UMLS:C1260386 - FACTA Search

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Query: UMLS:C1260386 (GSH)
38,102 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Methylxanthines (MX) inhibit cell division in sea urchin and clam eggs. This inhibitory effect is not mediated via cAMP. MX also inhibit respiration in marine eggs, at concentrations which inhibit cleavage. Studies showed that no changes occurred in ATP and ADP levels in the presence of inhibitory concentrations of MX, indicating an extra-mitochondrial site of action for the drug. Subsequent studies revealed decreased levels of NADP+ and NADPH, when eggs were incubated with inhibitory concentrations of MX, but no change in levels of NAD+ and NADH. MX did not affect the pentose phosphate shunt pathway and did not have any effect on the enzyme NAD+ -kinase. Further studies showed a marked inhibitory effect on the glutathione reductase activity of MX-treated eggs. Reduced glutathione (GSH) could reverse the cleavage inhibitory effect of MX. Moreover, diamide, a thiol-oxidizing agent specific for GSH in living cells, caused inhibition of cell division in sea urchin eggs. Diamide added to eggs containing mitotic apparatus (MA) could prevent cleavage by causing a dissolution of the formed MA. Both MX and diamide inhibit a Ca2+-activated ATPase in whole eggs. The enzyme can be reactivated by sulfhydryl reducing agents added in the assay mixture. In addition, diamide causes an inhibition of microtubule polymerization, reversible with dithioerythritol. All experimental evidence so far suggests that inhibition of mitosis in sea urchin eggs by MX is mediated by perturbations of the in vivo thiol-disulfide status of target systems, with a primary effect on glutathione levels.
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PMID:Effects of caffeine and other methylxanthines on the development and metabolism of sea urchin eggs. Involvement of NADP and glutathione. 1 15

The erythrocytes of newborn and adult goats were studied with respect to GSH stability, GSH regeneration, levels of ATP and 2, 3-DPG, glucose consumption and activities of nine different enzymes of Embden-Meyerhof and pentose phosphate pathways of glucose metabolism. Red cells from newborn goats had significantly higher levels of ATP and 2, 3-DPG. The activities of all the enzymes measured were also significantly greater in the newborn. It is suggested that newborn goats possess red blood cells that are metabolically more active than those of adult goats.
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PMID:In vitro metabolism of red blood cells from newborn and adult goats. 12 76

Glucose utilization and lactate formation in erythrocytes from normal and glutathione (GSH)-deficient sheep were similar. Significant differences were observed, however, between the 2 groups of sheep in the production of 14-CO2 from erythrocytes incubated with ascorbic acid or methylene blue, or both. The greater response of normal erythrocytes compared to erythrocytes deficient in GSH suggests that there are some metabolic differences in the pentose phosphate pathway (ppp) activity of the erythrocytes. The nature and site of these differences are, however, not known. When sheep were kept in a decompression chamber for 2 weeks and subjected to a simulated altitude of 7,000 m for 12 hours/day, the erythrocytes showed a four- to six-fold increase in the activity of the ppp.
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PMID:Erythrocyte metabolism in normal and glutathione-deficient sheep. 23 40

The present knowledge of glutathione (GSH) peroxidase is briefly reviewed: GSH peroxidase has a molecular weight of about 85,000, consists of four apparently-identical subunits and contains four g atom of selenium/mol. The enzyme-bound selenium can undergo a substrate-induced redox change and is obviously essential for activity. In accordance with the assumption that a selenol group is reversibly oxidized during catalysis, ping-pong kinetics are observed. Limiting maximum velocities and Michaelis constants, indicating the formation of an enzyme-substrate complex, are not detectable. The enzyme is highly specific for GSH but reacts with many hydroperoxides. It can be deduced from the kinetic analysis of GSH peroxidase that in physiological conditions removal of hydroperoxide is largely independent of fluctuations in the cellular concentration of GSH. However, the system will abruptly collapse if the rate of hydroperoxide formation exceeds that of regeneration of GSH. By these considerations, the pathophysiological manifestation of disorders in GSH metabolism and pentose-phosphate shunt may be explained. With regard to its low specificity for hydroperoxides, GSH peroxidase could be involved in various metabolic events such as H2O2 removal in compartments low in catalase, hydroperoxide-mediated mutagenesis, protection of unsaturated lipids in biomembranes, prostaglandin biosynthesis, and regulation of prostacyclin formation.
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PMID:Glutathione peroxidase: fact and fiction. 38 23

The effects of thyrotropin-releasing hormone (TRH) on a group of 12 normal euthyroid subjects (8 males, 4 females) were analyzed through the metabolic response of oxidoreduction chains of red cells and leucocytes of venous blood. During the reaction of the pituitary-thyroid glandular system (increase of circulating TSH and T-3) to hypothalamic stimulation, the authors have demonstrated: (1) a significant reduction in erythrocytic GSH rate with no anomaly of in vitro stability; (2) an obvious stimulation of the two dehydrogenases of the leucocyte pentose shunt: G6PD and 6PGD. Regarding red cells, the same enzymes do not undergo any quantitative modification, and no behavioral difference of acid phosphatase is observed. The authors also refer to the biochemical mechanism which is involved for regulation of the oxidoreductive metabolism in the molecular response to hormonal or hrehormonal solicitations.
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PMID:Effects of thyrotropin-releasing hormone on the erythrocyte and leucocyte enzyme activities in man. 80 52

In patients on hemodialysis, a metabolic block of the pentose phosphate shunt has been described that impairs the reduction of oxidized glutathione. The block results in lack of detoxication of the free hydroxyl radicals produced inside the red blood cell (RBC) and causes oxidative damage to the polyunsaturated fatty acids of the RBC membrane that results in formation of aldehydes. Malonyldialdehyde has been used as an index of the oxidative damage. In a study group of 13 patients on hemodialysis, the authors have tested whether administering reduced glutathione (GSH) at 1200 mg/day for 1 month could minimize oxidative damage to the RBC membranes and improve the hematologic parameters. Treatment with GSH was followed by significant improvement of hematocrit (P = 0.008), hemoglobin (P = 0.03), and RBC count (P = 0.0037); however, oxidative damage to the membranes was increased (P = 0.0004), which suggests that improvement of the hematologic parameters is not related to reduction of the oxidative damage. This is because oxidized glutathione, formed in the oxidative process, cannot be reduced back to GSH because of alteration of the pentose phosphate shunt.
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PMID:Administration of GSH has no influence on the RBC membrane: oxidative damage to patients on hemodialysis. 145 Apr 86

Misonidazole is a metabolically active drug. Its addition to cells causes an immediate alteration in cellular electron transfer pathways. Under aerobic conditions the metabolic alterations can result in futile cycling with electron transfer to oxygen and production of peroxide. Thiol levels are extremely important in protecting the cell against the peroxide formation and potentially hazardous conditions for hydroxyl radical production. Nevertheless such electron shunting out of cellular metabolism will result in alterations in pentose cycle, glycolysis and cellular capacity to reduce metabolites to essential intermediates needed in DNA metabolism (i.e. deoxyribonucleotides). Glutathione must be depleted to very low levels before toxic effects of misonidazole and other nitro compounds are manifested in cell death via peroxidative damage. Under hypoxic conditions misonidazole also diverts the pentose cycle via its own reduction; however, unlike the aerobic conditions, there are a number of reductive intermediates produced that react with non-protein thiols such as GSH as well as protein thiols. The reaction with protein thiols results in the inhibition of glycolysis and other as yet undetermined enzyme systems. The consequences of the hypoxic pretreatment of cells with nitro compounds are increased vulnerability to radiation and chemotherapeutic drugs such as L-PAM, cis-platinum and bleomycin. The role that altered enzyme activity has in the cellular response to misonidazole and chemotherapeutic agents remains to be determined. It is also clear that the GSH depleted state not only makes cells more vulnerable to oxidative stress but also to hypoxic intermediates produced by the reduction of misonidazole beyond the one electron stage. The relevancy of the present work to the proposed use of thiol depletion in vivo to enhance the radiation or chemotherapeutic response of tumor tissue lies with the following considerations. Apparently, spontaneous peroxidative damage to normal tissue such as liver can occur with GSH depletion to 10-20% of control and with other normal tissue when GSH reaches 50% of control. This situation can obviously become more critical if peroxide producing drugs are administered. The only advantage to such combined drug treatments would lie in the possibility that tumors vary in their catalase and peroxidase activity and consequently may be more vulnerable to oxidative stress (cf. review by Meister. Our tumor model, the A549 human lung carcinoma cell in vitro, appears to be an exception because it has catalase, peroxidase and a high content of GSH.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Biochemistry of reduction of nitro heterocycles. 293 68

Recently there has been a great deal of interest in exploring possible ways to protect the lung from oxidant damage. Since sulfhydryl compounds are among the most important endogenous antioxidants, their therapeutic use has been proposed. Glutathione (GSH), the main intracellular nonprotein sulfhydryl, plays an important role in the maintenance of cellular proteins and lipids in their functional state. With oxidant stress, GSH acts to protect cell constituents as evidenced by increased turnover to GSSG, formation of mixed disulfides with proteins, utilization of NADPH, and utilization of glucose in the pentose pathway. When GSH is experimentally lowered (e.g., by protein deficiency or with diethylmaleate) the toxic effects of oxidant stress are exacerbated as evidenced by increased membrane and cell damage, pulmonary edema, and mortality. Several recent investigations have shown that sulfhydryl reagents (particularly N-acetyl cysteine, a cell-permeable GSH precursor) can provide significant protection against certain pulmonary toxins. N-acetyl cysteine reduced the lethal effects of 100% O2 in rats by 65%. Therefore, the therapeutic potential of sulfhydryl reagents in the treatment and prevention of oxidant injury and the mechanisms involved are an important direction for lung research.
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PMID:Protective role of sulfhydryl reagents in oxidant lung injury. 306 90

Red cells collected in CPD and suspended in SAGM medium were stored in plastic (PVC) containers for 42 days at +4 degrees C. Comparison was made between aerobic storage (normal air exposure) and anaerobic storage (exposure to nitrogen gas). The air-exposed units showed a strong increase in pO2 and oxygen saturation as a result of oxygen penetration into the bags from outside. This resulted in a decrease in ATP and adenylate energy charge, a slower metabolization of adenine and hypoxanthine to AMP and IMP, respectively, and a faster decrease in red cell fluidity. To explain the findings it is concluded that aerobic storage causes an increased need of high-energy phosphate groups, possibly used for replacement of the phospholipid membrane bilayer or in repair of phosphate bonds in the cytoskeleton. It is further proposed that a slight formation of hydrogen peroxide from free oxygen radicals moderately increases the oxidation of reduced (GSH) to oxidized (GSSG) glutathione and slightly enhances the need for reduced nicotinamide-adenine dinucleotides mainly provided by increased flux through the pentose phosphate shunt.
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PMID:Effects of oxygen on red cells during liquid storage at +4 degrees C. 309 Jul 83

Glucose-6-phosphate dehydrogenase (G-6-PDH) is the key enzyme of the pentose phosphate cycle and therefore regulates the synthesis of the nucleic acid constituent ribose-5-phosphate. At the same time the enzyme is coupled to the synthesis of reduced glutathione (GSH) which detoxifies electrophilic molecules (radicals) in the organism. Activity and stability of G-6-PDH and the influence of SIN 1--the active metabolite of molsidomine (Corvaton)--dithiothreitol (DTT) and NADP on these parameters were studied in enzyme preparations from different organs of the rat (liver, ethmoturbinates, blood) and from blood of mouse, guinea pig, rabbit, dog and man. The highest activity of G-6-PDH was measured in rat ethmoturbinates (69.26 +/- 5.91 mU/mg protein/min), the lowest in human blood (2.99 +/- 0.18 mU/mg protein/min). G-6-PDH of rat ethmoturbinates and of rat and dog blood was unstable and nearly completely inhibited by SIN 1. The enzyme of rat liver and of human, mouse, guinea pig and rabbit blood was stable and not influenced by SIN 1. These organ-and species-specific findings are discussed with respect to the toxicological actions of SIN 1.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Organ- and species-specific properties of glucose-6-phosphate dehydrogenase and the effect of molsidomine]. 336 74

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