Shan Yao, Yao Qiuyi, Jia Qisheng, Lu Jiping, Cai Xiaoming, Chen Zongmao, Bian Lei
Key Laboratory of Biology, Genetics, and Breeding of Special Economic Animals and Plants, Ministry of Agriculture and Rural Affairs, Tea Research Institute, Chinese Academy of Agricultural Science, 9 Meiling South Road, Xihu District, Hangzhou 310008, China.
State Key Laboratory for Ecological Pest Control of Fujian and Taiwan Crops, Institute of Applied Ecology, Fujian Agriculture and Forestry University, Fuzhou 350002, China.
Plants (Basel). 2025 Apr 7;14(7):1147. doi: 10.3390/plants14071147.
The physical properties of plants affect the transmission of plant-borne vibrational signals, which many herbivorous insects use for communication. Male calling signals (MCaSs, with sections S0, S1, and S2) and courtship signals (MCoSs, with sections S1 and S2) of Matsuda (Hemiptera: Cicadellidae), a major pest of tea plant, have a multicomponent structure. The same MCaS was repeatedly played back on different leaves of a tea branch, and parameters of the transmitted signal and female responses were measured on the leaf inhabited by females. We also measured the signal parameters and behaviors of on single leaves of different ages. The intensity of MCaSs from other leaves attenuated after they propagated to leaves on which females were located, which decreased the duration of MCaS-S2. Higher leaf thickness, leaf hardness, and leaf area were associated with an increased pulse repetition time () of MCaSs, number of pulses in MCaS-S2, and duration of MCaS-S2, respectively. MCoS-S1 had a higher dominant frequency () in leaves with a long main vein and high hardness, and the of MCoS-S2 was longer on thicker leaves. In the initial stage of courtship, the signal excitation of males was affected by leaf traits, especially the temporal parameters of MCaS-S2, which was the most significantly affected section after host transmission; it also had an important effect on the response delay of females. In the location stage, the signal excitation of males was not only affected by leaf traits but also interacted with the signal excitation of females. These results facilitate exploration of the interaction between leafhoppers and host plants during courtship communication and have implications for the breeding of -resistant varieties.
植物的物理特性会影响植物传播的振动信号的传递,许多植食性昆虫利用这些信号进行交流。茶小绿叶蝉(半翅目:叶蝉科)是茶树的主要害虫,其雄虫求偶信号(MCaSs,包括S0、S1和S2部分)和求偶信号(MCoSs,包括S1和S2部分)具有多组分结构。在茶树枝条的不同叶片上反复播放相同的MCaS,并在雌虫栖息的叶片上测量传输信号的参数和雌虫的反应。我们还测量了不同年龄单叶上的信号参数和行为。来自其他叶片的MCaSs强度在传播到雌虫所在叶片后会减弱,这缩短了MCaS-S2的持续时间。较高的叶片厚度、叶片硬度和叶面积分别与MCaSs的脉冲重复时间()增加、MCaS-S2中的脉冲数增加以及MCaS-S2的持续时间增加相关。在主脉长且硬度高的叶片中,MCoS-S1具有较高的主频(),在较厚的叶片上,MCoS-S2的持续时间更长。在求偶初期,雄虫的信号激发受叶片性状影响,尤其是MCaS-S2的时间参数,它是寄主传播后受影响最显著的部分;它对雌虫的反应延迟也有重要影响。在定位阶段,雄虫的信号激发不仅受叶片性状影响,还与雌虫的信号激发相互作用。这些结果有助于探索叶蝉与寄主植物在求偶交流过程中的相互作用,并对抗虫品种的培育具有启示意义。
