Your search keyword '"Janos Kerner"' showing total 95 results

1. HIF drives lipid deposition and cancer in ccRCC via repression of fatty acid metabolism

Author

Weinan Du, Luchang Zhang, Adina Brett-Morris, Brittany Aguila, Janos Kerner, Charles L. Hoppel, Michelle Puchowicz, Dolors Serra, Laura Herrero, Brian I. Rini, Steven Campbell, and Scott M. Welford

Subjects

Science

Abstract

Clear cell renal cancers (ccRCC) display elevated intracellular lipid storage. Here the authors show that such lipid accumulation is due to the repression of carnitine palmitoyltransferase 1A (CPT1A) enzyme that impairs fatty acid (FA) transport into the mitochondrion resulting in reduced FA beta oxidation.

Published

2017

2. Aging-dependent changes in rat heart mitochondrial glutaredoxins—Implications for redox regulation

Author

Xing-Huang Gao, Suparna Qanungo, Harish V. Pai, David W. Starke, Kelly M. Steller, Hisashi Fujioka, Edward J. Lesnefsky, Janos Kerner, Mariana G. Rosca, Charles L. Hoppel, and John J. Mieyal

Subjects

Aging, Glutaredoxin, Glutathionylation, Iron–sulfur cluster, Mitochondria, Reactive oxygen species (ROS), Redox regulation, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Clinical and animal studies have documented that hearts of the elderly are more susceptible to ischemia/reperfusion damage compared to young adults. Recently we found that aging-dependent increase in susceptibility of cardiomyocytes to apoptosis was attributable to decrease in cytosolic glutaredoxin 1 (Grx1) and concomitant decrease in NF-κB-mediated expression of anti-apoptotic proteins. Besides primary localization in the cytosol, Grx1 also exists in the mitochondrial intermembrane space (IMS). In contrast, Grx2 is confined to the mitochondrial matrix. Here we report that Grx1 is decreased by 50–60% in the IMS, but Grx2 is increased by 1.4–2.6 fold in the matrix of heart mitochondria from elderly rats. Determination of in situ activities of the Grx isozymes from both subsarcolemmal (SSM) and interfibrillar (IFM) mitochondria revealed that Grx1 was fully active in the IMS. However, Grx2 was mostly in an inactive form in the matrix, consistent with reversible sequestration of the active-site cysteines of two Grx2 molecules in complex with an iron–sulfur cluster. Our quantitative evaluations of the active/inactive ratio for Grx2 suggest that levels of dimeric Grx2 complex with iron–sulfur clusters are increased in SSM and IFM in the hearts of elderly rats. We found that the inactive Grx2 can be fully reactivated by sodium dithionite or exogenous superoxide production mediated by xanthine oxidase. However, treatment with rotenone, which generates intramitochondrial superoxide through inhibition of mitochondrial respiratory chain Complex I, did not lead to Grx2 activation. These findings suggest that insufficient ROS accumulates in the vicinity of dimeric Grx2 to activate it in situ.

Published

2013

3. Diabetes or peroxisome proliferator-activated receptor α agonist increases mitochondrial thioesterase I activity in heart

Author

Kristen L. King, Martin E. Young, Janos Kerner, Hazel Huang, Karen M. O'Shea, Stefan E.H. Alexson, Charles L. Hoppel, and William C. Stanley

Subjects

cardiac, fatty acids, lipotoxicity, Biochemistry, QD415-436

Abstract

Peroxisome proliferator-activated receptor α (PPARα) is a transcriptional regulator of the expression of mitochondrial thioesterase I (MTE-I) and uncoupling protein 3 (UCP3), which are induced in the heart at the mRNA level in response to diabetes. Little is known about the regulation of protein expression of MTE-I and UCP3 or about MTE-I activity; thus, we investigated the effects of diabetes and treatment with a PPARα agonist on these parameters. Rats were either made diabetic with streptozotocin (55 mg/kg ip) and maintained for 10–14 days or treated with the PPARα agonist fenofibrate (300 mg/kg/day) for 4 weeks. MTE-I and UCP3 protein expression, MTE-1 activity, palmitate export, and oxidative phosphorylation were measured in isolated cardiac mitochondria. Diabetes and fenofibrate increased cardiac MTE-I mRNA, protein, and activity (∼4-fold compared with controls). This increase in activity was matched by a 6-fold increase in palmitate export in fenofibrate-treated animals, despite there being no effect in either group on UCP3 protein expression. Both diabetes and fenofibrate caused significant decreases in state III respiration of isolated mitochondria with pyruvate + malate as the substrate, but only diabetes reduced state III rates with palmitoylcarnitine. Both diabetes and specific PPARα activation increased MTE-I protein, activity, and palmitate export in the heart, with little effect on UCP3 protein expression.

Published

2007

4. Acetyl-l-carnitine increases mitochondrial protein acetylation in the aged rat heart

Author

Elizabeth Yohannes, Ashraf Virmani, Charles L. Hoppel, Claudio Cavazza, Janos Kerner, Kwangwon Lee, Mark R. Chance, and Aleardo Koverech

Subjects

Aging, ATP synthase, Myocardium, Lysine, Respiratory chain, Acetylation, Biology, Mitochondrion, Mitochondria, Heart, Rats, Inbred F344, Article, Rats, Mitochondrial Proteins, Citric acid cycle, Isocitrate dehydrogenase, Biochemistry, medicine, biology.protein, Animals, Acetylcarnitine, Developmental Biology, medicine.drug

Abstract

Previously we showed that in vivo treatment of elderly Fisher 344 rats with acetylcarnitine abolished the age-associated defect in respiratory chain complex III in interfibrillar mitochondria and improved the functional recovery of the ischemic/reperfused heart. Herein, we explored mitochondrial protein acetylation as a possible mechanism for acetylcarnitine's effect. In vivo treatment of elderly rats with acetylcarnitine restored cardiac acetylcarnitine content and increased mitochondrial protein lysine acetylation and increased the number of lysine-acetylated proteins in cardiac subsarcolemmal and interfibrillar mitochondria. Enzymes of the tricarboxylic acid cycle, mitochondrial β-oxidation, and ATP synthase of the respiratory chain showed the greatest acetylation. Acetylation of isocitrate dehydrogenase, long-chain acyl-CoA dehydrogenase, complex V, and aspartate aminotransferase was accompanied by decreased catalytic activity. Several proteins were found to be acetylated only after treatment with acetylcarnitine, suggesting that exogenous acetylcarnitine served as the acetyl-donor. Two-dimensional fluorescence difference gel electrophoresis analysis revealed that acetylcarnitine treatment also induced changes in mitochondrial protein amount; a two-fold or greater increase/decrease in abundance was observed for thirty one proteins. Collectively, our data provide evidence for the first time that in the aged rat heart in vivo administration of acetylcarnitine provides acetyl groups for protein acetylation and affects the amount of mitochondrial proteins.

Published

2015

5. HIF drives lipid deposition and cancer in ccRCC via repression of fatty acid metabolism

Author

Luchang Zhang, Charles L. Hoppel, Brian I. Rini, Scott M. Welford, Laura Herrero, Janos Kerner, Brittany Aguila, Dolors Serra, Weinan Du, Adina Brett-Morris, Michelle Puchowicz, Steven C. Campbell, and Universitat de Barcelona

Subjects

0301 basic medicine, Carcinogenesis, Àcids grassos, General Physics and Astronomy, Mitochondrion, medicine.disease_cause, Càncer de ronyó, Mitocondris, chemistry.chemical_compound, Lipid droplet, Basic Helix-Loop-Helix Transcription Factors, lcsh:Science, chemistry.chemical_classification, Mice, Inbred BALB C, Multidisciplinary, Chemistry, Fatty Acids, Lipids, Metabolisme, Kidney Neoplasms, 3. Good health, Mitochondria, Renal cancer, Biochemistry, Female, Science, Mice, Nude, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Cell Line, Tumor, medicine, Animals, Humans, Carnitine O-palmitoyltransferase, Fatty acids, Carcinoma, Renal Cell, Fatty acid metabolism, Carnitine O-Palmitoyltransferase, Fatty acid, General Chemistry, medicine.disease, Hypoxia-Inducible Factor 1, alpha Subunit, Clear cell renal cell carcinoma, Metabolism, 030104 developmental biology, Lípids, Cancer research, lcsh:Q, Clear cell

Abstract

Clear cell renal cell carcinoma (ccRCC) is histologically defined by its lipid and glycogen-rich cytoplasmic deposits. Alterations in the VHL tumor suppressor stabilizing the hypoxia-inducible factors (HIFs) are the most prevalent molecular features of clear cell tumors. The significance of lipid deposition remains undefined. We describe the mechanism of lipid deposition in ccRCC by identifying the rate-limiting component of mitochondrial fatty acid transport, carnitine palmitoyltransferase 1A (CPT1A), as a direct HIF target gene. CPT1A is repressed by HIF1 and HIF2, reducing fatty acid transport into the mitochondria, and forcing fatty acids to lipid droplets for storage. Droplet formation occurs independent of lipid source, but only when CPT1A is repressed. Functionally, repression of CPT1A is critical for tumor formation, as elevated CPT1A expression limits tumor growth. In human tumors, CPT1A expression and activity are decreased versus normal kidney; and poor patient outcome associates with lower expression of CPT1A in tumors in TCGA. Together, our studies identify HIF control of fatty acid metabolism as essential for ccRCC tumorigenesis., Clear cell renal cancers (ccRCC) display elevated intracellular lipid storage. Here the authors show that such lipid accumulation is due to the repression of carnitine palmitoyltransferase 1A (CPT1A) enzyme that impairs fatty acid (FA) transport into the mitochondrion resulting in reduced FA beta oxidation.

Published

2017

6. Fatty Acid Chain Elongation in Palmitate-perfused Working Rat Heart

Author

Charles L. Hoppel, Edward J. Lesnefsky, Janos Kerner, and Paul E. Minkler

Subjects

chemistry.chemical_classification, Stereochemistry, Coenzyme A, Acetyl-CoA, Fatty acid, Cell Biology, Biology, Biochemistry, Palmitic acid, chemistry.chemical_compound, chemistry, medicine, Carnitine, Acetylcarnitine, Molecular Biology, Beta oxidation, Palmitoylcarnitine, medicine.drug

Abstract

Rat hearts were perfused with [1,2,3,4-13C4]palmitic acid (M+4), and the isotopic patterns of myocardial acylcarnitines and acyl-CoAs were analyzed using ultra-HPLC-MS/MS. The 91.2% 13C enrichment in palmitoylcarnitine shows that little endogenous (M+0) palmitate contributed to its formation. The presence of M+2 myristoylcarnitine (95.7%) and M+2 acetylcarnitine (19.4%) is evidence for β-oxidation of perfused M+4 palmitic acid. Identical enrichment data were obtained in the respective acyl-CoAs. The relative 13C enrichment in M+4 (84.7%, 69.9%) and M+6 (16.2%, 17.8%) stearoyl- and arachidylcarnitine, respectively, clearly shows that the perfused palmitate is chain-elongated. The observed enrichment of 13C in acetylcarnitine (19%), M+6 stearoylcarnitine (16.2%), and M+6 arachidylcarnitine (17.8%) suggests that the majority of two-carbon units for chain elongation are derived from β-oxidation of [1,2,3,4-13C4]palmitic acid. These data are explained by conversion of the M+2 acetyl-CoA to M+2 malonyl-CoA, which serves as the acceptor for M+4 palmitoyl-CoA in chain elongation. Indeed, the 13C enrichment in mitochondrial acetyl-CoA (18.9%) and malonyl-CoA (19.9%) are identical. No 13C enrichment was found in acylcarnitine species with carbon chain lengths between 4 and 12, arguing against the simple reversal of fatty acid β-oxidation. Furthermore, isolated, intact rat heart mitochondria 1) synthesize malonyl-CoA with simultaneous inhibition of carnitine palmitoyltransferase 1b and 2) catalyze the palmitoyl-CoA-dependent incorporation of 14C from [2-14C]malonyl-CoA into lipid-soluble products. In conclusion, rat heart has the capability to chain-elongate fatty acids using mitochondria-derived two-carbon chain extenders. The data suggest that the chain elongation process is localized on the outer surface of the mitochondrial outer membrane.

Published

2014

7. Sterol Regulatory Element-binding Protein-1 (SREBP-1) Is Required to Regulate Glycogen Synthesis and Gluconeogenic Gene Expression in Mouse Liver

Author

Aisha Gamble, Peter J. Roach, Charles L. Hoppel, Anna A. DePaoli-Roach, Rafaela Ruiz, Vincent S. Tagliabracci, Yongyong Hou, Janos Kerner, Michelle Puchowicz, Victoria Jideonwo, Sneha Surendran, Núria Morral, Miwon Ahn, and Jose Irimia-Dominguez

Subjects

Male, endocrine system, medicine.medical_specialty, Biology, Carbohydrate metabolism, digestive system, Biochemistry, Glycogen debranching enzyme, Mice, chemistry.chemical_compound, Internal medicine, polycyclic compounds, medicine, Animals, Gene Regulation, Obesity, Glycogen synthase, Molecular Biology, Glycogen, Glucokinase, Gluconeogenesis, food and beverages, Cell Biology, Sterol regulatory element-binding protein, Diabetes Mellitus, Type 1, Endocrinology, Diabetes Mellitus, Type 2, Gene Expression Regulation, Liver, chemistry, Gene Knockdown Techniques, Lipogenesis, biology.protein, Sterol Regulatory Element Binding Protein 1, lipids (amino acids, peptides, and proteins)

Abstract

Sterol regulatory element-binding protein-1 (SREBP-1) is a key transcription factor that regulates genes in the de novo lipogenesis and glycolysis pathways. The levels of SREBP-1 are significantly elevated in obese patients and in animal models of obesity and type 2 diabetes, and a vast number of studies have implicated this transcription factor as a contributor to hepatic lipid accumulation and insulin resistance. However, its role in regulating carbohydrate metabolism is poorly understood. Here we have addressed whether SREBP-1 is needed for regulating glucose homeostasis. Using RNAi and a new generation of adenoviral vector, we have silenced hepatic SREBP-1 in normal and obese mice. In normal animals, SREBP-1 deficiency increased Pck1 and reduced glycogen deposition during fed conditions, providing evidence that SREBP-1 is necessary to regulate carbohydrate metabolism during the fed state. Knocking SREBP-1 down in db/db mice resulted in a significant reduction in triglyceride accumulation, as anticipated. However, mice remained hyperglycemic, which was associated with up-regulation of gluconeogenesis gene expression as well as decreased glycolysis and glycogen synthesis gene expression. Furthermore, glycogen synthase activity and glycogen accumulation were significantly reduced. In conclusion, silencing both isoforms of SREBP-1 leads to significant changes in carbohydrate metabolism and does not improve insulin resistance despite reducing steatosis in an animal model of obesity and type 2 diabetes.

Published

2014

8. Oxidation of Fatty Acids Is the Source of Increased Mitochondrial Reactive Oxygen Species Production in Kidney Cortical Tubules in Early Diabetes

Author

Charles L. Hoppel, Qun Chen, Edwin J. Vazquez, Mariana G. Rosca, Janos Kerner, and Timothy S. Kern

Subjects

Male, Ubiquinol, Complications, Ubiquinone, Endocrinology, Diabetes and Metabolism, Oxidative phosphorylation, Biology, Mitochondrion, Diabetes Mellitus, Experimental, Superoxide dismutase, Kidney Tubules, Proximal, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Pyruvic Acid, Internal Medicine, Animals, Rats, Wistar, Beta oxidation, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Reactive oxygen species, Carnitine O-Palmitoyltransferase, Superoxide Dismutase, Fatty Acids, Fatty acid, Mitochondria, Rats, chemistry, Biochemistry, 030220 oncology & carcinogenesis, Coenzyme Q – cytochrome c reductase, biology.protein, Reactive Oxygen Species, Oxidation-Reduction

Abstract

Mitochondrial reactive oxygen species (ROS) cause kidney damage in diabetes. We investigated the source and site of ROS production by kidney cortical tubule mitochondria in streptozotocin-induced type 1 diabetes in rats. In diabetic mitochondria, the increased amounts and activities of selective fatty acid oxidation enzymes is associated with increased oxidative phosphorylation and net ROS production with fatty acid substrates (by 40% and 30%, respectively), whereas pyruvate oxidation is decreased and pyruvate-supported ROS production is unchanged. Oxidation of substrates that donate electrons at specific sites in the electron transport chain (ETC) is unchanged. The increased maximal production of ROS with fatty acid oxidation is not affected by limiting the electron flow from complex I into complex III. The maximal capacity of the ubiquinol oxidation site in complex III in generating ROS does not differ between the control and diabetic mitochondria. In conclusion, the mitochondrial ETC is neither the target nor the site of ROS production in kidney tubule mitochondria in short-term diabetes. Mitochondrial fatty acid oxidation is the source of the increased net ROS production, and the site of electron leakage is located proximal to coenzyme Q at the electron transfer flavoprotein that shuttles electrons from acyl-CoA dehydrogenases to coenzyme Q.

Published

2012

9. Mitochondrial Carnitine Palmitoyltransferase 1a (CPT1a) Is Part of an Outer Membrane Fatty Acid Transfer Complex

Author

Charles L. Hoppel, Janos Kerner, and Kwang Won Lee

Subjects

Electrophoresis, Male, Voltage-dependent anion channel, Immunoprecipitation, Dimer, Trimer, Random hexamer, Biochemistry, Rats, Sprague-Dawley, chemistry.chemical_compound, Coenzyme A Ligases, Animals, Voltage-Dependent Anion Channels, Protein Structure, Quaternary, Molecular Biology, chemistry.chemical_classification, Carnitine O-Palmitoyltransferase, biology, Molecular mass, Fatty Acids, Fatty acid, Biological Transport, Cell Biology, Mitochondria, Rats, Molecular Weight, Metabolism, Liver, chemistry, Mitochondrial Membranes, biology.protein, Protein Multimerization, Bacterial outer membrane

Abstract

CPT1a (carnitine palmitoyltransferase 1a) in the liver mitochondrial outer membrane (MOM) catalyzes the primary regulated step in overall mitochondrial fatty acid oxidation. It has been suggested that the fundamental unit of CPT1a exists as a trimer, which, under native conditions, could form a dimer of the trimers, creating a hexamer channel for acylcarnitine translocation. To examine the state of CPT1a in the MOM, we employed a combined approach of sizing by mass and isolation using an immunological method. Blue native electrophoresis followed by detection with immunoblotting and mass spectrometry identified large molecular mass complexes that contained not only CPT1a but also long chain acyl-CoA synthetase (ACSL) and the voltage-dependent anion channel (VDAC). Immunoprecipitation with antisera against the proteins revealed a strong interaction between the three proteins. Immobilized CPT1a-specific antibodies immunocaptured not only CPT1a but also ACSL and VDAC, further strengthening findings with blue native electrophoresis and immunoprecipitation. This study shows strong protein-protein interaction between CPT1a, ACSL, and VDAC. We propose that this complex transfers activated fatty acids through the MOM.

Published

2011

10. Post-translational modifications of mitochondrial outer membrane proteins

Author

Kwangwon Lee, Charles L. Hoppel, and Janos Kerner

Subjects

Carnitine O-Palmitoyltransferase, biology, Translocase of the outer membrane, Peripheral membrane protein, Membrane Proteins, Acetylation, General Medicine, Mitochondrial carrier, Biochemistry, Cell biology, Mitochondrial membrane transport protein, Membrane protein, Coenzyme A Ligases, Mitochondrial Membranes, Translocase of the inner membrane, biology.protein, Humans, Outer membrane efflux proteins, Phosphorylation, Protein Processing, Post-Translational, Integral membrane protein, Protein Binding

Abstract

The mitochondrial outer membrane surrounds the entire organelle. It is composed of a phospholipid bilayer with proteins either embedded into or anchored to the bilayer and mediates the interactions between mitochondria and the rest of the cell. Most of the proteins present in the mitochondrial outer membrane are highly hydrophobic with one or more transmembrane segments. These proteins in conjunction with proteins localized in the inner membrane catalyse energy exchange reactions, the flux of small molecules such as ions, the activation and uptake of long chain fatty acids, import of proteins into the mitochondria, and elimination of biogenic amines among others. In addition, some outer membrane proteins serve as docking sites for non-resident enzymes such as hexokinase and other kinases of signal transduction. All these processes require an intact outer membrane and are highly regulated. One level of regulation with physiological/pathophysiological relevance involves post-translational modification of outer membrane proteins, either by phosphorylation, acetylation or other type of reversible covalent modification. Post-translational modification such as nitration and carbonylation becomes significant under disease states that are associated with increased oxidative stress, i.e. inflammation and ischemia. This review examines the different post-translational modifications of mitochondrial outer membrane proteins and discusses the physiological relevance of these modifications.

Published

2010

11. Proteomics of mitochondrial inner and outer membranes

Author

Charles L. Hoppel, Janos Kerner, and Anne M. Distler

Subjects

Proteomics, Gel electrophoresis, Spectrometry, Mass, Electrospray Ionization, Chromatography, Chemistry, Membrane Proteins, Mitochondrion, Biochemistry, Mitochondrial Proteins, Membrane, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Mitochondrial Membranes, Proteome, Animals, Humans, Inner membrane, Electrophoresis, Gel, Two-Dimensional, Electrophoresis, Polyacrylamide Gel, Inner mitochondrial membrane, Bacterial outer membrane, Molecular Biology

Abstract

For the proteomic study of mitochondrial membranes, documented high quality mitochondrial preparations are a necessity to ensure proper localization. Despite the state-of-the-art technologies currently in use, there is no single technique that can be used for all studies of mitochondrial membrane proteins. Herein, we use examples to highlight solubilization techniques, different chromatographic methods, and developments in gel electrophoresis for proteomic analysis of mitochondrial membrane proteins. Blue-native gel electrophoresis has been successful not only for dissection of the inner membrane oxidative phosphorylation system, but also for the components of the outer membrane such as those involved in protein import. Identification of PTMs such as phosphorylation, acetylation, and nitration of mitochondrial membrane proteins has been greatly improved by the use of affinity techniques. However, understanding of the biological effect of these modifications is an area for further exploration. The rapid development of proteomic methods for both identification and quantitation, especially for modifications, will greatly impact the understanding of the mitochondrial membrane proteome.

Published

2008

12. Cardiac mitochondria in heart failure: decrease in respirasomes and oxidative phosphorylation

Author

Hani N. Sabbah, Charles L. Hoppel, Edwin J. Vazquez, William Parland, Margaret P. Chandler, Janos Kerner, William C. Stanley, and Mariana G. Rosca

Subjects

Physiology, Cellular respiration, Cell Respiration, Heart failure, Oxidative phosphorylation, 030204 cardiovascular system & hematology, Biology, Mitochondrion, Mitochondria, Heart, Electron Transport, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Adenosine Triphosphate, Dogs, Mitochondrial myopathy, Physiology (medical), medicine, Animals, Inner mitochondrial membrane, Heart metabolism, 030304 developmental biology, 0303 health sciences, Hemodynamics, Membrane Transport Proteins, Mitochondrial Myopathies, Original Articles, Electron transport chain complexes, medicine.disease, Mitochondria, Respirasomes, Biochemistry, chemistry, Electron Transport Chain Complex Proteins, Respirasome, Biophysics, Cardiology and Cardiovascular Medicine, Oxidoreductases, Adenosine triphosphate

Abstract

Aims Mitochondrial dysfunction is a major factor in heart failure (HF). A pronounced variability of mitochondrial electron transport chain (ETC) defects is reported to occur in severe acquired cardiomyopathies without a consistent trend for depressed activity or expression. The aim of this study was to define the defect in the integrative function of cardiac mitochondria in coronary microembolization-induced HF. Methods and results Studies were performed in the canine coronary microembolization-induced HF model of moderate severity. Oxidative phosphorylation was assessed as the integrative function of mitochondria, using a comprehensive variety of substrates in order to investigate mitochondrial membrane transport, dehydrogenase activity and electron-transport coupled to ATP synthesis. The supramolecular organization of the mitochondrial ETC also was investigated by native gel electrophoresis. We found a dramatic decrease in ADP-stimulated respiration that was not relieved by an uncoupler. Moreover, the ADP/O ratio was normal, indicating no defect in the phosphorylation apparatus. The data point to a defect in oxidative phosphorylation within the ETC. However, the individual activities of ETC complexes were normal. The amount of the supercomplex consisting of complex I/complex III dimer/complex IV, the major form of respirasome considered essential for oxidative phosphorylation, was decreased. Conclusions We propose that the mitochondrial defect lies in the supermolecular assembly rather than in the individual components of the ETC.

Published

2008

13. Homozygous carnitine palmitoyltransferase 1b (muscle isoform) deficiency is lethal in the mouse

Author

Trenton R. Schoeb, Philip A. Wood, Yun You, Charles L. Hoppel, Janos Kerner, J. Daniel Sharer, Wallace S. Chick, Doug A. Hamm, and Shaonin Ji

Subjects

Male, Gene isoform, endocrine system, medicine.medical_specialty, Genotype, endocrine system diseases, Endocrinology, Diabetes and Metabolism, Hypothermia, Biology, Biochemistry, Article, Mice, Endocrinology, Carnitine palmitoyltransferase 1, Internal medicine, Brown adipose tissue, Genetics, medicine, Animals, Genetic Predisposition to Disease, heterocyclic compounds, Northern blot, Carnitine, Muscle, Skeletal, neoplasms, Molecular Biology, Mice, Knockout, Carnitine O-Palmitoyltransferase, Homozygote, Skeletal muscle, Embryo, digestive system diseases, Isoenzymes, medicine.anatomical_structure, Organ Specificity, Embryo Loss, Female, medicine.symptom, medicine.drug

Abstract

Carnitine palmitoyltransferase-1 (CPT-1) catalyzes the rate-limiting step of mitochondrial beta-oxidation of long chain fatty acids (LCFA), the most abundant fatty acids in mammalian membranes and in energy metabolism. Human deficiency of the muscle isoform CPT-1b is poorly understood. In the current study, embryos with a homozygous knockout of Cpt-1b were lost before embryonic day 9.5-11.5. Also, while there were normal percentages of CPT-1b+/- pups born from both male and female CPT-1b+/- mice crossed with wild-type mates, the number of CPT-1b+/- pups from CPT-1b+/- breeding pairs was under-represented (63% of the expected number). Northern blot analysis demonstrated approximately 50% Cpt-1b mRNA expression in brown adipose tissue (BAT), heart and skeletal muscles in the CPT-1b+/- male mice. Consistent with tissue-specific expression of Cpt-1b mRNA in muscle but not liver, CPT-1+/- mice had approximately 60% CPT-1 activity in skeletal muscle and no change in total liver CPT-1 activity. CPT-1b+/- mice had normal fasting blood glucose concentration. Consistent with expression of CPT-1b in BAT and muscle, approximately 7% CPT-1b+/- mice (n=30) developed fatal hypothermia following a 3h cold challenge, while none of the CPT-1b+/+ mice (n=30) did. With a prolonged cold challenge (6h), significantly more CPT-1b+/- mice developed fatal hypothermia (52% CPT-1b+/- mice vs. 21% CPT-1b+/+ mice), with increased frequency in females of both genotypes (67% female vs. 38% male CPT-1b+/- mice, and 33% female vs. 8% male CPT-1b+/+ mice). Therefore, lethality of homozygous CPT-1b deficiency in the mice is consistent with paucity of human cases.

Published

2008

14. Diabetes or peroxisome proliferator-activated receptor α agonist increases mitochondrial thioesterase I activity in heart

Author

Martin E. Young, Charles L. Hoppel, Kristen L. King, Karen M. O'Shea, Janos Kerner, Hazel Huang, William C. Stanley, and Stefan E.H. Alexson

Subjects

Male, Agonist, medicine.medical_specialty, medicine.drug_class, cardiac, Palmitic Acid, Peroxisome proliferator-activated receptor, Alpha (ethology), QD415-436, Biology, fatty acids, Biochemistry, Ion Channels, Mitochondria, Heart, Diabetes Mellitus, Experimental, Mitochondrial Proteins, Oxygen Consumption, Endocrinology, Fenofibrate, Internal medicine, medicine, Animals, Uncoupling Protein 3, Uncoupling protein, PPAR alpha, RNA, Messenger, Rats, Wistar, UCP3, chemistry.chemical_classification, Cell Biology, lipotoxicity, Rats, Palmitoyl-CoA Hydrolase, Lipotoxicity, chemistry, Peroxisome proliferator-activated receptor alpha, medicine.drug

Abstract

Peroxisome proliferator-activated receptor alpha (PPAR alpha) is a transcriptional regulator of the expression of mitochondrial thioesterase I (MTE-I) and uncoupling protein 3 (UCP3), which are induced in the heart at the mRNA level in response to diabetes. Little is known about the regulation of protein expression of MTE-I and UCP3 or about MTE-I activity; thus, we investigated the effects of diabetes and treatment with a PPAR alpha agonist on these parameters. Rats were either made diabetic with streptozotocin (55 mg/kg ip) and maintained for 10-14 days or treated with the PPAR alpha agonist fenofibrate (300 mg/kg/day) for 4 weeks. MTE-I and UCP3 protein expression, MTE-1 activity, palmitate export, and oxidative phosphorylation were measured in isolated cardiac mitochondria. Diabetes and fenofibrate increased cardiac MTE-I mRNA, protein, and activity ( approximately 4-fold compared with controls). This increase in activity was matched by a 6-fold increase in palmitate export in fenofibrate-treated animals, despite there being no effect in either group on UCP3 protein expression. Both diabetes and fenofibrate caused significant decreases in state III respiration of isolated mitochondria with pyruvate + malate as the substrate, but only diabetes reduced state III rates with palmitoylcarnitine. Both diabetes and specific PPAR alpha activation increased MTE-I protein, activity, and palmitate export in the heart, with little effect on UCP3 protein expression.

Published

2007

15. Post-translational modifications of rat liver mitochondrial outer membrane proteins identified by mass spectrometry

Author

Anne M. Distler, Charles L. Hoppel, and Janos Kerner

Subjects

Male, Voltage-dependent anion channel, Molecular Sequence Data, Biophysics, Mitochondria, Liver, Mitochondrion, Biochemistry, Article, Analytical Chemistry, Rats, Sprague-Dawley, Mitochondrial membrane transport protein, Animals, Amino Acid Sequence, Phosphorylation, Tyrosine, Molecular Biology, biology, Chemistry, Membrane Proteins, Acetylation, Rats, Membrane protein, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, biology.protein, Electrophoresis, Polyacrylamide Gel, Carnitine palmitoyltransferase I, Bacterial outer membrane, Protein Processing, Post-Translational

Abstract

The identification of post-translational modifications is difficult especially for hydrophobic membrane proteins. Here we present the identification of several types of protein modifications on membrane proteins isolated from mitochondrial outer membranes. We show, in vivo, that the mature rat liver mitochondrial carnitine palmitoyltransferase-I enzyme is N-terminally acetylated, phosphorylated on two threonine residues, and nitrated on two tyrosine residues. We show that long chain acyl-CoA synthetase 1 is acetylated at both the N-terminal end and at a lysine residue and tyrosine residues are found to be phosphorylated and nitrated. For the three voltage-dependent anion channel isoforms present in the mitochondria, the N-terminal regions of the protein were determined and sites of phosphorylation were identified. These novel findings raise questions about regulatory aspects of carnitine palmitoyltransferase-I, long chain acyl-CoA synthetase and voltage dependent anion channel and further studies should advance our understanding about regulation of mitochondrial fatty acid oxidation in general and these three proteins in specific.

Published

2007

16. Validated method for the quantification of free and total carnitine, butyrobetaine, and acylcarnitines in biological samples

Author

Stephen T. Ingalls, Paul E. Minkler, Maria S.K. Stoll, Charles L. Hoppel, and Janos Kerner

Subjects

Spectrometry, Mass, Electrospray Ionization, Trimethylsilyl Compounds, Electrospray ionization, Metabolite, Mass spectrometry, High-performance liquid chromatography, Analytical Chemistry, Diabetes Mellitus, Experimental, chemistry.chemical_compound, Carnitine, medicine, Animals, Humans, Solid phase extraction, Derivatization, Muscle, Skeletal, Chromatography, High Pressure Liquid, Mesylates, Chromatography, Chemistry, Selected reaction monitoring, Solid Phase Extraction, Rats, Betaine, medicine.drug

Abstract

A validated quantitative method for the determination of free and total carnitine, butyrobetaine, and acylcarnitines is presented. The versatile method has four components: (1) isolation using strong cation-exchange solid-phase extraction, (2) derivatization with pentafluorophenacyl trifluoromethanesulfonate, (3) sequential ion-exchange/reversed-phase (ultra) high-performance liquid chromatography [(U)HPLC] using a strong cation-exchange trap in series with a fused-core HPLC column, and (4) detection with electrospray ionization multiple reaction monitoring (MRM) mass spectrometry (MS). Standardized carnitine along with 65 synthesized, standardized acylcarnitines (including short-chain, medium-chain, long-chain, dicarboxylic, hydroxylated, and unsaturated acyl moieties) were used to construct multiple-point calibration curves, resulting in accurate and precise quantification. Separation of the 65 acylcarnitines was accomplished in a single chromatogram in as little as 14 min. Validation studies were performed showing a high level of accuracy, precision, and reproducibility. The method provides capabilities unavailable by tandem MS procedures, making it an ideal approach for confirmation of newborn screening results and for clinical and basic research projects, including treatment protocol studies, acylcarnitine biomarker studies, and metabolite studies using plasma, urine, tissue, or other sample matrixes.

Published

2015

17. Competition between acetate and oleate for the formation of malonyl-CoA and mitochondrial acetyl-CoA in the perfused rat heart

Author

Kathryn A. Jobbins, Charles L. Hoppel, Fang Bian, Henri Brunengraber, Janos Kerner, Paul E. Minkler, Vernon E. Anderson, and Takhar Kasumov

Subjects

Male, Acetates, In Vitro Techniques, Mitochondrion, Mitochondria, Heart, Article, Rats, Sprague-Dawley, chemistry.chemical_compound, Acetyl Coenzyme A, Animals, Molecular Biology, Beta oxidation, Heart metabolism, chemistry.chemical_classification, Chromatography, Myocardium, Fatty Acids, Acetyl-CoA, Models, Cardiovascular, Fatty acid, Acetyl—CoA synthetase, Rats, Malonyl Coenzyme A, Perfusion, Malonyl-CoA, chemistry, Propionate, Propionates, Cardiology and Cardiovascular Medicine, Oxidation-Reduction, Oleic Acid

Abstract

We previously showed that, in the perfused rat heart, the capacity of n-fatty acids to generate mitochondrial acetyl-CoA decreases as their chain length increases. In the present study, we investigated whether the oxidation of a long-chain fatty acid, oleate, is inhibited by short-chain fatty acids, acetate or propionate (which do and do not generate mitochondrial acetyl-CoA, respectively). We perfused rat hearts with buffer containing 4 mM glucose, 0.2 mM pyruvate, 1 mM lactate, and various concentrations of either (i) [U-(13)C]acetate, (ii) [U-(13)C]acetate plus [1-(13)C]oleate, or (iii) unlabeled propionate plus [1-(13)C]oleate. Using mass isotopomer analysis, we determined the contributions of the labeled substrates to the acetyl moiety of citrate (a probe of mitochondrial acetyl-CoA) and to malonyl-CoA. We found that acetate, even at low concentration, markedly inhibits the oxidation of [1-(13)C]oleate in the heart, without change in malonyl-CoA concentration. We also found that propionate, at a concentration higher than 1 mM, decreases (i) the contribution of [1-(13)C]oleate to mitochondrial acetyl-CoA and (ii) malonyl-CoA concentration. The inhibition by acetate or propionate of acetyl-CoA production from oleate probably results from a competition for mitochondrial CoA between the CoA-utilizing enzymes.

Published

2006

18. Quantification of malonyl-coenzyme A in tissue specimens by high-performance liquid chromatography/mass spectrometry

Author

Paul E. Minkler, Charles L. Hoppel, William Parland, Takhar Kasumov, and Janos Kerner

Subjects

Male, Electrospray ionization, Biophysics, Mass spectrometry, Biochemistry, High-performance liquid chromatography, Mass Spectrometry, Rats, Sprague-Dawley, chemistry.chemical_compound, medicine, Animals, Trichloroacetic acid, Muscle, Skeletal, Molecular Biology, Chromatography, High Pressure Liquid, Chromatography, Myocardium, Extraction (chemistry), Reproducibility of Results, Skeletal muscle, Cell Biology, Repeatability, Rats, Malonyl Coenzyme A, Standard curve, medicine.anatomical_structure, Liver, chemistry, lipids (amino acids, peptides, and proteins)

Abstract

We present a validated high-performance liquid chromatography/mass spectrometry (HPLC/MS) method for the quantification of malonyl-coenzyme A (CoA) in tissues. The assay consists of extraction of malonyl-CoA from tissue using 10% trichloroacetic acid, isolation using a reversed-phase solid-phase extraction column, HPLC separation, and detection using electrospray MS. Quantification was performed using an internal standard ([(13)C(3)]malonyl-CoA) and multiple-point standard curves from 50 to 1000pmol. The procedure was validated by performing recovery, accuracy, and precision studies. Recoveries of malonyl-CoA were determined to be 28.8+/-0.9, 48.5+/-1.8, and 44.7+/-4.4% (averages+/-SD, n=5) for liver, heart, and skeletal muscle, respectively. Accuracy was demonstrated by the addition of known amounts of malonyl-CoA to tissue samples. The malonyl-CoA detected was compared with the malonyl-CoA added, and the resulting relationships were linear with slopes and regression coefficients equal to 1. Precision was demonstrated by repetitive analysis of identical samples. These showed a within-run variation between 5 and 11%, and the interbatch repeatability was essentially the same. This procedure was then applied to rat liver, heart, and skeletal muscle, where the malonyl-CoA contents were found to be 1.9+/-0.6, 1.3+/-0.4, and 0.7+/-0.2nmol/g wet weight, respectively, for these tissues. This analytical approach can be extended to the quantification of other acyl-CoA species with no significant modification.

Published

2006

19. A Rostrocaudal Muscular Dystrophy Caused by a Defect in Choline Kinase Beta, the First Enzyme in Phosphatidylcholine Biosynthesis

Author

Shaonin Ji, Kimberly A. Huebsch, Wayne N. Frankel, Yan Yang, Roger B. Sher, Dennis E. Vance, Philip A. Wood, Chieko Aoyama, Gregory A. Cox, Janos Kerner, and Charles L. Hoppel

Subjects

Male, Time Factors, Choline kinase, Muscle Proteins, Biochemistry, Dystrophin, Mice, chemistry.chemical_compound, Sarcolemma, Choline Kinase, Muscular dystrophy, Coloring Agents, Creatine Kinase, Phosphocholine, Recombination, Genetic, Mice, Inbred BALB C, biology, Muscles, Chromosome Mapping, Physical Chromosome Mapping, Lipids, Mitochondria, Cholesterol, Phenotype, Liver, Phosphatidylcholines, Female, ITGA7, Evans Blue, Genotype, Immunoblotting, Mice, Transgenic, Catalysis, Phosphatidylcholine Biosynthesis, Choline kinase beta, medicine, Animals, Muscle, Skeletal, Molecular Biology, Crosses, Genetic, Triglycerides, Glycoproteins, Carnitine O-Palmitoyltransferase, Models, Genetic, Cell Membrane, Dystrophy, Cell Biology, Muscular Dystrophy, Animal, Blotting, Northern, medicine.disease, Molecular biology, Mice, Inbred C57BL, Microscopy, Electron, Microscopy, Fluorescence, chemistry, Mutation, biology.protein

Abstract

Muscular dystrophies include a diverse group of genetically heterogeneous disorders that together affect 1 in 2000 births worldwide. The diseases are characterized by progressive muscle weakness and wasting that lead to severe disability and often premature death. Rostrocaudal muscular dystrophy (rmd) is a new recessive mouse mutation that causes a rapidly progressive muscular dystrophy and a neonatal forelimb bone deformity. The rmd mutation is a 1.6-kb intragenic deletion within the choline kinase beta (Chkb) gene, resulting in a complete loss of CHKB protein and enzymatic activity. CHKB is one of two mammalian choline kinase (CHK) enzymes (alpha and beta) that catalyze the phosphorylation of choline to phosphocholine in the biosynthesis of the major membrane phospholipid phosphatidylcholine. While mutant rmd mice show a dramatic decrease of CHK activity in all tissues, the dystrophy is only evident in skeletal muscle tissues in an unusual rostral-to-caudal gradient. Minor membrane disruption similar to dysferlinopathies suggest that membrane fusion defects may underlie this dystrophy, because severe membrane disruptions are not evident as determined by creatine kinase levels, Evans Blue infiltration, and unaltered levels of proteins in the dystrophin-glycoprotein complex. The rmd mutant mouse offers the first demonstration of a defect in a phospholipid biosynthetic enzyme causing muscular dystrophy, representing a unique model for understanding mechanisms of muscle degeneration.

Published

2006

20. Regulation of cardiac malonyl-CoA content and fatty acid oxidation during increased cardiac power

Author

Gary D. Lopaschuk, Aneta E. Reszko, William C. Stanley, Isidore C. Okere, Margaret P. Chandler, Tracy A. McElfresh, Jason R.B. Dyck, Kristen L. King, Janos Kerner, and Naveen Sharma

Subjects

medicine.medical_specialty, Cardiotonic Agents, Carboxy-lyases, Physiology, Sus scrofa, Blood Pressure, macromolecular substances, AMP-Activated Protein Kinases, Protein Serine-Threonine Kinases, Mitochondrion, chemistry.chemical_compound, Oxygen Consumption, AMP-Activated Protein Kinase Kinases, AMP-activated protein kinase, Heart Rate, Multienzyme Complexes, Dobutamine, Proto-Oncogene Proteins, Physiology (medical), Internal medicine, medicine, Animals, Phosphorylation, Beta oxidation, chemistry.chemical_classification, biology, Myocardium, Fatty Acids, Myocardial Contraction, Pyruvate carboxylase, Malonyl Coenzyme A, enzymes and coenzymes (carbohydrates), Enzyme, Malonyl-CoA, Endocrinology, chemistry, Biochemistry, Hyperglycemia, biology.protein, lipids (amino acids, peptides, and proteins), Carnitine palmitoyltransferase I, Cardiology and Cardiovascular Medicine, Oxidation-Reduction, Protein Kinases, Proto-Oncogene Proteins c-akt

Abstract

Myocardial fatty acid oxidation is regulated by carnitine palmitoyltransferase I (CPT I), which is inhibited by malonyl-CoA. Increased cardiac power causes a fall in malonyl-CoA content and accelerated fatty acid oxidation; however, the mechanism for the decrease in malonyl-CoA is unclear. Malonyl-CoA is formed by acetyl-CoA carboxylase (ACC) and degraded by malonyl-CoA decarboxylase (MCD); thus a fall in malonyl-CoA could be due to activation of MCD, inhibition of ACC, or both. This study assessed the effects of increased cardiac power on malonyl-CoA content and ACC and MCD activities. Anesthetized pigs were studied under control conditions and during increased cardiac power in response to dobutamine infusion and aortic constriction alone, under hyperglycemic conditions, or with the CPT I inhibitor oxfenicine. An increase in cardiac power was accompanied by increased myocardial O2consumption, decreased malonyl-CoA concentration, and increased fatty acid oxidation. There were no differences among groups in activity of ACC or AMP-activated protein kinase (AMPK), which physiologically inhibits ACC. There also were no differences in Vmaxor Kmof MCD. Previous studies have demonstrated that AMPK can be inhibited by protein kinase B (PKB); however, PKB was activated by dobutamine and the elevated insulin that accompanied hyperglycemia, but there was no effect on AMPK activity. In conclusion, the fall in malonyl-CoA and increase in fatty acid oxidization that occur with increased cardiac work were not due to inhibition of ACC or activation of MCD, suggesting alternative regulatory mechanisms for the work-induced decrease in malonyl-CoA concentration.

Published

2005

21. Carnitine Palmitoyltransferase-I and Regulation of Mitochondrial Fatty Acid Oxidation

Author

Charles L. Hoppel and Janos Kerner

Subjects

chemistry.chemical_classification, ACACB, Fatty acid, macromolecular substances, General Chemistry, Pyruvate carboxylase, enzymes and coenzymes (carbohydrates), chemistry.chemical_compound, Enzyme, Malonyl-CoA, chemistry, Biochemistry, Methylcrotonyl-CoA carboxylase, medicine, lipids (amino acids, peptides, and proteins), Carnitine, Carnitine palmitoyltransferase I, medicine.drug

Abstract

Carnitine palmitoyltransferase-I catalyzes the regulated step in overall mitochondrial fatty acid oxidation. The enzyme is controlled by the steady state level of malonyl-CoA and the enzyme’s sensitivity to inhibition by malonyl-CoA. The former is established by the activities of acetyl-CoA carboxylase 2 and malonyl-CoA decarboxylase, while the latter is influenced by post-translational modification (phosphorylation) of CPT-I and/or by changes in the lipid environment of CPT-I.

Published

2005

22. Quantitation of long-chain acylcarnitines by HPLC/fluorescence detection: application to plasma and tissue specimens from patients with carnitine palmitoyltransferase-II deficiency

Author

Charles L. Hoppel, Paul E. Minkler, Janos Kerner, and Kathryn N. North

Subjects

Clinical Biochemistry, Sensitivity and Specificity, Biochemistry, High-performance liquid chromatography, Lipid Metabolism, Inborn Errors, chemistry.chemical_compound, Hplc fluorescence, Carnitine, medicine, Humans, Chromatography, High Pressure Liquid, Palmitoylcarnitine, Chromatography, Carnitine O-Palmitoyltransferase, Biochemistry (medical), Lipid metabolism, General Medicine, medicine.disease, Standard curve, Spectrometry, Fluorescence, chemistry, Carnitine palmitoyltransferase II deficiency, Long chain, medicine.drug

Abstract

Background: Carnitine palmitoyltransferase-II deficiency (CPT-II deficiency) is a rare disorder of lipid metabolism, in which the accumulation of long-chain acylcarnitines is a diagnostic marker. HPLC with fluorescence detection is an attractive analysis method due to its favorable combination of sensitivity, specificity, ease of analysis and minimal capital equipment costs. Methods: Long-chain acylcarnitines were isolated from tissue homogenates (0.5–2 mg wet weight) or plasma (50 μl) using silica gel columns and derivatized with 2-(2,3-naphthalimino)ethyl trifluoromethanesulfonate. Quantitation was by HPLC and fluorescence detection with standard curves (0.0–5.0 nmol/ml) for myristoyl-, palmitoleoyl-, palmitoyl-, oleoyl- and stearoylcarnitine using heptadecanoylcarnitine as the internal standard. Results: Significantly greater amounts of long-chain acylcarnitines were quantified in patients with CPT-II deficiency when compared to controls; e.g. (nmol/ml in patient plasma, controls mean±standard deviation): myristoylcarnitine (0.3, not detectable), palmitoleoylcarnitine (0.5, 0.1±0.1), palmitoylcarnitine (0.9, 0.1±0.0), oleoylcarnitine (3.0, 0.2±0.1), stearoylcarnitine (0.4, not detectable). Conclusions: This method can be used to quantitate long-chain acylcarnitines, illustrating their accumulation in CPT-II deficiency. The analysis was accomplished using inexpensive and widely available instrumentation and is appropriate for research investigators who require precise quantitation of long-chain acylcarnitines in complex biological samples.

Published

2005

23. Carnitine: a nutritional, biosynthetic, and functional perspective

Author

Alison Steiber, Charles L. Hoppel, and Janos Kerner

Subjects

medicine.medical_specialty, Clinical Biochemistry, Biology, Biochemistry, Carnitine transport, chemistry.chemical_compound, Biosynthesis, Carnitine, Internal medicine, medicine, Animals, Humans, Nutritional Physiological Phenomena, Molecular Biology, Beta oxidation, Fatty Acids, General Medicine, Metabolism, Peroxisome, Mitochondria, Malonyl-CoA, Endocrinology, chemistry, Carnitine biosynthesis, Molecular Medicine, Acyl Coenzyme A, medicine.drug

Abstract

Carnitine status in humans is reported to vary according to body composition, gender, and diet. Plasma carnitine concentration positively correlates with the dietary intake of carnitine. The content of carnitine in foodstuff is based on old and inadequate methodology. Nevertheless, dietary carnitine is important. The molecular biology of the enzymes of carnitine biosynthesis has recently been accomplished. Carnitine biosynthesis requires pathways in different tissues and is an efficient system. Overall biosynthesis is determined by the availability of trimethyllysine from tissue proteins. Carnitine deficiency resulting from a defect in biosynthesis has yet to be reported. The role of carnitine in long-chain fatty acid oxidation is well defined. Recent evidence supports a role for the voltage-dependent anion channel in the transport of acyl-CoAs through the mitochondrial outer membrane. The mitochondrial outer membrane carnitine palmitoyltransferase-I in liver can be phosphorylated and when phosphorylated the sensitivity to malonyl-CoA is greatly decreased. This may explain the change in sensitivity of liver carnitine palmitoyltransferase-I observed during fasting and diabetes. Recently reported data clarify the role of carnitine and the carnitine transport system in the interplay between peroxisomes and mitochondrial fatty acid oxidation. Lastly, the buffering of the acyl-CoA/CoA coupled by carnitine reflects intracellular metabolism. This mass action effect underlies the use of carnitine as a therapeutic agent. In summary, these new observations help to further our understanding of the molecular aspects of carnitine in medicine.

Published

2004

24. Phosphorylation of Rat Liver Mitochondrial Carnitine Palmitoyltransferase-I

Author

Charles L. Hoppel, Paul E. Minkler, Janos Kerner, Anne M. Distler, Scott M. Peterman, and William Parland

Subjects

chemistry.chemical_classification, Kinase, Phosphatase, Peptide, Cell Biology, Biology, Mitochondrion, Biochemistry, Molecular biology, Amino acid, chemistry, medicine, Phosphorylation, Carnitine palmitoyltransferase I, Carnitine, Molecular Biology, medicine.drug

Abstract

Hepatic carnitine palmitoyltransferase-I (CPT-IL) isolated from mitochondrial outer membranes obtained in the presence of protein phosphatase inhibitors is readily recognized by phosphoamino acid antibodies. Mass spectrometric analysis of CPT-IL tryptic digests revealed the presence of three phosphopeptides including one with a protein kinase CKII (CKII) consensus site. Incubation of dephosphorylated outer membranes with protein kinases and [γ-32P]ATP resulted in radiolabeling of CPT-I only by CKII. Using mass spectrometry, only one region of phosphorylation was detected in CPT-I isolated from CKII-treated mitochondria. The sequence of the peptide and position of phosphorylated amino acids have been determined unequivocally as FpSSPETDpSHRFGK (residues 740-752). Furthermore, incubation of dephosphorylated outer membranes with CKII and unlabeled ATP led to increased catalytic activity and rendered malonyl-CoA inhibition of CPT-I from competitive to uncompetitive. These observations identify a new mechanism for regulation of hepatic CPT-I by phosphorylation.

Published

2004

25. Isolation of Hepatic Mitochondrial Contact Sites: Previously Unrecognized Inner Membrane Components

Author

Charles L. Hoppel, Peter J. Turkaly, Bernard Tandler, Paul E. Minkler, and Janos Kerner

Subjects

Male, Proteome, Translocase of the outer membrane, Vesicle, Biophysics, Porins, Mitochondria, Liver, Intracellular Membranes, Cell Biology, Biology, Biochemistry, Rats, Rats, Sprague-Dawley, Membrane, Adenine nucleotide, Porin, Translocase of the inner membrane, Animals, Inner membrane, Bacterial outer membrane, Molecular Biology, Subcellular Fractions

Abstract

An improved, fast, and relatively simple procedure for isolation of hepatic mitochondrial contact sites is described. These contact sites include conventional outer membrane, but the inner membrane component (which we term fusion patches) has a unique biochemical composition characterized by a clustering of three specific inner membrane proteins of 54, 52, and 31 kDa identified by proteomics, respectively, as the alpha and beta subunits of ATP synthase and the liver isoform of adenine nucleotide transferase. The contact site fraction was prepared using a discontinuous sucrose gradient from crude outer membranes derived from swollen/shrunk rat liver mitochondria. The resultant contact sites were analyzed using a continuous sucrose density gradient, revealing an apparent heterogeneity due to varying amounts of retained fusion patches in relation to the unvarying outer membrane component. By electron microscopy, contact sites consist of small vacuoles that contain one or several tiny vesicles, many of which are composed of multiple, closely packed lamellae. The contact site subfraction morphology is consistent with the biochemical variation. Thus, contact sites are not haphazard fusions of outer and inner membrane, but consist in part of regions of inner membrane of novel composition (fusion patches) and of conventional outer membrane.

Published

2002

26. Fatty acid chain elongation in palmitate‐perfused working rat heart: mitochondrial acetyl‐CoA is the source of two‐carbon units for chain elongation (758.2)

Author

Charles L. Hoppel, Janos Kerner, Paul E. Minkler, and Edward J. Lesnefsky

Subjects

chemistry.chemical_classification, Acetyl-CoA, chemistry.chemical_element, Fatty acid, Biochemistry, chemistry.chemical_compound, chemistry, Chain (algebraic topology), Genetics, Elongation, Molecular Biology, Carbon, Biotechnology

Published

2014

27. Fatty acid chain elongation in palmitate-perfused working rat heart: mitochondrial acetyl-CoA is the source of two-carbon units for chain elongation

Author

Janos, Kerner, Paul E, Minkler, Edward J, Lesnefsky, and Charles L, Hoppel

Subjects

Carnitine O-Palmitoyltransferase, Palmitoyl Coenzyme A, Myocardium, Palmitic Acid, Muscle Proteins, Mitochondria, Heart, Rats, Inbred F344, Rats, Malonyl Coenzyme A, Perfusion, Metabolism, Acetyl Coenzyme A, Animals, Enzyme Inhibitors, Oxidation-Reduction

Abstract

Rat hearts were perfused with [1,2,3,4-(13)C4]palmitic acid (M+4), and the isotopic patterns of myocardial acylcarnitines and acyl-CoAs were analyzed using ultra-HPLC-MS/MS. The 91.2% (13)C enrichment in palmitoylcarnitine shows that little endogenous (M+0) palmitate contributed to its formation. The presence of M+2 myristoylcarnitine (95.7%) and M+2 acetylcarnitine (19.4%) is evidence for β-oxidation of perfused M+4 palmitic acid. Identical enrichment data were obtained in the respective acyl-CoAs. The relative (13)C enrichment in M+4 (84.7%, 69.9%) and M+6 (16.2%, 17.8%) stearoyl- and arachidylcarnitine, respectively, clearly shows that the perfused palmitate is chain-elongated. The observed enrichment of (13)C in acetylcarnitine (19%), M+6 stearoylcarnitine (16.2%), and M+6 arachidylcarnitine (17.8%) suggests that the majority of two-carbon units for chain elongation are derived from β-oxidation of [1,2,3,4-(13)C4]palmitic acid. These data are explained by conversion of the M+2 acetyl-CoA to M+2 malonyl-CoA, which serves as the acceptor for M+4 palmitoyl-CoA in chain elongation. Indeed, the (13)C enrichment in mitochondrial acetyl-CoA (18.9%) and malonyl-CoA (19.9%) are identical. No (13)C enrichment was found in acylcarnitine species with carbon chain lengths between 4 and 12, arguing against the simple reversal of fatty acid β-oxidation. Furthermore, isolated, intact rat heart mitochondria 1) synthesize malonyl-CoA with simultaneous inhibition of carnitine palmitoyltransferase 1b and 2) catalyze the palmitoyl-CoA-dependent incorporation of (14)C from [2-(14)C]malonyl-CoA into lipid-soluble products. In conclusion, rat heart has the capability to chain-elongate fatty acids using mitochondria-derived two-carbon chain extenders. The data suggest that the chain elongation process is localized on the outer surface of the mitochondrial outer membrane.

Published

2014

28. Kruppel-like Factor 15 Is a Critical Regulator of Cardiac Lipid Metabolism*

Author

Xudong Liao, Jihe Zhao, Shamanthika Shelkay, Kemal M. Akat, Hisashi Fujioka, Mariana G. Rosca, Edwin J. Vazquez, Charles L. Hoppel, Pedro Artero-Calderon, Xiaodong Bai, Thomas Tuschl, P. Christian Schulze, Domenick A. Prosdocimo, Jacob Kirsh, Priti Anand, Mukesh K. Jain, D'Vesharronne Moore, Han Zhu, Saptarsi M. Haldar, Zev Williams, Janos Kerner, and Lilei Zhang

Subjects

medicine.medical_specialty, Regulator, Kruppel-Like Transcription Factors, Peroxisome proliferator-activated receptor, Muscle Proteins, Cardiomegaly, KLF15, Biology, Biochemistry, Cell Line, Transcriptome, Mice, Lipid oxidation, Internal medicine, medicine, Animals, Humans, Molecular Biology, Transcription factor, chemistry.chemical_classification, Heart Failure, Mice, Knockout, Myocardium, Nuclear Proteins, Lipid metabolism, Cell Biology, medicine.disease, Lipid Metabolism, DNA-Binding Proteins, Endocrinology, Metabolism, chemistry, Heart failure, E1A-Associated p300 Protein, Oxidation-Reduction, Transcription Factors

Abstract

The mammalian heart, the body's largest energy consumer, has evolved robust mechanisms to tightly couple fuel supply with energy demand across a wide range of physiologic and pathophysiologic states, yet, when compared with other organs, relatively little is known about the molecular machinery that directly governs metabolic plasticity in the heart. Although previous studies have defined Kruppel-like factor 15 (KLF15) as a transcriptional repressor of pathologic cardiac hypertrophy, a direct role for the KLF family in cardiac metabolism has not been previously established. We show in human heart samples that KLF15 is induced after birth and reduced in heart failure, a myocardial expression pattern that parallels reliance on lipid oxidation. Isolated working heart studies and unbiased transcriptomic profiling in Klf15-deficient hearts demonstrate that KLF15 is an essential regulator of lipid flux and metabolic homeostasis in the adult myocardium. An important mechanism by which KLF15 regulates its direct transcriptional targets is via interaction with p300 and recruitment of this critical co-activator to promoters. This study establishes KLF15 as a key regulator of myocardial lipid utilization and is the first to implicate the KLF transcription factor family in cardiac metabolism.

Published

2014

29. Aging skeletal muscle mitochondria in the rat: decreased uncoupling protein-3 content

Author

Janos Kerner, Charles L. Hoppel, Peter J. Turkaly, and Paul E. Minkler

Subjects

Male, Aging, medicine.medical_specialty, Physiology, Endocrinology, Diabetes and Metabolism, Citrate (si)-Synthase, Oxidative phosphorylation, Mitochondrion, Biology, Ion Channels, Oxidative Phosphorylation, Mitochondrial Proteins, Oxygen Consumption, Physiology (medical), Internal medicine, medicine, Animals, Uncoupling Protein 3, Citrate synthase, Carnitine palmitoyltransferase II, Uncoupling protein, Carnitine, Phosphorylation, Muscle, Skeletal, Carnitine O-Palmitoyltransferase, Skeletal muscle, Rats, Inbred F344, Mitochondria, Muscle, Rats, Adenosine Diphosphate, Succinate Dehydrogenase, Kinetics, Endocrinology, medicine.anatomical_structure, biology.protein, Carnitine palmitoyltransferase I, Carrier Proteins, Oxidation-Reduction, medicine.drug

Abstract

The goal of the present study was to discern the cellular mechanism(s) that contributes to the age-associated decrease in skeletal muscle aerobic capacity. Skeletal muscle mitochondrial content, a parameter of oxidative capacity, was significantly lower (25 and 20% calculated on the basis of citrate synthase and succinate dehydrogenase activities, respectively) in 24-mo-old Fischer 344 rats compared with 6-mo-old adult rats. Mitochondria isolated from skeletal muscle of both age groups had identical state 3 (ADP-stimulated) and ADP-stimulated maximal respiratory rates and phosphorylation potential (ADP-to-O ratios) with both nonlipid and lipid substrates. In contrast, mitochondria from 24-mo-old rats displayed significantly lower state 4 (ADP-limited) respiratory rates and, consequently, higher respiratory control ratios. Consistent with the tighter coupling, there was a 68% reduction in uncoupling protein-3 (UCP-3) abundance in mitochondria from elderly compared with adult rats. Congruent with the respiratory studies, there was no age-associated decrease in carnitine palmitoyltransferase I and carnitine palmitoyltransferase II activities in isolated skeletal muscle mitochondria. However, there was a small, significant decrease in tissue total carnitine content. It is concluded that the in vivo observed decrease in skeletal muscle aerobic capacity with advanced age is a consequence of the decreased mitochondrial density. On the basis of the dramatic reduction of UCP-3 content associated with decreased state 4 respiration of skeletal muscle mitochondria from elderly rats, we propose that an increased free radical production might contribute to the metabolic compromise in aging.

Published

2001

30. Mitochondrial Dysfunction in Cardiac Disease: Ischemia–Reperfusion, Aging, and Heart Failure

Author

Charles L. Hoppel, Janos Kerner, Edward J. Lesnefsky, Shadi Moghaddas, and Bernard Tandler

Subjects

Aging, medicine.medical_specialty, Heart Diseases, Myocardial Ischemia, Ischemia, Cardiomyopathy, Myocardial Reperfusion Injury, Disease, Biology, Mitochondrion, Cell Physiological Phenomena, Pathogenesis, Internal medicine, medicine, Animals, Humans, Molecular Biology, Beta oxidation, Heart Failure, Myocardium, medicine.disease, Mitochondria, Heart failure, Cardiology, Ischemic preconditioning, Cardiology and Cardiovascular Medicine

Abstract

Mitochondria contribute to cardiac dysfunction and myocyte injury via a loss of metabolic capacity and by the production and release of toxic products. This article discusses aspects of mitochondrial structure and metabolism that are pertinent to the role of mitochondria in cardiac disease. Generalized mechanisms of mitochondrial-derived myocyte injury are also discussed, as are the strengths and weaknesses of experimental models used to study the contribution of mitochondria to cardiac injury. Finally, the involvement of mitochondria in the pathogenesis of specific cardiac disease states (ischemia, reperfusion, aging, ischemic preconditioning, and cardiomyopathy) is addressed.

Published

2001

31. Fatty acid import into mitochondria

Author

Charles L. Hoppel and Janos Kerner

Subjects

Saccharomyces cerevisiae Proteins, Porins, Carnitine-acylcarnitine translocase, Gene Expression Regulation, Enzymologic, Carnitine transport, Structure-Activity Relationship, Carnitine, Coenzyme A Ligases, medicine, Animals, Humans, Carnitine palmitoyltransferase II, Inner mitochondrial membrane, Molecular Biology, Binding Sites, Carnitine O-Palmitoyltransferase, biology, Fatty Acids, Biological Transport, Intracellular Membranes, Cell Biology, Mitochondrial carrier, Mitochondria, Malonyl Coenzyme A, Repressor Proteins, Biochemistry, Translocase of the inner membrane, biology.protein, Carnitine palmitoyltransferase I, Oxidation-Reduction, medicine.drug

Abstract

The mitochondrial carnitine system plays an obligatory role in beta-oxidation of long-chain fatty acids by catalyzing their transport into the mitochondrial matrix. This transport system consists of the malonyl-CoA sensitive carnitine palmitoyltransferase I (CPT-I) localized in the mitochondrial outer membrane, the carnitine:acylcarnitine translocase, an integral inner membrane protein, and carnitine palmitoyltransferase II localized on the matrix side of the inner membrane. Carnitine palmitoyltransferase I is subject to regulation at the transcriptional level and to acute control by malonyl-CoA. The N-terminal domain of CPT-I is essential for malonyl-CoA inhibition. In liver CPT-I activity is also regulated by changes in the enzyme's sensitivity to malonyl-CoA. As fluctuations in tissue malonyl-CoA content are parallel with changes in acetyl-CoA carboxylase activity, which in turn is under the control of 5'-AMP-activated protein kinase, the CPT-I/malonyl-CoA system is part of a fuel sensing gauge, turning off and on fatty acid oxidation depending on the tissue's energy demand. Additional mechanism(s) of short-term control of CPT-I activity are emerging. One proposed mechanism involves phosphorylation/dephosphorylation dependent direct interaction of cytoskeletal components with the mitochondrial outer membrane or CPT-I. We have proposed that contact sites between the outer and inner mitochondrial membranes form a microenvironment which facilitates the carnitine transport system. In addition, this system includes the long-chain acyl-CoA synthetase and porin as components.

Published

2000

32. A 22 kDa polyanion inhibits carnitine-dependent fatty acid oxidation in rat liver mitochondria

Author

Janos Kerner, Charles L. Hoppel, and Peter J. Turkaly

Subjects

Male, Polymers, Biophysics, Mitochondria, Liver, Mitochondrion, Biology, Biochemistry, Ion Channels, Rats, Sprague-Dawley, chemistry.chemical_compound, Oxygen Consumption, Structural Biology, Hexokinase, Carnitine, Genetics, medicine, Animals, Carnitine palmitoyltransferase, Carnitine O-palmitoyltransferase, Molecular Biology, Beta oxidation, Palmitoylcarnitine, Carnitine O-Palmitoyltransferase, Fatty Acids, Porin, technology, industry, and agriculture, Cell Biology, Polyelectrolytes, Rats, chemistry, Fatty acid oxidation, Methacrylates, Polystyrenes, Polyanion, Bacterial outer membrane, Oxidation-Reduction, medicine.drug

Abstract

The transport of activated fatty acids across the mitochondrial outer membrane has not been fully addressed. A polyanion (Mn=22 kDa) inhibited the ADP-stimulated carnitine-dependent oxidation of both palmitoyl-CoA and palmitate plus CoA as well as mitochondrial hexokinase binding. In contrast, the oxidation of palmitoylcarnitine plus malate, as well as glutamate oxidation, was essentially unaffected. Mitochondrial carnitine palmitoyltransferase-1 was not inhibited by the polyanion. The data suggest an additional component in carnitine-dependent mitochondrial fatty acid oxidation, possibly porin.

Published

1999

33. Beta-receptor blockade decreases carnitine palmitoyl transferase I activity in dogs with heart failure

Author

Ashish R. Panchal, Hani N. Sabbah, William C. Stanley, and Janos Kerner

Subjects

Cardiac function curve, medicine.medical_specialty, Adrenergic beta-Antagonists, chemistry.chemical_compound, Dogs, Internal medicine, Animals, Medicine, Citrate synthase, Carnitine, Beta oxidation, Triglycerides, Metoprolol, Heart Failure, Ejection fraction, Carnitine O-Palmitoyltransferase, Triglyceride, biology, business.industry, Fatty Acids, Hemodynamics, Stroke Volume, medicine.disease, Rats, Disease Models, Animal, Endocrinology, chemistry, Heart failure, biology.protein, Cardiology and Cardiovascular Medicine, business, medicine.drug

Abstract

Background: Pharmacological inhibition of carnitine palmitoyl transferase I (CPT-I), the enzyme controlling the rate of fatty acid transport into the mitochondria, prevents the contractile dysfunction, myosin isozyme shift and deterioration in sarcoplasmic reticulum Ca2− handling that occurs in rat models of left ventricular hypertrophy. In this study we examine whether the improved cardiac function with beta blockade therapy in heart failure is associated with an alteration in CPT-I activity. Methods and Results: We examined dogs with coronary microembolism-induced heart failure treated for 12 weeks with metoprolol (25 mg twice daily). Myocardial activities of CPT-I, medium-chain acyl co-enzyme A dehydrogenase (MCAD, a beta-oxidation enzyme), citrate synthase, and triglyceride content were measured. The progressive decrease in cardiac function was prevented by treatment with metoprolol, as reflected by an improved ejection fraction over 12 weeks in the metoprolol group (from 35% to 40%) compared to the untreated heart failure dogs (decrease from 36% to 26%). Dogs treated with metoprolol had a marked decrease in CPT-I activity (0.46 ± 0.03 vs. 0.64 ± 0.02 μmol min−1g−1wet weight; P < .02) along with an increase in triglyceride concentration compared to untreated heart failure dogs (3.9 ± 0.3 v 4.9 ± 0.2 μmol/g wet weight, respectively; P < .003). By contrast, MCAD and citrate synthase activities did not change. Conclusion: Metoprolol induced a decrease in CPT-I activity and an increase in triglyceride content. These results suggest that the improved function observed with beta blockers in heart failure could be due, in part, to a decrease in CPT-I activity and less fatty acid oxidation by the heart.

Published

1998

34. Carnitine and β-Oxidation

Author

Charles L. Hoppel and Janos Kerner

Subjects

chemistry.chemical_classification, Flavin adenine dinucleotide, Citric acid cycle, chemistry.chemical_compound, Lipoprotein lipase, Malonyl-CoA, chemistry, Biochemistry, Fatty acid, Oxidative phosphorylation, Nicotinamide adenine dinucleotide, Beta oxidation

Abstract

Fatty acids represent the major fuel for energy production. The substrate fatty acids either are mobilized from triglycerides stored in a adipose tissue and transported via the bloodstream to tissues or are derived from plasma lipoproteins by the lipoprotein lipase. Following uptake into tissues by specific transport proteins, fatty acids are either stored as triglycerides or used for energy production. This latter process, called β -oxidation, is localized within the mitochondria and involves activation of fatty acids in the cytosol, the carnitine-dependent uptake of activated fatty acids into mitochondria, and their sequential oxidative chain shortening yielding acetyl-CoA and reducing equivalents (flavin adenine dinucleotide, nicotinamide adenine dinucleotide). Complete oxidation of fatty acid-derived acetyl-CoA in the citric acid cycle produces additional reducing equivalents. The energy in the form of ATP is formed during the reoxidation of reducing equivalents in the electron transport chain coupled with ATP synthesis.

Published

2013

35. Kruppel-like factor 15 regulates skeletal muscle lipid flux and exercise adaptation

Author

Han Zhu, Mitsuharu Okutsu, Marco Brotto, Zhen Yan, Betty L. Eapen, Yuan Lu, Thomas M. Nosek, Leticia Brotto, Saptarsi M. Haldar, Domenick A. Prosdocimo, Mariana G. Rosca, Darwin Jeyaraj, Janos Kerner, Charles L. Hoppel, Aaron P. Russell, Daiji Kawanami, Xiaodong Bai, Anthony N. Gerber, Rodney J. Snow, Priti Anand, Mukesh K. Jain, Owen P. McGuinness, and Hisashi Fujioka

Subjects

medicine.medical_specialty, Multidisciplinary, Muscle fatigue, Kruppel-Like Transcription Factors, Skeletal muscle, Nuclear Proteins, Lipid metabolism, KLF15, Carbohydrate metabolism, Biology, Biological Sciences, Lipid Metabolism, Endocrinology, medicine.anatomical_structure, Glucose, Internal medicine, medicine, Myocyte, Homeostasis, Humans, Amino Acids, Muscle, Skeletal, Flux (metabolism), Exercise

Abstract

The ability of skeletal muscle to enhance lipid utilization during exercise is a form of metabolic plasticity essential for survival. Conversely, metabolic inflexibility in muscle can cause organ dysfunction and disease. Although the transcription factor Kruppel-like factor 15 (KLF15) is an important regulator of glucose and amino acid metabolism, its endogenous role in lipid homeostasis and muscle physiology is unknown. Here we demonstrate that KLF15 is essential for skeletal muscle lipid utilization and physiologic performance. KLF15 directly regulates a broad transcriptional program spanning all major segments of the lipid-flux pathway in muscle. Consequently, Klf15 -deficient mice have abnormal lipid and energy flux, excessive reliance on carbohydrate fuels, exaggerated muscle fatigue, and impaired endurance exercise capacity. Elucidation of this heretofore unrecognized role for KLF15 now implicates this factor as a central component of the transcriptional circuitry that coordinates physiologic flux of all three basic cellular nutrients: glucose, amino acids, and lipids.

Published

2012

36. Isolation and mass spectrometric analysis of native protein complexes in rat liver mitochondrial contact sites

Author

Charles L. Hoppel, Kwang Won Lee, and Janos Kerner

Subjects

Biochemistry, Chemistry, Rat liver, Genetics, Native protein, Isolation (microbiology), Molecular Biology, Mass spectrometric, Biotechnology

Published

2012

37. Effect of propionylcarnitine on mitochondrial energy metabolism in elderly rat heart

Author

Aleardo Koverech, Charles L. Hoppel, Janos Kerner, and Ashraf Virmani

Subjects

medicine.medical_specialty, Endocrinology, Chemistry, Internal medicine, Genetics, medicine, Energy metabolism, Rat heart, Molecular Biology, Biochemistry, Biotechnology

Published

2012

38. A liver mitochondrial outer membrane (MOM) fatty acid transfer complex

Author

Janos Kerner, Charles L. Hoppel, and Kwang Won Lee

Subjects

chemistry.chemical_classification, Chemistry, Genetics, Biophysics, Fatty acid, Bacterial outer membrane, Molecular Biology, Biochemistry, Biotechnology

Published

2010

39. Acetylcarnitine treatment increases mitochondrial protein‐lysine acetylation and protein expression

Author

Elizabeth Yohannes, Janos Kerner, Aleardo Koverech, Marc Chance, Ashraf Virmani, and Charles L. Hoppel

Subjects

Chemistry, Lysine, Biochemistry, Protein expression, Acetylation, Genetics, medicine, lipids (amino acids, peptides, and proteins), Carnitine, Acetylcarnitine, Molecular Biology, Mitochondrial protein, Biotechnology, medicine.drug

Abstract

Myocardial carnitine content of Fischer 344 rats decreases with age and proportionally affects total, free, acyl-, and acetylcarnitine (ALC). In both adult and elderly hearts, ALC is the major acyl...

Published

2010

40. Effect of etomoxiryl-CoA on different carnitine acyltransferases

Author

Loran L. Bieber, Rena VanRenterghem, Kathleen Lilly, Janos Kerner, and Chung Chang

Subjects

Male, Coenzyme A, Biology, Mitochondrion, Biochemistry, Mitochondria, Heart, chemistry.chemical_compound, Adenosine Triphosphate, Glucosides, medicine, Animals, Carnitine O-palmitoyltransferase, Carnitine, Pharmacology, Carnitine O-Palmitoyltransferase, Rats, Inbred Strains, Peroxisome, Rats, Malonyl Coenzyme A, Carnitine Acyltransferases, chemistry, Microsomes, Liver, Microsome, Epoxy Compounds, Cattle, Uncompetitive inhibitor, Etomoxir, medicine.drug

Abstract

The effects of etomoxiryl-CoA on purified carnitine acyltransferases and on carnitine acyl-transferases of rat heart mitochondria and rat liver microsomes were determined. At nanomolar concentrations, the data agreed with that of other investigators who have shown that etomoxiryl-CoA must be binding to a high affinity site with specific inhibition of mitochondrial carnitine palmitoyltransferase (CPTo). Micromolar amounts of etomoxiryl-CoA inhibited both short- and long-chain carnitine acyltransferases. The concentrations of etomoxiryl-CoA required for 50% inhibition of the different carnitine acetyltransferases and microsomal and peroxisomal carnitine octanoyltransferase were in the low micromolar range. Mixed-type and uncompetitive inhibition kinetics were obtained, depending on the source of purified enzyme. When purified rat heart CPT was incubated with etomoxiryl-CoA, it increased the K0.5 and decreased the Hill coefficient for acyl-CoA. Both proteins and phospholipids of mitochondria and microsomes formed covalent adducts of [3H]etomoxir, with the predominant labeling in phospholipids. None of the purified enzymes formed covalent adducts when incubated with [3H]etomoxiryl-CoA, in contrast to intact mitochondria or microsomes. The major 3H-labeled protein for rat heart mitochondria had a molecular weight of 81,000 +/- 4000, and the major proteins from microsomes had a molecular weight of 51,000-57,000. Malonyl-CoA prevented most of the tritum incorporation into the 81,000 Da protein of mitochondria, but it had little effect on incorporation of tritiated etomoxir into the 51,000-57,000 Da proteins of microsomes. When 50 microM etomoxiryl-CoA was added to microsomes and to mitochondria that had been incubated with radioactive etomoxiryl-CoA, much of the radioactive etomoxir disappeared from the major microsomal proteins, but virtually none was displaced from the mitochondrial protein. Thus, at least two different types of covalent etomoxir complexes were formed. This pulse-chase experiment showed that the mitochondrial protein-etomoxir complex was not turned over, consistent with other data showing that etomoxir inhibited carnitine palmitoyltransferase. In contrast, the major protein-etomoxir complex in microsomes was turned over during the pulse-chase experiment.

Published

1992

41. Post-translational modifications of mitochondrial outer membrane proteins

Author

Anne M, Distler, Janos, Kerner, Kwangwon, Lee, and Charles L, Hoppel

Subjects

Mitochondrial Proteins, Proteomics, Carnitine O-Palmitoyltransferase, Mitochondrial Membranes, Molecular Sequence Data, Animals, Humans, Electrophoresis, Polyacrylamide Gel, Amino Acid Sequence, Protein Processing, Post-Translational, Mass Spectrometry

Abstract

In recent years, a wide variety of proteomic approaches using gel electrophoresis and mass spectrometry has been developed to detect post-translational modifications. Mitochondria are often a focus of these studies due to their important role in cellular function. Many of their crucial transport and oxidative-phosphorylation functions are performed by proteins residing in the inner and outer membranes of the mitochondria. Although proteomic technologies have greatly enhanced our understanding of regulation in cellular processes, analysis of membrane proteins has lagged behind that of soluble proteins. Herein, we present techniques to facilitate the detection of post-translational modifications of mitochondrial membrane proteins including the isolation of resident membranes as well as electrophoretic and immunological-based methods for identification of post-translational modifications.

Published

2009

42. Fatty acid beta oxidation is the source of malonyl‐CoA for fatty acid chain elongation in rat heart

Author

Maria S. K. Stoll, Janos Kerner, Paul E. Minkler, and Charles L. Hoppel

Subjects

chemistry.chemical_classification, chemistry.chemical_compound, Malonyl-CoA, Biochemistry, chemistry, Genetics, Fatty acid, Rat heart, Elongation, Fatty acid beta-oxidation, Molecular Biology, Biotechnology

Published

2009

43. Chapter 6 Post‐translational Modifications of Mitochondrial Outer Membrane Proteins

Author

Anne M. Distler, Charles L. Hoppel, Janos Kerner, and Kwangwon Lee

Subjects

Gel electrophoresis, Mitochondrial membrane transport protein, Membrane, Membrane protein, biology, biology.protein, Mitochondrion, Inner mitochondrial membrane, Bacterial outer membrane, Polyacrylamide gel electrophoresis, Cell biology

Abstract

In recent years, a wide variety of proteomic approaches using gel electrophoresis and mass spectrometry has been developed to detect post-translational modifications. Mitochondria are often a focus of these studies due to their important role in cellular function. Many of their crucial transport and oxidative-phosphorylation functions are performed by proteins residing in the inner and outer membranes of the mitochondria. Although proteomic technologies have greatly enhanced our understanding of regulation in cellular processes, analysis of membrane proteins has lagged behind that of soluble proteins. Herein, we present techniques to facilitate the detection of post-translational modifications of mitochondrial membrane proteins including the isolation of resident membranes as well as electrophoretic and immunological-based methods for identification of post-translational modifications.

Published

2009

44. Quantification of carnitine and acylcarnitines in biological matrices by HPLC electrospray ionization-mass spectrometry

Author

Shuming Yang, Stephen T. Ingalls, Charles L. Hoppel, Paul E. Minkler, Janos Kerner, and Maria S. K. Stoll

Subjects

Spectrometry, Mass, Electrospray Ionization, Chromatography, Molecular Structure, Electrospray ionization, Biochemistry (medical), Clinical Biochemistry, Acetylation, Mass spectrometry, Tandem mass spectrometry, High-performance liquid chromatography, chemistry.chemical_compound, chemistry, Tandem Mass Spectrometry, Carnitine, Calibration, medicine, Humans, Ion trap, Acetylcarnitine, Palmitoylcarnitine, Chromatography, High Pressure Liquid, medicine.drug

Abstract

Background: Analysis of carnitine and acylcarnitines by tandem mass spectrometry (MS/MS) has limitations. First, preparation of butyl esters partially hydrolyzes acylcarnitines. Second, isobaric nonacylcarnitine compounds yield false-positive results in acylcarnitine tests. Third, acylcarnitine constitutional isomers cannot be distinguished.Methods: Carnitine and acylcarnitines were isolated by ion-exchange solid-phase extraction, derivatized with pentafluorophenacyl trifluoromethanesulfonate, separated by HPLC, and detected with an ion trap mass spectrometer. Carnitine was quantified with d3-carnitine as the internal standard. Acylcarnitines were quantified with 42 synthesized calibrators. The internal standards used were d6-acetyl-, d3-propionyl-, undecanoyl-, undecanedioyl-, and heptadecanoylcarnitine.Results: Example recoveries [mean (SD)] were 69.4% (3.9%) for total carnitine, 83.1% (5.9%) for free carnitine, 102.2% (9.8%) for acetylcarnitine, and 107.2% (8.9%) for palmitoylcarnitine. Example imprecision results [mean (SD)] within runs (n = 6) and between runs (n = 18) were, respectively: total carnitine, 58.0 (0.9) and 57.4 (1.7) μmol/L; free carnitine, 44.6 (1.5) and 44.3 (1.2) μmol/L; acetylcarnitine, 7.74 (0.51) and 7.85 (0.69) μmol/L; and palmitoylcarnitine, 0.12 (0.01) and 0.11 (0.02) μmol/L. Standard-addition slopes and linear regression coefficients were 1.00 and 0.9998, respectively, for total carnitine added to plasma, 0.99 and 0.9997 for free carnitine added to plasma, 1.04 and 0.9972 for octanoylcarnitine added to skeletal muscle, and 1.05 and 0.9913 for palmitoylcarnitine added to skeletal muscle. Reference intervals for plasma, urine, and skeletal muscle are provided.Conclusions: This method for analysis of carnitine and acylcarnitines overcomes the observed limitations of MS/MS methods.

Published

2008

45. Rat liver mitochondrial carnitine palmitoyltransferase-I, hepatic carnitine, and malonyl-CoA: effect of starvation

Author

Paul E. Minkler, Charles L. Hoppel, Janos Kerner, and William Parland

Subjects

Male, medicine.medical_specialty, Physiology, Blotting, Western, Mitochondria, Liver, Mitochondrion, Biology, Rats, Sprague-Dawley, chemistry.chemical_compound, Physiology (medical), Internal medicine, Carnitine, Ketogenesis, medicine, Animals, IC50, Beta oxidation, Starvation, Carnitine O-Palmitoyltransferase, Body Weight, General Medicine, Organ Size, Rats, Malonyl Coenzyme A, Malonyl-CoA, Endocrinology, chemistry, Biochemistry, Liver, Electrophoresis, Polyacrylamide Gel, Carnitine palmitoyltransferase I, medicine.symptom, medicine.drug

Abstract

Hepatic mitochondrial fatty acid oxidation and ketogenesis increase during starvation. Carnitine palmitoyltransferase I (CPT-I) catalyses the rate-controlling step in the overall pathway and retains its control over beta-oxidation under fed, starved and diabetic conditions. To determine the factors contributing to the reported several-fold increase in fatty acid oxidation in perfused livers, we measured the V(max) and K(m) values for palmitoyl-CoA and carnitine, the K(i) (and IC(50)) values for malonyl-CoA in isolated liver mitochondria as well as the hepatic malonyl-CoA and carnitine contents in control and 48 h starved rats. Since CPT-I is localized in the mitochondrial outer membrane and in contact sites, the kinetic properties of CPT-I also was determined in these submitochondrial structures. After 48 h starvation, there is: (a) a significant increase in K(i) and decrease in hepatic malonyl-CoA content; (b) a decreased K(m) for palmitoyl-CoA; and (c) increased catalytic activity (V(max)) and CPT-I protein abundance that is significantly greater in contact sites compared with outer membranes. Based on these changes the estimated increase in mitochondrial fatty acid oxidation is significantly less than that observed in perfused liver. This suggests that CPT-I is regulated in vivo by additional mechanism(s) lost during mitochondrial isolation or/and that mitochondrial oxidation of peroxisomal beta-oxidation products contribute to the increased ketogenesis by bypassing CPT-I. Furthermore, the greater increase in CPT-I protein in contact sites as compared to outer membranes emphasizes the significance of contact sites in hepatic fatty acid oxidation.

Published

2008

46. Mass spectrometric demonstration of the presence of liver carnitine palmitoyltransferase-I (CPT-I) in heart mitochondria of adult rats

Author

Anne M. Distler, Charles L. Hoppel, and Janos Kerner

Subjects

Gene isoform, Male, Spectrometry, Mass, Electrospray Ionization, Molecular Sequence Data, Biophysics, Mitochondria, Liver, Mitochondrion, Biology, Biochemistry, Mitochondria, Heart, Analytical Chemistry, Rats, Sprague-Dawley, Tandem Mass Spectrometry, medicine, Animals, Carnitine, Amino Acid Sequence, Tyrosine, Phosphorylation, Molecular Biology, Beta oxidation, Alanine, Carnitine O-Palmitoyltransferase, Muscles, Skeletal muscle, Molecular biology, Rats, Isoenzymes, Molecular Weight, medicine.anatomical_structure, Carnitine palmitoyltransferase I, medicine.drug

Abstract

The carnitine palmitoyltransferase-I (CPT-I) enzymes catalyze the regulated step in overall mitochondrial fatty acid oxidation. The liver and muscle isoforms are expressed in liver and skeletal muscle respectively with the isoforms exhibiting different kinetic properties and apparent molecular weight masses. In contrast, the heart expresses both isoforms at the mRNA level. However, for the expression of the liver isoform at the protein level only indirect evidence is available, such as tagging with radiolabeled CPT-I inhibitors followed by SDS-PAGE separation and kinetic analysis using inhibitors. The importance of fatty acid oxidation in the heart and the potential regulation via the liver isoform of CPT-I demands proof of the liver isoform in the heart. Using a proteomic approach in the present study we demonstrate that rat heart mitochondria (a) contain both the muscle and liver isoforms; (b) both proteins retain their C- and N-termini; (c) the N-terminal alanine residues are acetylated; (d) and in rat heart mitochondria the liver isoform is phosphorylated on tyrosine 281. By providing amino acid sequence information this is the first unequivocal demonstration that the liver isoform of CPT-I is expressed at the protein level in adult rat heart mitochondria and that the apparent smaller molecular size of the muscle isoform is not due to proteolytic truncation.

Published

2008

47. Carnitine Ester Excretion in Pediatric Patients Receiving Parenteral Nutrition

Author

Emanuel Lebenthal, Thomas M. Rossi, Janos Kerner, Eberhard Schmidt-Sommerfeld, Loran L. Bieber, and Duna Penn

Subjects

Adult, Parenteral Nutrition, medicine.medical_specialty, Adolescent, Gastrointestinal Diseases, Kidney, Absorption, Excretion, Older patients, Carnitine, Internal medicine, medicine, Humans, Child, Carbon chain, Free carnitine, Chemistry, Infant, Esters, Inflammatory Bowel Diseases, medicine.anatomical_structure, Parenteral nutrition, Endocrinology, Child, Preschool, Renal physiology, Pediatrics, Perinatology and Child Health, medicine.drug

Abstract

Carnitine plasma concentrations and the excretion of carnitine and individual carnitine esters were determined in 25 children and adolescents with gastrointestinal diseases receiving carnitine-free parenteral nutrition for at least 1 mo using radiochemical and radioisotopic exchange HPLC methods. Children less than 12-y-old usually had carnitine plasma concentrations less than -2 SD from the normal mean for age, whereas patients greater than 12-y-old had carnitine plasma concentrations within the normal range. Age was the only variable to correlate significantly with plasma carnitine concentrations during parenteral nutrition. Free carnitine (FC) excretion was closely correlated with plasma FC concentrations and minimal at values less than 25 mumols/L. The excretion of FC and short-chain acylcarnitines was reduced by an order of magnitude in younger compared with older patients and controls, but the excretion of "other" acylcarnitines was less affected. Some of the latter were tentatively identified using gas-liquid chromatographic and mass spectroscopic techniques as unsaturated and/or branched medium-chain carnitine esters with a carbon chain of C8-C10. The results suggest that FC and short-chain acylcarnitine are conserved by the kidney in nutritional carnitine deficiency but that there may be an obligatory renal excretion of other carnitine esters that contributes to the development of hypocarnitinemia in the younger age group.

Published

1990

48. L-Carnitine Replacement Therapy in Chronic Valproate Treatment

Author

G. Acsadi, Béla Melegh, Attila Sandor, J. Lakatos, and Janos Kerner

Subjects

Male, medicine.medical_specialty, Adolescent, medicine.medical_treatment, Ketone Bodies, Glucagon, Oral administration, Carnitine, Internal medicine, Ketogenesis, medicine, Humans, Lipolysis, Child, Epilepsy, business.industry, Valproic Acid, Insulin, General Medicine, Lipid Metabolism, Endocrinology, Anticonvulsant, Chronic Disease, Pediatrics, Perinatology and Child Health, Ketone bodies, Female, lipids (amino acids, peptides, and proteins), Neurology (clinical), business, medicine.drug

Abstract

Ten epileptic children with chronic valproic acid (VPA) treatment were given L-carnitine for 14 days. As compared to age and sex matched control subjects the carnitine status of the VPA treated children showed carnitine insufficiency prior to the carnitine administration with lower total and free carnitine in plasma and in urine. In response to the extra intake the plasma free and esterified carnitines increased 1.7-fold. The daily excreted amount of esterified carnitines increased 6.5-fold (1.55 +/- 0.23 vs 10.1 +/- 1.68 mumol/kg/day, means +/- SEM, p less than 0.005) showing that a considerable part of the administered carnitine participated in the elimination of acyl groups from the body. The depressed level of beta-hydroxybutyrate in the plasma (31.8 +/- 7.42 vs controls 118.0 +/- 16.0 mumol/l, means +/- SEM, p less than 0.005) remained unaffected by the carnitine administration (29.7 +/- 7.06 mumol/l) suggesting that the hypoketonemia is not a direct consequence of the carnitine insufficiency. No differences were observed in the plasma level of free fatty acids, triglycerides and in insulin: glucagon ratios between the VPA treated and control subjects, suggesting that lipolysis of fats and the hepatic hormonal control mediated by these hormones are not the sites at which VPA causes reduced fasting ketogenesis. The plasma level of VPA and the seizure control remained unaffected by carnitine treatment.

Published

1990

49. FATTY ACID CHAIN-ELONGATION IN PERFUSED RAT HEART: SYNTHESIS OF STEAROYLCARNITINE FROM PERFUSED PALMITATE

Author

Janos Kerner, Edward J. Lesnefsky, Paul E. Minkler, and Charles L. Hoppel

Subjects

Biophysics, Palmitates, Endogeny, Mitochondrion, Biology, Biochemistry, Article, chemistry.chemical_compound, Structural Biology, Fatty acid elongation, Carnitine, Genetics, medicine, Lipolysis, Animals, Molecular Biology, Palmitoylcarnitine, Chromatography, High Pressure Liquid, chemistry.chemical_classification, Myocardium, Fatty Acids, Fatty acid, Heart, Cell Biology, Stearoylcarnitine, Rats, Inbred F344, Mitochondria, Rats, Perfusion, Glucose, chemistry, medicine.drug

Abstract

Rat hearts perfused for up to 60 min in the working mode with palmitate, but not with glucose, resulted in substantial formation of palmitoylcarnitine and stearoylcarnitine. To test whether lipolysis of endogenous lipids was responsible for the increased stearoylcarnitine content or whether some of the perfused palmitate underwent chain elongation, hearts were perfused with hexadecanoic-16,16,16-d3 acid (M+3). The pentafluorophenacyl ester of deuterium labeled stearoylcarnitine had an M+3 (639.4 m/z) compared to the unlabeled M+0 (636.3 m/z) consistent with a direct chain elongation of the perfused palmitate. Furthermore, the near equal isotope enrichment of palmitoyl- (90.2 ± 5.8%) and stearoylcarnitine (78.0 ± 7.1%) suggest that both palmitoyl- and stearoyl-CoA have ready access to mitochondrial carnitine palmitoyltransferase and that most of the stearoylcarnitine is derived from the perfused palmitate.

Published

2007

50. Fatty acid oxidation in cardiac and skeletal muscle mitochondria is unaffected by deletion of CD36

Author

Kristen L. King, Charles L. Hoppel, Maria Febbraio, Mariana G. Rosca, William C. Stanley, and Janos Kerner

Subjects

CD36 Antigens, Male, CD36, Biophysics, Biology, Mitochondrion, Biochemistry, Mitochondria, Heart, Article, Mice, parasitic diseases, medicine, Animals, Molecular Biology, Beta oxidation, Cells, Cultured, chemistry.chemical_classification, Mice, Knockout, Fatty Acids, Wild type, Fatty acid, Skeletal muscle, hemic and immune systems, Transport protein, Mitochondria, Muscle, medicine.anatomical_structure, chemistry, Lipotoxicity, biology.protein, Oxidation-Reduction, Gene Deletion, circulatory and respiratory physiology

Abstract

Recent studies found that the plasma membrane fatty acid transport protein CD36 also resides in mitochondrial membranes in cardiac and skeletal muscle. Pharmacological studies suggest that CD36 may play an essential role in mitochondrial fatty acid oxidation. We isolated cardiac and skeletal muscle mitochondria from wild type and CD36 knock-out mice. There were no differences between wild type and CD36 knock-out mice in mitochondrial respiration with palmitoyl-CoA, palmitoyl-carnitine or glutamate as substrate. We investigated a potential alternative role for CD36 in mitochondria, i.e. the export of fatty acids generated in the matrix. Palmitate export was not different between wild type and CD36 knock-out mice. Taken together, CD36 does not appear to play an essential role in mitochondrial uptake of fatty acids or export of fatty acid anions.

Published

2007