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01-12-2014 | Original Paper

α-Ketoglutaramate: an overlooked metabolite of glutamine and a biomarker for hepatic encephalopathy and inborn errors of the urea cycle

Authors: Arthur J. L. Cooper, Tomiko Kuhara

Published in: Metabolic Brain Disease | Issue 4/2014

Abstract

Glutamine metabolism is generally regarded as proceeding via glutaminase-catalyzed hydrolysis to glutamate and ammonia, followed by conversion of glutamate to α-ketoglutarate catalyzed by glutamate dehydrogenase or by a glutamate-linked aminotransferase (transaminase). However, another pathway exists for the conversion of glutamine to α-ketoglutarate that is often overlooked, but is widely distributed in nature. This pathway, referred to as the glutaminase II pathway, consists of a glutamine transaminase coupled to ω-amidase. Transamination of glutamine results in formation of the corresponding α-keto acid, namely, α-ketoglutaramate (KGM). KGM is hydrolyzed by ω-amidase to α-ketoglutarate and ammonia. The net glutaminase II reaction is: L ‐ Glutamine + α ‐ keto acid + H₂O → α ‐ ketoglutarate + L ‐ amino acid + ammonia. In this mini-review the biochemical importance of the glutaminase II pathway is summarized, with emphasis on the key component KGM. Forty years ago it was noted that the concentration of KGM is increased in the cerebrospinal fluid (CSF) of patients with hepatic encephalopathy (HE) and that the level of KGM in the CSF correlates well with the degree of encephalopathy. In more recent work, we have shown that KGM is markedly elevated in the urine of patients with inborn errors of the urea cycle. It is suggested that KGM may be a useful biomarker for many hyperammonemic diseases including hepatic encephalopathy, inborn errors of the urea cycle, citrin deficiency and lysinuric protein intolerance.

Enzymes that catalyze the transfer of an amino group from an amino acid to an α-keto acid were originally named transaminases. The word transaminase has been largely replaced by the word aminotransferase, especially for those enzymes that utilize as substrates L-glutamate and α-ketoglutarate. However, the word transaminase continues to be used for those enzymes that catalyze the transfer of the amino group of glutamine to a suitable α-keto acid acceptor.

Perry et al. (1993) sequenced rat kidney GTK (a pyridoxal 5′-phosphate-containing enzyme) and later the human orthologue (Perry et al. 1995). Because GTK has considerable cysteine S-conjugate β-lyase activity the authors referred to GTK as cysteine S-conjugate β-lyase. As a result, the gene for GTK is listed in human and rodent genome databanks as CCBL1 (Cysteine S-Conjugate Beta-Lyase isozyme 1) and antibody products are listed under this name. GTK and KAT I are listed as synonyms. The CCBL1 nomenclature is unfortunate because the cysteine S-conjugate β-lyase activity is presumably not the physiological role of this enzyme. Moreover, many additional pyridoxal 5′-phosphate-containing enzymes can also catalyze cysteine S-conjugate β-lyase reactions (Cooper et al. 2011). A second gene listed in mammalian genomes is referred to as CCBL2, a gene closely related to CCBL1. CCBL2 encodes GTL/KAT III.

Albuquerque EX, Schwarcz R (2013) Kynurenic acid as an antagonist of α7 nicotinic acetylcholine receptors in the brain: facts and challenges. Biochem Pharmacol 85:1027–1032PubMedCentralPubMed

Abou-Khalil WH, Yunis AA, Abou-Khalil S (1983) Prominent glutamine oxidation activity in mitochondria of hematopoietic tumors. Cancer Res 43:1990–1993PubMed

Barglow KT, Saikatendu KS, Bracey MH, Huey R, Morris GM, Olson AJ, Stevens RC, Cravatt BF (2008) Functional proteomic and structural insights into molecular recognition in the nitrilase family enzymes. Biochemistry 47:13514–13523PubMedCentralPubMed

Beal MF, Swartz KJ, Isacson O (1992) Developmental changes in brain kynurenic acid concentrations. Brain Res Dev Brain Res 68:136–139PubMed

Bergmeyer U (ed) (1974) Methods of Enzymatic analysis. 2nd English edn. Verlag ChemieWeiheim, Academic Press, New York, p 2285

Bourke E, Fine A, Scott J (1971a) Mechanism of ammoniagenesis in human kidney. Biochem J 125(4):94PPubMedCentralPubMed

Bourke E, Fine A, Scott JM (1971b) Glutaminase II pathway in human kidney. Nat New Biol 233:249–250PubMed

Bourke E, Frindt G, Rubio-Paez D, Schreiner GE (1971c) Effect of chronic alkalosis and acidosis on glutaminase II path in the dog kidney in vivo. Am J Physiol 220:1033–1036PubMed

Brennan RW, Plum F (1971) A cerebrospinal fluid transfer model for hepatic and uremic encephalopathy. Trans Am Neurol Assoc 96:210–211PubMed

Bröer S, Palacín M (2011) The role of amino acid transporters in inherited and acquired diseases. Biochem J 436:193–211PubMed

Brusilow SW, Horwich AL (2001) Urea cycle enzymes Chapter 85. In: Scriver CR, Beaudet AL, Sly WS, Valle D, Childs B, Kinzler KW, Vogelstein B (eds) The metabolic and molecular bases of inherited disease, 8th edn. McGraw-Hill, New York

Brusilow SW, Cooper AJL (2011) Encephalopathy in acute liver failure resulting from acetaminophen intoxication: new observations with potential therapy. Crit Care Med 39:2550–2553PubMedCentralPubMed

Brusilow SW, Koehler RC, Traystman RJ, Cooper AJL (2010) Astrocyte glutamine synthetase: importance in hyperammonemic syndromes and potential target for therapy. Neurotherapeutics 7:452–470PubMedCentralPubMed

Buchli R, Alberati-Giani D, Malherbe P, Köhler C, Broger C, Cesura AM (1995) Cloning and functional expression of a soluble form of kynurenine/α-aminoadipate aminotransferase from rat kidney. J Biol Chem 270:29330–29335PubMed

Butterworth RF (2013) The liver-brain axis in liver failure: neuroinflammation and encephalopathy. Nat Rev Gastroenterol Hepatol 10:522–528PubMed

Cassago A, Ferreira AP, Ferreira IM, Fornezari C, Gomes ER, Greene KS, Pereira HM, Garratt RC, Dias SM, Ambrosio AL (2012) Mitochondrial localization and structure-based phosphate activation mechanism of Glutaminase C with implications for cancer metabolism. Proc Natl Acad Sci U S A 109:1092–1097PubMedCentralPubMed

Cathelineau L, Briand P, Ogier H, Charpentier C, Coude FX, Saudubray JM (1981) Occurrence of hyperammonemia in the course of 17 cases of methylmalonic acidemia. J Pediatr 99:279–280PubMed

Chavarria L, Alonso J, García-Martínez R, Simón-Talero M, Ventura-Cots M, Ramírez C, Torrens M, Vargas V, Rovira A, Córdoba J (2013) Brain magnetic resonance spectroscopy in episodic hepatic encephalopathy. J Cereb Blood Flow Metab 33:272–277PubMedCentralPubMed

Chien CH, Gao QZ, Cooper AJL, Lyu JH, Sheu SY (2012) Structural insights into the catalytic active site and activity of human Nit2/ω-amidase: kinetic assay and molecular dynamics simulation. J Biol Chem 287:25715–25726PubMedCentralPubMed

Chow KW, Walser M (1974) Substitution of five essential amino acids by their alpha-keto analogues in the diet of rats. J Nutr 104:1208–1214PubMed

Cooper AJL (1988) Glutamine aminotransferases and ω-amidases. In: Kvamme E (ed) Glutamine and glutamate in mammals, vol 1. CRC Press, Inc, Boca Raton, pp 33–52

Cooper AJL (2004) The role of glutamine transaminase K (GTK) in sulfur and α-keto acid metabolism in the brain, and possible bioactivation of neurotoxicants. Neurochem Int 44:557–577PubMed

Cooper AJL (2013) Possible treatment of end-stage hyperammonemic encephalopathy by inhibition of glutamine synthetase. Metab Brain Dis 28:119–125PubMed

Cooper AJL, Gross M (1977) The glutamine transaminase-ω-amidase system in rat and human brain. J Neurochem 28:771–778PubMed

Cooper AJL, Meister A (1972) Isolation and properties of highly purified glutamine transaminase. Biochemistry 11:661–671PubMed

Cooper AJL, Meister A (1974) Isolation and properties of a new glutamine transaminase from rat kidney. J Biol Chem 249:2554–2561PubMed

Cooper AJL, Meister A (1977) The glutamine transaminase - ω-amidase pathway. CRC Crit Rev Biochem 4:281–303PubMed

Cooper AJL, Meister A (1981) Comparative studies of glutamine transaminases from rat tissues. Comp Biochem Physiol 69B:137–145

Cooper AJL, Plum F (1987) Biochemistry and physiology of brain ammonia. Physiol Rev 67:440–519PubMed

Cooper AJL, Dhar AK, Kutt H, Duffy TE (1980) Determination of 2-pyrrolidone-5-carboxylic and α-ketoglutaramic acids in human cerebrospinal fluid by gas chromatography. Anal Biochem 103:118–126PubMed

Cooper AJL, Duffy TE, Meister A (1985) α-Keto acid ω-amidase from rat liver. Methods Enzymol 113:350–358PubMed

Cooper AJL, Abraham DG, Gelbard AS, Lai JC, Petito CK (1993) High activities of glutamine transaminase K (dichlorovinylcysteine β-lyase) and ω-amidase in the choroid plexus of rat brain. J Neurochem 61:1731–1741PubMed

Cooper AJL, Krasnikov BF, Niatsetskaya ZV, Pinto JT, Callery PS, Villar MT, Artigues A, Bruschi SA (2011) Cysteine S-conjugate β-lyases: important roles in the metabolism of naturally occurring sulfur and selenium-containing compounds, xenobiotics and anticancer agents. Amino Acids 41:7–27PubMedCentralPubMed

Cooper AJL, Dorai T, Dorai B, Krasnikov BF, Li J, Hallen A, Pinto JT (2013) Role of Glutamine transaminases in nitrogen, sulfur, selenium and 1-carbon metabolism. In: Rajendram R, Preedy VR, Patel VB (eds) Glutamine in health and disease. Springer, New York, in press

Cudalbu C, Lanz B, Duarte JM, Morgenthaler FD, Pilloud Y, Mlynárik V, Gruetter R (2012) Cerebral glutamine metabolism under hyperammonemia determined in vivo by localized ¹H and ¹⁵N NMR spectroscopy. J Cereb Blood Flow Metab 32:696–708PubMedCentralPubMed

Dai Y, Wensink PC, Abeles RH (1999) One protein, two enzymes. J Biol Chem 274:1193–1195PubMed

Dai Y, Pochapsky TC, Abeles RH (2001) Mechanistic studies of two dioxygenases in the methionine salvage pathway of Klebsiella pneumoniae. Biochemistry 40:6379–6387PubMed

Darmaun D, Matthews DE, Bier DM (1986) Glutamine and glutamate kinetics in humans. Am J Physiol 251:E117–E126PubMed

Desjardins P, Du T, Jiang W, Peng L, Butterworth RF (2012) Pathogenesis of hepatic encephalopathy and brain edema in acute liver failure: role of glutamine redefined. Neurochem Int 60:690–696PubMed

Duffy TE, Cooper AJL, Meister A (1974a) Identification of α-ketoglutaramate in rat liver, kidney, and brain. Relationship to glutamine transaminase and ω-amidase activities. J Biol Chem 249:7603–7606PubMed

Duffy TE, Vergara F, Plum F (1974b) α-Ketoglutaramate in hepatic encephalopathy. Res Publ Assoc Res Nerv Ment Dis 53:39–52PubMed

Durán RV, Oppliger W, Robitaille AM, Heiserich L, Skendaj R, Gottlieb E, Hall MN (2012) Glutaminolysis activates Rag-mTORC1 signaling. Mol Cell 47:349–358PubMed

Erickson JW, Cerione RA (2010) Glutaminase: a hot spot for regulation of cancer cell metabolism? Oncotarget 1:734–740PubMedCentralPubMed

Errera M, Greenstein JP (1949) Phosphate-activated glutaminase in kidney and other tissues. J Biol Chem 178:495–502PubMed

Filipowicz HR, Ernst SL, Ashurst CL, Pasquali M, Longo N (2006) Metabolic changes associated with hyperammonemia in patients with propionic acidemia. Mol Genet Metab 88:123–130PubMed

Greenstein JP, Price VE (1949) α-Keto acid-activated glutaminase and asparaginase. J Biol Chem 178:695–705PubMed

Guidetti P, Amori L, Sapko MT, Okuno E, Schwarcz R (2007) Mitochondrial aspartate aminotransferase: a third kynurenate-producing enzyme in the mammalian brain. J Neurochem 102:103–111PubMed

Halámková L, Mailloux S, Halámek J, Cooper AJ, Katz E (2012) Enzymatic analysis of α-ketoglutaramate - a biomarker for hyperammonemia. Talanta 100:7–11PubMed

Han Q, Li J, Li J (2004) pH dependence, substrate specificity and inhibition of human kynurenine aminotransferase I. Eur J Biochem 71:4804–4814

Han Q, Cai T, Tagle DA, Robinson H, Li J (2008) Substrate specificity and structure of human aminoadipate aminotransferase/kynurenine aminotransferase II. Biosci Rep 28:205–215PubMedCentralPubMed

Han Q, Robinson H, Cai T, Tagle DA, Li J (2009) Biochemical and structural properties of mouse kynurenine aminotransferase III. Mol. Cell Biol 29:784–793

Häussinger D, Stehle T, Gerok W (1985) Glutamine metabolism in isolated perfused rat liver. The transamination pathway. Biol Chem Hoppe Seyler 366:527–536PubMed

Heidelberger C, Gullberg ME, Morgan AF, Lepkovsky S (1949) Tryptophan metabolism; concerning the mechanism of the mammalian conversion of tryptophan into kynurenine, kynurenic acid, and nicotinic acid. J Biol Chem 179:143–150PubMed

Heins J, Zwingmann C (2010) Organic osmolytes in hyponatremia and ammonia toxicity. Metab Brain Dis 25:81–89PubMed

Herlong HF, Maddrey WC, Walser M (1980) The use of ornithine salts of branched-chain ketoacids in portal-systemic encephalopathy. Ann Intern Med 93:545–550PubMed

Hersh LB (1971) Rat liver ω-amidase: purification and properties. Biochemistry 10:2884–2891PubMed

Hersh LB (1972) Rat liver ω-amidase. Kinetic evidence for an acyl-enzyme intermediate. Biochemistry 11:2251–2256PubMed

Hoffer LJ, Taveroff A, Robitaille L, Mamer OA, Reimer ML (1993) α-Keto and α-hydroxy branched-chain acid interrelationships in normal humans. J Nutr 123:1513–1521PubMed

Holecek M (2013) Evidence of a vicious cycle in glutamine synthesis and breakdown in pathogenesis of hepatic encephalopathy-therapeutic perspectives. Metab Brain Dis

Huebner K, Saldivar JC, Sun J, Shibata H, Druck T (2011) Hits, Fhits and Nits: beyond enzymatic function. Adv Enzyme Regul 51:208–217PubMedCentralPubMed

Hutson SM, Harper AE (1981) Blood and tissue branched-chain amino and α-keto acid concentrations: effect of diet, starvation, and disease. Am J Clin Nutr 34:173–183

Hutson SM, Rannels SL (1985) Characterization of a mitochondrial transport system for branched chain α-keto acids. J Biol Chem 260:14189–14193PubMed

Jaisson S, Veiga-da-Cunha M, Van Schaftingen E (2009) Molecular identification of ω-amidase, the enzyme that is functionally coupled with glutamine transaminases, as the putative tumor suppressor Nit2. Biochimie 91:1066–1071PubMed

Jones TW, Qin C, Schaeffer VH, Stevens JL (1988) Immunohistochemical localization of glutamine transaminase K, a rat kidney cysteine conjugate β-lyase, and the relationship to the segment specificity of cysteine conjugate nephrotoxicity. Mol Pharmacol 34:621–627PubMed

Keiding S, Pavese N (2013) Brain metabolism in patients with hepatic encephalopathy studied by PET and MR. Arch Biochem Biophys 536:131–142PubMed

Kim HS, Cha SH, Abraham DG, Cooper AJL, Endou H (1997) Intranephron distribution of cysteine S-conjugate beta-lyase activity and its implication for hexachloro-1,3-butadiene-induced nephrotoxicity in rats. Arch Toxicol 71:131–141PubMed

Koppenol WH, Bounds PL, Dang CV (2011) Otto Warburg’s contributions to current concepts of cancer metabolism. Nat Rev Cancer 11:325–337PubMed

Krasnikov BF, Chien C-H, Nostramo R, Pinto JT, Nieves E, Callaway M, Sun J, Huebner K, Cooper AJL (2009) Identification of the putative tumor suppressor Nit2 as ω-amidase, an enzyme metabolically linked to glutamine and asparagine transamination. Biochimie 91:1072–1080PubMedCentralPubMed

Kuhara T (2007) Noninvasive human metabolome analysis for differential diagnosis of inborn errors of metabolism. J Chromatogr B Anal Technol Biomed Life Sci 855:42–50

Kuhara T, Ohse M, Inoue Y, Cooper AJL (2011a) A GC/MS-based metabolomic approach for diagnosing citrin deficiency. Anal Bioanal Chem 400:1881–1894PubMed

Kuhara T, Inoue Y, Ohse M, Krasnikov BF, Cooper AJL (2011b) Urinary 2-hydroxy-5-oxoproline, the lactam form of α-ketoglutaramate, is markedly increased in urea cycle disorders. Anal Bioanal Chem 400:1843–1851PubMedCentralPubMed

Lavoie J, Giguère JF, Layrargues GP, Butterworth RF (1987) Amino acid changes in autopsied brain tissue from cirrhotic patients with hepatic encephalopathy. J Neurochem 49:692–697PubMed

Lin CH, Chung MY, Chen WB, Chien CH (2007) Growth inhibitory effect of the human NIT2 gene and its allelic imbalance in cancers. FEBS J 274:2946–2956PubMed

Linster CL, Van Schaftingen E, Hanson AD (2013) Metabolite damage and its repair or pre-emption. Nat Chem Biol 9:72–80PubMed

Lockwood AH, Duffy TE (1977) Glutamine transaminase and ω-amidase: species variations in brain activity and effect of portacaval shunting. J Neurochem 28:673–675PubMed

Maddrey WC, Weber FL Jr, Coulter AW, Chura CM, Chapanis NP, Walser M (1976) Effects of keto analogues of essential amino acids in portal-systemic encephalopathy. Gastroenterology 71:190–195PubMed

Malherbe P, Alberati-Giani D, Köhler C, Cesura AM (1995) Identification of a mitochondrial form of kynurenine aminotransferase/glutamine transaminase K from rat brain. FEBS Lett 367:141–144PubMed

Mallet RT, Kelleher JK, Jackson MJ (1986) Substrate metabolism of isolated jejunal epithelium: conservation of three-carbon units. Am J Physiol 250:C191–C198PubMed

Martinez-Hernandez A, Bell KP, Norenberg MD (1977) Glutamine synthetase: glial localization in brain. Science 195:1356–1358PubMed

Mardini H, Smith FE, Record CO, Blamire AM (2011) Magnetic resonance quantification of water and metabolites in the brain of cirrhotics following induced hyperammonaemia. J Hepatol 54:1154–1160PubMed

Meister A (1953) Preparation and enzymatic reactions of the keto analogues of glutamine and asparagine. J Biol Chem 200:571–589PubMed

Meister A, Sober HA, Tice SV, Fraser PE (1952) Transamination and associated deamidation of asparagine and glutamine. J Biol Chem 197:319–330PubMed

Meister A, Levintow L, Greenfield RE, Abendschein PA (1955) Hydrolysis and transfer reactions catalyzed by ω-amidase. J Biol Chem 215:441–460PubMed

Mena FV, Baab PJ, Zielke CL, Huang Y, Zielke HR (2005) Formation of extracellular glutamate from glutamine: exclusion of pyroglutamate as an intermediate. Brain Res 1052:88–96PubMed

Miller JE, Litwack G (1971) Purification, properties, and identity of liver mitochondrial tyrosine aminotransferase. J Biol Chem 246:3234–3240PubMed

Mosca M, Cozzi L, Breton J, Speciale C, Okuno E, Schwarcz R, Benatti L (1994) Molecular cloning of rat kynurenine aminotransferase: identity with glutamine transaminase K. FEBS Lett 353:21–24PubMed

Nissim I, Wehrli S, States B, Nissim I, Yudkoff M (1991) Analysis and physiological implications of renal 2-oxoglutaramate metabolism. Biochem J 277:33–38PubMedCentralPubMed

Norenberg MD, Martinez-Hernandez A (1979) Fine structural localization of glutamine synthetase in astrocytes of rat brain. Brain Res 161:303–310PubMed

Notarangelo FM, Wu HQ, Macherone A, Graham DR, Schwarcz R (2012) Gas chromatography/tandem mass spectrometry detection of extracellular kynurenine and related metabolites in normal and lesioned rat brain. Anal Biochem 421:573–581PubMedCentralPubMed

Ogier de Baulny H, Schiff M, Dionisi-Vici C (2012) Lysinuric protein intolerance (LPI): a multi organ disease by far more complex than a classic urea cycle disorder. Mol Genet Metab 106:12–17PubMed

Okuno E, Nakamura M, Schwarcz R (1991) Two kynurenine aminotransferases in human brain. Brain Res 542:307–312PubMed

Olson KC, Chen G, Lynch CJ (2013) Quantification of branched-chain keto acids in tissue by ultra fast liquid chromatography-mass spectrometry. Anal Biochem 439:116–122PubMed

Otani TT, Meister A (1957) ω-Amide and ω-amino acid derivatives of α-ketoglutaric and oxalacetic acids. J Biol Chem 224:137–148PubMed

Pace HC, Brenner C (2001) The nitrilase superfamily: classification, structure and function. Genome Biol 2(1)

Pailla K, Blonde-Cynober F, Aussel C, De Bandt JP, Cynober L (2000) Branched-chain keto-acids and pyruvate in blood: measurement by HPLC with fluorimetric detection and changes in older subjects. Clin Chem 46:848–853PubMed

Pamiljans V, Krishnaswamy PR, Dumville G, Meister A (1962) Studies on the mechanism of glutamine synthesis; isolation and properties of the enzyme from sheep brain. Biochemistry 1:153–158PubMed

Patel TB, Waymack PP, Olson MS (1980) The effect of the monocarboxylate translocator inhibitor, α-cyanocinnamate, on the oxidation of branched chain α-keto acids in rat liver. Arch Biochem Biophys 201:629–635PubMed

Pawlak D, Tankiewicz A, Matys T, Buczko W (2003) Peripheral distribution of kynurenine metabolites and activity of kynurenine pathway enzymes in renal failure. J Physiol Pharmacol 54:175–189PubMed

Perry SJ, Schofield MA, MacFarlane M, Lock EA, King LJ, Gibson GG, Goldfarb PS (1993) Isolation and expression of a cDNA coding for rat kidney cytosolic cysteine conjugate β-lyase. Mol Pharmacol 43:660–665PubMed

Perry S, Harries H, Scholfield C, Lock T, King L, Gibson G, Goldfarb P (1995) Molecular cloning and expression of a cDNA for human kidney cysteine conjugate β-lyase. FEBS Lett 360:277–280PubMed

Plum F (1971) The CSF in hepatic encephalopathy. Exp Biol Med 4:34–41PubMed

Polet F, Feron O (2013) Endothelial cell metabolism and tumour angiogenesis: glucose and glutamine as essential fuels and lactate as the driving force. J Intern Med 273:156–165PubMed

Porter LD, Ibrahim H, Taylor L, Curthoys NP (2002) Complexity and species variation of the kidney-type glutaminase gene. Physiol Genomics 9:157–166PubMed

Record CO, Buxton B, Chase RA, Curzon G, Murray-Lyon IM, Williams R (1976) Plasma and brain amino acids in fulminant hepatic failure and their relationship to hepatic encephalopathy. Eur J Clin Invest 6:387–394PubMed

Roediger WE (1982) Utilization of nutrients by isolated epithelial cells of the rat colon. Gastroenterology 83:424–429PubMed

Sahai A, Nissim I, Tannen RL (1991) Pathways of acute pH regulation of ammoniagenesis in LLC-PK₁ cells: study with [¹⁵N]glutamine. Am J Physiol 261:F481–F487PubMed

Saheki T, Kobayashi K (2002) Mitochondrial aspartate glutamate carrier (citrin) deficiency as the cause of adult-onset type II citrullinemia (CTLN2) and idiopathic neonatal hepatitis (NICCD). J Hum Genet 47:333–341PubMed

Sapir DG, Owen OE, Pozefsky T, Walser M (1974) Nitrogen sparing induced by a mixture of essential amino acids given chiefly as their keto-analogues during prolonged starvation in obese subjects. J Clin Invest 54:974–980PubMedCentralPubMed

Scholl-Bürgi S, Sass JO, Zschocke J, Karall D (2012) Amino acid metabolism in patients with propionic acidaemia. J Inherit Metab Dis 35:65–70PubMed

Schwarcz R, Bruno JP, Muchowski PJ, Wu HQ (2012) Kynurenines in the mammalian brain: when physiology meets pathology. Nat Rev Neurosci 13:465–477PubMedCentralPubMed

Shrawder E, Martinez-Carrion M (1972) Evidence of phenylalanine transaminase activity in the isoenzymes of aspartate transaminase. J Biol Chem 247:2486–2492PubMed

Siguira M (1957) A pharmacological aspect on glutamic acid metabolism in brain: transamination and associated deamidation of glutamine to α-keto acid in brain. Jpn J Pharmacol 7:1–5

Stegink LD, Filer LJ Jr, Brummel MC, Baker GL, Krause WL, Bell EF, Ziegler EE (1991) Plasma amino acid concentrations and amino acid ratios in normal adults and adults heterozygous for phenylketonuria ingesting a hamburger and milk shake meal. Am J Clin Nutr 53:670–675PubMed

Steele RD (1986) Blood–brain barrier transport of the α-keto acid analogs of amino acids. Fed Proc 45:2060–2064PubMed

Sweatt AJ, Wood M, Suryawan A, Wallin R, Willingham MC, Hutson SM (2004) Branched-chain amino acid catabolism: unique segregation of pathway enzymes in organ systems and peripheral nerves. Am J Physiol Endocrinol Metab 286:E64–E76PubMed

Van Leuven F (1975) Highly purified glutamine transaminase from rat brain. Physical and kinetic properties. Eur J Biochem 58:153–158PubMed

Van Leuven F (1976) Glutamine transaminase from brain tissue. Further studies on kinetic properties and specificity of the enzyme. Eur J Biochem 65:271–274PubMed

Van Schaftingen E, Rzem R, Marbaix A, Collard F, Veiga-da-Cunha M, Linster CL (2013) Metabolite proofreading, a neglected aspect of intermediary metabolism. J Inherit Metab Dis 36:427–434PubMed

Vergara F, Plum F, Duffy TE (1974) α-Ketoglutaramate: increased concentrations in the cerebrospinal fluid of patients in hepatic coma. Science 183:81–83PubMed

Walser M, Williamson JR (eds) (1981) Metabolism and clinical implications of branched chain amino and ketoacids. Elsevier, North Holland

Walser M, Lund P, Ruderman NB, Coulter AW (1973) Synthesis of essential amino acids from their α-keto analogues by perfused rat liver and muscle. J Clin Invest 52:2865–2877PubMedCentralPubMed

Walker S, Götz R, Czygan P, Stiehl A, Lanzinger G, Sieg A, Raedsch R, Kommerell B (1982) Oral keto analogs of branched-chain amino acids in hyperammonemia in patients with cirrhosis of the liver. A double-blind crossover study. Digestion 24:105–111PubMed

Ward PS, Thompson CB (2012) Metabolic reprogramming: a cancer hallmark even Warburg did not anticipate. Cancer Cell 21:297–308PubMedCentralPubMed

Wipf D, Ludewig U, Tegeder M, Rentsch D, Koch W, Frommer WB (2002) Conservation of amino acid transporters in fungi, plants and animals. Trends Biochem Sci 27:139–147PubMed

Wray JW, Abeles RH (1995) The methionine salvage pathway in Klebsiella pneumoniae and rat liver. Identification and characterization of two novel dioxygenases. J Biol Chem 270:3147–3153PubMed

Yoshida T (1967) Purification and some properties of soluble and mitochondrial glutamine-ketoacids transaminase isozymes. Vitamins 35:227–234, Japanese

Zheng X, Kang A, Dai C, Liang Y, Xie T, Xie L, Peng Y, Wang G, Hao H (2012) Quantitative analysis of neurochemical panel in rat brain and plasma by liquid chromatography-tandem mass spectrometry. Anal Chem 84:10044–10051PubMed

Zielke HR, Ozand PT, Tildon JT, Sevdalian DA, Cornblath M (1978) Reciprocal regulation of glucose and glutamine utilization by cultured human diploid fibroblasts. J Cell Physiol 95:41–48PubMed

Title: α-Ketoglutaramate: an overlooked metabolite of glutamine and a biomarker for hepatic encephalopathy and inborn errors of the urea cycle
Authors: Arthur J. L. Cooper
Tomiko Kuhara
Publication date: 01-12-2014
Publisher: Springer US
Published in: Metabolic Brain Disease / Issue 4/2014
Print ISSN: 0885-7490
Electronic ISSN: 1573-7365
DOI: https://doi.org/10.1007/s11011-013-9444-9

2024 ASCO Annual Meeting

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α-Ketoglutaramate: an overlooked metabolite of glutamine and a biomarker for hepatic encephalopathy and inborn errors of the urea cycle

Abstract

2024 ASCO Annual Meeting

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Abstract

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