Glucose, a common monosaccharide in nature, is dominated by the d-enantiomer. Meanwhile, the discovery of l-glucose-utilizing bacteria and the elucidation of their metabolic pathways 10 years ago suggests that l-glucose exists naturally. Most carbohydrates exist as glycosides rather than monosaccharides; therefore, we expected that nature also contains l-glucosides. Sequence analysis within glycoside hydrolase family 29 led us to identify two α-l-glucosidases, ClAgl29A and ClAgl29B, derived from Cecembia lonarensis LW9. ClAgl29A and ClAgl29B exhibited higher K m, k cat, and k cat/K m values for p-nitrophenyl α-l-glucoside than that for p-nitrophenyl α-l-fucoside. Structural analysis of ClAgl29B in complex with l-glucose showed that these enzymes have an active-site pocket that preferentially binds α-l-glucoside, but excludes α-l-fucoside. These results suggest that ClAgl29A and ClAgl29B evolved to hydrolyze α-l-glucoside, implying the existence of α-l-glucoside in nature. Furthermore, α-l-glucosidic linkages (α-l-Glc-(1 → 3)-l-Glc, α-l-Glc-(1 → 2)-l-Glc, and α-l-Glc-(1 → 6)-l-Glc) were synthesized by the transglucosylation activity of ClAgl29A and ClAgl29B. We believe that this study will lead to new research on α-l-glucosides, including determining the physiological effects on humans, and the discovery of novel α-l-glucoside-related enzymes.
© 2022 The Authors. Published by American Chemical Society.