Habitat isolation moderates the strength of top-down control in experimental pond food webs

Habitat isolation is well known to alter patterns of species' abundance, richness, and the ratios of predators: prey. Less clear, however, is how isolation alters interactions within food webs. Here, we present the results from an experiment performed in artificial ponds (mesocosms) manipulatin...

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Veröffentlicht in:	Ecology (Durham) 2010-03, Vol.91 (3), p.637-643
Hauptverfasser:	Chase, Jonathan M., Burgett, Amber A., Biro, Elizabeth G.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animal and plant ecology Animal, plant and microbial ecology Animals Biodiversity Biological and medical sciences Biomass dispersal Ecology Evolution experimental ponds Food Chain Food chains Food webs Fresh water ecosystems Fundamental and applied biological sciences. Psychology General aspects habitat isolation Habitats Herbivores Invertebrates - physiology Marine ecology metacommunity Metapopulation ecology Phytoplankton - physiology Ponds Predation Predators Predatory Behavior - physiology Synecology trophic cascade Trophic cascades Trophic relationships Zooplankton - physiology
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container_title	Ecology (Durham)
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creator	Chase, Jonathan M. Burgett, Amber A. Biro, Elizabeth G.
description	Habitat isolation is well known to alter patterns of species' abundance, richness, and the ratios of predators: prey. Less clear, however, is how isolation alters interactions within food webs. Here, we present the results from an experiment performed in artificial ponds (mesocosms) manipulating habitat isolation crossed with a predator reduction treatment to disentangle how isolation mediates the top-down effect of predators. The strength of the trophic cascade, from predators, through herbivores, to producers, was considerably stronger in connected than in isolated habitats. We further found that the overall richness of both predator and herbivore species declined strongly with isolation. Experimental predator reductions suggest that the mechanism underlying the herbivore response was likely mediated by a keystone predator effect; when predators were reduced, herbivore richness was lower, and there was no discernable effect of isolation on herbivore richness. Finally, we found that the composition of predators in more isolated habitats consisted of species that were smaller and likely less effective predators than species that persisted in less isolated habitats. In all, our experiment showed that habitat isolation can alter the structure of communities by a combination of direct effects of the species in question, as well as effects mediated through their interactions in the food web.
doi_str_mv	10.1890/09-0262.1
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Finally, we found that the composition of predators in more isolated habitats consisted of species that were smaller and likely less effective predators than species that persisted in less isolated habitats. 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subjects	Animal and plant ecology Animal, plant and microbial ecology Animals Biodiversity Biological and medical sciences Biomass dispersal Ecology Evolution experimental ponds Food Chain Food chains Food webs Fresh water ecosystems Fundamental and applied biological sciences. Psychology General aspects habitat isolation Habitats Herbivores Invertebrates - physiology Marine ecology metacommunity Metapopulation ecology Phytoplankton - physiology Ponds Predation Predators Predatory Behavior - physiology Synecology trophic cascade Trophic cascades Trophic relationships Zooplankton - physiology
title	Habitat isolation moderates the strength of top-down control in experimental pond food webs
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