Oxidized quercetin reacts with thiols rather than with ascorbate: implication for quercetin supplementation

When an antioxidant scavenges a reactive species, i.e., when it exerts its antioxidant activity, the antioxidant is converted into potentially harmful oxidation products. In this way, the antioxidant quercetin might yield an ortho-quinone, denoted as QQ, which has four tautomeric forms, i.e., the ortho-quinone and three quinonmethides. We evaluated the interaction of QQ with ascorbate or glutathione (GSH). Ascorbate recycles QQ to the parent compound quercetin, while GSH forms two adducts with QQ, i.e., 6-GSQ and 8-GSQ. When both GSH and ascorbate are present, QQ is converted exclusively into GSQ. In the absence of GSH, protein thiols will be arylated by QQ. This protein arylation is not prevented by ascorbate. Thiol arylation by quinones and quinonmethides can impair several vital enzymes. This implies that the product formed when quercetin displays its antioxidant scavenging effect is toxic in the absence of GSH. Therefore, an adequate GSH level should be maintained when quercetin is supplemented.     

The reaction of flavonoid metabolites with peroxynitrite

There is much interest in the bioactivity of in vivo flavonoid metabolites. We report for the first time the hierarchy of reactivity of flavonoid metabolites with peroxynitrite and characterise novel reaction products. O-Methylation of the B-ring catechol containing flavonoids epicatechin and quercetin, and O-glucuronidation of all flavonoids reduced their reactivity with peroxynitrite. The reaction of the flavanones hesperetin and naringenin and their glucuronides resulted in the formation of multiple mono-nitrated and nitrosated products. In contrast, the catechol-containing flavonoids epicatechin and quercetin yielded oxidation products which when trapped with glutathione led to the production of glutathionyl-conjugates. However, the O-methylated metabolites of epicatechin yielded both mono- and di-nitrated products and nitrosated metabolites. The 3'-O-methyl metabolite of quercetin also yielded a nitrosated species, although its counterpart 4'-O-methyl quercetin yielded only oxidation products. Such products may represent novel metabolic products in vivo and may also express cellular activity.     

Modification of Proteinase Inhibitor II in Adzuki Beans during Germination

We investigated the effects of compounds isolated from a methanolic extract of rose hips on melanin biosynthesis in B16 mouse melanoma cells and the possible mechanisms responsible for the inhibition of melanin biosynthesis. We found that, among the isolated compounds, quercetin was a particularly potent melanogenesis inhibitor. To reveal the mechanism for this inhibition, the effects on tyrosinase of B16 mouse melanoma were measured. Quercetin decreased the intracellular tyrosinase activity as well as the tyrosinase activity in a cell culture-free system. We also examined the cellular level of tyrosinase protein and found that quercetin dose-dependently inhibited tyrosinase protein expression. We consider from these results that the inhibition of melanogenesis by quercetin was due to the inhibition of both tyrosinase activity and of the protein expression.