LncNAT11-GbMYB11-GbF3'H/GbFLS模块介导黄酮醇生物合成以调节银杏叶的耐盐胁迫性。

IF 5.6 2区 生物学 Q1 PLANT SCIENCES
Sian Liu, Hanyue Zhang, Zhaolong Meng, Zhichao Jia, Fangfang Fu, Biao Jin, Fuliang Cao, Li Wang
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引用次数: 0

摘要

黄酮醇是重要的次级代谢产物,可使植物抵抗环境胁迫。虽然 MYB 对黄酮醇生物合成的调控作用已得到深入研究,但参与调控黄酮醇生物合成的 lncRNA-MYB 网络仍不为人知。银杏叶富含黄酮醇,是最重要的药用成分。基于多组学数据和系统发生树,我们发现 GbMYB11 是调控黄酮醇生物合成的潜在关键转录因子。过表达和VIGS实验证实,GbMYB11是黄酮醇生物合成过程中的关键正调控因子。在过表达 GbMYB11 的胼胝体转录组中,我们发现黄酮醇生物合成途径中的 GbF3'H 和 GbFLS 显著上调。酵母单杂交和双荧光素酶试验表明,GbMYB11通过与GbF3'H和GbFLS的启动子结合,增强了它们的表达。有趣的是,我们发现了与 GbMYB11 互补的反义 lncRNA LncNAT11,它通过抑制 GbMYB11 的表达来负向调节黄酮醇的生物合成。因此,我们将LncNAT11-GbMYB11-GbF3'H/GbFLS模块确立为黄酮醇生物合成的关键调控因子,并进一步阐明了该模块可在盐胁迫期间通过调节黄酮醇的生物合成来缓解活性氧的积累。这些发现揭示了黄酮醇生物合成的新机制和lncRNA-MYB介导的植物耐盐胁迫策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
LncNAT11-GbMYB11-GbF3'H/GbFLS module mediates flavonol biosynthesis to regulate salt stress tolerance in Ginkgo biloba.

Flavonols are important secondary metabolites that enable plants to resist environmental stresses. Although MYB regulation of flavonol biosynthesis has been well studied, the lncRNA-MYB networks involved in regulating flavonol biosynthesis remain unknown. Ginkgo biloba is rich in flavonols, which are the most important medicinal components. Based on multi-omics data and phylogenetic trees, we identified GbMYB11 as a potential key transcription factor regulating flavonol biosynthesis. Overexpression and VIGS experiments confirmed that GbMYB11 acts as a pivotal positive regulator in flavonol biosynthesis. In the transcriptome of calli overexpressing GbMYB11, we identified significant upregulation of GbF3'H and GbFLS in the flavonol biosynthetic pathway. Yeast one-hybrid and dual-luciferase assays demonstrated that GbMYB11 enhances the expression of GbF3'H and GbFLS by binding to their promoters. Interestingly, we identified LncNAT11, an antisense lncRNA complement to GbMYB11, which negatively regulates flavonol biosynthesis by repressing the expression of GbMYB11. Consequently, we established the LncNAT11-GbMYB11-GbF3'H/GbFLS module as a critical regulator of flavonol biosynthesis in G. biloba, and further elucidated that this module can mitigate the accumulation of reactive oxygen species by modulating flavonol biosynthesis during salt stress. These findings unveil a novel mechanism underlying flavonol biosynthesis and a lncRNA-MYB mediated salt stress tolerance strategy in plants.

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来源期刊
Journal of Experimental Botany
Journal of Experimental Botany 生物-植物科学
CiteScore
12.30
自引率
4.30%
发文量
450
审稿时长
1.9 months
期刊介绍: The Journal of Experimental Botany publishes high-quality primary research and review papers in the plant sciences. These papers cover a range of disciplines from molecular and cellular physiology and biochemistry through whole plant physiology to community physiology. Full-length primary papers should contribute to our understanding of how plants develop and function, and should provide new insights into biological processes. The journal will not publish purely descriptive papers or papers that report a well-known process in a species in which the process has not been identified previously. Articles should be concise and generally limited to 10 printed pages.
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