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Comprehensive engineering of novel glycosyltransferase for efficient, donor-promiscuous, and regioselective glycosylation of flavonoids

Yang Lu, Lianghua Xie, Jiahong Xie, Gexin Liu, Jiaqi Fu, Luheng Zou, Qiu Lin, Yong Wang, Wei Chen

2025Science Advances15 citationsDOIOpen Access PDF

Abstract

Flavonoid O -glycosylation, catalyzed by uridine diphosphate (UDP)–glycosyltransferases, is crucial for their therapeutic efficacy. However, most UDP-glycosyltransferases encounter three major limitations: low activity, poor regioselectivity, and restricted substrate availability, hindering their pharmaceutical applications. To address these challenges, we conducted protein engineering on a previously unidentified glycosyltransferase, UGT75AJ2, which had 3′,7- O -glycosylation capabilities. Our approach involved three strategies: (i) development of a tailored focused rational iterative site-specific mutagenesis strategy, augmented by virtual screening and iterative mutagenesis, to design mutant Mut4-1 (S367A/V274A/F82V/I132T) with a 128-fold enhancement in relative catalytic activity; (ii) enhancement of the enzyme’s compatibility with a broader spectrum of sugar donors achieved through structural-based engineering, yielding mutant S14G/F366H/S367G and demonstrating effective utilization of diverse donors; (iii) construction of a targeted mutant library to enhance regioselectivity by active site analysis, leading to mutants with high selectivity for targeted glycosylation sites. This comprehensive study tackles predominant challenges in UDP-glycosyltransferases protein engineering, providing innovative approaches and insights that enhance the development of flavonoid glycosides.

Topics & Concepts

GlycosylationMutantRational designGlycosyltransferaseBiochemistryMutagenesisChemistryRegioselectivityComputational biologyFlavonoidProtein engineeringVirtual screeningCombinatorial chemistryActive siteDirected evolutionDrug designDrug discoveryProtein–protein interactionSite-directed mutagenesisSubstrate specificityEnzymeUridine diphosphateSaturated mutagenesisHigh-throughput screeningSubstrate (aquarium)Computer scienceGlycosylation and Glycoproteins ResearchCarbohydrate Chemistry and SynthesisBiochemical and Structural Characterization
Comprehensive engineering of novel glycosyltransferase for efficient, donor-promiscuous, and regioselective glycosylation of flavonoids | Litcius