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Directed Evolution of the UDP-Glycosyltransferase UGT<sub>BL</sub>1 for Highly Regioselective and Efficient Biosynthesis of Natural Phenolic Glycosides

Chenhao Zhang, Yongchao Cai, Z. Zhang, Nan Zheng, Huimin Zhou, Yumeng Su, Shuang Du, Asif Hussain, Xiaole Xia

2024Journal of Agricultural and Food Chemistry15 citationsDOI

Abstract

The O-glycosylation of polyphenols for the synthesis of glycosides has garnered substantial attention in food research applications. However, the practical utility of UDP-glycosyltransferases (UGTs) is significantly hindered by their low catalytic efficiency and suboptimal regioselectivity. The concurrent optimization of the regioselectivity and activity during the glycosylation of polyphenols presents a formidable challenge. Here, we addressed the long-standing activity–regioselectivity tradeoff in glycosyltransferase UGT BL 1 through systematic enzyme engineering. The optimal combination of mutants, N61S/I62M/D63W/A208R/P218W/R282W (SMWRW 1 W 2 ), yielded a 6.1-fold improvement in relative activity and a 17.3-fold increase in the ratio of gastrodin to para -hydroxybenzyl alcohol-4′- O -β-glucoside (with 89.5% regioselectivity for gastrodin) compared to those of the wild-type enzyme and ultimately allowed gram-scale production of gastrodin (1,066.2 mg/L) using whole-cell biocatalysis. In addition, variant SMWRW 1 W 2 exhibited a preference for producing phenolic glycosides from several substrates. This study lays the foundation for the engineering of additional UGTs and the practical applications of UGTs in regioselective retrofitting.

Topics & Concepts

RegioselectivityGlycosylationGlycosyltransferaseGlycosideChemistryGastrodinBiocatalysisDirected evolutionEnzymeBiochemistryStereochemistryMutantCatalysisGeneIonic liquidChromatographyEnzyme Catalysis and ImmobilizationPlant Gene Expression AnalysisMicrobial Metabolic Engineering and Bioproduction