Glucose modification of human serum albumin: a structural study.

Structural changes associated with the exposure of human serum albumin (HSA) to glucose with or without the presence of Cu (II) have been characterized using a bank of methods for structural analysis including circular dichroism (CD), amino acid analysis (AAA), fluorescence measurements, SDS-PAGE, and boronate binding (which is a measure of Amadori product formation). We show that in the short-term (10 d) incubation mixtures, HSA is resistant to Cu (II)-mediated oxidative damage and that the early products of glycation of HSA had minimal effects on the folded structure. Amino acid analysis showed that there was no formation of advanced glycation endproducts (AGE), which can be measured by loss of lysine. This remained the case in longer term incubation of HSA (56 d) in the hyperglycemic concentration range (5-25 mM glucose) despite increased levels of Amadori product (60% boronate binding) and the formation of glycophore (Excitation 350, Emission 425). At high, nonphysiological concentrations (100 mM and 500 mM) of glucose, glycophore formation increased and 3 and 11 mol Lysine-glucose adduct/mol HSA were converted to AGE, respectively. This was accompanied by increased damage to tryptophan and protein-protein crosslinking but only minor tertiary structural change. In the presence of Cu (II), however, AGE formation was accompanied by extensive damage to histidine and tryptophan side chains, main chain fragmentation, and loss of both secondary and tertiary structure. Thus, changes in structure appear to be the result of oxidation as opposed to glycation, per se.