Elevated Temperature and Drought Interact to Reduce Parasitoid Effectiveness in Suppressing Hosts

• Published in: PloS one Vol. 8; no. 3; p. e58136
• Main Authors: Romo, Cecilia M., Tylianakis, Jason M.
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 05.03.2013; Public Library of Science (PLoS)
• Subjects: Agricultural pests; Agriculture; Animal reproduction; Animals; Aphidoidea; Aphids; Aphids - parasitology; Biology; Climate; Climate Change; Climate effects; Climatic extremes; Drought; Droughts; Ecology; Ecosystem; Ecosystems; Emergence; Female; Fitness; Food Chain; Geography; Global temperature changes; Global warming; Herbivores; Herbivory; High temperature; Host-Parasite Interactions; Hyperparasitism; Insects; Laboratory experiments; Longevity; Mean temperatures; Natural enemies; New Zealand; Offspring; Outbreaks; Parasitoids; Pest Control, Biological; Pest outbreaks; Pests; Physiology; Poisson Distribution; Population growth; Predator-prey interactions; Predictions; Prey; Quality; Studies; Success; Temperature; Temperature effects; Temperature rise; Temperature variations; Time Factors; Trophic levels; Wasps; New Zealand
• ISSN: 1932-6203; 1932-6203
• DOI: 10.1371/journal.pone.0058136

Climate change affects the abundance, distribution and activity of natural enemies that are important for suppressing herbivore crop pests. Moreover, higher mean temperatures and increased frequency of climatic extremes are expected to induce different responses across trophic levels, potentially disrupting predator-prey interactions. Using field observations, we examined the response of an aphid host-parasitoid system to variation in temperature. Temperature was positively associated with attack rates by parasitoids, but also with a non-significant trend towards increased attack rates by higher-level hyperparasitoids. Elevated hyperparasitism could partly offset any benefit of climate warming to parasitoids, and would suggest that higher trophic levels may hamper predictions of predator-prey interactions. Additionally, the mechanisms affecting host-parasitoid dynamics were examined using controlled laboratory experiments that simulated both temperature increase and drought. Parasitoid fitness and longevity responded differently when exposed to each climatic variable in isolation, compared to the interaction of both variables at once. Although temperature increase or drought tended to positively affect the ability of parasitoids to control aphid populations, these effects were significantly reversed when the drivers were expressed in concert. Additionally, separate warming and drought treatments reduced parasitoid longevity, and although temperature increased parasitoid emergence success and drought increased offspring production, combined temperature and drought produced the lowest parasitoid emergence. The non-additive effects of different climate drivers, combined with differing responses across trophic levels, suggest that predicting future pest outbreaks will be more challenging than previously imagined.