植物中病原体感染的图像

M. Barón, M. Pineda, M. Pérez-Bueno
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引用次数: 44

摘要

几种成像技术为评估生物胁迫对寄主植物的影响提供了有价值的工具。利用这些技术,可以通过分析叶片代谢在发病过程中的时空异质性来研究植物与病原体的相互作用。本文综述了基于叶绿素荧光、多色荧光和热成像的成像技术在病毒、细菌和真菌感染植物研究中的应用。这些研究揭示了病原菌胁迫对光合性能、次生代谢和叶片蒸腾的影响,为田间和温室病害管理提供了一种有前景的工具。在叶绿素荧光诱导动力学过程中获得的标准叶绿素荧光(Chl-F)参数图像与光化学过程和能量耗散有关,可以作为监测发病机制的良好胁迫指标。用多色荧光成像技术检测到的紫外诱导的蓝色荧光(F440)和绿色荧光(F520)的变化似乎与植物次生代谢的上调以及参与植物防御的酚类化合物(如东莨菪碱、绿原酸或阿魏酸)的增加有关。热成像显示了发病过程中的叶片蒸腾图,强调了气孔在植物先天免疫中的关键作用。同时使用几种成像技术可以获得特定病原体的疾病特征。这些技术也被证明是非常有用的症状前病原体检测,以及精准农业的强大的非破坏性工具。它们在实验室规模、遥感领域和高通量植物表型分析方面的适用性使它们特别有用。热传感器被广泛应用于作物田间,用于检测空气传播和土壤传播病原体引起的叶片蒸腾的早期变化。在冠层水平上通过Chl-F测量光合作用的局限性正在得到解决,而由于所使用的光激发类型,使用多光谱荧光成像非常具有挑战性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Picturing pathogen infection in plants
Abstract Several imaging techniques have provided valuable tools to evaluate the impact of biotic stress on host plants. The use of these techniques enables the study of plant-pathogen interactions by analysing the spatial and temporal heterogeneity of foliar metabolism during pathogenesis. In this work we review the use of imaging techniques based on chlorophyll fluorescence, multicolour fluorescence and thermography for the study of virus, bacteria and fungi-infected plants. These studies have revealed the impact of pathogen challenge on photosynthetic performance, secondary metabolism, as well as leaf transpiration as a promising tool for field and greenhouse management of diseases. Images of standard chlorophyll fluorescence (Chl-F) parameters obtained during Chl-F induction kinetics related to photochemical processes and those involved in energy dissipation, could be good stress indicators to monitor pathogenesis. Changes on UV-induced blue (F440) and green fluorescence (F520) measured by multicolour fluorescence imaging in pathogen-challenged plants seem to be related with the up-regulation of the plant secondary metabolism and with an increase in phenolic compounds involved in plant defence, such as scopoletin, chlorogenic or ferulic acids. Thermal imaging visualizes the leaf transpiration map during pathogenesis and emphasizes the key role of stomata on innate plant immunity. Using several imaging techniques in parallel could allow obtaining disease signatures for a specific pathogen. These techniques have also turned out to be very useful for presymptomatic pathogen detection, and powerful non-destructive tools for precision agriculture. Their applicability at lab-scale, in the field by remote sensing, and in high-throughput plant phenotyping, makes them particularly useful. Thermal sensors are widely used in crop fields to detect early changes in leaf transpiration induced by both air-borne and soil-borne pathogens. The limitations of measuring photosynthesis by Chl-F at the canopy level are being solved, while the use of multispectral fluorescence imaging is very challenging due to the type of light excitation that is used.
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