Glycosyltransferase Engineering and Multi-glycosylation Routes Development Facilitating Synthesis of High-intensity Sweetener Mogrosides

Overview

Journal iScience

Publisher Cell Press

Date 2022 Oct 17

PMID 36248741

Authors

Jiao Li

Shicheng Mu

Jiangang Yang

Cui Liu

Yanfei Zhang

Peng Chen

Yan Zeng

Yueming Zhu

Yuanxia Sun

Affiliations

Soon will be listed here.

Abstract

Mogrosides are widely served as natural zero-calorie sweeteners. To date, the biosynthesis of high-intensity sweetness mogrosides V from mogrol has not been achieved because of inefficient and uncontrollable multi-glycosylation process. To address this challenge, we reported three UDP-glycosyltransferases (UGTs) catalyzing the primary and branched glycosylation of mogrosides and increased the catalytic efficiency by 74-400-folds toward branched glycosylation using an activity-based sequence conservative analysis engineering strategy. The computational studies provided insights into the origin of improved catalytic activity. By virtue of UGT mutants, we provided regio- and bond-controllable multi-glycosylation routes, successfully facilitating sequential glycosylation of mogrol to three kinds of mogroside V in excellent yield of 91-99%. Meanwhile, the feasibility of the routes was confirmed in engineered yeasts. It suggested that the multi-glycosylation routes would be combined with mogrol synthetic pathway to produce mogrosides from glucose by aid of metabolic engineering and synthetic biology strategies in the future.

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