Engineering the glucansucrase GTFR enzyme reaction and glycosidic bond specificity: toward tailor-made polymer and oligosaccharide products

Abstract

Two long-standing questions about glucansucrases (EC 2.4.1.5) are how they control oligosaccharide versus polysaccharide synthesis and how they direct their glycosidic linkage specificity. This information is required for the production of tailor-made saccharides. Mutagenesis promises to be an effective tool for enzyme engineering approaches for altering the regioselectivity and acceptor substrate specificity. Therefore, we chose the most conserved motif around the transition state stabilizer in glucansucrases for a random mutagenesis of the glucansucrase GTFR of Streptococcus oralis, yielding different variants with altered reaction specificity. Modifications at position S628 achieved by saturation mutagenesis guided the reaction toward the synthesis of short chain oligosaccharides with a drastically increased yield of isomaltose (47%) or leucrose (64%). Alternatively, GTFR variant R624G/V630I/D717A exhibited a drastic switch in regioselectivity from a dextran type with mainly alpha-1,6-glucosidic linkages to a mutan type polymer with predominantly alpha-1,3-glucosidic linkages. Targeted modifications demonstrated that both mutations near the transition state stabilizer, R624G and V630I, are contributing to this alteration. It is thus shown that mutagenesis can guide the transglycosylation reaction of glucansucrase enzymes toward the synthesis of (a) various short chain oligosaccharides or (b) novel polymers with completely altered linkages, without compromising their high transglycosylation activity and efficiency.