Department of Chemistry, Kwame Nkrumah University of Science and Technology, Kumasi, Ghana.
Biointeractions and Crop Protection Department, Rothamsted Research, Harpenden, AL5 2JQ, UK.
J Chem Ecol. 2020 Mar;46(3):288-298. doi: 10.1007/s10886-020-01149-7. Epub 2020 Jan 17.
Cowpea, Vigna unguiculata L. Walp. (Fabaceae), is one of the most important food legumes grown on the African continent, as it provides an affordable source of dietary protein. Yields of cowpea are significantly reduced through damage by legume pod-borer, Maruca vitrata (Lepidoptera: Crambidae), caterpillars to flowers, tender leaves and pods. Semiochemical-based strategies are considered as environmentally benign and affordable for pest management, particularly on smallholder farms. In this study, we investigated the importance of cowpea flower volatiles as host location cues for egg-laying M. vitrata, and herbivore-induced plant volatiles (HIPVs) as M. vitrata repellents and natural enemy (Apanteles taragamae and Phanerotoma syleptae parasitoid) attractants. In oviposition choice assays, M. vitrata laid more eggs on flowering cowpea plants than non-flowering plants. Coupled gas chromatography-electrophysiology (GC-EAG) analysis using the antennae of female M. vitrata and an extract of flower volatiles collected by dynamic headspace collection revealed the presence of five EAG-active components that were identified by coupled GC-mass spectrometry (GC-MS) analysis as benzaldehyde, benzyl alcohol, acetophenone, a vinylbenzaldehyde isomer and (E)-cinnamaldehyde. A synthetic blend of the identified compounds, prepared using 3-vinylbenzaldehyde, induced M. vitrata to lay as many eggs on non-flowering cowpea as on flowering plants. The moths also preferred laying eggs on intact plants compared to M. vitrata-infested plants. As the emission of EAG-active floral compounds was determined to be lower in the headspace of infested cowpea flowers, the role of HIPVs emitted by M. vitrata-damaged leaves was also investigated. Of the compounds induced by larval damage, (E)-DMNT, indole, n-hexyl acetate, 1-octen-3-ol and linalool were shown by GC-EAG to possess electrophysiological activity. A synthetic blend of the EAG-active compounds, using racemic 1-octen-3-ol and linalool, significantly reduced egg numbers on flowering cowpea. Larval and egg parasitoids, i.e. A. taragamae and Ph. syleptae, respectively, of M. vitrata both preferred the Y-tube olfactometer arm treated with synthetic (E)-DMNT, whereas preference for racemic linalool and (E)-nerolidol was dose-dependent in A. taragamae. Our results provide the platform for the development of future semiochemical-based pest management strategies against M. vitrata on smallholder farms in West Africa.
豇豆,Vigna unguiculata L. Walp.(豆科),是非洲大陆上最重要的食用豆类之一,因为它提供了一种负担得起的膳食蛋白质来源。豇豆花叶甲(鳞翅目:螟蛾科)幼虫对花朵、嫩叶和豆荚的破坏,导致豇豆的产量显著下降。基于半化学物质的策略被认为是对害虫管理具有环境友好性和可负担性的,特别是在小农户农场。在这项研究中,我们研究了豇豆花挥发物作为卵产卵的 Maruca vitrata 的寄主定位线索的重要性,以及植物诱导挥发物(HIPVs)作为豇豆花叶甲的驱避剂和天然天敌(Apanteles taragamae 和 Phanerotoma syleptae 寄生蜂)引诱剂的重要性。在产卵选择试验中,豇豆花叶甲在开花豇豆植株上产卵多于非开花植株。使用雌性豇豆花叶甲的触角进行耦合气相色谱-电生理学(GC-EAG)分析,并通过动态顶空收集提取花挥发物,发现了五种 EAG 活性成分,通过耦合气相色谱-质谱(GC-MS)分析鉴定为苯甲醛、苯甲醇、苯乙酮、一种乙烯基苯甲醛异构体和(E)-肉桂醛。使用 3-乙烯基苯甲醛制备的鉴定化合物的合成混合物,诱导豇豆花叶甲在非开花豇豆上产卵与在开花植物上产卵一样多。与受豇豆花叶甲侵害的植物相比,飞蛾也更喜欢在完整的植物上产卵。由于在受感染的豇豆花的顶空确定 EAG 活性花香化合物的排放较低,因此还研究了由豇豆花叶甲受损叶片释放的 HIPVs 的作用。在幼虫损伤诱导的化合物中,(E)-DMNT、吲哚、乙酸己酯、1-辛烯-3-醇和芳樟醇通过 GC-EAG 显示出电生理活性。使用外消旋 1-辛烯-3-醇和芳樟醇的 EAG 活性化合物的合成混合物,显著减少了开花豇豆上的卵数。豇豆花叶甲的幼虫和卵寄生蜂,即 A. taragamae 和 Ph. syleptae,分别更喜欢用合成(E)-DMNT 处理的 Y 型嗅觉计臂,而 A. taragamae 对外消旋芳樟醇和(E)-橙花叔醇的偏好则取决于剂量。我们的研究结果为未来在西非小农户农场针对豇豆花叶甲的基于半化学物质的害虫管理策略的发展提供了平台。
