A tug-of-war to control plant emission of an airborne alarm signal.

Jie Hao, Junfei Ma, Hua Shi, Ying Wang
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Abstract

Aphids represent a major threat to crops. Hundreds of different viruses are aphid-borne. Upon aphid attack, plants release volatile organic compounds (VOCs) as airborne alarm signals to turn on the airborne defense (AD) of neighboring plants, thereby repelling aphids as well as reducing aphid fitness and virus transmission. This phenomenon provides a critical community-wide plant protection to fend off aphids, but the underlying molecular basis remains undetermined for a long time. In a recent article, Gong et al. established the NAC2-SAMT1 module as the core component regulating the emission of methyl-salicylate (MeSA), a major component of VOCs in aphid-attacked plants. Furthermore, they showed that SABP2 protein is critical for the perception of volatile MeSA signal by converting MeSA to Salicylic Acid (SA), which is the cue to elicit AD against aphids at the community level. Moreover, they showed that multiple viruses use a conserved glycine residue in the ATP-dependent helicase domain in viral proteins to shuttle NAC2 from the nucleus to the cytoplasm for degradation, leading to the attenuation of MeSA emission and AD. These findings illuminate the functional roles of key regulators in the complex MeSA-mediated airborne defense process and a counter-defense mechanism used by viruses, which has profound significance in advancing the knowledge of plant-pathogen interactions as well as providing potential targets for gene editing-based crop breeding.

一场控制工厂发射空中警报信号的拔河比赛。
蚜虫是对农作物的主要威胁。数百种不同的病毒是由蚜虫传播的。当蚜虫攻击植物时,植物释放挥发性有机化合物(VOCs)作为空中警报信号,启动邻近植物的空中防御(AD),从而击退蚜虫,减少蚜虫的适合度和病毒传播。这一现象为抵御蚜虫提供了重要的社区范围内的植物保护,但其潜在的分子基础长期以来仍未确定。在最近的一篇文章中,Gong等人建立了NAC2-SAMT1模块作为调节水杨酸甲酯(MeSA)排放的核心组件,MeSA是蚜虫侵害植物中挥发性有机化合物的主要成分。此外,他们发现SABP2蛋白对挥发性MeSA信号的感知至关重要,通过将MeSA转化为水杨酸(SA),这是在群落水平上引发针对蚜虫的AD的线索。此外,他们发现多种病毒利用病毒蛋白中atp依赖解旋酶结构域的一个保守甘氨酸残基将NAC2从细胞核运送到细胞质中进行降解,从而导致MeSA发射和AD的衰减。这些发现阐明了mesa介导的复杂空气传播防御过程中关键调控因子的功能作用和病毒的反防御机制,对推进植物与病原体相互作用的认识具有深远意义,并为基于基因编辑的作物育种提供了潜在靶点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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