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)

Adenosine 2'-monophospho-5'-diphosphoribose (P-ADP-Rib) is a structural analog of NADPH which was reported to competitively inhibit (Kiapp = 21.7 microM) solubilized rat liver 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase (Tanazawa, K., and A. Endo. 1979. Eur. J. Biochem. 98: 195-201). However, microsomal HMG-CoA reductase, which at low thiol concentrations exhibits allosteric properties, is only poorly inhibited by P-ADP-Rib (Kiapp = 550 microM at 4.5 mM GSH). Gradual shift of the microsomal reductase towards a non-allosteric form by increasing glutathione (GSH) concentrations resulted in a higher inhibition by P-ADP-Rib. Under these conditions, Ki values for P-ADP-Rib were 165 microM and 53 microM at 9 mM and 27 mM GSH, respectively. The largest change in the degree of inhibition by P-ADP-Rib was observed within the 10 mM range of GSH. By contrast, freeze-thaw solubilized HMG-CoA reductase, which does not display allosteric properties, is readily inhibited by P-ADP-Rib, even when assayed at a low concentration of GSH (Kiapp = 50 microM at 4.5 mM GSH). Assaying the solubilized reductase in the presence of increased thiol concentration results in a minor decrease in the apparent Ki for P-ADP-Rib (22 microM at 27 mM GSH). Microsomal HMG-CoA reductase is allosterically activated by various nucleotides. When activated by NADH, the enzyme is effectively inhibited by P-ADP-Rib even at a 4.5-mM GSH concentration (Kiapp = 175 microM in the presence of 300 microM NADH).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Allosteric and non-allosteric forms of rat liver 3-hydroxy-3-methylglutaryl coenzyme A reductase: differential inhibition of activity by adenosine 2'-monophospho-5'-diphosphoribose. 377 49

We have assessed a previously proposed mechanism mediating 5'-deiodinase activation involving enzymic reduction of disulphides to thiols in non-glutathione cytosolic components of Mr approx. 13,000 (Fraction B) catalysed by NADPH in the presence of other cytosolic components of Mr greater than 60,000 (Fraction A). The extent of Fraction B reduction under various experimental conditions was monitored by determining the amount of 14C incorporated into chromatographically isolated Fractions B and A after their alkylation with iodo[14C]acetamide. Incorporation of 14C into B was found to require the simultaneous presence of NADPH and A, to be directly proportional to the concentration of NADPH added, and to be unaffected by either propylthiouracil or iopanoate. Activation of 5'-deiodinase attainable using B after its partial reduction by various concentrations of NADPH and subsequent alkylation with non-radioactive iodoacetamide was inversely proportional to the previously added concentration of NADPH. Fraction B was stable at 100 degrees C for 5 min, while similar heat treatment of Fraction A or omission of NADPH resulted in a complete loss of 14C incorporation. A greater than 90% reduction in iodo[14C]acetamide incorporation was revealed when 0.2 mM-sodium arsenite was added after enzymic reduction of B, as well as when NADPH was replaced by NADH. Fraction B could be labelled more extensively after reduction non-specifically, with dithiothreitol or NaBH4, but not by GSH. These observations provide strong evidence for the presence in vivo of a cytosolic disulphide (DFBS2) in Fraction B which can be reduced enzymically to a dithiol [DFB(SH)2] by NADPH and cytosolic components in Fraction A. The degree of activation of hepatic 5'-deiodinase correlated with the amount of available (unalkylated) Fraction B.
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PMID:NADPH-dependent generation of a cytosolic dithiol which activates hepatic iodothyronine 5'-deiodinase. Demonstration by alkylation with iodoacetamide. 381 95

The redox interconversion of Escherichia coli glutathione reductase has been studied both in situ, with permeabilized cells treated with different reductants, and in vivo, with intact cells incubated with compounds known to alter their intracellular redox state. The enzyme from toluene-permeabilized cells was inactivated in situ by NADPH, NADH, dithionite, dithiothreitol, or GSH. The enzyme remained, however, fully active upon incubation with the oxidized forms of such compounds. The inactivation was time-, temperature-, and concentration-dependent; a 50% inactivation was promoted by just 2 microM NADPH, while 700 microM NADH was required for a similar effect. The enzyme from permeabilized cells was completely protected against redox inactivation by GSSG, and to a lesser extent by dithiothreitol, GSH, and NAD(P)+. The inactive enzyme was efficiently reactivated in situ by physiological GSSG concentrations. A significant reactivation was promoted also by GSH, although at concentrations two orders of magnitude below its physiological concentrations. The glutathione reductase from intact E. coli cells was inactivated in vivo by incubation with DL-malate, DL-isocitrate, or higher L-lactate concentrations. The enzyme was protected against redox inactivation and fully reactivated by diamide in a concentration-dependent fashion. Diamide reactivation was not dependent on the synthesis of new protein, thus suggesting that the effect was really a true reactivation and not due to de novo synthesis of active enzyme. The glutathione reductase activity increased significantly after incubation of intact cells with tert-butyl or cumene hydroperoxides, suggesting that the enzyme was partially inactive within such cells. In conclusion, the above results show that both in situ and in vivo the glutathione reductase of Escherichia coli is subjected to a redox interconversion mechanism probably controlled by the intracellular NADPH and GSSG concentrations.
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PMID:Redox interconversion of Escherichia coli glutathione reductase. A study with permeabilized and intact cells. 390 6

The stabilities of bilirubin (BR) glucuronide, monoglucuronide (BMG), and diglucuronide (BDG) were studied under various conditions by HPLC. In aqueous media, BMG showed a pronounced lability and was easily transformed into equimolar BDG and BR. It was proved by direct analysis of tetrapyrrole isomers that BDG and BR were formed from dipyrrole exchange of BMG molecules. All reducing agents examined (sodium ascorbate, cysteine, GSH, dithiothreitol, NADH, and NADPH) suppressed the transformation of BMG into BDG and BR. Bovine serum albumin and rat liver cytosol fractions also stabilized BMG strongly. BDG was fairly stable in aqueous media as compared with BMG. When BMG was incubated both with and without liver plasma membranes (N2 fraction) from Wistar rats, the formation rates of BDG and BR in both incubation mixtures were exactly the same. The composition of BDG and BR isomers was the same in both mixtures. Also, heat denaturation of the plasma membranes did not affect formation rates. Moreover, the reaction was completely inhibited by sodium ascorbate. These findings indicate that rat liver plasma membranes have no enzyme activity for BDG formation from BMG.
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PMID:Study of bilirubin metabolism by high-performance liquid chromatography: stability of bilirubin glucuronides. 403

It has been suggested that in the chloramphenicol-induced aplastic anemia nitrosochloramphenicol may be involved as a toxic intermediate. We found that aminochloramphenicol, which reportedly is formed from chloramphenicol by intestinal bacteria, is N-oxygenated by liver microsomes of untreated rats with apparent Km = 0.4 mM and Vmax = 0.28 nmole/min/mg protein. These values are in close agreement with those reported for aniline N-oxygenation. Reductive reactions, however, eliminate the N-oxygenation products at markedly higher rates. As judged from hemoglobin-free single-pass liver perfusion experiments, N-hydroxy-chloramphenicol is reduced at rates faster than 300 nmole/min/g liver wet, and nitrosochloramphenicol is eliminated at rates faster than 1.5 mumole/min/g liver. At least two NADPH- and two NADH-dependent cytosolic enzymes are responsible for nitrosochloramphenicol reduction. Determination of the kinetic parameters of these enzymes by stop-flow analysis revealed the contribution of enzymes, one of it being alcohol dehydrogenase, with Michaelis constants in the micromolar range. Despite this high reducing capacity, about 10% of nitrosochloramphenicol reacted with GSH under formation of glutathionesulfinamidochloramphenicol and GSSG released from the liver into bile and venous effluent. At high nitrosochloramphenicol load these reactions led to glutathione depletion of the liver, caused membrane damage, and impaired bile production. At low nitrosochloramphenicol load, i.e. below 0.5 mumole/min/g, no relevant nitrosochloramphenicol passed the liver. These data together with the previously reported reactions of nitrosochloramphenicol within human blood suggest that nitrosochloramphenicol, if formed at all in the intestine or liver, is rather unlikely to be transferred to the critical target.
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PMID:Formation and disposition of nitrosochloramphenicol in rat liver. 405 15

Reduced divicine (2,6-diamino-4,5-dihydroxypyrimidine), an aglycone implicated in the pathogenesis of favism, reduces methemoglobin efficiently in intact erythrocytes and in hemolysates. Oxidized divicine produces the same effect when glucose or an NADPH-generating system is added to intact erythrocytes or to hemolysates. Although NADPH, NADH, and GSH have no direct methemoglobin-reducing activity in vitro, they convert oxidized divicine to the reduced hydroquinone species, which is responsible for the electron transfer to methemoglobin. Reduction of methemoglobin is optimally observed under nitrogen since, in the presence of oxygen, reduced divicine undergoes autoxidation. Several lines of evidence rule out the reduction of methemoglobin by divicine through an enzyme-catalyzed process, although it is certainly sustained by the hexose monophosphate shunt activity of erythrocytes through the generation of both NADPH and GSH. Thus, the strong enhancing effect that glucose produces on the divicine-dependent methemoglobin reduction within intact normal erythrocytes is completely absent in erythrocytes from glucose-6-phosphate dehydrogenase-deficient subjects. This distinctive behavior might account for the enhanced methemoglobin levels that are found both in vitro in glucose-6-phosphate dehydrogenase-deficient erythrocytes exposed to divicine and in vivo as a typical feature of the acute hemolytic crisis of favic patients.
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PMID:Hexose monophosphate shunt-stimulated reduction of methemoglobin by divicine. 406 95

1. The oxidation of NADH and NADPH catalysed by the soluble supernatant from the hepatopancreas of Octopus vulgaris is due to a single enzyme, which has been purified approximately 100-fold. The enzyme reacts rapidly with potassium ferricyanide, and more slowly with 2,6-dichlorophenol-indophenol. No activity is obtained with oxygen, cytochrome c, lipoic acid, vitamin K(1), vitamin K(3), ubiquinone-30, p-benzoquinone, 2-p-iodophenyl-3-p-nitrophenyl-5-phenyltetrazolium chloride or methylene blue. 2. GSH, cysteine and mercaptoethanol stimulate the enzymic activity up to fivefold. GSSG is without any apparent effect. When stimulated by GSH the enzyme becomes sensitive to dicoumarol, which produces an inhibition competitive with respect to the activator. 3. The purified enzyme contains an acid-removable flavine component, which has been identified as FMN by spectrofluorimetry and chromatography in three solvent systems. After acid ammonium sulphate treatment the enzymic activity is lost, but it can be almost fully restored by incubation with FMN. FAD produces only a partial reactivation.
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PMID:Purification and properties of a soluble reduced nicotinamide-adenine dinucleotide (phosphate) dehydrogenase from the hepatopancreas of Octopus vulgaris. 417 22

Cell-free extracts of adult rat brain incubated with mevalonic acid-2-(14)C synthesize (14)C-labeled nonsaponifiable fractions consisting largely of squalene-(14)C. If the cofactor concentrations of the incubation medium are adjusted, much of the squalene can be induced to undergo turnover, with a resultant increase in (14)C-labeled digitonin-precipitable sterols, which include a small amount of cholesterol. The synthesis of labeled sterols is markedly increased in the presence of Mg(++) and depressed by nicotinamide. ATP, NADH, GSH, and glucose-6-phosphate are required for optimal synthesis of digitonin-precipitable material but, unlike Mg(++), are not essential. The cofactor-adjusted extracts also synthesize a complex ester mixture containing, in addition to cholesterol-(14)C, several compounds less polar than cholesterol. The biosynthesis of cholesterol in the extracts is a slow process; at least 12 hr of incubation is required for maximal sterol biosynthesis. A complex mixture of hydrocarbons accompanies squalene in the incubated extracts.
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PMID:Biosynthesis of squalene and cholesterol by cell-free extracts of adult rat brain. 430 11

Spectrophotometric assay methods are described for glutathione synthetase, gamma-glutamylcysteine synthetase and gamma-glutamyl transpeptidase of erythrocytes. The contents of these enzymes in normal human erythrocytes are reported. Erythrocyte glutathione synthetase is inhibited by ADP; this inhibition is competitive with respect to ATP. gamma-Glutamylcysteine synthetase is subject to feedback inhibition by GSH, and is also inhibited by NADH, and to a lesser extent by NAD(+) and NADPH. This enzyme is irreversibly inactivated by cysteamine.
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PMID:Studies in the enzymology of glutathione metabolism in human erythrocytes. 438 10

1. Liver microsomes form lipid peroxide when incubated with ascorbate or NADPH, but not with NADH. Increasing the concentration of ascorbate beyond the optimum (0.5mm) decreases the rate of lipid peroxide formation, but this effect does not occur with NADPH. Other reducing agents such as p-phenylenediamine or ferricyanide were not able to replace ascorbate and induce lipid peroxide formation. 2. The rate of ascorbate-induced peroxidation is optimum at pH6.0 whereas the rate of the NADPH system is optimum at pH7.0. Both systems require phosphate for maximum activity. 3. Lipid peroxide formation occurs at the maximum specific rate in very dilute microsome suspensions (0.15mg. of protein/ml.). 4. Treatment of microsomes with deoxycholate and other detergents causes membrane disintegration and inhibits lipid peroxide formation. 5. Lipid peroxide formation is accompanied by a rapid uptake of oxygen and there is a large excess of oxygen utilized for each molecule of malonaldehyde measured in the peroxide method. 6. Boiled microsomes form lipid peroxide in the presence of ascorbate, but not if NADPH is added. 7. Lipid peroxide formation induced by NADPH is strongly inhibited by p-chloromercuribenzoate, weakly inhibited by N-ethylmaleimide and unaffected by iodoacetamide. Ascorbate-induced peroxidation in untreated microsomes is unaffected by p-chloromercuribenzoate, but inhibited if boiled microsomes are used. These experiments may be interpreted on the basis that a ferredoxin-type protein forms part of the system in which NADPH induces lipid peroxide formation. 8. Most heavy-metal ions, with the exception of inorganic iron (Fe(2+) or Fe(3+)), which activates, inhibit both ascorbate-induced and NADPH-induced peroxidation. Mg(2+) increases the rate of peroxidation whereas Ca(2+) inhibits it. 9. Lipid peroxide formation is inhibited strongly by GSH and weakly by cysteine. Ascorbate-induced peroxidation is much more sensitive than NADPH-induced peroxidation. 10. Peroxidation is strongly inhibited by addition of low concentrations (0.01-0.1mm) of cytochrome c or of haemoglobin. 11. It is considered that lipid peroxide formation occurs as a result of the operation of the microsomal electron-transport chain switching from hydroxylation to oxidize unsaturated lipids of the endoplasmic reticulum.
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PMID:Lipid peroxide formation in microsomes. General considerations. 439 Jan 1

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