Conchou Lucie, Lucas Philippe, Meslin Camille, Proffit Magali, Staudt Michael, Renou Michel
INRA, Sorbonne Université, INRA, CNRS, UPEC, IRD, University P7, Institute of Ecology and Environmental Sciences of Paris, Paris, France.
CEFE, CNRS, EPHE, IRD, Université de Montpellier, Université Paul-Valéry Montpellier, Montpellier, France.
Front Physiol. 2019 Aug 2;10:972. doi: 10.3389/fphys.2019.00972. eCollection 2019.
Olfaction is an essential sensory modality for insects and their olfactory environment is mostly made up of plant-emitted volatiles. The terrestrial vegetation produces an amazing diversity of volatile compounds, which are then transported, mixed, and degraded in the atmosphere. Each insect species expresses a set of olfactory receptors that bind part of the volatile compounds present in its habitat. Insect odorscapes are thus defined as species-specific olfactory spaces, dependent on the local habitat, and dynamic in time. Manipulations of pest-insect odorscapes are a promising approach to answer the strong demand for pesticide-free plant-protection strategies. Moreover, understanding their olfactory environment becomes a major concern in the context of global change and environmental stresses to insect populations. A considerable amount of information is available on the identity of volatiles mediating biotic interactions that involve insects. However, in the large body of research devoted to understanding how insects use olfaction to locate resources, an integrative vision of the olfactory environment has rarely been reached. This article aims to better apprehend the nature of the insect odorscape and its importance to insect behavioral ecology by reviewing the literature specific to different disciplines from plant ecophysiology to insect neuroethology. First, we discuss the determinants of odorscape composition, from the production of volatiles by plants (section "Plant Metabolism and Volatile Emissions") to their filtering during detection by the olfactory system of insects (section "Insect Olfaction: How Volatile Plant Compounds Are Encoded and Integrated by the Olfactory System"). We then summarize the physical and chemical processes by which volatile chemicals distribute in space (section "Transportation of Volatile Plant Compounds and Spatial Aspects of the Odorscape") and time (section "Temporal Aspects: The Dynamics of the Odorscape") in the atmosphere. The following sections consider the ecological importance of background odors in odorscapes and how insects adapt to their olfactory environment. Habitat provides an odor background and a sensory context that modulate the responses of insects to pheromones and other olfactory signals (section "Ecological Importance of Odorscapes"). In addition, insects do not respond inflexibly to single elements in their odorscape but integrate several components of their environment (section "Plasticity and Adaptation to Complex and Variable Odorscapes"). We finally discuss existing methods of odorscape manipulation for sustainable pest insect control and potential future developments in the context of agroecology (section "Odorscapes in Plant Protection and Agroecology").
嗅觉对于昆虫来说是一种至关重要的感觉方式,它们的嗅觉环境主要由植物释放的挥发性物质组成。陆地植被产生了种类惊人的挥发性化合物,这些化合物随后在大气中进行传输、混合和降解。每种昆虫物种都表达一组嗅觉受体,这些受体能够结合其栖息地中存在的部分挥发性化合物。因此,昆虫气味景观被定义为特定物种的嗅觉空间,它依赖于当地栖息地,并且随时间动态变化。对害虫昆虫气味景观进行操控是满足对无农药植物保护策略强烈需求的一种有前景的方法。此外,在全球变化和昆虫种群面临环境压力的背景下,了解它们的嗅觉环境成为一个主要关注点。关于介导涉及昆虫的生物相互作用的挥发性物质的身份,已有大量信息。然而,在致力于理解昆虫如何利用嗅觉来定位资源的大量研究中,很少达成对嗅觉环境的综合认识。本文旨在通过回顾从植物生态生理学到昆虫神经行为学等不同学科的特定文献,更好地理解昆虫气味景观的本质及其对昆虫行为生态学的重要性。首先,我们讨论气味景观组成的决定因素,从植物产生挥发性物质(“植物代谢与挥发性物质排放”部分)到昆虫嗅觉系统在检测过程中对其进行筛选(“昆虫嗅觉:挥发性植物化合物如何被嗅觉系统编码和整合”部分)。然后,我们总结挥发性化学物质在大气中在空间(“挥发性植物化合物的传输与气味景观的空间方面”部分)和时间(“时间方面:气味景观的动态变化”部分)上分布的物理和化学过程。接下来的部分考虑气味景观中背景气味的生态重要性以及昆虫如何适应其嗅觉环境。栖息地提供了一种气味背景和一种感官背景,可调节昆虫对信息素和其他嗅觉信号的反应(“气味景观的生态重要性”部分)。此外,昆虫不会对其气味景观中的单个元素做出僵化反应,而是整合其环境中的多个成分(“对复杂多变气味景观的可塑性与适应性”部分)。我们最后讨论用于可持续害虫防治的现有气味景观操控方法以及农业生态学背景下潜在的未来发展(“植物保护与农业生态学中的气味景观”部分)。
