Thomas E Saunders, Lee-Anne M Manning, Gonzalo A Avila, Gregory I Holwell, Kye Chung Park
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Electrophysiological techniques such as electroantennography (EAG) and GC-EAD (gas chromatography coupled with electroantennographic detection) are widely used to identify bioactive semiochemicals. But the application of these techniques to understanding how chemical ecological cues mediate parasitoid host specificity has not been as thoroughly explored. We conducted GC-EAD and EAG studies to identify olfactory-active compounds associated with adult females of nine stink bug species from Aotearoa/New Zealand on the antennae of three closely related parasitoid species: Trissolcus japonicus Ashmead, a pre-emptively (= proactively) approved biocontrol agent against brown marmorated stink bug; T. basalis (Wollaston), a biocontrol agent introduced against Nezara viridula L. in 1949; and T. oenone Johnson, a native Australasian pentatomid parasitoid. Eight compounds associated with stink bugs elicited antennal responses from all three parasitoids, and we were able to identify seven of these. (E)-2-hexenal, (E)-4-oxo-2-hexenal, (E)-2-octenal and (E)-2-decenal generally elicited stronger responses in the three parasitoids, while n-tridecane, n-dodecane, and (E)-2-decenyl acetate elicited weaker responses. 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引用次数: 0
摘要
寄生生物控制剂主要依靠嗅觉来确定寄主的位置。众所周知,与寄主和非寄主相关的化学线索会影响寄主偏好和寄主特异性的表达。根据与潜在寄主相关的挥发性有机化合物,更好地了解寄生虫如何以及为何攻击某些物种而不攻击其他物种,可以提供寄生虫寄主偏好的关键信息,这些信息可用于经典生物防治剂的释放前风险评估。电生理学技术(如电休眠法(EAG)和气相色谱-电休眠检测法(GC-EAD))被广泛用于鉴定生物活性半化学物质。但是这些技术在了解化学生态线索如何介导寄生虫宿主特异性方面的应用还没有得到深入探讨。我们进行了 GC-EAD 和 EAG 研究,以鉴定与奥特亚罗瓦/新西兰的九种蝽类雌成虫有关的嗅觉活性化合物:T. basalis (Wollaston),一种于 1949 年引入的针对 Nezara viridula L. 的生物控制剂;以及 T. oenone Johnson,一种澳大拉西亚本地的五蝽类寄生虫。与蝽相关的八种化合物引起了所有三种寄生虫的触角反应,我们能够识别其中的七种。一般来说,(E)-2-己烯醛、(E)-4-氧代-2-己烯醛、(E)-2-辛烯醛和(E)-2-癸烯醛在三种寄生虫中引起的反应较强,而正十三烷、正十二烷和(E)-2-癸烯乙酸酯引起的反应较弱。我们将讨论如何以及为什么电生理学实验结果可以应用于生物控制计划中的非目标风险评估。
Electrophysiological Responses of Trissolcus japonicus, T. basalis, and T. oenone (Hymenoptera: Scelionidae) to Volatile Compounds Associated with New Zealand Stink Bugs (Hemiptera: Pentatomidae).
Parasitoid biological control agents rely heavily on olfaction to locate their hosts. Chemical cues associated with hosts and non-hosts are known to influence the expression of host preferences and host-specificity. A better understanding of how and why parasitoids attack some species and not others, based on volatile organic compounds associated with potential hosts, can provide key information on the parasitoid's host preferences, which could be applied to pre-release risk assessments for classical biological control agents. Electrophysiological techniques such as electroantennography (EAG) and GC-EAD (gas chromatography coupled with electroantennographic detection) are widely used to identify bioactive semiochemicals. But the application of these techniques to understanding how chemical ecological cues mediate parasitoid host specificity has not been as thoroughly explored. We conducted GC-EAD and EAG studies to identify olfactory-active compounds associated with adult females of nine stink bug species from Aotearoa/New Zealand on the antennae of three closely related parasitoid species: Trissolcus japonicus Ashmead, a pre-emptively (= proactively) approved biocontrol agent against brown marmorated stink bug; T. basalis (Wollaston), a biocontrol agent introduced against Nezara viridula L. in 1949; and T. oenone Johnson, a native Australasian pentatomid parasitoid. Eight compounds associated with stink bugs elicited antennal responses from all three parasitoids, and we were able to identify seven of these. (E)-2-hexenal, (E)-4-oxo-2-hexenal, (E)-2-octenal and (E)-2-decenal generally elicited stronger responses in the three parasitoids, while n-tridecane, n-dodecane, and (E)-2-decenyl acetate elicited weaker responses. We discuss how and why the results from electrophysiological experiments can be applied to non-target risk assessments within biological control programmes.
期刊介绍:
Journal of Chemical Ecology is devoted to promoting an ecological understanding of the origin, function, and significance of natural chemicals that mediate interactions within and between organisms. Such relationships, often adaptively important, comprise the oldest of communication systems in terrestrial and aquatic environments. With recent advances in methodology for elucidating structures of the chemical compounds involved, a strong interdisciplinary association has developed between chemists and biologists which should accelerate understanding of these interactions in nature.
Scientific contributions, including review articles, are welcome from either members or nonmembers of the International Society of Chemical Ecology. Manuscripts must be in English and may include original research in biological and/or chemical aspects of chemical ecology. They may include substantive observations of interactions in nature, the elucidation of the chemical compounds involved, the mechanisms of their production and reception, and the translation of such basic information into survey and control protocols. Sufficient biological and chemical detail should be given to substantiate conclusions and to permit results to be evaluated and reproduced.
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