诱导性 BVOCs：如何让我们的模型出错？

Induced BVOCs: how to bug our models?

机构信息

Physical Geography and Ecosystem Analysis, Lund University, Lund, Sweden.

出版信息

Trends Plant Sci. 2010 Mar;15(3):118-25. doi: 10.1016/j.tplants.2009.12.004. Epub 2010 Jan 12.

DOI:10.1016/j.tplants.2009.12.004

PMID:20071208

Abstract

Climate-herbivory interactions have been largely debated vis-à-vis ecosystem carbon sequestration. However, invertebrate herbivores also modify emissions of plant biogenic volatile organic compounds (BVOCs). Over the shorter term, they do this by the induction of de novo synthesis of a plethora of compounds; but invertebrates also affect the relative proportions of constitutively BVOCs-emitting plants. Thus, invertebrate-BVOCs interactions have potentially important implications for air quality and climate. Insect outbreaks are expected to increase with warmer climate, but quantitative understanding of BVOCs-invertebrate ecology, climate connections and atmospheric feedback remain as yet elusive. Examination of these interactions requires a description of outbreaks in ecosystem models, combined with quantitative observations on leaf and ecosystem level. We review here recent advances and propose a strategy for inclusion of invertebrate-BVOCs relationships in terrestrial ecosystem models.

摘要

气候-食草动物相互作用在很大程度上是通过生态系统碳固存来讨论的。然而，无脊椎草食动物也会改变植物生源挥发性有机化合物（BVOC）的排放。从短期来看，它们通过诱导大量新合成化合物来实现这一点；但无脊椎动物也会影响组成性释放 BVOC 的植物的相对比例。因此，无脊椎动物-BVOC 相互作用对空气质量和气候可能具有重要意义。随着气候变暖，昆虫爆发预计会增加，但对 BVOC-无脊椎动物生态学、气候联系和大气反馈的定量理解仍然难以捉摸。这些相互作用的研究需要在生态系统模型中描述爆发情况，并结合叶片和生态系统水平的定量观测。在这里，我们回顾了最近的进展，并提出了一种将无脊椎动物-BVOC 关系纳入陆地生态系统模型的策略。

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诱导性 BVOCs：如何让我们的模型出错？

Induced BVOCs: how to bug our models?

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