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蚜虫报警信息素 (E)-β-farnesene及其类似物的生物活性和作用机制研究进展

秦耀果 杨朝凯 凌云 陈巨莲 段红霞 杨新玲

秦耀果, 杨朝凯, 凌云, 陈巨莲, 段红霞, 杨新玲. 蚜虫报警信息素 (E)-β-farnesene及其类似物的生物活性和作用机制研究进展[J]. 农药学学报, 2019, 21(5-6): 643-659. doi: 10.16801/j.issn.1008-7303.2019.0101
引用本文: 秦耀果, 杨朝凯, 凌云, 陈巨莲, 段红霞, 杨新玲. 蚜虫报警信息素 (E)-β-farnesene及其类似物的生物活性和作用机制研究进展[J]. 农药学学报, 2019, 21(5-6): 643-659. doi: 10.16801/j.issn.1008-7303.2019.0101
QIN Yaoguo, YANG Zhaokai, LING Yun, CHEN Julian, DUAN Hongxia, YANG Xinling. Research progress on bioactivities and mechanism of aphid alarm pheromone (E)-β-farnesene and its analogues[J]. Chinese Journal of Pesticide Science, 2019, 21(5-6): 643-659. doi: 10.16801/j.issn.1008-7303.2019.0101
Citation: QIN Yaoguo, YANG Zhaokai, LING Yun, CHEN Julian, DUAN Hongxia, YANG Xinling. Research progress on bioactivities and mechanism of aphid alarm pheromone (E)-β-farnesene and its analogues[J]. Chinese Journal of Pesticide Science, 2019, 21(5-6): 643-659. doi: 10.16801/j.issn.1008-7303.2019.0101

蚜虫报警信息素 (E)-β-farnesene及其类似物的生物活性和作用机制研究进展

doi: 10.16801/j.issn.1008-7303.2019.0101
基金项目: 国家重点研发计划 (2017YFD0200504,2017YFD0201701);国家自然科学基金 (31371946,31871966,31772207,31071717);中国博士后科学基金项目 (2018M631646)
详细信息
    作者简介:

    秦耀果,女,博士后,主要研究方向为昆虫信息素合成及作用机制,E-mail:qinyg1018@163.com

    通讯作者:

    杨新玲,通信作者 (Author for correspondence),女,博士,教授,主要研究方向为新农药分子创制与合成,E-mail:yangxl@cau.edu.cn

  • 中图分类号: S482.3

Research progress on bioactivities and mechanism of aphid alarm pheromone (E)-β-farnesene and its analogues

  • 摘要: 蚜虫报警信息素 [(E)-β-farnesene,简称EBF] 是蚜虫腹管分泌的一种物质,它能对同种其他个体产生报警反应,使其迅速逃离危险现场。作为天然蚜虫信息素,EBF通过蚜虫嗅觉系统的气味结合蛋白OBPs和嗅觉受体ORs发挥作用,具有驱避、杀蚜、增效等多种生物活性,可用于蚜虫的行为调控,但由于其结构中存在的共轭双键而导致其稳定性差,从而限制了其实际应用。本文在简介蚜虫报警信息素EBF的基础上,系统介绍了EBF的结构修饰和改造进展,并对EBF及其类似物的生物活性和作用机制进行了综述,最后对EBF及其类似物的应用前景进行了展望,期望为开发具有实用价值的生态友好型蚜虫控制剂提供参考。
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    图  1  蚜虫信息素被OBPs运输及可能的传递给嗅觉受体信号途径(摘自Zhou等[79],2010)

    Figure  1.  Aphid pheromone transport by OBPs and possible signal transduction pathways to the olfactory receptor complex (Quoted from Zhou et al[79], 2010)

    图  2  豌豆蚜嗅觉受体的结构 (摘自Smadja等[85],2009)

    Figure  2.  Structure of pea aphid olfactory receptor (Quoted from Smadja et al[85], 2009)

    图  3  豌豆蚜ApisOBP3的分子模型 (摘自Sun等[33j],2011)

    Figure  3.  Model of A. pisum OBP3 (Quoted from Sun et al[33j], 2011)

    图  4  EBF共轭双键与RpadOBP3的3个关键氨基酸间的相互作用 (摘自Fan等[93],2017)

    Figure  4.  The interaction between the conjugated double bond of EBF and three key residues of RpadOBP3 (Quoted from Fan et al[93], 2017)

    图  5  巢菜修尾蚜OBP3 (A) 和莴苣蚜OBP3晶体结构 (B) (摘自Northey等[95],2016)

    Figure  5.  The OBP3 crystal structures of Megoura viciae (A) and Nasonovia ribisnigri (B) (Quoted from Northey et al[95], 2016)

    图  6  豌豆蚜ORs与小分子的相互作用 (摘自Zhang等[94],2017)

    Figure  6.  The interaction between A. pisum ORs and small molecular (Quoted from Zhang et al[94], 2017)

    表  1  豌豆蚜基因组的气味结合蛋白[80]

    Table  1.   Odorant-binding proteins annotated in the Acyrthosiphon pisum genome[80]

    基因名称
    Name of gene
    EST 冗余
    EST redundancy
    信号肽
    Signal peptide
    氨基酸
    Amino acids
    基因编号
    Gene ID*
    ApisOBP1 112 1–21 aa 159 aa ACYPIG336037
    ApisOBP2 29 1–19 aa 243 aa ACYPIG179180
    ApisOBP3 52 1–23 aa 141 aa ACYPIG117886
    ApisOBP4 22 1–22 aa 193 aa ACYPIG478320
    ApisOBP5 21 1–25 aa 221 aa ACYPIG747500
    ApisOBP6 3 1–19 aa 215 aa ACYPIG250873
    ApisOBP7 7 1–30 aa 155 aa ACYPIG658982
    ApisOBP8 2 1–18 aa 162 aa ACYPIG938564
    ApisOBP9 3 1–24 aa 165 aa ACYPIG781430
    ApisOBP10 ND 1–24 aa 143 aa ACYPIG102270
    ApisOBP11 ND 1–23 aa 112 aa ACYPIG252504
    ApisOBP12-CN ND No SP 112 aa ACYPIG244867
    ApisOBP13-NT NA No SP 82 aa ACYPIG620194
    ApisOBP14-CN NA NA 26 aa ACYPIG570521
    ApisOBP15-NT NA No SP 23 aa ACYPIG803752
    注:*蚜虫基因鉴定。CN:C端和N端都缺失;CT:C端缺失;NA:未申请;ND:未检测;NT:N端缺失;SP:信号肽。Note:*aphid gene identity. CN: both C- and N-terminus missing; CT: C-terminus missing; NA: not applied; ND: not detected; NT: N-terminus missing; SP: signal peptide.
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