The autoxidation of glyceraldehyde and other simple monosaccharides under physiological conditions catalysed by buffer ions

Abstract

Glyceraldehyde and other simple monosaccharides autoxidise under physiological conditions generating 1-hydroxyalkyl (carbon-centred) free radicals and intermediates of dioxygen reduction: superoxide, hydrogen peroxide and hydroxyl radicals. The major glyceraldehyde-derived product is the alpha-ketoaldehyde, hydroxypyruvaldehyde. Close similarities between the temperature dependence of the kinetics of glyceraldehyde autoxidation and glyceraldehyde enolisation to an ene-diol indicates that enolisation is the rate-determining step in the autoxidative process. Inspection of a wide range of carbonyl compounds showed that the monosaccharide moiety -CH(OH)-C- is conserved in carbonyl compounds reactive towards autoxidation, indicating that the ability to form an ene-diol is a prerequisite to monosaccharide autoxidation. The ene-diol intermediate autoxidises rapidly to the products: hydrogen peroxide, water and alpha-ketoaldehydes: beta-hydroxypyruvaldehyde is produced from glyceraldehyde and dihydroxyacetone, glyoxal from glycolaldehyde autoxidation. Ene-diol autoxidation is catalysed by hydrogen peroxide and trace metal ion contaminants; removal of either of these factors sufficiently retards ene-diol autoxidation such that ene-diol autoxidation rather than enolisation becomes the rate determining step in the overall autoxidative process. Under enolisation control, the rate of monosaccharide autoxidation is influenced by pH and the buffer system used for pH control.