Project description:The transcriptional regulation of peroxisome proliferator-activated receptor (PPAR) α by post-translational modification, such as ubiquitin, has not been described. We report here for the first time an ubiquitin ligase (muscle ring finger-1/MuRF1) that inhibits fatty acid oxidation by inhibiting PPARα, but not PPARβ/δ or PPARγ in cardiomyocytes in vitro. Similarly, MuRF1 Tg+ hearts showed significant decreases in nuclear PPARα activity and acyl-carnitine intermediates, while MuRF1−/− hearts exhibited increased PPARα activity and acyl-carnitine intermediates. MuRF1 directly interacts with PPARα, mono-ubiquitinates it, and targets it for nuclear export to inhibit fatty acid oxidation in a proteasome independent manner. We then identified a previously undescribed nuclear export sequence in PPARα, along with three specific lysines (292, 310, 388) required for MuRF1's targeting of nuclear export. These studies identify the role of ubiquitination in regulating cardiac PPARα, including the ubiquitin ligase that may be responsible for this critical regulation of cardiac metabolism in heart failure.

Project description:Muscle ring finger (MuRF) proteins have been implicated in the transmission of mechanical forces to nuclear cell signaling pathways through their association with the sarcomere. We recently reported that MuRF1, but not MuRF2, regulated pathologic cardiac hypertrophy in vivo. This was surprising since MuRF1 and MuRF2 interact redundantly with sarcomeric proteins in yeast two hybrid studies, and form both homo- and hetero-dimers with each other. To determine if MuRF1 and MuRF2 were functionally redundant during development, we created mice lacking either 3 or 4 of the MuRF1 and MuRF2 alleles and compared them functionally. Surprisingly, only mice missing all four MuRF1 and MuRF2 alleles (MuRF1-/-//MuRF2-/-) developed a spontaneous hypertrophic cardiomyopathy - mice that were null for one of the genes, but heterozygous for the other (i.e. MuRF1-/-//MuRF2+/- or MuRF1+/-//MuRF2-/-) were phenotypically identical to wild type mice. Electron microscopy of the hearts of MuRF1-/-//MuRF2-/-(MuRF1/MuRF2 DN) mice identified altered Z disc and M line architecture, and a distinct swelling of mitochondria. MuRF1-/-//MuRF2-/- mouse hearts displayed increased expression of genes associated with fetal cardiac metabolism, including smooth muscle actin and b myosin heavy chain, suggesting that the cardiac hypertrophy seen in these mice was associated with a reversion to a fetal gene program. Despite our prediction that we would also see an increase in glucose compared to fatty acid oxidation (another trait of fetal cardiac metabolism) we saw that MuRF1-/-//MuRF2-/- heart homogenates oxidized significantly less glucose compared to controls, suggesting an important role for MuRF1 and MuRF2 in the regulation of glucose metabolism in vivo. This study identifies a previously unreported redundancy in the function of MuRF proteins in normal cardiac development. Keywords: Genetic modification. Four strain-matched groups of 12 week old mice were investigated: 1) MuRF1 -/- MuRF2 -/-; 2) MuRF1 +/+ MuRF2 +/+; 3) MuRF1 -/- MuRF2 +/-; 4) MuRF1 +/- MuRF2 -/-. Biological replicates: 4 WT, 4 MuRF1 -/- // MuRF2 -/-, 4 MuRF1 +/- //MuRF2 -/-, 4 MuRF1 -/- // MuRF2 +/-. Hearts harvested. One replicate per array.

Project description:Muscle ring finger (MuRF) proteins have been implicated in the transmission of mechanical forces to nuclear cell signaling pathways through their association with the sarcomere. We recently reported that MuRF1, but not MuRF2, regulated pathologic cardiac hypertrophy in vivo. This was surprising since MuRF1 and MuRF2 interact redundantly with sarcomeric proteins in yeast two hybrid studies, and form both homo- and hetero-dimers with each other. To determine if MuRF1 and MuRF2 were functionally redundant during development, we created mice lacking either 3 or 4 of the MuRF1 and MuRF2 alleles and compared them functionally. Surprisingly, only mice missing all four MuRF1 and MuRF2 alleles (MuRF1-/-//MuRF2-/-) developed a spontaneous hypertrophic cardiomyopathy - mice that were null for one of the genes, but heterozygous for the other (i.e. MuRF1-/-//MuRF2+/- or MuRF1+/-//MuRF2-/-) were phenotypically identical to wild type mice. Electron microscopy of the hearts of MuRF1-/-//MuRF2-/-(MuRF1/MuRF2 DN) mice identified altered Z disc and M line architecture, and a distinct swelling of mitochondria. MuRF1-/-//MuRF2-/- mouse hearts displayed increased expression of genes associated with fetal cardiac metabolism, including smooth muscle actin and b myosin heavy chain, suggesting that the cardiac hypertrophy seen in these mice was associated with a reversion to a fetal gene program. Despite our prediction that we would also see an increase in glucose compared to fatty acid oxidation (another trait of fetal cardiac metabolism) we saw that MuRF1-/-//MuRF2-/- heart homogenates oxidized significantly less glucose compared to controls, suggesting an important role for MuRF1 and MuRF2 in the regulation of glucose metabolism in vivo. This study identifies a previously unreported redundancy in the function of MuRF proteins in normal cardiac development. Keywords: Genetic modification.

Project description:Muscle ring finger-1 (MuRF1) is a muscle-specific protein implicated in the regulation of cardiac myocyte size and contractility. MuRF2, a closely related family member, redundantly interacts with protein substrates, and hetero-dimerizes with MuRF1. Mice lacking either MuRF1 or MuRF2 are phenotypically normal whereas mice lacking both proteins develop a spontaneous cardiac and skeletal muscle hypertrophy indicating cooperative control of muscle mass by MuRF1 and MuRF2. In order to identify the role that MuRF1 plays in regulating cardiac hypertrophy in vivo, we created transgenic mice expressing increased amounts of cardiac MuRF1. Adult MuRF1 transgenic (Tg+) hearts exhibited a non-progressive thinning of the left ventricular wall and a concomitant decrease in cardiac function. Experimental induction of cardiac hypertrophy by trans-aortic constriction (TAC) induced rapid failure of MuRF1 Tg+ hearts. Microarray analysis identified that the levels of genes associated with metabolism (and in particular mitochondrial processes) were significantly altered in MuRF1 Tg+ hearts, both at baseline and during the development of cardiac hypertrophy. Surprisingly, ATP levels in MuRF1 Tg+ mice did not differ from wild type mice despite the depressed contractility following TAC. To explain this discrepancy between the ongoing heart failure and maintained ATP levels in MuRF1 Tg+ hearts, we compared the level and activity of creatine kinase (CK) between wild type and MuRF1 Tg+ hearts. Although mCK and CK-M/B protein levels were unaffected in MuRF1 Tg+ hearts, total CK activity was significantly inhibited. We conclude that MuRF1’s inhibition of CK activity leads to increased susceptibility to heart failure following TAC, demonstrating for the first time that MuRF1 regulates cardiac energetics in vivo. Keywords: Genetic modification, physiological manipulation. Three-condition experiment, MuRF1 Tg+ vs. WT mice. Biological replicates: 4 WT baseline, 3 MuRF1 Tg+ baseline, cardiac overpressure hypertrophy induced by trans-aortic banding at 1 week (3 WT, 3 MurF Tg) and 4 weeks (3 WT, 3 MurF Tg), hearts harvested. One replicate per array.

Project description:Muscle ring finger-1 (MuRF1) is a muscle-specific protein implicated in the regulation of cardiac myocyte size and contractility. MuRF2, a closely related family member, redundantly interacts with protein substrates, and hetero-dimerizes with MuRF1. Mice lacking either MuRF1 or MuRF2 are phenotypically normal whereas mice lacking both proteins develop a spontaneous cardiac and skeletal muscle hypertrophy indicating cooperative control of muscle mass by MuRF1 and MuRF2. In order to identify the role that MuRF1 plays in regulating cardiac hypertrophy in vivo, we created transgenic mice expressing increased amounts of cardiac MuRF1. Adult MuRF1 transgenic (Tg+) hearts exhibited a non-progressive thinning of the left ventricular wall and a concomitant decrease in cardiac function. Experimental induction of cardiac hypertrophy by trans-aortic constriction (TAC) induced rapid failure of MuRF1 Tg+ hearts. Microarray analysis identified that the levels of genes associated with metabolism (and in particular mitochondrial processes) were significantly altered in MuRF1 Tg+ hearts, both at baseline and during the development of cardiac hypertrophy. Surprisingly, ATP levels in MuRF1 Tg+ mice did not differ from wild type mice despite the depressed contractility following TAC. To explain this discrepancy between the ongoing heart failure and maintained ATP levels in MuRF1 Tg+ hearts, we compared the level and activity of creatine kinase (CK) between wild type and MuRF1 Tg+ hearts. Although mCK and CK-M/B protein levels were unaffected in MuRF1 Tg+ hearts, total CK activity was significantly inhibited. We conclude that MuRF1’s inhibition of CK activity leads to increased susceptibility to heart failure following TAC, demonstrating for the first time that MuRF1 regulates cardiac energetics in vivo. Keywords: Genetic modification, physiological manipulation.

Project description:vanEunen2013 - Network dynamics of fatty acid β-oxidation (time-course model) Lipid metabolism plays an important role in the development of metabolic syndrome, a major risk factor for cardiovascular disease and diabetes. This model gives insights into the response of lipid oxidation to dietart and medical interventions. The model predicts the rate of lipid oxidation and the time course of most acyl carnitines. There are two models described in the paper, (i) steady-state model [ BIOMD0000000505 ], (ii) time-course model [ BIOMD0000000506 ]. This model corresponds to the time-course model. This model is described in the article: Biochemical competition makes fatty-acid β-oxidation vulnerable to substrate overload. van Eunen K, Simons SM, Gerding A, Bleeker A, den Besten G, Touw CM, Houten SM, Groen BK, Krab K, Reijngoud DJ, Bakker BM. PLoS Comput Biol. 2013;9(8):e1003186. Abstract: Fatty-acid metabolism plays a key role in acquired and inborn metabolic diseases. To obtain insight into the network dynamics of fatty-acid β-oxidation, we constructed a detailed computational model of the pathway and subjected it to a fat overload condition. The model contains reversible and saturable enzyme-kinetic equations and experimentally determined parameters for rat-liver enzymes. It was validated by adding palmitoyl CoA or palmitoyl carnitine to isolated rat-liver mitochondria: without refitting of measured parameters, the model correctly predicted the β-oxidation flux as well as the time profiles of most acyl-carnitine concentrations. Subsequently, we simulated the condition of obesity by increasing the palmitoyl-CoA concentration. At a high concentration of palmitoyl CoA the β-oxidation became overloaded: the flux dropped and metabolites accumulated. This behavior originated from the competition between acyl CoAs of different chain lengths for a set of acyl-CoA dehydrogenases with overlapping substrate specificity. This effectively induced competitive feedforward inhibition and thereby led to accumulation of CoA-ester intermediates and depletion of free CoA (CoASH). The mitochondrial [NAD⁺]/[NADH] ratio modulated the sensitivity to substrate overload, revealing a tight interplay between regulation of β-oxidation and mitochondrial respiration. This model is hosted on BioModels Database and identified by: BIOMD0000000506 . To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models . To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:vanEunen2013 - Network dynamics of fatty acid β-oxidation (steady-state model) Lipid metabolism plays an important role in the development of metabolic syndrome, a major risk factor for cardiovascular disease and diabetes. This model gives insights into the response of lipid oxidation to dietart and medical interventions. The model predicts the rate of lipid oxidation and the time course of most acyl carnitines. There are two models described in the paper, (i) steady-state model [ BIOMD0000000505 ], (ii) time-course model [ BIOMD0000000506 ]. This model corresponds to the steady-state model. This model is described in the article: Biochemical competition makes fatty-acid β-oxidation vulnerable to substrate overload. van Eunen K, Simons SM, Gerding A, Bleeker A, den Besten G, Touw CM, Houten SM, Groen BK, Krab K, Reijngoud DJ, Bakker BM. PLoS Comput Biol. 2013;9(8):e1003186. Abstract: Fatty-acid metabolism plays a key role in acquired and inborn metabolic diseases. To obtain insight into the network dynamics of fatty-acid β-oxidation, we constructed a detailed computational model of the pathway and subjected it to a fat overload condition. The model contains reversible and saturable enzyme-kinetic equations and experimentally determined parameters for rat-liver enzymes. It was validated by adding palmitoyl CoA or palmitoyl carnitine to isolated rat-liver mitochondria: without refitting of measured parameters, the model correctly predicted the β-oxidation flux as well as the time profiles of most acyl-carnitine concentrations. Subsequently, we simulated the condition of obesity by increasing the palmitoyl-CoA concentration. At a high concentration of palmitoyl CoA the β-oxidation became overloaded: the flux dropped and metabolites accumulated. This behavior originated from the competition between acyl CoAs of different chain lengths for a set of acyl-CoA dehydrogenases with overlapping substrate specificity. This effectively induced competitive feedforward inhibition and thereby led to accumulation of CoA-ester intermediates and depletion of free CoA (CoASH). The mitochondrial [NAD⁺]/[NADH] ratio modulated the sensitivity to substrate overload, revealing a tight interplay between regulation of β-oxidation and mitochondrial respiration. This model is hosted on BioModels Database and identified by: BIOMD0000000505 . To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models . To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:We previously identified a role for the muscle-specific ubiquitin ligase MuRF1 (Muscle Ring Finger-1) in cardiac ischemia-reperfusion (I/R) injury. We found that cardiomyocyte-specific (alphaMHC-) MuRF1 transgenic mice (MuRF1 Tg+) mice were significantly protected from I/R injury. As we discovered MuRF1’s regulation of other transcriptions factors, we sought to identify other ways in which MuRF1 was cardioprotective in I/R injury. In the present study, we first identified the regulation of MuRF1 expression by qPCR in a porcine model of I/R injury. MuRF1 mRNA significantly increased within 90 minutes of I/R injury. We next assayed MuRF1 Tg+ ventricular tissue after I/R reperfusion injury by microarray (44K transcripts) to identify how MuRF1 regulates the transcriptome. We identified 71 significantly altered genes having a >1.5-fold (p<0.01) in MuRF1 Tg+ and wildtype hearts challenged with I/R injury (or sham operation). Functional annotation of the top upregulated genes found enrichment for myogenesis, cell adhesion, and nucleic acid metabolism. TRANSFAC analysis of MuRF1 Tg+ significant genes identified enrichment for genes (30-53%) with promoter regions recognized by the transcription factors MAZ, PIT1, VMW65, and BACH2. The transcription factor MAZ binds muscle creatine kinase (MCK) promoter in skeletal and cardiac myocytes, known most for its regulation of myogenin and MEF2C in cardiomyocytes. While the role of PIT1 and BACH2 in adult cardiomyocytes is not clear, VMW65 is a powerful transactivator with functions in chromatin remodeling. In neonatal cardiomycoyte I/R injury, VMW65 associates with HIF1alpha to upregulate cardioprotective VEGF, Glut-1, Glut-4, HSP70, and iNOS expression. These findings elucidate the MuRF1-specific regulation of genes in cardiac I/R injury that are associated with cardioprotection and may represent multiple additional direct or indirect mechanisms that MuRF1 regulates cardiomyocyte signaling.

Project description:The heart relies mainly on mitochondrial fatty acid beta-oxidation (FAO) for its high energy requirements. Cardiomyopathy and arrhythmias can be severe complications in patients with inherited defects in mitochondrial long-chain FAO, reinforcing the importance of FAO for cardiac health. However, the pathophysiological mechanisms that underlie the cardiac abnormalities in long-chain FAO disorders remain largely unknown. Here, we investigated the cardiac transcriptional adaptations to the FAO defect in the long-chain acyl-CoA dehydrogenase (LCAD) knockout (KO) mouse. We found a prominent activation of the integrated stress response (ISR) mediated by the eIF2a/ATF4 axis in both fed and fasted states, accompanied by a reduction in cardiac protein synthesis during a short period of food withdrawal. Notably, we found an accumulation of uncharged tRNAs in LCAD KO hearts, consistent with a reduced availability of cardiac amino acids, in particular, glutamine. We replicated the activation of the cardiac ISR in hearts of mice with a muscle-specific deletion of carnitine palmitoyltransferase 2 deletion (Cpt2M-/-). Our results show that perturbations in amino acid metabolism caused by long-chain FAO deficiency impact cardiac metabolic signaling, in particular the ISR, and may play a role in the associated cardiac pathology.

Project description:1. Background- Long-chain acyl-CoA synthetases (ACSL) catalyze the conversion of long-chain fatty acids (FA) to fatty acyl-CoAs. Cardiac-specific ACSL1 knockout results in a shift towards glycolysis that promotes mTORC1-mediated ventricular hypertrophy. We used unbiased metabolomics and gene expression analyses to examine the early effects of genetic inactivation of FA oxidation on cardiac metabolism and function. 2. Methods and Results- Compared to WT hearts, global cardiac transcriptional analysis revealed differential expression of 245 genes in Acsl1H-/- hearts 2 weeks after Acsl1 ablation. Comparison of the 2- and 10-week transcriptional responses uncovered 139 genes whose expression was uniquely changed upon short-term cardiac inactivation of ACSL1. In particular, partial ACSL1 ablation led to the distinct upregulation of fibrosis genes, a phenomenon not observed after complete ACSL1 knockout. Metabolomic analysis identified 65 metabolites altered in hearts displaying partially reduced ACSL activity, whereas rapamycin treatment normalized the cardiac metabolomic fingerprint. Chronic mTOR inhibition via rapamycin treatment revealed novel mTORC1 targets involved in fibrosis, amino acid catabolism, and mitochondrial transport and metabolism. 3. Conclusions- Short-term cardiac-specific ACSL1 inactivation (Acsl1H-/-) resulted in metabolic and transcriptional derangements distinct from those observed upon complete ACSL1 knockout, leading to the identification of novel mTORC1 targets that regulate cardiac hypertrophy development, and suggesting heart-specific mTOR signaling that occurs during the early stages of substrate switching. Moreover, the rate of increased glucose use correlated negatively with hypertrophy development, strongly suggesting that hearts do not become hypertrophied if they can compensate or switch faster from FA to glucose use.