testing with large measurement error margins, results obtained under pathophysiologic conditions may still lie well within the 95% confidence interval of normal myocardial PCr/ATP dynamics. Current measurement precision of localized 31P-MRS for quantification of the myocardial PCr/ATP ratio precludes the detection of the changes predicted by computational modeling. This hampers clinical employment of 31P-MRS for diagnostic testing and risk stratification, and warrants developments in cardiac 31P-MRS exercise stress testing methodology.

In vivo mouse myocardial (31)P MRS using three-dimensional image-selected in vivo spectroscopy (3D ISIS): technical considerations and biochemical validations.

(31)P MRS provides a unique non-invasive window into myocardial energy homeostasis. Mouse models of cardiac disease are widely used in preclinical studies, but the application of (31)P MRS in the in vivo mouse heart has been limited. The small-sized, fast-beating mouse heart imposes challenges regarding localized signal acquisition devoid of contamination with signal originating from surrounding tissues. Here, we report the implementation and validation of three-dimensional image-selected in vivo spectroscopy (3D ISIS) for localized (31)P MRS of the in vivo mouse heart at 9.4 T. Cardiac (31)P MR spectra were acquired in vivo in healthy mice (n = 9) and in transverse aortic constricted (TAC) mice (n = 8) using respiratory-gated, cardiac-triggered 3D ISIS. Localization and potential signal contamination were assessed with (31)P MRS experiments in the anterior myocardial wall, liver, skeletal muscle and blood. For healthy hearts, results were validated against ex vivo biochemical assays. Effects of isoflurane anesthesia were assessed by measuring in vivo hemodynamics and blood gases. The myocardial energy status, assessed via the phosphocreatine (PCr) to adenosine 5'-triphosphate (ATP) ratio, was approximately 25% lower in TAC mice compared with controls (0.76 ± 0.13 versus 1.00 ± 0.15; P < 0.01). Localization with one-dimensional (1D) ISIS resulted in two-fold higher PCr/ATP ratios than measured with 3D ISIS, because of the high PCr levels of chest skeletal muscle that contaminate the 1D ISIS measurements. Ex vivo determinations of the myocardial PCr/ATP ratio (0.94 ± 0.24; n = 8) confirmed the in vivo observations in control mice. Heart rate (497 ± 76 beats/min), mean arterial pressure (90 ± 3.3 mmHg) and blood oxygen saturation (96.2 ± 0.6%) during the experimental conditions of in vivo (31)P MRS were within the normal physiological range. Our results show that respiratory-gated, cardiac-triggered 3D ISIS allows for non-invasive assessments of in vivo mouse myocardial energy homeostasis with (31)P MRS under physiological conditions.

Chronic Hypoxia Enhances Expression and Activity of Mitochondrial Creatine Kinase and Hexokinase in the Rat Ventricular Myocardium

Background: Creatine kinase (CK) and hexokinase (HK) play a key role in myocardial energy homeostasis. We aimed to determine CK and HK expression and enzyme activity in the left (LV) and right (RV) ventricles of rats adapted for 3 weeks to normobaric hypoxia (10 % O₂) either continuously (CNH) or intermittently with 1-h or 16-h normoxic episode per day. Methods: The Real-Time RT-PCR, Western blot, and enzyme-coupled assays were used. In addition, the effect of CNH on the HK co-localization with mitochondria, which can inhibit apoptosis, was assessed using immunofluorescence techniques. Results: CK and HK activities increased in the LV during all hypoxic adaptations, which was consistent with elevated protein levels of mitochondrial mtCKs, cytosolic CKB, HK1, and HK2 isoforms. Enzyme activities also increased in the hypoxic RV, but only CKB protein was elevated. No effect of CNH on HK1 or HK2 co-localization with mitochondria was observed. Conclusion: Up-regulation of mtCKs and HK isoforms may stimulate the respiratory chain and help to maintain energy homeostasis of chronically hypoxic myocardium and prevent oxidative stress. In this way, CK and HK enzymes can possibly participate in the establishment of ischemia-resistant phenotype of chronically hypoxic hearts.

Peroxisome proliferator-activated receptor δ regulates mitofusin 2 expression in the heart

Mitofusin 2 (Mfn2) has been proposed as an important mitochondrial protein in maintaining mitochondrial network and bioenergetics. Mfn2 is highly expressed in the heart, but is downregulated in response to hypertrophic stimuli. However, little is known about how Mfn2's expression is regulated in cardiomyocytes. Here, we have investigated how Mfn2 expression in the heart responds to fasting condition and determined if Mfn2 is one of those PPARδ-selective target genes that are involved in myocardial energy metabolism. Fasting for 48 h in mice led to a robust increase of Mfn2 expression in the heart. On the other hand, cardiomyocyte-restricted PPARδ deficiency in mice led to substantially diminished cardiac expression of Mfn2 transcript and protein compared to that of controls. Fasting induced cardiac expression of Mfn2 was blunted in cardiomyocyte-restricted PPARδ deficient hearts. Moreover, PPARδ-selective ligand treatment in cultured cardiomyocytes induced elevated Mfn2 expression. A functional PPRE consensus sequence located at − 837 to − 817 bp upstream of the mouse Mfn2 promoter was identified and confirmed by Electrophoretic Mobility Shift Assays and Luciferase Promoter Reporter Assays. We conclude that Mfn2 is a PPARδ-selective target, which may play an important role in regulating myocardial energy homeostasis.

Targeted Deletion of Thioredoxin-Interacting Protein Regulates Cardiac Dysfunction in Response to Pressure Overload

Biomechanical overload induces cardiac hypertrophy and heart failure, and reactive oxygen species (ROS) play a role in both processes. Thioredoxin-Interacting Protein (Txnip) is encoded by a mechanically-regulated gene that controls cell growth and apoptosis in part through interaction with the endogenous dithiol antioxidant thioredoxin. Here we show that Txnip is a critical regulator of the cardiac response to pressure overload. We generated inducible cardiomyocyte-specific and systemic Txnip-null mice (Txnip-KO) using Flp/frt and Cre/loxP technologies. Compared with littermate controls, Txnip-KO hearts had attenuated cardiac hypertrophy and preserved left ventricular (LV) contractile reserve through 4 weeks of pressure overload; however, the beneficial effects were not sustained and Txnip deletion ultimately led to maladaptive LV remodeling at 8 weeks of pressure overload. Interestingly, these effects of Txnip deletion on cardiac performance were not accompanied by global changes in thioredoxin activity or ROS; instead, Txnip-KO hearts had a robust increase in myocardial glucose uptake. Thus, deletion of Txnip plays an unanticipated role in myocardial energy homeostasis rather than redox regulation. These results support the emerging concept that the function of Txnip is not as a simple thioredoxin inhibitor but as a metabolic control protein.

Adiponectin and its receptors are expressed in adult ventricular cardiomyocytes and upregulated by activation of peroxisome proliferator-activated receptor γ

Adiponectin is a protein hormone involved in maintaining energy homeostasis in metabolically active tissues. It enhances glucose and lipid metabolism via activation of AMP-dependent kinase (AMPK) in skeletal muscle and liver. Energy homeostasis is vital for the heart to work as a pump. In this study, we investigated whether adiponectin and its receptors are expressed in adult ventricular cardiomyocytes. We observed adiponectin transcript and protein in cultured ventricular cardiomyocytes isolated from adult rat, by quantitative real-time PCR, ELISA assays, Western blots, and immunofluorescent staining. In addition, we detected adiponectin receptor (AdipoR1 and AdipoR2) expression in the heart. AdipoR1 was expressed in rat myocardium at a level of ∼50% of that in skeletal muscle; whereas adipoR2 was expressed at a similar level to that in liver. Rosiglitazone, a Peroxisome proliferator activated receptor γ (PPARγ) activator, substantially elevated expression of adiponectin in cultured cardiomyocytes and its secretion into cultured media. Rosiglitazone also increased adipoR1 and adipoR2 expression in cardiomyocytes. Treatment of recombinant globular adiponectin in cultured cardiomyocytes increased fatty acid oxidation and glucose uptake via activation of AMPK, suggesting a role for adiponectin in cardiac energy metabolism. Together, these data establish the existence of a local cardiac-specific adiponectin system that is regulated by PPARγ. Moreover, these findings indicate a role for adiponectin on normal myocardial energy homeostasis, in part, through the activation of AMPK.

Creatine kinase knockout mice show left ventricular hypertrophy and dilatation, but unaltered remodeling post-myocardial infarction

Creatine kinase (CK) is responsible for the transport of high-energy phosphates in excitable tissue and is of central importance in myocardial energy homeostasis. Significant changes in myocardial energetics have been reported in mice lacking the various CK isoenzymes. Our hypothesis was that ablation of CK isoenzymes leads to cardiac hypertrophy, impaired function, and aggravation of left ventricular remodeling post-myocardial infarction. CK-deficient mice (CK KO) were examined by cardiac magnetic resonance imaging (MRI) to determine left ventricular volumes, ejection fraction, and mass: ten wild-type (WT), 6 mitochondrial CK KO (Mito-CK-/-), 10 cytosolic CK KO (M-CK-/-), and 10 mice with combined KO (M/Mito-CK-/-). While ejection fraction was similar in all groups, there was significant LV dilatation with a approximately 30% increase in LV end-diastolic volumes in Mito-CK-/- and in M/Mito-CK-/-. Compared to WT, there was a striking 73% and 64% increase of LV mass in Mito-CK-/- and in M/Mito-CK-/- mice, respectively, but no significant increase of LV mass (+33%; p=n.s.) in M-CK-/-. Furthermore, significant re-expression of beta-MHC, a marker of myocardial hypertrophy, was found in all CK-deficient hearts. LV remodeling was investigated by MRI in hearts of 7 WT and 10 M/Mito-CK-/- mice 4 weeks postmyocardial infarction (MI). Four weeks post-LAD ligation (MI size approximately 32%), WT and M/Mito-CK-/- showed a similar degree of cardiac dysfunction, dilatation, and hypertrophy. Mito-CK-/- and M/Mito-CK-/- mice show significant LV dilatation and marked LV hypertrophy, but LV remodeling post-MI is not aggravated. CK ablation leads to substantial adaptational changes in heart.

Glucose Metabolism and Energy Homeostasis in Mouse Hearts Overexpressing Dominant Negative α2 Subunit of AMP-activated Protein Kinase

AMP-activated protein kinase (AMPK) is an energy-sensing enzyme that plays a pivotal role in regulating cellular metabolism for sustaining energy homeostasis under stress conditions. Activation of AMPK has been observed in the heart during acute and chronic stresses, but its functional role has not been completely understood because of the lack of effective activators and inhibitors of this kinase in the heart. We generated transgenic mice (TG) with cardiac-specific overexpression of a dominant negative mutant of the AMPK alpha2 catalytic subunit to clarify the functional role of this kinase in myocardial ischemia. In isolated perfused hearts subjected to a 10-min ischemia, AMPK alpha2 activity in wild type (WT) increased substantially (by 4.5-fold), whereas AMPK alpha2 activity in TG was similar to the level of WT at base line. Basal AMPK alpha1 activity was unchanged in TG and increased normally during ischemia. Ischemia stimulated a 2.5-fold increase in 2-deoxyglucose uptake over base line in WT, whereas the inactivation of AMPK alpha2 in TG significantly blunted this response. Using 31P NMR spectroscopy, we found that ATP depletion was accelerated in TG hearts during no-flow ischemia, and these hearts developed left ventricular dysfunction manifested by an early and more rapid increase in left ventricular end-diastolic pressure. The exacerbated ATP depletion could not be attributed to impaired glycolytic ATP synthesis because TG hearts consumed slightly more glycogen during this period of no-flow ischemia. Thus, AMPK alpha2 is necessary for maintaining myocardial energy homeostasis during ischemia. It is likely that the functional role of AMPK in myocardial energy metabolism resides both in energy supply and utilization.

Mitochondrial creatine kinase is critically necessary for normal myocardial high-energy phosphate metabolism.

The individual functional significance of the various creatine kinase (CK) isoenzymes for myocardial energy homeostasis is poorly understood. Whereas transgenic hearts lacking the M subunit of CK (M-CK) show unaltered cardiac energetics and left ventricular (LV) performance, deletion of M-CK in combination with loss of sarcomeric mitochondrial CK (ScCKmit) leads to significant alterations in myocardial high-energy phosphate metabolites. To address the question as to whether this alteration is due to a decrease in total CK activity below a critical threshold or due to the specific loss of ScCKmit, we studied isolated perfused hearts with selective loss of ScCKmit (ScCKmit(-/-), remaining total CK activity approximately 70%) using (31)P NMR spectroscopy at two different workloads. LV performance in ScCKmit(-/-) hearts (n = 11) was similar compared with wild-type hearts (n = 9). Phosphocreatine/ATP, however, was significantly reduced in ScCKmit(-/-) compared with wild-type hearts (1.02 +/- 0.05 vs. 1.54 +/- 0.07, P < 0.05). In parallel, free [ADP] was higher (144 +/- 11 vs. 67 +/- 7 microM, P < 0.01) and free energy release for ATP hydrolysis (DeltaG(ATP)) was lower (-55.8 +/- 0.5 vs. -58.5 +/- 0.5 kJ/mol, P < 0.01) in ScCKmit(-/-) compared with wild-type hearts. These results demonstrate that M- and B-CK containing isoenzymes are unable to fully substitute for the loss of ScCKmit. We conclude that ScCKmit, in contrast to M-CK, is critically necessary to maintain normal high-energy phosphate metabolite levels in the heart.

Deficiencies of myocardial troponin-T and creatine kinase MB isoenzyme in dogs with idiopathic dilated cardiomyopathy

Abstract Objective To test the hypothesis that the derangement of myocardial energy homeostasis characteristic of idiopathic dilated cardiomyopathy (IDCM) of Doberman Pinschers was attributable to deficiency of creatine kinase (CK) isoenzyme MB relative to CK isoenzyme MM and troponin-T (Tn-T). Animals 9 Doberman Pinschers with advanced congestive heart failure attributable to IDCM and 9 mixed-breed dogs without cardiac disease (controls). Procedure Myocardial myofibrillar CK-MM, mitochondrial CK, and cytosolic CK-MB activities were determined in comparison with the concentration of cardiac-specific, myofibrillar protein Tn-T. Myocardial biopsy specimens were obtained after euthanasia and were ultrafrozen. Isoenzymes of CK were separated eloctrophoretically, and their activity was determined, using a coupled-enzyme, kinetic, fluorescent assay and densitometry. Troponin-T content was determined by immunoassay. Results Myofibrillar CK-MM and mitochondrial CK activities and Tn-T content were 25% lower in the dogs with IDCM than in controls, whereas cytosolic CK-MB activity was 50% lower. Conclusion Deficiency of CK-MB activity is a component of and may have a central role in the energy deficiency characteristic of failing myocardium in IDCM of Doberman Pinschers. A side-product of this study was the observation that, in dogs, CK-MB activity and Tn-T content of myocardium are sufficiently high to be candidate serum markers for active cardiac injury. (Am J Vet Res 1997;58:11–16)