EC:1.4.1.2 - FACTA Search

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Query: EC:1.4.1.2 (glutamate dehydrogenase)
4,380 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The integrated use of several energy sources allows high muscular power outputs to be sustained. Muscle glycogen provides the major fuel source for muscular exercise, but other fuels can provide alternative energy sources which allow for muscle glycogen-sparing and an increased potential for prolonged high metabolic rates. Blood-borne glucose, derived from liver glycogenolysis and glyconeogenesis, as well as intra-muscular lipids and plasma free fatty acids derived from adipose tissue provide the main energy alternatives to muscle glycogen. Several amino acids, including the essential amino acid leucine, are also used directly as oxidizable fuels during exercise. Depending on the duration and intensity of exercise and other factors such as glycogen stores and energy intake, amino acids can provide from a few to approximately 10% of the total energy for sustained exercise. Additionally, many amino acids can be converted to glutamate (via glutamate dehydrogenase) and then to alanine (via glutamate-pyruvate transaminase). Alanine, along with lactate and pyruvate, are recognized as the major gluconeogenic precursors. Via this mechanism, several amino acids play crucial roles in providing the carbon sources for maintaining blood glucose homeostasis during exercise and glycogen restitution during recovery. And finally, during exercise and recovery, amino acids likely play important anaplerotic functions sustaining the whole metabolic apparatus.
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PMID:Amino acid and protein metabolism during exercise and recovery. 331 14

The effects of different substrates supporting respiration and glutamine-dependent citrulline synthesis from ornithine, ammonia, and bicarbonate by isolated hepatic mitochondria from Squalus acanthias (spiny dogfish) were determined. Highest rates of respiration were achieved with succinate, palmitoyl-CoA, and beta-hydroxybutyrate as oxidizable substrates. All acyl-CoAs tested (from C-2 to C-22) supported carnitine-dependent respiration at a substantial rate. Short-chain fatty acids did not support respiration. Ammonia required for citrulline synthesis could be formed from glutamate, or from leucine plus alpha-ketoglutarate which gives rise to glutamate by transamination, as the result of glutamate dehydrogenase activity, but the reaction was inhibited by succinate or other oxidizable substrates. Alanine or ornithine could not be substituted for leucine, suggesting that leucine may specifically activate glutamate dehydrogenase. Glutamate required for citrulline synthesis could be formed from alpha-ketoglutarate and ammonia as the result of glutamate dehydrogenase activity if succinate was present. Transamination of alpha-ketoglutarate with ornithine present in the reaction mixtures provided glutamate at a rapid rate whether or not succinate was present. These results are consistent with the view that hepatic dogfish mitochondria efficiently utilize acyl-CoAs derived from triglyceride stores in the liver to support respiration, glutamine-dependent citrulline synthesis from ammonia, and formation of ketone bodies as a major fuel for muscle.
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PMID:Support of respiration and citrulline synthesis by isolated hepatic mitochondria from Squalus acanthias by acyl-CoAs and other nitrogen-donating substrates. 381 53

Buono, F. (Syracuse University, Syracuse, N.Y.), R. Testa, and D. G. Lundgren. Physiology of growth and sporulation in Bacillus cereus. I. Effect of glutamic and other amino acids. J. Bacteriol. 91:2291-2299. 1966.-Growth and sporulation were studied in Bacillus cereus by use of an active culture technique and a synthetic medium. A high level of glutamic acid (70 mm) was required for optimal growth and glucose oxidation followed by sporulation even though relatively little glutamic acid was consumed (14 mm). Optimal growth occurred with a combination of 14 mm glutamic acid and 56 mm (NH(4))(2)SO(4), aspartic acid, or alanine. Ornithine or arginine at 70 mm could replace glutamic acid in the synthetic medium without affecting the normal growth cycle. Glutamic acid was not replaced by any other amino acid, by (NH(4))(2)SO(4), or by a combination of either alpha-ketoglutarate or pyruvate plus (NH(4))(2)SO(4). Enzyme assays of cell-free extracts prepared from cells harvested at different times were used to study the metabolism of glutamic acid. Glutamic-oxaloacetic and glutamic-pyruvate transaminases were completely activated (or derepressed) during early stages of sporulation (period of 6 to 8 hr). Alanine dehydrogenase responded in a similar manner, but the levels of this enzyme were much higher throughout the culture cycle. Neither glutamic dehydrogenase nor alpha-ketoglutarate dehydrogenase was detected. Sporulation in a replacement salts medium was studied with cells harvested at different times from the synthetic medium. Cultures 2 to 6 hr old were unable to sporulate in the replacement salts medium unless glutamic acid (7.0 mm) was present. By the 6th hr, cells were in the early stages of sporulation, showing spore septa development. Cultures 8 hr old sporulated in the replacement salts medium. Other metabolic intermediates able to replace glutamic acid in the replacement salts medium were alanine, aspartic acid, and glutamine at equimolar concentrations. Also, ammonium ions in combination with pyruvic, oxaloacetic, alpha-ketoglutaric, or fumaric acid replaced glutamic acid. The likely role of these metabolites is discussed.
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PMID:Physiology of growth and sporulation in Bacillus cereus. I. Effect of glutamic and other amino acids. 495 15

In L. minor grown in sterile culture, the primary enzymes of nitrate assimilation, nitrate reductase (NR), nitrite reductase (NiR) and glutamate dehydrogenase (GDH) change in response to nitrogen source. NR and NiR levels are low when grown on amino acids (hydrolyzed casein) or ammonia; both enzymes are rapidly induced on addition of nitrate, while addition of nitrite induces NiR only. Ammonia represses the nitrate induced synthesis of both NR and NiR.NADH dependent GDH activity is low when grown on amino acids and high when grown on nitrate or ammonia, but the activities of NADPH dependent GDH and Alanine dehydro-genase (AIDH) are much less affected by nitrogen source. NADH-GDH and AIDH are induced by ammonia, and it is suggested that these enzymes are involved in primary nitrogen assimilation.
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PMID:Nitrogen metabolis of Lemna minor. II. Enzymes of nitrate assimilation and some aspects of their regulation. 579 47

Studies of the nitrogen nutrition and pathways of ammonia assimilation in Rhodocyclus purpureus and Rhodospirillum tenue have shown that these two seemingly related bacteria differ considerably in aspects of their nitrogen metabolism. When grown photoheterotrophically with malate as carbon source, R. purpureus utilized only NH4+ or glutamine as sole nitrogen sources and was unable to fix N2. By contrast, R. tenue was found to utilize a variety of amino acids as nitrogen sources and was a good N2 fixer. No nitrogenase activity was detected in cells of R. purpureus grown on limiting ammonia, whereas cells of R. tenue grown under identical conditions reduced acetylene to ethylene at high rates. Regardless of the nitrogen source supporting growth, extracts of cells of R. purpureus contained high levels of glutamate dehydrogenase, whereas R. tenue contained only trace levels of this enzyme. Alanine dehydrogenase activity was absent from both species. We conclude that R. purpureus is incapable of fixing molecular nitrogen and employs the glutamate dehydrogenase pathway as the primary means of assimilating NH4+ under all growth conditions. R. tenue, on the other hand, employs the glutamine synthetase/glutamate synthase pathway for the incorporation of NH4+ supplied exogenously or as the product of N2 fixation.
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PMID:Nitrogen metabolism in the phototrophic bacteria Rhodocyclus purpureus and Rhodospirillum tenue. 686 18

Glutamate dehydrogenase (L-glutamate:NADP+ oxidoreductase (deaminating), EC 1.4.1.4) has been purified from Mycobacterium smegmatis CDC 46 using (NH4)2SO4 precipitation, negative adsorption on DEAE-cellulose, 2',5'-ADP-Sepharose affinity chromatography and Sephadex G-200. The enzyme was purified 1041.6-fold and the preparation was found to be homogeneous on column chromatography, polyacrylamide gel electrophoresis and SDS-polyacrylamide gel electrophoresis. Alanine and threonine were identified as the N- and C-terminal amino acids of glutamate dehydrogenase from M. smegmastis. The enzyme kinetics and regulation of glutamate dehydrogenase activity by different nutritional factors has been studied. Initial velocity plots showed that the reaction mechanism of glutamate dehydrogenase from M. smegmatis followed an ordered sequential ter-bi mechanism.
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PMID:Isolation and characterisation of glutamate dehydrogenase from Mycobacterium smegmatis CDC 46. 741 53

Insect cell metabolism was studied in substrate-limited fed batch cultures of Spodoptera frugiperda (Sf-9) cells. Results from a glucose-limited culture, a glutamine-limited culture, a culture limited in both glucose and glutamine, and a batch culture were compared. A stringent relation between glucose excess and alanine formation was found. In contrast, glucose limitation induced ammonium formation, while, at the same time, alanine formation was completely suppressed. Simultaneous glucose and glucosamine limitation suppressed both alanine and ammonium formation. Although the metabolism was influenced by substrate limitation, the specific growth rate was similar in all cultures. Alanine formation must involve incorporation of free ammonium, if ammonium formation is mediated by glutaminase and glutamate dehydrogenase, as our data suggest. On the basis of the results, two possible pathways for the formation of alanine in the intermediary metabolism are suggested. The cellular yield on glucose was increased 6.6 times during glucose limitation, independently of the cellular yield on glutamine, which was increased 50-100 times during glutamine limitation. The results indicate that alanine overflow metabolism is energetically wasteful and that glutamine is a dispensable amino acid for cultured Sf-9 cells. Preliminary data confirm that glutamine can be synthesized by the cells themselves in amounts sufficient to support growth.
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PMID:Induction of a metabolic switch in insect cells by substrate-limited fed batch cultures. 859 Jun 51

The idea of a metabolic coupling between neurons and astrocytes in the brain has been entertained for about 100 years. The use recently of simple and well-compartmentalized nervous systems, such as the honeybee retina or purified preparations of neurons and glia, provided strong support for a nutritive function of glial cells: glial cells transform glucose to a fuel substrate taken up and used by neurons. Particularly, in the honeybee retina, photoreceptor-neurons consume alanine supplied by glial cells and exogenous proline. NH4+ and glutamate are transported into glia by functional plasma membrane transport systems. During increased activity a transient rise in the intraglial concentration of NH4+ or of glutamate causes a net increase in the level of reduced nicotinamide adenine dinucleotides [NAD(P)H]. Quantitative biochemistry showed that this is due to activation of glycolysis in glial cells by the direct action of NH4+ and of glutamate, probably on the enzymatic reactions controlled by phosphofructokinase alanine aminotransferase and glutamate dehydrogenase. This activation leads to a massive increase in the production and release of alanine by glia. This constitutes an intracellular signal and it depends upon the rate of conversion of NH4+ and of glutamate to alanine and alpha-ketoglutarate, respectively, in the glial cells. Alanine and alpha-ketoglutarate are released extracellularly and then taken up by neurons where they contribute to the maintenance of the mitochondrial redox potential. This signaling raises the novel hypothesis of a tight regulation of the nutritive function of glia.
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PMID:The nutritive function of glia is regulated by signals released by neurons. 929 50

Klebsiella aerogenes strains with reduced levels of D-amino acid dehydrogenase not only fail to use alanine as a growth substrate but also become sensitive to alanine in minimal media supplemented with glucose and ammonium. The inability of these mutant strains to catabolize the alanine provided in the medium interferes with both pathways of glutamate production. Alanine derepresses the nitrogen regulatory system (Ntr), which in turn represses glutamate dehydrogenase, one pathway of glutamate production. Alanine also inhibits the enzyme glutamine synthetase, the first enzyme in the other pathway of glutamate production. Therefore, in the presence of alanine, strains with mutations in dadA (the gene that codes for a subunit of the dehydrogenase) exhibit a glutamate auxotrophy when ammonium is the sole source of nitrogen. The alanine catabolic operon of Klebsiella aerogenes, dadAB, was cloned, and its DNA sequence was determined. The clone complemented the alanine defects of dadA strains. The operon has a high similarity to the dadAB operon of Salmonella typhimurium and the dadAX operon of Escherichia coli, each of which codes for the smaller subunit of D-amino acid dehydrogenase and the catabolic alanine racemase. Unlike the cases for E. coli and S. typhimurium, the dad operon of K. aerogenes is activated by the Ntr system, mediated in this case by the nitrogen assimilation control protein (NAC). A sequence matching the DNA consensus for NAC-binding sites is located centered at position -44 with respect to the start of transcription. The promoter of this operon also contains consensus binding sites for the catabolite activator protein and the leucine-responsive regulatory protein.
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PMID:Alanine catabolism in Klebsiella aerogenes: molecular characterization of the dadAB operon and its regulation by the nitrogen assimilation control protein. 945 58

Although glutamine is a major carbon source for mammalian cells in culture, its chemical decomposition or cellular metabolism leads to an undesirable excess of ammonia. This limits the shelf-life of glutamine-supplemented media and may reduce the cell yield under certain conditions. We have attempted to develop a less ammoniagenic medium for the growth of BHK-21 cells by a mole-to-mole substitution of glutamine by glutamate. This results in a medium that is thermally stable but unable to support an equivalent growth yield. However, supplementation of the glutamate-based medium with asparagine (3 mM) and a minimal level of glutamine (0.5 mM) restored the original growth capacity of the cultures. Substitution of the low level of glutamine with the glutamine dipeptides, ala-gln (1 mM), or gly-gln (3 mM) resulted in an equivalent cell yield and in a thermally stable medium. The ammonia accumulation in cultures with glutamate-based medium was reduced significantly (>60%). Factors mediating growth and adaptation in medium substituted with glutamate were also investigated. The maximum growth capacity of the BHK-21 cells in glutamate-based medium (without glutamine) was achieved after a period of adaptation of 5 culture passages from growth in glutamine-based cultures. Adaptation was not influenced by increases in glutamate uptake which was constitutively high in BHK cells. Adaptation was associated with changes in the activities of enzymes involved in glutamate or glutamine metabolism. The activities of glutamine synthetase (GS) and alanine aminotransferase (ALT) increased significantly and the activity of phosphate-activated glutaminase (PAG) decreased significantly. The activity of glutamate dehydrogenase (GDH) showed no significant change after adaptation to glutamate. These changes resulted in an altered metabolic profile which included a reduced ammonia production but an increased alanine production. Alanine production is suspected of being an alternative route for removal of excess nitrogen.
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PMID:The adaptation of BHK cells to a non-ammoniagenic glutamate-based culture medium. 1039 67

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