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Systematic Engineering of <i>Saccharomyces cerevisiae</i> Chassis for Efficient Flavonoid-7-<i>O</i>-Disaccharide Biosynthesis

Zhiqiang Xiao, Yongtong Wang, Juan Liu, Siqi Zhang, Xinjia Tan, Yifei Zhao, Jiwei Mao, Ning Jiang, Jingwen Zhou, Yang Shan

2023ACS Synthetic Biology34 citationsDOI

Abstract

Flavonoids are an essential class of secondary metabolites found in plants and possess various nutritional, medicinal, and agricultural properties. However, the poor water solubility of flavonoid aglycones limits their potential applications. To overcome this issue, glycosylation is a promising approach for improving water solubility and bioavailability. In this study, we constructed a flavonoid-7- O -disaccharide biosynthetic pathway with flavonoid aglycones as substrates in Saccharomyces cerevisiae . Subsequently, through metabolic engineering and promoter strategies, we constructed a UDP-rhamnose regeneration system and optimized the UDP-glucose (UDPG) synthetic pathway. The optimized strain produced up to 131.3 mg/L eriocitrin. After this, the chassis cells were applied to other flavonoids, with substrates such as (2 S )-naringenin, (2 S )-hesperetin, diosmetin, and (2 S )-eriodictyol, which resulted in the synthesis of 179.9 mg/L naringin, 276.6 mg/L hesperidin, 249.0 mg/L neohesperidin, 30.4 mg/L diosmin, and 100.7 mg/L neoeriocitrin. To the best of our knowledge, this is the first report on the biosynthesis of flavonoid-7- O -disaccharide.

Topics & Concepts

EriodictyolHesperidinFlavonoidNaringinChemistryNaringeninFlavonoid biosynthesisRhamnoseBiochemistryHesperetinDisaccharideBiosynthesisMetabolic engineeringFlavanoneGalactoseEnzymeChromatographyAntioxidantGene expressionPathologyAlternative medicineGeneTranscriptomeMedicinePlant Gene Expression AnalysisFungal Biology and ApplicationsPlant biochemistry and biosynthesis
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