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)

Ammonia is known to inhibit the steady-state rate of oxidation of L-glutamate catalyzed by glutamate dehydrogenase. We reported previously [Brown, A., Colen, A. H., & Fisher, H. F. (1978) Biochemistry 17, 2031] kinetic evidence supporting the formation in the initial rapid phase of a complex which is composed of enzyme, reduced coenzyme, alpha-ketoglutarate, and ammonia. We show here that the effects of ammonia on the steady-state reaction can be correlated with transient-state kinetic effects related to the concentration of that ammonia-containing complex. These results indicate the existence of alternate reaction pathways which become important at high ammonia concentrations. These new pathways provide an additional route for the release of NADPH from the enzyme surface. The expanded mechanism shows that the noncompetitive product inhibition by ammonia can occur without the simultaneous presence of ammonia and L-glutamate on the enzyme. This mechanism also accommodates the observed substrate inhibition by L-glutamate.
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PMID:Effect of ammonia on the glutamate dehydrogenase catalyzed oxidative deamination of L-glutamate. The steady state. 51 77

1. The concentration of HCO3- (independent of any change of pH) exerts different effects on glutamine metabolism in rat kidney-cortex tubules, hepatocytes and enterocytes.2. In kidney tubules HCO3- (10.5-50 MM) has no effect on glutaminase (EC 3.5.1.2), whereas glutamate dehydrogenase (EC 1.4.1.3) is inhibited as HCO3- concentration is increased. The result is that flux through the entire glutamate-to-glucose pathway is inhibited by increasing HCO3- concentrations. A large proportion (more than 30%) of the glutamine removed undergoes complete oxidation. 3. In hepatocytes, and to a smaller extent in enterocytes, HCO3- is an accelerator of glutaminase. Synthesis of glucose and urea from glutamine in hepatocytes increases as HCO3- concentration is increased. Calculations show that fumarate, formed via aspartate aminotransferase and arginino-succinate lyase, is the precursor of the glucose. There is no complete oxidation of the carbon skeleton of glutamine in hepatocytes. 4. Leucine at near-physiological concentrations (0.1-1 mM) is an accelerator of glutaminase in hepatocytes, but not in kidney tubules or in enterocytes. 5. The results are discussed in relation to regulation of acid/base balance in vivo.
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PMID:A role for bicarbonate in the regulation of mammalian glutamine metabolism. 54 52

Stopped-flow studies of the initial burst of NADPH production accompanying the oxidative deamination of L-glutamate by L-glutamate dehydrogenase and NADP+ were performed in the presence of alpha-ketoglutarate, a product of the reaction. Both binary enzyme-alpha-ketoglutarate and ternary enzyme--NADP+-alpha-ketoglutarate complexes are inhibitory in the burst presence of the enzyme-catalyzed reaction. Order-of-addition experiments show the binary complex to form rapidly, in the 3 ms dead time of the stopped-flow instrument. There is a distinct lag, however, in the achievement of the full ternary complex inhibitory effect unless the enzyme is preincubated with both NADP+ and alpha-ketoglutarate prior to initiation of the catalytic reaction with L-glutamate. The formation of an inhibitory enzyme--NADP+-alpha-ketoglutarate complex appears to be sufficiently slow to give a delayed kinetic response when alpha-ketoglutarate is added to the reaction system.
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PMID:Transient-state kinetics of L-glutamate dehydrogenase: mechanism of alpha-ketoglutarate inhibition in the burst phase. 56 27

This communication describes the isolation and characterization of mutants of Rhizobium trifolii which can induce nitrogenase activity in defined liquid medium. Two procedures were used for the isolation of these mutants from R. trifolii strain DT-6: (1) following chemical mutagenesis, slow growing mutants were selected which were unable to utilize NH+4 as sole source of nitrogen; (2) as spontaneous mutants resistant to the glutamate analogue L-methionine-DL-sulfoximine. Mutants (DT-71, DT-125) isolated by these procedures induced nitrogenase activity in the free-living state, whereas the parent strain lacked this property. Induction of nitrogenase activity in these mutants occurred during the late exponential phase of growth when the rate of protein synthesis was decreasing. The addition of NH+4 to a medium containing glutamate as the nitrogen-source resulted in a 50--70% reduction (repression?) of nitrogenase activity; in contrast, the rate of protein synthesis or the rate of respiration was not influenced by exogenous NH+4. Biochemical analysis showed that these mutants (strains DT-71 and DT-125) have defects in both nitrogen and carbon metabolism. The levels of glutamate synthase (both NADP+ -and NAD+ -dependent activities) and glutamate dehydrogenase (NAD+-dependent activity) were markedly lower. In addition, the mutants were found to have no detectable ribitol dehydrogenase or beta-galactosidase activity. These findings are discussed in relation to a mechanism of regulation of symbiotic nitrogen fixation.
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PMID:Regulation of nitrogen fixation in Rhizobium spp. Isolation of mutants of Rhizobium trifolii which induce nitrogenase activity. 58 92

1. The presence of glutamate dehydrogenase in the microsomal fraction of rat liver was confirmed. The identities of mitochondrial and microsomal glutamate dehydrogenases were proved by immunochemical methods and by SDS polyacrylamide gel electrophoresis of purified enzymes. 2. Synthesis of glutamate dehydrogenase by the membrane-bound ribosomes of rough endoplasmic reticulum was determined. Newly synthesized enzyme molecules were discharged on the cytoplasmic surface of endoplasmic reticulum membranes. 3. A precursor-product relationship was found between microsomal and mitochondrial glutamate dehydrogenases. About six hours were needed for the transport of glutamate dehydrogenase from the site of synthesis to mitochondria. 4. The half-life of glutamate dehydrogenase was about 5.5 days, which was somewhat longer than that of mitochondrial total protein determined in the same experiment. 5. Mitochondrial-type malate dehydrogenase was also present in the microsomal fraction. Subfractionation of smooth microsomes revealed the existence of particular light microsomal vesicles in which both glutamate dehydrogenase and malate dehydrogenase were concentrated. These vesicles may participate in intracellular transport of matrix enzymes from microsomes to mitochondria.
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PMID:Biogenesis of the mitochondrial matrix enzyme, glutamate dehydrogenase, in rat liver cells. I. Subcellular localization, biosynthesis, and intracellular translocation of glutamate dehydrogenase. 59 7

1. The pathway of glutamate metabolism in non-synaptic rat brain mitochondria was investigated by measuring glutamate, aspartate and ammonia concentrations and oxygen uptakes in mitochondria metabolizing glutamate or glutamine under various conditions. 2. Brain mitochondria metabolizing 10mm-glutamate in the absence of malate produce aspartate at 15nmol/min per mg of protein, but no detectable ammonia. If amino-oxyacetate is added, the aspartate production is decreased by 80% and ammonia production is now observed at a rate of 6.3nmol/min per mg of protein. 3. Brain mitochondria metabolizing glutamate at various concentrations (0-10mm) in the presence of 2.5mm-malate produce aspartate at rates that are almost stoicheiometric with glutamate disappearance, with no detectable ammonia production. In the presence of amino-oxyacetate, although the rate of aspartate production is decreased by 75%, ammonia production is only just detectable (0.3nmol/min per mg of protein). 4. Brain mitochondria metabolizing 10mm-glutamine and 2.5mm-malate in States 3 and 4 were studied by using glutamine as a source of intramitochondrial glutamate without the involvement of mitochondrial translocases. The ammonia production due to the oxidative deamination of glutamate produced from the glutamine was estimated as 1nmol/min per mg of protein in State 3 and 3nmol/min per mg of protein in State 4. 5. Brain mitochondria metabolizing 10mm-glutamine in the presence of 1mm-amino-oxyacetate under State-3 conditions in the presence or absence of 2.5mm-malate showed no detectable aspartate production. In both cases, however, over the first 5min, ammonia production from the oxidative deamination of glutamate was 21-27nmol/min per mg of protein, but then decreased to approx. 1-1.5nmol/min per mg. 6. It is concluded that the oxidative deamination of glutamate by glutamate dehydrogenase is not a major route of metabolism of glutamate from either exogenous or endogenous (glutamine) sources in rat brain mitochondria.
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PMID:The pathway of glutamate metabolism in rat brain mitochondria. 60 50

Using renal cortical slices from acidotic and normal dogs we show that fatty acids such as crotonate, octanoate, palmitate and oleate as well as ketone bodies (beta-hydroxybutyrate and acetoacetate) in concentrations ranging from 0.5 to 5.0 mM induce a 30 to 50% decrease in glutamine uptake and ammonia production when glutamine (1 mM) is used as the basic substrate. Glucose production also decreases by 20 to 30%. Glutamate release in the incubation medium is significantly augmented by fatty acids or ketones. When glutamate 5 mM is used as substrate instead of glutamine, glutamate uptake, ammoniagenesis and glucose production are significantly depressed by fatty acids and ketones. Increased glutamate release from glutamine, decreased glutamate uptake and decreased gluconeogenesis from glutamine or glutamate provide evidence that ketone bodies and fatty acids depress the net flux through the glutamate dehydrogenase reaction invovled in glutamine metabolism. This is further supported by the fact that addition of ketones to alpha-ketoglutarate and ammonia stimulates net glutamate synthesis by kidney tubules.
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PMID:Relationship between the renal metabolism of glutamine, fatty acids and ketone bodies. 61 72

The enthalpy change for the oxidative deamination of glutamate by NADP+ catalyzed by bovine liver glutamate dehydrogenase has been determined calorimetrically. The deltaH0 values are 64.6 +/- 1.2 kJ/mol and 70.3 +/- 1.2 kJ/mol at 25 and 35 degrees C respectively. The equilibrium constants for the reaction at the two temperatures were determined spectrophotometrically. This enabled the determination of deltaG0 and deltaS0 of the reaction as well. deltaH0 values were also determined for the reaction using an alternative coenzyme and the deuterated substrate.
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PMID:Thermodynamics of the glutamate dehydrogenase catalytic reaction. 62 77

The metabolism of proline was studied in liver cells isolated from starved rats. The following observations were made. 1. Consumption of proline could be largely accounted for by production of glucose, urea, glutamate and glutamine. 2. At least 50% of the total consumption of oxygen was used for proline catabolism. 3. Ureogenesis and gluconeogenesis from proline could be stimulated by partial uncoupling of oxidative phosphorylation. 4. Addition of ethanol had little effect on either proline uptake or oxygen consumption, but strongly inhibited the production of both urea and glucose and caused further accumulation of glutamate and lactate. Accumulation of glutamine was not affected by ethanol. 5. The effects of ethanol could be overcome by partial uncoupling of oxidative phosphorylation. 6. The apparent K(m) values of argininosuccinate synthetase (EC 6.3.4.5) for aspartate and citrulline in the intact hepatocyte are higher than those reported for the isolated enzyme. 7. 3-Mercaptopicolinate, an inhibitor of phosphoenolpyruvate carboxykinase (EC 4.1.1.32), greatly enhanced cytosolic aspartate accumulation during proline metabolism, but inhibited urea synthesis. 8. It is concluded that when proline is provided as a source of nitrogen to liver cells, production of ammonia by oxidative deamination of glutamate is inhibited by the highly reduced state of the nicotinamide nucleotides within the mitochondria. 9. Conversion of proline into glucose and urea is a net-energy-yielding process, and the high state of reduction of the nicotinamide nucleotides is presumably maintained by a high phosphorylation potential. Thus when proline is present as sole substrate, the further oxidation of glutamate by glutamate dehydrogenase (EC 1.4.1.3) is limited by the rate of energy expenditure of the cell.
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PMID:Prolone metabolism in isolated rat liver cells. 64 9

We have studied the effects of ammonium acetate on the transient "burst" phase of the oxidation of L-glutamate by glutamate dehydrogenase. Two measurable changes are observed in the "burst" phase as ammonium acetate concentration is increased: (i) an increase in the apparent first-order rate constant, kapp, and (ii) a decrease in the amplitude of the absorbance change measured at 320 nm. The increase in kapp shows a hyperbolic dependence on ammonium acetate concentration and is independent of glutamate concentration. The results demonstrate the existence of an intermediate immediately following hydrogen transfer. The intermediate contains enzyme, reduced coenzyme, ammonia, and alpha-ketoglutarate moieties and is in equilibrium with the known complex consisting of enzyme, reduced coenzyme, and alpha-ketoglutarate. At high concentrations of ammonium acetate, the equilibrium favors the ammonia containing complex.
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PMID:Effect of ammonia on the glutamate dehydrogenase catalyzed oxidative deamination of L-glutamate: production of an ammonia-containing intermediate in the "burst" phase. 65 77

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