生物
基因
类黄酮生物合成
类黄酮
转录因子
逆转录聚合酶链式反应
植物
萜类
曲霉
聚合酶链反应
真菌
亚科
遗传学
逆转录酶
性二态性
脱落酸
互补DNA
蒽醌类
代谢组学
抄写(语言学)
转录组
DNA测序
表型
基因表达
实时聚合酶链反应
系统发育学
显著性差异
微生物学
DNA
作者
Xiaori Zhan,Zhengwu Fang,Lingxiao Zhang,Huijie Ma,Xiuli Ma,Yan Jiang,Chenjia Shen
摘要
Dioecious plants often exhibit dimorphism in morphology, physiology, and environmental adaptation. As a dioecious gymnosperm, Taxus is well known for its ornamental and ecological value. However, the sexual dimorphism in the responses of Taxus mairei to fungal infection remains unclear. In the present study, we investigated the effect of sex on the responses of T. mairei to S01, a fungus belonging to the Aspergillus genus, using untargeted metabolomic analysis. Although there is no significant difference in the contents of eight analyzed flavonoid monomers between female and male T. mairei plants under normal condition, a significant difference emerges under fungal infection. We identified 15 members of the abscisic acid insensitive3/viviparous1 (RAV)-like gene subfamily in the T. mairei genome. Subsequently, a RAV-like transcription factor (TF) gene, RAV-like 9, which is responsive to S01 infection, was identified to be involved in flavonoid metabolism based on Pearson's correlation analysis. To identify the genome-wide binding sites of RAV-like 9, DNA affinity purification sequencing (DAP-seq) was performed, yielding 3993 overlapping peaks. Motif enrichment analysis identified several de novo motifs, providing new insights into RAV TF recognition sites. After searching the peak pool, two flavonoid biosynthesis-related target genes were detected: ANS (ctg19199_gene.2) and IRL1 (ctg9900_gene.5). Quantitative reverse transcription polymerase chain reaction analysis confirmed the differential expression of ANS and IRL1 between female and male T. mairei under S01 infection. Our data suggest that RAV-like 9 may play an important regulatory role in sex-specific responses of flavonoid biosynthesis to fungal infection by targeting the ANS and IRL1 genes.
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