EC:6.3.2.3 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:6.3.2.3 (glutathione synthetase)
678 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The glutamate analog, alpha-aminomethylglutaric acid, was synthetized by Michael addition of ammonia to 2-methylene glutaronitrile followed by hydrolysis of the intermediate alpha-aminomethylglutaryl nitrile; the analog cyclizes readily on heating to 2-piperidone-5-carboxylic acid. Sheep brain glutamine synthetase utilizes one isomer of DL-alpha-aminomethylglutarate at about 10% of the rate with L-glutamate. gamma-Glutamylcysteine synthetase uses both isomers of DL-alpha-aminomethylglutarate, preferentially acting on the same isomer used by glutamine synthetase. gamma-(alpha-Aminomethyl)glutaryl-alpha-aminobutyrate, prepared enzymatically with gamma-glutamylcysteine synthetase, was found to be a substrate and an inhibitor of glutathione synthetase. alpha-Aminomethylglutarate does not inhibit gamma-glutamyl cyclotransferase and gamma-glutamyl transpeptidase appreciably. When alpha-aminomethylglutarate was administered to mice, there were substantial decreases in the levels of glutamine, glutathione, glutamate, and glycine in the kidney, and of glutamine and glutamate in the liver, indicating that this glutamate analog is effective as an inhibitor of glutamine and glutathione synthesis in vivo, and suggesting that it may also inhibit other enzymes.
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PMID:alpha-Aminomethylglutarate, a beta-amino analog of glutamate that interacts with glutamine synthetase and the enzymes that catalyze glutathione synthesis. 0 41

The concentrations of glutathione precursors in human erythrocytes were investigated. 300muM glutamate, 375 muM glycine, and 10muM cysteine were found by automated amino acid analysis. The concentration of 2-aminobutyrate, the precursor of ophthalmic acid, was 15muM. The influence of the activities of endogenous or added glutamyl-cysteine synthetase and glutathione synthetase on the rate of glutathione biosynthesis was measured in membrane-free hemolysates under physiological conditions. The results show that the rate of the overall biosynthesis mainly depends on the formation of the dipeptide glutamyl-cysteine. The effect of glutathione precursor concentrations on the synthesis of the tripeptide was investigated at constant (endogenous) activities of the synthesizing enzymes. The rate was not enhanced by addition of glutamate and/or glycine unless cysteine or glutamyl-cysteine was also added. It is concluded that the concentration of cysteine limits the actual rate of the glutamyl-cysteine-synthetase reaction in vivo. No cysteine or bis(glutamyl)cystine was detected in human hemolysate; however, these disulfides were converted to glutathione. This indicates that erythrocytes have an appropriate system for their reduction, since the disulfides themselves are not substrates for the glutathione-synthesizing enzymes. Studies with intact human red cells indicate that the uptake of cysteine is the rate-determining step in the biosynthesis of glutathione.
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PMID:[The biosynthesis of glutathione in human erythrocytes (author's transl)]. 1 76

Erythrocyte glutathione concentration increases dramatically in sheep when they become anemic. To determine the mechanism of this change in glutathione control, we measured the enzymes and substrates necessary for glutathione control, we measured the enzymes and substrates necessary for glutathione synthesis after acute blood loss in both low- (gamma-glutamylcysteine synthetase deficient) and high-glutathione sheep. Erythrocyte glutamate, ATP, and glycine increased dramatically in all sheep. Erythrocyte gamma-glutamylcysteine synthetase increased slowly and seemed unrelated to changes in glutathione. Erythrocyte glutathione synthetase and cysteine and plasma cysteine, glutamate and glycine did not change significantly. Apparently substrate concentrations may be important in regulating erythrocyte glutathione levels.
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PMID:Elevated erythrocyte glutathione associated with elevated substrate in high- and low-glutathione sheep. 1 66

GAMMA-Glutamyl transpeptidase, gamma-glutamyl cyclotransferase, L-pyrrolidone carboxylate hydrolase, gamma-glutamylcysteine synthetase and glutathione synthetase, the enzymes of the gamma-glutamyl cycle, were found in mouse brain, liver and kidney. The activity of L-pyrrolidone carboxylate hydrolase was many times lower than the activities of the other enzymes, and thus the conversion of L-pyrrolidone carboxylate to L-glutamate is likely to be the rate-limiting step of the cycle. The specificity of gamma-glutamyl cyclotransferase from mouse tissues was similar to that from rat tissues. The concentration of pyrrolidone carboxylate and gamma-glutamyl amino acids, intermediates of the gamma-glutamyl cycle, was determined by a gas chromatographic procedure coupled with electron capture detection. Administration of L-2-aminobutyrate, an amino acid that is utilized as substrate in the reaction catalyzed by gamma-glutamylcysteine synthetase, led to a large accumulation of gamma-glutamyl-2-aminobutyrate and pyrrolidone carboxylate in mouse tissues. L-Methionine-RS-sulfoximine, an inhibitor of gamma-glutamylcysteine synthetase, abolished the increase in concentration of pyrrolidone carboxylate. No accumulation of pyrrolidone carboxylate was observed after L-cysteine. The separate administration of several protein amino acids had little effect on the concentration of pyrrolidone carboxylate; however formation of small amounts of the corresponding gamma-glutamyl derivatives (e.g. gamma-glutamylmethionine and gamma-glutamylphenylalanine) was detected. These intermediates are probably formed by transpeptidation between glutathione and the corresponding amino acid, catalyzed by gamma-glutamyl transpeptidase. The concentration of pyrrolidone carboxylate increased significantly after administration of a mixture containing all protein amino acids, the highest increase occurring in the kidney. The results suggest that two separate pathways for the formation of gamma-glutamyl amino acids and pyrrolidone carboxylate exist in vivo. One of these results from the function of gamma-glutamylcysteine synthetase in glutathione synthesis. The other pathway involves the amino-acid-dependent degradation of glutathione, mediatedby gamma-glutamyl transpeptidase. Only very small amounts of free intermediates are apparently derived from the latter pathway, suggesting that the gamma-glutamyl amino acids formed in this pathway are either enzyme-bound or are directly hydrolyzed to glutamate and free amino acid.
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PMID:Intermediates of the gamma-glutamyl cycle in mouse tissues. Influence of administration of amino acids on pyrrolidone carboxylate and gamma-glutamyl amino acids. 23 63

Gamma-Glutamyl-cysteine synthetase is inhibited by glutathione under conditions similar to those which prevail in vivo, thus strongly suggesting a physiologically significant feedback mechanism. Inhibition by glutathione, which is not allosteric, appears to involve the binding of glutathione to the glutamate site of the enzyme as well as to another enzyme site; the latter binding appears to require a sulfhydryl group since ophthalmic acid (gamma-glutamyl-alpha-aminobutyryl-glycine) is only a weak inhibitor. The finding that glutathione regulates its own synthesis by inhibiting synthesis of gamma-glutamyl-cysteine appears to explain observations on patients with 5-oxoprolinuria, who were shown to have a block in the gamma-glutamyl cycle consisting of a marked deficiency of glutathione synthetase and consequently of glutathione. These patients produce greater than normal amounts of gamma-glutamyl-cysteine, which is converted by the action of gamma-glutamyl cyclotransferase to 5-oxoproline; production of the latter compound exceeds the capacity of 5-oxoprolinase to convert it to glutamate. The apparent Km value for L-cysteine for gamma-glutamyl-cysteine synthetase (0.35 mM) is not far from intracellular concentrations of L-cysteine suggesting that the availability of L-cysteine may also play a role in the regulation of glutathione synthesis.
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PMID:Regulation of gamma-glutamyl-cysteine synthetase by nonallosteric feedback inhibition by glutathione. 111 10

The primary metabolic defect in 5-oxoprolinuria (pyroglutamic aciduria) is the lack of glutathione synthetase. The mechanism of the concomitant overproduction of 5-oxoproline was studied using cell-free extracts of erythrocytes from control individuals and from patients with 5-oxoprolinuria. Such extracts catalyzed the synthesis of 5-oxoproline from L-glutamate. Addition of ATP, Mg ions and alpha-aminobutyrate was needed for optimal activity. The conversion of glutamate to 5-oxoproline occurred in two steps, catalyzed by gamma-glutamyl-cysteine synthetase and gamma-glutamyl cyclotransferase, respectively. Extracts of erythrocytes from control subjects and patients with 5-oxoprolinuria had identical capacity to synthesize 5-oxoproline. The conversion of glutamate to 5-oxoproline was markedly inhibited by reduced glutathione, which exerted its effect on the gamma-glutamyl-cysteine synthetase step. The following mechanism is postulated for the overproduction of 5-oxoproline in 5-oxoprolinuria: the deficiency of glutathione synthetase causes a lack of glutathione which is an essential feed-back inhibitor in the initial step of its biosynthesis. Therefore gamma-glutamyl-cysteine is produced in excessive amounts and it is subsequently converted to 5-oxoproline (and cysteine) by gamma-glutamyl cyclotransferase. This overproduction of 5-oxoproline exceeds the capacity of the 5-oxoprolinase and 5-oxoproline accumulates in body fluids.
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PMID:On the mechanism of 5-oxoproline overproduction in 5-oxoprolinuria. 126 Oct 42

We reported that glucagon and phenylephrine decrease hepatocyte GSH by inhibiting gamma-glutamylcysteine synthetase (GCS), the rate-limiting enzyme in GSH synthesis (Lu, S.C., J. Kuhlenkamp, C. Garcia-Ruiz, and N. Kaplowitz. 1991. J. Clin. Invest. 88:260-269). In contrast, we have found that insulin (In, 1 microgram/ml) and hydrocortisone (HC, 50 nM) increased GSH of cultured hepatocytes up to 50-70% (earliest significant change at 6 h) with either methionine or cystine alone as the sole sulfur amino acid in the medium. The effect of In occurred independent of glucose concentration in the medium. Changes in steady-state cellular cysteine levels, cell volume, GSH efflux, or expression of gamma-glutamyl transpeptidase were excluded as possible mechanisms. Both hormones are known to induce cystine/glutamate transport, but this was excluded as the predominant mechanism since the induction in cystine uptake required a lag period of greater than 6 h, and the increase in cell GSH still occurred when cystine uptake was blocked. Assay of GSH synthesis in extracts of detergent-treated cells revealed that In and HC increased the activity of GCS by 45-65% (earliest significant change at 4 h) but not GSH synthetase. In and HC treatment increased the Vmax of GCS by 31-43% with no change in Km. Both the hormone-mediated increase in cell GSH and GCS activity were blocked with either cycloheximide or actinomycin D. Finally, when studied in vivo, streptozotocin-treated diabetic and adrenalectomized rats exhibited lower hepatic GSH levels and GCS activities than respective controls. Both of these abnormalities were prevented with hormone replacement. Thus, both in vitro and in vivo, In and glucocorticoids are required for normal expression of GCS.
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PMID:Insulin and glucocorticoid dependence of hepatic gamma-glutamylcysteine synthetase and glutathione synthesis in the rat. Studies in cultured hepatocytes and in vivo. 135 65

The zonal distribution of GSH metabolism was investigated by comparing hepatocytes obtained from the periportal (zone 1) or perivenous (zone 3) region by digitonin/collagenase perfusion. Freshly isolated periportal and perivenous cells had similar viability (dye exclusion, lactate dehydrogenase leakage and ATP content) and GSH content (2.4 and 2.7 mumol/g respectively). During incubation, periportal cells slowly accumulated GSH (0.35 mumol/h per g), whereas in perivenous cells a decrease occurred (-0.14 mumol/h per g). Also, in the presence of either L-methionine or L-cysteine (0.5 mM) periportal hepatocytes accumulated GSH much faster (3.5 mumol/h per g) than did perivenous cells (1.9 mumol/h per g). These periportal-perivenous differences were also found in cells from fasted rats. Efflux of GSH was faster from perivenous cells than from periportal cells, but this difference only explained 10-20% of the periportal-perivenous difference in accumulation. Furthermore, periportal cells accumulated GSH to a plateau 26-40% higher than in perivenous cells. There was no significant difference in gamma-glutamylcysteine synthetase or glutathione synthetase activity between the periportal and perivenous cell preparations. The periportal-perivenous difference in GSH accumulation was unaffected by inhibition of gamma-glutamyl transpeptidase or by 5 mM-glutamate or -glutamine, but was slightly diminished by 2 mM-L-methionine. This suggests differences between periportal and perivenous cells in their metabolism and/or transport of (sulphur) amino acids. Our results suggest that a lower GSH replenishment capacity of the hepatocytes from the perivenous region may contribute to the greater vulnerability of this region to xenobiotic damage.
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PMID:Glutathione replenishment capacity is lower in isolated perivenous than in periportal hepatocytes. 290 50

Perchloric acid extracts of LLC-PK1/Cl4 cells, a renal epithelial cell line, incubated with either [2-13C]glycine L-[3-13C]alanine, or D,L-[3-13C]aspartic acid were investigated by 13C-NMR spectroscopy. All amino acids, except labelled glycine, gave rise to glycolytic products and tricarboxylic acid cycle (TCA) intermediates. For the first time we also observed activity of gamma-glutamyltransferase activity and glutathione synthetase activity in LLC-PK1 cells, as is evident from enrichment of reduced glutathione. Time courses showed that only 6% of the labelled glycine was utilized in 30 min, whereas 31% of L-alanine and 60% of L-aspartic acid was utilized during the same period. 13C-NMR was also shown to be a useful tool for the determination of amino acid uptake in LLC-PK1 cells. These uptake experiments indicated that glycine, alanine and aspartic acid are transported into Cl4 cells via a sodium-dependent process. From the relative enrichment of the glutamate carbons, we calculated the activity of pyruvate dehydrogenase to be about 61% when labelled L-alanine was the only carbon source for LLC-PK1/Cl4 cells. Experiments with labelled D,L-aspartic, however, showed that about 40% of C-3-enriched oxaloacetate (arising from a de-amination of aspartic acid) reached the pyruvate pool.
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PMID:A 13C-NMR study on the influxes into the tricarboxylic acid cycle of a renal epithelial cell line, LLC-PK1/Cl4: the metabolism of [2-13C]glycine, L-[3-13C]alanine and L-[3-13C]aspartic acid in renal epithelial cells. 340 8

A strain of Escherichia coli enriched in its content of gamma-glutamylcysteine synthetase and glutathione synthetase by recombinant DNA techniques has been immobilized in a carrageenan matrix and used for the synthesis of various types of isotopically labeled glutathione (L-gamma-glutamyl-L-cysteinyl-glycine) (K. Murata, W. A. Abbott, R. J. Bridges, and A. Meister (1985) Anal. Biochem. 150, 235-237). In the present work, this E. coli matrix was used as the basis of a method for the synthesis of glutathione analogs. Thus, amino acid analogs were used in place of the corresponding amino acid constituents of glutathione (e.g., 4-fluoroglutamate was substituted for glutamate) in the reaction mixtures. Using this method we have synthesized several analogs of glutathione including L-gamma-glutamyl-(beta-chloro)-L-alanyl-glycine, (R,S)-4-fluoro-DL-gamma-glutamyl-L-cysteinyl-glycine, D-gamma-glutamyl-L-cysteinyl-glycine, and L-gamma-glutamyl-L-homocysteinyl-glycine. This method may also be used for the synthesis of a number of L- and D-gamma-glutamyl amino acids. The analogs are purified by gel-filtration and ion-exchange chromatography. The analogs are used to examine the substrate specificity and mechanisms of action of glutathione-utilizing enzymes and for studies on glutathione metabolism and function. Fluorine-containing analogs may be used for NMR studies. The enzymatically prepared compounds may also be used as intermediates in the chemical synthesis of other analogs of glutathione and glutathione disulfide.
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PMID:Enzymatic synthesis of novel glutathione analogs. 355 55

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