Your search keyword '"cardiac metabolism"' showing total 1,612 results

1. Transition from fetal to postnatal state in the heart: Crosstalk between metabolism and regeneration.

Author

Sada, Tai and Kimura, Wataru

Subjects

*AMINO acid metabolism, *HEART metabolism, *FATTY acid oxidation, *METABOLIC reprogramming, *MYOCARDIAL injury

Abstract

Cardiovascular disease is the leading cause of mortality worldwide. Myocardial injury resulting from ischemia can be fatal because of the limited regenerative capacity of adult myocardium. Mammalian cardiomyocytes rapidly lose their proliferative capacities, with only a small fraction of adult myocardium remaining proliferative, which is insufficient to support post‐injury recovery. Recent investigations have revealed that this decline in myocardial proliferative capacity is closely linked to perinatal metabolic shifts. Predominantly glycolytic fetal myocardial metabolism transitions towards mitochondrial fatty acid oxidation postnatally, which not only enables efficient production of ATP but also causes a dramatic reduction in cardiomyocyte proliferative capacity. Extensive research has elucidated the mechanisms behind this metabolic shift, as well as methods to modulate these metabolic pathways. Some of these methods have been successfully applied to enhance metabolic reprogramming and myocardial regeneration. This review discusses recently acquired insights into the interplay between metabolism and myocardial proliferation, emphasizing postnatal metabolic transitions. [ABSTRACT FROM AUTHOR]

Published

2024

2. Cardiac Molecular Analysis Reveals Aging‐Associated Metabolic Alterations Promoting Glycosaminoglycans Accumulation via Hexosamine Biosynthetic Pathway.

Author

Grilo, Luís F., Zimmerman, Kip D., Puppala, Sobha, Chan, Jeannie, Huber, Hillary F., Li, Ge, Jadhav, Avinash Y. L., Wang, Benlian, Li, Cun, Clarke, Geoffrey D., Register, Thomas C., Oliveira, Paulo J., Nathanielsz, Peter W., Olivier, Michael, Pereira, Susana P., and Cox, Laura A.

Subjects

*KREBS cycle, *CARDIAC hypertrophy, *HEART metabolism, *DISEASE risk factors, *AGE, *GLYCOSAMINOGLYCANS

Abstract

Age is a prominent risk factor for cardiometabolic disease, often leading to heart structural and functional changes. However, precise molecular mechanisms underlying cardiac remodeling and dysfunction exclusively resulting from physiological aging remain elusive. Previous research demonstrated age‐related functional alterations in baboons, analogous to humans. The goal of this study is to identify early cardiac molecular alterations preceding functional adaptations, shedding light on the regulation of age‐associated changes. Unbiased transcriptomics of left ventricle samples are performed from female baboons aged 7.5–22.1 years (human equivalent ≈30–88 years). Weighted‐gene correlation network and pathway enrichment analyses are performed, with histological validation. Modules of transcripts negatively correlated with age implicated declined metabolism‐oxidative phosphorylation, tricarboxylic acid cycle, glycolysis, and fatty‐acid β‐oxidation. Transcripts positively correlated with age suggested a metabolic shift toward glucose‐dependent anabolic pathways, including hexosamine biosynthetic pathway (HBP). This shift is associated with increased glycosaminoglycan synthesis, modification, precursor synthesis via HBP, and extracellular matrix accumulation, verified histologically. Upregulated extracellular matrix‐induced signaling coincided with glycosaminoglycan accumulation, followed by cardiac hypertrophy‐related pathways. Overall, these findings revealed a transcriptional shift in metabolism favoring glycosaminoglycan accumulation through HBP before cardiac hypertrophy. Unveiling this metabolic shift provides potential targets for age‐related cardiac diseases, offering novel insights into early age‐related mechanisms. [ABSTRACT FROM AUTHOR]

Published

2024

3. An intrinsic mechanism of metabolic tuning promotes cardiac resilience to stress.

Author

Sorge, Matteo, Savoré, Giulia, Gallo, Andrea, Acquarone, Davide, Sbroggiò, Mauro, Velasco, Silvia, Zamporlini, Federica, Femminò, Saveria, Moiso, Enrico, Morciano, Giampaolo, Balmas, Elisa, Raimondi, Andrea, Nattenberg, Gabrielle, Stefania, Rachele, Tacchetti, Carlo, Rizzo, Angela Maria, Corsetto, Paola, Ghigo, Alessandra, Turco, Emilia, and Altruda, Fiorella

Abstract

Defining the molecular mechanisms underlying cardiac resilience is crucial to find effective approaches to protect the heart. A physiologic level of ROS is produced in the heart by fatty acid oxidation, but stressful events can boost ROS and cause mitochondrial dysfunction and cardiac functional impairment. Melusin is a muscle specific chaperone required for myocardial compensatory remodeling during stress. Here we report that Melusin localizes in mitochondria where it binds the mitochondrial trifunctional protein, a key enzyme in fatty acid oxidation, and decreases it activity. Studying both mice and human induced pluripotent stem cell-derived cardiomyocytes, we found that Melusin reduces lipid oxidation in the myocardium and limits ROS generation in steady state and during pressure overload and doxorubicin treatment, preventing mitochondrial dysfunction. Accordingly, the treatment with the lipid oxidation inhibitor Trimetazidine concomitantly with stressful stimuli limits ROS accumulation and prevents long-term heart dysfunction. These findings disclose a physiologic mechanism of metabolic regulation in the heart and demonstrate that a timely restriction of lipid metabolism represents a potential therapeutic strategy to improve cardiac resilience to stress. Synopsis: FAO is catalyzed by the mitochondrial trifunctional protein (MTP) and, if overloaded, generates ROS. ROS are boosted during stressful events, favoring cardiac maladaptive remodeling. Melusin is a muscle-specific chaperone able to sustain heart resilience during a wide variety of stressful insults. Melusin interacts and inhibits the MTP, restraining FAO and ROS generation in the myocardium. Heart resilience depends on the rate of FAO during stressful events occurrence. Inhibiting lipid metabolism in a timely manner during stress protects the heart from dysfunction and prolongs the survival in preclinical models. FAO is catalyzed by the mitochondrial trifunctional protein (MTP) and, if overloaded, generates ROS. ROS are boosted during stressful events, favoring cardiac maladaptive remodeling. Melusin is a muscle-specific chaperone able to sustain heart resilience during a wide variety of stressful insults. [ABSTRACT FROM AUTHOR]

Published

2024

4. A Feasibility Study of [18F]F-AraG Positron Emission Tomography (PET) for Cardiac Imaging–Myocardial Viability in Ischemia–Reperfusion Injury Model.

Author

Shrestha, Uttam M., Chae, Hee-Don, Fang, Qizhi, Lee, Randall J., Packiasamy, Juliet, Huynh, Lyna, Blecha, Joseph, Huynh, Tony L., VanBrocklin, Henry F., Levi, Jelena, and Seo, Youngho

Subjects

*POSITRON emission tomography, *MYOCARDIAL infarction, *HEART metabolism, *TISSUE viability, *DIETARY supplements, *T cells

Abstract

Purpose: Myocardial infarction (MI) with subsequent inflammation is one of the most common heart conditions leading to progressive tissue damage. A reliable imaging marker to assess tissue viability after MI would help determine the risks and benefits of any intervention. In this study, we investigate whether a new mitochondria-targeted imaging agent, 18F-labeled 2'-deoxy-2'-18F-fluoro-9-β-d-arabinofuranosylguanine ([18F]F-AraG), a positron emission tomography (PET) agent developed for imaging activated T cells, is suitable for cardiac imaging and to test the myocardial viability after MI. Procedure: To test whether the myocardial [18F]-F-AraG signal is coming from cardiomyocytes or immune infiltrates, we compared cardiac signal in wild-type (WT) mice with that of T cell deficient Rag1 knockout (Rag1 KO) mice. We assessed the effect of dietary nucleotides on myocardial [18F]F-AraG uptake in normal heart by comparing [18F]F-AraG signals between mice fed with purified diet and those fed with purified diet supplemented with nucleotides. The myocardial viability was investigated in rodent model by imaging rat with [18F]F-AraG and 2-deoxy-2[18F]fluoro-D-glucose ([18F]FDG) before and after MI. All PET signals were quantified in terms of the percent injected dose per cc (%ID/cc). We also explored [18F]FDG signal variability and potential T cell infiltration into fibrotic area in the affected myocardium with H&E analysis. Results: The difference in %ID/cc for Rag1 KO and WT mice was not significant (p = ns) indicating that the [18F]F-AraG signal in the myocardium was primarily coming from cardiomyocytes. No difference in myocardial uptake was observed between [18F]F-AraG signals in mice fed with purified diet and with purified diet supplemented with nucleotides (p = ns). The [18F]FDG signals showed wider variability at different time points. Noticeable [18F]F-AraG signals were observed in the affected MI regions. There were T cells in the fibrotic area in the H&E analysis, but they did not constitute the predominant infiltrates. Conclusions: Our preliminary preclinical data show that [18F]F-AraG accumulates in cardiomyocytes indicating that it may be suitable for cardiac imaging and to evaluate the myocardial viability after MI. [ABSTRACT FROM AUTHOR]

Published

2024

5. Metabolic cycles: A unifying concept for energy transfer in the heart.

Author

Beito, Mitchell and Taegtmeyer, Heinrich

Subjects

*CARDIAC hypertrophy, *IRON supplements, *MYOCARDIUM, *HEART metabolism, *ENERGY transfer

Abstract

It is still debated whether changes in metabolic flux are cause or consequence of contractile dysfunction in non-ischemic heart disease. We have previously proposed a model of cardiac metabolism grounded in a series of six moiety-conserved, interconnected cycles. In view of a recent interest to augment oxygen availability in heart failure through iron supplementation, we integrated this intervention in terms of moiety conservation. Examining published work from both human and murine models, we argue this strategy restores a mitochondrial cycle of energy transfer by enhancing mitochondrial pyruvate carrier (MPC) expression and providing pyruvate as a substrate for carboxylation and anaplerosis. Metabolomic data from failing heart muscle reveal elevated pyruvate levels with a concomitant decrease in the levels of Krebs cycle intermediates. Additionally, MPC is downregulated in the same failing hearts, as well as under hypoxic conditions. MPC expression increases upon mechanical unloading in the failing human heart, as does contractile function. We note that MPC deficiency also alters expression of enzymes involved in pyruvate carboxylation and decarboxylation, increases intermediates of biosynthetic pathways, and eventually leads to cardiac hypertrophy and dilated cardiomyopathy. Collectively, we propose that an unbroken chain of moiety-conserved cycles facilitates energy transfer in the heart. We refer to the transport and subsequent carboxylation of pyruvate in the mitochondrial matrix as an example and a proposed target for metabolic support to reverse impaired contractile function. [Display omitted] • Metabolic cycles in the heart optimize transfer of available energy • Energy transfer is impaired in heart failure • Moiety-conserved cycles are a potential target in the treatment of heart failure [ABSTRACT FROM AUTHOR]

Published

2024

6. Advancing Human iPSC-Derived Cardiomyocyte Hypoxia Resistance for Cardiac Regenerative Therapies through a Systematic Assessment of In Vitro Conditioning.

Author

Snyder, Caroline A., Dwyer, Kiera D., and Coulombe, Kareen L. K.

Subjects

*HEART metabolism, *WNT signal transduction, *MYOCARDIAL ischemia, *TISSUE engineering, *GENETIC translation, *PLURIPOTENT stem cells, *MYOCARDIAL infarction

Abstract

Acute myocardial infarction (MI) is a sudden, severe cardiac ischemic event that results in the death of up to one billion cardiomyocytes (CMs) and subsequent decrease in cardiac function. Engineered cardiac tissues (ECTs) are a promising approach to deliver the necessary mass of CMs to remuscularize the heart. However, the hypoxic environment of the heart post-MI presents a critical challenge for CM engraftment. Here, we present a high-throughput, systematic study targeting several physiological features of human induced pluripotent stem cell-derived CMs (hiPSC-CMs), including metabolism, Wnt signaling, substrate, heat shock, apoptosis, and mitochondrial stabilization, to assess their efficacy in promoting ischemia resistance in hiPSC-CMs. The results of 2D experiments identify hypoxia preconditioning (HPC) and metabolic conditioning as having a significant influence on hiPSC-CM function in normoxia and hypoxia. Within 3D engineered cardiac tissues (ECTs), metabolic conditioning with maturation media (MM), featuring high fatty acid and calcium concentration, results in a 1.5-fold increase in active stress generation as compared to RPMI/B27 control ECTs in normoxic conditions. Yet, this functional improvement is lost after hypoxia treatment. Interestingly, HPC can partially rescue the function of MM-treated ECTs after hypoxia. Our systematic and iterative approach provides a strong foundation for assessing and leveraging in vitro culture conditions to enhance the hypoxia resistance, and thus the successful clinical translation, of hiPSC-CMs in cardiac regenerative therapies. [ABSTRACT FROM AUTHOR]

Published

2024

7. Maternal high fat–high energy diet alters metabolic factors in the non‐human primate fetal heart.

Author

Bertossa, Melanie R., Darby, Jack R. T., Holman, Stacey L., Meakin, Ashley S., Li, Cun, Huber, Hillary F., Wiese, Michael D., Nathanielsz, Peter W., and Morrison, Janna L.

Subjects

*HIGH-fat diet, *OBESITY in women, *HEART metabolism disorders, *FETAL heart, *TRIIODOTHYRONINE, *INSULIN receptors, *BABOONS

Abstract

The consumption of high fat–high energy diets (HF‐HEDs) continues to rise worldwide and parallels the rise in maternal obesity (MO) that predisposes offspring to cardiometabolic disorders. Although the underlying mechanisms are unclear, thyroid hormones (TH) modulate cardiac maturation in utero. Therefore, we aimed to determine the impact of a high fat–high energy diet (HF‐HED) on the hormonal, metabolic and contractility profile of the non‐human primate (NHP) fetal heart. At ∼9 months preconception, female baboons (Papiohamadryas) were randomly assigned to either a control diet or HF‐HED. At 165 days gestational age (term = 184 days), fetuses were delivered by Caesarean section under anaesthesia, humanely killed, and left ventricular cardiac tissue (Control (n = 6 female, 6 male); HF‐HED (n = 6 F, 6 M)) was collected. Maternal HF‐HED decreased the concentration of active cardiac TH (i.e. triiodothyronine (T3)), and type 1 iodothyronine deiodinase (DIO1) mRNA expression. Maternal HF‐HED decreased the abundance of cardiac markers of insulin‐mediated glucose uptake phosphorylated insulin receptor substrate 1 (Ser789) and glucose transporter 4, and increased protein abundance of key oxidative phosphorylation complexes (I, III, IV) and mitochondrial abundance in both sexes. Maternal HF‐HED alters cardiac TH status, which may induce early signs of cardiac insulin resistance. This may increase the risk of cardiometabolic disorders in later life in offspring born to these pregnancies. Key points: Babies born to mothers who consume a high fat–high energy diet (HF‐HED) prior to and during pregnancy are predisposed to an increased risk of cardiometabolic disorders across the life course.Maternal HF‐HED prior to and during pregnancy decreased thyroid hormone triiodothyronine (T3) concentrations and type 1 iodothyronine deiodinase DIO1 mRNA expression in the non‐human primate fetal heart.Maternal HF‐HED decreased markers of insulin‐dependent glucose uptake, phosphorylated insulin receptor substrate 1 and glucose transporter 4 in the fetal heart.Maternal HF‐HED increased mitochondrial abundance and mitochondrial OXPHOS complex I, III and IV in the fetal heart.Fetuses from HF‐HED pregnancies are predisposed to cardiometabolic disorders that may be mediated by changes in T3, placing them on a poor lifetime cardiovascular health trajectory. [ABSTRACT FROM AUTHOR]

Published

2024

8. An intrinsic mechanism of metabolic tuning promotes cardiac resilience to stress

Author

Matteo Sorge, Giulia Savoré, Andrea Gallo, Davide Acquarone, Mauro Sbroggiò, Silvia Velasco, Federica Zamporlini, Saveria Femminò, Enrico Moiso, Giampaolo Morciano, Elisa Balmas, Andrea Raimondi, Gabrielle Nattenberg, Rachele Stefania, Carlo Tacchetti, Angela Maria Rizzo, Paola Corsetto, Alessandra Ghigo, Emilia Turco, Fiorella Altruda, Lorenzo Silengo, Paolo Pinton, Nadia Raffaelli, Nathan J Sniadecki, Claudia Penna, Pasquale Pagliaro, Emilio Hirsch, Chiara Riganti, Guido Tarone, Alessandro Bertero, and Mara Brancaccio

Subjects

Cardiac Metabolism, ROS, Doxorubicin, Pressure Overload, Chaperone Proteins, Medicine (General), R5-920, Genetics, QH426-470

Abstract

Abstract Defining the molecular mechanisms underlying cardiac resilience is crucial to find effective approaches to protect the heart. A physiologic level of ROS is produced in the heart by fatty acid oxidation, but stressful events can boost ROS and cause mitochondrial dysfunction and cardiac functional impairment. Melusin is a muscle specific chaperone required for myocardial compensatory remodeling during stress. Here we report that Melusin localizes in mitochondria where it binds the mitochondrial trifunctional protein, a key enzyme in fatty acid oxidation, and decreases it activity. Studying both mice and human induced pluripotent stem cell-derived cardiomyocytes, we found that Melusin reduces lipid oxidation in the myocardium and limits ROS generation in steady state and during pressure overload and doxorubicin treatment, preventing mitochondrial dysfunction. Accordingly, the treatment with the lipid oxidation inhibitor Trimetazidine concomitantly with stressful stimuli limits ROS accumulation and prevents long-term heart dysfunction. These findings disclose a physiologic mechanism of metabolic regulation in the heart and demonstrate that a timely restriction of lipid metabolism represents a potential therapeutic strategy to improve cardiac resilience to stress.

Published

2024

9. Repurposing Metformin for the Treatment of Atrial Fibrillation: Current Insights

Author

Sarkar A, Fanous KI, Marei I, Ding H, Ladjimi M, MacDonald R, Hollenberg MD, Anderson TJ, Hill MA, and Triggle CR

Subjects

metformin, atrial fibrillation, ampk, hyperglycemia, hypoglycemia, cardiac metabolism, cardio-vascular protection, atrial remodeling, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Aparajita Sarkar,1 Kareem Imad Fanous,1 Isra Marei,2 Hong Ding,2 Moncef Ladjimi,3 Ross MacDonald,4 Morley D Hollenberg,5 Todd J Anderson,6 Michael A Hill,7 Chris R Triggle2 1Department of Medical Education, Weill Cornell Medicine-Qatar, Doha, Qatar; 2Department of Pharmacology & Medical Education, Weill Cornell Medicine- Qatar, Doha, Qatar; 3Department of Biochemistry & Medical Education, Weill Cornell Medicine-Qatar, Doha, Qatar; 4Health Sciences Library, Weill Cornell Medicine-Qatar, Doha, Qatar; 5Department of Physiology & Pharmacology, and Department of Medicine, Cumming School of Medicine, University of Calgary, Calgary, Alberta, Canada; 6Department of Cardiac Sciences and Libin Cardiovascular Institute, Cumming School of Medicine, University of Calgary, Calgary, Alberta, Canada; 7Dalton Cardiovascular Research Center & Department of Medical Pharmacology & Physiology, School of Medicine, University of Missouri, Columbia, Missouri, USACorrespondence: Aparajita Sarkar; Chris R Triggle, Email aps4003@qatar-med.cornell.edu; cht2011@qatar-med.cornell.eduAbstract: Metformin is an orally effective anti-hyperglycemic drug that despite being introduced over 60 years ago is still utilized by an estimated 120 to 150 million people worldwide for the treatment of type 2 diabetes (T2D). Metformin is used off-label for the treatment of polycystic ovary syndrome (PCOS) and for pre-diabetes and weight loss. Metformin is a safe, inexpensive drug with side effects mostly limited to gastrointestinal issues. Prospective clinical data from the United Kingdom Prospective Diabetes Study (UKPDS), completed in 1998, demonstrated that metformin not only has excellent therapeutic efficacy as an anti-diabetes drug but also that good glycemic control reduced the risk of micro- and macro-vascular complications, especially in obese patients and thereby reduced the risk of diabetes-associated cardiovascular disease (CVD). Based on a long history of clinical use and an excellent safety record metformin has been investigated to be repurposed for numerous other diseases including as an anti-aging agent, Alzheimer’s disease and other dementias, cancer, COVID-19 and also atrial fibrillation (AF). AF is the most frequently diagnosed cardiac arrythmia and its prevalence is increasing globally as the population ages. The argument for repurposing metformin for AF is based on a combination of retrospective clinical data and in vivo and in vitro pre-clinical laboratory studies. In this review, we critically evaluate the evidence that metformin has cardioprotective actions and assess whether the clinical and pre-clinical evidence support the use of metformin to reduce the risk and treat AF. Keywords: metformin, atrial fibrillation, AMPK, hyperglycemia, hypoglycemia, cardiac metabolism, cardiovascular protection, atrial remodeling

Published

2024

10. Smoking cessation only partially reverses cardiac metabolic and structural remodeling in mice.

Author

Aid, Jekaterina, Tanjeko, Ajime Tom, Serré, Jef, Eggelbusch, Moritz, Noort, Wendy, de Wit, Gerard M. J., van Weeghel, Michel, Puurand, Marju, Tepp, Kersti, Gayan‐Ramirez, Ghislaine, Degens, Hans, Käämbre, Tuuli, and Wüst, Rob C. I.

Subjects

*HOOKAHS, *SMOKING cessation, *WARNING labels, *CHRONIC obstructive pulmonary disease, *CIGARETTE smoke, *HEART metabolism, *SMOKING

Abstract

Aims: Active cigarette smoking is a major risk factor for chronic obstructive pulmonary disease that remains elevated after cessation. Skeletal muscle dysfunction has been well documented after smoking, but little is known about cardiac adaptations to cigarette smoking. The underlying cellular and molecular cardiac adaptations, independent of confounding lifestyle factors, and time course of reversibility by smoking cessation remain unclear. We hypothesized that smoking negatively affects cardiac metabolism and induces local inflammation in mice, which do not readily reverse upon 2‐week smoking cessation. Methods: Mice were exposed to air or cigarette smoke for 14 weeks with or without 1‐ or 2‐week smoke cessation. We measured cardiac mitochondrial respiration by high‐resolution respirometry, cardiac mitochondrial density, abundance of mitochondrial supercomplexes by electrophoresis, and capillarization, fibrosis, and macrophage infiltration by immunohistology, and performed cardiac metabolome and lipidome analysis by mass spectrometry. Results: Mitochondrial protein, supercomplex content, and respiration (all p < 0.03) were lower after smoking, which were largely reversed within 2‐week smoking cessation. Metabolome and lipidome analyses revealed alterations in mitochondrial metabolism, a shift from fatty acid to glucose metabolism, which did not revert to control upon smoking cessation. Capillary density was not different after smoking but increased after smoking cessation (p = 0.02). Macrophage infiltration and fibrosis (p < 0.04) were higher after smoking but did not revert to control upon smoking cessation. Conclusions: While cigarette‐impaired smoking‐induced cardiac mitochondrial function was reversed by smoking cessation, the remaining fibrosis and macrophage infiltration may contribute to the increased risk of cardiovascular events after smoking cessation. [ABSTRACT FROM AUTHOR]

Published

2024

11. Crosstalk among Reactive Oxygen Species, Autophagy and Metabolism in Myocardial Ischemia and Reperfusion Stages.

Author

Yajie Peng, Yachuan Tao, Lingxu Liu, Ji Zhang, and Bo Wei

Subjects

*MYOCARDIAL ischemia, *REACTIVE oxygen species, *CARDIOVASCULAR diseases

Abstract

Myocardial ischemia is the most common cardiovascular disease. Reperfusion, an important myocardial ischemia tool, causes unexpected and irreversible damage to cardiomyocytes, resulting in myocardial ischemia/reperfusion (MI/R) injury. Upon stress, especially oxidative stress induced by reactive oxygen species (ROS), autophagy, which degrades the intracellular energy storage to produce metabolites that are recycled into metabolic pathways to buffer metabolic stress, is initiated during myocardial ischemia and MI/R injury. Excellent cardioprotective effects of autophagy regulators against MI and MI/R have been reported. Reversing disordered cardiac metabolism induced by ROS also exhibits cardioprotective action in patients with myocardial ischemia. Herein, we review current knowledge on the crosstalk between ROS, cardiac autophagy, and metabolism in myocardial ischemia and MI/R. Finally, we discuss the possible regulators of autophagy and metabolism that can be exploited to harness the therapeutic potential of cardiac metabolism and autophagy in the diagnosis and treatment of myocardial ischemia and MI/R. [ABSTRACT FROM AUTHOR]

Published

2024

12. Cardiac Molecular Analysis Reveals Aging‐Associated Metabolic Alterations Promoting Glycosaminoglycans Accumulation via Hexosamine Biosynthetic Pathway

Author

Luís F. Grilo, Kip D. Zimmerman, Sobha Puppala, Jeannie Chan, Hillary F. Huber, Ge Li, Avinash Y. L. Jadhav, Benlian Wang, Cun Li, Geoffrey D. Clarke, Thomas C. Register, Paulo J. Oliveira, Peter W. Nathanielsz, Michael Olivier, Susana P. Pereira, and Laura A. Cox

Subjects

aging, cardiac hypertrophy, cardiac metabolism, cardiovascular disease, glycosaminoglycan, Science

Abstract

Abstract Age is a prominent risk factor for cardiometabolic disease, often leading to heart structural and functional changes. However, precise molecular mechanisms underlying cardiac remodeling and dysfunction exclusively resulting from physiological aging remain elusive. Previous research demonstrated age‐related functional alterations in baboons, analogous to humans. The goal of this study is to identify early cardiac molecular alterations preceding functional adaptations, shedding light on the regulation of age‐associated changes. Unbiased transcriptomics of left ventricle samples are performed from female baboons aged 7.5–22.1 years (human equivalent ≈30–88 years). Weighted‐gene correlation network and pathway enrichment analyses are performed, with histological validation. Modules of transcripts negatively correlated with age implicated declined metabolism‐oxidative phosphorylation, tricarboxylic acid cycle, glycolysis, and fatty‐acid β‐oxidation. Transcripts positively correlated with age suggested a metabolic shift toward glucose‐dependent anabolic pathways, including hexosamine biosynthetic pathway (HBP). This shift is associated with increased glycosaminoglycan synthesis, modification, precursor synthesis via HBP, and extracellular matrix accumulation, verified histologically. Upregulated extracellular matrix‐induced signaling coincided with glycosaminoglycan accumulation, followed by cardiac hypertrophy‐related pathways. Overall, these findings revealed a transcriptional shift in metabolism favoring glycosaminoglycan accumulation through HBP before cardiac hypertrophy. Unveiling this metabolic shift provides potential targets for age‐related cardiac diseases, offering novel insights into early age‐related mechanisms.

Published

2024

13. Cardiac overexpression of a mitochondrial SUR2A splice variant impairs cardiac function and worsens myocardial ischemia reperfusion injury in female mice

Author

Allison C. Wexler, Holly Dooge, Sarah El-Meanawy, Elizabeth Santos, Timothy Hacker, Aditya Tewari, Francisco J. Alvarado, and Mohun Ramratnam

Subjects

ATP sensitive potassium channels, Sulfonylurea receptors, Myocardial ischemia reperfusion injury, Cardiac metabolism, Sex differences, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

The small splice variant of the sulfonylurea receptor protein isoform 2 A (SUR2A-55) targets mitochondria and enhances mitoKATP activity. In male mice the overexpression of this protein promotes cardioprotection, reducing myocardial injury after an ischemic insult. However, it is unclear what impact SUR2A-55 overexpression has on the female myocardium. To investigate the impact of SU2R2A-55 on the female heart, mice with cardiac specific transgenic overexpression of SUR2A-55 (TGSUR2A-55) were examined by resting echocardiography and histopathology. In addition, hearts were subjected to ischemia reperfusion (IR) injury. Female TGSUR2A-55 mice had resting LV dysfunction and worse hemodynamic recovery with increased infarct size after IR injury. RNA-seq analysis found 227 differential expressed genes between WT and TGSUR2A-55 female mouse hearts that were enriched in pathways of cellular metabolism. This was in direct contrast to male mice that had only four differentially expressed genes. Female TGSUR2A-55 mice compared to female WT mice had reduced cardiomyocyte mitochondrial membrane potential without a change in electron transport chain protein expression. In addition, isolated mitochondria from female TGSUR2A-55 hearts displayed reduced sensitivity to ATP and diazoxide suggestive of increased mitoKATP activity. In conclusion, our data suggests that female TGSUR2A-55 mice are unable to tolerate a more active mitoKATP channel leading to LV dysfunction and worse response to IR injury. This is in direct contrast to our prior report showing cardioprotection in male mice overexpressing SUR2A-55 in heart. Future research directed at examining the expression and activity of mitoKATP subunits according to sex may elucidate different treatments for male and female patients.

Published

2024

14. Cardiac Metabolism

Author

Martin-Puig, Silvia, Menendez-Montes, Ivan, Crusio, Wim E., Series Editor, Dong, Haidong, Series Editor, Radeke, Heinfried H., Series Editor, Rezaei, Nima, Series Editor, Steinlein, Ortrud, Series Editor, Xiao, Junjie, Series Editor, Rickert-Sperling, Silke, editor, Kelly, Robert G., editor, and Haas, Nikolaus, editor

Published

2024

15. A Feasibility Study of [18F]F-AraG Positron Emission Tomography (PET) for Cardiac Imaging–Myocardial Viability in Ischemia–Reperfusion Injury Model

Author

Shrestha, Uttam M., Chae, Hee-Don, Fang, Qizhi, Lee, Randall J., Packiasamy, Juliet, Huynh, Lyna, Blecha, Joseph, Huynh, Tony L., VanBrocklin, Henry F., Levi, Jelena, and Seo, Youngho

Published

2024

16. MRI Application and Challenges of Hyperpolarized Carbon-13 Pyruvate in Translational and Clinical Cardiovascular Studies: A Literature Review.

Author

Frijia, Francesca, Flori, Alessandra, Giovannetti, Giulio, Barison, Andrea, Menichetti, Luca, Santarelli, Maria Filomena, and Positano, Vincenzo

Subjects

*LITERATURE reviews, *NUCLEAR magnetic resonance spectroscopy, *HEART metabolism, *MAGNETIC resonance imaging, *PYRUVATES, *CARDIOVASCULAR diseases

Abstract

Cardiovascular disease shows, or may even be caused by, changes in metabolism. Hyperpolarized magnetic resonance spectroscopy and imaging is a technique that could assess the role of different aspects of metabolism in heart disease, allowing real-time metabolic flux assessment in vivo. In this review, we introduce the main hyperpolarization techniques. Then, we summarize the use of dedicated radiofrequency 13C coils, and report a state of the art of 13C data acquisition. Finally, this review provides an overview of the pre-clinical and clinical studies on cardiac metabolism in the healthy and diseased heart. We furthermore show what advances have been made to translate this technique into the clinic in the near future and what technical challenges still remain, such as exploring other metabolic substrates. [ABSTRACT FROM AUTHOR]

Published

2024

17. Myocardial glycophagy flux dysregulation and glycogen accumulation characterize diabetic cardiomyopathy.

Author

Mellor, Kimberley M., Varma, Upasna, Koutsifeli, Parisa, Daniels, Lorna J., Benson, Victoria L., Annandale, Marco, Li, Xun, Nursalim, Yohanes, Janssens, Johannes V., Weeks, Kate L., Powell, Kim L., O'Brien, Terence J., Katare, Rajesh, Ritchie, Rebecca H., Bell, James R., Gottlieb, Roberta A., and Delbridge, Lea M.D.

Subjects

*DIABETIC cardiomyopathy, *GLYCOGEN, *HEART disease related mortality, *TYPE 1 diabetes, *LYSOSOMES, *TYPE 2 diabetes, *HOMEOSTASIS

Abstract

Diabetic heart disease morbidity and mortality is escalating. No specific therapeutics exist and mechanistic understanding of diabetic cardiomyopathy etiology is lacking. While lipid accumulation is a recognized cardiomyocyte phenotype of diabetes, less is known about glycolytic fuel handling and storage. Based on in vitro studies, we postulated the operation of an autophagy pathway in the myocardium specific for glycogen homeostasis – glycophagy. Here we visualize occurrence of cardiac glycophagy and show that the diabetic myocardium is characterized by marked glycogen elevation and altered cardiomyocyte glycogen localization. We establish that cardiac glycophagy flux is disturbed in diabetes. Glycophagy may represent a potential therapeutic target for alleviating the myocardial impacts of metabolic disruption in diabetic heart disease. [Display omitted] • myocardial glycogen accumulation is a consistent feature of type 1 and type 2 diabetes • marked glycogen infiltration is visualized in diabetic myocardium, clustered near mitochondria and dispersed throughout the myofilament architecture • glycogen is captured as phago-lysosome cargo, and in process of capture or release can be visualized • disturbances in glycogen-autophagy ('glycophagy')-mediated glycogen degradation are linked with myocardial glycogen accumulation in the diabetic heart • cardiac glycophagy may be a potential therapeutic target for development of treatments for diabetic heart disease [ABSTRACT FROM AUTHOR]

Published

2024

18. Large animal models of pressure overload-induced cardiac left ventricular hypertrophy to study remodelling of the human heart with aortic stenosis.

Author

Beslika, Evangelia, Leite-Moreira, Adelino, Windt, Leon J De, and Martins, Paula A da Costa

Subjects

*AORTIC stenosis, *DOGS, *CARDIAC hypertrophy, *ANIMAL models in research, *LEFT ventricular hypertrophy, *CATS, *HEART failure, *MUSCULAR hypertrophy, *CELL death

Abstract

Pathologic cardiac hypertrophy is a common consequence of many cardiovascular diseases, including aortic stenosis (AS). AS is known to increase the pressure load of the left ventricle, causing a compensative response of the cardiac muscle, which progressively will lead to dilation and heart failure. At a cellular level, this corresponds to a considerable increase in the size of cardiomyocytes, known as cardiomyocyte hypertrophy, while their proliferation capacity is attenuated upon the first developmental stages. Cardiomyocytes, in order to cope with the increased workload (overload), suffer alterations in their morphology, nuclear content, energy metabolism, intracellular homeostatic mechanisms, contractile activity, and cell death mechanisms. Moreover, modifications in the cardiomyocyte niche, involving inflammation, immune infiltration, fibrosis, and angiogenesis, contribute to the subsequent events of a pathologic hypertrophic response. Considering the emerging need for a better understanding of the condition and treatment improvement, as the only available treatment option of AS consists of surgical interventions at a late stage of the disease, when the cardiac muscle state is irreversible, large animal models have been developed to mimic the human condition, to the greatest extend. Smaller animal models lack physiological, cellular and molecular mechanisms that sufficiently resemblance humans and in vitro techniques yet fail to provide adequate complexity. Animals, such as the ferret (Mustello purtorius furo), lapine (rabbit, Oryctolagus cunigulus), feline (cat, Felis catus), canine (dog, Canis lupus familiaris), ovine (sheep, Ovis aries), and porcine (pig, Sus scrofa), have contributed to research by elucidating implicated cellular and molecular mechanisms of the condition. Essential discoveries of each model are reported and discussed briefly in this review. Results of large animal experimentation could further be interpreted aiming at prevention of the disease progress or, alternatively, at regression of the implicated pathologic mechanisms to a physiologic state. This review summarizes the important aspects of the pathophysiology of LV hypertrophy and the applied surgical large animal models that currently better mimic the condition. [ABSTRACT FROM AUTHOR]

Published

2024

19. Metabolic profiling of aortic stenosis and hypertrophic cardiomyopathy identifies mechanistic contrasts in substrate utilization.

Author

Pal, Nikhil, Acharjee, Animesh, Ament, Zsuzsanna, Dent, Tim, Yavari, Arash, Mahmod, Masliza, Ariga, Rina, West, James, Steeples, Violetta, Cassar, Mark, Howell, Neil J., Lockstone, Helen, Elliott, Kate, Yavari, Parisa, Briggs, William, Frenneaux, Michael, Prendergast, Bernard, Dwight, Jeremy S., Kharbanda, Rajesh, and Watkins, Hugh

Abstract

Aortic stenosis (AS) and hypertrophic cardiomyopathy (HCM) are distinct disorders leading to left ventricular hypertrophy (LVH), but whether cardiac metabolism substantially differs between these in humans remains to be elucidated. We undertook an invasive (aortic root, coronary sinus) metabolic profiling in patients with severe AS and HCM in comparison with non‐LVH controls to investigate cardiac fuel selection and metabolic remodeling. These patients were assessed under different physiological states (at rest, during stress induced by pacing). The identified changes in the metabolome were further validated by metabolomic and orthogonal transcriptomic analysis, in separately recruited patient cohorts. We identified a highly discriminant metabolomic signature in severe AS in all samples, regardless of sampling site, characterized by striking accumulation of long‐chain acylcarnitines, intermediates of fatty acid transport across the inner mitochondrial membrane, and validated this in a separate cohort. Mechanistically, we identify a downregulation in the PPAR‐α transcriptional network, including expression of genes regulating fatty acid oxidation (FAO). In silico modeling of β‐oxidation demonstrated that flux could be inhibited by both the accumulation of fatty acids as a substrate for mitochondria and the accumulation of medium‐chain carnitines which induce competitive inhibition of the acyl‐CoA dehydrogenases. We present a comprehensive analysis of changes in the metabolic pathways (transcriptome to metabolome) in severe AS, and its comparison to HCM. Our results demonstrate a progressive impairment of β‐oxidation from HCM to AS, particularly for FAO of long‐chain fatty acids, and that the PPAR‐α signaling network may be a specific metabolic therapeutic target in AS. [ABSTRACT FROM AUTHOR]

Published

2024

20. Myocardial Metabolism in Heart Failure with Preserved Ejection Fraction.

Author

Henry, John Aaron, Couch, Liam S., and Rider, Oliver J.

Subjects

*HEART metabolism, *VENTRICULAR ejection fraction, *HEART failure, *METABOLIC disorders, *OXIDATIVE phosphorylation

Abstract

Heart failure with preserved ejection fraction (HFpEF) is increasingly prevalent and now accounts for half of all heart failure cases. This rise is largely attributed to growing rates of obesity, hypertension, and diabetes. Despite its prevalence, the pathophysiological mechanisms of HFpEF are not fully understood. The heart, being the most energy-demanding organ, appears to have a compromised bioenergetic capacity in heart failure, affecting all phenotypes and aetiologies. While metabolic disturbances in heart failure with reduced ejection fraction (HFrEF) have been extensively studied, similar insights into HFpEF are limited. This review collates evidence from both animal and human studies, highlighting metabolic dysregulations associated with HFpEF and its risk factors, such as obesity, hypertension, and diabetes. We discuss how changes in substrate utilisation, oxidative phosphorylation, and energy transport contribute to HFpEF. By delving into these pathological shifts in myocardial energy production, we aim to reveal novel therapeutic opportunities. Potential strategies include modulating energy substrates, improving metabolic efficiency, and enhancing critical metabolic pathways. Understanding these aspects could be key to developing more effective treatments for HFpEF. [ABSTRACT FROM AUTHOR]

Published

2024

21. From Beats to Metabolism: the Heart at the Core of Interorgan Metabolic Cross Talk.

Author

Romero-Becera, Rafael, Santamans, Ayelen M., Arcones, Alba C., and Sabio, Guadalupe

Subjects

*HEART metabolism, *HEART beat, *METABOLIC regulation, *HEART diseases, *CARDIOVASCULAR diseases, *METABOLIC disorders

Abstract

The heart, once considered a mere blood pump, is now recognized as a multifunctional metabolic and endocrine organ. Its function is tightly regulated by various metabolic processes, at the same time it serves as an endocrine organ, secreting bioactive molecules that impact systemic metabolism. In recent years, research has shed light on the intricate interplay between the heart and other metabolic organs, such as adipose tissue, liver, and skeletal muscle. The metabolic flexibility of the heart and its ability to switch between different energy substrates play a crucial role in maintaining cardiac function and overall metabolic homeostasis. Gaining a comprehensive understanding of how metabolic disorders disrupt cardiac metabolism is crucial, as it plays a pivotal role in the development and progression of cardiac diseases. The emerging understanding of the heart as a metabolic and endocrine organ highlights its essential contribution to whole body metabolic regulation and offers new insights into the pathogenesis of metabolic diseases, such as obesity, diabetes, and cardiovascular disorders. In this review, we provide an in-depth exploration of the heart’s metabolic and endocrine functions, emphasizing its role in systemic metabolism and the interplay between the heart and other metabolic organs. Furthermore, emerging evidence suggests a correlation between heart disease and other conditions such as aging and cancer, indicating that the metabolic dysfunction observed in these conditions may share common underlying mechanisms. By unraveling the complex mechanisms underlying cardiac metabolism, we aim to contribute to the development of novel therapeutic strategies for metabolic diseases and improve overall cardiovascular health. [ABSTRACT FROM AUTHOR]

Published

2024

22. Cardiovascular outcomes and molecular targets for the cardiac effects of Sodium-Glucose Cotransporter 2 Inhibitors: A systematic review

Author

Rosalinda Madonna, Filippo Biondi, Mattia Alberti, Sandra Ghelardoni, Letizia Mattii, and Alberto D’Alleva

Subjects

Randomized clinical trials, SGLT2i, Autophagy, Cardiac metabolism, Connexins, Epigenetics, Therapeutics. Pharmacology, RM1-950

Abstract

Sodium-glucose cotransporter 2 inhibitors (SGLT2i), a new class of glucose-lowering drugs traditionally used to control blood glucose levels in patients with type 2 diabetes mellitus, have been proven to reduce major adverse cardiovascular events, including cardiovascular death, in patients with heart failure irrespective of ejection fraction and independently of the hypoglycemic effect. Because of their favorable effects on the kidney and cardiovascular outcomes, their use has been expanded in all patients with any combination of diabetes mellitus type 2, chronic kidney disease and heart failure. Although mechanisms explaining the effects of these drugs on the cardiovascular system are not well understood, their effectiveness in all these conditions suggests that they act at the intersection of the metabolic, renal and cardiac axes, thus disrupting maladaptive vicious cycles while contrasting direct organ damage. In this systematic review we provide a state of the art of the randomized controlled trials investigating the effect of SGLT2i on cardiovascular outcomes in patients with chronic kidney disease and/or heart failure irrespective of ejection fraction and diabetes. We also discuss the molecular targets and signaling pathways potentially explaining the cardiac effects of these pharmacological agents, from a clinical and experimental perspective.

Published

2024

23. Extra-cardiac BCAA catabolism lowers blood pressure and protects from heart failure.

Author

Murashige, Danielle, Jung, Jae, Neinast, Michael, Levin, Michael, Chu, Qingwei, Lambert, Jonathan, Garbincius, Joanne, Kim, Boa, Hoshino, Atsushi, Marti-Pamies, Ingrid, McDaid, Kendra, Shewale, Swapnil, Flam, Emily, Yang, Steven, Roberts, Emilia, Li, Li, Morley, Michael, Bedi, Kenneth, Hyman, Matthew, Frankel, David, Margulies, Kenneth, Assoian, Richard, Elrod, John, Rabinowitz, Joshua, Arany, Zoltan, and Jang, Cholsoon

Subjects

BCAA, Mendelian randomization, blood pressure, branched-chain amino acid, cardiac metabolism, cardiovascular metabolism, heart failure, hypertension, metabolomics, Humans, Blood Pressure, Amino Acids, Branched-Chain, Heart, Heart Failure, Energy Metabolism

Abstract

Pharmacologic activation of branched-chain amino acid (BCAA) catabolism is protective in models of heart failure (HF). How protection occurs remains unclear, although a causative block in cardiac BCAA oxidation is widely assumed. Here, we use in vivo isotope infusions to show that cardiac BCAA oxidation in fact increases, rather than decreases, in HF. Moreover, cardiac-specific activation of BCAA oxidation does not protect from HF even though systemic activation does. Lowering plasma and cardiac BCAAs also fails to confer significant protection, suggesting alternative mechanisms of protection. Surprisingly, activation of BCAA catabolism lowers blood pressure (BP), a known cardioprotective mechanism. BP lowering occurred independently of nitric oxide and reflected vascular resistance to adrenergic constriction. Mendelian randomization studies revealed that elevated plasma BCAAs portend higher BP in humans. Together, these data indicate that BCAA oxidation lowers vascular resistance, perhaps in part explaining cardioprotection in HF that is not mediated directly in cardiomyocytes.

Published

2022

24. Influence of the cytoprotective drug meldonium on diastolic dysfunction of the myocardium

Author

Olga Chetrus, Ghenadie Calin, Oxana Sirbu, Diana Sasu, Svetlana Gavriliuc, and Valeriu Istrati

Subjects

cardiocitoprotector, cardiac metabolism, ischemic heart disease, Medicine

Abstract

Background: The use of myocardial cytoprotectors (meldonium) in patients with exertional angina is a scientific-practical dilemma. Material and methods: An open randomized clinical trial was conducted involving 160 patients with chronic heart faliure (117 men and 43 women) aged 37 to 81 years. Of them, 142 patients had angina pectoris of stable effort from different functional classes, and 21 – unstable angina pectoris. Study groups were comparable according to the frequency of indication of background drugs and meldonium. Results: The number of patients with normal diastolic function in both groups, but with a net superiority to meldonium combination administration, has considerably increased: 41 patients (91.11%) in group II vs 33 (58.93%) in the group treated with basic treatment after 9 months of medication; 43 patients (95.56%) group II vs 36 (64.29%) in group I at 12 months of medication. During this period, no patients with pseudonormal type of diastolic dysfunction were registered, these passing into a ”more” favorable category – delayed relaxation. Conclusions: The data obtained confirmed the benefit of using cardiocitoprotection in inducing the reverse-remodelling of the myocardium of left ventricle regardless of the initial ventricular geometric pattern, but the administration of mildronate combination demonstrated a significantly superior efficiency to the basic treatment in hypertrophy of left ventricle regression, an event notable towards the end of the research period.

Published

2023

25. Cardiac Metabolism, Reprogramming, and Diseases.

Author

Wang, Haichang, Shen, Min, Shu, Xiaofei, Guo, Baolin, Jia, Tengfei, Feng, Jiaxu, Lu, Zuocheng, Chen, Yanyan, Lin, Jie, Liu, Yue, Zhang, Jiye, Zhang, Xuan, and Sun, Dongdong

Abstract

Cardiovascular diseases (CVD) account for the largest bulk of deaths worldwide, posing a massive burden on societies and the global healthcare system. Besides, the incidence and prevalence of these diseases are on the rise, demanding imminent action to revert this trend. Cardiovascular pathogenesis harbors a variety of molecular and cellular mechanisms among which dysregulated metabolism is of significant importance and may even proceed other mechanisms. The healthy heart metabolism primarily relies on fatty acids for the ultimate production of energy through oxidative phosphorylation in mitochondria. Other metabolites such as glucose, amino acids, and ketone bodies come next. Under pathological conditions, there is a shift in metabolic pathways and the preference of metabolites, termed metabolic remodeling or reprogramming. In this review, we aim to summarize cardiovascular metabolism and remodeling in different subsets of CVD to come up with a new paradigm for understanding and treatment of these diseases. [ABSTRACT FROM AUTHOR]

Published

2024

26. The Na/K-ATPase α1/Src Signaling Axis Regulates Mitochondrial Metabolic Function and Redox Signaling in Human iPSC-Derived Cardiomyocytes.

Author

Cai, Liquan, Pessoa, Marco T., Gao, Yingnyu, Strause, Sidney, Banerjee, Moumita, Tian, Jiang, Xie, Zijian, and Pierre, Sandrine V.

Subjects

CARDIAC contraction, INDUCED pluripotent stem cells, GENE targeting, MITOCHONDRIA, AMINO acid sequence, BASAL metabolism, CELL contraction

Abstract

Na/K-ATPase (NKA)-mediated regulation of Src kinase, which involves defined amino acid sequences of the NKA α1 polypeptide, has emerged as a novel regulatory mechanism of mitochondrial function in metazoans. Mitochondrial metabolism ensures adequate myocardial performance and adaptation to physiological demand. It is also a critical cellular determinant of cardiac repair and remodeling. To assess the impact of the proposed NKA/Src regulatory axis on cardiac mitochondrial metabolic function, we used a gene targeting approach in human cardiac myocytes. Human induced pluripotent stem cells (hiPSC) expressing an Src-signaling null mutant (A420P) form of the NKA α1 polypeptide were generated using CRISPR/Cas9-mediated genome editing. Total cellular Na/K-ATPase activity remained unchanged in A420P compared to the wild type (WT) hiPSC, but baseline phosphorylation levels of Src and ERK1/2 were drastically reduced. Both WT and A420P mutant hiPSC readily differentiated into cardiac myocytes (iCM), as evidenced by marker gene expression, spontaneous cell contraction, and subcellular striations. Total NKA α1-3 protein expression was comparable in WT and A420P iCM. However, live cell metabolism assessed functionally by Seahorse extracellular flux analysis revealed significant reductions in both basal and maximal rates of mitochondrial respiration, spare respiratory capacity, ATP production, and coupling efficiency. A significant reduction in ROS production was detected by fluorescence imaging in live cells, and confirmed by decreased cellular protein carbonylation levels in A420P iCM. Taken together, these data provide genetic evidence for a role of NKA α1/Src in the tonic stimulation of basal mitochondrial metabolism and ROS production in human cardiac myocytes. This signaling axis in cardiac myocytes may provide a new approach to counteract mitochondrial dysfunction in cardiometabolic diseases. [ABSTRACT FROM AUTHOR]

Published

2023

27. In silico study of the mechanisms of hypoxia and contractile dysfunction during ischemia and reperfusion of hiPSC cardiomyocytes

Author

Mohamadamin Forouzandehmehr, Michelangelo Paci, Jari Hyttinen, and Jussi T. Koivumäki

Subjects

in silico modeling, human stem cell-derived cardiomyocytes, action potential, levosimendan, cardiac metabolism, ischemia, reperfusion, pharmacology, Medicine, Pathology, RB1-214

Published

2024

28. Cardiomyocyte tetrahydrobiopterin synthesis regulates fatty acid metabolism and susceptibility to ischaemia–reperfusion injury

Author

Sandy M. Chu, Lisa C. Heather, Surawee Chuaiphichai, Thomas Nicol, Benjamin Wright, Matthieu Miossec, Jennifer K. Bendall, Gillian Douglas, Mark J. Crabtree, and Keith M. Channon

Subjects

cardiac metabolism, ischaemia–reperfusion injury, tetrahydrobiopterin, Physiology, QP1-981

Abstract

Abstract Tetrahydrobiopterin (BH4) is an essential cofactor for nitric oxide (NO) synthases in which its production of NO is crucial for cardiac function. However, non‐canonical roles of BH4 have been discovered recently and the cell‐specific role of cardiomyocyte BH4 in cardiac function and metabolism remains to be elucidated. Therefore, we developed a novel mouse model of cardiomyocyte BH4 deficiency, by cardiomyocyte‐specific deletion of Gch1, which encodes guanosine triphosphate cyclohydrolase I, a required enzyme for de novo BH4 synthesis. Cardiomyocyte (cm)Gch1 mRNA expression and BH4 levels from cmGch1 KO mice were significantly reduced compared to Gch1flox/flox (WT) littermates. Transcriptomic analyses and protein assays revealed downregulation of genes involved in fatty acid oxidation in cmGch1 KO hearts compared with WT, accompanied by increased triacylglycerol concentration within the myocardium. Deletion of cardiomyocyte BH4 did not alter basal cardiac function. However, the recovery of left ventricle function was improved in cmGch1 KO hearts when subjected to ex vivo ischaemia–reperfusion (IR) injury, with reduced infarct size compared to WT hearts. Metabolomic analyses of cardiac tissue after IR revealed that long‐chain fatty acids were increased in cmGch1 KO hearts compared to WT, whereas at 5 min reperfusion (post‐35 min ischaemia) fatty acid metabolite levels were higher in WT compared to cmGch1 KO hearts. These results indicate a new role for BH4 in cardiomyocyte fatty acid metabolism, such that reduction of cardiomyocyte BH4 confers a protective effect in response to cardiac IR injury. Manipulating cardiac metabolism via BH4 could play a therapeutic role in limiting IR injury.

Published

2023

29. Programming of cardiac metabolism by miR-15b-5p, a miRNA released in cardiac extracellular vesicles following ischemia-reperfusion injury

Author

Lucas C. Pantaleão, Elena Loche, Denise S. Fernandez-Twinn, Laura Dearden, Adriana Córdova-Casanova, Clive Osmond, Minna K. Salonen, Eero Kajantie, Youguo Niu, Juliana de Almeida-Faria, Benjamin D. Thackray, Tuija M. Mikkola, Dino A. Giussani, Andrew J. Murray, Martin Bushell, Johan G. Eriksson, and Susan E. Ozanne

Subjects

Maternal obesity, Cardiac metabolism, miR-15b, CVD biomarker, Sex differences, Developmental programming, Internal medicine, RC31-1245

Abstract

Objective: We investigated the potential involvement of miRNAs in the developmental programming of cardiovascular diseases (CVD) by maternal obesity. Methods: Serum miRNAs were measured in individuals from the Helsinki Birth Cohort (with known maternal body mass index), and a mouse model was used to determine causative effects of maternal obesity during pregnancy and ischemia-reperfusion on offspring cardiac miRNA expression and release. Results: miR-15b-5p levels were increased in the sera of males born to mothers with higher BMI and in the hearts of adult mice born to obese dams. In an ex-vivo model of perfused mouse hearts, we demonstrated that cardiac tissue releases miR-15b-5p, and that some of the released miR-15b-5p was contained within small extracellular vesicles (EVs). We also demonstrated that release was higher from hearts exposed to maternal obesity following ischaemia/reperfusion. Over-expression of miR-15b-5p in vitro led to loss of outer mitochondrial membrane stability and to repressed fatty acid oxidation in cardiomyocytes. Conclusions: These findings suggest that miR-15-b could play a mechanistic role in the dysregulation of cardiac metabolism following exposure to an in utero obesogenic environment and that its release in cardiac EVs following ischaemic damage may be a novel factor contributing to inter-organ communication between the programmed heart and peripheral tissues.

Published

2024

30. Western diet triggers cardiac dysfunction in heterozygous Mybpc3-targeted knock-in mice: A two-hit model of hypertrophic cardiomyopathy

Author

Edgar E. Nollet, Sila Algül, Max Goebel, Saskia Schlossarek, Nicole N. van der Wel, Judith J.M. Jans, Mark A. van de Wiel, Jaco C. Knol, Thang V. Pham, Sander R. Piersma, Richard de Goeij-de Haas, Jill Hermans, Jan Bert van Klinken, Michel van Weeghel, Riekelt H. Houtkooper, Lucie Carrier, Connie R. Jimenez, Diederik W.D. Kuster, and Jolanda van der Velden

Subjects

Hypertrophic cardiomyopathy, Sarcomere mutation, Metabolic health, Cardiac metabolism, Pathophysiology, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Background and aim: Phenotypic expression of hypertrophic cardiomyopathy (HCM) and disease course are associated with unfavorable metabolic health. We investigated if Western diet (WD) feeding is sufficient to trigger cardiac hypertrophy and dysfunction in heterozygous (HET) Mybpc3c.772G>A knock-in mice. Methods and results: Wild-type (WT) and HET mice (3-months-old) were fed a WD or normal chow (NC) for 8 weeks. Metabolomic analyses on serum revealed systemic metabolic derailment in WD-fed WT and HET mice. Strikingly, only WD-fed HET mice developed cardiac hypertrophy and dysfunction, which was not driven by aggravated cardiac myosin binding protein-C haploinsufficiency. WD reduced oxidative phosphorylation and increased toxic lipids in the heart irrespective of genotype. Cardiac proteomic analyses revealed higher abundance of proteins involved in fatty acid oxidation in WD-fed mice, however this increase was blunted in HET compared to WT mice. Accordingly, cardiac metabolomic and lipidomic analyses showed accumulation of acylcarnitines in WD-fed HET vs WT mice. Conclusion: WD feeding triggered cardiac dysfunction and hypertrophy in otherwise phenotype-negative HET Mybpc3c.772G>A mice. We propose that the presence of a HCM mutation predisposes the heart to metabolic inflexibility when subjected to systemic metabolic stress. Our study represents a novel approach to study the interplay between unfavorable metabolic health and mutation-induced defects in HCM disease development.

Published

2023

31. CYTOPROTECTIVE EFFECT OF MELDONIUM ON CARDIOMYOCYTE

Author

Olga Chetruș

Subjects

cardiocitoprotector, cardiac metabolism, ischemic heart disease, Medicine, Surgery, RD1-811

Abstract

Background. The use of myocardial cytoprotectors (meldonium) in patients with exertional angina is a scientific-practical dilemma. Material and methods. An open randomized clinical trial was conducted involving 160 patients with chronic heart failure (117 men and 43 women) aged 37 to 81 years. Of them, 142 patients had angina pectoris of stable effort from different functional classes, and 21 – unstable angina pectoris. Study groups were comparable according to the frequency of indication of background drugs and meldonium. Results. The results of our study indicate the activation of oxidative stress in patients with stable angina pectoris, relevant in this regard being the changes of malonic dialdehyde, catalase and superoxide-dismutase, which become more pronounced in the first 24 hours after the start of the treatment and, although, by the 6th month an attenuation of the activity of the prooxidant status is detected, it intensifies by 12 months it intensifies. Discussions. All results completes the vision based on the link between the antioxidant defense and the aggravated cardiovascular evolution. Another consolidated aspect is to demonstrate the superior effectiveness of meldonium administration. There was demonstrated the effectiveness feasibility of meldonium vis-à-vis the markers of oxidative stress, endothelial dysfunction and comparable systemic inflammation. Conclusions. The inclusion of metabolic drugs in the complex treatment of patients with stable angina increases the clinical effectiveness of basic pharmacotherapy 4 times when prescribing meldonium (p

Published

2023

32. Editorial: Cardiac energetic efficiency and cardiometabolic diseases

Author

Teresa Vanessa Fiorentino, Francesca Cinti, and Ram Jagannathan

Subjects

myocardial efficiency, cardiovascular disease, cardiac energetics, cardiac metabolism, cardiac performance, Diseases of the circulatory (Cardiovascular) system, RC666-701

Published

2023

33. Epigenetics in Heart Failure: Role of DNA Methylation in Potential Pathways Leading to Heart Failure with Preserved Ejection Fraction.

Author

Rabkin, Simon W. and Wong, Chenille N.

Subjects

DNA methylation, VENTRICULAR ejection fraction, HEART failure, SARCOPLASMIC reticulum, ATRIAL fibrillation, EPIGENOMICS

Abstract

This review will focus on epigenetic modifications utilizing the DNA methylation mechanism, which is potentially involved in the pathogenesis of heart failure with preserved ejection fraction (HFpEF). The putative pathways of HFpEF will be discussed, specifically myocardial fibrosis, myocardial inflammation, sarcoplasmic reticulum Ca2+-ATPase, oxidative–nitrosative stress, mitochondrial and metabolic defects, as well as obesity. The relationship of HFpEF to aging and atrial fibrillation will be examined from the perspective of DNA methylation. [ABSTRACT FROM AUTHOR]

Published

2023

34. 心脏代谢损伤与适应性代偿在心力衰竭 发生发展中的作用.

Author

翟义远, 李俊杰, 任洁宇, and 唐 旻

Subjects

*FATTY acid oxidation, *HEART diseases, *HEART metabolism, *HEART failure, *KETONES

Abstract

Fatty acids, glucose, ketone bodies, and amino acids, arc utilized by the heart to meet its energy requirements, with fatty acids being the main source of energy. The damage of fatty acids oxidation is accompanied by heart failure. Cardiac metabolic remodeling occurs, wherein the heart utilizes glucose, ketone bodies, and other substances as energy substrates instead of fatty acid to meet its energetic requirements. Although this compensatory adaptation can improve energy deficiency-induced cardiac dysfunction, the metabolic balance of cardiomyocytcs can also he affected, thereby increasing the risk of cardiac dysfunction. This review summarizes the cardiac metabolic changes that occur during heart failure and the effects of cardiac metabolism nianipulation oil heart failure. It also explores the possibility of cardiac metabolic remodeling as a treatment for heart failure. [ABSTRACT FROM AUTHOR]

Published

2023

35. Development of heart failure with preserved ejection fraction is independent of eosinophils in a preclinical model.

Author

Pan, Qi, Chen, Cheng, Gong, Zhaoting, Chen, Guihao, and Yang, Yuejin

Subjects

*HEART failure, *EOSINOPHILS, *LEUCOCYTES, *VENTRICULAR ejection fraction, *ANIMAL models in research

Abstract

The increasing burden of heart failure with preserved ejection fraction (HFpEF) has become a global health problem. HFpEF is characterized by systematic inflammation, cardiac metabolic remodeling, and fibrosis. Eosinophils act as an essential but generally overlooked subgroup of white blood cells, which participate in cardiac fibrosis, as reported in several recent studies. Herein, we explored the role of eosinophils in a "two‐hit" preclinical HFpEF model. The peripheral eosinophil counts were comparable between the normal chow and HFpEF mice. Deficiency of eosinophils failed to alter the phenotype of HFpEF. Conclusively, the development of HFpEF is independent of eosinophils in terms of the functional, biochemical, and histological results. [ABSTRACT FROM AUTHOR]

Published

2023

36. The development and application of novel magnetic resonance spectroscopic and imaging techniques to assess cardiac energetics and substrate handling in the human heart

Author

Apps, Andrew, Rider, Oliver, and Tyler, Damian

Subjects

616.1, Cardiac metabolism, Diabetes, Magentic resonance spectroscopy, Coronary heart disease, Heart failure

Abstract

Myocardial energy homeostasis requires an interplay between three stages of energy transduction; the choice of substrate oxidised, the rate of mitochondrial oxidative phosphorylation, and finally transfer of adenosine triphosphate (ATP) to sites of disposal via the intermediate phosphocreatine (PCr). Whilst all three elements are fundamental, until recently, non-invasive assessment was limited to 31Phosphorus magnetic resonance spectroscopy (31P-MRS) assessment of the PCr/ATP ratio. This thesis aims to gain a deeper understanding of pathologic energy metabolism by using two novel MRS techniques. Firstly 31P-MRS at the ultra-high field strength of 7T to assess myocardial Pi, and secondly the first in man clinical translation of hyperpolarised 13C MRS, which offers the ability to quantify in real time the metabolism of an administered hyperpolarised 13C containing substrate into downstream 13C containing products. Using these techniques, a more comprehensive assessment of energy metabolism either side of the mitochondria was made in both the diabetic and failing heart. The pyruvate dehydrogenase complex (PDH) catalyses the irreversible decarboxylation of glycolytically derived pyruvate to Acetyl CoA (Coenzyme A). Flux through this enzyme determines the prevailing rate of glucose oxidation and is highly regulated. Using a hyperpolarised and 13C labelled version of its substrate ([1-13C]pyruvate), PDH flux can be recorded using MRS by monitoring production of [13C]bicarbonate. Chapter 3 presents preclinical work to define the optimal preparation strategy prior to recording [1-13C]pyruvate MRS. This was essential prior to translation into human hyperpolarised imaging studies, to both minimise variability and maximise baseline flux through the PDH complex. Chapter 4 is a human multi-nuclear 31P, 13C and 1H study of cardiac metabolism in diabetes. I present the first human cardiac hyperpolarised 13C MRS study, and show, along with elevated cardiac triglyceride and reduced PCr/ATP, a significant reduction in flux though PDH in diabetes. The switch from fatty acids to glucose oxidation occurring after feeding is also clearly shown in both controls and diabetics, providing the first non-invasive visualisation of the Randle cycle in vivo. The effect size of diabetes on PDH flux is greater than that on PCr/ATP, with only a small group of patients with diabetes needed to show a significant difference, demonstrating the power of the technique, and the magnitude of this physiological metabolic change. As all cellular energy requiring processes have a unique value for the free energy of ATP hydrolysis (ΔGATP) above which they halt, measurement of ΔGATP would be a powerful tool to understand the thermodynamic consequences of pathological substrate metabolism. However, whilst this is routinely performed in animal experiments, the measurement of myocardial inorganic phosphate (Pi) is necessary, which has previously not been achieved due to the presence of blood pool 2,3-diphoshphoglycerate (2,3-DPG) obscuring the Pi resonance within the 31P spectrum. In Chapter 5, I report results from a novel 31P MRS STimulated Echo Acquisition Mode (STEAM) sequence, which allowed suppression of the blood pool signal, and demonstration of Pi free from contamination. Firstly, the robustness of such an approach is proven, following which, gross stability of Pi/PCr, and myocardial pH (which can be computed from the chemical shift of Pi) in a healthy cohort during dobutamine stress is shown. In chapter 6, pathological energy metabolism in the diabetic heart is further investigated; a rise in resting Pi/PCr is shown, but in contrast to decreases in PCr/ATP, no change is seen during dobutamine stress. Finally, focus turns to dilated cardiomyopathy (DCM). Here a significant rise in Pi/PCr during stress is reported, independent of the degree of underlying systolic dysfunction, which has implications for a change in ΔGATP during physical exertion. My thesis data chapters conclude with chapter 7, presenting a small amount of metabolic imaging data obtained using a novel hybrid spiral shot 13C sequence and hyperpolarised [1-13C]pyruvate, in which regional variations of PDH flux in the hearts of those with coronary artery disease is shown. This preliminary work confirms the potential for hyperpolarised [13C]bicarbonate production, to be a novel marker of myocardial viability. Collectively, this work uses new MR techniques to study pathological energy metabolism on both sides of mitochondrial oxidative phosphorylation; upstream at the level of the substrate, and downstream in the high energy phosphate pool.

Published

2021

37. Revealing unseen changes in hearts of growth restricted babies.

Author

Thornburg, Kent L.

Subjects

*HEART metabolism, *HUMAN physiology, *HYPOXEMIA, *BRAIN injuries, *MEDICAL care

Published

2024

38. Dynamic FDG PET Imaging to Probe for Cardiac Metabolic Remodeling in Adults Born Premature

Author

Corrado, Philip A, Barton, Gregory P, Razalan-Krause, Francheska C, François, Christopher J, Chesler, Naomi C, Wieben, Oliver, Eldridge, Marlowe, McMillan, Alan B, and Goss, Kara N

Subjects

Paediatrics, Biomedical and Clinical Sciences, Nutrition, Prevention, Cardiovascular, Preterm, Low Birth Weight and Health of the Newborn, Heart Disease, Pediatric, Perinatal Period - Conditions Originating in Perinatal Period, Infant Mortality, Biomedical Imaging, Clinical Research, Aetiology, 2.1 Biological and endogenous factors, Good Health and Well Being, positron emission tomography, fluorodeoxyglucose, glucose, cardiac metabolism, premature birth, Clinical Sciences, Biomedical and clinical sciences

Abstract

Individuals born very premature have an increased cardiometabolic and heart failure risk. While the structural differences of the preterm heart are now well-described, metabolic insights into the physiologic mechanisms underpinning this risk are needed. Here, we used dynamic fluorodeoxyglucose (FDG) positron emission tomography/magnetic resonance imaging (PET-MRI) in young adults born term and preterm during normoxic (N = 28 preterm; 18 term) and hypoxic exposure (12% O2; N = 26 preterm; 17 term) to measure the myocardial metabolic rate of glucose (MMRglc) in young adults born term (N = 18) and preterm (N = 32), hypothesizing that young adults born preterm would have higher rates of MMRglc under normoxic conditions and a reduced ability to augment glucose metabolism under hypoxic conditions. MMRglc was calculated from the myocardial and blood pool time-activity curves by fitting the measured activities to the 3-compartment model of FDG kinetics. MMRglc was similar at rest between term and preterm subjects, and decreased during hypoxia exposure in both groups (p = 0.02 for MMRglc hypoxia effect). There were no differences observed between groups in the metabolic response to hypoxia, either globally (serum glucose and lactate measures) or within the myocardium. Thus, we did not find evidence of altered myocardial metabolism in the otherwise healthy preterm-born adult. However, whether subtle changes in myocardial metabolism may preceed or predict heart failure in this population remains to be determined.

Published

2021

39. Ketone metabolism in the heart

Author

Bin abdul kadir, Azrul, Evans, Rhys, and Clarke, Kieran

Subjects

612.1, Cardiac metabolism

Abstract

The aphorism “fat burns in the flame of carbohydrate” leads to the question of whether the oxidation of the ketone body, D-β-hydroxybutyrate (βHB), is facilitated by anaplerosis via glycogen and/or glucogenic amino acids. The work in this thesis aimed to investigate the importance of anaplerosis in ketone body metabolism in the isolated heart. The first study (Chapter 3) determined whether glycolysis from glycogen affected the heart’s ability to oxidise βHB. The glycogen content of isolated rat hearts was altered by perfusion with or without glucose, before perfusing with Krebs-Henseleit (KH) buffer containing [14C]-βHB or [5-3H]-glucose to measure βHB oxidation and glycolytic rates, respectively. βHB oxidation in hearts with low glycogen (LG) was 2-fold lower than those with high glycogen (HG), and βHB oxidation rates directly correlated with glycogen content. βHB oxidation decreased glycolytic rates to ~0.2 μmol. gww-1.min-1 in all hearts, redirecting glucose into glycogen in LG heart, but not in HG hearts. βHB alone or with glucose increased the Krebs cycle intermediates, citrate, 2-oxoglutarate and succinate, and the total nicotinamide adenine dinucleotide phosphate (NADP/H) pool measured using metabolomics. Thus, glycogen is required for βHB oxidation. The second study (Chapter 4) determined the effect of βHB oxidation on cardiac energetics using 31P-NMR spectroscopy. In HG hearts, βHB oxidation increased the free energy of ATP hydrolysis (∆GATP) by increasing the concentration of phosphocreatine ([PCr]) and the phosphorylation potential, calculated from the [ATP]/[ADP][Pi] ratio. βHB oxidation was unable to increase the low ∆GATP in LG hearts due to low glycolytic flux through pyruvate. The third study (Chapter 5) defined the effect of the glucogenic amino acids, asparagine, valine and glutamine, on βHB oxidation in hearts with decreased flux through pyruvate to oxaloacetate (glycogen-depleted and perfused with low glucose buffer). Asparagine increased βHB oxidation 2-fold by increasing the metabolites of the malate-aspartate shuttle and purine nucleotide cycle, aspartate, fumarate and guanosine triphosphate. Neither valine nor glutamine increased βHB oxidation rates. The final study (Chapter 6) determined the effect of substrates and loading conditions on cardiac efficiency (the ratio between hydraulic work and oxygen consumption) in working rat hearts. Fatty acids were found to decrease cardiac efficiency, via increased oxygen consumption and decreased hydraulic work, at both low and high pre- and afterloads. At high, but not at low, pre- and after-loads, βHB plus acetoacetate (AcAc) increased efficiency by increasing hydraulic work. Thus, βHB plus AcAc increased cardiac efficiency more than glucose alone or with fatty acids at high pre- and after-loads. In conclusion, βHB oxidation and glycolysis from glycogen have a synergistic relationship in heart, which serves to increase the ∆GATP and thereby cardiac efficiency.

Published

2020

40. MRI Application and Challenges of Hyperpolarized Carbon-13 Pyruvate in Translational and Clinical Cardiovascular Studies: A Literature Review

Author

Francesca Frijia, Alessandra Flori, Giulio Giovannetti, Andrea Barison, Luca Menichetti, Maria Filomena Santarelli, and Vincenzo Positano

Subjects

hyperpolarized magnetic resonance, dynamic nuclear polarization, carbon-13, pyruvate, cardiac metabolism, Medicine (General), R5-920

Abstract

Cardiovascular disease shows, or may even be caused by, changes in metabolism. Hyperpolarized magnetic resonance spectroscopy and imaging is a technique that could assess the role of different aspects of metabolism in heart disease, allowing real-time metabolic flux assessment in vivo. In this review, we introduce the main hyperpolarization techniques. Then, we summarize the use of dedicated radiofrequency 13C coils, and report a state of the art of 13C data acquisition. Finally, this review provides an overview of the pre-clinical and clinical studies on cardiac metabolism in the healthy and diseased heart. We furthermore show what advances have been made to translate this technique into the clinic in the near future and what technical challenges still remain, such as exploring other metabolic substrates.

Published

2024

41. Current status and emerging trends of cardiac metabolism from the past 20 years: A bibliometric study

Author

Hongqin Wang, Xiaolin Liu, Qingbing Zhou, Li Liu, Zijun Jia, Yifei Qi, Fengqin Xu, and Ying Zhang

Subjects

Cardiac metabolism, Bibliometric, Glucose metabolism, Fatty acid oxidation, Heart failure, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Background: Abnormal cardiac metabolism is a key factor in the development of cardiovascular diseases. Consequently, there has been considerable emphasis on researching and developing drugs that regulate metabolism. This study employed bibliometric methods to comprehensively and objectively analyze the relevant literature, offering insights into the knowledge dynamics in this field. Methods: The data source for this study was the Web of Science Core Collection (WoSCC), from which the collected data were imported into bibliometric software for analysis. Results: The United States was the leading contributor, accounting for 38.33 % of publications. The University of Washington and Damian J. Tyler were the most active institution and author, respectively. The American Journal of Physiology-Heart and Circulatory Physiology, Journal of Molecular and Cellular Cardiology, Cardiovascular Research, Circulation Research, and American Journal of Physiology-Endocrinology and Metabolism were highly influential journals that published numerous high-quality articles on cardiac metabolism. Common keywords in this research area included heart failure, insulin resistance, skeletal muscle, mitochondria, as well as topic words such as cardiac metabolism, fatty acid oxidation, glucose metabolism, and myocardial metabolism. Co-citation analysis has shown that research on heart failure and in vitro modeling of cardiovascular disease has gained prominence in recent years and making it a research hotspot. Conclusion: Research on cardiac metabolism is steadily growing, with a specific focus on heart failure and the interplay between mitochondrial dysfunction, insulin resistance, and cardiac metabolism. An emerging trend in this field involves the enhancement of maturation in human induced pluripotent stem cell-derived cardiomyocyte (hiPSC-CM) through the manipulation of cardiac metabolism.

Published

2023

42. Function and regulation of ubiquitin-like SUMO system in heart

Author

Ying Wang, Zhihao Liu, Xiyun Bian, Chenxu Zhao, Xin Zhang, Xiaozhi Liu, and Nan Wang

Subjects

SUMO, heart, protein quality control, Ca2+ cycle, cardiac metabolism, Biology (General), QH301-705.5

Abstract

The small ubiquitin-related modifier (SUMOylation) system is a conserved, reversible, post-translational protein modification pathway covalently attached to the lysine residues of proteins in eukaryotic cells, and SUMOylation is catalyzed by SUMO-specific activating enzyme (E1), binding enzyme (E2) and ligase (E3). Sentrin-specific proteases (SENPs) can cleave the isopeptide bond of a SUMO conjugate and catalyze the deSUMOylation reaction. SUMOylation can regulate the activity of proteins in many important cellular processes, including transcriptional regulation, cell cycle progression, signal transduction, DNA damage repair and protein stability. Biological experiments in vivo and in vitro have confirmed the key role of the SUMO conjugation/deconjugation system in energy metabolism, Ca2+ cycle homeostasis and protein quality control in cardiomyocytes. In this review, we summarized the research progress of the SUMO conjugation/deconjugation system and SUMOylation-mediated cardiac actions based on related studies published in recent years, and highlighted the further research areas to clarify the role of the SUMO system in the heart by using emerging technologies.

Published

2023

43. Development of heart failure with preserved ejection fraction is independent of eosinophils in a preclinical model

Author

Qi Pan, Cheng Chen, Zhaoting Gong, Guihao Chen, and Yuejin Yang

Subjects

cardiac fibrosis, cardiac metabolism, diastolic function, eosinophils, heart failure with preserved ejection, Immunologic diseases. Allergy, RC581-607

Abstract

Abstract The increasing burden of heart failure with preserved ejection fraction (HFpEF) has become a global health problem. HFpEF is characterized by systematic inflammation, cardiac metabolic remodeling, and fibrosis. Eosinophils act as an essential but generally overlooked subgroup of white blood cells, which participate in cardiac fibrosis, as reported in several recent studies. Herein, we explored the role of eosinophils in a “two‐hit” preclinical HFpEF model. The peripheral eosinophil counts were comparable between the normal chow and HFpEF mice. Deficiency of eosinophils failed to alter the phenotype of HFpEF. Conclusively, the development of HFpEF is independent of eosinophils in terms of the functional, biochemical, and histological results.

Published

2023

44. Parkinson's Disease and the Heart: Studying Cardiac Metabolism in the 6-Hydroxydopamine Model.

Author

Silva da Fonsêca, Victor, Goncalves, Valeria de Cassia, Augusto Izidoro, Mario, Guimarães de Almeida, Antônio-Carlos, Luiz Affonso Fonseca, Fernando, Alexandre Scorza, Fulvio, Finsterer, Josef, and Scorza, Carla Alessandra

Subjects

*HEART metabolism, *PARKINSON'S disease, *METABOLIC models, *ALANINE, *STEARIC acid, *LIPID metabolism, *ALANINE aminotransferase, *HYDROXYCHOLESTEROLS

Abstract

Parkinson's-disease (PD) is an incurable, age-related neurodegenerative disease, and its global prevalence of disability and death has increased exponentially. Although motor symptoms are the characteristic manifestations of PD, the clinical spectrum also contains a wide variety of non-motor symptoms, which are the main cause of disability and determinants of the decrease in a patient's quality of life. Noteworthy in this regard is the stress on the cardiac system that is often observed in the course of PD; however, its effects have not yet been adequately researched. Here, an untargeted metabolomics approach was used to assess changes in cardiac metabolism in the 6-hydroxydopamine model of PD. Beta-sitosterol, campesterol, cholesterol, monoacylglycerol, α-tocopherol, stearic acid, beta-glycerophosphoric acid, o-phosphoethanolamine, myo-inositol-1-phosphate, alanine, valine and allothreonine are the metabolites that significantly discriminate parkinsonian rats from sham counterparts. Upon analysis of the metabolic pathways with the aim of uncovering the main biological pathways involved in concentration patterns of cardiac metabolites, the biosynthesis of both phosphatidylethanolamine and phosphatidylcholine, the glucose-alanine cycle, glutathione metabolism and plasmalogen synthesis most adequately differentiated sham and parkinsonian rats. Our results reveal that both lipid and energy metabolism are particularly involved in changes in cardiac metabolism in PD. These results provide insight into cardiac metabolic signatures in PD and indicate potential targets for further investigation. [ABSTRACT FROM AUTHOR]

Published

2023

45. Unravelling the Interplay between Cardiac Metabolism and Heart Regeneration.

Author

Yu, Fan, Cong, Shuo, Yap, En Ping, Hausenloy, Derek J., and Ramachandra, Chrishan J.

Subjects

*HEART metabolism, *CARDIAC regeneration, *CORONARY disease, *MYOCARDIAL ischemia, *HEART failure, *CELL cycle

Abstract

Ischemic heart disease (IHD) is the leading cause of heart failure (HF) and is a significant cause of morbidity and mortality globally. An ischemic event induces cardiomyocyte death, and the ability for the adult heart to repair itself is challenged by the limited proliferative capacity of resident cardiomyocytes. Intriguingly, changes in metabolic substrate utilisation at birth coincide with the terminal differentiation and reduced proliferation of cardiomyocytes, which argues for a role of cardiac metabolism in heart regeneration. As such, strategies aimed at modulating this metabolism-proliferation axis could, in theory, promote heart regeneration in the setting of IHD. However, the lack of mechanistic understanding of these cellular processes has made it challenging to develop therapeutic modalities that can effectively promote regeneration. Here, we review the role of metabolic substrates and mitochondria in heart regeneration, and discuss potential targets aimed at promoting cardiomyocyte cell cycle re-entry. While advances in cardiovascular therapies have reduced IHD-related deaths, this has resulted in a substantial increase in HF cases. A comprehensive understanding of the interplay between cardiac metabolism and heart regeneration could facilitate the discovery of novel therapeutic targets to repair the damaged heart and reduce risk of HF in patients with IHD. [ABSTRACT FROM AUTHOR]

Published

2023

46. Cardiomyocyte tetrahydrobiopterin synthesis regulates fatty acid metabolism and susceptibility to ischaemia–reperfusion injury.

Author

Chu, Sandy M., Heather, Lisa C., Chuaiphichai, Surawee, Nicol, Thomas, Wright, Benjamin, Miossec, Matthieu, Bendall, Jennifer K., Douglas, Gillian, Crabtree, Mark J., and Channon, Keith M.

Subjects

*TETRAHYDROBIOPTERIN, *FATTY acids, *HEART metabolism, *FATTY acid oxidation, *GUANOSINE triphosphate, *NITRIC oxide

Abstract

New Findings: What is the central question of this study?What are the physiological roles of cardiomyocyte‐derived tetrahydrobiopterin (BH4) in cardiac metabolism and stress response?What is the main finding and its importance?Cardiomyocyte BH4 has a physiological role in cardiac metabolism. There was a shift of substrate preference from fatty acid to glucose in hearts with targeted deletion of BH4 synthesis. The changes in fatty‐acid metabolic profile were associated with a protective effect in response to ischaemia–reperfusion (IR) injury, and reduced infarct size. Manipulating fatty acid metabolism via BH4 availability could play a therapeutic role in limiting IR injury. Tetrahydrobiopterin (BH4) is an essential cofactor for nitric oxide (NO) synthases in which its production of NO is crucial for cardiac function. However, non‐canonical roles of BH4 have been discovered recently and the cell‐specific role of cardiomyocyte BH4 in cardiac function and metabolism remains to be elucidated. Therefore, we developed a novel mouse model of cardiomyocyte BH4 deficiency, by cardiomyocyte‐specific deletion of Gch1, which encodes guanosine triphosphate cyclohydrolase I, a required enzyme for de novo BH4 synthesis. Cardiomyocyte (cm)Gch1 mRNA expression and BH4 levels from cmGch1 KO mice were significantly reduced compared to Gch1flox/flox (WT) littermates. Transcriptomic analyses and protein assays revealed downregulation of genes involved in fatty acid oxidation in cmGch1 KO hearts compared with WT, accompanied by increased triacylglycerol concentration within the myocardium. Deletion of cardiomyocyte BH4 did not alter basal cardiac function. However, the recovery of left ventricle function was improved in cmGch1 KO hearts when subjected to ex vivo ischaemia–reperfusion (IR) injury, with reduced infarct size compared to WT hearts. Metabolomic analyses of cardiac tissue after IR revealed that long‐chain fatty acids were increased in cmGch1 KO hearts compared to WT, whereas at 5 min reperfusion (post‐35 min ischaemia) fatty acid metabolite levels were higher in WT compared to cmGch1 KO hearts. These results indicate a new role for BH4 in cardiomyocyte fatty acid metabolism, such that reduction of cardiomyocyte BH4 confers a protective effect in response to cardiac IR injury. Manipulating cardiac metabolism via BH4 could play a therapeutic role in limiting IR injury. [ABSTRACT FROM AUTHOR]

Published

2023

47. Changes in Lipoprotein Lipase in the Heart Following Diabetes Onset

Author

Chae Syng Lee, Yajie Zhai, and Brian Rodrigues

Subjects

Cardiac metabolism, Lipoprotein lipase, Heparanase, Vascular endothelial growth factor, Diabetic cardiomyopathy, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Due to its constant pumping and contraction, the heart requires a substantial amount of energy, with fatty acids (FAs) providing a major part of its adenosine triphosphate (ATP). However, the heart is incapable of making this substrate and attains its FAs from multiple sources, including the action of lipoprotein lipase (LPL). LPL is produced in cardiomyocytes and subsequently secreted to its heparan sulfate proteoglycan (HSPG) binding sites on the plasma membrane. To then move LPL to the endothelial cell (EC) lumen, glycosylphosphatidylinositol-anchored high-density lipoprotein-binding protein 1 (GPIHBP1) attaches to interstitial LPL and transfers it to the vascular lumen, where the LPL is ready to perform its function of breaking down circulating triglycerides (TG) into FAs. The endo-β-glucuronidase heparanase (Hpa) is unique in that it is the only known mammalian enzyme to cleave heparan sulfate (HS), thereby promoting the abovementioned release of LPL from the cardiomyocyte HSPG. In diabetes, it has been suggested that changes in how the heart generates energy are responsible for the development of diabetic cardiomyopathy (DCM). Following moderate diabetes, with the reduction in glucose utilization, the heart increases its LPL activity at the vascular lumen due to an increase in Hpa action. Although this adaptation might be beneficial to compensate for the underutilization of glucose by the heart, it is toxic over the long term, as harmful lipid metabolite accumulation, along with augmented FA oxidation and thus oxidative stress, leads to cell death. This coincides with the loss of a cardioprotective growth factor—namely, vascular endothelial growth factor B (VEGFB). This review discusses interconnections between Hpa, LPL, and VEGFB and their potential implications in DCM. Given that mechanism-based therapeutic care for DCM is unavailable, understanding the pathology of this cardiomyopathy, along with the contribution of LPL, will help us advance its clinical management.

Published

2023

48. Diet-induced insulin resistance altered cardiac GLUT4 and FATP/CD36 expression in rats

Author

Oladele Ayobami Afolabi, Babatunde Adebola Alabi, and Olufemi Oluranti

Subjects

Energy substrate, Cardiac metabolism, Transport protein, Substrate utilization, Hyperinsulinemia, Medicine (General), R5-920, Science

Abstract

Abstract Background Altered substrate transport protein expression is central to the effect of insulin resistance on cardiac metabolism. The present study was thus designed to investigate the comparative effects of high fat, high sucrose and salt-induced IR on cardiac expression of fatty acid transporter (FATP) and glucose transporter (GLUT4) in rats. Results Rats fed with high fat, high sucrose and salt diets developed impaired glucose tolerance (p > 0.05) and hyperinsulinemia (p

Published

2022

49. Glycometabolism reprogramming: Implications for cardiovascular diseases.

Author

Peng, Guolong, Yan, Jialong, Chen, Linxi, and Li, Lanfang

Subjects

*CARDIOVASCULAR diseases, *PENTOSE phosphate pathway, *CARDIAC hypertrophy, *CARDIOVASCULAR system, *HEART, *OXIDATIVE phosphorylation, *PULMONARY hypertension, *GLYCOLYSIS, *RIGHT ventricular hypertrophy

Abstract

Glycometabolism is well known for its roles as the main source of energy, which mainly includes three metabolic pathways: oxidative phosphorylation, glycolysis and pentose phosphate pathway. The orderly progress of glycometabolism is the basis for the maintenance of cardiovascular function. However, upon exposure to harmful stimuli, the intracellular glycometabolism changes or tends to shift toward another glycometabolism pathway more suitable for its own development and adaptation. This shift away from the normal glycometabolism is also known as glycometabolism reprogramming, which is commonly related to the occurrence and aggravation of cardiovascular diseases. In this review, we elucidate the physiological role of glycometabolism in the cardiovascular system and summarize the mechanisms by which glycometabolism drives cardiovascular diseases, including diabetes, cardiac hypertrophy, heart failure, atherosclerosis, and pulmonary hypertension. Collectively, directing GMR back to normal glycometabolism might provide a therapeutic strategy for the prevention and treatment of related cardiovascular diseases. [ABSTRACT FROM AUTHOR]

Published

2023

50. Functional and Metabolic Imaging in Heart Failure with Preserved Ejection Fraction: Promises, Challenges, and Clinical Utility.

Author

Burrage, Matthew K, Lewis, Andrew J, and Miller, Jack J J.

Abstract

Heart failure with preserved ejection fraction (HFpEF) is recognised as an increasingly prevalent, morbid and burdensome condition with a poor outlook. Recent advances in both the understanding of HFpEF and the technological ability to image cardiac function and metabolism in humans have simultaneously shone a light on the molecular basis of this complex condition of diastolic dysfunction, and the inflammatory and metabolic changes that are associated with it, typically in the context of a complex patient. This review both makes the case for an integrated assessment of the condition, and highlights that metabolic alteration may be a measurable outcome for novel targeted forms of medical therapy. It furthermore highlights how recent technological advancements and advanced medical imaging techniques have enabled the characterisation of the metabolism and function of HFpEF within patients, at rest and during exercise. [ABSTRACT FROM AUTHOR]

Published

2023