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7. N[sup ε]-(γ-l-Glutamyl)-l-lysine (GGEL) is increased in cerebrospinal fluid of patients with Huntington's disease.

Author

Jeitner, T.M., Bogdanov, M.B., Matson, W.R., Daikhin, Y., Yudkoff, M., Folk, J.E., Steinman, L., Browne, S.E., Beal, M.F., Blass, J., and Cooper, A.J.L.

Subjects
HUNTINGTON disease, CEREBROSPINAL fluid, TRANSGLUTAMINASES
Abstract

Pathological-length polyglutamine (Q[sub n]) expansions, such as those that occur in the huntingtin protein (htt) in Huntington's disease (HD), are excellent substrates for tissue transglutaminase in vitro, and transglutaminase activity is increased in post-mortem HD brain. However, direct evidence for the participation of tissue transglutaminase (or other transglutaminases) in HD patients in vivo is scarce. We now report that levels of N[sup ε]-(γ-l-glutamyl)-l-lysine (GGEL) – a ‘marker’ isodipeptide produced by the transglutaminase reaction – are elevated in the CSF of HD patients (708 ± 41 pmol/mL, SEM, n = 36) vs. control CSF (228 ± 36, n = 27); p < 0.0001. These data support the hypothesis that transglutaminase activity is increased in HD brain in vivo. [ABSTRACT FROM AUTHOR]

Published
2001
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8. Alanine metabolism in the perfused rat liver. Studies with (15)N.

Author

Brosnan, J T, Brosnan, M E, Yudkoff, M, Nissim, I, Daikhin, Y, Lazarow, A, Horyn, O, and Nissim, I

Abstract

We have utilized [(15)N]alanine or (15)NH(3) as metabolic tracers in order to identify sources of nitrogen for hepatic ureagenesis in a liver perfusion system. Studies were done in the presence and absence of physiologic concentrations of portal venous ammonia in order to test the hypothesis that, when the NH(4)(+):aspartate ratio is >1, increased hepatic proteolysis provides cytoplasmic aspartate in order to support ureagenesis. When 1 mm [(15)N]alanine was the sole nitrogen source, the amino group was incorporated into both nitrogens of urea and both nitrogens of glutamine. However, when studies were done with 1 mm alanine and 0.3 mm NH(4)Cl, alanine failed to provide aspartate at a rate that would have detoxified all administered ammonia. Under these circumstances, the presence of ammonia at a physiologic concentration stimulated hepatic proteolysis. In perfusions with alanine alone, approximately 400 nmol of nitrogen/min/g liver was needed to satisfy the balance between nitrogen intake and nitrogen output. When the model included alanine and NH(4)Cl, 1000 nmol of nitrogen/min/g liver were formed from an intra-hepatic source, presumably proteolysis. In this manner, the internal pool provided the cytoplasmic aspartate that allowed the liver to dispose of mitochondrial carbamyl phosphate that was rapidly produced from external ammonia. This information may be relevant to those clinical situations (renal failure, cirrhosis, starvation, low protein diet, and malignancy) when portal venous NH(4)(+) greatly exceeds the concentration of aspartate. Under these circumstances, the liver must summon internal pools of protein in order to accommodate the ammonia burden.

Published
2001
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10. Tricarboxylic acid cycle in rat brain synaptosomes. Fluxes and interactions with aspartate aminotransferase and malate/aspartate shuttle.

Author

Yudkoff, M, Nelson, D, Daikhin, Y, and Erecińska, M

Abstract

The flux through different segments of the tricarboxylic acid cycle was measured in rat brain synaptosomes with gas chromatography-mass spectrometry using either deuterated glutamine or [13C]aspartate. The flux between 2-oxoglutarate and oxaloacetate was estimated to be 3.14 and 4.97 nmol/min/mg protein with and without glucose, respectively. These values were 3-5-fold faster than the flux between oxaloacetate and 2-oxoglutarate (0.92 nmol/min per mg protein) measured in the presence of glucose. The pattern of intermediates labeling suggests that the overall rate-controlling reaction involves either citrate synthase or pyruvate dehydrogenase but not 2-oxoglutarate or isocitrate dehydrogenase. The enrichment in [3,3,4,4-2H4]glutamate from [2,3,3,4,4-2H5]glutamine was as rapid as in [2,3,3,4,4-2H5]glutamate, which indicates that the aspartate aminotransferase reaction is severalfold faster than the flux through the tricarboxylic acid cycle. [13C]Aspartate was rapidly converted to [13C]malate, suggesting that in intact synaptosomes aspartate entry into the mitochondrion is very slow. The finding that aspartate is taken up by mitochondria as malate, along with the observed high enrichment in [3-2H]malate (from [2,3,3,4,4-2H5]glutamine), is consistent with the substantial synaptosomal activity of the malate/aspartate shuttle.

Published
1994
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12. Regulation of brain glutamate metabolism by nitric oxide and S-nitrosylation.

Author

Raju K, Doulias PT, Evans P, Krizman EN, Jackson JG, Horyn O, Daikhin Y, Nissim I, Yudkoff M, Nissim I, Sharp KA, Robinson MB, and Ischiropoulos H

Subjects
Amino Acid Sequence, Animals, Blotting, Western, Chromatography, Liquid, Cysteine analogs & derivatives, Cysteine genetics, Excitatory Amino Acid Transporter 2 genetics, Excitatory Amino Acid Transporter 2 metabolism, Glutamine metabolism, HEK293 Cells, Humans, Male, Mice, Inbred C57BL, Mice, Knockout, Molecular Sequence Data, Mutation, Nitric Oxide Synthase Type I genetics, Nitric Oxide Synthase Type I metabolism, Nitric Oxide Synthase Type III genetics, Nitric Oxide Synthase Type III metabolism, Proteome metabolism, Proteomics methods, Rats, S-Nitrosothiols metabolism, Tandem Mass Spectrometry, Brain metabolism, Cysteine metabolism, Glutamic Acid metabolism, Nitric Oxide metabolism
Abstract

Nitric oxide (NO) is a signaling intermediate during glutamatergic neurotransmission in the central nervous system (CNS). NO signaling is in part accomplished through cysteine S-nitrosylation, a posttranslational modification by which NO regulates protein function and signaling. In our investigation of the protein targets and functional impact of S-nitrosylation in the CNS under physiological conditions, we identified 269 S-nitrosocysteine residues in 136 proteins in the wild-type mouse brain. The number of sites was significantly reduced in the brains of mice lacking endothelial nitric oxide synthase (eNOS(-/-)) or neuronal nitric oxide synthase (nNOS(-/-)). In particular, nNOS(-/-) animals showed decreased S-nitrosylation of proteins that participate in the glutamate/glutamine cycle, a metabolic process by which synaptic glutamate is recycled or oxidized to provide energy. (15)N-glutamine-based metabolomic profiling and enzymatic activity assays indicated that brain extracts from nNOS(-/-) mice converted less glutamate to glutamine and oxidized more glutamate than those from mice of the other genotypes. GLT1 [also known as EAAT2 (excitatory amino acid transporter 2)], a glutamate transporter in astrocytes, was S-nitrosylated at Cys(373) and Cys(561) in wild-type and eNOS(-/-) mice, but not in nNOS(-/-) mice. A form of rat GLT1 that could not be S-nitrosylated at the equivalent sites had increased glutamate uptake compared to wild-type GLT1 in cells exposed to an S-nitrosylating agent. Thus, NO modulates glutamatergic neurotransmission through the selective, nNOS-dependent S-nitrosylation of proteins that govern glutamate transport and metabolism., (Copyright © 2015, American Association for the Advancement of Science.)

Published
2015
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13. Engineering the gut microbiota to treat hyperammonemia.

Author

Shen TC, Albenberg L, Bittinger K, Chehoud C, Chen YY, Judge CA, Chau L, Ni J, Sheng M, Lin A, Wilkins BJ, Buza EL, Lewis JD, Daikhin Y, Nissim I, Yudkoff M, Bushman FD, and Wu GD

Subjects
Ammonia metabolism, Animals, Bacteria enzymology, Bacteria genetics, Bacterial Proteins genetics, Bacterial Proteins metabolism, Bioengineering, Chemical and Drug Induced Liver Injury therapy, Digestive System metabolism, Disease Models, Animal, Feces microbiology, Female, Genes, Bacterial, Hyperammonemia metabolism, Male, Mice, Mice, Inbred C57BL, Mice, SCID, Time Factors, Urease genetics, Urease metabolism, Biological Therapy methods, Digestive System microbiology, Hyperammonemia microbiology, Hyperammonemia therapy, Microbiota physiology
Abstract

Increasing evidence indicates that the gut microbiota can be altered to ameliorate or prevent disease states, and engineering the gut microbiota to therapeutically modulate host metabolism is an emerging goal of microbiome research. In the intestine, bacterial urease converts host-derived urea to ammonia and carbon dioxide, contributing to hyperammonemia-associated neurotoxicity and encephalopathy in patients with liver disease. Here, we engineered murine gut microbiota to reduce urease activity. Animals were depleted of their preexisting gut microbiota and then inoculated with altered Schaedler flora (ASF), a defined consortium of 8 bacteria with minimal urease gene content. This protocol resulted in establishment of a persistent new community that promoted a long-term reduction in fecal urease activity and ammonia production. Moreover, in a murine model of hepatic injury, ASF transplantation was associated with decreased morbidity and mortality. These results provide proof of concept that inoculation of a prepared host with a defined gut microbiota can lead to durable metabolic changes with therapeutic utility.

Published
2015
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14. Augmenting ureagenesis in patients with partial carbamyl phosphate synthetase 1 deficiency with N-carbamyl-L-glutamate.

Author

Ah Mew N, McCarter R, Daikhin Y, Lichter-Konecki U, Nissim I, Yudkoff M, and Tuchman M

Subjects
Adolescent, Adult, Ammonia blood, Carbamoyl-Phosphate Synthase I Deficiency Disease blood, Child, Child, Preschool, Female, Humans, Linear Models, Male, Mass Spectrometry, Treatment Outcome, Young Adult, Carbamoyl-Phosphate Synthase I Deficiency Disease drug therapy, Glutamates therapeutic use, Glutamine blood, Urea metabolism
Abstract

Identical studies using stable isotopes were performed before and after a 3-day trial of oral N-carbamyl-l-glutamate (NCG) in 5 subjects with late-onset carbamyl phosphate synthetase deficiency. NCG augmented ureagenesis and decreased plasma ammonia in 4 of 5 subjects. There was marked improvement in nitrogen metabolism with long-term NCG administration in 1 subject., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published
2014
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15. The molecular and metabolic influence of long term agmatine consumption.

Author

Nissim I, Horyn O, Daikhin Y, Chen P, Li C, Wehrli SL, Nissim I, and Yudkoff M

Subjects
Agmatine pharmacokinetics, Animals, Biological Transport, Active drug effects, Carnitine analogs & derivatives, Carnitine metabolism, Dietary Fats adverse effects, Dietary Fats pharmacology, Gene Expression Regulation drug effects, Humans, Male, Metabolome, Obesity chemically induced, Obesity metabolism, Oxidation-Reduction drug effects, PPAR gamma biosynthesis, Peroxisome Proliferator-Activated Receptor Gamma Coactivator 1-alpha, Rats, Rats, Sprague-Dawley, Time Factors, Transcription Factors biosynthesis, Agmatine pharmacology, Cyclic AMP metabolism, Fatty Acids metabolism, Gluconeogenesis drug effects, Liver metabolism, Obesity drug therapy
Abstract

Agmatine (AGM), a product of arginine decarboxylation, influences multiple physiologic and metabolic functions. However, the mechanism(s) of action, the impact on whole body gene expression and metabolic pathways, and the potential benefits and risks of long term AGM consumption are still a mystery. Here, we scrutinized the impact of AGM on whole body metabolic profiling and gene expression and assessed a plausible mechanism(s) of AGM action. Studies were performed in rats fed a high fat diet or standard chow. AGM was added to drinking water for 4 or 8 weeks. We used (13)C or (15)N tracers to assess metabolic reactions and fluxes and real time quantitative PCR to determine gene expression. The results demonstrate that AGM elevated the synthesis and tissue level of cAMP. Subsequently, AGM had a widespread impact on gene expression and metabolic profiling including (a) activation of peroxisomal proliferator-activated receptor-α and its coactivator, PGC1α, and (b) increased expression of peroxisomal proliferator-activated receptor-γ and genes regulating thermogenesis, gluconeogenesis, and carnitine biosynthesis and transport. The changes in gene expression were coupled with improved tissue and systemic levels of carnitine and short chain acylcarnitine, increased β-oxidation but diminished incomplete fatty acid oxidation, decreased fat but increased protein mass, and increased hepatic ureagenesis and gluconeogenesis but decreased glycolysis. These metabolic changes were coupled with reduced weight gain and a curtailment of the hormonal and metabolic derangements associated with high fat diet-induced obesity. The findings suggest that AGM elevated the synthesis and levels of cAMP, thereby mimicking the effects of caloric restriction with respect to metabolic reprogramming.

Published
2014
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16. Regulation of glucagon secretion in normal and diabetic human islets by γ-hydroxybutyrate and glycine.

Author

Li C, Liu C, Nissim I, Chen J, Chen P, Doliba N, Zhang T, Nissim I, Daikhin Y, Stokes D, Yudkoff M, Bennett MJ, Stanley CA, Matschinsky FM, and Naji A

Subjects
Adult, Diabetes Mellitus, Type 2 pathology, Female, Glucagon-Secreting Cells pathology, Humans, Insulin-Secreting Cells pathology, Male, Middle Aged, Receptors, GABA metabolism, Receptors, Glycine metabolism, gamma-Aminobutyric Acid metabolism, Diabetes Mellitus, Type 2 metabolism, Glucagon metabolism, Glucagon-Secreting Cells metabolism, Glucose metabolism, Glycine metabolism, Insulin-Secreting Cells metabolism, Sodium Oxybate metabolism
Abstract

Paracrine signaling between pancreatic islet β-cells and α-cells has been proposed to play a role in regulating glucagon responses to elevated glucose and hypoglycemia. To examine this possibility in human islets, we used a metabolomic approach to trace the responses of amino acids and other potential neurotransmitters to stimulation with [U-(13)C]glucose in both normal individuals and type 2 diabetics. Islets from type 2 diabetics uniformly showed decreased glucose stimulation of insulin secretion and respiratory rate but demonstrated two different patterns of glucagon responses to glucose: one group responded normally to suppression of glucagon by glucose, but the second group was non-responsive. The non-responsive group showed evidence of suppressed islet GABA levels and of GABA shunt activity. In further studies with normal human islets, we found that γ-hydroxybutyrate (GHB), a potent inhibitory neurotransmitter, is generated in β-cells by an extension of the GABA shunt during glucose stimulation and interacts with α-cell GHB receptors, thus mediating the suppressive effect of glucose on glucagon release. We also identified glycine, acting via α-cell glycine receptors, as the predominant amino acid stimulator of glucagon release. The results suggest that glycine and GHB provide a counterbalancing receptor-based mechanism for controlling α-cell secretory responses to metabolic fuels.

Published
2013
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17. Effects of a glucokinase activator on hepatic intermediary metabolism: study with 13C-isotopomer-based metabolomics.

Author

Nissim I, Horyn O, Nissim I, Daikhin Y, Wehrli SL, Yudkoff M, and Matschinsky FM

Subjects
Animals, Enzyme Activation drug effects, Enzyme Activation physiology, Hepatocytes drug effects, Liver drug effects, Liver enzymology, Male, Rats, Rats, Sprague-Dawley, Benzeneacetamides pharmacology, Glucokinase metabolism, Hepatocytes enzymology, Metabolomics methods
Abstract

GKAs (glucokinase activators) are promising agents for the therapy of Type 2 diabetes, but little is known about their effects on hepatic intermediary metabolism. We monitored the fate of (13)C-labelled glucose in both a liver perfusion system and isolated hepatocytes. MS and NMR spectroscopy were deployed to measure isotopic enrichment. The results demonstrate that the stimulation of glycolysis by GKA led to numerous changes in hepatic metabolism: (i) augmented flux through the TCA (tricarboxylic acid) cycle, as evidenced by greater incorporation of (13)C into the cycle (anaplerosis) and increased generation of (13)C isotopomers of citrate, glutamate and aspartate (cataplerosis); (ii) lowering of hepatic [Pi] and elevated [ATP], denoting greater phosphorylation potential and energy state; (iii) stimulation of glycogen synthesis from glucose, but inhibition of glycogen synthesis from 3-carbon precursors; (iv) increased synthesis of N-acetylglutamate and consequently augmented ureagenesis; (v) increased synthesis of glutamine, alanine, serine and glycine; and (vi) increased production and outflow of lactate. The present study provides a deeper insight into the hepatic actions of GKAs and uncovers the potential benefits and risks of GKA for treatment of diabetes. GKA improved hepatic bioenergetics, ureagenesis and glycogenesis, but decreased gluconeogenesis with a potential risk of lactic acidosis and fatty liver.

Published
2012
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18. N-carbamylglutamate enhancement of ureagenesis leads to discovery of a novel deleterious mutation in a newly defined enhancer of the NAGS gene and to effective therapy.

Author

Heibel SK, Ah Mew N, Caldovic L, Daikhin Y, Yudkoff M, and Tuchman M

Subjects
Adolescent, Alleles, Base Sequence, Binding Sites, Cell Line, Tumor, Child, Female, Gene Frequency, Glutamates metabolism, Hep G2 Cells, Hepatocyte Nuclear Factor 1 metabolism, Humans, Nucleotide Motifs, Polymorphism, Single Nucleotide, Sequence Alignment, Treatment Outcome, Urea Cycle Disorders, Inborn metabolism, Amino-Acid N-Acetyltransferase genetics, Enhancer Elements, Genetic, Glutamates therapeutic use, Sequence Deletion, Urea Cycle Disorders, Inborn drug therapy, Urea Cycle Disorders, Inborn genetics
Abstract

N-acetylglutamate synthase (NAGS) catalyzes the conversion of glutamate and acetyl-CoA to NAG, the essential allosteric activator of carbamyl phosphate synthetase I, the first urea cycle enzyme in mammals. A 17-year-old female with recurrent hyperammonemia attacks, the cause of which remained undiagnosed for 8 years in spite of multiple molecular and biochemical investigations, showed markedly enhanced ureagenesis (measured by isotope incorporation) in response to N-carbamylglutamate (NCG). This led to sequencing of the regulatory regions of the NAGS gene and identification of a deleterious single-base substitution in the upstream enhancer. The homozygous mutation (c.-3064C>A), affecting a highly conserved nucleotide within the hepatic nuclear factor 1 (HNF-1) binding site, was not found in single nucleotide polymorphism databases and in a screen of 1,086 alleles from a diverse population. Functional assays demonstrated that this mutation decreases transcription and binding of HNF-1 to the NAGS gene, while a consensus HNF-1 binding sequence enhances binding to HNF-1 and increases transcription. Oral daily NCG therapy restored ureagenesis in this patient, normalizing her biochemical markers, and allowing discontinuation of alternate pathway therapy and normalization of her diet with no recurrence of hyperammonemia. Inc., (© 2011 Wiley-Liss, Inc.)

Published
2011
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19. Down-regulation of hepatic urea synthesis by oxypurines: xanthine and uric acid inhibit N-acetylglutamate synthase.

Author

Nissim I, Horyn O, Nissim I, Daikhin Y, Caldovic L, Barcelona B, Cervera J, Tuchman M, and Yudkoff M

Subjects
1-Methyl-3-isobutylxanthine pharmacology, Amino-Acid N-Acetyltransferase isolation & purification, Amino-Acid N-Acetyltransferase metabolism, Animals, Carbamoyl-Phosphate Synthase (Ammonia) isolation & purification, Carbamoyl-Phosphate Synthase (Ammonia) metabolism, Citrulline biosynthesis, Dose-Response Relationship, Drug, Glutamates biosynthesis, Hepatocytes drug effects, Hepatocytes metabolism, Kinetics, Liver cytology, Liver enzymology, Male, Mice, Mitochondria drug effects, Mitochondria metabolism, Rats, Rats, Sprague-Dawley, Amino-Acid N-Acetyltransferase antagonists & inhibitors, Down-Regulation drug effects, Liver metabolism, Urea metabolism, Uric Acid pharmacology, Xanthine pharmacology
Abstract

We previously reported that isobutylmethylxanthine (IBMX), a derivative of oxypurine, inhibits citrulline synthesis by an as yet unknown mechanism. Here, we demonstrate that IBMX and other oxypurines containing a 2,6-dione group interfere with the binding of glutamate to the active site of N-acetylglutamate synthetase (NAGS), thereby decreasing synthesis of N-acetylglutamate, the obligatory activator of carbamoyl phosphate synthase-1 (CPS1). The result is reduction of citrulline and urea synthesis. Experiments were performed with (15)N-labeled substrates, purified hepatic CPS1, and recombinant mouse NAGS as well as isolated mitochondria. We also used isolated hepatocytes to examine the action of various oxypurines on ureagenesis and to assess the ameliorating affect of N-carbamylglutamate and/or l-arginine on NAGS inhibition. Among various oxypurines tested, only IBMX, xanthine, or uric acid significantly increased the apparent K(m) for glutamate and decreased velocity of NAGS, with little effect on CPS1. The inhibition of NAGS is time- and dose-dependent and leads to decreased formation of the CPS1-N-acetylglutamate complex and consequent inhibition of citrulline and urea synthesis. However, such inhibition was reversed by supplementation with N-carbamylglutamate. The data demonstrate that xanthine and uric acid, both physiologically occurring oxypurines, inhibit the hepatic synthesis of N-acetylglutamate. An important and novel concept emerging from this study is that xanthine and/or uric acid may have a role in the regulation of ureagenesis and, thus, nitrogen homeostasis in normal and disease states.

Published
2011
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20. N-carbamylglutamate augments ureagenesis and reduces ammonia and glutamine in propionic acidemia.

Author

Ah Mew N, McCarter R, Daikhin Y, Nissim I, Yudkoff M, and Tuchman M

Subjects
Administration, Oral, Adolescent, Ammonia metabolism, Blood Chemical Analysis, Child, Child, Preschool, Confidence Intervals, Dose-Response Relationship, Drug, Drug Administration Schedule, Female, Follow-Up Studies, Glutamine metabolism, Humans, Infant, Male, Probability, Prospective Studies, Risk Assessment, Treatment Outcome, Urea metabolism, Ammonia blood, Glutamates administration & dosage, Glutamine blood, Propionic Acidemia diagnosis, Propionic Acidemia drug therapy, Urea blood
Abstract

Objectives: The objective of this study was to determine whether N-carbamylglutamate (NCG) reduces plasma levels of ammonia and glutamine and increases the rate of ureagenesis in patients with propionic acidemia (PA)., Methods: Identical 4-hour studies were performed before and immediately after a 3-day trial of oral NCG in 7 patients with PA. An oral bolus of [(13)C]sodium acetate was administered at the start of each study, and sequential blood samples were obtained to measure [(13)C]urea, ammonia, urea, and amino acids., Results: With longitudinal mixed-effects linear regression, peak [(13)C]urea increased after treatment with NCG (from 2.2 to 3.8 microM; P < .0005). There were concomitant decreases in mean plasma ammonia (59-43 microM; P < .018) and glutamine (552-331 microM; P < .0005)., Conclusions: NCG augments ureagenesis and decreases plasma ammonia and glutamine in patients with PA. The drug may serve as an important therapeutic adjunct in the treatment of acute hyperammonemia in this disorder.

Published
2010
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21. Measuring in vivo ureagenesis with stable isotopes.

Author

Yudkoff M, Ah Mew N, Daikhin Y, Horyn O, Nissim I, Nissim I, Payan I, and Tuchman M

Subjects
Amino-Acid N-Acetyltransferase deficiency, Amino-Acid N-Acetyltransferase metabolism, Ammonium Chloride administration & dosage, Ammonium Chloride pharmacology, Carbon Dioxide metabolism, Carbon Isotopes metabolism, Humans, Urea blood, Isotope Labeling methods, Urea metabolism
Abstract

Stable isotopes have been an invaluable adjunct to biomedical research for more than 70years. Indeed, the isotopic approach has revolutionized our understanding of metabolism, revealing it to be an intensely dynamic process characterized by an unending cycle of synthesis and degradation. Isotopic studies have taught us that the urea cycle is intrinsic to such dynamism, since it affords a capacious mechanism by which to eliminate waste nitrogen when rates of protein degradation (or dietary protein intake) are especially high. Isotopes have enabled an appreciation of the degree to which ureagenesis is compromised in patients with urea cycle defects. Indeed, isotopic studies of urea cycle flux correlate well with the severity of cognitive impairment in these patients. Finally, the use of isotopes affords an ideal tool with which to gauge the efficacy of therapeutic interventions to augment residual flux through the cycle., (Copyright 2010 Elsevier Inc. All rights reserved.)

Published
2010
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22. Effects of a single dose of N-carbamylglutamate on the rate of ureagenesis.

Author

Ah Mew N, Payan I, Daikhin Y, Nissim I, Nissim I, Tuchman M, and Yudkoff M

Subjects
Adult, Amino Acids blood, Blood Glucose drug effects, Carbon Dioxide metabolism, Carbon Isotopes, Demography, Dose-Response Relationship, Drug, Exhalation drug effects, Female, Health, Humans, Infusions, Intravenous, Male, Sodium Bicarbonate administration & dosage, Sodium Bicarbonate pharmacology, Urea blood, Young Adult, Glutamates administration & dosage, Glutamates pharmacology, Urea metabolism
Abstract

We studied the effect on ureagenesis of a single dose of N-carbamylglutamate (NCG) in healthy young adults who received a constant infusion (300 min) of NaH(13)CO(3). Isotope ratio-mass spectrometry was used to measure the appearance of label in [(13)C]urea. At 90 min after initiating the H(13)CO3-infusion each subject took a single dose of NCG (50 mg/kg). In 5/6 studies the administration of NCG increased the formation of [(13)C]urea. Treatment with NCG significantly diminished the concentration of blood alanine, but not that of glutamine or arginine. The blood glucose concentration was unaffected by NCG administration. No untoward side effects were observed. The data indicate that treatment with NCG stimulates ureagenesis and could be useful in clinical settings of acute hyperammonemia of various etiologies.

Published
2009
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23. Ketosis and brain handling of glutamate, glutamine, and GABA.

Author

Yudkoff M, Daikhin Y, Horyn O, Nissim I, and Nissim I

Subjects
Animals, Diet, Ketogenic, Humans, Brain metabolism, Glutamic Acid metabolism, Glutamine metabolism, Ketosis metabolism, gamma-Aminobutyric Acid metabolism
Abstract

We hypothesize that one mechanism of the anti-epileptic effect of the ketogenic diet is to alter brain handling of glutamate. According to this formulation, in ketotic brain astrocyte metabolism is more active, resulting in enhanced conversion of glutamate to glutamine. This allows for: (a) more efficient removal of glutamate, the most important excitatory neurotransmitter; and (b) more efficient conversion of glutamine to GABA, the major inhibitory neurotransmitter.

Published
2008
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24. N-carbamylglutamate markedly enhances ureagenesis in N-acetylglutamate deficiency and propionic acidemia as measured by isotopic incorporation and blood biomarkers.

Author

Tuchman M, Caldovic L, Daikhin Y, Horyn O, Nissim I, Nissim I, Korson M, Burton B, and Yudkoff M

Subjects
Acetyl Coenzyme A metabolism, Adult, Amino Acids blood, Ammonia blood, Biomarkers blood, Carbon Dioxide metabolism, Carbon Isotopes, Child, Feasibility Studies, Female, Glutamates metabolism, Glutamates therapeutic use, Humans, Male, Metabolic Diseases drug therapy, Middle Aged, Glutamates deficiency, Glutamates pharmacology, Metabolic Diseases blood, Propionates blood, Urea blood
Abstract

N-acetylglutamate (NAG) is an endogenous essential cofactor for conversion of ammonia to urea in the liver. Deficiency of NAG causes hyperammonemia and occurs because of inherited deficiency of its producing enzyme, NAG synthase (NAGS), or interference with its function by short fatty acid derivatives. N-carbamylglutamate (NCG) can ameliorate hyperammonemia from NAGS deficiency and propionic and methylmalonic acidemia. We developed a stable isotope (13)C tracer method to measure ureagenesis and to evaluate the effect of NCG in humans. Seventeen healthy adults were investigated for the incorporation of (13)C label into urea. [(13)C]urea appeared in the blood within minutes, reaching maximum by 100 min, whereas breath (13)CO(2) reached a maximum by 60 min. A patient with NAGS deficiency showed very little urea labeling before treatment with NCG and normal labeling thereafter. Correspondingly, plasma levels of ammonia and glutamine decreased markedly and urea tripled after NCG treatment. Similarly, in a patient with propionic acidemia, NCG treatment resulted in a marked increase in urea labeling and decrease in glutamine, alanine, and glycine. These results provide a reliable method for measuring the effect of NCG on nitrogen metabolism and strongly suggest that NCG could be an effective treatment for inherited and secondary NAGS deficiency.

Published
2008
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25. Elimination of KATP channels in mouse islets results in elevated [U-13C]glucose metabolism, glutaminolysis, and pyruvate cycling but a decreased gamma-aminobutyric acid shunt.

Author

Li C, Nissim I, Chen P, Buettger C, Najafi H, Daikhin Y, Nissim I, Collins HW, Yudkoff M, Stanley CA, and Matschinsky FM

Subjects
Amino Acids chemistry, Animals, Gas Chromatography-Mass Spectrometry methods, Genotype, Glutamate Decarboxylase metabolism, Mice, Mice, Transgenic, Models, Biological, Oxygen metabolism, Adenosine Triphosphate chemistry, Glucose metabolism, Glutamine chemistry, Potassium chemistry, Pyruvates chemistry, gamma-Aminobutyric Acid metabolism
Abstract

Pancreatic beta cells are hyper-responsive to amino acids but have decreased glucose sensitivity after deletion of the sulfonylurea receptor 1 (SUR1) both in man and mouse. It was hypothesized that these defects are the consequence of impaired integration of amino acid, glucose, and energy metabolism in beta cells. We used gas chromatography-mass spectrometry methodology to study intermediary metabolism of SUR1 knock-out (SUR1(-/-)) and control mouse islets with d-[U-(13)C]glucose as substrate and related the results to insulin secretion. The levels and isotope labeling of alanine, aspartate, glutamate, glutamine, and gamma-aminobutyric acid (GABA) served as indicators of intermediary metabolism. We found that the GABA shunt of SUR1(-/-) islets is blocked by about 75% and showed that this defect is due to decreased glutamate decarboxylase synthesis, probably caused by elevated free intracellular calcium. Glutaminolysis stimulated by the leucine analogue d,l-beta-2-amino-2-norbornane-carboxylic acid was, however, enhanced in SUR1(-/-) and glyburide-treated SUR1(+/+) islets. Glucose oxidation and pyruvate cycling was increased in SUR1(-/-) islets at low glucose but was the same as in controls at high glucose. Malic enzyme isoforms 1, 2, and 3, involved in pyruvate cycling, were all expressed in islets. High glucose lowered aspartate and stimulated glutamine synthesis similarly in controls and SUR1(-/-) islets. The data suggest that the interruption of the GABA shunt and the lack of glucose regulation of pyruvate cycling may cause the glucose insensitivity of the SUR1(-/-) islets but that enhanced basal pyruvate cycling, lowered GABA shunt flux, and enhanced glutaminolytic capacity may sensitize the beta cells to amino acid stimulation.

Published
2008
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26. 3-isobutylmethylxanthine inhibits hepatic urea synthesis: protection by agmatine.

Author

Nissim I, Horyn O, Nissim I, Daikhin Y, Wehrli SL, and Yudkoff M

Subjects
Animals, Carbamoyl-Phosphate Synthase (Ammonia) metabolism, Cyclic AMP metabolism, Electron Transport drug effects, Male, Oxygen Consumption drug effects, Perfusion, Phosphoric Diester Hydrolases metabolism, Rats, Rats, Sprague-Dawley, 1-Methyl-3-isobutylxanthine pharmacology, Agmatine pharmacology, Liver metabolism, Mitochondria, Liver metabolism, Phosphodiesterase Inhibitors pharmacology, Urea metabolism
Abstract

We previously showed that agmatine stimulated hepatic ureagenesis. In this study, we sought to determine whether the action of agmatine is mediated via cAMP signaling. A pilot experiment demonstrated that the phosphodiesterase inhibitor, 3-isobutylmethylxanthine (IBMX), inhibited urea synthesis albeit increased [cAMP]. Thus, we hypothesized that IBMX inhibits hepatic urea synthesis independent of [cAMP]. We further theorized that agmatine would negate the IBMX action and improve ureagenesis. Experiments were carried out with isolated mitochondria and (15)NH(4)Cl to trace [(15)N]citrulline production or [5-(15)N]glutamine and a rat liver perfusion system to trace ureagenesis. The results demonstrate that IBMX induced the following: (i) inhibition of the mitochondrial respiratory chain and diminished O(2) consumption during liver perfusion; (ii) depletion of the phosphorylation potential and overall hepatic energetic capacity; (iii) inhibition of [(15)N]citrulline synthesis; and (iv) inhibition of urea output in liver perfusion with little effect on [N-acetylglutamate]. The results indicate that IBMX directly and specifically inhibited complex I of the respiratory chain and carbamoyl-phosphate synthase-I (CPS-I), with an EC(50) about 0.6 mm despite a significant elevation of hepatic [cAMP]. Perfusion of agmatine with IBMX stimulated O(2) consumption, restored hepatic phosphorylation potential, and significantly stimulated ureagenesis. The action of agmatine may signify a cascade effect initiated by increased oxidative phosphorylation and greater ATP synthesis. In addition, agmatine may prevent IBMX from binding to one or more active site(s) of CPS-I and thus protect against inhibition of CPS-I. Together, the data may suggest a new experimental application of IBMX in studies of CPS-I malfunction and the use of agmatine as intervention therapy.

Published
2008
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27. The ketogenic diet and brain metabolism of amino acids: relationship to the anticonvulsant effect.

Author

Yudkoff M, Daikhin Y, Melø TM, Nissim I, Sonnewald U, and Nissim I

Subjects
Anticonvulsants therapeutic use, Combined Modality Therapy, Diet, Glutamic Acid metabolism, Humans, Seizures diet therapy, Seizures drug therapy, Treatment Outcome, Amino Acids metabolism, Brain metabolism, Ketone Bodies metabolism, Ketosis metabolism, Seizures metabolism
Abstract

In many epileptic patients, anticonvulsant drugs either fail adequately to control seizures or they cause serious side effects. An important adjunct to pharmacologic therapy is the ketogenic diet, which often improves seizure control, even in patients who respond poorly to medications. The mechanisms that explain the therapeutic effect are incompletely understood. Evidence points to an effect on brain handling of amino acids, especially glutamic acid, the major excitatory neurotransmitter of the central nervous system. The diet may limit the availability of oxaloacetate to the aspartate aminotransferase reaction, an important route of brain glutamate handling. As a result, more glutamate becomes accessible to the glutamate decarboxylase reaction to yield gamma-aminobutyric acid (GABA), the major inhibitory neurotransmitter and an important antiseizure agent. In addition, the ketogenic diet appears to favor the synthesis of glutamine, an essential precursor to GABA. This occurs both because ketone body carbon is metabolized to glutamine and because in ketosis there is increased consumption of acetate, which astrocytes in the brain quickly convert to glutamine. The ketogenic diet also may facilitate mechanisms by which the brain exports to blood compounds such as glutamine and alanine, in the process favoring the removal of glutamate carbon and nitrogen.

Published
2007
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28. Evaluation of formulas for calculating total energy requirements of preadolescent children with cystic fibrosis.

Author

Trabulsi J, Ittenbach RF, Schall JI, Olsen IE, Yudkoff M, Daikhin Y, Zemel BS, and Stallings VA

Subjects
Anthropometry, Child, Child Development, Cystic Fibrosis complications, Cystic Fibrosis metabolism, Energy Intake physiology, Energy Metabolism physiology, Exocrine Pancreatic Insufficiency complications, Exocrine Pancreatic Insufficiency metabolism, Feces chemistry, Female, Growth physiology, Humans, Intestinal Absorption, Longitudinal Studies, Male, Nutrition Assessment, Nutritional Status, Weight Gain physiology, Cystic Fibrosis therapy, Exocrine Pancreatic Insufficiency therapy, Food, Formulated, Growth drug effects, Nutritional Requirements, Weight Gain drug effects
Abstract

Background: To support age-appropriate growth and to prevent and treat malnutrition in children with cystic fibrosis (CF), energy requirements for those children are often set above the requirements for healthy children. Care providers use one of several empirically derived formulas to calculate energy requirements, yet the validity of these formulas has seldom been tested., Objective: We evaluated 6 proposed formulas for calculating energy requirements in children with CF against a total energy requirement for children with CF (TER-CF) derived from measured total energy expenditure, fecal fat energy loss, and the theoretic energy required for age-appropriate tissue accretion., Design: Subjects were children aged 6-8 y who had CF and pancreatic insufficiency. Calculated TERs from each formula were evaluated against TER-CF by using summary statistics, regression analysis, and residual plots., Results: Subjects (n = 53) had suboptimal nutrition and growth status and mild-to-moderate lung disease. The formula that most closely (within 2%) approximated TER-CF was the estimated energy requirement (EER) formula at the active level (EERact). Regression analysis of TER-CF onto calculated TER from each formula yielded the best indexes of model fit for the EERact formula; residual plots of the EERact formula were tightly and normally distributed around zero., Conclusions: The EERact formula should be used to establish TER-CF in children in this age group who have mild-to-moderate CF. Changes in weight, height, and other indicators of nutritional status must be monitored to modify TER-CF as needed to support individual patient care goals.

Published
2007
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29. Energy balance and the accuracy of reported energy intake in preadolescent children with cystic fibrosis.

Author

Trabulsi J, Schall JI, Ittenbach RF, Olsen IE, Yudkoff M, Daikhin Y, Zemel BS, and Stallings VA

Subjects
Anthropometry, Child, Child Development, Child Nutrition Disorders etiology, Cohort Studies, Cystic Fibrosis complications, Feces chemistry, Female, Humans, Intestinal Absorption, Longitudinal Studies, Male, Nutritional Requirements, Nutritional Status, Prospective Studies, Weight Gain physiology, Child Nutrition Disorders prevention & control, Cystic Fibrosis metabolism, Energy Intake physiology, Energy Metabolism physiology, Growth physiology
Abstract

Background: Suboptimal growth and nutritional status are common among children with cystic fibrosis (CF) and pancreatic insufficiency (PI). A better understanding of energy balance is required to improve prevention and treatment of malnutrition., Objective: Our objective was to characterize energy balance and the reporting accuracy of dietary intake in children with CF by evaluating the relations between energy intake (EI), energy expenditure (EE), fecal energy loss, nutritional status, and growth., Design: The subjects were participants of a 24-mo prospective study of children 6-10 y of age with CF and PI. EE, EI, fecal energy loss, and anthropometric measures were obtained at baseline and at 24 mo., Results: The children (n = 69) had suboptimal growth at baseline (x +/- SD: weight-for-age z score, -0.53 +/- 1.19; adjusted height-for-age z score, -0.67 +/- 1.06; body mass index z score, -0.29 +/- 1.12), and these variables remained suboptimal at 24 mo. The median ratios of EI to EE at baseline and 24 mo were 1.15 and 1.18, respectively, which decreased to 1.09 and 1.10, respectively, when adjusted for fecal energy loss (EI(-FL):EE). At baseline, 7% of subjects were underreporters, 64% were accurate reporters, and 23% were overreporters of energy intake; the percentages were similar at 24 mo., Conclusions: Although EI(-FL):EE ratios were higher than expected at both baseline and 24 mo, this cohort showed only age-appropriate weight gain. Self-reported dietary intake data at the individual level should be interpreted with caution, and weight gain velocity may serve as an objective measure of long-term energy balance.

Published
2006
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30. Ifosfamide-induced nephrotoxicity: mechanism and prevention.

Author

Nissim I, Horyn O, Daikhin Y, Nissim I, Luhovyy B, Phillips PC, and Yudkoff M

Subjects
Acetaldehyde analogs & derivatives, Acetaldehyde pharmacokinetics, Agmatine pharmacology, Animals, Drug Interactions, Electron Transport Complex I antagonists & inhibitors, Electron Transport Complex I metabolism, Ifosfamide pharmacokinetics, Kidney Cortex enzymology, Kidney Cortex metabolism, Kidney Diseases enzymology, Male, Oxidative Phosphorylation drug effects, Rats, Antineoplastic Agents, Alkylating toxicity, Ifosfamide toxicity, Kidney Diseases chemically induced, Kidney Diseases prevention & control
Abstract

The efficacy of ifosfamide (IFO), an antineoplastic drug, is severely limited by a high incidence of nephrotoxicity of unknown etiology. We hypothesized that inhibition of complex I (C-I) by chloroacetaldehyde (CAA), a metabolite of IFO, is the chief cause of nephrotoxicity, and that agmatine (AGM), which we found to augment mitochondrial oxidative phosphorylation and beta-oxidation, would prevent nephrotoxicity. Our model system was isolated mitochondria obtained from the kidney cortex of rats treated with IFO or IFO + AGM. Oxidative phosphorylation was determined with electron donors specific to complexes I, II, III, or IV (C-I, C-II, C-III, or C-IV, respectively). A parallel study was done with (13)C-labeled pyruvate to assess metabolic dysfunction. Ifosfamide treatment significantly inhibited oxidative phosphorylation with only C-I substrates. Inhibition of C-I was associated with a significant elevation of [NADH], depletion of [NAD], and decreased flux through pyruvate dehydrogenase and the TCA cycle. However, administration of AGM with IFO increased [cyclic AMP (cAMP)] and prevented IFO-induced inhibition of C-I. In vitro studies with various metabolites of IFO showed that only CAA inhibited C-I, even with supplementation with 2-mercaptoethane sulfonic acid. Following IFO treatment daily for 5 days with 50 mg/kg, the level of CAA in the renal cortex was approximately 15 micromol/L. Taken together, these observations support the hypothesis that CAA is accumulated in renal cortex and is responsible for nephrotoxicity. AGM may be protective by increasing tissue [cAMP], which phosphorylates NADH:oxidoreductase. The current findings may have an important implication for the prevention of IFO-induced nephrotoxicity and/or mitochondrial diseases secondary to defective C-I.

Published
2006
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31. Effects of a GTP-insensitive mutation of glutamate dehydrogenase on insulin secretion in transgenic mice.

Author

Li C, Matter A, Kelly A, Petty TJ, Najafi H, MacMullen C, Daikhin Y, Nissim I, Lazarow A, Kwagh J, Collins HW, Hsu BY, Nissim I, Yudkoff M, Matschinsky FM, and Stanley CA

Subjects
Adenosine Diphosphate metabolism, Adenosine Triphosphate metabolism, Animals, Calcium Signaling drug effects, Glucose pharmacology, Glutamate Dehydrogenase antagonists & inhibitors, Glutamate Dehydrogenase metabolism, Glutamine pharmacology, Guanosine Triphosphate pharmacology, Humans, Hyperinsulinism enzymology, Hyperinsulinism genetics, Hyperinsulinism physiopathology, In Vitro Techniques, Insulin Secretion, Islets of Langerhans drug effects, Islets of Langerhans enzymology, Islets of Langerhans metabolism, Kinetics, Leucine pharmacology, Mice, Mice, Inbred C57BL, Mice, Transgenic, Models, Biological, Recombinant Proteins antagonists & inhibitors, Recombinant Proteins genetics, Recombinant Proteins metabolism, Glutamate Dehydrogenase genetics, Insulin metabolism, Mutation
Abstract

Glutamate dehydrogenase (GDH) plays an important role in insulin secretion as evidenced in children by gain of function mutations of this enzyme that cause a hyperinsulinism-hyperammonemia syndrome (GDH-HI) and sensitize beta-cells to leucine stimulation. GDH transgenic mice were generated to express the human GDH-HI H454Y mutation and human wild-type GDH in islets driven by the rat insulin promoter. H454Y transgene expression was confirmed by increased GDH enzyme activity in islets and decreased sensitivity to GTP inhibition. The H454Y GDH transgenic mice had hypoglycemia with normal growth rates. H454Y GDH transgenic islets were more sensitive to leucine- and glutamine-stimulated insulin secretion but had decreased response to glucose stimulation. The fluxes via GDH and glutaminase were measured by tracing 15N flux from [2-15N]glutamine. The H454Y transgene in islets had higher insulin secretion in response to glutamine alone and had 2-fold greater GDH flux. High glucose inhibited both glutaminase and GDH flux, and leucine could not override this inhibition. 15NH4Cl tracing studies showed 15N was not incorporated into glutamate in either H454Y transgenic or normal islets. In conclusion, we generated a GDH-HI disease mouse model that has a hypoglycemia phenotype and confirmed that the mutation of H454Y is disease causing. Stimulation of insulin release by the H454Y GDH mutation or by leucine activation is associated with increased oxidative deamination of glutamate via GDH. This study suggests that GDH functions predominantly in the direction of glutamate oxidation rather than glutamate synthesis in mouse islets and that this flux is tightly controlled by glucose.

Published
2006
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32. Short-term fasting, seizure control and brain amino acid metabolism.

Author

Yudkoff M, Daikhin Y, Nissim I, Horyn O, Luhovyy B, Lazarow A, and Nissim I

Subjects
Alanine biosynthesis, Alanine blood, Animals, Carbon Isotopes, Convulsants, Diet, Carbohydrate-Restricted, Energy Intake, Glucose administration & dosage, Pentylenetetrazole, Rats, Rats, Sprague-Dawley, Seizures chemically induced, Time Factors, Amino Acids metabolism, Brain metabolism, Fasting, Seizures metabolism, Seizures prevention & control
Abstract

The ketogenic diet is an effective treatment for seizures, but the mechanism of action is unknown. It is uncertain whether the anti-epileptic effect presupposes ketosis, or whether the restriction of calories and/or carbohydrate might be sufficient. We found that a relatively brief (24 h) period of low glucose and low calorie intake significantly attenuated the severity of seizures in young Sprague-Dawley rats (50-70 gms) in whom convulsions were induced by administration of pentylenetetrazole (PTZ). The blood glucose concentration was lower in animals that received less dietary glucose, but the brain glucose level did not differ from control blood [3-OH-butyrate] tended to be higher in blood, but not in brain, of animals on a low-glucose intake. The concentration in brain of glutamine increased and that of alanine declined significantly with low-glucose intake. The blood alanine level fell more than that of brain alanine, resulting in a marked increase ( approximately 50%) in the brain:blood ratio for alanine. In contrast, the brain:blood ratio for leucine declined by about 35% in the low-glucose group. When animals received [1-(13)C]glucose, a metabolic precursor of alanine, the appearance of (13)C in alanine and glutamine increased significantly relative to control. The brain:blood ratio for [(13)C]alanine exceeded 1, indicating that the alanine must have been formed in brain and not transported from blood. The elevated brain(alanine):blood(alanine) could mean that a component of the anti-epileptic effect of low carbohydrate intake is release of alanine from brain-to-blood, in the process abetting the disposal of glutamate, excess levels of which in the synaptic cleft would contribute to the development of seizures.

Published
2006
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33. Agmatine stimulates hepatic fatty acid oxidation: a possible mechanism for up-regulation of ureagenesis.

Author

Nissim I, Daikhin Y, Nissim I, Luhovyy B, Horyn O, Wehrli SL, and Yudkoff M

Subjects
Adenosine Diphosphate analysis, Adenosine Diphosphate metabolism, Adenosine Monophosphate analysis, Adenosine Monophosphate metabolism, Adenosine Triphosphate analysis, Adenosine Triphosphate metabolism, Agmatine pharmacology, Ammonia analysis, Ammonia metabolism, Animals, Carbon Isotopes, Citrulline biosynthesis, Dose-Response Relationship, Drug, Fasting, Gas Chromatography-Mass Spectrometry, Glutamates biosynthesis, Ketone Bodies biosynthesis, Kinetics, Liver cytology, Male, Mitochondria, Liver metabolism, Models, Biological, Nuclear Magnetic Resonance, Biomolecular, Oxidation-Reduction, Oxygen Consumption, Palmitic Acids metabolism, Perfusion, Rats, Rats, Sprague-Dawley, Urea analysis, Agmatine metabolism, Fatty Acids metabolism, Liver metabolism, Up-Regulation, Urea metabolism
Abstract

We demonstrated previously in a liver perfusion system that agmatine increases oxygen consumption as well as the synthesis of N-acetylglutamate and urea by an undefined mechanism. In this study our aim was to identify the mechanism(s) by which agmatine up-regulates ureagenesis. We hypothesized that increased oxygen consumption and N-acetylglutamate and urea synthesis are coupled to agmatine-induced stimulation of mitochondrial fatty acid oxidation. We used 13C-labeled fatty acid as a tracer in either a liver perfusion system or isolated mitochondria to monitor fatty acid oxidation and the incorporation of 13C-labeled acetyl-CoA into ketone bodies, tricarboxylic acid cycle intermediates, amino acids, and N-acetylglutamate. With [U-13C16] palmitate in the perfusate, agmatine significantly increased the output of 13C-labeled beta-hydroxybutyrate, acetoacetate, and CO2, indicating stimulated fatty acid oxidation. The stimulation of [U-13C16]palmitate oxidation was accompanied by greater production of urea and a higher 13C enrichment in glutamate, N-acetylglutamate, and aspartate. These observations suggest that agmatine leads to increased incorporation and flux of 13C-labeled acetyl-CoA in the tricarboxylic acid cycle and to increased utilization of 13C-labeled acetyl-CoA for synthesis of N-acetylglutamate. Experiments with isolated mitochondria and 13C-labeled octanoic acid also demonstrated that agmatine increased synthesis of 13C-labeled beta-hydroxybutyrate, acetoacetate, and N-acetylglutamate. The current data document that agmatine stimulates mitochondrial beta-oxidation and suggest a coupling between the stimulation of hepatic beta-oxidation and up-regulation of ureagenesis. This action of agmatine may be mediated via a second messenger such as cAMP, and the effects on ureagenesis and fatty acid oxidation may occur simultaneously and/or independently.

Published
2006
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34. Biosynthesis of agmatine in isolated mitochondria and perfused rat liver: studies with 15N-labelled arginine.

Author

Horyn O, Luhovyy B, Lazarow A, Daikhin Y, Nissim I, Yudkoff M, and Nissim I

Subjects
Animals, Cyclic AMP physiology, Glucagon physiology, In Vitro Techniques, Insulin physiology, Kinetics, Male, Nitrogen Isotopes, Oxygen Consumption, Rats, Agmatine metabolism, Carboxy-Lyases metabolism, Liver enzymology, Mitochondria, Liver enzymology
Abstract

An important but unresolved question is whether mammalian mitochondria metabolize arginine to agmatine by the ADC (arginine decarboxylase) reaction. 15N-labelled arginine was used as a precursor to address this question and to determine the flux through the ADC reaction in isolated mitochondria obtained from rat liver. In addition, liver perfusion system was used to examine a possible action of insulin, glucagon or cAMP on a flux through the ADC reaction. In mitochondria and liver perfusion, 15N-labelled agmatine was generated from external 15N-labelled arginine. The production of 15N-labelled agmatine was time- and dose-dependent. The time-course of [U-15N4]agmatine formation from 2 mM [U-15N4]arginine was best fitted to a one-phase exponential curve with a production rate of approx. 29 pmol x min(-1) x (mg of protein)(-1). Experiments with an increasing concentration (0- 40 mM) of [guanidino-15N2]arginine showed a Michaelis constant Km for arginine of 46 mM and a Vmax of 3.7 nmol x min(-1) x (mg of protein)(-1) for flux through the ADC reaction. Experiments with broken mitochondria showed little changes in Vmax or Km values, suggesting that mitochondrial arginine uptake had little effect on the observed Vmax or Km values. Experiments with liver perfusion demonstrated that over 95% of the effluent agmatine was derived from perfusate [guanidino-15N2]arginine regardless of the experimental condition. However, the output of 15N-labelled agmatine (nmol x min(-1) x g(-1)) increased by approx. 2-fold (P<0.05) in perfusions with cAMP. The findings of the present study provide compelling evidence that mitochondrial ADC is present in the rat liver, and suggest that cAMP may stimulate flux through this pathway.

Published
2005
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35. Brain amino acid requirements and toxicity: the example of leucine.

Author

Yudkoff M, Daikhin Y, Nissim I, Horyn O, Luhovyy B, Luhovyy B, Lazarow A, and Nissim I

Subjects
Adult, Animals, Humans, Leucine metabolism, Leucine physiology, Maple Syrup Urine Disease etiology, Maple Syrup Urine Disease genetics, Maple Syrup Urine Disease metabolism, Nutritional Requirements, Amino Acids, Branched-Chain metabolism, Amino Acids, Branched-Chain pharmacology, Amino Acids, Branched-Chain physiology, Brain drug effects, Brain metabolism, Brain physiology, Glutamic Acid biosynthesis, Glutamic Acid metabolism, Glutamic Acid physiology, Leucine toxicity
Abstract

Glutamic acid is an important excitatory neurotransmitter of the brain. Two key goals of brain amino acid handling are to maintain a very low intrasynaptic concentration of glutamic acid and also to provide the system with precursors from which to synthesize glutamate. The intrasynaptic glutamate level must be kept low to maximize the signal-to-noise ratio upon the release of glutamate from nerve terminals and to minimize the risk of excitotoxicity consequent to excessive glutamatergic stimulation of susceptible neurons. The brain must also provide neurons with a constant supply of glutamate, which both neurons and glia robustly oxidize. The branched-chain amino acids (BCAAs), particularly leucine, play an important role in this regard. Leucine enters the brain from the blood more rapidly than any other amino acid. Astrocytes, which are in close approximation to brain capillaries, probably are the initial site of metabolism of leucine. A mitochondrial branched-chain aminotransferase is very active in these cells. Indeed, from 30 to 50% of all alpha-amino groups of brain glutamate and glutamine are derived from leucine alone. Astrocytes release the cognate ketoacid [alpha-ketoisocaproate (KIC)] to neurons, which have a cytosolic branched-chain aminotransferase that reaminates the KIC to leucine, in the process consuming glutamate and providing a mechanism for the "buffering" of glutamate if concentrations become excessive. In maple syrup urine disease, or a congenital deficiency of branched-chain ketoacid dehydrogenase, the brain concentration of KIC and other branched-chain ketoacids can increase 10- to 20-fold. This leads to a depletion of glutamate and a consequent reduction in the concentration of brain glutamine, aspartate, alanine, and other amino acids. The result is a compromise of energy metabolism because of a failure of the malate-aspartate shuttle and a diminished rate of protein synthesis.

Published
2005
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36. The role of mitochondrially bound arginase in the regulation of urea synthesis: studies with [U-15N4]arginine, isolated mitochondria, and perfused rat liver.

Author

Nissim I, Luhovyy B, Horyn O, Daikhin Y, Nissim I, and Yudkoff M

Subjects
Animals, Cell Fractionation, In Vitro Techniques, Isoenzymes metabolism, Isoenzymes physiology, Male, Mitochondria, Liver metabolism, Perfusion, Rats, Rats, Sprague-Dawley, Arginase metabolism, Arginase physiology, Arginine analogs & derivatives, Arginine metabolism, Mitochondria, Liver chemistry, Mitochondria, Liver enzymology, Nitrogen Isotopes, Urea metabolism
Abstract

The main goal of the current study was to elucidate the role of mitochondrial arginine metabolism in the regulation of N-acetylglutamate and urea synthesis. We hypothesized that arginine catabolism via mitochondrially bound arginase augments ureagenesis by supplying ornithine for net synthesis of citrulline, glutamate, N-acetylglutamate, and aspartate. [U-(15)N(4)]arginine was used as precursor and isolated mitochondria or liver perfusion as a model system to monitor arginine catabolism and the incorporation of (15)N into various intermediate metabolites of the urea cycle. The results indicate that approximately 8% of total mitochondrial arginase activity is located in the matrix, and 90% is located in the outer membrane. Experiments with isolated mitochondria showed that approximately 60-70% of external [U-(15)N(4)]arginine catabolism was recovered as (15)N-labeled ornithine, glutamate, N-acetylglutamate, citrulline, and aspartate. The production of (15)N-labeled metabolites was time- and dose-dependent. During liver perfusion, urea containing one (U(m+1)) or two (U(m+2)) (15)N was generated from perfusate [U-(15)N(4)]arginine. The output of U(m+2) was between 3 and 8% of total urea, consistent with the percentage of activity of matrix arginase. U(m+1) was formed following mitochondrial production of [(15)N]glutamate from [alpha,delta-(15)N(2)]ornithine and transamination of [(15)N]glutamate to [(15)N]aspartate. The latter is transported to cytosol and incorporated into argininosuccinate. Approximately 70, 75, 7, and 5% of hepatic ornithine, citrulline, N-acetylglutamate, and aspartate, respectively, were derived from perfusate [U-(15)N(4)]arginine. The results substantiate the hypothesis that intramitochondrial arginase, presumably the arginase-II isozyme, may play an important role in the regulation of hepatic ureagenesis by furnishing ornithine for net synthesis of N-acetylglutamate, citrulline, and aspartate.

Published
2005
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37. Restoration of ureagenesis in N-acetylglutamate synthase deficiency by N-carbamylglutamate.

Author

Caldovic L, Morizono H, Daikhin Y, Nissim I, McCarter RJ, Yudkoff M, and Tuchman M

Subjects
Acetyltransferases genetics, Adolescent, Adult, Amino-Acid N-Acetyltransferase, Ammonia blood, Ammonium Chloride pharmacokinetics, Blood Urea Nitrogen, Female, Glutamine blood, Humans, Nitrogen Isotopes pharmacokinetics, Acetyltransferases deficiency, Glutamates therapeutic use, Urea metabolism
Abstract

In a patient with N-acetylglutamate synthase (NAGS) deficiency, incorporation of an isotopic label from ammonium chloride into urea was markedly reduced before treatment with N-carbamyl-L-glutamate (NCLG) and completely normalized following treatment. Blood ammonia rose following ammonium tracer ingestion before treatment but remained low following treatment. Serum urea concentration doubled following the treatment.

Published
2004
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38. A signaling role of glutamine in insulin secretion.

Author

Li C, Buettger C, Kwagh J, Matter A, Daikhin Y, Nissim IB, Collins HW, Yudkoff M, Stanley CA, and Matschinsky FM

Subjects
Ammonium Chloride pharmacokinetics, Animals, Calcium metabolism, Glutamine metabolism, Glyburide pharmacology, Hypoglycemic Agents pharmacology, Insulin Secretion, Islets of Langerhans drug effects, Mice, Mice, Knockout, Multidrug Resistance-Associated Proteins genetics, Nitrogen Isotopes, Potassium Channels, Inwardly Rectifying, Receptors, Drug, Signal Transduction drug effects, Sulfonylurea Receptors, ATP-Binding Cassette Transporters, Glutamine pharmacology, Insulin metabolism, Islets of Langerhans metabolism, Multidrug Resistance-Associated Proteins metabolism, Signal Transduction physiology
Abstract

Children with hypoglycemia due to recessive loss of function mutations of the beta-cell ATP-sensitive potassium (K(ATP)) channel can develop hypoglycemia in response to protein feeding. We hypothesized that amino acids might stimulate insulin secretion by unknown mechanisms, because the K(ATP) channel-dependent pathway of insulin secretion is defective. We therefore investigated the effects of amino acids on insulin secretion and intracellular calcium in islets from normal and sulfonylurea receptor 1 knockout (SUR1-/-) mice. Even though SUR1-/- mice are euglycemic, their islets are considered a suitable model for studies of the human genetic defect. SUR1-/- islets, but not normal islets, released insulin in response to an amino acid mixture ramp. This response to amino acids was decreased by 60% when glutamine was omitted. Insulin release by SUR1-/- islets was also stimulated by a ramp of glutamine alone. Glutamine was more potent than leucine or dimethyl glutamate. Basal intracellular calcium was elevated in SUR1-/- islets and was increased further by glutamine. In normal islets, methionine sulfoximine, a glutamine synthetase inhibitor, suppressed insulin release in response to a glucose ramp. This inhibition was reversed by glutamine or by 6-diazo-5-oxo-l-norleucine, a non-metabolizable glutamine analogue. High glucose doubled glutamine levels of islets. Methionine sulfoximine inhibition of glucose stimulated insulin secretion was associated with accumulation of glutamate and aspartate. We hypothesize that glutamine plays a critical role as a signaling molecule in amino acid- and glucose-stimulated insulin secretion, and that beta-cell depolarization and subsequent intracellular calcium elevation are required for this glutamine effect to occur.

Published
2004
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39. Ketogenic diet, brain glutamate metabolism and seizure control.

Author

Yudkoff M, Daikhin Y, Nissim I, Lazarow A, and Nissim I

Subjects
Amino Acids metabolism, Animals, Humans, Ketosis metabolism, Brain metabolism, Diet, Glutamic Acid metabolism, Ketone Bodies metabolism, Seizures metabolism, Seizures prevention & control
Abstract

We do not know the mode of action of the ketogenic diet in controlling epilepsy. One possibility is that the diet alters brain handling of glutamate, the major excitatory neurotransmitter and a probable factor in evoking and perpetuating a convulsion. We have found that brain metabolism of ketone bodies can furnish as much as 30% of glutamate and glutamine carbon. Ketone body metabolism also provides acetyl-CoA to the citrate synthetase reaction, in the process consuming oxaloacetate and thereby diminishing the transamination of glutamate to aspartate, a pathway in which oxaloacetate is a reactant. Relatively more glutamate then is available to the glutamate decarboxylase reaction, which increases brain [GABA]. Ketosis also increases brain [GABA] by increasing brain metabolism of acetate, which glia convert to glutamine. GABA-ergic neurons readily take up the latter amino acid and use it as a precursor to GABA. Ketosis also may be associated with altered amino acid transport at the blood-brain barrier. Specifically, ketosis may favor the release from brain of glutamine, which transporters at the blood-brain barrier exchange for blood leucine. Since brain glutamine is formed in astrocytes from glutamate, the overall effect will be to favor the release of glutamate from the nervous system.

Published
2004
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40. Role of the glutamate dehydrogenase reaction in furnishing aspartate nitrogen for urea synthesis: studies in perfused rat liver with 15N.

Author

Nissim I, Horyn O, Luhovyy B, Lazarow A, Daikhin Y, Nissim I, and Yudkoff M

Subjects
Amino Acids chemistry, Amino Acids metabolism, Ammonia chemistry, Ammonia metabolism, Animals, Aspartic Acid chemistry, Constriction, Freezing, Glutamate Dehydrogenase physiology, Glutamates metabolism, Glutamine chemistry, Glutamine metabolism, Liver metabolism, Male, Nitrogen Isotopes, Perfusion, Rats, Rats, Sprague-Dawley, Aspartic Acid metabolism, Glutamate Dehydrogenase metabolism, Liver enzymology, Nitrogen metabolism, Urea metabolism
Abstract

The present study was designed to determine: (i) the role of the reductive amination of alpha-ketoglutarate via the glutamate dehydrogenase reaction in furnishing mitochondrial glutamate and its transamination into aspartate; (ii) the relative incorporation of perfusate 15NH4Cl, [2-15N]glutamine or [5-15N]glutamine into carbamoyl phosphate and aspartate-N and, thereby, [15N]urea isotopomers; and (iii) the extent to which perfusate [15N]aspartate is taken up by the liver and incorporated into [15N]urea. We used a liver-perfusion system containing a physiological mixture of amino acids and ammonia similar to concentrations in vivo, with 15N label only in glutamine, ammonia or aspartate. The results demonstrate that in perfusions with a physiological mixture of amino acids, approx. 45 and 30% of total urea-N output was derived from perfusate ammonia and glutamine-N respectively. Approximately two-thirds of the ammonia utilized for carbamoyl phosphate synthesis was derived from perfusate ammonia and one-third from glutamine. Perfusate [2-15N]glutamine, [5-15N]glutamine or [15N]aspartate provided 24, 10 and 10% respectively of the hepatic aspartate-N pool, whereas perfusate 15NH4Cl provided approx. 37% of aspartate-N utilized for urea synthesis, secondary to the net formation of [15N]glutamate via the glutamate dehydrogenase reaction. The results suggest that the mitochondrial glutamate formed via the reductive amination of alpha-ketoglutarate may have a key role in ammonia detoxification by the following processes: (i) furnishing aspartate-N for ureagenesis; (ii) serving as a scavenger for excess ammonia; and (iii) improving the availability of the mitochondrial [glutamate] for synthesis of N -acetylglutamate. In addition, the current findings suggest that the formation of aspartate via the mitochondrial aspartate aminotransferase reaction may play an important role in the synthesis of cytosolic argininosuccinate.

Published
2003
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41. Metabolism of brain amino acids following pentylenetetrazole treatment.

Author

Yudkoff M, Daikhin Y, Nissim I, Horyn O, Lazarow A, and Nissim I

Subjects
Alanine metabolism, Amino Acids blood, Animals, Gas Chromatography-Mass Spectrometry, Glucose metabolism, Leucine metabolism, Male, Mice, Nitrogen metabolism, Prosencephalon drug effects, Prosencephalon metabolism, Seizures metabolism, Amino Acids metabolism, Brain Chemistry drug effects, Convulsants pharmacology, Pentylenetetrazole pharmacology
Abstract

We studied the effects of pentylenetetrazole (PTZ) on brain amino acid metabolism in mice. Administration of this convulsant did not change forebrain concentrations of amino acids, but when treated animals also received an injection of [15N]leucine, which served as a tracer of brain nitrogen metabolism, total (14N+15N) forebrain [leucine] exceeded control and [glutamate] and [aspartate] were less than control, as were forebrain concentrations of [15N]glutamate and [2-15N]glutamine. These data suggest greater uptake of [15N]leucine but diminished transamination of leucine to glutamate in experimental mice. In contrast to the [15N]leucine studies, which were associated with increased brain [leucine], the administration of [15N]alanine did not alter levels of alanine, glutamate or glutamine. However, label appeared in [2-15N]glutamine much more readily with [15N]alanine than with [15N]leucine as precursor and the ratio of enrichment in [2-15N]glutamine/[15N]alanine was much higher than that in [2-15N]glutamine/[15N]leucine, a finding that is compatible with preferential metabolism of alanine in astrocytes, which are the primary site of brain glutamine synthetase. We conclude that PTZ treatment favors the uptake of selected amino acids such as leucine but also diminishes transamination of leucine to yield glutamate via branched-chain amino acid transaminase. PTZ treatment may favor the "reverse" transamination of 2-keto-isocaproate (KIC), the ketoacid of leucine, to form leucine and to consume glutamate. A net result of these processes may be to enable the brain more readily to dispose of the glutamate that is released from neurons during convulsive activity.

Published
2003
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42. Regulation of leucine-stimulated insulin secretion and glutamine metabolism in isolated rat islets.

Author

Li C, Najafi H, Daikhin Y, Nissim IB, Collins HW, Yudkoff M, Matschinsky FM, and Stanley CA

Subjects
Adenosine Triphosphate metabolism, Animals, Cells, Cultured, Glutamate Dehydrogenase metabolism, Insulin Secretion, Islets of Langerhans drug effects, Kinetics, Male, Models, Biological, Perfusion, Rats, Rats, Wistar, Glutamine pharmacology, Insulin metabolism, Islets of Langerhans metabolism, Leucine pharmacology
Abstract

Glutamate dehydrogenase (GDH) is regulated by both positive (leucine and ADP) and negative (GTP and ATP) allosteric factors. We hypothesized that the phosphate potential of beta-cells regulates the sensitivity of leucine stimulation. These predictions were tested by measuring leucine-stimulated insulin secretion in perifused rat islets following glucose depletion and by tracing the nitrogen flux of [2-(15)N]glutamine using stable isotope techniques. The sensitivity of leucine stimulation was enhanced by long time (120-min) energy depletion and inhibited by glucose pretreatment. After limited 50-min glucose depletion, leucine, not alpha-ketoisocaproate, failed to stimulate insulin release. beta-Cells sensitivity to leucine is therefore proposed to be a function of GDH activation. Leucine increased the flux through GDH 3-fold compared with controls while causing insulin release. High glucose inhibited flux through both glutaminase and GDH, and leucine was unable to override this inhibition. These results clearly show that leucine induced the secretion of insulin by augmenting glutaminolysis through activating glutaminase and GDH. Glucose regulates beta-cell sensitivity to leucine by elevating the ratio of ATP and GTP to ADP and P(i) and thereby decreasing the flux through GDH and glutaminase. These mechanisms provide an explanation for hypoglycemia caused by mutations of GDH in children.

Published
2003
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43. Regulation of urea synthesis by agmatine in the perfused liver: studies with 15N.

Author

Nissim I, Horyn O, Daikhin Y, Nissim I, Lazarow A, and Yudkoff M

Subjects
Agmatine pharmacokinetics, Ammonium Chloride metabolism, Animals, Arginine pharmacology, Cytosol metabolism, Dose-Response Relationship, Drug, Glutamates metabolism, Glutamine metabolism, In Vitro Techniques, Liver chemistry, Male, Mitochondria, Liver metabolism, Nitric Oxide metabolism, Nitric Oxide Donors pharmacology, Nitrogen Isotopes metabolism, Oxygen Consumption, Rats, Rats, Sprague-Dawley, Agmatine metabolism, Arginine metabolism, Liver metabolism, Perfusion methods, Urea metabolism
Abstract

Administration of arginine or a high-protein diet increases the hepatic content of N-acetylglutamate (NAG) and the synthesis of urea. However, the underlying mechanism is unknown. We have explored the hypothesis that agmatine, a metabolite of arginine, may stimulate NAG synthesis and, thereby, urea synthesis. We tested this hypothesis in a liver perfusion system to determine 1) the metabolism of l-[guanidino-15N2]arginine to either agmatine, nitric oxide (NO), and/or urea; 2) hepatic uptake of perfusate agmatine and its action on hepatic N metabolism; and 3) the role of arginine, agmatine, or NO in regulating NAG synthesis and ureagenesis in livers perfused with 15N-labeled glutamine and unlabeled ammonia or 15NH4Cl and unlabeled glutamine. Our principal findings are 1) [guanidino-15N2]agmatine is formed in the liver from perfusate l-[guanidino-15N2]arginine ( approximately 90% of hepatic agmatine is derived from perfusate arginine); 2) perfusions with agmatine significantly stimulated the synthesis of 15N-labeled NAG and [15N]urea from 15N-labeled ammonia or glutamine; and 3) the increased levels of hepatic agmatine are strongly correlated with increased levels and synthesis of 15N-labeled NAG and [15N]urea. These data suggest a possible therapeutic strategy encompassing the use of agmatine for the treatment of disturbed ureagenesis, whether secondary to inborn errors of metabolism or to liver disease.

Published
2002
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44. Ketogenic diet, amino acid metabolism, and seizure control.

Author

Yudkoff M, Daikhin Y, Nissim I, Lazarow A, and Nissim I

Subjects
Animals, Brain cytology, Epilepsy physiopathology, Humans, Synaptic Transmission genetics, Amino Acids metabolism, Brain metabolism, Energy Metabolism physiology, Epilepsy metabolism, Epilepsy therapy, Food, Formulated, Ketone Bodies biosynthesis
Abstract

The ketogenic diet has been utilized for many years as an adjunctive therapy in the management of epilepsy, especially in those children for whom antiepileptic drugs have not permitted complete relief. The biochemical basis of the dietary effect is unclear. One possibility is that the diet leads to alterations in the metabolism of brain amino acids, most importantly glutamic acid, the major excitatory neurotransmitter. In this review, we explore the theme. We present evidence that ketosis can lead to the following: 1) a diminution in the rate of glutamate transamination to aspartate that occurs because of reduced availability of oxaloacetate, the ketoacid precursor to aspartate; 2) enhanced conversion of glutamate to GABA; and 3) increased uptake of neutral amino acids into the brain. Transport of these compounds involves an uptake system that exchanges the neutral amino acid for glutamine. The result is increased release from the brain of glutamate, particularly glutamate that had been resident in the synaptic space, in the form of glutamine. These putative adaptations of amino acid metabolism occur as the system evolves from a glucose-based fuel economy to one that utilizes ketone bodies as metabolic substrates. We consider mechanisms by which such changes might lead to the antiepileptic effect., (Copyright 2001 Wiley-Liss, Inc.)

Published
2001
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45. N(epsilon)-(gamma-L-glutamyl)-L-lysine (GGEL) is increased in cerebrospinal fluid of patients with Huntington's disease.

Author

Jeitner TM, Bogdanov MB, Matson WR, Daikhin Y, Yudkoff M, Folk JE, Steinman L, Browne SE, Beal MF, Blass JP, and Cooper AJ

Subjects
Adult, Chromatography, Liquid, Electrochemistry, Female, Humans, Male, Radioisotope Dilution Technique, Transglutaminases metabolism, o-Phthalaldehyde chemistry, Dipeptides cerebrospinal fluid, Huntington Disease cerebrospinal fluid
Abstract

Pathological-length polyglutamine (Q(n)) expansions, such as those that occur in the huntingtin protein (htt) in Huntington's disease (HD), are excellent substrates for tissue transglutaminase in vitro, and transglutaminase activity is increased in post-mortem HD brain. However, direct evidence for the participation of tissue transglutaminase (or other transglutaminases) in HD patients in vivo is scarce. We now report that levels of N(epsilon)-(gamma-L-glutamyl)-L-lysine (GGEL)--a 'marker' isodipeptide produced by the transglutaminase reaction--are elevated in the CSF of HD patients (708 +/- 41 pmol/mL, SEM, n = 36) vs. control CSF (228 +/- 36, n = 27); p < 0.0001. These data support the hypothesis that transglutaminase activity is increased in HD brain in vivo.

Published
2001
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46. Brain amino acid metabolism and ketosis.

Author

Yudkoff M, Daikhin Y, Nissim I, Lazarow A, and Nissim I

Subjects
Animals, Aspartic Acid metabolism, Blood-Brain Barrier, Body Weight, Coenzyme A analysis, Dietary Fats administration & dosage, Gas Chromatography-Mass Spectrometry, Glucose pharmacology, Glutamic Acid metabolism, Ketone Bodies metabolism, Male, Mice, Nerve Tissue Proteins analysis, Prosencephalon metabolism, gamma-Aminobutyric Acid analysis, Amino Acids metabolism, Brain metabolism, Dietary Fats pharmacology, Ketosis metabolism
Abstract

The relationship between ketosis and brain amino acid metabolism was studied in mice that consumed a ketogenic diet (>90% of calories as lipid). After 3 days on the diet the blood concentration of 3-OH-butyrate was approximately 5 mmol/l (control = 0.06-0.1 mmol/l). In forebrain and cerebellum the concentration of 3-OH-butyrate was approximately 10-fold higher than control. Brain [citrate] and [lactate] were greater in the ketotic animals. The concentration of whole brain free coenzyme A was lower in ketotic mice. Brain [aspartate] was reduced in forebrain and cerebellum, but [glutamate] and [glutamine] were unchanged. When [(15)N]leucine was administered to follow N metabolism, this labeled amino acid accumulated to a greater extent in the blood and brain of ketotic mice. Total brain aspartate ((14)N + (15)N) was reduced in the ketotic group. The [(15)N]aspartate/[(15)N]glutamate ratio was lower in ketotic animals, consistent with a shift in the equilibrium of the aspartate aminotransferase reaction away from aspartate. Label in [(15)N]GABA and total [(15)N]GABA was increased in ketotic animals. When the ketotic animals were injected with glucose, there was a partial blunting of ketoacidemia within 40 min as well as an increase of brain [aspartate], which was similar to control. When [U-(13)C(6)]glucose was injected, the (13)C label appeared rapidly in brain lactate and in amino acids. Label in brain [U-(13)C(3)]lactate was greater in the ketotic group. The ratio of brain (13)C-amino acid/(13)C-lactate, which reflects the fraction of amino acid carbon that is derived from glucose, was much lower in ketosis, indicating that another carbon source, i.e., ketone bodies, were precursor to aspartate, glutamate, glutamine and GABA., (Copyright 2001 Wiley-Liss, Inc.)

Published
2001
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47. Compartmentation of brain glutamate metabolism in neurons and glia.

Author

Daikhin Y and Yudkoff M

Subjects
Animals, Brain cytology, Glutamine metabolism, Synaptic Transmission physiology, Brain metabolism, Glutamic Acid metabolism, Neuroglia metabolism, Neurons metabolism
Abstract

Intrasynaptic [glutamate] must be kept low in order to maximize the signal-to-noise ratio after the release of transmitter glutamate. This is accomplished by rapid uptake of glutamate into astrocytes, which convert glutamate into glutamine. The latter then is released to neurons, which, via mitochondrial glutaminase, form the glutamate that is used for neurotransmission. This pattern of metabolic compartmentation is the "glutamate-glutamine cycle." This model is subject to the following two important qualifications: 1) brain avidly oxidizes glutamate via aspartate aminotransferase; and 2) because almost no glutamate crosses from blood to brain, it must be synthesized in the central nervous system (CNS). The primary source of glutamate carbon is glucose, and a major source of glutamate nitrogen is the branched-chain amino acids, which are transported rapidly into the CNS. This arrangement accomplishes the following: 1) maintenance of low external [glutamate], thereby maximizing signal-to-noise ratio upon depolarization; 2) the replenishing of the neuronal glutamate pool; 3) the "trafficking" of glutamate through the extracellular fluid in a nonneuroactive form (glutamine); 4) the importation of amino groups from blood, thus maintaining brain nitrogen homeostasis; and 5) the oxidation of glutamate/glutamine, a process that confers an additional level of control in terms of the regulation of brain glutamate, aspartate and gamma-aminobutyric acid.

Published
2000
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48. Rapid method for determining the rate of DNA synthesis and cellular proliferation.

Author

Nissim I, Starr SE, Sullivan KE, Campbell DE, Douglas SD, Daikhin Y, and Yudkoff M

Subjects
Cell Division, Humans, Sensitivity and Specificity, U937 Cells, Biological Assay methods, DNA Replication
Abstract

A new method has been developed for determination of DNA synthesis during cell proliferation. The method is based on the metabolism of [U-(13)C(6)]glucose to deoxyribose (DR) and then incorporation of [U-(13)C(5)]DR into newly synthesized DNA. Extracted cellular DNA is subjected to HCl hydrolysis (2 h at 100 degrees C), which converts DR into levulinic acid. The (13)C enrichment in DR is determined in the trimethylsilyl derivative of levulinate using gas chromatography-mass spectrometry. The method is rapid and sensitive. It can precisely determine (13)C enrichment below 1 at.% excess in as little as 4 ng DNA. We have used this method to determine the rate of cell proliferation in vitro and the level of DR in a given amount of DNA. The current approach has significant advantages over previously described methods and overcomes several difficulties related to the determination of DNA synthesis both in vivo and in vitro., (Copyright 2000 Academic Press.)

Published
2000
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49. Correction of ureagenesis after gene transfer in an animal model and after liver transplantation in humans with ornithine transcarbamylase deficiency.

Author

Batshaw ML, Robinson MB, Ye X, Pabin C, Daikhin Y, Burton BK, Wilson JM, and Yudkoff M

Subjects
Animals, Child, Disease Models, Animal, Female, Humans, Mice, Ornithine Carbamoyltransferase Deficiency Disease metabolism, Gene Transfer Techniques, Genetic Therapy, Liver Transplantation, Ornithine Carbamoyltransferase Deficiency Disease therapy, Urea metabolism
Abstract

We report effects of gene transfer and liver transplantation on urea synthesis in ornithine transcarbamylase deficiency (OTCD). We measured the formation of [15N] urea after oral administration of 15NH4Cl in two girls with partial OTCD before and after liver transplantation. Ureagenesis was less than 20% of that observed in controls before transplantation, and was normalized afterward. Studies performed on the OTCD sparse fur (spf/Y) mouse showed discordance between OTC enzyme activity and ureagenesis with modest increases in OTC enzyme activity after gene transfer resulting in significant improvement in ureagenesis. This study suggests that both liver transplantation and gene therapy may be effective in improving ureagenesis in OTCD.

Published
1999
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50. Decreased intraplatelet Ca2+ release and ATP secretion in pediatric nephrotic syndrome.

Author

Svetlov SI, Moskaleva ES, Pinelis VG, Daikhin Y, and Serebruany VL

Subjects
Adolescent, Child, Child, Preschool, Dose-Response Relationship, Drug, Female, Humans, Intracellular Fluid metabolism, Male, Platelet Activating Factor pharmacology, Thrombin pharmacology, Adenosine Triphosphate metabolism, Blood Platelets metabolism, Calcium metabolism, Nephrotic Syndrome metabolism
Abstract

Platelets play an important role in the natural history of idiopathic nephrotic syndrome (NS). Although thromboembolic events are rare, the activation of circulating platelets is generally considered an important factor in the prethrombotic state in children with NS. Platelet-activating factor (PAF), a potent endogenous phospholipid mediator of inflammation, stimulates intracellular free calcium (Ca2+) mobilization, aggregation, and release reactions in platelets obtained from normal donors. Platelet-related effects of PAF in children with NS are unknown. We studied PAF-induced intracellular Ca2+ mobilization in washed platelets and ATP secretion in platelet-rich plasma in 34 children with idiopathic NS and in 7 healthy children. There was a significant decrease in ATP secretion: 0.021+/-0.011 microg/10(7) cells with 20 nM PAF and 0.089+/-0.017 microg/10(7) platelets with 200 nM PAF versus control values (0.195+/-0.004 microg/10(7) and 0.813+/-0.09 microg/10(7), respectively). Moreover, PAF-evoked increase in intracellular free Ca2+ concentration was twofold lower in NS patients than in control subjects (230.1+/-22.4 nM versus 455.6+/-15.3 nM). Also, thrombin-induced intracellular free Ca2+ mobilization was diminished in children with NS compared with the control group. Thus, contrary to expectations, a decrease of platelet reactivity in response to PAF in vitro was observed in children with idiopathic NS. We suggest that this decreased platelet reactivity may reflect a period refractory to PAF and may be considered as platelet desensitization to PAF released in vivo in children with NS.

Published
1999
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