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Functional analysis of the dihydroflavonol 4-reductase family of <i>Camellia sinensis</i>: exploiting key amino acids to reconstruct reduction activity

Haixiang Ruan, Xingxing Shi, Liping Gao, Arif Rashid, Yan Li, Ting Lei, Xinlong Dai, Tao Xia, Yunsheng Wang

2022Horticulture Research43 citationsDOIOpen Access PDF

Abstract

Abstract Anthocyanins and proanthocyanidins (PAs) are important types of flavonoids, plant secondary metabolites with a wide range of industrial and pharmaceutical applications. DFR (dihydroflavonol 4-reductase) is a pivotal enzyme that plays an important role in the flavonoid pathway. Here, four CsDFR genes were isolated from Camellia sinensis, and their overexpression was analyzed in vitro and in vivo. Based on transcription and metabolic analyses, CsDFR expression was closely consistent with catechins and PAs accumulation. Moreover, enzyme activity analyses revealed that the two recombinant proteins CsDFRa and CsDFRc exhibited DFR activity, converting dihydroflavonols into leucoanthocyanins in vitro, but CsDFRb1 and CsDFRb3 did not. CsDFRa and CsDFRc overexpression in AtDFR mutants (tt3) revealed that CsDFRs are involved in the biosynthesis of anthocyanins and PAs, as CsDFRa and CsDFRc restored not only the purple petiole phenotype but also the seed coat color. Site-directed mutagenesis revealed that the two amino acid residues S117 and T123 of CsDFRa play a prominent role in controlling DFR reductase activity. Enzymatic assays indicated that CsDFRa and CsDFRc exhibited a higher affinity for DHQ and DHK, respectively, whereas CsDFRb1N120S and CsDFRb1C126T exhibited a higher affinity for DHM. Our findings comprehensively characterize the DFRs from C. sinensis and shed light on their critical role in metabolic engineering.

Topics & Concepts

BiologyCamellia sinensisBiochemistryAmino acidEnzymeReductaseFlavonoidBotanyAntioxidantPlant Gene Expression AnalysisTea Polyphenols and EffectsPhytochemicals and Antioxidant Activities
Functional analysis of the dihydroflavonol 4-reductase family of <i>Camellia sinensis</i>: exploiting key amino acids to reconstruct reduction activity | Litcius