Engineering novel S-glycosidase activity into extremo-adapted β-glucosidase by rational design

The breakdown of sulphur glycosidic bonds in thioglycosides can produce isothiocyanate, a chemoprotective agent linked to the prevention of cancers; however, only a handful of enzymes have been identified that are k0nown to catalyse this reaction. Structural studies of the myrosinase enzyme, which is capable of hydrolysing the thioglycosidic bond, have identified residues that may play important roles in sulphur bond specific activity. Using rational design, two extremo-adapted β-glycosidases from the species Thermus nonproteolyticus ( Tno GH1) and Halothermothrix orenii ( Hor GH1) were engineered towards thioglycoside substrates. Twelve variants, six for Tno GH1and six for Hor GH1, were assayed for activity. Remarkable enhancement of the specificity ( k cat / K M ) of Tno GH1 and Hor GH1 towards β-thioglycoside was observed in the single mutants Tno GH1-V287R (2500 M −1 s −1 ) and Hor GH1-M229R (13,260 M −1 s −1 ) which showed a 3-fold increase with no loss in turnover rate when compared with the wild-type enzymes. Thus, the role of arginine is key to induce β-thioglycosidase activity. Thorough kinetic investigation of the different mutants has shed light on the mechanism of β-glycosidases when acting on the native substrate. Key Points •Key residues were identified in the active site of Brevicoryne brassicae myrosinase. •Rationally designed mutations were introduced into two extremo-adapted β-glycosidases. •β-glycosidases mutants exhibited improved activity against thioglycosidic bonds. •The mutation to arginine in the active site yielded the best variant.