Stereospecificity of substrate usage by glyoxalase 1: nuclear magnetic resonance studies of kinetics and hemithioacetal substrate conformation

Abstract

The specificity of glyoxalase 1 for the diastereomers of its hemithioacetal substrate [which forms spontaneously between an alpha-keto aldehyde and reduced glutathione (GSH)] was investigated by exploiting the differences between their 1H NMR spectra at pH* 4.4. The 1H NMR spectra of the hemithioacetals of glutathione with phenylglyoxal or methylglyoxal were assigned with the aid of conventional decoupling and two-dimensional NMR spectroscopic techniques. The rate of interconversion of the diastereomers was determined at 30 degrees C from the results of an inversion-transfer technique and found to be 0.30 +/- 0.04 s-1 (+/- sd) in the case of phenylglyoxal and 0.15 +/- 0.02 s-1 in the case of methylglyoxal. Stereopreference of the enzyme was tested by the addition of large amounts of yeast glyoxalase 1 to a reaction mixture; glyoxalase 1 preferentially operated on one diastereomer of the phenylglyoxal hemithioacetal but the diastereomers of methylglyoxal appeared to be operated upon indiscriminately. From computer models of the kinetics of possible reaction schemes, a mechanism involving glyoxalase 1 catalysis of both diastereomers of the hemithioacetals was shown to be the most consistent with the experimental data. Estimates of internuclear distances in the diastereomers, obtained from 2D NMR spectra were used in "dynamical simulated annealing" calculations to generate likely structures of the substrates. Relative ring-current shifts obtained from 1D NMR spectra were used, together with a ring-current shift algorithm, to select structures with compatible conformations. We conclude that the rate of conversion of substrate by the enzyme is dependent upon the overall conformation of the substrate molecule, rather than merely its stereochemical configuration (R or S).