生理和比较转录组分析揭示了油菜花青素更多突变体耐涝性的机制

IF 3.3 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Li-Na Ding, Rui Liu, Teng Li, Ming Li, Xiao-Yan Liu, Wei-Jie Wang, Yan-Kun Yu, Jun Cao, Xiao-Li Tan
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引用次数: 0

摘要

背景:油菜籽(芸苔属)是全球第二大油料作物。它被广泛用于食品、能源生产和化学工业,同时也是一种观赏植物。因此,它具有巨大的经济价值和发展潜力。水涝是限制植物生长和发育的重要非生物胁迫。然而,人们对油菜耐涝的分子机制知之甚少:本研究调查了油菜栽培品种 "中双 11 号"(ZS11)及其花青素更多突变体(am)对涝胁迫的生理变化和发芽期油菜籽的转录组。与 ZS11 相比,该突变体表现出更强的耐涝性,在水涝 12 天后,水涝胁迫显著增加了突变体的花青素、可溶性糖和丙二醛含量,降低了叶绿素含量。RNA-seq分析发现,ZS11和am分别有1370和2336个不同表达基因(DEGs)对涝胁迫做出响应。富集分析表明,ZS11 的 DEGs 主要参与碳水化合物代谢,而 am 突变体的 DEGs 则特别富集于植物激素信号转导和对内源刺激的响应。共有 299 个 DEGs 被鉴定为与花青素生物合成相关的结构基因(24 个)和编码转录因子的调控基因(275 个),这可能是 am 突变体中花青素含量增加的原因。植物激素信号转导途径中共有 110 个基因被鉴定为 DEGs,其中有 70 个基因参与辅助素和乙烯信号转导,这些基因在突变体中发生了显著变化。此外,实时定量 PCR 验证了 16 个 DEGs 的表达水平与转录组图谱一致,这些 DEGs 可能在花青素积累和生物/非生物胁迫响应中发挥作用:本研究为油菜应对涝胁迫时花青素含量增加的分子机制提供了新的见解,这将有助于减少涝胁迫造成的损害,并进一步培育具有高耐涝性的油菜新品种。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Physiological and comparative transcriptome analyses reveal the mechanisms underlying waterlogging tolerance in a rapeseed anthocyanin-more mutant.

Background: Rapeseed (Brassica napus) is the second largest oil crop worldwide. It is widely used in food, energy production and the chemical industry, as well as being an ornamental. Consequently, it has a large economic value and developmental potential. Waterlogging is an important abiotic stress that restricts plant growth and development. However, little is known about the molecular mechanisms underlying waterlogging tolerance in B. napus.

Results: In the present study, the physiological changes and transcriptomes of germination-stage rapeseed in response to waterlogging stress were investigated in the B. napus cultivar 'Zhongshuang 11' (ZS11) and its anthocyanin-more (am) mutant, which was identified in our previous study. The mutant showed stronger waterlogging tolerance compared with ZS11, and waterlogging stress significantly increased anthocyanin, soluble sugar and malondialdehyde contents and decreased chlorophyll contents in the mutant after 12 days of waterlogging. An RNA-seq analysis identified 1370 and 2336 differently expressed genes (DEGs) responding to waterlogging stress in ZS11 and am, respectively. An enrichment analysis revealed that the DEGs in ZS11 were predominately involved in carbohydrate metabolism, whereas those in the am mutant were particularly enriched in plant hormone signal transduction and response to endogenous stimulation. In total, 299 DEGs were identified as anthocyanin biosynthesis-related structural genes (24) and regulatory genes encoding transcription factors (275), which may explain the increased anthocyanin content in the am mutant. A total of 110 genes clustered in the plant hormone signal transduction pathway were also identified as DEGs, including 70 involved in auxin and ethylene signal transduction that were significantly changed in the mutant. Furthermore, the expression levels of 16 DEGs with putative roles in anthocyanin accumulation and biotic/abiotic stress responses were validated by quantitative real-time PCR as being consistent with the transcriptome profiles.

Conclusion: This study provides new insights into the molecular mechanisms of increased anthocyanin contents in rapeseed in response to waterlogging stress, which should be useful for reducing the damage caused by waterlogging stress and for further breeding new rapeseed varieties with high waterlogging tolerance.

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