温度变化和物候不匹配对昆虫种群的直接和间接影响。

Direct and indirect effects of altered temperature regimes and phenological mismatches on insect populations.

机构信息

Department of Biological Sciences, Smith College, Northampton, MA, United States.

Department of Biological Sciences, George Washington University, DC, 20052, United States.

出版信息

Curr Opin Insect Sci. 2021 Oct;47:67-74. doi: 10.1016/j.cois.2021.04.008. Epub 2021 May 11.

DOI:10.1016/j.cois.2021.04.008

PMID:33989831

Abstract

Climate change is transforming ecosystems by altering species ranges, the composition of communities, and trophic interactions. Here, we synthesize recent reviews and subsequent developments to provide an overview of insect ecological and evolutionary responses to altered temperature regimes. We discuss both direct responses to thermal stress and indirect responses arising from phenological mismatches, altered host quality, and changes in natural enemy activity. Altered temperature regimes can increase exposure to both cold and heat stress and result in phenological and morphological mismatches with adjacent trophic levels. Host plant quality varies in a heterogenous way in response to altered temperatures with both increases and decreases observed. Density-dependent effects, spatial heterogeneity, and rapid evolutionary change provide some resilience to these threats.

摘要

气候变化正在通过改变物种分布范围、群落组成和营养相互作用来改变生态系统。在这里，我们综合了最近的综述和后续的发展，提供了一个关于昆虫对改变温度模式的生态和进化反应的概述。我们讨论了直接对热应激的反应，以及由于物候不匹配、寄主质量改变和天敌活动变化而产生的间接反应。改变的温度模式可以增加对冷和热应激的暴露，并导致与相邻营养级的物候和形态不匹配。寄主植物的质量会随着温度的变化而以一种不均匀的方式发生变化，观察到既有增加也有减少。密度依赖效应、空间异质性和快速的进化变化为这些威胁提供了一定的恢复能力。

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温度变化和物候不匹配对昆虫种群的直接和间接影响。

Direct and indirect effects of altered temperature regimes and phenological mismatches on insect populations.

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