Infection and invasion: study cases from aquatic communities

doi:10.1017/9781316479964.009

Chapter Nine - Infection and invasion: study cases from aquatic communities

from Part II - Understanding between-host processes

Published online by Cambridge University Press: 28 October 2019

Melanie J. Hatcher ,

Jaimie T.A. Dick ,

Jamie Bojko ,

Grant D. Stentiford ,

Paul Stebbing and

Edited by

Andy Fenton and

Kenneth Wilson: Affiliation:
Lancaster University
Andy Fenton: Affiliation:
University of Liverpool
Dan Tompkins: Affiliation:
Predator Free 2050 Ltd

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Summary

Invasive species drive biodiversity loss and lead to changes in parasite–host associations. Parasites are linked to invasions and can mediate invasion success and outcomes. We review theoretical and empirical research into parasites in biological invasions, focusing on a freshwater invertebrate study system. We focus on the effects of parasitic infection on host traits (behaviour and life history) that can mediate native/invader trophic interactions. We review evidence from the field and laboratory of parasite-driven changes in predation, intraguild predation and cannibalism. Theoretical work shows that the trait-mediated effects of parasites can be as strong as classical density effects and their impact on the host’s trophic interactions merits more consideration. We also report on evidence of broader cascading effects warranting deeper study. Biological invasion can lead to altered parasite–host associations. Focusing on amphipod invasions, we find patterns of parasite introduction and loss that mirror host invasion pathways, but also highlight the risks of introducing invasive parasites. Horizon scanning and impact predictions are vital in identifying future disease risks, potential pathways of introduction and suitable management measures for mitigation.

Keywords

invasive alien species trait-mediated effects biosecurity enemy release functional responses intraguild predation biological invasion trophic interactions

Type: Chapter
Information: Wildlife Disease Ecology
Linking Theory to Data and Application
, pp. 262 - 295

DOI: https://doi.org/10.1017/9781316479964.009 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2019

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Chapter Nine - Infection and invasion: study cases from aquatic communities

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