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102. Increased ketone body oxidation provides additional energy for the failing heart without improving cardiac efficiency

Author

Ho, Kim L, primary, Zhang, Liyan, additional, Wagg, Cory, additional, Al Batran, Rami, additional, Gopal, Keshav, additional, Levasseur, Jody, additional, Leone, Teresa, additional, Dyck, Jason R B, additional, Ussher, John R, additional, Muoio, Deborah M, additional, Kelly, Daniel P, additional, and Lopaschuk, Gary D, additional

Published
2019
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104. The antianginal ranolazine mitigates obesity-induced nonalcoholic fatty liver disease and increases hepatic pyruvate dehydrogenase activity

Author

Batran, Rami Al, primary, Gopal, Keshav, additional, Aburasayn, Hanin, additional, Eshreif, Amina, additional, Almutairi, Malak, additional, Greenwell, Amanda A., additional, Campbell, Scott A., additional, Saleme, Bruno, additional, Court, Emily A., additional, Eaton, Farah, additional, Light, Peter E., additional, Sutendra, Gopinath, additional, and Ussher, John R., additional

Published
2019
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106. Ketones can become the major fuel source for the heart but do not increase cardiac efficiency.

Author

Ho, Kim L, Karwi, Qutuba G, Wagg, Cory, Zhang, Liyan, Vo, Katherina, Altamimi, Tariq, Uddin, Golam M, Ussher, John R, and Lopaschuk, Gary D

Subjects
FATTY acid oxidation, KETONES, ADENOSINE triphosphate, TRICARBOXYLIC acids, KETOGENIC diet
Abstract

Aims Ketones have been proposed to be a 'thrifty' fuel for the heart and increasing cardiac ketone oxidation can be cardioprotective. However, it is unclear how much ketone oxidation can contribute to energy production in the heart, nor whether increasing ketone oxidation increases cardiac efficiency. Therefore, our goal was to determine to what extent high levels of the ketone body, β-hydroxybutyrate (βOHB), contributes to cardiac energy production, and whether this influences cardiac efficiency. Methods and results Isolated working mice hearts were aerobically perfused with palmitate (0.8 mM or 1.2 mM), glucose (5 mM) and increasing concentrations of βOHB (0, 0.6, 2.0 mM). Subsequently, oxidation of these substrates, cardiac function, and cardiac efficiency were assessed. Increasing βOHB concentrations increased myocardial ketone oxidation rates without affecting glucose or fatty acid oxidation rates where normal physiological levels of glucose (5 mM) and fatty acid (0.8 mM) are present. Notably, ketones became the major fuel source for the heart at 2.0 mM βOHB (at both low or high fatty acid concentrations), with the elevated ketone oxidation rates markedly increasing tricarboxylic acid (TCA) cycle activity, producing a large amount of reducing equivalents and finally, increasing myocardial oxygen consumption. However, the marked increase in ketone oxidation at high concentrations of βOHB was not accompanied by an increase in cardiac work, suggesting that a mismatch between excess reduced equivalents production from ketone oxidation and cardiac adenosine triphosphate production. Consequently, cardiac efficiency decreased when the heart was exposed to higher ketone levels. Conclusions We demonstrate that while ketones can become the major fuel source for the heart, they do not increase cardiac efficiency, which also underscores the importance of recognizing ketones as a major fuel source for the heart in times of starvation, consumption of a ketogenic diet or poorly controlled diabetes. [ABSTRACT FROM AUTHOR]

Published
2021
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108. Myocardial fatty acid metabolism in health and disease

Author

Lopaschuk, Gary D., Ussher, John R., Folmes, Clifford D. L., Jaswal, Jagdip S., and Stanley, William C.

Subjects
Fatty acid metabolism -- Research, Cardiomyopathy -- Genetic aspects, Cardiomyopathy -- Care and treatment, Heart diseases -- Genetic aspects, Heart diseases -- Care and treatment, Biological oxidation (Metabolism) -- Analysis, Biological sciences, Health
Published
2010

109. FoxO1 regulates myocardial glucose oxidation rates via transcriptional control of pyruvate dehydrogenase kinase 4 expression

Author

Gopal, Keshav, primary, Saleme, Bruno, additional, Al Batran, Rami, additional, Aburasayn, Hanin, additional, Eshreif, Amina, additional, Ho, Kim L., additional, Ma, Wayne K., additional, Almutairi, Malak, additional, Eaton, Farah, additional, Gandhi, Manoj, additional, Park, Edwards A., additional, Sutendra, Gopinath, additional, and Ussher, John R., additional

Published
2017
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117. Genetic and Pharmacological Inhibition of Malonyl CoA Decarboxylase Does Not Exacerbate Age-Related Insulin Resistance in Mice

Author

Ussher, John R., primary, Fillmore, Natasha, additional, Keung, Wendy, additional, Zhang, Liyan, additional, Mori, Jun, additional, Sidhu, Vaninder K., additional, Fukushima, Arata, additional, Gopal, Keshav, additional, Lopaschuk, David G., additional, Wagg, Cory S., additional, Jaswal, Jagdip S., additional, Dyck, Jason R.B., additional, and Lopaschuk, Gary D., additional

Published
2016
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119. TCF1 links GIPR signaling to the control of beta cell function and survival

Author

Campbell, Jonathan E, primary, Ussher, John R, additional, Mulvihill, Erin E, additional, Kolic, Jelena, additional, Baggio, Laurie L, additional, Cao, Xiemen, additional, Liu, Yu, additional, Lamont, Benjamin J, additional, Morii, Tsukasa, additional, Streutker, Catherine J, additional, Tamarina, Natalia, additional, Philipson, Louis H, additional, Wrana, Jeffrey L, additional, MacDonald, Patrick E, additional, and Drucker, Daniel J, additional

Published
2015
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121. FoxO1 regulates myocardial glucose oxidation rates via transcriptional control of pyruvate dehydrogenase kinase 4 expression.

Author

Ma, Wayne K., Gopal, Keshav, Al Batran, Rami, Aburasayn, Hanin, Eshreif, Amina, Almutairi, Malak, Eaton, Farah, Gandhi, Manoj, Ussher, John R., Ho, Kim L., Saleme, Bruno, Sutendra, Gopinath, and Park, Edwards A.

Subjects
FORKHEAD transcription factors, PYRUVATE dehydrogenase kinase
Abstract

Pyruvate dehydrogenase (PDH) is the ratelimiting enzyme for glucose oxidation and a critical regulator of metabolic flexibility during the fasting to feeding transition. PDH is regulated via both PDH kinases (PDHK) and PDH phosphatases, which phosphorylate/inactivate and dephosphorylate/activate PDH, respectively. Our goal was to determine whether the transcription factor forkhead box O1 (FoxO1) regulates PDH activity and glucose oxidation in the heart via increasing the expression of Pdk4, the gene encoding PDHK4. To address this question, we differentiated H9c2 myoblasts into cardiac myocytes and modulated FoxO1 activity, after which Pdk4/PDHK4 expression and PDH phosphorylation/activity were assessed. We assessed binding of FoxO1 to the Pdk4 promoter in cardiac myocytes in conjunction with measuring the role of FoxO1 on glucose oxidation in the isolated working heart. Both pharmacological (1 μM AS1842856) and genetic (siRNA mediated) inhibition of FoxO1 decreased Pdk4/PDHK4 expression and subsequent PDH phosphorylation in H9c2 cardiac myocytes, whereas 10 μM dexamethasone-induced Pdk4/PDHK4 expression was abolished via pretreatment with 1 μM AS1842856. Furthermore, transfection of H9c2 cardiac myocytes with a vector expressing FoxO1 increased luciferase activity driven by a Pdk4 promoter construct containing the FoxO1 DNA-binding element region, but not in a Pdk4 promoter construct lacking this region. Finally, AS1842856 treatment in fasted mice enhanced glucose oxidation rates during aerobic isolated working heart perfusions. Taken together, FoxO1 directly regulates Pdk4 transcription in the heart, thereby controlling PDH activity and subsequent glucose oxidation rates. NEW & NOTEWORTHY Although studies have shown an association between FoxO1 activity and pyruvate dehydrogenase kinase 4 expression, our study demonstrated that pyruvate dehydrogenase kinase 4 is a direct transcriptional target of FoxO1 (but not FoxO3/FoxO4) in the heart. Furthermore, we report here, for the first time, that FoxO1 inhibition increases glucose oxidation in the isolated working mouse heart. [ABSTRACT FROM AUTHOR]

Published
2017
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126. Treatment with the 3-Ketoacyl-CoA Thiolase Inhibitor Trimetazidine Does Not Exacerbate Whole-Body Insulin Resistance in Obese Mice

Author

Ussher, John R., primary, Keung, Wendy, additional, Fillmore, Natasha, additional, Koves, Timothy R., additional, Mori, Jun, additional, Zhang, Liyan, additional, Lopaschuk, David G., additional, Ilkayeva, Olga R., additional, Wagg, Cory S., additional, Jaswal, Jagdip S., additional, Muoio, Deborah M., additional, and Lopaschuk, Gary D., additional

Published
2014
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130. Inhibition of Dipeptidyl Peptidase-4 Impairs Ventricular Function and Promotes Cardiac Fibrosis in High Fat-Fed Diabetic Mice.

Author

Mulvihill, Erin E., Varin, Elodie M., Ussher, John R., Campbell, Jonathan E., Bang, K. W. Annie, Abdullah, Tahmid, Baggio, Laurie L., and Drucker, Daniel J.

Subjects
CD26 antigen, TYPE 2 diabetes, CARDIOTONIC agents, HEART failure, MESSENGER RNA, ANIMAL models in research, THERAPEUTICS, RNA metabolism, ANIMAL experimentation, CYTOKINES, DIABETES, DIET, HEART, CARDIAC hypertrophy, HEART ventricles, HETEROCYCLIC compounds, HYPOGLYCEMIC agents, IMMUNOBLOTTING, INFLAMMATION, MICE, MYOCARDIUM, PROTEOLYTIC enzymes, RESEARCH funding, RNA, PROTEASE inhibitors, FIBROSIS, VENTRICULAR remodeling, GENE expression profiling, PHARMACODYNAMICS, PHYSIOLOGY
Abstract

Dipeptidyl peptidase-4 (DPP4) inhibitors used for the treatment of type 2 diabetes are cardioprotective in preclinical studies; however, some cardiovascular outcome studies revealed increased hospitalization rates for heart failure (HF) among a subset of DPP4 inhibitor-treated subjects with diabetes. We evaluated cardiovascular function in young euglycemic Dpp4(-/-) mice and in older, high fat-fed, diabetic C57BL/6J mice treated with either the glucagon-like peptide 1 receptor (GLP-1R) agonist liraglutide or the highly selective DPP4 inhibitor MK-0626. We assessed glucose metabolism, ventricular function and remodeling, and cardiac gene expression profiles linked to inflammation and fibrosis after transverse aortic constriction (TAC) surgery, a pressure-volume overload model of HF. Young euglycemic Dpp4(-/-) mice exhibited a cardioprotective response after TAC surgery or doxorubicin administration, with reduced fibrosis; however, cardiac mRNA analysis revealed increased expression of inflammation-related transcripts. Older, diabetic, high fat-fed mice treated with the GLP-1R agonist liraglutide exhibited preservation of cardiac function. In contrast, diabetic mice treated with MK-0626 exhibited modest cardiac hypertrophy, impairment of cardiac function, and dysregulated expression of genes and proteins controlling inflammation and cardiac fibrosis. These findings provide a model for the analysis of mechanisms linking fibrosis, inflammation, and impaired ventricular function to DPP4 inhibition in preclinical studies. [ABSTRACT FROM AUTHOR]

Published
2016
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135. Inhibition of Serine Palmitoyl Transferase I Reduces Cardiac Ceramide Levels and Increases Glycolysis Rates following Diet-Induced Insulin Resistance

Author

Ussher, John R., primary, Folmes, Clifford D. L., additional, Keung, Wendy, additional, Fillmore, Natasha, additional, Jaswal, Jagdip S., additional, Cadete, Virgilio J., additional, Beker, Donna L., additional, Lam, Victoria H., additional, Zhang, Liyan, additional, and Lopaschuk, Gary D., additional

Published
2012
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137. Cardiac hypertrophy in the newborn delays the maturation of fatty acid β-oxidation and compromises postischemic functional recovery

Author

Oka, Tatsujiro, primary, Lam, Victoria H., additional, Zhang, Liyan, additional, Keung, Wendy, additional, Cadete, Virgilio J. J., additional, Samokhvalov, Victor, additional, Tanner, Brandon A., additional, Beker, Donna L., additional, Ussher, John R., additional, Huqi, Alda, additional, Jaswal, Jagdip S., additional, Rebeyka, Ivan M., additional, and Lopaschuk, Gary D., additional

Published
2012
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143. Abstract 9474: Trim35-Mediated Ubiquitination and Degradation of Nuclear PKM2 is Sufficient to Promote Heart Failure

Author

Lorenzana Carrillo, Maria A, Gopal, Keshav, Byrne, Nikole, Tejay, Saymon, Saleme, Bruno, Das, Subhash, Zhang, Yongneng, Haromy, Alois S, Eaton, Farah, Mendiola Pla, Michelle, Bowles, Dawn E, Dyck, Jason R, Ussher, John R, Michelakis, Evangelos D, and Sutendra, Gopinath

Abstract

Introduction:Pyruvate Kinase M2 (PKM2) is a glycolytic enzyme that can translocate to the nucleus to regulate different transcription factors (TF) in different tissues or pathologic states. Although its function has been studied extensively in cancer, its biologic role in the heart and specifically terminally differentiated adult cardiomyocytes remains unresolved.Hypothesis:PKM2 may be critical in regulating cardiomyocyte(CM)-specific TF important for cardiac survival.Methods:Transverse aortic constriction (TAC) banding model was used to assess the levels and modifications of PKM2 during heart failure (HF). CM-specific PKM2-deficient and CM-specific Trim35 overexpressing(OE) mice were generated to evaluate the role of PKM2/Trim35 in adult CM. Human Dilated Left Ventricle biopsies were used to translate mechanistic findings into a clinical setting.Results:Here we show that nuclear PKM2 (S37P-PKM2) in CM interacts with several pro-survival or pro-apoptotic TF, including Gata-4, Gata-6, and p53. CM-specific PKM2-deficient mice developed age-dependent dilated cardiac dysfunction and had decreased levels of Gata-4/6, but increased levels of p53, compared to control Cre+ hearts. Mechanistically, we found that nuclear PKM2 can prevent caspase-1 dependent cleavage Gata-4/Gata-6, while also providing a platform for Mdm2-mediated ubiquitination of p53. In a preclinical HF model, nuclear PKM2, along with Gata-4/6 levels decreased, but p53 levels increased (compared to sham controls). Loss of nuclear PKM2 was ubiquitination-dependent and associated with the induction of the E3 ubiquitin-ligase TRIM35. CM-specific Trim35 OE mice had decreased S37P-PKM2 and GATA-4/6, along with increased p53 levels (compared to littermate controls) and had similar cardiac dysfunction to CM-specific PKM2-deficient mice. In a well-characterized cohort of patients with dilated left ventricles, we found a significant increase in TRIM35 levels that was associated with a decrease in S37P-PKM2, Gata-4/6 levels, but an increase in p53 levels, compared to non-failing ventricles.Conclusion:This study provides insight into a previously unrecognized biologic role for PKM2 in providing a molecular platform for TF essential for preserving cardiac survival.

Published
2022
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144. Cardiac hypertrophy in the newborn delays the maturation of fatty acid β-oxidation and compromises postischemic functional recovery.

Author

Tatsujiro Oka, Lam, Victoria H., Liyan Zhang, Keung, Wendy, Cadete, Virgilio J. J., Samokhvalov, Victor, Tanner, Brandon A., Beker, Donna L., Ussher, John R., Huqi, Alda, Jaswal, Jagdip S., Rebeyka, Ivan M., and Lopaschuk, Gary D.

Abstract

During the neonatal period, cardiac energy metabolism progresses from a fetal glycolytic profile towards one more dependent on mitochondrial oxidative metabolism. In this study, we identified the effects of cardiac hypertrophy on neonatal cardiac metabolic maturation and its impact on neonatal postischemic functional recovery. Seven-day-old rabbits were subjected to either a sham or a surgical procedure to induce a left-to-right shunt via an aortocaval fistula to cause RV volume-overload. At 3 wk of age, hearts were isolated from both groups and perfused as isolated, biventricular preparations to assess cardiac energy metabolism. Volume-overload resulted in cardiac hypertrophy (16% increase in cardiac mass, P < 0.05) without evidence of cardiac dysfunction in vivo or in vitro. Fatty acid oxidation rates were 60% lower (P < 0.05) in hypertrophied hearts than controls, whereas glycolysis increased 246% (P < 0.05). In contrast, glucose and lactate oxidation rates were unchanged. Overall ATP production rates were significantly lower in hypertrophied hearts, resulting in increased AMP-to-ATP ratios in both aerobic hearts and ischemia-reperfused hearts. The lowered energy generation of hypertrophied hearts depressed functional recovery from ischemia. Decreased fatty acid oxidation rates were accompanied by increased malonyl-CoA levels due to decreased malonyl-CoA decarboxylase activity/expression. Increased glycolysis in hypertrophied hearts was accompanied by a significant increase in hypoxia-inducible factor-1α expression, a key transcriptional regulator of glycolysis. Cardiac hypertrophy in the neonatal heart results in a reemergence of the fetal metabolic profile, which compromises ATP production in the rapidly maturing heart and impairs recovery of function following ischemia. [ABSTRACT FROM AUTHOR]

Published
2012
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145. Gipr Is Essential for Adrenocortical Steroidogenesis; However, Corticosterone Deficiency Does Not Mediate the Favorable Metabolic Phenotype of Gipr-/- Mice.

Author

Bates, Holly E., Campbell, Jonathan E., Ussher, John R., Baggio, Laurie L., Maida, Adriano, Seino, Yutaka, and Drucker, Daniel J.

Subjects
INSULIN therapy, GLUCOCORTICOIDS, POLYPEPTIDES, LABORATORY mice, HYPOGLYCEMIC agents, OBESITY
Abstract

Glucose-dependent insulinotropic polypeptide (GIP) promotes glucose-dependent insulin secretion. However, GIP also enhances glucocorticoid secretion and promotes adiposity. Because obesity and diabetes are glucocorticoid dependent, we examined whether the effects of GIP on energy balance and glycemia are regulated by glucocorticoids using pharmacological activation of GIP receptor (GIPR) signaling with [D-Ala2]GIP in mice and in Y1 adrenocortical cells. Genetic elimination of GIPR activity was also studied in normal- and high-fat (HF)-fed Gipr-deficient (Gipr-/-)mice. [D-Ala²]GIP increased murine corticosterone levels in a GIPR-dependent manner. Conversely, basal corticosterone levels were reduced, whereas food deprivation resulted in significantly enhanced plasma corticosterone levels in Gipr-/- mice. [D-Ala²]GIP increased cAMP levels, activated extracellular signal--related kinase (ERK)1/2, increased expression of steroidogenic genes, and increased neutral lipid storage in Y1GIPR cells. Gipr-/- adrenal glands demonstrated a twofold upregulation of the ACTH receptor mRNA and increased sensitivity to ACTH ex vivo. Although HF-fed Gipr-/- mice exhibited significantly lower plasma corticosterone, glucocorticoid-treated HF-fed Gipr-/- mice had similar energy balance and glycemia compared with Gipr-/- controls. Hence, although the Gipr is essential for adrenal steroidogenesis and links HF feeding to increased levels of corticosterone, reduced glucocorticoid levels do not significantly contribute to the enhanced metabolic pheno-types in HF-fed Gipr-/- mice. Diabetes 61:40--48, 2012 [ABSTRACT FROM AUTHOR]

Published
2012
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146. Type 1 diabetic cardiomyopathy in the Akita (Ins2WT/C96Y) mouse model is characterized by lipotoxicity and diastolic dysfunction with preserved systolic function.

Author

Basu, Ratnadeep, Oudit, Gavin Y., Xiuhua Wang, Liyan Zhang, Ussher, John R., Lopaschuk, Gary D., and Kassiri, Zamaneh

Subjects
DIAGNOSIS of diabetes, CARDIOMYOPATHIES, HEART failure, HEART function tests, LABORATORY mice, ECHOCARDIOGRAPHY, DOPPLER ultrasonography, HYPERTROPHY
Abstract

Diabetic cardiomyopathy is an important contributor to diastolic and systolic heart failure. We examined the nature and mechanism of the cardiomyopathy in Akita (Ins2WT/C96Y) mice, a model of genetic nonobese type I diabetes that recapitulates human type 1 diabetes. Cardiac function was evaluated in male Ins2WT/C96Y and their littermate control (Ins2WT/C96Y) mice using echocardiography and tissue Doppler imaging, in vivo hemodynamic measurements, as well as ex vivo working heart preparation. At 3 and 6 mo of age, Ins2WT/C96Y mice exhibited preserved cardiac systolic function compared with Ins2WT/C96Y mice, as evaluated by ejection fraction, fractional shortening, left ventricular (LV) end-systolic pressure and maximum rate of increase in LV pressure in vivo, cardiac work, cardiac power, and rate-pressure product ex vivo. Despite the unaltered systolic function, Ins2WT/C96Y mice exhibited significant and progressive diastolic dysfunction at 3 and 6 mo of age compared with Ins2WT/C96Y mice as assessed by tissue and pulse Doppler imaging (E-wave velocity, isovolumetric relaxation time) and by in vivo hemodynamic measurements (LV end-diastolic pressure, time constant of LV relaxation, and maximum rate of decrease in LV pressure). We found no evidence of myocardial hypeitrophy or fibrosis in the InsWT/C96Y myocardium. Consistent with the lack of fibrosis, expression of procollagen-cs type I, pmcollagen-α type III, and fibronectin were not increased in these hearts. Ins2WT/C96Y hearts showed significantly reduced sarcoplasmic reticulum Ca2+-ATPase 2a (cardiac sarcoplasmic reticulum Ca2+ pump) levels, elevated β-myosin heavy chain isoform, increased long-chain fatty acids, and triacylglycerol with evidence of lipotoxicity, as indicated by a significant rise in ceramide, diacylglycerol, and lipid deposits in the myocardium. Consistent with metabolic perturbation, and a switch to fatty acid oxidation from glucose oxidation in lns2WT/C96Y hearts, expression of mitochondrial long-chain acyl-CoA dehydrogenase and pyruvate dehydrogenase kinase isoform 4 were increased. Insulin treatment reversed the diastolic dysfunction, the elevated B-type natriuretic peptide and 3-myosin heavy chain, and the reduced sarcoplasmic reticulum Ca2+-ATPase 2a levels with abolition of cardiac lipotoxicity. We conclude that early type 1 diabetic cardiomyopathy is characterized by diastolic dysfunction associated with lipotoxic cardiomyopathy with preserved systolic function in the absence of interstitial fibrosis and hypertrophy. [ABSTRACT FROM AUTHOR]

Published
2009
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147. Deletion of BCATm increases insulin-stimulated glucose oxidation in the heart.

Author

Uddin, Golam M., Karwi, Qutuba G., Pherwani, Simran, Gopal, Keshav, Wagg, Cory S., Biswas, Dipsikha, Atnasious, Mariam, Wu, Yikuan, Wu, Guoqing, Zhang, Liyan, Ho, Kim L., Pulinilkunnil, Thomas, Ussher, John R., and Lopaschuk, Gary D.

Subjects
OXIDATION of glucose, BRANCHED chain amino acids, INSULIN, INSULIN sensitivity, INSULIN resistance, HEART metabolism
Abstract

Branched chain amino acid (BCAA) oxidation is impaired in cardiac insulin resistance, leading to the accumulation of BCAAs and the first products of BCAA oxidation, the branched chain ketoacids. However, it is not clear whether it is the BCAAs, BCKAs or both that are mediating cardiac insulin resistance. To determine this, we produced mice with a cardiac-specific deletion of BCAA aminotransferase (BCATm−/−), the first enzyme in the BCAA oxidation pathway that is responsible for converting BCAAs to BCKAs. Eight-week-old BCATm cardiac specific knockout (BCATm−/−) male mice and their α-MHC (myosin heavy chain) - Cre expressing wild type littermates (WT-Cre+/+) received tamoxifen (50 mg/kg i.p. 6 times over 8 days). At 16-weeks of age, cardiac energy metabolism was assessed in isolated working hearts. BCATm−/− mice have decreased cardiac BCAA oxidation rates, increased cardiac BCAAs and a reduction in cardiac BCKAs. Hearts from BCATm−/− mice showed an increase in insulin stimulation of glucose oxidation and an increase in p-AKT. To determine the impact of reversing these events, we perfused isolated working mice hearts with high levels of BCKAs, which completely abolished insulin-stimulated glucose oxidation rates, an effect associated with decreased p-AKT and inactivation of pyruvate dehydrogenase (PDH), the rate-limiting enzyme in glucose oxidation. This implicates the BCKAs, and not BCAAs, as the actual mediators of cardiac insulin resistance and suggests that lowering cardiac BCKAs can be used as a therapeutic strategy to improve insulin sensitivity in the heart. • Cardiac-specific BCATm deletion selectively increases BCAAs levels and decreases BCKAs levels. • Lowering cardiac BCKAs levels, not BCAAs, enhances cardiac insulin sensitivity. • Cardiac BCAA accumulation, triggers the mTOR signaling and cardiac hypertrophy in the BCATm knockout hearts. • Augmented levels of BCKAs, not BCAAs, abolish insulin-stimulated cardiac glucose oxidation. [ABSTRACT FROM AUTHOR]

Published
2021
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148. Liraglutide alleviates experimental diabetic cardiomyopathy in a PDH-dependent manner.

Author

Chan, Jordan S. F., Greenwell, Amanda A., Saed, Christina T., Stenlund, Magnus J., Mangra-Bala, Indiresh A., Tabatabaei Dakhili, Seyed Amirhossein, Kunyan Yang, Ferrari, Sally R., Eaton, Farah, Gopal, Keshav, and Ussher, John R.

Abstract

Liraglutide, a glucagon-like peptide-1 receptor (GLP-1R) agonist used for the treatment of T2D, has been shown to alleviate diabetic cardiomyopathy (DbCM) in experimental T2D, which was associated with increased myocardial glucose oxidation. To determine whether this increase in glucose oxidation is necessary for cardioprotection, we hypothesized that liraglutide's ability to alleviate DbCM would be abolished in mice with cardiomyocyte-specific deletion of pyruvate dehydrogenase (PDH; Pdha1CM-/- mice), the rate-limiting enzyme of glucose oxidation. Male Pdha1CM-/- mice and their a-myosin heavy chain Cre expressing littermates (aMHCCre mice) were subjected to experimental T2D via 10 weeks of high-fat diet supplementation, with a single low-dose injection of streptozotocin (75 mg/kg) provided at week 4. All mice were randomized to treatment with either vehicle control or liraglutide (30 µg/kg) twice daily during the final 2.5 weeks, with cardiac function assessed via ultrasound echocardiography. As expected, liraglutide treatment improved glucose homeostasis in both aMHCCre and Pdha1CM-/- mice with T2D, in the presence of mild weight loss. Parameters of systolic function were unaffected by liraglutide treatment in both aMHCCre and Pdha1CM-/- mice with T2D. However, liraglutide treatment alleviated diastolic dysfunction in aMHCCre mice, as indicated by an increase and decrease in the e'/a' and E/e' ratios, respectively. Conversely, liraglutide failed to rescue these indices of diastolic dysfunction in Pdha1CM-/- mice. Our findings suggest that increases in glucose oxidation are necessary for GLP-1R agonist mediated alleviation of DbCM. As such, strategies aimed at increasing PDH activity may represent a novel approach for the treatment of DbCM. [ABSTRACT FROM AUTHOR]

Published
2024
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149. The ketogenic diet does not improve cardiac function and blunts glucose oxidation in ischaemic heart failure.

Author

Ho, Kim L, Karwi, Qutuba G, Wang, Faqi, Wagg, Cory, Zhang, Liyan, Panidarapu, Sai, Chen, Brandon, Pherwani, Simran, Greenwell, Amanda A, Oudit, Gavin Y, Ussher, John R, and Lopaschuk, Gary D

Subjects
*FATTY acid oxidation, *KETOGENIC diet, *CORONARY artery surgery, *OXIDATION of glucose, *HEART metabolism
Abstract

Aims Cardiac energy metabolism is perturbed in ischaemic heart failure and is characterized by a shift from mitochondrial oxidative metabolism to glycolysis. Notably, the failing heart relies more on ketones for energy than a healthy heart, an adaptive mechanism that improves the energy-starved status of the failing heart. However, whether this can be implemented therapeutically remains unknown. Therefore, our aim was to determine if increasing ketone delivery to the heart via a ketogenic diet can improve the outcomes of heart failure. Methods and results C57BL/6J male mice underwent either a sham surgery or permanent left anterior descending coronary artery ligation surgery to induce heart failure. After 2 weeks, mice were then treated with either a control diet or a ketogenic diet for 3 weeks. Transthoracic echocardiography was then carried out to assess in vivo cardiac function and structure. Finally, isolated working hearts from these mice were perfused with appropriately 3H or 14C labelled glucose (5 mM), palmitate (0.8 mM), and β-hydroxybutyrate (β-OHB) (0.6 mM) to assess mitochondrial oxidative metabolism and glycolysis. Mice with heart failure exhibited a 56% drop in ejection fraction, which was not improved with a ketogenic diet feeding. Interestingly, mice fed a ketogenic diet had marked decreases in cardiac glucose oxidation rates. Despite increasing blood ketone levels, cardiac ketone oxidation rates did not increase, probably due to a decreased expression of key ketone oxidation enzymes. Furthermore, in mice on the ketogenic diet, no increase in overall cardiac energy production was observed, and instead, there was a shift to an increased reliance on fatty acid oxidation as a source of cardiac energy production. This resulted in a decrease in cardiac efficiency in heart failure mice fed a ketogenic diet. Conclusion We conclude that the ketogenic diet does not improve heart function in failing hearts, due to ketogenic diet-induced excessive fatty acid oxidation in the ischaemic heart and a decrease in insulin-stimulated glucose oxidation. [ABSTRACT FROM AUTHOR]

Published
2024
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150. Redefining Diabetic Cardiomyopathy: Perturbations in Substrate Metabolism at the Heart of Its Pathology.

Author

Heather, Lisa C., Gopal, Keshav, Srnic, Nikola, and Ussher, John R.

Subjects
*DIABETIC cardiomyopathy, *HEART metabolism, *VENTRICULAR dysfunction, *CARDIOMYOPATHIES, *HEART failure
Abstract

Cardiovascular disease represents the leading cause of death in people with diabetes, most notably from macrovascular diseases such as myocardial infarction or heart failure. Diabetes also increases the risk of a specific form of cardiomyopathy, referred to as diabetic cardiomyopathy (DbCM), originally defined as ventricular dysfunction in the absence of underlying coronary artery disease and/or hypertension. Herein, we provide an overview on the key mediators of DbCM, with an emphasis on the role for perturbations in cardiac substrate metabolism. We discuss key mechanisms regulating metabolic dysfunction in DbCM, with additional focus on the role of metabolites as signaling molecules within the diabetic heart. Furthermore, we discuss the preclinical approaches to target these perturbations to alleviate DbCM. With several advancements in our understanding, we propose the following as a new definition for, or approach to classify, DbCM: "diastolic dysfunction in the presence of altered myocardial metabolism in a person with diabetes but absence of other known causes of cardiomyopathy and/or hypertension." However, we recognize that no definition can fully explain the complexity of why some individuals with DbCM exhibit diastolic dysfunction, whereas others develop systolic dysfunction. Due to DbCM sharing pathological features with heart failure with preserved ejection fraction (HFpEF), the latter of which is more prevalent in the population with diabetes, it is imperative to determine whether effective management of DbCM decreases HFpEF prevalence. Article Highlights: Diabetic cardiomyopathy (DbCM) is characterized by diastolic dysfunction and perturbations in cardiac substrate metabolism and is more prevalent in people with diabetes than previously recognized. Optimizing cardiac substrate metabolism is often associated with improvements in DbCM, and this improvement may be related to changes in flux, mitochondrial function, bioenergetics, and/or metabolite-regulated signaling processes. Heart failure with preserved ejection fraction (HFpEF) is also more prevalent in people with diabetes and is characterized by diastolic dysfunction, and the question of whether interventions aimed specifically at treating DbCM can decrease the risk or progression of HFpEF is an important area for future investigation. [ABSTRACT FROM AUTHOR]

Published
2024
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