- Novel degradation pathway of glycated amino acids into free fructosamine by a Pseudomonas sp. soil strain extract.
Novel degradation pathway of glycated amino acids into free fructosamine by a Pseudomonas sp. soil strain extract.
A Pseudomonas sp. soil strain, selected for its ability to grow on epsilon-(1-deoxyfructosyl) aminocaproic acid, was induced to express a membrane-bound enzymatic activity which oxidatively degrades Amadori products into free fructosamine. Apparent Km values for fructosyl aminocaproate, epsilon-fructosyl lysine, fructosyl glycine, and ribated lysine were 0.21 mM, 2.73 mM, 3.52 mM, and 1.57 mM, respectively. The enzyme was also active against alpha-fructosyl lysine and borohydride-reduced Amadori product, weakly active with ribated and glycated polylysine, and inactive with reducing sugars, amino acids, and glycated proteins. The enzymatic activity was highest at pH 6.5 and 25 degrees C in 0.1 M sodium phosphate, while over 80% of the activity was lost above 65 degrees C. Complete inhibition was observed by HgCl2, NaN3, and NaCN suggesting a role for SH groups and copper in the enzymatic activity. The reaction products were characterized by 1H NMR, 13C NMR, and GC/MS and found to correspond to 1-deoxy-1-aminofructose, i.e. free "fructosamine," and adipic acid. Confirmation of the free fructosamine structure was based on the complete spectroscopic identity of the borohydride reduction product with commercially available glucamine (1-amino-1-deoxyglucitol). The new enzyme is provisorily classified as fructosyl N-alkyl amino acid oxidase (EC 1.5.3) (fructosyl-amino acid:oxygen oxidoreductase) and may thus belong to a novel class of "Amadoriases" which deglycate Amadori products oxidatively. In contrast, however, the new enzyme acts on the alkylamine bond rather than the ketoamine bond of the Amadori product.