Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.4.3.11 (glutamate dehydrogenase)
 4,437 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The in vivo activity of glutamate dehydrogenase (GDH) in the direction of reductive amination was measured in rat brain at steady-state concentrations of brain ammonia and glutamate after intravenous infusion of the substrate 15NH4+. The in vivo rate was determined from the steady-state fractional 15N enrichment of brain ammonia, measured by selective observation of 15NH4+ protons in brain extract by 1H-15N heteronuclear multiple-quantum coherence transfer NMR, and the rate of increase of brain [15N]glutamate and [2-15N]glutamine measured by 15N NMR. The in vivo GDH activity was 0.76-1.17 mumol/h/g, and 1.1-1.2 mumol/h/g at 1.0 +/- 0.17 mumol/g. Comparison of the observed in vivo GDH activity with the in vivo rates of glutamine synthesis and of phosphate-activated glutaminase suggests that, under mild hyperammonemia, GDH-catalyzed de novo synthesis can provide a minimum of 19% of the glutamate pool that is recycled from neurons to astrocytes through the glutamate-glutamine cycle.
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PMID:Steady-state in vivo glutamate dehydrogenase activity in rat brain measured by 15N NMR. 755

A new procedure for the analysis and detection of phosphate-activated glutaminase (EC 3.5.1.2) by native electrophoresis has been developed. The method is based on the in situ detection of glutaminase activity in two different systems of native polyacrylamide gradient gels, containing 3-(3-cholamidopropyl)-dimethyl-ammonio-1-propane sulfonate (CHAPS) or Triton X-100 as nondenaturant detergents. Crude Triton X-100 extracts of mitochondria were resolved by electrophoresis. The enzyme was specifically revealed by incubation of the gel with glutamine and coupling the oxidation of the glutamate formed to the reduction of a tetrazolium dye, in the presence of glutamate dehydrogenase trapped in a 1% agar solid overlay. Both Ehrlich ascitic cell and mouse kidney glutaminases were resolved by native electrophoresis and specifically detected with the activity staining. Moreover, the redox-cycling staining was tested in solution, showing linearity with the amount of glutamate or glutaminase activity present. The method described could be a useful tool for native polyacrylamide gel electrophoresis of membrane proteins.
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PMID:Native polyacrylamide gel electrophoresis of membrane proteins: glutaminase detection after in situ specific activity staining. 768 75

In renal ammoniagenesis, two major pathways of glutamine metabolism have been described: (i) intracellular metabolism by phosphate-dependent glutaminase (PDG) and glutamate dehydrogenase and (ii) extracellular metabolism by phosphate-independent glutaminase. The latter has been identified as the hydrolytic activity of the apically membrane-bound gamma-glutamyl transpeptidase (gamma-GT). The growth properties of cultured renal epithelia enable the study of in vitro extracellular metabolic properties occurring at the apical epithelial surface in the culture dish. Therefore, confluent epithelia of the LLC-PK1 renal epithelial cell line were used to elucidate the role of extracellular (apical) hydrolysis of glutamine by gamma-GT in LLC-PK1 ammonia production. To distinguish between intra- and extracellular metabolism of glutamine, confluent LLC-PK1 epithelia were incubated with either D-glutamine as substrate, which cannot be metabolized intracellularly by PDG, or with L-glutamine and hippurate to stimulate, and AT-125 (acivicin) to inhibit gamma-GT activity, respectively. In addition, cellular uptake of the glutamate, extracellularly formed by gamma-GT, was inhibited by D-aspartate. D-Glutamine (2 mM) did not increase ammonia formation above endogenous production levels, indicating the negligible role of extracellular hydrolysis of glutamine by gamma-GT. After modulating gamma-GT activity by hippurate or AT-125, almost identical ammonia production rates were found within the various experimental protocols, further confirming that extracellular metabolism of glutamine does not significantly contribute to LLC-PK1 ammoniagenesis.
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PMID:Ammoniagenesis in renal cell culture. Lack of extracellular ammoniagenesis at the apical surface of LLC-PK1 epithelia. 768 42

The precise mechanism(s) of action of PTH, insulin or glucagon in the regulation of renal glutamine and ammonia metabolism is unknown. Our aim was to delineate the effects and the site(s) of action of these hormones on renal glutamine metabolism. Experiments were carried out using OK cells as a model system. Cell cultures were incubated for three hours in a bicarbonate buffer of pH 7.4 supplemented with either 1 mM [2-15N] or [5-15N] glutamine and 10(-7) M PTH, insulin or glucagon. Comparative studies were performed at pH 6.8, 7.4 or 7.6 without hormone. PTH and acute acidosis significantly stimulated glutamine metabolism via both the phosphate-dependent glutaminase (PDG) and glutamate dehydrogenase (GLDH) pathways. The opposite was observed at pH 7.6. Insulin augmented flux via PDG with little effect on the GLDH pathway. Glucagon had insignificant effects on either PDG or GLDH pathways. Intracellular [15N] glutamate formed from [2-15N] glutamine was removed partially by transamination to alanine, aspartate and serine and partially by translocation to an extracellular compartment. Acidosis, PTH and insulin enhanced the formation of [15N] alanine with little effect on [15N] aspartate. PTH, insulin and glucagon significantly stimulated the production of [15N]serine, whereas acidosis had little effect. The translocation of intracellular glutamate was significantly increased by acidosis, PTH and insulin and decreased by acute alkalosis. The data indicate that: (a) PTH mimicks the effect of acute acidosis on renal glutamine metabolism, that is, augmented glutamine metabolism through both PDG and GLDH pathways and stimulated the output of intracellular glutamate. This effect might be mediated via decreased activity of the Na(+)-H+ exchanger associated with cellular acidification and/or through a second messenger; (b) insulin, but not glucagon, increased glutamine uptake and metabolism, and simultaneously enhanced output of intracellular glutamate sufficiently to stimulate the PDG pathway; and (c) overall, glucagon had little effect on glutamine metabolism by OK cells compared with either PTH or insulin.
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PMID:Hormonal regulation of glutamine metabolism by OK cells. 773 Nov 75

The mechanisms whereby prostaglandin F2 alpha (PGF2 alpha) and the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) inhibit ammoniagenesis and the reason why they behave differently at pH 7.4, were examined with (15N)glutamine to assess the metabolic pathways and 2'-7'-bis(2-carboxyethyl)-5-(and-6)-carboxylfluorescein, acetoxymethylester (BCECF-AM) to evaluate Na+/H+ antiporter activity. LLC-PK1 cultures were incubated for 1 h in a Krebs-Hensleit bicarbonate buffer of pH 7.4 and pH 6.8 supplemented either with 5-15N- or 2-15N-labeled glutamine, followed by the assessment of (15N)ammonia and (15N)amino acid formation. Exposure of cells to either PGF2 alpha or TPA completely inhibited the low pH-induced increases in (15N)ammonia formation from incubations with 5-15N, reflecting reduced flux through the mitochondrial phosphate-dependent glutaminase, and from (2-15N)glutamine, reflecting reduced flux through the mitochondrial glutamate dehydrogenase pathway. They also qualitatively reversed the acute acidosis-induced changes in (15N)alanine formation and (15N)glutamate accumulation in the media. By contrast only TPA, but not PGF2 alpha, modified glutamine metabolism at pH 7.4. Na+/H+ antiporter activity was assessed under both acidified and basal (pH 7.4) conditions by measuring changes in intracellular pH in cells loaded with BCECF. TPA and PGF2 alpha both stimulated Na+/H+ antiporter activity comparably under acidified conditions. When cells were studied at pH 7.4, TPA but not PGF2 alpha stimulated the Na+/H+ antiporter and increased steady-state intracellular pH.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Prostaglandin F2 alpha- and 12-O-tetradecanoylphorbol-13-acetate-induced alterations in the pathways of renal ammoniagenesis. 778 46

The in vivo activity of phosphate-activated glutaminase (PAG) was measured in the brain of hyperammonaemic rat by 15N n.m.r. Brain glutamine was 15N-enriched by intravenous infusion of 15NH4+ until the concentration of [5-15N]glutamine reached 6.1 mumol/g. Further glutamine synthesis was inhibited by intraperitoneal injection of methionine-DL-sulphoximine, an inhibitor of glutamine synthetase, and the infusate was changed to 14NH4+ during observation of decrease in brain [5-15N]glutamine due to PAG and other glutamine utilization pathways. Progressive decrease in brain [5-15N]glutamine, PAG-catalysed production of 15NH4+ and its subsequent assimilation into glutamate by glutamate dehydrogenase were monitored in vivo by 15N n.m.r. Brain [5-15N]glutamine (15N enrichment of 0.35-0.50) decreased at a rate of 1.2 mumol/h per g of brain. The in vivo PAG activity, determined from the observed rate and the quantity of 15NH4+ produced and subsequently assimilated into glutamate and aspartate, was 0.9-1.3 mumol/h per g. This activity is less than 1.1% of the reported activity in vitro measured in rat brain homogenate at a 10 mM concentration of the activator Pi. Inhibition by ammonia (brain level 1.4 mumol/g) alone does not account for the observed low activity in vivo. The result strongly suggests that, in intact brain, PAG activity is maintained at a low level by a suboptimal in situ concentration of Pi and the strong inhibitory effect of glutamate. The observed PAG activity in vivo is lower than the reported in vivo activity of glutamate decarboxylase which converts glutamate into gamma-aminobutyrate (GABA). The result suggests that PAG-catalysed hydrolysis of glutamine is not the sole provider of glutamate used for GABA synthesis.
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PMID:In vivo activity of glutaminase in the brain of hyperammonaemic rats measured by 15N nuclear magnetic resonance. 782 49

Glutamine is actively metabolized in human platelets, representing a preferential mitochondrial oxidative substrate in these cells. The primary importance of this metabolic route of glutamine is further confirmed here by the observation that platelet glutaminase activity is entirely represented by the phosphate dependent glutaminase or glutaminase I, most probably localized in the mitochondrial platelet fraction and classified by kinetic analysis as a kidney-type form. The following step of the glutamine metabolizing pathway, allowing the entrance of the amino acid skeleton carbons in the Krebs cycle, might be catalyzed by both glutamate dehydrogenase and aspartate transaminase, the first being entirely mitochondrial and the latter 65% mitochondrial. We also investigated platelets for the presence of one or more specific transport systems involved in glutamine uptake and we present the first evidence for two glutamine transport systems in human platelets that by inhibition analysis appear to share characteristics with the Na(+)-dependent ASC system and the Na(+)-independent L system for dipolar amino acid uptake. Both systems display affinity characteristics for glutamine in the range of plasma glutamine concentration and may thus have physiological relevance for the uptake of the amino acid in these cells.
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PMID:Glutamine transport and enzymatic activities involved in glutaminolysis in human platelets. 782 6

We measured ammonium production rates, phosphate-dependent glutaminase (PDG) activity, and glutamate dehydrogenase (GDH) activity in microdissected S1 proximal tubules of rats to investigate the role of adaptations of PDG activity and GDH activity in response to a step increase in acid intake. In vivo ammonium excretion increased much more rapidly than did single-tubule ammonium production in vitro or ammoniagenic enzyme activities measured in microdissected tubules, manifesting an 85-fold increase in the first 24 h. In vitro ammonium production rates in microdissected tubules rose only twofold in the first 24 h, fourfold by day 2, and fivefold by day 4 of acid loading. The adaptation of PDG activity paralleled the increase in single-tubule ammoniagenic capacity measured in vitro. GDH activity, on the other hand, did not change significantly even after 4 days of acid loading. From these observations, we conclude that 1) the adaptation of in vitro ammoniagenic capacity in S1 proximal tubules is temporally associated with an adaptation in PDG activity and not GDH activity, and 2) a major portion of the increased ammonium excretion seen in the first 24 h is due to factors other than an adaptive increase in ammoniagenic enzyme activity.
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PMID:Dissociation of ammoniagenic enzyme adaptation in rat S1 proximal tubules and ammonium excretion response. 809 54

Interorgan glutamine and associated metabolite fluxes were measured across the gut and liver to delineate splanchnic bed fluxes secondary to enhanced arterial loads mobilized in the periphery by glucocorticoid. Experiments were performed on adrenalectomized rats since adrenalectomy doubled the hepatic glucocorticoid receptor population compared with intact animals. Under these conditions, triamcinolone supplement (40 micrograms.day-1.100 g body wt-1) enhanced the combined net glutamine uptake by gut and liver eightfold, whereas combined gut and liver unidirectional breakdown and synthesis fluxes both increased (3.4- and 7.4-fold, respectively). Triamcinolone supplement also altered the pattern of metabolite released; gut released predominantly ammonium and some alanine, whereas the liver removed more alanine along with glutamine and released more urea, glutamate, and glutathione. Mechanistically, enhanced cellular glutamine uptake could be attributed to a three- to fourfold acceleration of glutamine transport associated with a rise in intracellular glutamine content. However, uptake by isolated membrane vesicles revealed only a small (27%) increase in System N activity, whereas extraction and reconstitution of the transporter into proteoliposomes failed to demonstrate increased transporter activity. Similarly, activity of phosphate-dependent glutaminase and glutamate dehydrogenase increased in crude homogenates (2-fold), but the former disappears in completely disrupted preparations. Furthermore, whereas messenger RNA and assayable enzymic activity for glutamate dehydrogenase clearly increased with glucocorticoid, glutaminase message was less significantly increased. Thus glucocorticoid appears directly capable of accelerating hepatic glutamine extraction primarily by modulating transporter activity that is closely coupled to glutamine utilization.
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PMID:Glucocorticoid regulation of splanchnic glutamine, alanine, glutamate, ammonia, and glutathione fluxes. 809 75

The role of extracellular glutamate formation as opposed to cellular glutamate removal in regulating monolayer glutamate content in response to metabolic acidosis was studied in LLC-PK1-F+ cells. Exposure to metabolic acidosis (14 mM bicarbonate; pH 7.1) for 18 h resulted in 24% fall in monolayer glutamate content. Of this, approximately one-half could be attributed to enhanced glutamate removal via glutamate dehydrogenase, consistent with a rise in ammonium production. The remainder appears due to reduced extracellular glutamate formation as a consequence of diminished gamma-glutamyltranspeptidase (gamma-Gt) activity. Metabolic acidosis, but not respiratory acidosis, resulted in a 33% fall in gamma-Gt activity and a proportional fall in extracellular glutamate formation; glutamate transport into these cells was not rate limiting in acidosis. Overall glutamine utilization decreased 36%, reflecting the fall in gamma-Gt activity as well as a decrease in a pH-sensitive glutamine uptake, whereas glutamine transport coupled to the phosphate-dependent glutaminase flux increased. It is noteworthy that the increased ammonium produced in metabolic acidosis was preferentially secreted into the apical compartment; acid secretion, but not production, was similarly increased. Thus reduced cellular glutamate appears to coordinate activation of intracellular glutaminase to the apical membrane exchanger, consistent with the functioning kidney response to metabolic acidosis.
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PMID:Response of LLC-PK1-F+ cells to metabolic acidosis. 863 75


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