Upper thermal limits differ among and within component species in a tritrophic host-parasitoid-hyperparasitoid system

Understanding how climate change affects host-parasite systems and predicting the consequences for ecosystems, economies, and human health has emerged as an important task for science and society. Some basic insight into this complex problem can be gained by comparing the thermal physiology of inter...

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Veröffentlicht in:	PloS one 2018-06, Vol.13 (6), p.e0198803
Hauptverfasser:	Agosta, Salvatore J, Joshi, Kanchan A, Kester, Karen M
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Sprache:	eng
Schlagworte:	Adaptation, Physiological Air temperature Analysis Animals Biology Biology and Life Sciences Braconidae Climate change Earth Sciences Ecological effects Ecological monitoring Ecology Ecology and Environmental Sciences Environmental changes Heat Host-Parasite Interactions Host-parasite relationships Hymenoptera Hymenoptera - classification Hymenoptera - physiology Influence Insects Instars Laboratories Lepidoptera Manduca - parasitology Manduca - physiology Manduca sexta Medicine and Health Sciences Organisms Parasites Physiology Species Sphingidae Temperature Temperature tolerance Thermal stress Thermotolerance Tobacco Tri-trophic interactions
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creator	Agosta, Salvatore J Joshi, Kanchan A Kester, Karen M
description	Understanding how climate change affects host-parasite systems and predicting the consequences for ecosystems, economies, and human health has emerged as an important task for science and society. Some basic insight into this complex problem can be gained by comparing the thermal physiology of interacting host and parasite species. In this study, we compared upper thermal tolerance among three component species in a natural host-parasitoid-hyperparasitoid system from Virginia, USA. To assess the ecological relevance of our results, we also examined a record of maximum daily air temperatures collected near the study site in the last 124 years. We found that the caterpillar host Manduca sexta had a critical thermal maximum (CTmax) about 4°C higher than the parasitic wasp, Cotesia congregata, and the hyperparasitic wasp, Conura sp., had a CTmax about 6°C higher than its host, C. congregata. We also found significant differences in CTmax among instars and between parasitized and non-parasitized M. sexta. The highest maximum daily air temperature recorded near the study in the last 124 years was 42°C, which equals the average CTmax of one species (C. congregata) but is several degrees lower than the average CTmax of the other two species (M. sexta, Conura sp.) in this study. Our results combined with other studies suggest that significant differences in thermal performance within and among interacting host and parasite species are common in nature and that climate change may be largely disruptive to these systems with responses that are highly variable and complex.
doi_str_mv	10.1371/journal.pone.0198803
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subjects	Adaptation, Physiological Air temperature Analysis Animals Biology Biology and Life Sciences Braconidae Climate change Earth Sciences Ecological effects Ecological monitoring Ecology Ecology and Environmental Sciences Environmental changes Heat Host-Parasite Interactions Host-parasite relationships Hymenoptera Hymenoptera - classification Hymenoptera - physiology Influence Insects Instars Laboratories Lepidoptera Manduca - parasitology Manduca - physiology Manduca sexta Medicine and Health Sciences Organisms Parasites Physiology Species Sphingidae Temperature Temperature tolerance Thermal stress Thermotolerance Tobacco Tri-trophic interactions
title	Upper thermal limits differ among and within component species in a tritrophic host-parasitoid-hyperparasitoid system
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