Feature-Based Molecular Networking Analysis of the Metabolites Produced by In Vitro Solid-State Fermentation Reveals Pathways for the Bioconversion of Epigallocatechin Gallate.
Hao-Fen XieYa-Shuai KongRu-Ze LiLouis-Félix NothiasAlexey V MelnikHong ZhangLu-Lu LiuTing-Ting AnRui LiuZi YangJia-Ping KePeng ZhangGuan-Hu BaoZhong-Wen XieDa-Xiang LiXiao-Chun WanQian-Ying DaiLiang ZhangMing ZhaoMao-Qiang AnYan-Hua LongTie-Jun LingPublished in: Journal of agricultural and food chemistry (2020)
Dark teas are prepared by a microbial fermentation process. Flavan-3-ol B-ring fission analogues (FBRFAs) are some of the key bioactive constituents that characterize dark teas. The precursors and the synthetic mechanism involved in the formation of FBRFAs are not known. Using a unique solid-state fermentation system with β-cyclodextrin inclusion complexation as well as targeted chromatographic isolation, spectroscopic identification, and Feature-based Molecular Networking on the Global Natural Products Social Molecular Networking web platform, we reveal that dihydromyricetin and the FBRFAs, including teadenol A and fuzhuanin A, are derived from epigallocatechin gallate upon exposure to fungal strains isolated from Fuzhuan brick tea. In particular, the strains from subphylum Pezizomycotina were key drivers for these B-/C-ring oxidation transformations. These are the same transformations seen during the fermentation process of dark teas. These discoveries set the stage to enrich dark teas and other food products for these health-promoting constituents.
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