vitamin-k-semiquinone-radical and diphenyl-sulfoxide

The reduction of sulindac, sulphinpyrazone and diphenyl sulphoxide to their thioether analogues has been studied in vitro using rat and rabbit tissues. Sulindac reduction was about 10-fold higher in homogenates of rat kidney and liver than in other tissues although the tissue differences decreased when dithiothreitol was used as a co-factor. The greatest sulindac reducing activity in rat liver was in the cytosolic fraction whereas reoxidation of the thioether back to the sulphoxide was largely in the microsomal fraction. Studies using NADPH/NADH, acetaldehyde and dithiothreitol as cofactors showed that aldehyde oxidase was the main sulindac reducing system in rat and rabbit liver cytosols but not in renal cytosols where reduction was probably linked to the thioredoxin system, as reported previously. Menadione and hydralazine caused essentially complete inhibition of sulindac reduction by hepatic but not renal cytosol and the inhibition was dependent on preincubation of the enzyme with the inhibitor, which is indicative of aldehyde oxidase activity. Little reduction of sulphinpyrazone or diphenyl sulphoxide was detected with rat or rabbit kidney or renal cytosols, although increased reduction was detected when acetaldehyde was added as a cofactor to rabbit and rat liver cytosols. The data indicate that different enzyme systems are responsible for sulphoxide reduction in the liver and kidney.

Topics: Animals; Benzene Derivatives; Female; Hydralazine; Kidney; Liver; Oxidation-Reduction; Oxidoreductases; Oxidoreductases Acting on Sulfur Group Donors; Rabbits; Rats; Subcellular Fractions; Sulfinpyrazone; Sulindac; Vitamin K

To characterize the properties of diphenyl sulfoxide (DPSO) as a new type of electron acceptor for guinea pig liver aldehyde oxidase (AO), we compared the kinetics of the reductions of DPSO and other classical electron acceptors such as O2 and ferricyanide. The double-reciprocal plot of the 2-hydroxypyrimidine (2-OH PM)-linked DPSO reduction with the highly purified enzyme was biphasic. Similar biphasic plots were obtained with the reductions of other electron acceptors. Only the lower Km value, which was obtained by extrapolation of the plot at lower concentrations of 2-OH PM, was identical with that shown by the freshly prepared crude enzyme. DPSO as well as menadione progressively inhibited the reductions of O2 and ferricyanide with time. Menadione inhibited the DPSO reduction noncompetitively with respect to 2-OH PM and competitively with respect to DPSO, while its mode of inhibition of ferricyanide reduction was uncompetitive for either the electron donor or the acceptor. On the other hand, DPSO showed an uncompetitive and a noncompetitive inhibition of ferricyanide reduction with respect to 2-OH PM and ferricyanide, respectively. These results may indicate that DPSO interacts with the enzyme at the same site as menadione, and thereby when other electron acceptors are present it serves as an actual inhibitor rather than as an electron acceptor for AO.

Topics: Aldehyde Oxidase; Aldehyde Oxidoreductases; Animals; Benzene Derivatives; Guinea Pigs; Kinetics; Liver; Milk; Oxidation-Reduction; Vitamin K; Xanthine Oxidase