WRKY蛋白质结构域
生物
山茶
转录组
苯丙素
代谢组学
基因
山奈酚
植物抗病性
植物
体外
代谢组
生物技术
儿茶素
遗传学
微分效应
类黄酮
生物化学
转录因子
抗真菌
山茶科
体外毒理学
作者
Meishan Fang,Feiyan Wang,Lijie Wang,R. Zhang,Huiyi Liao,Jingyi Huang,Changbin Wei,Y. e Liang Zhang
标识
DOI:10.1021/acs.jafc.5c12894
摘要
Tea gray blight caused by Pestalotiopsis theae threatens tea production. We investigated the differential responses in two cultivated ("JX", "YJ") and two wild tea resources ("R", "S") via metabolomics, transcriptomics, and in vitro analyses. Phenotypically, resistance ranked "JX" > "R" > "YJ" > "S", with "JX" and "R" showing stronger resistance. Metabolomically, a total of 1062 differentially accumulated metabolites (DAMs) responded to infection. Resistant materials were enriched with lipids, alkaloids, etc., while susceptible materials were enriched with flavonoids, amino acids, etc. Transcriptomically, 32,168 differentially expressed genes (DEGs) were identified. Resistant materials upregulated more genes involved in hormone signaling and phenylpropanoid biosynthesis, with WRKY TFs (CsWRKY75/65/30) as key regulators. "JX" accumulated higher levels of dihydromyricetin, myricetin, quercetin, and kaempferol than "YJ", which effectively inhibited P. theae. This study elucidates the molecular-metabolic regulatory mechanism underlying tea plant resistance to P. theae, providing a theoretical framework for resistance breeding and natural antifungal agents for green disease control.
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