Computational and experimental analyses of furcatin hydrolase for substrate specificity studies of disaccharide-specific glycosidases.

Disaccharide-specific glycosidases (diglycosidases) are unique glycoside hydrolases, as their substrate specificities differ from those of monosaccharide-specific beta-glycosidases (monoglycosidases), in spite of similarities in their sequences and reaction mechanisms. Diglycosidases selectively hydrolyse the beta-glycosidic bond between glycone and aglycone of disaccharide glycosides, but do not cleave the bond between two saccharides, and barely hydrolyse monosaccharide glycosides. We analysed the substrate recognition mechanisms of diglycosidases by computational and experimental methods, using furcatin hydrolase (FH) (EC 3.2.1.161) derived from Viburnum furcatum. Amino acid sequence comparisons and model structure building revealed two residues, Ala419 and Ser504 of FH, as candidates determining the substrate specificity. These residues were specifically conserved in the diglycosidases. The model structure suggested that Ala419 is involved in the aglycone recognition, whereas Ser504 recognizes the external saccharide of the glycone. Mutations at these sites drastically decreased the diglycosidase activity. The mechanism by which the diglycosidases acquired their substrate specificity is discussed, based on these observations.

Furcatin hydrolase from Viburnum furcatum Blume is a novel disaccharide-specific acuminosidase in glycosyl hydrolase family 1.

Furcatin hydrolase (FH) is a unique disaccharide-specific acuminosidase, which hydrolyzes furcatin (p-allylphenyl 6-O-beta-D-apiofuranosyl-beta-D-glucopyranoside (acuminoside)) into p-allylphenol and the disaccharide acuminose. We have isolated a cDNA coding for FH from Viburnum furcatum leaves. The open reading frame in the cDNA encoded a 538-amino acid polypeptide including a putative chloroplast transit peptide. The deduced protein showed 64% identity with tea leaf beta-primeverosidase, which is another disaccharide glycosidase specific to beta-primeverosides (6-O-beta-D-xylopyranosyl-beta-D-glucopyranosides). The deduced FH also shared greater than 50% identity with various plant beta-glucosidases in glycosyl hydrolase family 1. The recombinant FH expressed in Escherichia coli exhibited the highest level of activity toward furcatin with a Km value of 2.2 mm and specifically hydrolyzed the beta-glycosidic bond between p-allylphenol and acuminose, confirming FH as a disaccharide glycosidase. The FH also hydrolyzed beta-primeverosides and beta-vicianoside (6-O-alpha-L-arabinopyranosyl-beta-D-glucopyranoside) but poorly hydrolyzed beta-gentiobiosides (6-O-beta-D-glucopyranosyl-beta-d-glucopyranosides), indicating high substrate specificity for the disaccharide glycone moiety. The FH exhibited activity toward p-allylphenyl beta-D-glucopyranoside containing the same aglycone as furcatin but little activity toward the other beta-D-glucopyranosides. Stereochemical analysis using 1H NMR spectroscopy revealed that FH is a retaining glycosidase. The subcellular localization of FH was analyzed using green fluorescent protein fused with the putative N-terminal signal peptide, indicating that FH is localized to the chloroplast. Phylogenetic analysis of plant beta-glucosidases revealed that FH clusters with beta-primeverosidase, and this suggests that the disaccharide glycosidases will form a new subfamily in glycosyl hydrolase family 1.