EC:1.4.3.11 - FACTA Search

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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)

Pathophysiological concentrations of ammonia, both in vivo and in vitro, suppressed the oxidation of glutamate by rat cerebellar mitochondria. The transport of glutamate into mitochondria was either unaltered or enhanced during hyperammonemic states. Activities of mitochondrial enzymes, aspartate aminotransferase, alanine aminotransferase, glutamate dehydrogenase, glutaminase, and GABA-transaminase were suppressed during hyperammonemic states. Suppression of 14CO2 production with (aminooxy)acetic acid but not with glutamic acid diethyl ester indicated that transamination but not oxidative deamination of glutamate plays a major role in glutamate oxidation during normal and hyperammonemic states.
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PMID:Transport and metabolism of glutamate by rat cerebellar mitochondria during ammonia toxicity. 810 3

Alterations in the glutamate metabolism during Newcastle disease virus (NDV) infection were studied in different brain regions of chick. The glutamate dehydrogenase, the glutamine synthetase, the glutamic acid decarboxylase activities were decreased and the glutamine content was decreased in all brain regions of chick after 24 hr. and 72 hr. of NDV infection. The results obtained in the present study reveal that the glutamate metabolism and its conversion to GABA were operated in low profile during NDV infection.
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PMID:The fate of glutamate in different brain regions of the chick during Newcastle disease virus infection. 885 May 16

In type I (insulin-dependent) diabetes, destruction of pancreatic beta cells has been associated with the presence of circulating antibodies against glutamate decarboxylase (GAD), a GABA (gamma-aminobutyric acid) synthesizing enzyme which is located in the beta cells. We examined whether destruction of islet beta cells can lead to discharge of GAD in the extracellular medium, making it a potential autoantigen. Rat islet beta cells were first exposed for 1 hour to streptozotocin and then cultured for 4 to 24 hours before cellular and medium GAD activities were measured. After 24 hours culture, 70 percent of streptozotocin-treated beta cells were disintegrated whereas the number of control cells remained unchanged. Control cells exhibited a stable cellular GAD activity over the 24 hour period with no enzyme activity detectable in their culture medium. The cells recovered 24 hours after streptozotocin treatment exhibited 10-fold lower levels of GAD-activity and of GABA; their culture medium contained GAD, its enzymatic activity reaching peak values after 10 hours. The beta-cell enzymes glutamate dehydrogenase and glyceraldehyde-3-phosphate dehydrogenase were not detectable in the medium of control or streptozotocin-treated cells. Similar observations were made when beta cells had been exposed to cytotoxic concentrations of alloxan. It is concluded that damage to rat islet beta cells results in transient discharge of GAD in the extracellular medium making this enzyme a candidate extracellular marker for beta cell toxic processes and a potential autoantigen for immune reactivity.
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PMID:Damaged rat beta cells discharge glutamate decarboxylase in the extracellular medium. 892 Sep 8

Replication-defective Moloney murine leukemia virus expressing the GAD67 gene under the control of the GFAP promoter was produced using selected clones of a fibroblast-packaging cell line. A spontaneously immortalized astrocyte cell line was infected with this virus and cellular clones expressing GAD67 selected. Astrocyte and fibroblast clones expressed functional GAD (detected by glutamic acid decarboxylation), but only fibroblasts were able to also produce GABA in the extracellular medium. When exposed to 200 microM glutamate, despite an observed difference in the rates of glutamate accumulation in control and GAD67-expressing astrocytes, similar proportions of glutamate taken up were detected. In GAD67-expressing astrocytes, the glutamate was mainly converted into GABA, suggesting GAD transgene activity to be dominant over other glutamate metabolic pathways, such as glutamine synthetase and glutamate dehydrogenase. Moreover, rapid GABA release into the cell medium was also observed, suggesting the involvement of reverse GABA transporters. The use of the GFAP promoter might be able to take advantage of its activation in response to factors inducing reactive gliosis observed in pathological insults. GAD67-expressing astrocytes might therefore be used for future grafting in pathological situations in which an excess of glutamate results in neuronal dysfunction or cell death.
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PMID:Glutamate-modulated production of GABA in immortalized astrocytes transduced by a glutamic acid decarboxylase-expressing retrovirus. 943 90

This review focuses on the role of acute pH changes in the regulation of Gln/Glu metabolism in the kidney, liver, and brain. Alterations of proton concentration ([H(+)]) profoundly affect flux through phosphate-dependent glutaminase (PDG) or glutamate dehydrogenase (GDH), the primary enzymes responsible for mitochondrial metabolism of glutamine and glutamate, respectively. In the kidney, acute acidosis stimulates Gln uptake and its metabolism via the PDG pathway. The Glu formed from Gln can be removed via 1) oxidative deamination through the GDH reaction, 2) transamination reactions, and 3) transport of Glu from intracellular to extracellular compartment, thereby diminishing the intramitochondrial pool of glutamate sufficiently to stimulate flux through the PDG pathway. Converse changes may occur with increased pH. In the liver, acidosis diminishes the rate of Gln and Glu metabolism via the PDG and GDH pathways, but stimulates glutamine synthesis (i.e., glutamine recycling). Alkalosis has little effect. Hepatic Gln metabolism via the PDG pathway has a central role in ureagenesis via 1) supplementation of nitrogen for the synthesis of carbamyl phosphate, and 2) providing glutamate for N-acetylglutamate synthesis. In the brain, Gln/Glu metabolism links ammonia detoxification and energy metabolism via 1) detoxification of ammonia and excess glutamate by glutamine synthesis in astrocytes, 2) formation and export of glutamine to neurons where it is metabolized to glutamate and GABA, and 3) production of alpha-ketoglutarate and lactate from Glu and their transport to neurons. Changes in intracellular pH associated with changes in cellular [K(+)] may have a key role in the regulation of these processes of glial-neuronal metabolism of Gln/Glu metabolism.
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PMID:Newer aspects of glutamine/glutamate metabolism: the role of acute pH changes. 1051 71

The significant role the amino acid glutamate assumes in a number of fundamental metabolic pathways is becoming better understood. As a central junction for interchange of amino nitrogen, glutamate facilitates both amino acid synthesis and degradation. In the liver, glutamate is the terminus for release of ammonia from amino acids, and the intrahepatic concentration of glutamate modulates the rate of ammonia detoxification into urea. In pancreatic beta-cells, oxidation of glutamate mediates amino acid-stimulated insulin secretion. In the central nervous system, glutamate serves as an excitatory neurotransmittor. Glutamate is also the precursor of the inhibitory neurotransmittor GABA, as well as glutamine, a potential mediator of hyperammonemic neurotoxicity. The recent identification of a novel form of congenital hyperinsulinism associated with asymptomatic hyperammonemia assigns glutamate oxidation by glutamate dehydrogenase a more important role than previously recognized in beta-cell insulin secretion and hepatic and CNS ammonia detoxification. Disruptions of glutamate metabolism have been implicated in other clinical disorders, such as pyridoxine-dependent seizures, confirming the importance of intact glutamate metabolism. This article will review glutamate metabolism and clinical disorders associated with disrupted glutamate metabolism.
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PMID:Disorders of glutamate metabolism. 1175 24

We have carried out a detailed examination of L-glutamine metabolism in rat islets in order to elucidate the paradoxical failure of L-glutamine to stimulate insulin secretion. L-Glutamine was converted by isolated islets into GABA (gamma-aminobutyric acid), L-aspartate and L-glutamate. Saturation of the intracellular concentrations of all of these amino acids occurred at approx. 10 mmol/l L-glutamine, and their half-maximal values were attained at progressively increasing concentrations of L-glutamine (0.3 mmol/l for GABA; 0.5 and 1.0 mmol/l for Asp and Glu respectively). GABA accumulation accounted for most of the 14CO2 produced at various L-[U-14C]glutamine concentrations. Potentiation by L-glutamine of L-leucine-induced insulin secretion in perifused islets was suppressed by malonic acid dimethyl ester, was accompanied by a significant decrease in islet GABA accumulation, and was not modified in the presence of GABA receptor antagonists [50 micromol/l saclofen or 10 micromol/l (+)-bicuculline]. L-Leucine activated islet glutamate dehydrogenase activity, but had no effect on either glutamate decarboxylase or GABA transaminase activity, in islet homogenates. We conclude that (i) L-glutamine is metabolized preferentially to GABA and L-aspartate, which accumulate in islets, thus preventing its complete oxidation in the Krebs cycle, which accounts for its failure to stimulate insulin secretion; (ii) potentiation by L-glutamine of L-leucine-induced insulin secretion involves increased metabolism of L-glutamate and GABA via the Krebs cycle (glutamate dehydrogenase activation) and the GABA shunt (2-oxoglutarate availability for GABA transaminase) respectively, and (iii) islet release of GABA does not seem to play an important role in the modulation of the islet secretory response to the combination of L-leucine and L-glutamine.
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PMID:Conversion into GABA (gamma-aminobutyric acid) may reduce the capacity of L-glutamine as an insulin secretagogue. 1476

Neurological dysfunction caused by traumatic brain injury results in profound changes in net synaptic efficacy, leading to impaired cognition. Because excitability is directly controlled by the balance of excitatory and inhibitory activity, underlying mechanisms causing these changes were investigated using lateral fluid percussion brain injury in mice. Although injury-induced shifts in net synaptic efficacy were not accompanied by changes in hippocampal glutamate and GABA levels, significant reductions were seen in the concentration of branched chain amino acids (BCAAs), which are key precursors to de novo glutamate synthesis. Dietary consumption of BCAAs restored hippocampal BCAA concentrations to normal, reversed injury-induced shifts in net synaptic efficacy, and led to reinstatement of cognitive performance after concussive brain injury. All brain-injured mice that consumed BCAAs demonstrated cognitive improvement with a simultaneous restoration in net synaptic efficacy. Posttraumatic changes in the expression of cytosolic branched chain aminotransferase, branched chain ketoacid dehydrogenase, glutamate dehydrogenase, and glutamic acid decarboxylase support a perturbation of BCAA and neurotransmitter metabolism. Ex vivo application of BCAAs to hippocampal slices from injured animals restored posttraumatic regional shifts in net synaptic efficacy as measured by field excitatory postsynaptic potentials. These results suggest that dietary BCAA intervention could promote cognitive improvement by restoring hippocampal function after a traumatic brain injury.
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PMID:Dietary branched chain amino acids ameliorate injury-induced cognitive impairment. 1999 60

100 mg of taurine per kg body weight had been administered intraperitoneally and 30 min after the administration the animals were sacrificed. Glutamate dehydrogenase, aspartate aminotransferase, alanine aminotransferase, glutaminase, glutamine synthetase, glutamate decarboxylase and GABA aminotransferase along with the content of glutamate and GABA in cerebral cortex, cerebellum and brain stem were studied and compared with the same obtained in the rats treated with normal saline in place of taurine. The results indicated a significant decrease in the activity of glutamate dehydrogenase in cerebral cortex and cerebellum and a significant increase in brain stem. Glutaminase and glutamine synthetase were found to increase significantly both in cerebral cortex and cerebellum. The activities of glutamate decarboxylase was found to increase in all the three regions along with a significant decrease in GABA aminotransferase while the content of glutamate showed a decrease in all the three brain regions, the content of GABA was observed to increase significantly. The above effects of taurine on the metabolism of glutamate and GABA are discussed in relation to the functional role of GABA and glutamate. The results indicate that taurine administration would result in a state of inhibition in brain.
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PMID:Acute metabolic effects of taurine on the enzymes metabolizing glutamate and gaba. 2049 55

Eight weeks of latent iron deficiency in weaned female rats of Sprague Dawley strain maintained on experimental low-iron diet (18-20 mg/Kg) did not significantly change the gross body weight and tissue weights of brain and liver. Packed cell volume (PCV) and hemoglobin concentration remained unaltered. However, non-heme iron content in liver and brain decreased significantly (P<0.001). The activities of glutamate dehydrogenase, glutamic acid decarboxylase, and GABA-transaminase (GABA-T) in brain decreased by 15%, 11.4% and 25.7% respectively. However, this decrease was not statistically significant. Binding of(3)H Muscimol at pH 7.5 and 1 mg protein/assay increased by 143% (P<0.001) in synaptic vesicular membranes from iron-deficient rats as compared to the controls.(3)H glutamate binding to the synaptic vesicles was also carried out under similar condition. However, the L-glutamate binding was reduced by 63% in the vesicular membranes of iron deficient animals. These studies in dicate that iron plays an important functional role in both excitatory and inhibitory neurotransmitter receptors.
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PMID:Effect of latent iron deficiency on gaba and glutamate neuroreceptors in rat brain. 2310 45

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