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Abstract
Sucrose phosphorylase is a bacterial α-transglucosidase that catalyses glucosyl transfer from sucrose to phosphate, releasing d-fructose and α-d-glucose 1-phosphate as the product of the first (enzyme glucosylation) and second (enzyme deglucosylation) step of the enzymatic reaction, respectively. The transferred glucosyl moiety of sucrose is accommodated at the catalytic subsite of the phosphorylase through a network of charged hydrogen bonds whereby a highly conserved residue pair of Asp and Arg points towards the equatorial hydroxyl at C4. To examine the role of this ‘hyperpolar’ binding site for the substrate 4-OH, we have mutated Asp49 and Arg395 of Leuconostoc mesenteroides sucrose phosphorylase individually to Ala (D49A) and Leu (R395L), respectively, and also prepared an ‘uncharged’ double mutant harbouring both site-directed substitutions. The efficiency for enzyme glucosylation from sucrose was massively decreased in purified preparations of D49A (107-fold) and R395L (105-fold) as compared to wild-type enzyme. The double mutant was not active above the detection limit. Enzyme deglucosylation to phosphate proceeded relatively efficient in D49A as well as R395L, about 500-fold less than in the wild-type phosphorylase. Substrate inhibition by phosphate and a loss in selectivity for reaction with phosphate as compared to water were new features in the two mutants. Asp49 and Arg395 are both essential in the catalytic reaction of L. mesenteroides sucrose phosphorylase.
Declaration of interest: The authors report no conflicts of interest. The authors alone are responsible for the content and writing of the paper. Financial support from the Austrian Science Funds FWF (project L586-B03 to B.N.) is gratefully acknowledged.