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HD-ZIP转录因子响应病菌与非生物胁迫研究进展

刘娇 帅鹏

刘娇,帅鹏. HD-ZIP转录因子响应病菌与非生物胁迫研究进展 [J]. 福建农业学报,2021,36(1):124−134 doi: 10.19303/j.issn.1008-0384.2021.01.015
引用本文: 刘娇,帅鹏. HD-ZIP转录因子响应病菌与非生物胁迫研究进展 [J]. 福建农业学报,2021,36(1):124−134 doi: 10.19303/j.issn.1008-0384.2021.01.015
LIU J, SHUAI P. Research Progress on HD-ZIP Transcription Factors in Response to Pathogenic or Abiotic Stresses [J]. Fujian Journal of Agricultural Sciences,2021,36(1):124−134 doi: 10.19303/j.issn.1008-0384.2021.01.015
Citation: LIU J, SHUAI P. Research Progress on HD-ZIP Transcription Factors in Response to Pathogenic or Abiotic Stresses [J]. Fujian Journal of Agricultural Sciences,2021,36(1):124−134 doi: 10.19303/j.issn.1008-0384.2021.01.015

HD-ZIP转录因子响应病菌与非生物胁迫研究进展

doi: 10.19303/j.issn.1008-0384.2021.01.015
基金项目: 国家自然科学基金项目(31971626);国家自然基金青年科学基金项目(31600481)
详细信息
    作者简介:

    刘娇(1997−),女,硕士研究生,主要从事植物分子机制研究(E-mail: Lioujiao-161726084@qq.com

    通讯作者:

    帅鹏(1988−),男,硕士生导师,主要从事植物分子机制研究(E-mail: grooot@qq.com

  • 中图分类号: Q 945

Research Progress on HD-ZIP Transcription Factors in Response to Pathogenic or Abiotic Stresses

  • 摘要: 逆境条件通常影响植物生长发育,间接或直接导致作物减产甚至植物死亡。HD-ZIP转录因子则参与植物对不利环境条件的响应。Homeodomain-Leucine Zipper(HD-ZIP)转录因子是植物中特有的一类转录因子,属于同源异形盒(homeobox, HB)蛋白家族,由高度保守的同源异形结构域(Homeodomain)和亮氨酸拉链结构域(ZIP)紧密连接而成。通过LZ结构域介导的蛋白二聚体的形成使HD结构域与靶DNA结合,调控靶基因的表达。HD-ZIP转录因子不仅对植物生长发育发挥重要调控作用,并且对逆境抵抗中起关键作用。本文基于近年来HD-ZIP转录因子的最新研究成果,着重归纳HD-ZIP四个亚家族(Ⅰ-Ⅳ)对不同病菌和非生物胁迫例如干旱、高盐、极端温度、弱光、机械损伤、重金属胁迫做出的响应机制,以期揭示HD-ZIP转录因子如何通过整合激素和环境信号来改良植物生长特性的内在分子机制,从而为提升植物抗逆性奠定基础。
  • 图  1  HD-ZIP家族的分类结构示意图[15]

    Figure  1.  Schematic diagram of classified HD-ZIP family[15]

    图  2  HD-ZIP干旱胁迫调控通路

    Figure  2.  Regulatory route of HD-ZIP in response to drought stress

    图  3  HD-ZIP盐胁迫调控通路

    Figure  3.  Regulatory route of HD-ZIP in response to salt stress

    图  4  HD-ZIP避光反应调控通路

    注:R/FR光的变化导致R光吸收模式(Pr)和FR光吸收模式(Pfr)之间的平衡向Pr转移,从而导致植物色素PhyB、PhyD、PhyE失活。植物色素失活有利于避光反应正调节因子PIFs的转录。PIF进而激活HD-ZIP Ⅱ和HFR1/SICS1基因的转录。HFR1/SICS1则会抑制PIF和ATHB2、ATHB4的活性。然而PhyB、PhyD、PhyE以及HD-ZIP Ⅲ亚家族成员可激活ATHB2、ATHB4的转录活性从而正调控避光反应。

    Figure  4.  Regulatory route of HD-ZIP in response to shading

    Note: Changes in R/FR light cause equilibrium sift from FR light-absorbing photo-convertible isoform (Pfr) to R light-absorbing photo-convertible isoform (Pr) resulting in deactivations of phyB, phyD, and phyE. This, in turn, results in an enhanced stability and/or activity of several phytochrome-interacting transcription factors (PIFs). PIFs, within a brief moment, activate the transcription of HD-ZIPs II and HFR1/SICS1 genes. HFR1/SICS1 can inhibit activities of PIF, ATHB2, and ATHB4. But PhyB, PhyD, PhyE, and HD-ZIP Ⅲ subfamily members can activate the transcriptional activities of ATHB2 and ATHB4 to positively regulate the response to light-shielding.

    表  1  HD-ZIP在干旱胁迫下的不同表达模式

    Table  1.   Differential expressions of HD-ZIP transcription factors under drought stress

    植物物种
    Plant species
    HD-ZIP转
    录因子
    HD-ZIP TFs
    亚家族
    Subfamily
    表达模式
    Express patterns
    单子叶植物
    monocotyledon
    玉米 Zea mays L. ZmHDZ4 1 h时显著上调 up-regulated Significantly at 1 h
    Zmhdz10 上调,12时达到峰值 up-regulated,peaked at 12 h
    水稻 Oryza sativa L. OsHOX22 显著上调 up-regulated Significantly
    OsHOX24
    小麦 Triticum aestivum TaHDZipI-3 微弱上调 Slightly up-regulated
    TaHDZipI-4 较为显著上调 up-regulated
    TaHDZipI-5 显著上调 up-regulated Significantly
    双子叶植物
    Dicotyledon
    拟南芥 Arabidopsis thaliana AtHB13 上调,8天时达到5倍峰值 up-regulated,fivefold after 8 days
    AtHB7AtHB12 显著上调 up-regulated Significantly
    HDG11 上调 up-regulated
    向日葵 Helianthus annuus L. HaHB4 上调 up-regulated
    鹰嘴豆 Cicer arietinum CaHDZ12 根中48 h上调显著 up-regulated Significantly in roots after 48 h
    番茄 Solanum lycopersicum SIHB2 2 h后持续上调,保持高水平 Continue to up-regulatedand keep a high level after 2 h
    下载: 导出CSV

    表  2  HD-ZIP转录因子在盐胁迫下不同表达模式

    Table  2.   Differential expressions of HD-ZIP transcription factors under salt stress

    项目
    Items
    植物物种
    Plant species
    HD-ZIP
    TFs
    亚家族
    Subfamily
    表达模式
    Express patterns
    单子叶植物 monocotyledon 玉米 Zea mays L. ZmHDZ10 上调,12 h达到峰值 up-regulated,peaked at 12 h
    ZmHDZ1 1 h时显著上调 up-regulated Significantly at 1 h
    双子叶植物 Dicotyledon 拟南芥 Arabidopsis thaliana ATHB17 在叶中显著诱导 Induced Significantly in leaves
    HDG11 上调 up-regulated
    毛果杨 Populus trichocarpa PtrHox11 上调 up-regulated
    大豆 Glycine max Gshdz4 在根中显著上调 up-regulated Significantly in roots
    鹰嘴豆 Cicerarietinum CaHDZ12 在72 h、96 h显著上调 up-regulated Significantly at 72 h,96 h
    番茄 Solanum lycopersicum SIHB2 在2 h时显著上调 up-regulated Significantly at 2 h
    麻风树 Jatropha curcas L. JcHDZ16 所有时间点均被下调 Down-regulated at all pont
    下载: 导出CSV

    表  3  HD-ZIP转录因子在高温与低温胁迫中的不同表达模式

    Table  3.   Differential expressions of HD-ZIP transcription factors under high- and low-temp stresses

    植物物种
    Plant species
    HD-ZIP转
    录因子
    HD-ZIP TFs
    亚家族
    Subfamily
    温度胁迫
    Temperature stress
    表达模式
    Expression Patterns
    黄瓜 Cucumis sativus L. CsHDZ02,33 高温低温 显著上调 up-regulated Significantly
    CsHDZ08,22
    CsHDZ11,37
    土豆 Solanum tuberosum L. StHOX20 在根与叶中显著上调 up-regulated Significantly in leaves and roots
    小麦 Triticum aestivum L. TaHDZipI-2TaHDZipI-3 低温 下调 down-regulated
    TaHDZipI-4TaHDZipI-5 上调 up-regulated
    番茄 Solanum lycopersicum SIHZ17 下调,且没有反弹 down-regulated without any rebound
    黑麦草 Lolium perenne L. LpHOX6,8,24 高温 在叶片和根中上调 up-regulated in leaves and roots
    LpHOX21 在根和叶片中下调 down-regulated in leaves and roots
    向日葵 Helianthus annuus L. HaHB4 上调 up-regulated
    下载: 导出CSV
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出版历程
  • 收稿日期:  2020-08-16
  • 修回日期:  2020-10-21
  • 网络出版日期:  2020-11-13
  • 刊出日期:  2021-01-31

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