Trapping of reactive intermediates in enzymology. Exogenous flavin reduction during catalytic turnover of substrate by glyoxalase I.

Although but weak inhibitors of glyoxalase I under steady-state conditions, flavins are reduced by yeast glyoxalase I (lactoyl-glutathione lyase, EC 4.4.1.5) plus its substrate (the hemithiolacetal from glutathione and phenylglyoxal) during catalytic turnover. Studies with 10-ethylisoalloxazine showed that this flavin reduction was peculiar not merely to glyoxalase I's substrate, but was characteristic of the complete system, enzyme plus substrate undergoing catalytic turnover. Flavins are poor hydride-ion acceptors and the reduction observed most likely represents an oxidative trap of a transient carbanion formed in the glyoxalase I mechanism of action. Hydrophobic flavins were more efficient traps than the hydrophilic ones, and values of the Km for the phenylglyoxal: glutathione hemithiolacetal adduct measured by the flavin-reaction and by normal steady-state kinetics were closely similar. This argues that trapping has occurred of an enediolate ion (an enzyme-generated carbanion) still bound to glyoxalase I.

Partial transition-state inhibitors of glyoxalase I from human erythrocytes, yeast and rat liver.

Glyoxalase I (lactoylglutathione lyase, EC 4.4.1.5) converts the hemithiolacetal of glutathione and an alpha-ketoaldehyde to S-D-lactoylglutathione which is hydrolysed under the catalytic influence of glyoxalase II to produce D-lactate and regenerate glutathione. There is much evidence that glyoxalase I operates via an enediol intermediate, and in this study a number of inhibitors are described which were designed based on the enediol moiety of this reactive intermediate. These enediol and paene-enediol moieties were combined with groups designed to make use of an adjacent hydrophobic site and can be described as partial transition-state analogues. Derivatives of lapachol and kojic acid were good competitive inhibitors of glyoxalase I from various sources unless the free hydroxy group was blocked or replaced. Flavones with strong inhibitors of glyoxalase I and gallocyanine (a dye) showed spectral changes on binding to glyoxalase I indicative of binding to a metal-ion site (probably Zn2+ or Mg2+). The use of the enediol-binding determinant to produce glyoxalase I inhibitors is discussed as a route to potential antitumour derivatives.