Your search keyword '"Kelly, Daniel P."' showing total 40 results

1. SGLT2 Inhibitors Act Independently of SGLT2 to Confer Benefit for HFrEF in Mice.

Author

Berger JH, Matsuura TR, Bowman CE, Taing R, Patel J, Lai L, Leone TC, Reagan JD, Haldar SM, Arany Z, and Kelly DP

Subjects

Animals, Mice, Stroke Volume drug effects, Mice, Knockout, Mice, Inbred C57BL, Male, Sodium-Glucose Transporter 2 Inhibitors therapeutic use, Sodium-Glucose Transporter 2 Inhibitors pharmacology, Sodium-Glucose Transporter 2 metabolism, Sodium-Glucose Transporter 2 genetics, Heart Failure drug therapy

Abstract

Competing Interests: Data that support the findings of this study are available from the corresponding author upon reasonable request. D.P. Kelly is a consultant for Amgen and Pfizer LLC. J.D. Reagan and S.M. Haldar are employees of and shareholders in Amgen. S.M. Haldar is a scientific founder and a shareholder of Tenaya Therapeutics. The other authors report no conflicts.

Published

2024

2. Cardiac maturation.

Author

Sakamoto T and Kelly DP

Subjects

Humans, Cardiomegaly genetics, Cardiomegaly metabolism, Energy Metabolism physiology, Mitochondria metabolism, Myocytes, Cardiac metabolism, Heart Failure genetics, Heart Failure metabolism

Abstract

The heart undergoes a dynamic maturation process following birth, in response to a wide range of stimuli, including both physiological and pathological cues. This process entails substantial re-programming of mitochondrial energy metabolism coincident with the emergence of specialized structural and contractile machinery to meet the demands of the adult heart. Many components of this program revert to a more "fetal" format during development of pathological cardiac hypertrophy and heart failure. In this review, emphasis is placed on recent progress in our understanding of the transcriptional control of cardiac maturation, encompassing the results of studies spanning from in vivo models to cardiomyocytes derived from human stem cells. The potential applications of this current state of knowledge to new translational avenues aimed at the treatment of heart failure is also addressed., Competing Interests: Declaration of Competing Interest Authors declare no conflicts of interest., (Copyright © 2023. Published by Elsevier Ltd.)

Published

2024

3. RIP140 deficiency enhances cardiac fuel metabolism and protects mice from heart failure.

Author

Yamamoto T, Maurya SK, Pruzinsky E, Batmanov K, Xiao Y, Sulon SM, Sakamoto T, Wang Y, Lai L, McDaid KS, Shewale SV, Leone TC, Koves TR, Muoio DM, Dierickx P, Lazar MA, Lewandowski ED, and Kelly DP

Subjects

Animals, Mice, Cardiomegaly metabolism, Energy Metabolism genetics, Fatty Acids metabolism, Myocytes, Cardiac metabolism, Heart Failure genetics, Heart Failure metabolism, Nuclear Receptor Interacting Protein 1 genetics, Nuclear Receptor Interacting Protein 1 metabolism

Abstract

During the development of heart failure (HF), the capacity for cardiomyocyte (CM) fatty acid oxidation (FAO) and ATP production is progressively diminished, contributing to pathologic cardiac hypertrophy and contractile dysfunction. Receptor-interacting protein 140 (RIP140, encoded by Nrip1) has been shown to function as a transcriptional corepressor of oxidative metabolism. We found that mice with striated muscle deficiency of RIP140 (strNrip1-/-) exhibited increased expression of a broad array of genes involved in mitochondrial energy metabolism and contractile function in heart and skeletal muscle. strNrip1-/- mice were resistant to the development of pressure overload-induced cardiac hypertrophy, and CM-specific RIP140-deficient (csNrip1-/-) mice were protected against the development of HF caused by pressure overload combined with myocardial infarction. Genomic enhancers activated by RIP140 deficiency in CMs were enriched in binding motifs for transcriptional regulators of mitochondrial function (estrogen-related receptor) and cardiac contractile proteins (myocyte enhancer factor 2). Consistent with a role in the control of cardiac fatty acid oxidation, loss of RIP140 in heart resulted in augmented triacylglyceride turnover and fatty acid utilization. We conclude that RIP140 functions as a suppressor of a transcriptional regulatory network that controls cardiac fuel metabolism and contractile function, representing a potential therapeutic target for the treatment of HF.

Published

2023

4. Myocardial Metabolomics of Human Heart Failure With Preserved Ejection Fraction.

Author

Hahn VS, Petucci C, Kim MS, Bedi KC Jr, Wang H, Mishra S, Koleini N, Yoo EJ, Margulies KB, Arany Z, Kelly DP, Kass DA, and Sharma K

Subjects

Humans, Stroke Volume, Myocardium metabolism, Obesity pathology, Fatty Acids, Heart Failure metabolism, Diabetes Mellitus pathology

Abstract

Background: The human heart primarily metabolizes fatty acids, and this decreases as alternative fuel use rises in heart failure with reduced ejection fraction (HFrEF). Patients with severe obesity and diabetes are thought to have increased myocardial fatty acid metabolism, but whether this is found in those who also have heart failure with preserved ejection fraction (HFpEF) is unknown., Methods: Plasma and endomyocardial biopsies were obtained from HFpEF (n=38), HFrEF (n=30), and nonfailing donor controls (n=20). Quantitative targeted metabolomics measured organic acids, amino acids, and acylcarnitines in myocardium (72 metabolites) and plasma (69 metabolites). The results were integrated with reported RNA sequencing data. Metabolomics were analyzed using agnostic clustering tools, Kruskal-Wallis test with Dunn test, and machine learning., Results: Agnostic clustering of myocardial but not plasma metabolites separated disease groups. Despite more obesity and diabetes in HFpEF versus HFrEF (body mass index, 39.8 kg/m 2 versus 26.1 kg/m 2 ; diabetes, 70% versus 30%; both P <0.0001), medium- and long-chain acylcarnitines (mostly metabolites of fatty acid oxidation) were markedly lower in myocardium from both heart failure groups versus control. In contrast, plasma levels were no different or higher than control. Gene expression linked to fatty acid metabolism was generally lower in HFpEF versus control. Myocardial pyruvate was higher in HFpEF whereas the tricarboxylic acid cycle intermediates succinate and fumarate were lower, as were several genes controlling glucose metabolism. Non-branched-chain and branched-chain amino acids (BCAA) were highest in HFpEF myocardium, yet downstream BCAA metabolites and genes controlling BCAA metabolism were lower. Ketone levels were higher in myocardium and plasma of patients with HFrEF but not HFpEF. HFpEF metabolomic-derived subgroups were differentiated by only a few differences in BCAA metabolites., Conclusions: Despite marked obesity and diabetes, HFpEF myocardium exhibited lower fatty acid metabolites compared with HFrEF. Ketones and metabolites of the tricarboxylic acid cycle and BCAA were also lower in HFpEF, suggesting insufficient use of alternative fuels. These differences were not detectable in plasma and challenge conventional views of myocardial fuel use in HFpEF with marked diabetes and obesity and suggest substantial fuel inflexibility in this syndrome.

Published

2023

5. Ketones and the Heart: Metabolic Principles and Therapeutic Implications.

Author

Matsuura TR, Puchalska P, Crawford PA, and Kelly DP

Subjects

Humans, Ketones therapeutic use, 3-Hydroxybutyric Acid therapeutic use, Epigenesis, Genetic, Ketone Bodies therapeutic use, Ketone Bodies metabolism, Heart Failure metabolism, Ketosis drug therapy, Ketosis metabolism, Ketosis pathology

Abstract

The ketone bodies beta-hydroxybutyrate and acetoacetate are hepatically produced metabolites catabolized in extrahepatic organs. Ketone bodies are a critical cardiac fuel and have diverse roles in the regulation of cellular processes such as metabolism, inflammation, and cellular crosstalk in multiple organs that mediate disease. This review focuses on the role of cardiac ketone metabolism in health and disease with an emphasis on the therapeutic potential of ketosis as a treatment for heart failure (HF). Cardiac metabolic reprogramming, characterized by diminished mitochondrial oxidative metabolism, contributes to cardiac dysfunction and pathologic remodeling during the development of HF. Growing evidence supports an adaptive role for ketone metabolism in HF to promote normal cardiac function and attenuate disease progression. Enhanced cardiac ketone utilization during HF is mediated by increased availability due to systemic ketosis and a cardiac autonomous upregulation of ketolytic enzymes. Therapeutic strategies designed to restore high-capacity fuel metabolism in the heart show promise to address fuel metabolic deficits that underpin the progression of HF. However, the mechanisms involved in the beneficial effects of ketone bodies in HF have yet to be defined and represent important future lines of inquiry. In addition to use as an energy substrate for cardiac mitochondrial oxidation, ketone bodies modulate myocardial utilization of glucose and fatty acids, two vital energy substrates that regulate cardiac function and hypertrophy. The salutary effects of ketone bodies during HF may also include extra-cardiac roles in modulating immune responses, reducing fibrosis, and promoting angiogenesis and vasodilation. Additional pleotropic signaling properties of beta-hydroxybutyrate and AcAc are discussed including epigenetic regulation and protection against oxidative stress. Evidence for the benefit and feasibility of therapeutic ketosis is examined in preclinical and clinical studies. Finally, ongoing clinical trials are reviewed for perspective on translation of ketone therapeutics for the treatment of HF.

Published

2023

6. Defects in the Proteome and Metabolome in Human Hypertrophic Cardiomyopathy.

Author

Previs MJ, O'Leary TS, Morley MP, Palmer BM, LeWinter M, Yob JM, Pagani FD, Petucci C, Kim MS, Margulies KB, Arany Z, Kelly DP, and Day SM

Subjects

Adenosine Triphosphate metabolism, Amino Acids, Branched-Chain metabolism, Fatty Acids metabolism, Humans, Metabolome, Myocytes, Cardiac metabolism, Proteome, Proteomics, Cardiomyopathy, Hypertrophic, Heart Failure metabolism

Abstract

Background: Defects in energetics are thought to be central to the pathophysiology of hypertrophic cardiomyopathy (HCM); yet, the determinants of ATP availability are not known. The purpose of this study is to ascertain the nature and extent of metabolic reprogramming in human HCM, and its potential impact on contractile function., Methods: We conducted proteomic and targeted, quantitative metabolomic analyses on heart tissue from patients with HCM and from nonfailing control human hearts., Results: In the proteomic analysis, the greatest differences observed in HCM samples compared with controls were increased abundances of extracellular matrix and intermediate filament proteins and decreased abundances of muscle creatine kinase and mitochondrial proteins involved in fatty acid oxidation. These differences in protein abundance were coupled with marked reductions in acyl carnitines, byproducts of fatty acid oxidation, in HCM samples. Conversely, the ketone body 3-hydroxybutyrate, branched chain amino acids, and their breakdown products, were all significantly increased in HCM hearts. ATP content, phosphocreatine, nicotinamide adenine dinucleotide and its phosphate derivatives, NADP and NADPH, and acetyl CoA were also severely reduced in HCM compared with control hearts. Functional assays performed on human skinned myocardial fibers demonstrated that the magnitude of observed reduction in ATP content in the HCM samples would be expected to decrease the rate of cross-bridge detachment. Moreover, left atrial size, an indicator of diastolic compliance, was inversely correlated with ATP content in hearts from patients with HCM., Conclusions: HCM hearts display profound deficits in nucleotide availability with markedly reduced capacity for fatty acid oxidation and increases in ketone bodies and branched chain amino acids. These results have important therapeutic implications for the future design of metabolic modulators to treat HCM.

Published

2022

7. Glutaminolysis is Essential for Myofibroblast Persistence and In Vivo Targeting Reverses Fibrosis and Cardiac Dysfunction in Heart Failure.

Author

Gibb AA, Murray EK, Huynh AT, Gaspar RB, Ploesch TL, Bedi K, Lombardi AA, Lorkiewicz PK, Roy R, Arany Z, Kelly DP, Margulies KB, Hill BG, and Elrod JW

Subjects

Cells, Cultured, Fibrosis, Humans, Myocardium, Myofibroblasts pathology, Heart Diseases pathology, Heart Failure drug therapy, Heart Failure pathology

Published

2022

8. The nuclear receptor ERR cooperates with the cardiogenic factor GATA4 to orchestrate cardiomyocyte maturation.

Author

Sakamoto T, Batmanov K, Wan S, Guo Y, Lai L, Vega RB, and Kelly DP

Subjects

Gene Expression Regulation, Humans, Myocytes, Cardiac metabolism, GATA4 Transcription Factor genetics, GATA4 Transcription Factor metabolism, Heart Failure genetics, Heart Failure metabolism, Induced Pluripotent Stem Cells metabolism, Receptors, Estrogen genetics, Receptors, Estrogen metabolism

Abstract

Estrogen-related receptors (ERR) α and γ were shown recently to serve as regulators of cardiac maturation, yet the underlying mechanisms have not been delineated. Herein, we find that ERR signaling is necessary for induction of genes involved in mitochondrial and cardiac-specific contractile processes during human induced pluripotent stem cell-derived cardiomyocyte (hiPSC-CM) differentiation. Genomic interrogation studies demonstrate that ERRγ occupies many cardiomyocyte enhancers/super-enhancers, often co-localizing with the cardiogenic factor GATA4. ERRγ interacts with GATA4 to cooperatively activate transcription of targets involved in cardiomyocyte-specific processes such as contractile function, whereas ERRγ-mediated control of metabolic genes occurs independent of GATA4. Both mechanisms require the transcriptional coregulator PGC-1α. A disease-causing GATA4 mutation is shown to diminish PGC-1α/ERR/GATA4 cooperativity and expression of ERR target genes are downregulated in human heart failure samples suggesting that dysregulation of this circuitry may contribute to congenital and acquired forms of heart failure., (© 2022. The Author(s).)

Published

2022

9. Multimodality assessment of heart failure with preserved ejection fraction skeletal muscle reveals differences in the machinery of energy fuel metabolism.

Author

Zamani P, Proto EA, Wilson N, Fazelinia H, Ding H, Spruce LA, Davila A Jr, Hanff TC, Mazurek JA, Prenner SB, Desjardins B, Margulies KB, Kelly DP, Arany Z, Doulias PT, Elrod JW, Allen ME, McCormack SE, Schur GM, D'Aquilla K, Kumar D, Thakuri D, Prabhakaran K, Langham MC, Poole DC, Seeholzer SH, Reddy R, Ischiropoulos H, and Chirinos JA

Subjects

Exercise Tolerance, Humans, Muscle, Skeletal metabolism, Oxygen Consumption, Proteomics, Stroke Volume, Heart Failure diagnosis, Heart Failure metabolism

Abstract

Aims: Skeletal muscle (SkM) abnormalities may impact exercise capacity in patients with heart failure with preserved ejection fraction (HFpEF). We sought to quantify differences in SkM oxidative phosphorylation capacity (OxPhos), fibre composition, and the SkM proteome between HFpEF, hypertensive (HTN), and healthy participants., Methods and Results: Fifty-nine subjects (20 healthy, 19 HTN, and 20 HFpEF) performed a maximal-effort cardiopulmonary exercise test to define peak oxygen consumption (VO 2, peak ), ventilatory threshold (VT), and VO 2 efficiency (ratio of total work performed to O 2 consumed). SkM OxPhos was assessed using Creatine Chemical-Exchange Saturation Transfer (CrCEST, n = 51), which quantifies unphosphorylated Cr, before and after plantar flexion exercise. The half-time of Cr recovery (t 1/2, Cr ) was taken as a metric of in vivo SkM OxPhos. In a subset of subjects (healthy = 13, HTN = 9, and HFpEF = 12), percutaneous biopsy of the vastus lateralis was performed for myofibre typing, mitochondrial morphology, and proteomic and phosphoproteomic analysis. HFpEF subjects demonstrated lower VO 2,peak , VT, and VO 2 efficiency than either control group (all P < 0.05). The t 1/2, Cr was significantly longer in HFpEF (P = 0.005), indicative of impaired SkM OxPhos, and correlated with cycle ergometry exercise parameters. HFpEF SkM contained fewer Type I myofibres (P = 0.003). Proteomic analyses demonstrated (a) reduced levels of proteins related to OxPhos that correlated with exercise capacity and (b) reduced ERK signalling in HFpEF., Conclusions: Heart failure with preserved ejection fraction patients demonstrate impaired functional capacity and SkM OxPhos. Reductions in the proportions of Type I myofibres, proteins required for OxPhos, and altered phosphorylation signalling in the SkM may contribute to exercise intolerance in HFpEF., (© 2021 The Authors. ESC Heart Failure published by John Wiley & Sons Ltd on behalf of European Society of Cardiology.)

Published

2021

10. Ketone Ester Treatment Improves Cardiac Function and Reduces Pathologic Remodeling in Preclinical Models of Heart Failure.

Author

Yurista SR, Matsuura TR, Silljé HHW, Nijholt KT, McDaid KS, Shewale SV, Leone TC, Newman JC, Verdin E, van Veldhuisen DJ, de Boer RA, Kelly DP, and Westenbrink BD

Subjects

Adenosine Triphosphate metabolism, Animals, Aorta surgery, Atrial Natriuretic Factor metabolism, Constriction, Pathologic, Fibrosis, Heart Failure metabolism, Heart Failure pathology, Heart Ventricles metabolism, Heart Ventricles pathology, Mice, Myocardial Infarction metabolism, Myocardial Infarction pathology, Myocardium pathology, Myocytes, Cardiac pathology, Organ Size, Rats, Ventricular Dysfunction, Left metabolism, Ventricular Dysfunction, Left pathology, Ventricular Function, Left, Dietary Supplements, Heart Failure physiopathology, Hydroxybutyrates, Myocardial Infarction physiopathology, Myocardium metabolism, Stroke Volume physiology, Ventricular Dysfunction, Left physiopathology

Abstract

Background: Accumulating evidence suggests that the failing heart reprograms fuel metabolism toward increased utilization of ketone bodies and that increasing cardiac ketone delivery ameliorates cardiac dysfunction. As an initial step toward development of ketone therapies, we investigated the effect of chronic oral ketone ester (KE) supplementation as a prevention or treatment strategy in rodent heart failure models., Methods: Two independent rodent heart failure models were used for the studies: transverse aortic constriction/myocardial infarction (MI) in mice and post-MI remodeling in rats. Seventy-five mice underwent a prevention treatment strategy with a KE comprised of hexanoyl-hexyl-3-hydroxybutyrate KE (KE-1) diet, and 77 rats were treated in either a prevention or treatment regimen using a commercially available β-hydroxybutyrate-(R)-1,3-butanediol monoester (DeltaG; KE-2) diet., Results: The KE-1 diet in mice elevated β-hydroxybutyrate levels during nocturnal feeding, whereas the KE-2 diet in rats induced ketonemia throughout a 24-hour period. The KE-1 diet preventive strategy attenuated development of left ventricular dysfunction and remodeling post-transverse aortic constriction/MI (left ventricular ejection fraction±SD, 36±8 in vehicle versus 45±11 in KE-1; P =0.016). The KE-2 diet therapeutic approach also attenuated left ventricular dysfunction and remodeling post-MI (left ventricular ejection fraction, 41±11 in MI-vehicle versus 61±7 in MI-KE-2; P <0.001). In addition, ventricular weight, cardiomyocyte cross-sectional area, and the expression of ANP (atrial natriuretic peptide) were significantly attenuated in the KE-2-treated MI group. However, treatment with KE-2 did not influence cardiac fibrosis post-MI. The myocardial expression of the ketone transporter and 2 ketolytic enzymes was significantly increased in rats fed KE-2 diet along with normalization of myocardial ATP levels to sham values., Conclusions: Chronic oral supplementation with KE was effective in both prevention and treatment of heart failure in 2 preclinical animal models. In addition, our results indicate that treatment with KE reprogrammed the expression of genes involved in ketone body utilization and normalized myocardial ATP production following MI, consistent with provision of an auxiliary fuel. These findings provide rationale for the assessment of KEs as a treatment for patients with heart failure.

Published

2021

11. Extreme Acetylation of the Cardiac Mitochondrial Proteome Does Not Promote Heart Failure.

Author

Davidson MT, Grimsrud PA, Lai L, Draper JA, Fisher-Wellman KH, Narowski TM, Abraham DM, Koves TR, Kelly DP, and Muoio DM

Subjects

Acetylation, Animals, Carnitine O-Acetyltransferase deficiency, Carnitine O-Acetyltransferase genetics, Disease Models, Animal, Energy Metabolism, Heart Failure genetics, Heart Failure physiopathology, Lysine, Male, Mice, Inbred C57BL, Mice, Knockout, Oxidative Stress, Protein Processing, Post-Translational, Proteomics, Sirtuin 3 deficiency, Sirtuin 3 genetics, Heart Failure metabolism, Mitochondria, Heart metabolism, Mitochondrial Proteins metabolism, Myocytes, Cardiac metabolism, Proteome

Abstract

Rationale: Circumstantial evidence links the development of heart failure to posttranslational modifications of mitochondrial proteins, including lysine acetylation (Kac). Nonetheless, direct evidence that Kac compromises mitochondrial performance remains sparse., Objective: This study sought to explore the premise that mitochondrial Kac contributes to heart failure by disrupting oxidative metabolism., Methods and Results: A DKO (dual knockout) mouse line with deficiencies in CrAT (carnitine acetyltransferase) and Sirt3 (sirtuin 3)-enzymes that oppose Kac by buffering the acetyl group pool and catalyzing lysine deacetylation, respectively-was developed to model extreme mitochondrial Kac in cardiac muscle, as confirmed by quantitative acetyl-proteomics. The resulting impact on mitochondrial bioenergetics was evaluated using a respiratory diagnostics platform that permits comprehensive assessment of mitochondrial function and energy transduction. Susceptibility of DKO mice to heart failure was investigated using transaortic constriction as a model of cardiac pressure overload. The mitochondrial acetyl-lysine landscape of DKO hearts was elevated well beyond that observed in response to pressure overload or Sirt3 deficiency alone. Relative changes in the abundance of specific acetylated lysine peptides measured in DKO versus Sirt3 KO hearts were strongly correlated. A proteomics comparison across multiple settings of hyperacetylation revealed ≈86% overlap between the populations of Kac peptides affected by the DKO manipulation as compared with experimental heart failure. Despite the severity of cardiac Kac in DKO mice relative to other conditions, deep phenotyping of mitochondrial function revealed a surprisingly normal bioenergetics profile. Thus, of the >120 mitochondrial energy fluxes evaluated, including substrate-specific dehydrogenase activities, respiratory responses, redox charge, mitochondrial membrane potential, and electron leak, we found minimal evidence of oxidative insufficiencies. Similarly, DKO hearts were not more vulnerable to dysfunction caused by transaortic constriction-induced pressure overload., Conclusions: The findings challenge the premise that hyperacetylation per se threatens metabolic resilience in the myocardium by causing broad-ranging disruption to mitochondrial oxidative machinery.

Published

2020

12. A Case for Adaptive Cardiac Hypertrophic Remodeling Is CITED.

Author

Sakamoto T and Kelly DP

Subjects

Humans, Transcription Factors, Cardiomegaly, Heart Failure

Published

2020

13. Implications of Altered Ketone Metabolism and Therapeutic Ketosis in Heart Failure.

Author

Selvaraj S, Kelly DP, and Margulies KB

Subjects

Animals, Biomarkers, Cardiac Output, Low etiology, Cardiac Output, Low metabolism, Cardiotonic Agents therapeutic use, Diet, Ketogenic, Energy Metabolism, Fatty Acids metabolism, Glucose metabolism, Heart Failure complications, Heart Failure diet therapy, Heart Failure drug therapy, Humans, Ketone Bodies metabolism, Ketones administration & dosage, Ketones therapeutic use, Liver metabolism, Mice, Myocardial Reperfusion Injury drug therapy, Myocardial Reperfusion Injury etiology, Rats, Inbred Dahl, Sodium-Glucose Transporter 2 Inhibitors therapeutic use, Stroke Volume, Heart Failure metabolism, Ketones metabolism, Ketosis metabolism

Abstract

Despite existing therapy, patients with heart failure (HF) experience substantial morbidity and mortality, highlighting the urgent need to identify novel pathophysiological mechanisms and therapies, as well. Traditional models for pharmacological intervention have targeted neurohormonal axes and hemodynamic disturbances in HF. However, several studies have now highlighted the potential for ketone metabolic modulation as a promising treatment paradigm. During the pathophysiological progression of HF, the failing heart reduces fatty acid and glucose oxidation, with associated increases in ketone metabolism. Recent studies indicate that enhanced myocardial ketone use is adaptive in HF, and limited data demonstrate beneficial effects of exogenous ketone therapy in studies of animal models and humans with HF. This review will summarize current evidence supporting a salutary role for ketones in HF including (1) normal myocardial ketone use, (2) alterations in ketone metabolism in the failing heart, (3) effects of therapeutic ketosis in animals and humans with HF, and (4) the potential significance of ketosis associated with sodium-glucose cotransporter 2 inhibitors. Although a number of important questions remain regarding the use of therapeutic ketosis and mechanism of action in HF, current evidence suggests potential benefit, in particular, in HF with reduced ejection fraction, with theoretical rationale for its use in HF with preserved ejection fraction. Although it is early in its study and development, therapeutic ketosis across the spectrum of HF holds significant promise.

Published

2020

14. Unlocking the Secrets of Mitochondria in the Cardiovascular System: Path to a Cure in Heart Failure—A Report from the 2018 National Heart, Lung, and Blood Institute Workshop

Author

Tian R, Colucci WS, Arany Z, Bachschmid MM, Ballinger SW, Boudina S, Bruce JE, Busija DW, Dikalov S, Dorn GW II, Galis ZS, Gottlieb RA, Kelly DP, Kitsis RN, Kohr MJ, Levy D, Lewandowski ED, McClung JM, Mochly-Rosen D, O'Brien KD, O'Rourke B, Park JY, Ping P, Sack MN, Sheu SS, Shi Y, Shiva S, Wallace DC, Weiss RG, Vernon HJ, Wong R, and Schwartz Longacre L

Subjects

Biomedical Research methods, Biomedical Research trends, Education trends, Heart Failure diagnosis, Heart Failure epidemiology, Humans, Translational Research, Biomedical methods, Translational Research, Biomedical trends, United States epidemiology, Cardiovascular System pathology, Education methods, Heart Failure therapy, Mitochondria physiology, National Heart, Lung, and Blood Institute (U.S.) trends, Research Report trends

Abstract

Mitochondria have emerged as a central factor in the pathogenesis and progression of heart failure, and other cardiovascular diseases, as well, but no therapies are available to treat mitochondrial dysfunction. The National Heart, Lung, and Blood Institute convened a group of leading experts in heart failure, cardiovascular diseases, and mitochondria research in August 2018. These experts reviewed the current state of science and identified key gaps and opportunities in basic, translational, and clinical research focusing on the potential of mitochondria-based therapeutic strategies in heart failure. The workshop provided short- and long-term recommendations for moving the field toward clinical strategies for the prevention and treatment of heart failure and cardiovascular diseases by using mitochondria-based approaches., (© 2019 American Heart Association, Inc.)

Published

2019

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

Author

Ho KL, Zhang L, Wagg C, Al Batran R, Gopal K, Levasseur J, Leone T, Dyck JRB, Ussher JR, Muoio DM, Kelly DP, and Lopaschuk GD

Subjects

Acetylation, Acyl-CoA Dehydrogenase, Long-Chain genetics, Acyl-CoA Dehydrogenase, Long-Chain metabolism, Adaptation, Physiological, Animals, Disease Models, Animal, Fatty Acids metabolism, Glucose metabolism, Heart Failure pathology, Heart Failure physiopathology, Hypertrophy, Left Ventricular pathology, Hypertrophy, Left Ventricular physiopathology, Male, Mice, Inbred C57BL, Myocardium pathology, Oxidation-Reduction, Stroke Volume, 3-Hydroxybutyric Acid metabolism, Energy Metabolism, Heart Failure metabolism, Hypertrophy, Left Ventricular metabolism, Myocardium metabolism, Ventricular Function, Left

Abstract

Aims: The failing heart is energy-starved and inefficient due to perturbations in energy metabolism. Although ketone oxidation has been shown recently to increase in the failing heart, it remains unknown whether this improves cardiac energy production or efficiency. We therefore assessed cardiac metabolism in failing hearts and determined whether increasing ketone oxidation improves cardiac energy production and efficiency., Methods and Results: C57BL/6J mice underwent sham or transverse aortic constriction (TAC) surgery to induce pressure overload hypertrophy over 4-weeks. Isolated working hearts from these mice were perfused with radiolabelled β-hydroxybutyrate (βOHB), glucose, or palmitate to assess cardiac metabolism. Ejection fraction decreased by 45% in TAC mice. Failing hearts had decreased glucose oxidation while palmitate oxidation remained unchanged, resulting in a 35% decrease in energy production. Increasing βOHB levels from 0.2 to 0.6 mM increased ketone oxidation rates from 251 ± 24 to 834 ± 116 nmol·g dry wt-1 · min-1 in TAC hearts, rates which were significantly increased compared to sham hearts and occurred without decreasing glycolysis, glucose, or palmitate oxidation rates. Therefore, the contribution of ketones to energy production in TAC hearts increased to 18% and total energy production increased by 23%. Interestingly, glucose oxidation, in parallel with total ATP production, was also significantly upregulated in hearts upon increasing βOHB levels. However, while overall energy production increased, cardiac efficiency was not improved., Conclusions: Increasing ketone oxidation rates in failing hearts increases overall energy production without compromising glucose or fatty acid metabolism, albeit without increasing cardiac efficiency., (Published on behalf of the European Society of Cardiology. All rights reserved. © The Author(s) 2019. For permissions, please email: journals.permissions@oup.com.)

Published

2019

16. Mitochondrial Dysfunction in Heart Failure With Preserved Ejection Fraction.

Author

Kumar AA, Kelly DP, and Chirinos JA

Subjects

Adenosine Triphosphate metabolism, Animals, Heart Failure pathology, Heart Failure physiopathology, Humans, Mitochondria, Heart pathology, Mitochondria, Muscle pathology, Muscle, Skeletal pathology, Muscle, Skeletal physiopathology, Myocytes, Cardiac pathology, Oxygen Consumption, Energy Metabolism, Exercise Tolerance, Heart Failure metabolism, Mitochondria, Heart metabolism, Mitochondria, Muscle metabolism, Muscle, Skeletal metabolism, Myocytes, Cardiac metabolism, Stroke Volume, Ventricular Function, Left

Abstract

Heart failure with preserved ejection fraction (HFpEF) is a complex syndrome with an increasingly recognized heterogeneity in pathophysiology. Exercise intolerance is the hallmark of HFpEF and appears to be caused by both cardiac and peripheral abnormalities in the arterial tree and skeletal muscle. Mitochondrial abnormalities can significantly contribute to impaired oxygen utilization and the resulting exercise intolerance in HFpEF. We review key aspects of the complex biology of this organelle, the clinical relevance of mitochondrial function, the methods that are currently available to assess mitochondrial function in humans, and the evidence supporting a role for mitochondrial dysfunction in the pathophysiology of HFpEF. We also discuss the role of mitochondrial function as a therapeutic target, some key considerations for the design of early-phase clinical trials using agents that specifically target mitochondrial function to improve symptoms in patients with HFpEF, and ongoing trials with mitochondrial agents in HFpEF.

Published

2019

17. The failing heart utilizes 3-hydroxybutyrate as a metabolic stress defense.

Author

Horton JL, Davidson MT, Kurishima C, Vega RB, Powers JC, Matsuura TR, Petucci C, Lewandowski ED, Crawford PA, Muoio DM, Recchia FA, and Kelly DP

Subjects

Animals, Disease Models, Animal, Disease Progression, Dogs, Female, Heart Failure etiology, Heart Failure pathology, Heart Ventricles cytology, Heart Ventricles pathology, Humans, Hydroxybutyrate Dehydrogenase genetics, Hydroxybutyrate Dehydrogenase metabolism, Isolated Heart Preparation, Male, Mice, Mice, Knockout, Mitochondria metabolism, Mitochondria pathology, Myocardium cytology, Myocardium pathology, Oxidation-Reduction, Stress, Physiological, Thermodynamics, Ventricular Remodeling, 3-Hydroxybutyric Acid metabolism, Energy Metabolism, Heart Failure metabolism, Heart Ventricles metabolism, Myocardium metabolism

Abstract

Evidence has emerged that the failing heart increases utilization of ketone bodies. We sought to determine whether this fuel shift is adaptive. Mice rendered incapable of oxidizing the ketone body 3-hydroxybutyrate (3OHB) in the heart exhibited worsened heart failure in response to fasting or a pressure overload/ischemic insult compared with WT controls. Increased delivery of 3OHB ameliorated pathologic cardiac remodeling and dysfunction in mice and in a canine pacing model of progressive heart failure. 3OHB was shown to enhance bioenergetic thermodynamics of isolated mitochondria in the context of limiting levels of fatty acids. These results indicate that the heart utilizes 3OHB as a metabolic stress defense and suggest that strategies aimed at increasing ketone delivery to the heart could prove useful in the treatment of heart failure.

Published

2019

18. The Failing Heart Relies on Ketone Bodies as a Fuel.

Author

Aubert G, Martin OJ, Horton JL, Lai L, Vega RB, Leone TC, Koves T, Gardell SJ, Krüger M, Hoppel CL, Lewandowski ED, Crawford PA, Muoio DM, and Kelly DP

Subjects

Animals, Female, Gene Expression Profiling methods, Heart Failure diet therapy, Mice, Mice, Inbred C57BL, Diet, Ketogenic methods, Fatty Acids metabolism, Heart Failure metabolism, Heart Failure pathology, Ketone Bodies metabolism

Abstract

Background: Significant evidence indicates that the failing heart is energy starved. During the development of heart failure, the capacity of the heart to utilize fatty acids, the chief fuel, is diminished. Identification of alternate pathways for myocardial fuel oxidation could unveil novel strategies to treat heart failure., Methods and Results: Quantitative mitochondrial proteomics was used to identify energy metabolic derangements that occur during the development of cardiac hypertrophy and heart failure in well-defined mouse models. As expected, the amounts of proteins involved in fatty acid utilization were downregulated in myocardial samples from the failing heart. Conversely, expression of β-hydroxybutyrate dehydrogenase 1, a key enzyme in the ketone oxidation pathway, was increased in the heart failure samples. Studies of relative oxidation in an isolated heart preparation using ex vivo nuclear magnetic resonance combined with targeted quantitative myocardial metabolomic profiling using mass spectrometry revealed that the hypertrophied and failing heart shifts to oxidizing ketone bodies as a fuel source in the context of reduced capacity to oxidize fatty acids. Distinct myocardial metabolomic signatures of ketone oxidation were identified., Conclusions: These results indicate that the hypertrophied and failing heart shifts to ketone bodies as a significant fuel source for oxidative ATP production. Specific metabolite biosignatures of in vivo cardiac ketone utilization were identified. Future studies aimed at determining whether this fuel shift is adaptive or maladaptive could unveil new therapeutic strategies for heart failure., (© 2016 American Heart Association, Inc.)

Published

2016

19. Novel mouse model of left ventricular pressure overload and infarction causing predictable ventricular remodelling and progression to heart failure.

Author

Weinheimer CJ, Lai L, Kelly DP, and Kovacs A

Subjects

Animals, Female, Heart Failure physiopathology, Hypertrophy, Left Ventricular physiopathology, Mice, Mice, Inbred C57BL, Ultrasonography, Ventricular Dysfunction, Left diagnostic imaging, Ventricular Dysfunction, Left physiopathology, Disease Models, Animal, Disease Progression, Heart Failure diagnostic imaging, Hypertrophy, Left Ventricular diagnostic imaging, Ventricular Remodeling physiology

Abstract

Mouse surgical models are important tools for evaluating mechanisms of human cardiac disease. The clinically relevant comorbidities of hypertension and ischaemia have not been explored in mice. We have developed a surgical approach that combines transverse aortic constriction and distal left anterior coronary ligation (MI) to produce a gradual and predictable progression of adverse left ventricular (LV) remodelling that leads to heart failure (HF). Mice received either sham, MI alone, transverse aortic constriction alone or HF surgery. Infarct size and LV remodelling were evaluated by serial 2-D echocardiograms. Transverse aortic constriction gradients were measured by the Doppler velocity-time integral ratio between constricted and proximal aortic velocities. At 4 weeks, hearts were weighed and analysed for histology and brain natriuretic peptide, a molecular marker of HF. Echocardiographic analysis of segmental wall motion scores showed similarly small apical infarct sizes in the MI and HF groups at day 1 postsurgery. MI alone showed little change in infarct size over 4 weeks (0.26 ± 0.02 to 0.27 ± 0.04, P = 0.77); however, HF mice showed infarct expansion (0.25 ± 0.06 to 0.39 ± 0.09, P < 0.05). HF mice also showed LV remodelling with increases in LV volumes (1 day = 36.5 ± 5.2 mL, 28 days = 89.1 ± 16.0 mL) versus no significant changes in the other groups. Furthermore, systolic function progressively deteriorated in the HF group only (ejection fraction, 1 day = 55.6 ± 3.6%, 28 days = 17.6 ± 4.1%, P < 0.05) with an increase of brain natriuretic peptide by 3.5-fold. This surgical model of pressure overload in the setting of a small infarction causes progressive deterioration of cardiac structural and functional properties, and provides a clinically relevant tool to study adverse LV remodelling and heart failure., (© 2014 Wiley Publishing Asia Pty Ltd.)

Published

2015

20. Energy metabolic reprogramming in the hypertrophied and early stage failing heart: a multisystems approach.

Author

Lai L, Leone TC, Keller MP, Martin OJ, Broman AT, Nigro J, Kapoor K, Koves TR, Stevens R, Ilkayeva OR, Vega RB, Attie AD, Muoio DM, and Kelly DP

Subjects

Amino Acids metabolism, Animals, Disease Models, Animal, Down-Regulation physiology, Energy Metabolism genetics, Gene Expression Profiling, Heart Failure metabolism, Lipid Metabolism genetics, Metabolome, Mice, Up-Regulation physiology, Cardiomegaly physiopathology, Energy Metabolism physiology, Heart Failure physiopathology, Ventricular Remodeling physiology

Abstract

Background: An unbiased systems approach was used to define energy metabolic events that occur during the pathological cardiac remodeling en route to heart failure (HF)., Methods and Results: Combined myocardial transcriptomic and metabolomic profiling were conducted in a well-defined mouse model of HF that allows comparative assessment of compensated and decompensated (HF) forms of cardiac hypertrophy because of pressure overload. The pressure overload data sets were also compared with the myocardial transcriptome and metabolome for an adaptive (physiological) form of cardiac hypertrophy because of endurance exercise training. Comparative analysis of the data sets led to the following conclusions: (1) expression of most genes involved in mitochondrial energy transduction were not significantly changed in the hypertrophied or failing heart, with the notable exception of a progressive downregulation of transcripts encoding proteins and enzymes involved in myocyte fatty acid transport and oxidation during the development of HF; (2) tissue metabolite profiles were more broadly regulated than corresponding metabolic gene regulatory changes, suggesting significant regulation at the post-transcriptional level; (3) metabolomic signatures distinguished pathological and physiological forms of cardiac hypertrophy and served as robust markers for the onset of HF; and (4) the pattern of metabolite derangements in the failing heart suggests bottlenecks of carbon substrate flux into the Krebs cycle., Conclusions: Mitochondrial energy metabolic derangements that occur during the early development of pressure overload-induced HF involve both transcriptional and post-transcriptional events. A subset of the myocardial metabolomic profile robustly distinguished pathological and physiological cardiac remodeling., (© 2014 American Heart Association, Inc.)

Published

2014

21. Perturbations in the gene regulatory pathways controlling mitochondrial energy production in the failing heart.

Author

Aubert G, Vega RB, and Kelly DP

Subjects

Adenosine Triphosphate biosynthesis, Adult, Cardiomegaly complications, Cardiomegaly metabolism, Cardiomegaly physiopathology, Energy Metabolism genetics, Gene Expression Regulation, Heart Failure etiology, Heart Failure metabolism, Heart Failure physiopathology, Humans, Mitochondria genetics, Myocardium pathology, PPAR gamma metabolism, Protein Isoforms genetics, Protein Isoforms metabolism, Signal Transduction, Cardiomegaly genetics, Gene Regulatory Networks, Heart Failure genetics, Mitochondria metabolism, Myocardium metabolism, PPAR gamma genetics

Abstract

The heart is an omnivore organ that requires constant energy production to match its functional demands. In the adult heart, adenosine-5'-triphosphate (ATP) production occurs mainly through mitochondrial fatty acid and glucose oxidation. The heart must constantly adapt its energy production in response to changes in substrate supply and work demands across diverse physiologic and pathophysiologic conditions. The cardiac myocyte maintains a high level of mitochondrial ATP production through a complex transcriptional regulatory network that is orchestrated by the members of the peroxisome proliferator-activated receptor gamma coactivator-1 (PGC-1) family. There is increasing evidence that during the development of cardiac hypertrophy and in the failing heart, the activity of this network, including PGC-1, is altered. This review summarizes our current understanding of the perturbations in the gene regulatory pathways that occur during the development of heart failure. An appreciation of the role this regulatory circuitry serves in the regulation of cardiac energy metabolism may unveil novel therapeutic targets aimed at the metabolic disturbances that presage heart failure. This article is part of a Special Issue entitled:Cardiomyocyte Biology: Cardiac Pathways of Differentiation, Metabolism and Contraction., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2013

22. The PGC-1 cascade as a therapeutic target for heart failure.

Author

Schilling J and Kelly DP

Subjects

Animals, Gene Expression Regulation, Gene Regulatory Networks, Heart physiopathology, Heart Failure metabolism, Heart Failure physiopathology, Humans, Molecular Targeted Therapy, Myocardium metabolism, Receptors, Estrogen metabolism, Heart Failure drug therapy, Signal Transduction drug effects, Transcription Factors metabolism

Abstract

The PPARγ coactivator-1 (PGC-1) family of transcriptional coactivators, together with estrogen related receptors (ERRs), plays a key role in regulating genes involved in myocardial fuel metabolism and cardiac function. Increasing evidence implicates dysregulation of this transcriptional regulatory circuit in the metabolic and functional disturbances that presage heart failure due to common diseases such as hypertension and diabetes. Accordingly, the PGC-1/ERR axis is a plausible candidate therapeutic target for novel therapeutics aimed at reversing the energy metabolic disturbances that contribute to heart failure. This review describes the biologic actions of the PGC-1 and ERR cascade and summarizes the evidence that dysregulation of this transcriptional regulatory circuit contributes to heart failure. Potential strategies to modulate this target pathway are reviewed. This article is part of a special issue entitled "Key Signaling Molecules in Hypertrophy and Heart Failure.", (Copyright © 2010 Elsevier Ltd. All rights reserved.)

Published

2011

23. Toll-like receptor-mediated inflammatory signaling reprograms cardiac energy metabolism by repressing peroxisome proliferator-activated receptor γ coactivator-1 signaling.

Author

Schilling J, Lai L, Sambandam N, Dey CE, Leone TC, and Kelly DP

Subjects

Animals, Cells, Cultured, Disease Models, Animal, Fatty Acids metabolism, Heart Failure chemically induced, Heart Failure physiopathology, Lipid Metabolism drug effects, Lipid Metabolism physiology, Lipopolysaccharides adverse effects, Lipopolysaccharides pharmacology, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Myocardium pathology, Myocytes, Cardiac drug effects, Myocytes, Cardiac metabolism, Myocytes, Cardiac pathology, NF-kappa B metabolism, Reactive Oxygen Species metabolism, Signal Transduction drug effects, Toll-Like Receptor 4 genetics, Transcription Factors metabolism, Energy Metabolism physiology, Heart Failure metabolism, Myocardium metabolism, Signal Transduction physiology, Toll-Like Receptor 4 metabolism, Transcription Factors antagonists & inhibitors

Abstract

Background: Currently, there are no specific therapies available to treat cardiac dysfunction caused by sepsis and other chronic inflammatory conditions. Activation of toll-like receptor 4 (TLR4) by lipopolysaccharide (LPS) is an early event in Gram-negative bacterial sepsis, triggering a robust inflammatory response and changes in metabolism. Peroxisome proliferator-activated receptor-γ coactivator-1 (PGC-1) α and β serve as critical physiological regulators of energy metabolic gene expression in heart., Methods and Results: Injection of mice with LPS triggered a myocardial fuel switch similar to that of the failing heart: reduced mitochondrial substrate flux and myocyte lipid accumulation. The LPS-induced metabolic changes were associated with diminished ventricular function and suppression of the genes encoding PGC-1α and β, known transcriptional regulators of mitochondrial function. This cascade of events required TLR4 and nuclear factor-κB activation. Restoration of PGC-1β expression in cardiac myocytes in culture and in vivo in mice reversed the gene regulatory, metabolic, and functional derangements triggered by LPS. Interestingly, the effects of PGC-1β overexpression were independent of the upstream inflammatory response, highlighting the potential utility of modulating downstream metabolic derangements in cardiac myocytes as a novel strategy to prevent or treat sepsis-induced heart failure., Conclusions: LPS triggers cardiac energy metabolic reprogramming through suppression of PGC-1 coactivators in the cardiac myocyte. Reactivation of PGC-1β expression can reverse the metabolic and functional derangements caused by LPS-TLR4 activation, identifying the PGC-1 axis as a candidate therapeutic target for sepsis-induced heart failure.

Published

2011

24. The PPAR trio: regulators of myocardial energy metabolism in health and disease.

Author

Madrazo JA and Kelly DP

Subjects

Animals, Diabetes Mellitus genetics, Diabetes Mellitus metabolism, Fatty Acids genetics, Glucose genetics, Heart Failure genetics, Humans, Hypertension genetics, Hypertension metabolism, Mice, Peroxisome Proliferator-Activated Receptors genetics, Energy Metabolism genetics, Fatty Acids metabolism, Gene Expression Regulation genetics, Glucose metabolism, Heart Failure metabolism, Myocardium metabolism, Peroxisome Proliferator-Activated Receptors metabolism

Abstract

Common causes of heart failure are associated with derangements in myocardial fuel utilization. Evidence is emerging that metabolic abnormalities may contribute to the development and progression of myocardial disease. The peroxisome proliferator-activated receptor (PPAR) family of nuclear receptor transcription factors has been shown to regulate cardiac fuel metabolism at the gene expression level. The three PPAR family members (alpha, beta/delta and gamma) are uniquely suited to serve as transducers of developmental, physiological, and dietary cues that influence cardiac fatty acid and glucose metabolism. This review describes murine PPAR loss- and gain-of-function models that have shed light on the roles of these receptors in regulating myocardial metabolic pathways and have defined key links to disease states including the hypertensive and diabetic heart.

Published

2008

25. Transcriptional Control of Mitochondrial Biogenesis and Maturation

Author

Vega, Rick B., Leone, Teresa C., Kelly, Daniel P., Dhalla, Naranjan S., Series editor, and Lopaschuk, Gary D., editor

Published

2014

26. Gene Regulatory Mechanisms Governing Energy Metabolism during Cardiac Hypertrophic Growth

Author

Lehman, John J. and Kelly, Daniel P.

Published

2002

27. PGC1α Plays a Critical Role in TWEAK-Induced Cardiac Dysfunction.

Author

Jianru Shi, Bingbing Jiang, Yiling Qiu, Jian Guan, Jain, Mohit, Xin Cao, Bauer, Michael, Lihe Su, Burkly, Linda C., Leone, Teresa C., Kelly, Daniel P., and Liao, Ronglih

Subjects

CYTOKINES, HEART failure, TUMOR necrosis factors, CARDIOMYOPATHIES, PEROXISOMES, ADENOVIRUSES

Abstract

Background: Inflammatory cytokines play an important role in the pathogenesis of heart failure. We have recently found the cytokine TWEAK (tumor necrosis factor (TNF)-like weak inducer of apoptosis), a member of the TNF superfamily, to be increased in patients with cardiomyopathy and result in the development of heart failure when overexpressed in mice. The molecular mechanisms underlying TWEAK-induced cardiac pathology, however, remain unknown. Methodology and Critical Finding: Using mouse models of elevated circulating TWEAK levels, established through intravenous injection of adenovirus expressing TWEAK or recombinant TWEAK protein, we find that TWEAK induces a progressive dilated cardiomyopathy with impaired contractile function in mice. Moreover, TWEAK treatment is associated with decreased expression of peroxisome proliferator-activated receptor gamma coactivator-1α (PGC1α) and genes required for mitochondrial oxidative phosphorylation, which precede the onset of cardiac dysfunction. TWEAK-induced downregulation of PGC1α requires expression of its cell surface receptor, fibroblast growth factor-inducible 14 (Fn14). We further find that TWEAK downregulates PGC1α gene expression via the TNF receptor-associated factor 2 (TRAF2) and NFκB signaling pathways. Maintaining PGC1α levels through adenoviral-mediated gene expression is sufficient to protect against TWEAK-induced cardiomyocyte dysfunction. Conclusion: Collectively, our data suggest that TWEAK induces cardiac dysfunction via downregulation of PGC1α, through FN14-TRAF2-NFκB-dependent signaling. Selective targeting of the FN14-TRAF2-NFκB-dependent signaling pathway or augmenting PGC1α levels may serve as novel therapeutic strategies for cardiomyopathy and heart failure. [ABSTRACT FROM AUTHOR]

Published

2013

28. EXAMINING RENAL PATIENTS' DEATH TRAJECTORIES WITHOUT DIALYSIS.

Author

Noble, Helen, Meyer, Julienne, Bridges, Jackie, Kelly, Daniel, and Johnson, Barbara

Subjects

KIDNEY diseases, QUALITATIVE research, DIALYSIS (Chemistry), PATIENT-professional relations, HEART failure, DISEASE management, MEDICAL care, PATIENTS

Abstract

Background: Minimal work has been carried out into dying trajectories of people with stage-5 (end-stage) chronic kidney disease (CKD). Consequently, little is known about such patients and how they and their families/loved ones cope with the dying phase of the disease. Aim: This article reports on part of a larger, qualitative study exploring the experiences and trajectory towards death of people with stage-5 CKD who decided not to undergo dialysis. It provides case studies to illustrate the encountered death trajectories. Methods: Interview data were gathered during naturally occurring consultations with patients with stage-5 CKD and/or carers who were seen at a nurse-led, renal supportive care service. All patients referred to the service were asked to participate. Thirty patients and 17 carers were recruited. Patients were seen at approximately 3-month intervals until they died or the study finished. Carers took part in the consultation when present. Eighty-two consultations were included in the wider study. Results: Although the expectation was that patients would die from renal failure following a gradual decline in functional status, this was not always the case. The study identified three trajectories: those who died a typical uraemic death, those who followed another death trajectory, e.g. heart failure, and those where the cause of death was unclear. Conclusions: The management of patients dying from stage-5 CKD and for whom the time and manner of death is unknown can be problematic for healthcare professionals. Conflicts of interest: none. [ABSTRACT FROM AUTHOR]

Published

2010

29. The transcriptional coactivator PGC-1α is essential for maximal and efficient cardiac mitochondrial fatty acid oxidation and lipid homeostasis.

Author

Lehman, John J., Boudina, Sihem, Banke, Natasha Hausler, Sambandam, Nandakumar, Xianlin Han, Young, Deanna M., Leone, Teresa C., Gross, Richard W., Lewandowski, E. Douglas, Abel, E. Dale, and Kelly, Daniel P.

Subjects

MITOCHONDRIA, HEART physiology, FATTY acids, OXIDATION, LIPIDS, HOMEOSTASIS

Abstract

High-capacity mitochondrial ATP production is essential for normal function of the adult heart, and evidence is emerging that mitochondrial derangements occur in common myocardial diseases. Previous overexpression studies have shown that the inducible transcriptional coactivator peroxisome proliferator-activated receptor-γ coactivator (PGC)-1α is capable of activating postnatal cardiac myocyte mitochondrial biogenesis. Recently, we generated mice deficient in PGC-1α (PGC-1α-/- mice), which survive with modestly blunted postnatal cardiac growth. To determine if PGC-1α is essential for normal cardiac energy metabolic capacity, mitochondrial function experiments were performed on saponin-permeabilized myocardial fibers from PGC-1α-/- mice. These experiments demonstrated reduced maximal (state 3) palmitoyl-L-carnitine respiration and increased maximal (state 3) pyruvate respiration in PGC-1α-/- mice compared with PGC-1α+/+ controls. ATP synthesis rates obtained during maximal (state 3) respiration in permeabilized myocardial fibers were reduced for PGC-1α-/- mice, whereas ATP produced per oxygen consumed (ATP/O), a measure of metabolic efficiency, was decreased by 58% for PGC-1α-/- fibers. Ex vivo isolated working heart experiments demonstrated that PGC-1α-/- mice exhibited lower cardiac power, reduced palmitate oxidation, and increased reliance on glucose oxidation, with the latter likely a compensatory response. 13C NMR revealed that hearts from PGC-1α-/- mice exhibited a limited capacity to recruit triglyceride as a source for lipid oxidation during β-adrenergic challenge. Consistent with reduced mitochondrial fatty acid oxidative enzyme gene expression, the total triglyceride content was greater in hearts of PGC-1α-/- mice relative to PGC-1α+/+ following a fast. Overall, these results demonstrate that PGC-1α is essential for the maintenance of maximal, efficient cardiac mitochondrial fatty acid oxidation, ATP synthesis, and myocardial lipid homeostasis. [ABSTRACT FROM AUTHOR]

Published

2008

30. PGC-1 coactivators: inducible regulators of energy metabolism in health and disease.

Author

Finck, Brian N. and Kelly, Daniel P.

Subjects

*NUCLEAR receptors (Biochemistry), *HEART failure, *DIABETES, *LIVER, *STRIATED muscle, *HEART diseases, *ANIMALS, *ENERGY metabolism, *TRANSCRIPTION factors, *SKELETAL muscle

Abstract

Members of the PPARgamma coactivator-1 (PGC-1) family of transcriptional coactivators serve as inducible coregulators of nuclear receptors in the control of cellular energy metabolic pathways. This Review focuses on the biologic and physiologic functions of the PGC-1 coactivators, with particular emphasis on striated muscle, liver, and other organ systems relevant to common diseases such as diabetes and heart failure. [ABSTRACT FROM AUTHOR]

Published

2006

31. Cardiac-specific overexpression of peroxisome proliferator-activated receptor-alpha causes insulin resistance in heart and liver.

Author

Park, So-Young, Cho, You-Ree, Finck, Brian N., Kim, Hyo-Jeong, Higashimori, Takamasa, Hong, Eun-Gyoung, Lee, Mi-Kyung, Danton, Cheryl, Deshmukh, Swati, Cline, Gary W., Wu, Julie J., Bennett, Anton M., Rothermel, Beverly, Kalinowski, April, Russell, Kerry S., Kim, Young-Bum, Kelly, Daniel P., and Kim, Jason K.

Subjects

DIABETES complications, HEART failure, INSULIN resistance, PEROXISOMES, PEOPLE with diabetes, ENERGY metabolism, INSULIN receptors, LABORATORY mice, HEART metabolism, PROTEIN metabolism, GLUCOSE metabolism, ANIMAL experimentation, CELLULAR signal transduction, GENES, HEART, LIVER, MICE, PROTEINS, RESEARCH funding

Abstract

Diabetic heart failure may be causally associated with alterations in cardiac energy metabolism and insulin resistance. Mice with heart-specific overexpression of peroxisome proliferator-activated receptor (PPAR)alpha showed a metabolic and cardiomyopathic phenotype similar to the diabetic heart, and we determined tissue-specific glucose metabolism and insulin action in vivo during hyperinsulinemic-euglycemic clamps in awake myosin heavy chain (MHC)-PPARalpha mice (12-14 weeks of age). Basal and insulin-stimulated glucose uptake in heart was significantly reduced in the MHC-PPARalpha mice, and cardiac insulin resistance was mostly attributed to defects in insulin-stimulated activities of insulin receptor substrate (IRS)-1-associated phosphatidylinositol (PI) 3-kinase, Akt, and tyrosine phosphorylation of signal transducer and activator of transcription 3 (STAT3). Interestingly, MHC-PPARalpha mice developed hepatic insulin resistance associated with defects in insulin-mediated IRS-2-associated PI 3-kinase activity, increased hepatic triglyceride, and circulating interleukin-6 levels. To determine the underlying mechanism, insulin clamps were conducted in 8-week-old MHC-PPARalpha mice. Insulin-stimulated cardiac glucose uptake was similarly reduced in 8-week-old MHC-PPARalpha mice without changes in cardiac function and hepatic insulin action compared with the age-matched wild-type littermates. Overall, these findings indicate that increased activity of PPARalpha, as occurs in the diabetic heart, leads to cardiac insulin resistance associated with defects in insulin signaling and STAT3 activity, subsequently leading to reduced cardiac function. Additionally, age-associated hepatic insulin resistance develops in MHC-PPARalpha mice that may be due to altered cardiac metabolism, functions, and/or inflammatory cytokines. [ABSTRACT FROM AUTHOR]

Published

2005

32. A missense mutation in the beta myosin heavy chain gene is a predictor of premature sudden death...

Author

Marian, Ali Jalilian and Kelly, Daniel

Subjects

CARDIAC hypertrophy, HEART failure, GENETICS

Abstract

Reports that missense mutations in exon 13 of the beta-MHC gene causes severe heart failure and sudden death in persons with familial hypertrophic cardiomyopathy (FHCM). Electrophoretic separation of the DNA from the tested individuals; Clinical analysis; Genetic experiments; Results and discussion.

Published

1994

33. RIP140 deficiency enhances cardiac fuel metabolism and protects mice from heart failure.

Author

Tsunehisa Yamamoto, Maurya, Santosh K., Pruzinsky, Elizabeth, Batmanov, Kirill, Yang Xiao, Sulon, Sarah M., Tomoya Sakamoto, Yang Wang, Ling Lai, McDaid, Kendra S., Shewale, Swapnil V., Leone, Teresa C., Koves, Timothy R., Muoio, Deborah M., Dierickx, Pieterjan, Lazar, Mitchell A., Lewandowski, E. Douglas, and Kelly, Daniel P.

Subjects

*HEART metabolism, *HEART failure, *FATTY acid oxidation, *CARDIAC hypertrophy, *RECEPTOR-interacting proteins

Abstract

During the development of heart failure (HF), the capacity for cardiomyocyte (CM) fatty acid oxidation (FAO) and ATP production is progressively diminished, contributing to pathologic cardiac hypertrophy and contractile dysfunction. Receptor-interacting protein 140 (RIP140, encoded by Nrip1) has been shown to function as a transcriptional corepressor of oxidative metabolism. We found that mice with striated muscle deficiency of RIP140 (strNrip1-/-) exhibited increased expression of a broad array of genes involved in mitochondrial energy metabolism and contractile function in heart and skeletal muscle. strNrip1-/- mice were resistant to the development of pressure overload-induced cardiac hypertrophy, and CM-specific RIP140-deficient (csNrip1-/-) mice were protected against the development of HF caused by pressure overload combined with myocardial infarction. Genomic enhancers activated by RIP140 deficiency in CMs were enriched in binding motifs for transcriptional regulators of mitochondrial function (estrogen-related receptor) and cardiac contractile proteins (myocyte enhancer factor 2). Consistent with a role in the control of cardiac fatty acid oxidation, loss of RIP140 in heart resulted in augmented triacylglyceride turnover and fatty acid utilization. We conclude that RIP140 functions as a suppressor of a transcriptional regulatory network that controls cardiac fuel metabolism and contractile function, representing a potential therapeutic target for the treatment of HF. [ABSTRACT FROM AUTHOR]

Published

2023

34. Mouse models of mitochondrial dysfunction and heart failure

Author

Russell, Laurie K., Finck, Brian N., and Kelly, Daniel P.

Subjects

*MITOCHONDRIA, *HEART failure, *CARDIAC arrest, *MICROBIAL genetics

Abstract

Abstract: Mitochondria in the adult mammalian heart have a tremendous capacity for oxidative metabolism, and the conversion of energy by these pathways is critical for proper cardiac function. This review describes mouse models relating mitochondrial metabolism to cardiac function through gain- or loss-of-function approaches that manipulate mitochondrial energy transduction or ATP synthetic pathways. Mouse models of mitochondrial defects are relevant to genetic and acquired forms of human cardiomyopathy. Examples include inborn errors in mitochondrial metabolism or end-stage heart failure. Conversely, chronic reliance on energy production via mitochondrial fatty acid oxidation, such as occurs in the diabetic heart, likely leads to maladaptive sequelae including cellular lipotoxicity and mitochondrial dysfunction. Collectively, these model systems have allowed us to begin to dissect the relationship between mitochondrial metabolism and the development of cardiomyopathy and to define the molecular pathways regulating cardiac mitochondrial number and function. [Copyright &y& Elsevier]

Published

2005

35. Therapeutic Potential of Ketone Bodies for Patients With Cardiovascular Disease: JACC State-of-the-Art Review.

Author

Yurista, Salva R., Chong, Cher-Rin, Badimon, Juan J., Kelly, Daniel P., de Boer, Rudolf A., and Westenbrink, B. Daan

Subjects

*CARDIOVASCULAR diseases, *KETONES, *CARDIOVASCULAR diseases risk factors, *DIABETIC acidosis, *KETOGENIC diet, *HEART metabolism, *DIETARY supplements, *HEART diseases

Abstract

Metabolic perturbations underlie a variety of cardiovascular disease states; yet, metabolic interventions to prevent or treat these disorders are sparse. Ketones carry a negative clinical stigma as they are involved in diabetic ketoacidosis. However, evidence from both experimental and clinical research has uncovered a protective role for ketones in cardiovascular disease. Although ketones may provide supplemental fuel for the energy-starved heart, their cardiovascular effects appear to extend far beyond cardiac energetics. Indeed, ketone bodies have been shown to influence a variety of cellular processes including gene transcription, inflammation and oxidative stress, endothelial function, cardiac remodeling, and cardiovascular risk factors. This paper reviews the bioenergetic and pleiotropic effects of ketone bodies that could potentially contribute to its cardiovascular benefits based on evidence from animal and human studies. [ABSTRACT FROM AUTHOR]

Published

2021

36. Parkin-mediated mitophagy directs perinatal cardiac metabolic maturation.

Author

Guohua Gong, Moshi Song, Csordas, Gyorgy, Kelly, Daniel P., Matkovich, Scot J., and Dorn II, Gerald W.

Subjects

*HEART failure, *HEART metabolism, *CARDIAC arrest, *CARBOHYDRATES, *FATTY acids

Abstract

In developing hearts, changes in the cardiac metabolic milieu during the perinatal period redirect mitochondrial substrate preference from carbohydrates to fatty acids. Mechanisms responsible for this mitochondrial plasticity are unknown. Here, we found that PINK1-Mfn2-Parkin-mediated mitophagy directs this metabolic transformation in mouse hearts. A mitofusin (Mfn) 2 mutant lacking PINK1 phosphorylation sites necessary for Parkin binding (Mfn2 AA) inhibited mitochondrial Parkin translocation, suppressing mitophagy without impairing mitochondrial fusion. Cardiac Parkin deletion or expression of Mfn2 AA from birth, but not after weaning, prevented postnatal mitochondrial maturation essential to survival. Five-week-old Mfn2 AA hearts retained a fetal mitochondrial transcriptional signature without normal increases in fatty acid metabolism and mitochondrial biogenesis genes. Myocardial fatty acylcarnitine levels and cardiomyocyte respiration induced by palmitoylcarnitine were concordantly depressed. Thus, instead of transcriptional reprogramming, fetal cardiomyocyte mitochondria undergo perinatal Parkin-mediated mitophagy and replacement by mature adult mitochondria. Mitophagic mitochondrial removal underlies developmental cardiomyocyte mitochondrial plasticity and metabolic transitioning of perinatal hearts. [ABSTRACT FROM AUTHOR]

Published

2015

37. The transcriptional coactivators, PGC-1α and β, cooperate to maintain cardiac mitochondrial function during the early stages of insulin resistance

Author

Mitra, Riddhi, Nogee, Daniel P., Zechner, Juliet F., Yea, Kyungmoo, Gierasch, Carrie M., Kovacs, Attila, Medeiros, Denis M., Kelly, Daniel P., and Duncan, Jennifer G.

Subjects

*MITOCHONDRIA, *INSULIN resistance, *FATTY acids, *ESTROGEN, *PEROXISOME proliferator-activated receptors, *OXIDATIVE phosphorylation, *ELECTRON microscopy, *GLUCOSE tolerance tests

Abstract

Abstract: We previously demonstrated a cardiac mitochondrial biogenic response in insulin resistant mice that requires the nuclear receptor transcription factor PPARα. We hypothesized that the PPARα coactivator peroxisome proliferator-activated receptor gamma coactivator-1 alpha (PGC-1α) is necessary for mitochondrial biogenesis in insulin resistant hearts and that this response was adaptive. Mitochondrial phenotype was assessed in insulin resistant mouse models in wild-type (WT) versus PGC-1α deficient (PGC-1α−/−) backgrounds. Both high fat-fed (HFD) WT and 6week-old Ob/Ob animals exhibited a significant increase in myocardial mitochondrial volume density compared to standard chow fed or WT controls. In contrast, HFD PGC-1α−/− and Ob/Ob-PGC-1α−/− hearts lacked a mitochondrial biogenic response. PGC-1α gene expression was increased in 6week-old Ob/Ob animals, followed by a decline in 8week-old Ob/Ob animals with more severe glucose intolerance. Mitochondrial respiratory function was increased in 6week-old Ob/Ob animals, but not in Ob/Ob-PGC-1α−/− mice and not in 8week-old Ob/Ob animals, suggesting a loss of the early adaptive response, consistent with the loss of PGC-1α upregulation. Animals that were deficient for PGC-1α and heterozygous for the related coactivator PGC-1β (PGC-1α−/−β+/−) were bred to the Ob/Ob mice. Ob/Ob-PGC-1α−/−β+/− hearts exhibited dramatically reduced mitochondrial respiratory capacity. Finally, the mitochondrial biogenic response was triggered in H9C2 myotubes by exposure to oleate, an effect that was blunted with shRNA-mediated PGC-1 “knockdown”. We conclude that PGC-1 signaling is important for the adaptive cardiac mitochondrial biogenic response that occurs during the early stages of insulin resistance. This response occurs in a cell autonomous manner and likely involves exposure to high levels of free fatty acids. [Copyright &y& Elsevier]

Published

2012

38. Fatty Acid Synthase Modulates Homeostatic Responses to Myocardial Stress.

Author

Razani, Babak, Zhang, Haixia, Schulze, P. Christian, Schilling, Joel D., Verbsky, John, Lodhi, Irfan J., Topkara, Veli K., Feng, Chu, Coleman, Trey, Kovacs, Attila, Kelly, Daniel P., Saffitz, Jeffrey E., Dorn, Gerald W., Nichols, Colin G., and Semenkovich, Clay F.

Subjects

*FATTY acid synthesis, *CARDIOMYOPATHIES, *CALCIUM channels, *CALMODULIN, *HEART cells, *HEART failure, *LABORATORY mice

Abstract

Fatty acid synthase (FAS) promotes energy storage through de novo lipogenesis and participates in signaling by the nuclear receptor PPARa in noncardiac tissues. To determine if de novo lipogenesis is relevant to cardiac physiology, we generated and characterized FAS knockout in the myocardium (FASKard) mice. FASKard mice develop normally, manifest normal resting heart function, and have normal cardiac PPARa signaling as well as fatty acid oxidation. However, they decompensate with stress. Most die within 1 h of transverse aortic constriction, probably due to arrhythmia. Voltage clamp measurements of FASKard cardiomyocytes show hyperactivation of L-type calcium channel current that could not be reversed with palmitate supplementation. Of the classic regulators of this current, Ca2+/calmodulin-dependent protein kinase II (CaMKII) but not protein kinase A signaling is activated in FASKard hearts, and knockdown of FAS in cultured cells activates CaMKII. In addition to being intolerant of the stress of acute pressure, FASKard hearts were also intolerant of the stress of aging, reflected as persistent CaMKII hyperactivation, progression to dilatation, and premature death by ~1 year of age. CaMKII signaling appears to be pathogenic in FASKard hearts because inhibition of its signaling in vivo rescues mice from early mortality after transverse aortic constriction. FAS was also increased in two mechanistically distinct mouse models of heart failure and in the hearts of humans with end stage cardiomyopathy. These data implicate a novel relationship between FAS and calcium signaling in the heart and suggest that FAS induction in stressed myocardium represents a compensatory response to protect cardiomyocytes from pathological calcium flux. [ABSTRACT FROM AUTHOR]

Published

2011

39. Altered myocardial fatty acid and glucose metabolism in idiopathic dilated cardiomyopathy

Author

Dávila-Román, V.íctor G., Vedala, Giridhar, Herrero, Pilar, de las Fuentes, Lisa, Rogers, Joseph G., Kelly, Daniel P., Gropler, Robert J., and Dávila-Román, Víctor G

Subjects

*CARDIOMYOPATHIES, *HEART metabolism

Abstract

: ObjectivesThe purpose of this study was to determine whether patients with idiopathic dilated cardiomyopathy (IDCM) exhibit alterations in myocardial fatty acid and glucose metabolism.: BackgroundAlterations in myocardial metabolism have been implicated in the pathogenesis of heart failure (HF); however, studies of myocardial metabolic function in human HF have yielded conflicting results. Animal models of HF have shown a downregulation of the expression of enzymes of fatty acid beta-oxidation that recapitulates the fetal energy metabolic program, in which fatty acid metabolism is decreased and glucose metabolism is increased.: MethodsSeven patients with IDCM (mean left ventricular ejection fraction 27 ± 8%) and 12 normal controls underwent positron emission tomography for measurements of myocardial blood flow (MBF), myocardial oxygen consumption (MVO2), myocardial glucose utilization (MGU), myocardial fatty acid utilization (MFAU) and myocardial fatty acid oxidation (MFAO).: ResultsThe systolic and diastolic blood pressures, plasma substrates and insulin levels, MBF and MVO2, were similar between groups. The rates of MFAU and MFAO were significantly lower in IDCM than in the normal control group (MFAU: 134 ± 44 vs. 213 ± 49 nmol/g/min, p = 0.003; and MFAO: 113 ± 50 vs. 205 ± 49 nmol/g/min, p = 0.001) and the rates of MGU were significantly higher in IDCM than the normal control group (MGU: 247 ± 63 vs. 125 ± 64 nmol/g/min, p < 0.001).: ConclusionsPatients with IDCM exhibit alterations in myocardial metabolism characterized by decreased fatty acid metabolism and increased myocardial glucose metabolism, a pattern similar to that shown in animal models of HF. Whether alterations in myocardial metabolism constitute an adaptive response or mediate the development of HF remains to be determined. [Copyright &y& Elsevier]

Published

2002

40. Abstract 14219: Enhancing Cardiac Beta-Hydroxybutyrate Consumption Halts the Progression From Compensated to Decompensated Heart Failure in Dogs With Tachypacing-Induced Dilated Cardiomyopathy.

Author

Kurishima, Clara, Powers, Jeffery C, Seki, Mitsuru, Kavitha, Pavithra, Tsipenyuk, Florence, Cunningham, Keely, Gopi, Heramba V, Matsuura, Timothy, Kelly, Daniel P, and Recchia, Fabio A

Subjects

*DILATED cardiomyopathy, *HEART failure, *3-Hydroxybutyric acid, *CARDIAC pacing, *FREE fatty acids

Abstract

Introduction: Recent Evidence indicates that circulating ketone bodies serve as an alternative myocardial substrate in heart failure (HF). Hypothesis: We tested the hypothesis that enhancing ketones delivery to the heart during early/compensated stages of HF delays the progression towards decompensation. Methods: Eight chronically instrumented dogs were subjected to cardiac tachypacing and infused with the ketone beta-hydroxybutyrate (BHB), starting after 2 weeks of pacing (HF+BHB group), i.e. during the early stages of cardiac dysfunction. A group of 8 dogs was subjected to cardiac pacing without BHB infusion (HF group). In 5 dogs per group, paired blood samples were withdrawn from aorta and coronary sinus to measure cardiac substrate utilization. 3H-oleate and 14C-glucose were co-infused to track the metabolic fate of free fatty acids (FFA) and glucose. Results: Blood BHB concentrations reached 190.3±19.7 microM in HF+BHB, approximately 4-fold the normal baseline values. This enhanced cardiac ketone uptake from 0.0091±0.002 to 0.022±0.005 umol/beat/100gr in HF+BHB vs HF (P<0.05). Cardiac glucose oxidation was more than doubled in HF vs control and but was suppressed in HF+BHB together with a 60% reduction in lactate uptake (all P<0.05). In contrast, FFA oxidation rates were modestly increased by the BHB infusion. These metabolic alterations were associated with marked functional protection: after 29±1 days of cardiac pacing, LV end-diastolic pressure was ≥25 mmHg in HF, indicating end-stage decompensation, while it remained at normal physiological values in HF+BHB. Cardiac output was also preserved and the fall in ejection fraction was significantly attenuated (56.1±1.5 vs 37.0±3.1%, P<0.05) in HF+BHB compared to HF. Beta-adrenergic response to dobutamine was also significantly higher in HF+BHB. However, BHB did not prevent alterations of other hemodynamic parameters, such as systemic blood pressures and dP/dtmax/min, typically occurring in HF. Conclusions: These results provide the first evidence that high levels of circulating BHB exert strong beneficial effects in HF opposing the progression toward decompensation, perhaps in part due to the shift of failing hearts from carbohydrate to ketones as a major source of energy. [ABSTRACT FROM AUTHOR]

Published

2018