生物技术通报 ›› 2022, Vol. 38 ›› Issue (12): 27-34.doi: 10.13560/j.cnki.biotech.bull.1985.2022-0256
收稿日期:
2022-02-28
出版日期:
2022-12-26
发布日期:
2022-12-29
作者简介:
季洁韵,女,硕士,研究方向:植物的逆境生理和分子机制;E-mail:基金资助:
JI Jie-yun1(), LI Qiang2, ZENG You-ling1()
Received:
2022-02-28
Published:
2022-12-26
Online:
2022-12-29
摘要:
microRNA(miRNA)是一类非编码小RNA,通过剪切mRNA或抑制翻译调控与其互补的靶基因。近年来,已发现miRNA及其靶基因组成的调控模块广泛且深度地参与植物的生理生化过程。植物miR169及主要靶基因Nuclear Factor Y-As(NFYAs)家族会通过脱落酸介导的激素信号通路参与植物抵御非生物胁迫过程。本文阐述了miR169/NFYA模块在植物非生物胁迫及生长发育中的作用机制,为抗性分子育种提供参考。
季洁韵, 李强, 曾幼玲. miR169/NFYA模块响应植物非生物胁迫的研究进展[J]. 生物技术通报, 2022, 38(12): 27-34.
JI Jie-yun, LI Qiang, ZENG You-ling. Research Progress in miR169/NFYA Module Responding to Abiotic Stress in Plants[J]. Biotechnology Bulletin, 2022, 38(12): 27-34.
物种 Species | miRNA | miRNA功能 miRNA function | 靶基因 Target gene | 靶基因功能 Target gene function | 调控方式 Control method | 参考文献 Reference |
---|---|---|---|---|---|---|
拟南芥A. thaliana | AtmiR169a | 耐旱性↓ | AtNFYA5 | 耐旱性↑ | 剪切mRNA | [ |
拟南芥A. thaliana | AtmiR169i/l | 耐旱性↑ | AtNFYA5 | 耐旱性↑ | 增加蛋白丰度 | [ |
大豆G. max | GmmiR169c | 耐旱性↓ | GmNFYA3 | 耐旱性↑ | 剪切mRNA | [14,19] |
油菜B. napus | BnmiR169n | 耐旱性↓ | BnNFYA8 | 耐旱性↑ | 剪切mRNA | [ |
番茄S. lycopersicum | SlmiR169c | 耐旱性↑ | SlNFYA1/2/3、SlMRP1 | / | 剪切mRNA | [ |
杨树P. trichocarpa | PtmiR169o | 耐旱性↑ | PtNFYA6 | 耐旱性↓ | 剪切mRNA | [ |
玉米Z. mays | ZmmiR169q | 耐盐性↓ | ZmNFYA8 | 耐盐性↑ | 剪切mRNA | [ |
表1 miR169/NFYA模块参与植物的盐、旱胁迫
Table 1 miR169/NFYA module involved in plant salt and drought stress
物种 Species | miRNA | miRNA功能 miRNA function | 靶基因 Target gene | 靶基因功能 Target gene function | 调控方式 Control method | 参考文献 Reference |
---|---|---|---|---|---|---|
拟南芥A. thaliana | AtmiR169a | 耐旱性↓ | AtNFYA5 | 耐旱性↑ | 剪切mRNA | [ |
拟南芥A. thaliana | AtmiR169i/l | 耐旱性↑ | AtNFYA5 | 耐旱性↑ | 增加蛋白丰度 | [ |
大豆G. max | GmmiR169c | 耐旱性↓ | GmNFYA3 | 耐旱性↑ | 剪切mRNA | [14,19] |
油菜B. napus | BnmiR169n | 耐旱性↓ | BnNFYA8 | 耐旱性↑ | 剪切mRNA | [ |
番茄S. lycopersicum | SlmiR169c | 耐旱性↑ | SlNFYA1/2/3、SlMRP1 | / | 剪切mRNA | [ |
杨树P. trichocarpa | PtmiR169o | 耐旱性↑ | PtNFYA6 | 耐旱性↓ | 剪切mRNA | [ |
玉米Z. mays | ZmmiR169q | 耐盐性↓ | ZmNFYA8 | 耐盐性↑ | 剪切mRNA | [ |
物种Species | 基因Gene | 功能Function | 参考文献 Reference |
---|---|---|---|
大豆G. max | GmNFYA5 | ABA依赖途径增强植物耐旱性 | [ |
大豆G. max | GmNFYA13 | ABA依赖途径增强植物耐盐抗旱性 | [ |
杨树P. trichocarpa | PtNFYA9 | 放大ABA合成与信号通路,提高植物幼苗期对盐、旱的敏感性,成苗期对盐、旱的耐受性 | [ |
水稻O. sativa | OsNFYA7 | 非ABA依赖途径增强植物耐旱性 | [ |
柑橘C. sinensis | CsNFYAs | 增强植物苗期耐旱性 | [ |
大豆G. max | GmNFYA | 增强组蛋白的乙酰化来提高植物的耐盐性 | [ |
拟南芥A. thaliana | AtNFYA1 | 增强ABA的信号通路,提高植物幼苗期对盐的敏感性,成苗期对盐的耐受性 | [ |
小麦T. aestivum | TaNFYA10 | 增强植物的盐敏感性、旱耐性 | [ |
棉花G. hirsutum | GhNFYA10/23 | 增强植物的耐盐性 | [ |
谷子S. italica | SiNFYA1 | 增强植物的抗盐耐旱性 | [ |
表2 NFYA转录因子在盐、旱胁迫中发挥作用
Table 2 NFYA transcription factors playing a role in salt and drought stress
物种Species | 基因Gene | 功能Function | 参考文献 Reference |
---|---|---|---|
大豆G. max | GmNFYA5 | ABA依赖途径增强植物耐旱性 | [ |
大豆G. max | GmNFYA13 | ABA依赖途径增强植物耐盐抗旱性 | [ |
杨树P. trichocarpa | PtNFYA9 | 放大ABA合成与信号通路,提高植物幼苗期对盐、旱的敏感性,成苗期对盐、旱的耐受性 | [ |
水稻O. sativa | OsNFYA7 | 非ABA依赖途径增强植物耐旱性 | [ |
柑橘C. sinensis | CsNFYAs | 增强植物苗期耐旱性 | [ |
大豆G. max | GmNFYA | 增强组蛋白的乙酰化来提高植物的耐盐性 | [ |
拟南芥A. thaliana | AtNFYA1 | 增强ABA的信号通路,提高植物幼苗期对盐的敏感性,成苗期对盐的耐受性 | [ |
小麦T. aestivum | TaNFYA10 | 增强植物的盐敏感性、旱耐性 | [ |
棉花G. hirsutum | GhNFYA10/23 | 增强植物的耐盐性 | [ |
谷子S. italica | SiNFYA1 | 增强植物的抗盐耐旱性 | [ |
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