The alpha-amylases as glycosylases, with wider catalytic capacities than envisioned or explained by their representation as hydrolases

In a study undertaken to illustrate the inadequacy of the familiar concept of carbohydrases as hydrolases, crystalline α-amylases from six different sources, as well as crude salivary amylase, were examined and found to catalyze the synthesis of maltose and maltosaccharides from α-d-glucopyranosyl fluoride, a stereoanalog of α-d-glucopyranose. These syntheses apparently involve initial formation of maltosyl fluoride and higher maltosaccharide 1-fluorides, traces of which were found in digests with certain α-amylases. That the reactions are due to the α-amylases themselves and not to some accompanying enzyme(s) appears certain from the purity and diversity of the preparations; their failure (with one exception) to attack α- or β-maltose; the correspondence of the synthesized products with the known specificity of α-amylases for α-1,4-d-glucosidic linkages (and capacity of different α-amylases to hydrolyze saccharides of different sizes). The “saccharifying” α-amylase of B. sublilis var amylosacchariticus was unique in producing maltosaccharides from both α- and β-maltose (i.e., by α-d-glucosyl transfer). However, the entire group of α-amylases had the capacity to promote α-d-glucosyl transfer from α-d-glucosyl fluoride to C₄-carbinol sites, demonstrating for the first time that the catalytic range of α-amylase extends beyond hydrolysis and its reversal. Indeed, all transferred the glucosyl group of α-d-glycosyl fluoride preferentially to C₄-carbinols rather than water—a finding neither anticipated nor explained by the representation of α-amylases as hydrolases.