<b>Predation on live and artificial insect prey shows different global latitudinal patterns</b>

  1. Zvereva, Elena L.
  2. Adroit, Benjamin
  3. Andersson, Tommi
  4. R. A. Barnett, Craig
  5. Branco, Sofia
  6. Castagneyrol, Bastien
  7. Chiarenza, Giancarlo Maria
  8. Dáttilo, Wesley
  9. del-Val, Ek
  10. Filip, Jan
  11. Griffith, Jory
  12. Hargreaves, Anna L.
  13. Hernández Agüero, Juan Antonio
  14. L. H. Silva, Isabelle
  15. Yixuan, Hong
  16. Kietzka, Gabriella
  17. Klimeš, Petr
  18. Koistinen, Max
  19. Kruglova, Oksana
  20. Kumpula, Satu
  21. Lopezosa, Paula
  22. March-Salas, Marti
  23. Marquis, Robert J.
  24. Marusik, Yuri M.
  25. Moles, Angela T.
  26. Muola, Anne
  27. Murkwe, Mercy
  28. Nakamura, Akihiro
  29. Olson, Cameron
  30. Pagani-Núñez, Emilio
  31. Popova, Anna
  32. Rahn, Olivia
  33. Reshchikov, Alexey
  34. Rodriguez-Campbell, Antonio
  35. Rytkönen, Seppo
  36. Sam, Katerina
  37. Sounapoglou, Antigone
  38. Tropek, Robert
  39. Wendan, Cheng
  40. Xu, Guorui
  41. Zeng, Yu
  42. Zolotarev, Maxim
  43. A. Zubrij, Natalia
  44. Zverev, Vitali
  45. Kozlov, Mikhail V.
  46. Mostrar todos los/as autores/as +

Editor: figshare

Año de publicación: 2024

Tipo: Dataset

CC BY 4.0

DOI: 10.6084/M9.FIGSHARE.26340373 lock_openAcceso abierto editor

Resumen

Long-standing theory predicts that the intensity of biotic interactions increases from high to low latitudes. Studies addressing geographic variation in predation on insect prey have often relied on prey models, which lack many biological characteristics of live prey. Our goals were to explore global latitudinal patterns of predator attack rates on standardised live insect prey and to compare the patterns in predation on live insects with those on plasticine prey models. We measured predation rates in 43 forested locations distributed across five continents from 34.1°S to 69.5°N latitude. At each location, we exposed 20 sets of three bait types, one set per tree. Each set included three live fly larvae (maggots), three live fly puparia, and three plasticine models of the puparia. We used glue rings to isolate half of the sets from non-flying predators. Arthropod attack rates on plasticine prey decreased linearly from low to high latitudes, whereas attack rates on maggots had a U shaped distribution, with the lowest predation rates at temperate latitudes and the highest rates at tropical and boreal latitudes. This difference emerged from intensive predator attacks on live maggots, but not on plasticine models, in boreal sites. Site-specific attack rates of arthropod predators on live and plasticine prey were not correlated. In contrast, bird attack rates on live maggots and plasticine models were positively correlated, but did not show significant latitudinal changes. We concluded that latitudinal patterns in predation differ between major groups of predators and between types of prey. Poleward decreases in both arthropod and combined arthropod and bird predation on plasticine models do not mirror patterns of predation on our live prey, the latter likely reflecting real patterns of predation risk better than do patterns of attack on artificial prey.