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)

Neutrophils and monocytes are the prime defenders of the body against suppurative bacterial and fungal infections. To accomplish their role in inflammation, they must respond appropriately to chemotactic signals elaborated from complement and bacteria. This response predictably results in the adherence and subsequent directed movement of the phagocytes toward the infected area where they recognize opsonized microbes. Attachment of the microbes to the membrane of the cell leads to their ingestion and subsequent demise, principally by the reduced oxygen by-product H2O2, which is generated by the neutrophils and monocytes during phagocytosis. Optimal killing requires the translocation of granule myeloperoxidase into the phagocytic vacuole containing the bacteria and a suitable halide ion. Degranulation is controlled, in part, by assembled microtubules whereas ingestion requires assembly of submembrane microfilaments. Deficiency states resulting from vitamin E results in diminished membrane-related chemotaxis and ingestion, whereas depletion of cellular GSH results in defective microtubule assembly preventing the normal increase in adherence, chemotaxis, degranulation, and microbicidal activity of the phagocytic cells. Deficiency states resulting in dysfunction of the microtubule system include neutrophil glutathione synthetase deficiency, rodent glutathione peroxidase deficiency, and the Chediak-Higashi syndrome.
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PMID:Role of membrane vitamin E and cytoplasmic glutathione in the regulation of phagocytic functions of neutrophils and monocytes. 39 94

(1) Oxygen uptake and lactate production of different strains of ascites tumor cells were assayed after exposure to an extracellular photochemical system known to produce reactive oxygen derivatives. The various cells tested showed differential sensitivity to the treatment, ranging from nearly full inactivation of Ehrlich cells to nearly full resistance of Yoshida cells. (2) Glucose plus succinate added after the treatment reestablished basal oxygen uptake capacity suggesting that the cell membrane was the primary site of damage. This was confirmed by dye-permeabilization and protein leakage in sensitive cells. (3) H2O2 was shown to be the only relevant oxygen derivative in the production of cell damage: catalase was the only externally added agent that protected sensitive cells, and H2O2 (congruent to 10(-3) M) had the same effects as the photochemical treatment. (4) While the absence of catalase is a feature common to all tumors tested, sensitivity to H2O2 appears to be related to cellular levels of glutathione peroxidase and of its subsidiary enzymes glucose-6-phosphate dehydrogenase, glutathione reductase and glutathione synthetase.
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PMID:Differential sensitivity of tumor cells to externally generated hydrogen peroxide. Role of glutathione and related enzymes. 55 3

Two modes of killing of Escherichia coli by hydrogen peroxide can be distinguished. Mode-one killing is maximal at 1-2 mM; at higher concentrations the killing rate is approximately half-maximal and is independent of H2O2 concentration but first order with respect to exposure time. Mutagenesis and induction of a phage lambda lysogen are similarly affected by H2O2 concentration, with reduced levels of response above 1-2 mM-H2O2. Mutagenesis is not affected by inactivation of umuC. Mode-one killing requires active metabolism during the H2O2 challenge and it results in sfiA-independent filamentation of both cells that survive and those that are killed by the challenge. This mode of killing is enhanced in xth, polA, recA and recB strains; however, it is unaffected by mutations in the nth, uvrA, uvrB, uvrC, uvrD, rep, gyrA, htpR and rel loci. Mode-one killing is normal in strains totally lacking catalase activity (katE, katG), glutathione reductase (gor) or glutathione synthetase (gshB), but enhanced in a strain lacking NADH dehydrogenase (ndh). Mode-one killing is accelerated by the presence of CN- or by an unidentified function that is induced by anoxic growth and is under the control of the fnr locus. A strain carrying both xth and recA mutations and certain polA mutants appear to undergo spontaneous mode-one killing only under aerobic conditions. Taken together, these observations imply that mode-one killing results from DNA damage that normally occurs at a low, non-lethal level during aerobic growth. Models for the resistance to mode-one killing at dose above 1-2 mM-H2O2 will be discussed. Mode-two killing occurs at high concentrations of H2O2 and longer times. It does not require active metabolism, and cells that are killed do not filament, although survivors demonstrate a dose-dependent growth lag followed by a period of filamentation. Mode-two killing is accompanied by enhanced mutagenesis, but strains with DNA repair defects were not observed to be especially sensitive to this mode of killing.
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PMID:Toxicity, mutagenesis and stress responses induced in Escherichia coli by hydrogen peroxide. 330 21

Nacystelyn (NAL), a recently-developed lysine salt of N-acetylcysteine (NAC), and NAG, both known to have excellent mucolytic capabilities, were tested for their ability to enhance cellular antioxidant defence mechanisms. To accomplish this, both drugs were tested in vitro for their capacity: (1) to inhibit O2- and H2O2 in cell-free assay systems; (2) to reduce O2- and H2O2 released by polymorphonuclear leukocytes (PMN); and (3) for their cellular glutathione (GSH) precursor effect. In comparison with GSH, NAL and NAC inhibited H2O2, but not O2-, in cell-free, in vitro test systems in a similar manner. The anti-H2O2 effect of these drugs was as potent as that of GSH, an important antioxidant in mammalian cells. To enhance cellular GSH levels, increasing concentrations (0-2 x 10(-4) mol l-1) of both substances were added to a transformed alveolar cell line (A549 cells). After NAC administration (2 x 10(-4) mol l-1), total intracellular GSH (GSH + 2GSSG) levels reached 4.5 +/- 1.1 x 10(-6) mol per 10(6) cells, whereas NAL increased GSH to 8.3 +/- 1.6 x 10(-6) mol per 10(6) cells. NAC and NAL administration also induced extracellular GSH secretion; about two-fold (NAC), and 1.5-fold (NAL), respectively. The GSH precursor potency of cystine was about two-fold higher than that of NAL and NAC, indicating that the deacetylation process of NAL and NAC slows the ability of both drugs to induce cellular glut production and secretion. Buthionine-sulphoximine, which is an inhibitor of GSH synthetase, blocked the cellular GSH precursor effect of all substances. In addition, these data demonstrate that NAC and NAL reduce H2O2 released by freshly-isolated cultured blood PMN from smokers with chronic obstructive pulmonary disease (COPD) (n = 10) in a similar manner (about 45% reduction of H2O2 activity by NAC or NAL at 4 x 10(-6) mol l-1). In accordance with the results obtained from cell-free, in vitro assays, O2- released by PMN was not affected. Ambroxol (concentrations: 10(-9)-10(-3) mol l-1) did not reduce activity levels of H2O2 and O2- in vitro. Due to the basic effect of dissolved lysine, which separates easily in solution from NAL, the acidic function of the remaining NAC molecule is almost completely neutralized [at concentration 2 x 10(-4) M: pH 3.6 (NAC), pH 6.4 (NAL)]. Due to their function as H2O2 scavengers, and due to their ability to enhance cellular glutathione levels, NAL and NAC both have potent antioxidant capabilities in vitro. The advantage of NAL over NAC is two-fold; it enhances intracellular GSH levels twice as effectively, and it forms neutral pH solutions whereas NAC is acidic. Concluding from these in vitro results, NAL could be an interesting alternative to enhance the antioxidant capacity at the epithelial surface of the lung by aerosol administration.
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PMID:Nacystelyn, a novel lysine salt of N-acetylcysteine, to augment cellular antioxidant defence in vitro. 913 55

Glutathione plays a pivotal role in protecting plants from environmental stresses, oxidative stress, xenobiotics, and some heavy metals. Arabidopsis plants treated with cadmium or copper responded by increasing transcription of the genes for glutathione synthesis, gamma-glutamylcysteine synthetase and glutathione synthetase, as well as glutathione reductase. The response was specific for those metals whose toxicity is thought to be mitigated through phytochelatins, and other toxic and nontoxic metals did not alter mRNA levels. Feeding experiments suggested that neither oxidative stress, as results from exposure to H2O2, nor oxidized or reduced glutathione levels were responsible for activating transcription of these genes. Jasmonic acid also activated the same suite of genes, which suggests that it might be involved in the signal transduction pathway for copper and cadmium. Jasmonic acid treatment increased mRNA levels and the capacity for glutathione synthesis but did not alter the glutathione content in unstressed plants, which supports the idea that the glutathione concentration is controlled at multiple levels.
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PMID:Glutathione metabolic genes coordinately respond to heavy metals and jasmonic acid in Arabidopsis. 972 99

The exposure of Saccharomyces cerevisiae cells to 13-L-hydroperoxylinoleic acid (LOOH) caused their death, the degree of which was dependent on the growth phase of the cells. Pre-application of ethanol, hydrogen peroxide (H2O2) and LOOH to S. cerevisiae cells reduced the effect of LOOH on the cells, showing the transient cross adaptation to LOOH. Antioxidants such as N,N',-diphenyl-p-phenylenediamine (DPPD), melatonin and vitamin E, and inhibitors of permeability transition of mitochondria, cyclosporin A and trifluoperazine, inhibited the LOOH-triggered cell death, while an inhibitor of glutathione synthetase, buthionine sulfoximine (BSO), enhanced the cell death by LOOH. Reactive oxygen species (ROS) were detected by flow cytometry, using the ROS-specific fluorescent indicator. A ferric iron chelator, deferoxamine, inhibited the LOOH-triggered cell death, and peroxyl radicals (LOO.) were detected by a spin trapping method. These reactive radicals possibly induced the death of S. cerevisiae cells. However, the DNA fragmentation characteristic of apoptosis was not observed in S. cerevisiae cells after exposure to LOOH, staurosporine, dexamethasone or etoposide, which have been reported to cause apoptosis in mammalian cells.
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PMID:Generation of free radicals during the death of Saccharomyces cerevisiae caused by lipid hydroperoxide. 1042 87

Mutants with defects in components of the glutathione-glutaredoxin (GSH/Grx) system of Rhodobacter capsulatus were constructed to study its role in defense against oxidative stress and the redox-dependent formation of photosynthetic complexes. The lack of the glutaredoxin 3 gene (grxC) or the glutathione synthetase B gene (gshB) resulted in lower growth rates under aerobic conditions and higher sensitivity to oxidative stress, confirming the role of the GSH/Grx system in oxidative stress defense. Both mutants are highly sensitive to disulfide stress, indicating a major contribution of the GSH/Grx system to the thiol-disulfide redox buffer in the cytoplasm. Like mutations in the thioredoxin system, mutations in the GSH/Grx system affected the formation of photosynthetic complexes, which is redox dependent in R. capsulatus. Expression of the genes grxC, gshB, grxA for glutaredoxin 1, and gorA for glutathione reductase, all encoding components of the GSH/Grx system, was not induced by oxidative stress. Other genes, for which a role in oxidative stress was established in Escherichia coli, acnA, fpr, fur, and katG, were strongly induced by oxidative stress in R. capsulatus. Mutations in the grxC, and/or gshB, and/or trxC (thioredoxin 2) genes affected expression of these genes, indicating an interplay of the different defense systems against oxidative stress. The OxyR and the SoxRS regulons control the expression of many genes involved in oxidative stress defense in E. coli in response to H2O2 and superoxide, respectively. Our data and the available genome sequence of R. capsulatus suggest that a SoxRS system is lacking but an alternative superoxide specific regulator exists in R. capsulatus. While the expression of gorA and grxA is regulated by H2O2 in E. coli this is not the case in R. capsulatus, indicating that the OxyR regulons of these two species are significantly different.
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PMID:The glutathione-glutaredoxin system in Rhodobacter capsulatus: part of a complex regulatory network controlling defense against oxidative stress. 1546 32

Oligodendrocyte progenitors are highly susceptible to oxidative stress due to their limited content of antioxidants and high iron levels. We previously showed that iron plays a central role in the toxicity of dopamine (DA) to oligodendrocyte progenitors. Here, we further explore the mechanisms involved in DA toxicity, specifically the role of superoxide and the glutathione system. DA induces accumulation of superoxide, membrane damage and loss in cell viability. An iron chelator, deferoxamine, reduces superoxide accumulation. However, a superoxide dismutase mimetic, MnTBAP, potentiates DA toxicity, suggesting that superoxide plays an indirect role in toxicity through dismutation to H2O2. In addition, the glutathione (GSH) analog (GME), blocks DA-induced superoxide accumulation, heme-oxygenase-1 (HO-1) expression and caspase-3 activation, and reduces cell death, while the glutathione synthetase inhibitor, buthionine sulfoximine, potentiates DA-induced HO-1 expression and cell death. Moreover, a mimetic of the peroxide-scavenging enzyme, glutathione peroxidase (GPx), ebselen, blocks caspase-3 activation induced by DA alone or in combination with iron. In conclusion, superoxide and inadequate defense by glutathione and GPx are responsible for the susceptibility of oligodendrocyte progenitors to DA toxicity. Furthermore, peroxides play a primary role in toxicity induced by DA and iron.
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PMID:Deficient peroxide detoxification underlies the susceptibility of oligodendrocyte progenitors to dopamine toxicity. 1740 Feb 58

While the toxicity of hexavalent chromium is well established, trivalent chromium is an essential nutrient involved in insulin and glucose homeostasis. To study the antioxidant effects of Cr(III)His, cDNA arrays were used to investigate the modulation of gene expression by trivalent chromium histidinate (Cr(III)His) in HaCaT human keratinocytes submitted to hydrogen peroxide (H2O2). Array was composed by a set of 81 expressed sequences tags (ESTs) essentially represented by antioxidant and DNA repair genes. HaCaT were preincubated for 24 h with 50 microM Cr(III)His and were treated with 50 muM H2O2. Total RNAs were isolated immediately or 6 h after the stress. In Cr(III)His preincubated cells, transcripts related to antioxidant family were upregulated (glutathione synthetase, heme oxygenase 2, peroxiredoxin 4). In Cr(III)His preincubated cells and exposed to H2O2, increased expressions of polymerase delta 2 and antioxidant transcripts were observed. Biochemical methods performed in parallel to measure oxidative stress in cells showed that Cr(III)His supplementation before H2O2 stress protected HaCaT from thiol groups decrease and thiobarbituric acid reactive substances increase. In summary, these results give evidence of antioxidant gene expression and antioxidant protection in HaCaT preincubated with Cr(III)His and help to explain the lack of toxicity reported for Cr(III)His.
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PMID:Chromium III histidinate exposure modulates gene expression in HaCaT human keratinocytes exposed to oxidative stress. 1990 59

The stable HepG2 transfectants anti-sensing expression of the glutathione synthetase (GS) gene exhibited delayed cell growth and increased reactive oxygen species (ROS) level. After the treatment with hydrogen peroxide, the intracellular ROS level was much higher in the stable transfectants than in the vector control cells. However, the GSH levels decreased more significantly in the stable transfectants than in the vector control cells, in the presence of hydrogen peroxide. Hydrogen peroxide-induced apoptosis of the stable transfectants was notably higher than that of the vector control cells. The GS anti-sense RNAs rendered the HepG2 cells more sensitive to growth arrest caused by glucose deprivation. They also sensitized the HepG2 cells to cadmium chloride (Cd) and nitric oxide (NO)-generating sodium nitroprusside (SNP). In brief, the results confirm that GS plays an important role in the defense of the human hepatoma cells against oxidative stress by reducing apoptosis and maintaining redox homeostasis.
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PMID:Disruption of redox homeostasis and induction of apoptosis by suppression of glutathione synthetase expression in a mammalian cell line. 2167 55

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