EC:1.6.5.2 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.6.5.2 (NQO1)
6,196 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A nonhepatic vitamin K-dependent protein, matrix Gla protein, has recently been identified in cartilage where it may play an important role in the control of mineralization or matrix development. We have investigated the vitamin K cycle in chondrocytes isolated from bovine and rabbit articular cartilage and examined these cells for their ability to synthesize vitamin K-dependent proteins. Chondrocytes were found to have an active vitamin K-dependent carboxylation system. Preincubation of the cells with warfarin resulted in a significant increase in the measured carboxylase activity. Both vitamin K epoxide reductase and DT-diaphorase (EC 1.6.99.2) activity were present indicating that chondrocytes are capable of producing reduced vitamin K1H2, the cofactor for the vitamin K-dependent carboxylase. Specific 14C-labeling of microsomal vitamin K-dependent protein precursors demonstrated synthesis of several vitamin K-dependent proteins by chondrocytes. 35S-labeling of chondrocyte proteins provided evidence that matrix Gla protein is synthesized by these cells.
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PMID:Vitamin K-dependent carboxylation in articular chondrocytes. 176 34

In this in vivo study, the time-dependent effect of oral sodium warfarin was studied in male rats synchronized under a 12-hr light-dark cycle (light 0600-1800). Groups of 5 animals received an oral dose of 500 micrograms/kg of warfarin or saline at 0600 or 1800 and 1 mg/kg of vitamin K 8 hr later and the rats were sacrificed 240 min after vitamin K administration. The activities of the vitamin K reductase and vitamin K epoxide reductase were measured indirectly by determining the content of vitamin K1 and vitamin K epoxide reductase in the plasma and liver. The data obtained in control rats indicated that vitamin K and vitamin K 2,3 epoxide concentrations in plasma and liver were higher (P less than 0.05) at 1800 than at 0600. Warfarin had a greater (P less than 0.05) inhibitory effect on the vitamin K and vitamin K-epoxide reductases at 0600 compared to 1800; plasma levels of S- and R-warfarin did not vary with time of administration. The findings suggest that the activity of both reductases under control conditions, and the warfarin-induced inhibition of these enzymes varied depending on the time of drug administration.
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PMID:Temporal variation in the effects of warfarin on the vitamin K cycle. 209 73

Vitamin K is required as a cofactor for a microsomal enzyme that converts glutamyl residues in precursor proteins to gamma-carboxyglutamyl residues in completed proteins. These residues are essential for the biological function of prothrombin, factors VII, IX, and X, protein C, and protein S. Current data suggest that recognition of protein substrates by the carboxylase requires an unidentified protein-protein interaction in addition to the Glu substrate binding site. The primary vitamin K-dependent event has now been shown to be the abstraction of the gamma-hydrogen of the substrate Glu residue with the concurrent formation of vitamin K 2,3-epoxide. Coumarin anticoagulants appear to inhibit the microsomal vitamin K epoxide reductase and one of a number of microsomal quinone reductases. They therefore block vitamin K action by preventing the recycling of vitamin K epoxide to the quinone and to the active cofactor form, the hydroquinone. Excess vitamin K can reverse a coumarin anticoagulant effect as the nonsensitive quinone reductase can continue to furnish the active coenzyme.
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PMID:Studies of the vitamin K-dependent carboxylase and vitamin K epoxide reductase in rat liver. 353 Aug 99

The systems involved in vitamin K-dependent carboxylation and vitamin K metabolism have been extensively studied in rat liver. To determine how clinically applicable this information is, similar in vitro studies were completed using human liver. One major difference exists in the pathways that provide reduced vitamin K1 cofactor for the carboxylation reaction. The coumarin-sensitive DT-diaphorase (EC.1.6.99.2) in human liver appears to play a relatively minor role in the dehydrogenase pathway. However, similar to rat liver, the human liver contains a warfarin-insensitive enzyme in this dehydrogenase pathway. The data suggest that this enzyme is responsible for the antidotic effect of vitamin K1 in cases of coumarin intoxication. Human vitamin K epoxide reductase, which constitutes the other pathway for vitamin K1 reduction, has kinetic and enzymological characteristics that are very similar to the rat enzyme. This enzyme exhibited similar activity in rat and human microsomes. Initial velocities for vitamin K1 epoxide reduction in rat and human microsomes were 20 and 32 pmol/mg X min, respectively. The human enzyme is highly sensitive to warfarin inhibition. The mechanism for this inhibition appears to be similar to what has been proposed for the rat enzyme. Also, a vitamin K-dependent carboxylation system is described that allows both pathways to support the carboxylation reaction with reduced vitamin K1 cofactor. The effect of warfarin on this in vitro system is consistent with the current model for the mechanism of action of coumarin anticoagulant drugs in the rat.
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PMID:Vitamin K-dependent carboxylation and vitamin K metabolism in liver. Effects of warfarin. 393 74

The mechanism of salicylate-induced hypoprothrombinaemia has been investigated in the rat. Salicylate administration produced an increase in the percentage of the total liver vitamin that was present as vitamin K 2,3-epoxide, but the addition of salicylate did not influence vitamin K epoxide reductase activity in-vitro. Neither did it influence vitamin K-dependent carboxylase or vitamin K epoxidase activity. Both cytosolic and microsomal DT-diaphorase activities were, however, inhibited about 50% by 75 microM sodium salicylate. Salicylate inhibition was also observed when vitamin K quinone and NADH or dithiothreitol were used to support carboxylation. To achieve 50% inhibition required 0.5 mM salicylate with NADH as a reductant and 4 mM salicylate when dithiothreitol was the reductant. These results suggest that the main effect of salicylate on vitamin K metabolism is to inhibit quinone reductases and may be useful in explaining the inhibition of the biosynthesis of vitamin K-dependent clotting factors that occurs in salicylate-induced hypothrombinaemia. These data also demonstrate that the percentage of total liver vitamin present as vitamin K epoxide can be increased by agents that do not have a direct effect on the vitamin K epoxide reductase in-vitro.
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PMID:The effects of salicylate on enzymes of vitamin K metabolism. 613 82

Salicylate antagonizes the vitamin K-dependent biosynthesis of clotting factors in the rat and produces an elevation of the ratio of vitamin K epoxide to vitamin K in the liver. Vitamin K epoxide is reduced to vitamin K by a vitamin K epoxide reductase, and 1 mM salicylate was required to cause a 50% inhibition of the dithiothreitol-dependent in-vitro reduction of vitamin K epoxide by this enzyme. This enzyme was, however, inhibited 50% by as little as 70-80 microM salicylate when reducing equivalents for the reaction were furnished by endogenous cytosolic reductants. This effect on the cytosolic reductant supply was shown to be unrelated to a previously demonstrated inhibition of DT-diaphorase by salicylate. The concentrations of salicylate at which significant inhibitory effects are exerted in-vitro (50-100 microM) are below the 200 microM levels observed in the livers of rats given an anticoagulating dose of salicylate.
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PMID:Indirect inhibition of vitamin K epoxide reduction by salicylate. 614 81

Lapachol [2-hydroxy-3-(3-methyl-2-butenyl)-1,4-naphthoquinone] has been shown to be a potent inhibitor of both vitamin K epoxide reductase and the dithiothreitol-dependent vitamin K quinone reductase of rat liver microsomes in vitro. These observations explain the anticoagulant activity of lapachol previously observed in both rats and humans. Lapachol inhibition of the vitamin K epoxide and quinone reductases resembled coumarin anticoagulant inhibition, and was observed in normal strain but not in warfarin-resistant strain rat liver microsomes. This similarity of action suggests that the lactone functionality of the coumarins is not critical for their activity. The initial-velocity steady-state inhibition patterns for lapachol inhibition of the solubilized vitamin K epoxide reductase were consistent with tight binding of lapachol to the oxidized form of the enzyme, and somewhat lower affinity for the reduced form. It is proposed that lapachol assumes a 4-enol tautomeric structure similar to that of the 4-hydroxy coumarins. These structures are analogs of the postulated hydroxyvitamin K enolate intermediate bound to the oxidized form of the enzyme in the chemical reaction mechanism of vitamin K epoxide reductase, thus explaining their high affinity.
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PMID:Lapachol inhibition of vitamin K epoxide reductase and vitamin K quinone reductase. 649 79

Administration of the antihypertensive drug ticrynafen [2,3-dichloro-4-(2-thienylcarbonyl)-phenoxyacetic acid] has been reported to potentiate the effects of coumarin anticoagulants and to have caused hemorrhagic incidents in some patients. This drug interaction has now been reproduced in the rat. Ticrynafen administration enhanced the degree of hypoprothrombinemia and altered plasma and hepatic vitamin K epoxide concentrations in warfarin-treated rats. Ticrynafen did not affect vitamin K-dependent carboxylase or vitamin K epoxide reductase activities in vitro. Cytosolic DT-diaphorase was very sensitive to ticrynafen inhibition in vitro, and inhibition of vitamin K reduction via this enzyme is a possible mechanism by which ticrynafen potentiates coumarin anticoagulant action. Inhibition of this enzyme may also contribute to the reported hepatotoxicity of ticrynafen.
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PMID:Mechanism of ticrynafen potentiation of coumarin anticoagulant action. 661 42

Two procedures have been developed for the solubilization of vitamin K epoxide reductase from rat liver microsomal membranes using the detergent Deriphat 160 at pH 10.8. The methods are applicable to both normal and Warfarin-resistant-strain rat liver microsomes and yield material suitable for further purification. The preparations retain dithiothreitol-dependent vitamin K quinone reductase activity as well as vitamin K epoxide reductase and are free of vitamin K-dependent carboxylase and epoxidase activities. Optimal epoxide reductase activity is obtained at 0.1 M KCl and pH 9 in the presence of sodium cholate. Artifactual formation of vitamin K metabolites was eliminated through the use of mercuric chloride to remove excess dithiothreitol prior to extraction and metabolite assay. Using the solubilized enzyme, valid initial velocities were measured, and reproducible kinetic data was obtained. The substrate initial velocity patterns were determined and are consistent with a ping-pong kinetic mechanism. The kinetic parameters obtained are a function of the cholate concentration, but do not vary drastically from those obtained using intact microsomal membranes. At 0.8% cholate, the enzymes solubilized from normal Warfarin-sensitive- and Warfarin-resistant-strain rat livers exhibit respective values of Vmax = 3 and 0.75 nmol/min/g liver; Km for vitamin K epoxide = 9 and 4 microM; and Km for dithiothreitol of 0.6 and 0.16 mM.
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PMID:Solubilization and characterization of vitamin K epoxide reductase from normal and warfarin-resistant rat liver microsomes. 669 43

The in vitro effects of two coumarin anticoagulants, warfarin and difenacoum, on rat liver microsomal vitamin K dependent carboxylase, vitamin K epoxidase, vitamin K epoxide reductase, and cytosolic vitamin K reductase (DT-diaphorase) from the livers of normal and a warfarin-resistant strain of rats have been determined. Millimolar concentrations of both coumarins are required to inhibit the carboxylase and epoxidase activities in both strains of rats. Sensitivity of DT-diaphorase to coumarin inhibition differs when a soluble or liposomal-associated substrate is used, but the diaphorases isolated from both strains of rats have comparable sensitivity. The anticoagulant difenacoum is an effective rodenticide in the warfarin-resistant strain of rats, and the only enzyme studied from warfarin-resistant rat liver that demonstrated a significant differential inhibition by the two coumarins used was the vitamin K epoxide reductase. This enzyme also showed the greatest sensitivity to coumarin inhibition among the enzymes studied. These results support the hypothesis that the physiologically important site of action of coumarin anticoagulants is the vitamin K epoxide reductase.
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PMID:Mechanism of coumarin action: sensitivity of vitamin K metabolizing enzymes of normal and warfarin-resistant rat liver. 680 39

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