The strength of biotic interactions is generally thought to increase toward the equator, but support for this hypothesis is contradictory. We explored whether predator attacks on artificial prey of eight different colors vary among climates and whether this variation affects the detection of latitudinal patterns in predation. Bird attack rates negatively correlated with model luminance in cold and temperate environments, but not in tropical environments. Bird predation on black and on white (extremes in luminance) models demonstrated different latitudinal patterns, presumably due to differences in prey conspicuousness between habitats with different light regimes. When attacks on models of all colors were combined, arthropod predation decreased, whereas bird predation increased with increasing latitude. We conclude that selection for prey coloration may vary geographically and according to predator identity, and that the importance of different predators may show contrasting patterns, thus weakening the overall latitudinal trend in top-down control of herbivorous insects.
Original language | English |
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Pages (from-to) | 14273-14285 |
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Journal | Ecology and Evolution |
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Volume | 9 |
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Issue number | 24 |
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DOIs | |
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Publication status | Published - 1 Dec 2019 |
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Externally published | Yes |
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The authors were supported by multiple funding bodies, including Academy of Finland (projects 311929 and 316182), Spanish Ministry of Economy and Competitiveness (PCIN‐2016‐150), Community of Madrid (PEJD‐2017‐PRE/AMB‐3669), Chinese Academy of Sciences (2017XTBG‐T01 and West Light Foundation), Conselho Nacional de Pesquisa CNPq (grant 307210‐2016‐2), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES/PNPD), PELD/CNPq (no. 441703/2016‐0; site TANG), Consejo Nacional de Ciencia, Tecnología e Innovación del Perú (CONCYTEC) (grant 107‐2016‐FONDECYT‐ERANet‐LAC), and Linnaeus University. We are grateful to Instituto Estadual de Florestas for issuing a state permit, to D. Heese‐Krige and H. Schreuder for granting access to their land, and to M. J. Aguilar, Y. Antonini, T. N. Brandt, P. Chambi, C. Cardoso, R. Cruz, L. Forsman, M. Forsman, S. Forsman, Y. He, N. Henriques, V. Huaman, M. Mendez, A. Nina, D. Nunes, A. Popova, R. Souza, V. Sperandei, E. Valdes‐Correcher, and Y. Valdez for various help with the experiments.
The authors were supported by multiple funding bodies, including Academy of Finland (projects 311929 and 316182), Spanish Ministry of Economy and Competitiveness (PCIN-2016-150), Community of Madrid (PEJD-2017-PRE/AMB-3669), Chinese Academy of Sciences (2017XTBG-T01 and West Light Foundation), Conselho Nacional de Pesquisa CNPq (grant 307210-2016-2), Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior (CAPES/PNPD), PELD/CNPq (no. 441703/2016-0; site TANG), Consejo Nacional de Ciencia, Tecnolog?a e Innovaci?n del Per? (CONCYTEC) (grant 107-2016-FONDECYT-ERANet-LAC), and Linnaeus University. We are grateful to Instituto Estadual de Florestas for issuing a state permit, to D. Heese-Krige and H. Schreuder for granting access to their land, and to M. J. Aguilar, Y. Antonini, T. N. Brandt, P. Chambi, C. Cardoso, R. Cruz, L. Forsman, M. Forsman, S. Forsman, Y. He, N. Henriques, V. Huaman, M. Mendez, A. Nina, D. Nunes, A. Popova, R. Souza, V. Sperandei, E. Valdes-Correcher, and Y. Valdez for various help with the experiments.