RESUMEN
The heart alters the rate and relative oxidation of fatty acids and glucose based on availability and energetic demand. Insulin plays a crucial role in this process diminishing fatty acid and increasing glucose oxidation when glucose availability increases. Loss of insulin sensitivity and metabolic flexibility can result in cardiovascular disease. It is therefore important to identify mechanisms by which insulin regulates substrate utilization in the heart. Mitochondrial pyruvate dehydrogenase (PDH) is the key regulatory site for the oxidation of glucose for ATP production. Nevertheless, the impact of insulin on PDH activity has not been fully delineated, particularly in the heart. We sought in vivo evidence that insulin stimulates cardiac PDH and that this process is driven by the inhibition of fatty acid oxidation. Mice injected with insulin exhibited dephosphorylation and activation of cardiac PDH. This was accompanied by an increase in the content of malonyl-CoA, an inhibitor of carnitine palmitoyltransferase 1 (CPT1), and, thus, mitochondrial import of fatty acids. Administration of the CPT1 inhibitor oxfenicine was sufficient to activate PDH. Malonyl-CoA is produced by acetyl-CoA carboxylase (ACC). Pharmacologic inhibition or knockout of cardiac ACC diminished insulin-dependent production of malonyl-CoA and activation of PDH. Finally, circulating insulin and cardiac glucose utilization exhibit daily rhythms reflective of nutritional status. We demonstrate that time-of-day-dependent changes in PDH activity are mediated, in part, by ACC-dependent production of malonyl-CoA. Thus, by inhibiting fatty acid oxidation, insulin reciprocally activates PDH. These studies identify potential molecular targets to promote cardiac glucose oxidation and treat heart disease.
Asunto(s)
Ácidos Grasos , Insulina , Miocardio , Oxidación-Reducción , Complejo Piruvato Deshidrogenasa , Animales , Insulina/metabolismo , Complejo Piruvato Deshidrogenasa/metabolismo , Ratones , Miocardio/metabolismo , Miocardio/enzimología , Ácidos Grasos/metabolismo , Acetil-CoA Carboxilasa/metabolismo , Acetil-CoA Carboxilasa/genética , Carnitina O-Palmitoiltransferasa/metabolismo , Carnitina O-Palmitoiltransferasa/genética , Malonil Coenzima A/metabolismo , Masculino , Ratones Noqueados , Glucosa/metabolismo , Ratones Endogámicos C57BLRESUMEN
Myocardial infarction (MI) is characterized by a significant loss of cardiomyocytes (CMs), and it is suggested that reactive oxygen species (ROS) are involved in cell cycle arrest, leading to impaired CM renewal. Thioredoxin-1 (Trx-1) scavenges ROS and may play a role in restoring CM renewal. However, the truncated form of Trx-1, Trx-80, can compromise its efficacy by exerting antagonistic effects. Therefore, a Trx-1 mimetic peptide called CB3 was tested as an alternative way to restore CMs. This study aimed to investigate the effects of Trx-1, Trx-80, and CB3 on mice with experimental MI and study the underlying mechanism of CB3 on CMs. Mouse cardiac parameters were quantified by echocardiography, and infarction size and fibrosis determined using Trichrome and Picro-Sirius Red staining. The study found that Trx-1 and CB3 improved mouse cardiac function, reduced the size of cardiac infarct and fibrosis, and decreased the expression of cardiac inflammatory markers. Furthermore, CB3 polarized macrophages into M2 phenotype, reduced apoptosis and oxidative stress after MI, and increased CM proliferation in cell culture and in vivo. CB3 effectively protected against myocardial infarction and could represent a new class of compounds for treating MI.
Asunto(s)
Infarto del Miocardio , Tiorredoxinas , Ratones , Animales , Especies Reactivas de Oxígeno/metabolismo , Tiorredoxinas/metabolismo , Infarto del Miocardio/metabolismo , Miocitos Cardíacos/metabolismo , Péptidos/farmacología , Péptidos/uso terapéutico , Péptidos/metabolismo , Apoptosis , Fibrosis , Remodelación Ventricular , Miocardio/metabolismo , Modelos Animales de EnfermedadRESUMEN
Cardiomyocytes are highly metabolic cells responsible for generating the contractile force in the heart. During fetal development and regeneration, these cells actively divide but lose their proliferative activity in adulthood. The mechanisms that coordinate their metabolism and proliferation are not fully understood. Here, we study the role of the transcription factor NFYa in developing mouse hearts. Loss of NFYa alters cardiomyocyte composition, causing a decrease in immature regenerative cells and an increase in trabecular and mature cardiomyocytes, as identified by spatial and single-cell transcriptome analyses. NFYa-deleted cardiomyocytes exhibited reduced proliferation and impaired mitochondrial metabolism, leading to cardiac growth defects and embryonic death. NFYa, interacting with cofactor SP2, activates genes linking metabolism and proliferation at the transcription level. Our study identifies a nodal role of NFYa in regulating prenatal cardiac growth and a previously unrecognized transcriptional control mechanism of heart metabolism, highlighting the importance of mitochondrial metabolism during heart development and regeneration.
Asunto(s)
Miocitos Cardíacos , Factores de Transcripción , Animales , Ratones , Proliferación Celular/fisiología , Desarrollo Fetal , Corazón Fetal/metabolismo , Corazón/fisiología , Miocitos Cardíacos/metabolismo , Factores de Transcripción/metabolismoRESUMEN
Obesity affects a growing fraction of the population and is a risk factor for type 2 diabetes and cardiovascular disease. Even in the absence of hypertension and coronary artery disease, type 2 diabetes can result in a heart disease termed diabetic cardiomyopathy. Diminished glucose oxidation, increased reliance on fatty acid oxidation for energy production, and oxidative stress are believed to play causal roles. However, the progression of metabolic changes and mechanisms by which these changes impact the heart have not been established. Cardiac pyruvate dehydrogenase (PDH), the central regulatory site for glucose oxidation, is rapidly inhibited in mice fed high dietary fat, a model of obesity and diabetes. Increased reliance on fatty acid oxidation for energy production, in turn, enhances mitochondrial pro-oxidant production. Inhibition of PDH may therefore initiate metabolic inflexibility and oxidative stress and precipitate diabetic cardiomyopathy. We discuss evidence from the literature that supports a role for PDH inhibition in loss in energy homeostasis and diastolic function in obese and diabetic humans and in rodent models. Finally, seemingly contradictory findings highlight the complexity of the disease and the need to delineate progressive changes in cardiac metabolism, the impact on myocardial structure and function, and the ability to intercede.
RESUMEN
Emerging evidence indicates that a subset of RNA molecules annotated as noncoding contain short open reading frames that code for small functional proteins called microproteins, which have largely been overlooked due to their small size. To search for cardiac-expressed microproteins, we used a comparative genomics approach and identified mitolamban (Mtlbn) as a highly conserved 47-amino acid transmembrane protein that is abundantly expressed in the heart. Mtlbn localizes specifically to the inner mitochondrial membrane where it interacts with subunits of complex III of the electron transport chain and with mitochondrial respiratory supercomplexes. Genetic deletion of Mtlbn in mice altered complex III assembly dynamics and reduced complex III activity. Unbiased metabolomic analysis of heart tissue from Mtlbn knockout mice further revealed an altered metabolite profile consistent with deficiencies in complex III activity. Cardiac-specific Mtlbn overexpression in transgenic (TG) mice induced cardiomyopathy with histological, biochemical, and ultrastructural pathologic features that contributed to premature death. Metabolomic analysis and biochemical studies indicated that hearts from Mtlbn TG mice exhibited increased oxidative stress and mitochondrial dysfunction. These findings reveal Mtlbn as a cardiac-expressed inner mitochondrial membrane microprotein that contributes to mitochondrial electron transport chain activity through direct association with complex III and the regulation of its assembly and function.
Asunto(s)
Cardiomiopatías/metabolismo , Complejo III de Transporte de Electrones/metabolismo , Proteínas de la Membrana/metabolismo , Mitocondrias Cardíacas/metabolismo , Proteínas Mitocondriales/metabolismo , Miocardio/metabolismo , Animales , Cardiomiopatías/genética , Células Cultivadas , Complejo III de Transporte de Electrones/genética , Proteínas de la Membrana/genética , Ratones , Ratones Noqueados , Mitocondrias Cardíacas/genética , Proteínas Mitocondriales/genética , Especificidad de ÓrganosRESUMEN
The inability of adult mammalian cardiomyocytes to proliferate underpins the development of heart failure following myocardial injury. Although the newborn mammalian heart can spontaneously regenerate for a short period of time after birth, this ability is lost within the first week after birth in mice, partly due to increased mitochondrial reactive oxygen species (ROS) production which results in oxidative DNA damage and activation of DNA damage response. This increase in ROS levels coincides with a postnatal switch from anaerobic glycolysis to fatty acid (FA) oxidation by cardiac mitochondria. However, to date, a direct link between mitochondrial substrate utilization and oxidative DNA damage is lacking. Here, we generated ROS-sensitive fluorescent sensors targeted to different subnuclear compartments (chromatin, heterochromatin, telomeres, and nuclear lamin) in neonatal rat ventricular cardiomyocytes, which allowed us to determine the spatial localization of ROS in cardiomyocyte nuclei upon manipulation of mitochondrial respiration. Our results demonstrate that FA utilization by the mitochondria induces a significant increase in ROS detection at the chromatin level compared to other nuclear compartments. These results indicate that mitochondrial metabolic perturbations directly alter the nuclear redox status and that the chromatin appears to be particularly sensitive to the prooxidant effect of FA utilization by the mitochondria.
Asunto(s)
Ácidos Grasos/metabolismo , Mitocondrias/metabolismo , Miocitos Cardíacos/metabolismo , Animales , Línea Celular , Proliferación Celular , Daño del ADN , Ratones , Estrés Oxidativo , Especies Reactivas de Oxígeno/metabolismoRESUMEN
BACKGROUND: Metabolic remodeling precedes most alterations during cardiac hypertrophic growth under hemodynamic stress. The elevation of glucose utilization has been recognized as a hallmark of metabolic remodeling. However, its role in cardiac hypertrophic growth and heart failure in response to pressure overload remains to be fully illustrated. Here, we aimed to dissect the role of cardiac PKM1 (pyruvate kinase muscle isozyme 1) in glucose metabolic regulation and cardiac response under pressure overload. METHODS: Cardiac-specific deletion of PKM1 was achieved by crossing the floxed PKM1 mouse model with the cardiomyocyte-specific Cre transgenic mouse. PKM1 transgenic mice were generated under the control of tetracycline response elements, and cardiac-specific overexpression of PKM1 was induced by doxycycline administration in adult mice. Pressure overload was triggered by transverse aortic constriction. Primary neonatal rat ventricular myocytes were used to dissect molecular mechanisms. Moreover, metabolomics and nuclear magnetic resonance spectroscopy analyses were conducted to determine cardiac metabolic flux in response to pressure overload. RESULTS: We found that PKM1 expression is reduced in failing human and mouse hearts. It is important to note that cardiomyocyte-specific deletion of PKM1 exacerbates cardiac dysfunction and fibrosis in response to pressure overload. Inducible overexpression of PKM1 in cardiomyocytes protects the heart against transverse aortic constriction-induced cardiomyopathy and heart failure. At the mechanistic level, PKM1 is required for the augmentation of glycolytic flux, mitochondrial respiration, and ATP production under pressure overload. Furthermore, deficiency of PKM1 causes a defect in cardiomyocyte growth and a decrease in pyruvate dehydrogenase complex activity at both in vitro and in vivo levels. CONCLUSIONS: These findings suggest that PKM1 plays an essential role in maintaining a homeostatic response in the heart under hemodynamic stress.
Asunto(s)
Proteínas Portadoras/genética , Susceptibilidad a Enfermedades , Insuficiencia Cardíaca/etiología , Insuficiencia Cardíaca/metabolismo , Proteínas de la Membrana/genética , Miocitos Cardíacos/metabolismo , Hormonas Tiroideas/genética , Remodelación Ventricular/genética , Animales , Biomarcadores , Proteínas Portadoras/metabolismo , Respiración de la Célula , Modelos Animales de Enfermedad , Progresión de la Enfermedad , Activación Enzimática , Expresión Génica , Glucosa/metabolismo , Glucólisis , Insuficiencia Cardíaca/fisiopatología , Pruebas de Función Cardíaca , Humanos , Proteínas de la Membrana/metabolismo , Ratones , Ratones Noqueados , Mitocondrias/genética , Mitocondrias/metabolismo , Modelos Biológicos , Hormonas Tiroideas/metabolismo , Proteínas de Unión a Hormona TiroideRESUMEN
[Figure: see text].
Asunto(s)
Insuficiencia Cardíaca Diastólica/terapia , Mitocondrias Cardíacas/metabolismo , Miopatías Mitocondriales/terapia , NAD/biosíntesis , Niacinamida/análogos & derivados , Compuestos de Piridinio/administración & dosificación , Acetilación , Acil-CoA Deshidrogenasa/metabolismo , Animales , Modelos Animales de Enfermedad , Regulación hacia Abajo , Ácidos Grasos/metabolismo , Humanos , Cetona Oxidorreductasas/metabolismo , Masculino , Ratones , Ratones Endogámicos C57BL , Miopatías Mitocondriales/metabolismo , NAD/análisis , NAD/deficiencia , NAD/genética , Niacinamida/administración & dosificación , Oxidación-Reducción , Consumo de Oxígeno , Sirtuina 3/metabolismoRESUMEN
The adipose tissue stroma is a rich source of molecularly distinct stem and progenitor cell populations with diverse functions in metabolic regulation, adipogenesis, and inflammation. The ontology of these populations and the mechanisms that govern their behaviors in response to stimuli, such as overfeeding, however, are unclear. Here, we show that the developmental fates and functional properties of adipose platelet-derived growth factor receptor beta (PDGFRß)+ progenitor subpopulations are tightly regulated by mitochondrial metabolism. Reducing the mitochondrial ß-oxidative capacity of PDGFRß+ cells via inducible expression of MitoNEET drives a pro-inflammatory phenotype in adipose progenitors and alters lineage commitment. Furthermore, disrupting mitochondrial function in PDGFRß+ cells rapidly induces alterations in immune cell composition in lean mice and impacts expansion of adipose tissue in diet-induced obesity. The adverse effects on adipose tissue remodeling can be reversed by restoring mitochondrial activity in progenitors, suggesting therapeutic potential for targeting energy metabolism in these cells.
Asunto(s)
Adipogénesis , Tejido Adiposo Blanco , Tejido Adiposo/metabolismo , Tejido Adiposo Blanco/metabolismo , Animales , Proteínas de Unión a Hierro/metabolismo , Proteínas de la Membrana/metabolismo , Ratones , Mitocondrias , Células Madre/metabolismoRESUMEN
BACKGROUND: BET (bromodomain and extraterminal) epigenetic reader proteins, in particular BRD4 (bromodomain-containing protein 4), have emerged as potential therapeutic targets in a number of pathological conditions, including cancer and cardiovascular disease. Small-molecule BET protein inhibitors such as JQ1 have demonstrated efficacy in reversing cardiac hypertrophy and heart failure in preclinical models. Yet, genetic studies elucidating the biology of BET proteins in the heart have not been conducted to validate pharmacological findings and to unveil potential pharmacological side effects. METHODS: By engineering a cardiomyocyte-specific BRD4 knockout mouse, we investigated the role of BRD4 in cardiac pathophysiology. We performed functional, transcriptomic, and mitochondrial analyses to evaluate BRD4 function in developing and mature hearts. RESULTS: Unlike pharmacological inhibition, loss of BRD4 protein triggered progressive declines in myocardial function, culminating in dilated cardiomyopathy. Transcriptome analysis of BRD4 knockout mouse heart tissue identified early and specific disruption of genes essential to mitochondrial energy production and homeostasis. Functional analysis of isolated mitochondria from these hearts confirmed that BRD4 ablation triggered significant changes in mitochondrial electron transport chain protein expression and activity. Computational analysis identified candidate transcription factors participating in the BRD4-regulated transcriptome. In particular, estrogen-related receptor α, a key nuclear receptor in metabolic gene regulation, was enriched in promoters of BRD4-regulated mitochondrial genes. CONCLUSIONS: In aggregate, we describe a previously unrecognized role for BRD4 in regulating cardiomyocyte mitochondrial homeostasis, observing that its function is indispensable to the maintenance of normal cardiac function.
Asunto(s)
Cardiomiopatía Dilatada/metabolismo , Núcleo Celular/metabolismo , Metabolismo Energético , Mitocondrias Cardíacas/metabolismo , Miocitos Cardíacos/metabolismo , Proteínas Nucleares/metabolismo , Factores de Transcripción/metabolismo , Transcriptoma , Disfunción Ventricular Izquierda/metabolismo , Función Ventricular Izquierda , Animales , Cardiomiopatía Dilatada/genética , Cardiomiopatía Dilatada/patología , Cardiomiopatía Dilatada/fisiopatología , Núcleo Celular/genética , Núcleo Celular/patología , Proteínas del Complejo de Cadena de Transporte de Electrón/genética , Proteínas del Complejo de Cadena de Transporte de Electrón/metabolismo , Metabolismo Energético/genética , Epigénesis Genética , Receptor alfa de Estrógeno/genética , Receptor alfa de Estrógeno/metabolismo , Perfilación de la Expresión Génica , Insuficiencia Cardíaca/genética , Insuficiencia Cardíaca/metabolismo , Insuficiencia Cardíaca/patología , Insuficiencia Cardíaca/fisiopatología , Ratones Noqueados , Mitocondrias Cardíacas/genética , Mitocondrias Cardíacas/patología , Miocitos Cardíacos/patología , Proteínas Nucleares/genética , Factores de Transcripción/genética , Disfunción Ventricular Izquierda/genética , Disfunción Ventricular Izquierda/patología , Disfunción Ventricular Izquierda/fisiopatología , Función Ventricular Izquierda/genéticaRESUMEN
The neonatal mammalian heart is capable of regeneration for a brief window of time after birth. However, this regenerative capacity is lost within the first week of life, which coincides with a postnatal shift from anaerobic glycolysis to mitochondrial oxidative phosphorylation, particularly towards fatty-acid utilization. Despite the energy advantage of fatty-acid beta-oxidation, cardiac mitochondria produce elevated rates of reactive oxygen species when utilizing fatty acids, which is thought to play a role in cardiomyocyte cell-cycle arrest through induction of DNA damage and activation of DNA-damage response (DDR) pathway. Here we show that inhibiting fatty-acid utilization promotes cardiomyocyte proliferation in the postnatatal heart. First, neonatal mice fed fatty-acid deficient milk showed prolongation of the postnatal cardiomyocyte proliferative window, however cell cycle arrest eventually ensued. Next, we generated a tamoxifen-inducible cardiomyocyte-specific, pyruvate dehydrogenase kinase 4 (PDK4) knockout mouse model to selectively enhance oxidation of glycolytically derived pyruvate in cardiomyocytes. Conditional PDK4 deletion resulted in an increase in pyruvate dehydrogenase activity and consequently an increase in glucose relative to fatty-acid oxidation. Loss of PDK4 also resulted in decreased cardiomyocyte size, decreased DNA damage and expression of DDR markers and an increase in cardiomyocyte proliferation. Following myocardial infarction, inducible deletion of PDK4 improved left ventricular function and decreased remodelling. Collectively, inhibition of fatty-acid utilization in cardiomyocytes promotes proliferation, and may be a viable target for cardiac regenerative therapies.
Asunto(s)
Ciclo Celular , Mitocondrias Cardíacas/metabolismo , Miocitos Cardíacos/citología , Animales , Daño del ADN , Grasas de la Dieta/administración & dosificación , Grasas de la Dieta/metabolismo , Ácidos Grasos/metabolismo , Ratones , Ratones Noqueados , Miocitos Cardíacos/metabolismo , Piruvato Deshidrogenasa Quinasa Acetil-Transferidora/genética , Piruvato Deshidrogenasa Quinasa Acetil-Transferidora/metabolismo , Especies Reactivas de Oxígeno/metabolismoRESUMEN
The healthy heart has a dynamic capacity to respond and adapt to changes in nutrient availability. Metabolic inflexibility, such as occurs with diabetes, increases cardiac reliance on fatty acids to meet energetic demands, and this results in deleterious effects, including mitochondrial dysfunction, that contribute to pathophysiology. Enhancing glucose usage may mitigate metabolic inflexibility and be advantageous under such conditions. Here, we sought to identify how mitochondrial function and cardiac metabolism are affected in a transgenic mouse model of enhanced cardiac glycolysis (GlycoHi) basally and following a short-term (7-day) high-fat diet (HFD). GlycoHi mice constitutively express an active form of phosphofructokinase-2, resulting in elevated levels of the PFK-1 allosteric activator fructose 2,6-bisphosphate. We report that basally GlycoHi mitochondria exhibit augmented pyruvate-supported respiration relative to fatty acids. Nevertheless, both WT and GlycoHi mitochondria had a similar shift toward increased rates of fatty acid-supported respiration following HFD. Metabolic profiling by GC-MS revealed distinct features based on both genotype and diet, with a unique increase in branched-chain amino acids in the GlycoHi HFD group. Targeted quantitative proteomics analysis also supported both genotype- and diet-dependent changes in protein expression and uncovered an enhanced expression of pyruvate dehydrogenase kinase 4 (PDK4) in the GlycoHi HFD group. These results support a newly identified mechanism whereby the levels of fructose 2,6-bisphosphate promote mitochondrial PDK4 levels and identify a secondary adaptive response that prevents excessive mitochondrial pyruvate oxidation when glycolysis is sustained after a high-fat dietary challenge.
Asunto(s)
Dieta Alta en Grasa/efectos adversos , Glucólisis/efectos de los fármacos , Corazón/efectos de los fármacos , Miocardio/metabolismo , Proteínas Quinasas/metabolismo , Proteínas Quinasas Activadas por AMP/metabolismo , Animales , Glucosa/metabolismo , Ratones , Mitocondrias Cardíacas/efectos de los fármacos , Mitocondrias Cardíacas/metabolismo , Miocardio/citología , Proteómica , Estrés Fisiológico , Factores de TiempoRESUMEN
Tissue regenerative potential displays striking divergence across phylogeny and ontogeny, but the underlying mechanisms remain enigmatic. Loss of mammalian cardiac regenerative potential correlates with cardiomyocyte cell-cycle arrest and polyploidization as well as the development of postnatal endothermy. We reveal that diploid cardiomyocyte abundance across 41 species conforms to Kleiber's law-the ¾-power law scaling of metabolism with bodyweight-and inversely correlates with standard metabolic rate, body temperature, and serum thyroxine level. Inactivation of thyroid hormone signaling reduces mouse cardiomyocyte polyploidization, delays cell-cycle exit, and retains cardiac regenerative potential in adults. Conversely, exogenous thyroid hormones inhibit zebrafish heart regeneration. Thus, our findings suggest that loss of heart regenerative capacity in adult mammals is triggered by increasing thyroid hormones and may be a trade-off for the acquisition of endothermy.
Asunto(s)
Corazón/fisiología , Miocitos Cardíacos/fisiología , Poliploidía , Regeneración/fisiología , Hormonas Tiroideas/fisiología , Animales , Regulación de la Temperatura Corporal , Puntos de Control del Ciclo Celular , Proliferación Celular , Diploidia , Ratones , Miocitos Cardíacos/clasificación , Filogenia , Receptores de Hormona Tiroidea/genética , Receptores de Hormona Tiroidea/fisiología , Regeneración/efectos de los fármacos , Regeneración/genética , Transducción de Señal , Hormonas Tiroideas/farmacología , Pez CebraRESUMEN
BACKGROUND: Inorganic phosphate (Pi) is used extensively as a preservative and a flavor enhancer in the Western diet. Physical inactivity, a common feature of Western societies, is associated with increased cardiovascular morbidity and mortality. It is unknown whether dietary Pi excess contributes to exercise intolerance and physical inactivity. METHODS: To determine an association between Pi excess and physical activity in humans, we assessed the relationship between serum Pi and actigraphy-determined physical activity level, as well as left ventricular function by cardiac magnetic resonance imaging, in DHS-2 (Dallas Heart Study phase 2) participants after adjusting for relevant variables. To determine direct effects of dietary Pi on exercise capacity, oxygen uptake, serum nonesterified fatty acid, and glucose were measured during exercise treadmill test in C57/BL6 mice fed either a high-Pi (2%) or normal-Pi (0.6%) diet for 12 weeks. To determine the direct effect of Pi on muscle metabolism and expression of genes involved in fatty acid metabolism, additional studies in differentiated C2C12 myotubes were conducted after subjecting to media containing 1 to 3 mmol/L Pi (pH 7.0) to simulate in vivo phosphate conditions. RESULTS: In participants of the DHS-2 (n=1603), higher serum Pi was independently associated with reduced time spent in moderate to vigorous physical activity ( P=0.01) and increased sedentary time ( P=0.004). There was no association between serum Pi and left ventricular ejection fraction or volumes. In animal studies, compared with the control diet, consumption of high-Pi diet for 12 weeks did not alter body weight or left ventricular function but reduced maximal oxygen uptake, treadmill duration, spontaneous locomotor activity, fat oxidation, and fatty acid levels and led to downregulation of genes involved in fatty acid synthesis, release, and oxidation, including Fabp4, Hsl, Fasn, and Pparγ, in muscle. Similar results were recapitulated in vitro by incubating C2C12 myotubes with high-Pi media. CONCLUSIONS: Our data demonstrate a detrimental effect of dietary Pi excess on skeletal muscle fatty acid metabolism and exercise capacity that is independent of obesity and cardiac contractile function. Dietary Pi may represent a novel and modifiable target to reduce physical inactivity associated with the Western diet.
Asunto(s)
Metabolismo Energético/efectos de los fármacos , Tolerancia al Ejercicio/efectos de los fármacos , Ácidos Grasos/metabolismo , Músculo Esquelético/efectos de los fármacos , Fosfatos/efectos adversos , Fósforo Dietético/efectos adversos , Animales , Línea Celular , Metabolismo Energético/genética , Ejercicio Físico , Tolerancia al Ejercicio/genética , Regulación de la Expresión Génica , Humanos , Masculino , Ratones Endogámicos C57BL , Mitocondrias Musculares/efectos de los fármacos , Mitocondrias Musculares/metabolismo , Músculo Esquelético/metabolismo , Consumo de Oxígeno , Fosfatos/administración & dosificación , Fosfatos/metabolismo , Fósforo Dietético/administración & dosificación , Fósforo Dietético/metabolismo , Conducta SedentariaRESUMEN
Micropeptide regulator of ß-oxidation (MOXI) is a conserved muscle-enriched protein encoded by an RNA transcript misannotated as non-coding. MOXI localizes to the inner mitochondrial membrane where it associates with the mitochondrial trifunctional protein, an enzyme complex that plays a critical role in fatty acid ß-oxidation. Isolated heart and skeletal muscle mitochondria from MOXI knockout mice exhibit a diminished ability to metabolize fatty acids, while transgenic MOXI overexpression leads to enhanced ß-oxidation. Additionally, hearts from MOXI knockout mice preferentially oxidize carbohydrates over fatty acids in an isolated perfused heart system compared to wild-type (WT) animals. MOXI knockout mice also exhibit a profound reduction in exercise capacity, highlighting the role of MOXI in metabolic control. The functional characterization of MOXI provides insight into the regulation of mitochondrial metabolism and energy homeostasis and underscores the regulatory potential of additional micropeptides that have yet to be identified.
Asunto(s)
Ácidos Grasos/metabolismo , Mitocondrias Musculares/metabolismo , Proteínas Mitocondriales/genética , Secuencia de Aminoácidos , Animales , Ácidos Grasos/química , Humanos , Proteínas de Transporte de Membrana/química , Proteínas de Transporte de Membrana/metabolismo , Ratones , Ratones Endogámicos C57BL , Ratones Noqueados , Ratones Transgénicos , Mitocondrias Cardíacas/metabolismo , Proteínas Mitocondriales/metabolismo , Oxidación-Reducción , Alineación de SecuenciaRESUMEN
Cardiac energy is produced primarily by oxidation of fatty acids and glucose, with the relative contributions of each nutrient being sensitive to changes in substrate availability and energetic demand. A major contributor to cardiac metabolic flexibility is pyruvate dehydrogenase (PDH), which converts glucose-derived pyruvate to acetyl-CoA within the mitochondria. PDH is inhibited by phosphorylation dependent on the competing activities of pyruvate dehydrogenase kinases (PDK1-4) and phosphatases (PDP1-2). A single high-fat meal increases cardiac PDK4 content and subsequently inhibits PDH activity, reducing pyruvate utilization when abundant fatty acids are available. In this study, we demonstrate that diet-induced increases in PDK4 are reversible and characterize a novel pathway that regulates PDK4 degradation in response to the cardiac metabolic environment. We found that PDK4 degradation is promoted by CoA (CoASH), the levels of which declined in mice fed a high-fat diet and normalized following transition to a control diet. We conclude that CoASH functions as a metabolic sensor linking the rate of PDK4 degradation to fatty acid availability in the heart. However, prolonged high-fat feeding followed by return to a low-fat diet resulted in persistent in vitro sensitivity of PDH to fatty acid-induced inhibition despite reductions in PDK4 content. Moreover, increases in the levels of proteins responsible for ß-oxidation and rates of palmitate oxidation by isolated cardiac mitochondria following long-term consumption of high dietary fat persisted after transition to the control diet. We propose that these changes prime PDH for inhibition upon reintroduction of fatty acids.
Asunto(s)
Coenzima A/metabolismo , Dieta Alta en Grasa , Miocardio/metabolismo , Proteínas Serina-Treonina Quinasas/metabolismo , Animales , Dieta con Restricción de Grasas , Ácidos Grasos/metabolismo , Ratones , Ratones Endogámicos C57BL , Mitocondrias Cardíacas/metabolismo , Oxidación-Reducción , Proteínas Serina-Treonina Quinasas/genética , Proteolisis , Piruvato Deshidrogenasa Quinasa Acetil-Transferidora , ARN Mensajero/metabolismoRESUMEN
OBJECTIVE: A decline in mitochondrial function and biogenesis as well as increased reactive oxygen species (ROS) are important determinants of aging. With advancing age, there is a concomitant reduction in circulating levels of insulin-like growth factor-1 (IGF-1) that is closely associated with neuronal aging and neurodegeneration. In this study, we investigated the effect of the decline in IGF-1 signaling with age on astrocyte mitochondrial metabolism and astrocyte function and its association with learning and memory. METHODS: Learning and memory was assessed using the radial arm water maze in young and old mice as well as tamoxifen-inducible astrocyte-specific knockout of IGFR (GFAP-CreTAM/igfrf/f). The impact of IGF-1 signaling on mitochondrial function was evaluated using primary astrocyte cultures from igfrf/f mice using AAV-Cre mediated knockdown using Oroboros respirometry and Seahorse assays. RESULTS: Our results indicate that a reduction in IGF-1 receptor (IGFR) expression with age is associated with decline in hippocampal-dependent learning and increased gliosis. Astrocyte-specific knockout of IGFR also induced impairments in working memory. Using primary astrocyte cultures, we show that reducing IGF-1 signaling via a 30-50% reduction IGFR expression, comparable to the physiological changes in IGF-1 that occur with age, significantly impaired ATP synthesis. IGFR deficient astrocytes also displayed altered mitochondrial structure and function and increased mitochondrial ROS production associated with the induction of an antioxidant response. However, IGFR deficient astrocytes were more sensitive to H2O2-induced cytotoxicity. Moreover, IGFR deficient astrocytes also showed significantly impaired glucose and Aß uptake, both critical functions of astrocytes in the brain. CONCLUSIONS: Regulation of astrocytic mitochondrial function and redox status by IGF-1 is essential to maintain astrocytic function and coordinate hippocampal-dependent spatial learning. Age-related astrocytic dysfunction caused by diminished IGF-1 signaling may contribute to the pathogenesis of Alzheimer's disease and other age-associated cognitive pathologies.
Asunto(s)
Péptidos beta-Amiloides/metabolismo , Astrocitos/metabolismo , Memoria a Corto Plazo , Mitocondrias/metabolismo , Receptor IGF Tipo 1/genética , Envejecimiento/metabolismo , Animales , Células Cultivadas , Glucosa/metabolismo , Hipocampo/citología , Hipocampo/crecimiento & desarrollo , Hipocampo/metabolismo , Factor I del Crecimiento Similar a la Insulina/metabolismo , Ratones , Ratones Endogámicos C57BL , Especies Reactivas de Oxígeno/metabolismo , Receptor IGF Tipo 1/metabolismo , Transducción de SeñalRESUMEN
BACKGROUND: Peroxisome proliferator activated receptor-alpha (PPARα) is a ubiquitously expressed nuclear receptor. The role of endogenous PPARα in retinal neuronal homeostasis is unknown. Retinal photoreceptors are the highest energy-consuming cells in the body, requiring abundant energy substrates. PPARα is a known regulator of lipid metabolism, and we hypothesized that it may regulate lipid use for oxidative phosphorylation in energetically demanding retinal neurons. RESULTS: We found that endogenous PPARα is essential for the maintenance and survival of retinal neurons, with Pparα -/- mice developing retinal degeneration first detected at 8 weeks of age. Using extracellular flux analysis, we identified that PPARα mediates retinal utilization of lipids as an energy substrate, and that ablation of PPARα ultimately results in retinal bioenergetic deficiency and neurodegeneration. This may be due to PPARα regulation of lipid transporters, which facilitate the internalization of fatty acids into cell membranes and mitochondria for oxidation and ATP production. CONCLUSION: We identify an endogenous role for PPARα in retinal neuronal survival and lipid metabolism, and furthermore underscore the importance of fatty acid oxidation in photoreceptor survival. We also suggest PPARα as a putative therapeutic target for age-related macular degeneration, which may be due in part to decreased mitochondrial efficiency and subsequent energetic deficits.
Asunto(s)
Ácidos Grasos/metabolismo , Metabolismo de los Lípidos , PPAR alfa/genética , Retina/metabolismo , Neuronas Retinianas/fisiología , Animales , Ratones , Ratones Endogámicos C57BL , Oxidación-Reducción , PPAR alfa/metabolismo , Ratas , Ratas Sprague-DawleyRESUMEN
Expansion of adipose tissue in response to a positive energy balance underlies obesity and occurs through both hypertrophy of existing cells and increased differentiation of adipocyte precursors (hyperplasia). To better understand the nutrient signals that promote adipocyte differentiation, we investigated the role of glucose availability in regulating adipocyte differentiation and maturation. 3T3-L1 preadipocytes were grown and differentiated in medium containing a standard differentiation hormone mixture and either 4 or 25 mm glucose. Adipocyte maturation at day 9 post-differentiation was determined by key adipocyte markers, including glucose transporter 4 (GLUT4) and adiponectin expression and Oil Red O staining of neutral lipids. We found that adipocyte differentiation and maturation required a pulse of 25 mm glucose only during the first 3 days of differentiation. Importantly, fatty acids were unable to substitute for the 25 mm glucose pulse during this period. The 25 mm glucose pulse increased adiponectin and GLUT4 expression and accumulation of neutral lipids via distinct mechanisms. Adiponectin expression and other early markers of differentiation required an increase in the intracellular pool of total NAD/P. In contrast, GLUT4 protein expression was only partially restored by increased NAD/P levels. Furthermore, GLUT4 mRNA expression was mediated by glucose-dependent activation of GLUT4 gene transcription through the cis-acting GLUT4-liver X receptor element (LXRE) promoter element. In summary, this study supports the conclusion that high glucose promotes adipocyte differentiation via distinct metabolic pathways and independently of fatty acids. This may partly explain the mechanism underlying adipocyte hyperplasia that occurs much later than adipocyte hypertrophy in the development of obesity.
Asunto(s)
Adipocitos Blancos/metabolismo , Adipogénesis , Regulación de la Expresión Génica , Transportador de Glucosa de Tipo 4/metabolismo , Glucosa/metabolismo , NADP/metabolismo , NAD/metabolismo , Células 3T3-L1 , Adipocitos Blancos/citología , Adipocitos Blancos/patología , Adiponectina/genética , Adiponectina/metabolismo , Tejido Adiposo Blanco/citología , Tejido Adiposo Blanco/metabolismo , Tejido Adiposo Blanco/patología , Animales , Biomarcadores/metabolismo , Células Cultivadas , Transportador de Glucosa de Tipo 4/genética , Hiperglucemia/metabolismo , Hiperglucemia/patología , Hipoglucemia/metabolismo , Hipoglucemia/patología , Lipogénesis , Receptores X del Hígado/genética , Receptores X del Hígado/metabolismo , Ratones , Ratones Endogámicos C57BL , Regiones Promotoras Genéticas , Células del Estroma/citología , Células del Estroma/metabolismo , Células del Estroma/patología , Regulación hacia ArribaRESUMEN
Ketogenic diets are low in carbohydrates and high in fat, which forces cells to rely more heavily upon mitochondrial oxidation of fatty acids for energy. Relative to normal cells, cancer cells are believed to exist under a condition of chronic mitochondrial oxidative stress that is compensated for by increases in glucose metabolism to generate reducing equivalents. In this study we tested the hypothesis that a ketogenic diet concurrent with radiation and chemotherapy would be clinically tolerable in locally advanced non-small cell lung cancer (NSCLC) and pancreatic cancer and could potentially exploit cancer cell oxidative metabolism to improve therapeutic outcomes. Mice bearing MIA PaCa-2 pancreatic cancer xenografts were fed either a ketogenic diet or standard rodent chow, treated with conventionally fractionated radiation (2 Gy/fraction), and tumor growth rates were assessed daily. Tumors were assessed for immunoreactive 4-hydroxy-2-nonenal-(4HNE)-modfied proteins as a marker of oxidative stress. Based on this and another previously published preclinical study, phase 1 clinical trials in locally advanced NSCLC and pancreatic cancer were initiated, combining standard radiation and chemotherapy with a ketogenic diet for six weeks (NSCLC) or five weeks (pancreatic cancer). The xenograft experiments demonstrated prolonged survival and increased 4HNE-modfied proteins in animals consuming a ketogenic diet combined with radiation compared to radiation alone. In the phase 1 clinical trial, over a period of three years, seven NSCLC patients enrolled in the study. Of these, four were unable to comply with the diet and withdrew, two completed the study and one was withdrawn due to a dose-limiting toxicity. Over the same time period, two pancreatic cancer patients enrolled in the trial. Of these, one completed the study and the other was withdrawn due to a dose-limiting toxicity. The preclinical experiments demonstrate that a ketogenic diet increases radiation sensitivity in a pancreatic cancer xenograft model. However, patients with locally advanced NSCLC and pancreatic cancer receiving concurrent radiotherapy and chemotherapy had suboptimal compliance to the oral ketogenic diet and thus, poor tolerance.