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CABI Book Chapter

Climate change and insect pests.

Book cover for Climate change and insect pests.

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Chapter 3 (Page no: 38)

Adaptive responses of plants to insect herbivores under climate change.

Global climate change, including the rise of CO2 emissions and global warming, are predicted to alter the composition of communities through differential colonization abilities between sessile plants and their mobile insect herbivores along latitudinal and elevation gradients. In particular, under the scenario of increasing temperature, it is expected that insect abundance and diversity will increase at higher elevation and latitude. The outcome of novel interactions between previously non-overlapping plant and insect species will ultimately result from the ability of the plant to adjust its defence and tolerance strategy. However, plant responses to herbivory may also be directly impacted by the effect of CO2 and temperature on plant defensive hormonal pathways. Additionally, syndromes of plant defences and tolerance are driven by inherited functional traits, biotic and abiotic conditions and the geographical and historical contingencies affecting the community. Therefore, understanding evolutionary species responses to climate change and novel plant-herbivore interactions requires understanding of genetic variation, strength of phenotypic plasticity in response to herbivore attack and trait phylogenetic conservatism. We advocate the study along elevation gradients for predicting ecological and evolutionary outcomes of climate change on plant-herbivore interaction.

Other chapters from this book

Chapter: 1 (Page no: 1) Climate change and insect pest distribution range. Author(s): Battisti, A. Larsson, S.
Chapter: 2 (Page no: 16) Species distribution modelling in predicting response to climate change. Author(s): Hill, M. P. Thomson, L. J.
Chapter: 4 (Page no: 54) Boreal woody species resistance affected by climate change. Author(s): Julkunen-Tiitto, R. Nybakken, L. Randriamanana, T. Virjamo, V.
Chapter: 5 (Page no: 74) Effects of climate change on the interactions between insect pests and their natural enemies. Author(s): Kalinkat, G. Rall, B. C.
Chapter: 6 (Page no: 92) Physiological variation of insects in agricultural landscapes: potential impacts of climate change. Author(s): Terblanche, J. S. Karsten, M. Mitchell, K. A. Barton, M. G. Gibert, P.
Chapter: 7 (Page no: 119) Climate change and biological control in agricultural systems: principles and examples from North America. Author(s): Eigenbrode, S. D. Davis, T. S. Crowder, D. W.
Chapter: 8 (Page no: 136) Climate change effects on agricultural insect pests in Europe. Author(s): Lindström, L. Lehmann, P.
Chapter: 9 (Page no: 154) Abiotic factors, climatic variability and forest insect pests. Author(s): Neuvonen, S. Virtanen, T.
Chapter: 10 (Page no: 173) Responses of tree-killing bark beetles to a changing climate. Author(s): Raffa, K. F. Aukema, B. H. Bentz, B. J. Carroll, A. L. Hicke, J. A. Kolb, T. E.
Chapter: 11 (Page no: 202) The Eurasian spruce bark beetle: the role of climate. Author(s): Økland, B. Netherer, S. Marini, L.
Chapter: 12 (Page no: 220) Pine wood nematode, pine wilt disease, vector beetle and pine tree: how a multiplayer system could reply to climate change. Author(s): Roques, A. Zhao LiLin Sun JiangHua Robinet, C.
Chapter: 13 (Page no: 235) Northern geometrids and climate change: from abiotic factors to trophic interactions. Author(s): Ammunét, T. Bylund, H. Jepsen, J. U.
Chapter: 14 (Page no: 248) Effects of new forest management on insect damage risk in a changing climate. Author(s): Björkman, C. Bylund, H. Nilsson, U. Nordlander, G. Schroeder, M.

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