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

Radiosensitization by various concentrations of O2 has been studied in an Escherichia coli K-12 wild-type strain and some derived glutathione (GSH)-deficient mutants using 60Co gamma-irradiation. The maximum oxygen enhancement ratio (OER) and the K-value, the O2 concentration that produced half the maximum O2 effect, were found to depend on the GSH biosynthetic capacity of the strains. For the GSH+ wild-type strain, AB1157, and the GSH- mutant, 830, which is deficient in glutathione synthetase, the final enzyme in the GSH biosynthetic pathway, the maximum OERs were both about 3.9 and the K-values were 0.53% and 0.24% O2, respectively. On the other hand, the maximum OERs for two GSH- mutants, 7 and 821, both deficient in gamma-glutamylcysteine synthetase, the penultimate enzyme in the GSH biosynthetic pathway, were about 2.7 and the K-values were about 0.06% O2 for both. The fast chemical repair of O2-dependent damage in these strains was measured using a fast mixing and irradiation method, the gas explosion technique. The chemical repair rates in the various E. coli strains varied approximately in proportion to the O2 K-values, and both the rates of chemical repair and the K-values correlated approximately with the levels of non-protein sulphydryls in the various strains.
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PMID:The oxygen effect: variation of the K-value and lifetimes of O2-dependent damage in some glutathione-deficient mutants of Escherichia coli. 167 41

A loss of glutathione from the kidney can cause increased sensitivity to oxygen free radical-induced injury. In this study we investigated the effects of kidney preservation on glutathione and how various glutathione precursors affect glutathione concentration in the dog kidney. During 5-day continuous machine perfusion of the kidney at 5 degrees C, a loss of glutathione from the cortex tissue was seen (24% +/- 1% glutathione remained after 5 days). Perfusion with reduced glutathione (GSH, 3 mmol/L) suppressed this loss (77% +/- 11% of glutathione remained after 5 days). Oxidized glutathione (GSSG) did not prevent the loss of glutathione. The addition of the three amino acids that make up glutathione (glycine, glutamic acid, and cysteine, 3 mmol/L each) also suppressed the loss of glutathione (82% +/- 13% remained at 5 days). The glutathione precursor, thioproline, a cysteine delivery compound, in combination with glycine and glutamic acid (3 mmol/L each), stimulated the synthesis of glutathione in the kidney during hypothermic perfusion (137% +/- 23% of control values at 5 days). The increase in tissue glutathione stimulated by GSH or other precursors was sensitive to the glutathione synthetase inhibitor, buthionine sulfoximine. This indicated the existence of active glutathione metabolism even at 5 degrees C in perfused kidneys. This study showed that in kidney preservation a loss of glutathione occurred that could be suppressed by the addition of various precursors for glutathione synthesis. The loss of glutathione from preserved kidneys may be one cause of posttransplant renal injury that could be prevented by use of the appropriate glutathione precursors.
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PMID:Changes in glutathione concentration in hypothermically perfused dog kidneys. 199 54

The radioprotective role of endogenous and exogenous thiols was investigated, with survival as the end-point, after radiation exposure of cells under oxic and hypoxic conditions. Human cell strains originating from a 5-oxoprolinuria patient and from a related control were used. Due to a genetic deficiency in glutathione synthetase, the level of free SH groups, and in particular that of glutathione, is decreased in 5-oxoprolinuria cells. The glutathione synthetase deficient cells have a reduced oxygen enhancement ratio (1.5) compared to control cells (2.7). The radiosensitivity was assessed for both cell strains in the presence of different concentrations of an exogenous radioprotector:cysteamine. At concentrations varying between 0.1 and 20 mM, cysteamine protected the two cell strains to the same extent when irradiated under oxic and hypoxic conditions. The protective effect of cysteamine was lower under hypoxia than under oxic conditions for both cell strains. Consequently, the oxygen enhancement ratio decreased for both cell strains when cysteamine concentration increased. These results suggest that cysteamine cannot replace endogenous thiols as far as they are implicated in the radiobiological oxygen effect.
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PMID:Radioprotective effect of cysteamine in glutathione synthetase-deficient cells. 348 71

Using a human fibroblast strain deficient in glutathione synthetase and a related proficient control strain, the role of glutathione (GSH) in repair of potentially lethal damage (PLD) has been investigated in determining survival by plating cells immediately or 24 h after irradiation. After oxic or hypoxic irradiation, both cell strains repair radiation-induced damage. However, under hypoxic conditions, the proficient cells repair PLD as well as under oxic conditions while the deficient cells repair less PLD after irradiation under hypoxic than under oxic conditions. Therefore, the oxygen enhancement ratio (o.e.r.) for proficient cells is similar whether the cells are plated immediately or 24 h later (2.0 and 2.13, respectively). In contrast, the o.e.r. for deficient cells is lower when the cells are plated 24 h after irradiation than when they are plated immediately thereafter (1.16 as compared to 1.55). The results indicate that GSH is involved in PLD repair and, in particular, in the repair of damage induced by radiation delivered under hypoxic conditions.
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PMID:Reduced repair of potentially lethal radiation damage in glutathione synthetase-deficient human fibroblasts after X-irradiation. 348 89

Glutathione functions in catalysis, metabolism, transport, and reductive processes and in protection of cells by destruction of free radicals, reactive oxygen intermediates, and other toxic compounds of endogenous and exogenous origin. It also functions as a storage and transport form of cysteine. Depletion of glutathione (effectively accomplished by inhibition of its synthesis) increases sensitivity to radiation and to certain toxic compounds and is of value in combination with radiation therapy or chemotherapy in situations in which cell selectivity can be achieved. Increased cellular levels of glutathione protect cells against radiation and certain toxic compounds. Glutathione levels can be increased by administration of cysteine or of glutathione, but these approaches are not entirely satisfactory. Cellular glutathione levels can be increased by supplying substrate for gamma-glutamylcysteine synthetase or for glutathione synthetase. L-2-Oxothiazolidine-4-carboxylate is well transported into many cells and is converted by 5-oxoprolinase to cysteine, a substrate of gamma-glutamylcysteine synthetase. gamma-Glutamylcysteine and related compounds are effectively transported, especially into renal cells, thus providing substrate for glutathione synthetase; higher than normal levels of glutathione can be achieved because this enzyme is not significantly inhibited by glutathione, whereas gamma-glutamylcysteine synthetase is feedback-inhibited. Derivatives of glutathione that are effectively transported into cells (glutathione itself is not) offer another means of increasing glutathione levels. The monoethyl ester of glutathione (in which the glycine carboxyl group is esterified) is well transported in vivo into liver and kidney and into cultured fibroblasts and lymphoid cells. Glutathione levels much higher than usual can be obtained by this procedure, which protects lymphoid cells against the lethal effects of irradiation and mice against acetaminophen, and which therefore may be a relatively safe way to increase cellular resistance to radiation and certain toxic compounds.
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PMID:Intracellular cysteine and glutathione delivery systems. 372 29

The cytotoxic and radiosensitizing effects of misonidazole have been studied on glutathione synthetase deficient fibroblasts and on their controls. At any concentration from 0.1 to 4 mM, deficient cells are more sensitive to the cytotoxic effect of misonidazole than the control cells. The differential effect between the two cell strain concerns both the shoulder and the slope of the survival curve, thus suggesting that NPSH play a role in the determination of misonidazole cytotoxicity. Like oxygen, misonidazole clearly sensitizes deficient cells to a lesser extent than control cells. For both cell strains, the maximum sensitizing effect of misonidazole is very close to that of oxygen (1.5 and 1.5 for deficient cells, 2.8 and 2.9 for control cells, respectively). The sensitizing effect of misonidazole appears in the same concentration range for both cell strains, with a maximal effect at lower concentrations for deficient cells.
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PMID:Radiosensitizing and cytotoxic properties of misonidazole on glutathione synthetase deficient human fibroblasts. 387 43

The role of intracellular non-protein bound sulphydryl compounds (NPSH), and in particular that of glutathione (GSH), in the response of cells to ionizing radiation under different O2 concentrations has been assessed using cell strains deficient in glutathione synthetase and exhibiting different NPSH levels. The cell strains used originated from patients with 5-oxoprolinuria and from their relatives (heterozygotes and proficient homozygotes). No correlation has been found between NPSH and GSH concentrations and radiosensitivity under oxic, aerobic and hypoxic conditions. However, a highly significant correlation has been observed between radiosensitivity under hypoxic conditions (and therefore the oxygen enhancement ratio) and the glutathione synthetase activity, suggesting that synthesis of GSH is required after irradiation. In order to explain our results we postulated, beside radical processes, the existence of a GSH-dependent enzymatic repair mechanism for N2 type damage. Hypoxic radio-sensitivity measured with survival curves would result from the interaction of both competition and biochemical repair processes.
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PMID:Survival curves of glutathione synthetase deficient human fibroblasts: correlation between radiosensitivity in hypoxia and glutathione synthetase activity. 387 5

Mutants of Escherichia coli B that contain essentially no detectable glutathione were isolated. These mutants had a very low activity of gamma-glutamylcysteine synthetase or glutathione synthetase. No significant differences in growth in minimal medium were observed between the mutants and the parental strain. The mutants lacking gamma-glutamylcysteine synthetase activity were more susceptible to toxic compounds than either the parental strain or a glutathione synthetase-deficient strain. The mutants lacking gamma-glutamylcysteine synthetase activity were also susceptible to oxygen.
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PMID:Some properties of glutathione biosynthesis-deficient mutants of Escherichia coli B. 612 59

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