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Multiple predators in the pelagic: modelling behavioural cascades

  1. ØYVIND FIKSEN*,
  2. SIGRUNN ELIASSEN,
  3. JOSEFIN TITELMAN

Article first published online: 23 MAY 2005

DOI: 10.1111/j.1365-2656.2005.00937.x

Issue

Journal of Animal Ecology

Journal of Animal Ecology

Volume 74, Issue 3, pages 423–429, May 2005

Additional Information

How to Cite

FIKSEN, Ø., ELIASSEN, S. and TITELMAN, J. (2005), Multiple predators in the pelagic: modelling behavioural cascades. Journal of Animal Ecology, 74: 423–429. doi: 10.1111/j.1365-2656.2005.00937.x

Author Information

  1. Department of Biology, University of Bergen, Høyteknologisenteret, Pb 7800, N-5020 Bergen, Norway

* Øyvind Fiksen, Department of Biology, University of Bergen, Høyteknologisenteret, Pb 7800, N-5020 BERGEN, Norway. E-mail: oyvind.fiksen@bio.uib.no.

Publication History

  1. Issue published online: 23 MAY 2005
  2. Article first published online: 23 MAY 2005
  3. Received 7 May 2004; accepted 4 October 2004

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Keywords:

  • DVM;
  • dynamic programming;
  • emergent effects;
  • multiple predators;
  • zooplankton

Summary

  • 1
    The behaviour of predators is rarely considered in models of predator–prey interactions, nor is it common to include multiple predators in models of animal behaviour.
  • 2
    We introduce a model of optimal diel vertical migration in zooplankton prey facing predation from two functionally different predators, fish and other zooplankton. Zooplankton predators are themselves subject to predation from larger zooplankton, and all zooplankton face the classical trade-off between increasing growth rate and predation risk from fish towards the surface. Prey are most vulnerable to zooplankton predators at small sizes, but become more visible to fish as they grow. However, by habitat selection prey continuously manage their exposure to different sources of risk.
  • 3
    We analyse situations with cascading behavioural interactions of size-structured predator–prey interactions in the pelagic. In particular, we explore how vertical gradients in growth rates and relative abundance of fish and zooplankton predators affect optimal distribution patterns, growth and mortality schedules.
  • 4
    A major model prediction is that prey susceptibility to one functional predator type depends on the abundance of the other predator. Higher abundance of zooplankton predators leads to risk enhancement from fish, minor increases in predation rate from zooplankton and unchanged prey growth rates. Increasing abundance of fish does not alter the risk from zooplankton predators, but reduces growth and development rates. Such asymmetric emergent effects may be common when prey and predators share the same spatial refuge from a common top predator.
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