Predation pressure on sentinel prey does not necessarily diminish with advancing urbanization

Gábor L. Lövei; Roland Horváth; Szabolcs Mizser; Mária Tóth; Tibor Magura

doi:10.1111/1744-7917.70151

Insect Science ›› 2025, Vol. 32 ›› Issue (6) :1926 -1934. DOI: 10.1111/1744-7917.70151

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Predation pressure on sentinel prey does not necessarily diminish with advancing urbanization

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Abstract

Urbanization, one of the most significant global environmental issues of our time, causes significant environmental and structural changes in natural or seminatural habitat patches. These urbanization-related changes trigger significant impact on ecological interactions and functioning. Predation is one of the most important ecological interactions, and urbanization-related changes on predation pressure may have substantial ecological consequences. We studied predation pressure over a full season (from April to October) in rural versus urban forests using the sentinel approach in and around a large city (Debrecen) in the eastern part of the Great Hungarian Lowland. Model caterpillars made of nondrying green plasticine were readily attacked by arthropods, birds and mammals. From attack marks left by potential predators, a relatively high predation pressure was documented: up to 36% of the caterpillars exposed for 24 h showed attack marks. Seasonal differences were also obvious, with predation pressure during summer being significantly higher than in spring or autumn. This trend held for overall attack rates, also for attacks by arthropods and mammals but not birds. Surprisingly, attack rates were often higher in urban than rural habitats, contradicting the general hypothesis that predation pressure is lower in urbanized areas. As attack rates depend on both predator abundance and activity, and general data indicate lower predator abundances in urban habitats, this phenomenon may have been caused by hungrier predators in urban forest fragments or by the predator relaxation/safe habitat hypothesis that argues that a reduced need for vigilance allows more time to search for prey.

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artificial caterpillars / predation / rural forests / seasonality / urban forests

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Gábor L. Lövei, Roland Horváth, Szabolcs Mizser, Mária Tóth, Tibor Magura. Predation pressure on sentinel prey does not necessarily diminish with advancing urbanization. Insect Science, 2025, 32(6): 1926-1934 DOI:10.1111/1744-7917.70151

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Bates, D., Mächler, M., Bolker, B. and Walker, S. (2015) Fitting linear mixed-effects models using lme4. Journal of Statistical Software, 67, 1–48.

[2]	Breslow, N.E. and Clayton, D.G. (1993) Approximate inference in generalized linear mixed models. Journal of the American Statistical Association, 88, 9–25.

[3]	Bujan, J., Bertelsmeier, C. and Ješovnik, A. (2024) Insects in temperate urban parks face stronger selection pressure from the cold than the heat. Ecology and Evolution, 14, e11335.

[4]	de Mendiburu, F. (2023) agricolae: Statistical procedures for agricultural research. https://cran.r-project.org/package=agricolae.

[5]	Devictor, V., Julliard, R. and Jiguet, F. (2008) Distribution of specialist and generalist species along spatial gradients of habitat disturbance and fragmentation. Oikos, 117, 507–514.

[6]	Elek, Z., Lövei, G.L. and Bátki, M. (2017) Sex-specific interaction of body condition and asymmetry in carabids in distinct urbanisation stages. Community Ecology, 18, 253–259.

[7]	Eötvös, C.B., Lövei, G.L. and Magura, T. (2020) Predation pressure on sentinel insect prey along a riverside urbanization gradient in Hungary. Insects, 11, 97.

[8]	Eötvös, C.B., Magura, T. and Lövei, G.L. (2018) A meta-analysis indicates reduced predation pressure with increasing urbanization. Landscape and Urban Planning, 180, 54–59.

[9]	Ferrante, M., Lo Cacciato, A. and Lövei, G.L. (2014) Quantifying predation pressure along an urbanisation gradient in Denmark using artificial caterpillars. European Journal of Entomology, 111, 649–654.

[10]	Ferrarini, A., Bagni, L. and Gustin, M. (2025) Bird richness and abundance in urban areas: simulation-based conservation strategies for an Italian town. Biology, 14, 37.

[11]	Fischer, J.D., Cleeton, S.H., Lyons, T.P. and Miller, J.R. (2012) Urbanization and the predation paradox: the role of trophic dynamics in structuring vertebrate communities. Bioscience, 62, 809–818.

[12]	Gering, J.C. and Blair, R.B. (1999) Predation on artificial bird nests along an urban gradient: predatory risk or relaxation in urban environments? Ecography, 22, 532–541.

[13]	Gervais, L., Thompson, M.J., de Villemereuil, P., Burkhard, T., Teplitsky, C., Class, B. et al. (2025) Behavioral DiverCity: individual differences in behavior change along an urbanization gradient. Behavioral Ecology, 36, araf035.

[14]	Gomes, V., Ribeiro, R. and Carretero, M.A. (2011) Effects of urban habitat fragmentation on common small mammals: species versus communities. Biodiversity and Conservation, 20, 3577–3590.

[15]	Henderson, P.A. and Southwood, T.R.E. (2016) Ecological Methods, 4th edn. Wiley-Blackwell, p. 656.

[16]	Howe, A., Lövei, G.L. and Nachman, G. (2009) Dummy caterpillars as a simple method to assess predation rates on invertebrates in a tropical agroecosystem. Entomologia Experimentalis et Applicata, 131, 325–329.

[17]	Jensen, K., Mayntz, D., Toft, S., Clissold, F.J., Hunt, J., Raubenheimer, D. et al. (2012) Optimal foraging for specific nutrients in predatory beetles. Proceedings of the Royal Society B: Biological Sciences, 279, 2212–2218.

[18]	Kozlov, M.V., Lanta, V., Zverev, V., Rainio, K., Kunavin, M.A. and Zvereva, E.L. (2017) Decreased losses of woody plant foliage to insects in large urban areas are explained by bird predation. Global Change Biology, 23, 4354–4364.

[19]	Leroux, S.J. and Schmitz, O.J. (2015) Predator-driven elemental cycling: the impact of predation and risk effects on ecosystem stoichiometry. Ecology and Evolution, 5, 4976–4988.

[20]	Lima, S.L. (1998) Nonlethal effects in the ecology of predator-prey interactions: What are the ecological effects of anti-predator decision-making? Bioscience, 48, 25–34.

[21]	Lövei, G.L., Elek, Z., Howe, A. and Engaard, M. (2018) The use of percentile-percentile plots to compare differences in seasonal dynamics, illustrated by the case of ground beetles (Coleoptera, Carabidae) reacting to urbanisation. Community Ecology, 19, 1–8.

[22]	Lövei, G.L. and Ferrante, M. (2017) A review of the sentinel prey method as a way of quantifying invertebrate predation under field conditions. Insect Science, 24, 528–542.

[23]	Lövei, G.L. and Ferrante, M. (2024) The use and prospects of nonlethal methods in entomology. Annual Review of Entomology, 69, 183–198.

[24]	Lövei, G.L., Ferrante, M., Möller, D., Möller, G. and Vincze, É. (2023) The need for a (non-destructive) method revolution in entomology. Biological Conservation, 282, 110075.

[25]	Lövei, G.L. and Magura, T. (2022) Body size and the urban heat island effect modulate the temperature-size relationship in ground beetles. Journal of Biogeography, 49, 1618–1628.

[26]	Lövei, G.L. and Sunderland, K.D. (1996) Ecology and behavior of ground beetles (Coleoptera: Carabidae). Annual Review of Entomology, 41, 231–256.

[27]	Low, P.A., Sam, K., McArthur, C., Posa, M.R.C. and Hochuli, D.F. (2014) Determining predator identity from attack marks left in model caterpillars: guidelines for best practice. Entomologia Experimentalis Et Applicata, 152, 120–126.

[28]	Magura, T., Lövei, G.L. and Tóthmérész, B. (2010) Does urbanization decrease diversity in ground beetle (Carabidae) assemblages? Global Ecology and Biogeography, 19, 16–26.

[29]	Magura, T., Lövei, G.L. and Tóthmérész, B. (2018) Conversion from environmental filtering to randomness as assembly rule of ground beetle assemblages along an urbanization gradient. Scientific Reports, 8, 16992.

[30]	Magura, T., Mizser, S., Horváth, R., Tóth, M., Likó, I. and Lövei, G.L. (2024) Urbanization reduces gut bacterial microbiome diversity in a specialist ground beetle, Carabus convexus. Molecular Ecology, 33, e17265.

[31]	Magura, T., Tóthmérész, B. and Molnár, T. (2004) Changes in carabid beetle assemblages along an urbanisation gradient in the city of Debrecen, Hungary. Landscape Ecology, 19, 747–759.

[32]	Mansion-Vaquié, A., Ferrante, M., Cook, S.M., Pell, J.K. and Lövei, G.L. (2017) Manipulating field margins to increase predation intensity in fields of winter wheat (Triticum aestivum). Journal of Applied Entomology, 141, 600–611.

[33]	Martinson, H.M. and Raupp, M.J. (2013) A meta-analysis of the effects of urbanization on ground beetle communities. Ecosphere, 4, 60.

[34]	Muchula, K., Xie, G. and Gurr, G.M. (2019) Ambient temperature affects the utility of plasticine caterpillar models as a tool to measure activity of predators across latitudinal and elevational gradients. Biological Control, 129, 12–17.

[35]	Niemelä, J., Kotze, J., Ashworth, A., Brandmayr, P., Desender, K., New, T. et al. (2000) The search for common anthropogenic impacts on biodiversity: A global network. Journal of Insect Conservation, 4, 3–9.

[36]	Nuissl, H. and Siedentop, S. (2021) Urbanisation and land use change. In Sustainable Land Management in a European Context: A Co-Design Approach (eds. T. Weith, T. Barkmann, N. Gaasch, S. Rogga, C. Strauß & J. Zscheischler), pp. 75–99. Springer International Publishing, Cham.

[37]	Parsons, S.E. and Frank, S.D. (2019) Urban tree pests and natural enemies respond to habitat at different spatial scales. Journal of Urban Ecology, 5, juz010.

[38]	Prugh, L.R., Stoner, C.J., Epps, C.W., Bean, W.T., Ripple, W.J., Laliberte, A.S. et al. (2009) The rise of the mesopredator. Bioscience, 59, 779–791.

[39]	R Core Team. (2024) R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing, Vienna, Austria. https://www.r-project.org.

[40]	Seress, G., Lipovits, Á., Bókony, V. and Czúni, L. (2014) Quantifying the urban gradient: a practical method for broad measurements. Landscape and Urban Planning, 131, 42–50.

[41]	Shoshitaishvili, B. (2021) From Anthropocene to noosphere: the great acceleration. Earth's Future, 9, e2020EF001917.

[42]	Soanes, K., Taylor, L., Ramalho, C.E., Maller, C., Parris, K., Bush, J. et al. (2023) Conserving urban biodiversity: current practice, barriers, and enablers. Conservation Letters, 16, e12946.

[43]	Soulé, M.E., Bolger, D.T., Alberts, A.C., Wrights, J., Sorice, M. and Hill, S. (1988) Reconstructed dynamics of rapid extinctions of chaparral-requiring birds in urban habitat islands. Conservation Biology, 2, 75–92.

[44]	Svenningsen, C.S., Peters, B., Bowler, D.E., Dunn, R.R., Bonn, A. and Tøttrup, A.P. (2024) Insect biomass shows a stronger decrease than species richness along urban gradients. Insect Conservation and Diversity, 17, 182–188.

[45]	Szabó, B., Korányi, D., Gallé, R., Lövei, G.L., Bakonyi, G. and Batáry, P. (2023) Urbanization decreases species richness, and increases abundance in dry climates whereas decreases in wet climates: a global meta-analysis. Science of the Total Environment, 859, 160145.

[46]	Taylor, R.J. (1984) Predation. Springer, Dordrecht. p. 166.

[47]	Theodorou, P. (2022) The effects of urbanisation on ecological interactions. Current Opinion in Insect Science, 52, 100922.

[48]	Venables, W. and Ripley, B. (2002) Modern Applied Statistics with S. Springer, New York. p. 498.

[49]	Zuur, A., Ieno, E.N., Walker, N., Saveliev, A.A. and Smith, G.M. (2009) Mixed Effects Models and Extensions in Ecology with R. Springer, New York. p. 574.

[50]	Zvereva, E.L. and Kozlov, M.V. (2021) Seasonal variations in bird selection pressure on prey colouration. Oecologia, 196, 1017–1026.

[51]	Zvereva, E.L. and Kozlov, M.V. (2023) Predation risk estimated on live and artificial insect prey follows different patterns. Ecology, 104, e3943.