Woodlice change the habitat use of spiders in a different food chain

Background In old field systems, the common woodlouse may have an indirect effect on a nursery web spider. Woodlice and nursery web spiders feed in different food chains, yet previous work demonstrated that the presence of woodlice is correlated with higher predation success by nursery web spiders u...

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Main Authors: Stefanie M. Guiliano, Cerina M. Karr, Nathalie R. Sommer, Robert W. Buchkowski
Format: Article
Language:English
Published: PeerJ Inc. 2020-06-01
Series:PeerJ
Subjects:
Online Access:https://peerj.com/articles/9184.pdf
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spelling doaj-1c5c41a7a70a449f8dc269f50d75852f2020-11-25T03:11:28ZengPeerJ Inc.PeerJ2167-83592020-06-018e918410.7717/peerj.9184Woodlice change the habitat use of spiders in a different food chainStefanie M. Guiliano0Cerina M. Karr1Nathalie R. Sommer2Robert W. Buchkowski3Northeastern University, Boston, MA, United States of AmericaNortheastern University, Boston, MA, United States of AmericaSchool of Forestry & Environmental Studies, Yale University, New Haven, CT, United States of AmericaSchool of Forestry & Environmental Studies, Yale University, New Haven, CT, United States of AmericaBackground In old field systems, the common woodlouse may have an indirect effect on a nursery web spider. Woodlice and nursery web spiders feed in different food chains, yet previous work demonstrated that the presence of woodlice is correlated with higher predation success by nursery web spiders upon their grasshopper prey. This finding suggested a new hypothesis which links two seemingly disparate food chains: when woodlice are present, the spider predator or the grasshopper prey changes their location in the vegetative canopy in a way that increases their spatial overlap and therefore predation rate. However, warming temperatures may complicate this phenomenon. The spider cannot tolerate thermal stress, meaning warming temperatures may cause the spider to move downwards in the vegetative canopy or otherwise alter its response to woodlice. Therefore, we would expect warming and woodlice presence to have an interactive effect on predation rate. Methods We conducted behavioral experiments in 2015, 2017, and 2018 to track habitat domains—the use of the vegetative canopy space by grasshoppers and spiders—in experimental cages. Then, we used three models of spider movement to try to explain the response of spiders to woodlice: expected net energy gain, signal detection theory, and individual-based modelling. Results Habitat domain observations revealed that spiders shift upward in the canopy when woodlice are present, but the corresponding effect on grasshopper prey survival was variable over the different years of study. Under warming conditions, spiders remained lower in the canopy regardless of the presence of woodlice, suggesting that thermal stress is more important than the effect of woodlice. Our modelling results suggest that spiders do not need to move away from woodlice to maximize net energy gain (expected net energy gain and signal detection theory models). Instead spider behavior is consistent with the null hypothesis that they move away from unsuccessful encounters with woodlice (individual-based simulation). We conclude that mapping how predator behavior changes across biotic (e.g. woodlouse presence) and abiotic conditions (e.g. temperature) may be critical to anticipate changes in ecosystem dynamics.https://peerj.com/articles/9184.pdfBehaviorGrasshopperHabitat domainIndividual-based modelIsopodOld field
collection DOAJ
language English
format Article
sources DOAJ
author Stefanie M. Guiliano
Cerina M. Karr
Nathalie R. Sommer
Robert W. Buchkowski
spellingShingle Stefanie M. Guiliano
Cerina M. Karr
Nathalie R. Sommer
Robert W. Buchkowski
Woodlice change the habitat use of spiders in a different food chain
PeerJ
Behavior
Grasshopper
Habitat domain
Individual-based model
Isopod
Old field
author_facet Stefanie M. Guiliano
Cerina M. Karr
Nathalie R. Sommer
Robert W. Buchkowski
author_sort Stefanie M. Guiliano
title Woodlice change the habitat use of spiders in a different food chain
title_short Woodlice change the habitat use of spiders in a different food chain
title_full Woodlice change the habitat use of spiders in a different food chain
title_fullStr Woodlice change the habitat use of spiders in a different food chain
title_full_unstemmed Woodlice change the habitat use of spiders in a different food chain
title_sort woodlice change the habitat use of spiders in a different food chain
publisher PeerJ Inc.
series PeerJ
issn 2167-8359
publishDate 2020-06-01
description Background In old field systems, the common woodlouse may have an indirect effect on a nursery web spider. Woodlice and nursery web spiders feed in different food chains, yet previous work demonstrated that the presence of woodlice is correlated with higher predation success by nursery web spiders upon their grasshopper prey. This finding suggested a new hypothesis which links two seemingly disparate food chains: when woodlice are present, the spider predator or the grasshopper prey changes their location in the vegetative canopy in a way that increases their spatial overlap and therefore predation rate. However, warming temperatures may complicate this phenomenon. The spider cannot tolerate thermal stress, meaning warming temperatures may cause the spider to move downwards in the vegetative canopy or otherwise alter its response to woodlice. Therefore, we would expect warming and woodlice presence to have an interactive effect on predation rate. Methods We conducted behavioral experiments in 2015, 2017, and 2018 to track habitat domains—the use of the vegetative canopy space by grasshoppers and spiders—in experimental cages. Then, we used three models of spider movement to try to explain the response of spiders to woodlice: expected net energy gain, signal detection theory, and individual-based modelling. Results Habitat domain observations revealed that spiders shift upward in the canopy when woodlice are present, but the corresponding effect on grasshopper prey survival was variable over the different years of study. Under warming conditions, spiders remained lower in the canopy regardless of the presence of woodlice, suggesting that thermal stress is more important than the effect of woodlice. Our modelling results suggest that spiders do not need to move away from woodlice to maximize net energy gain (expected net energy gain and signal detection theory models). Instead spider behavior is consistent with the null hypothesis that they move away from unsuccessful encounters with woodlice (individual-based simulation). We conclude that mapping how predator behavior changes across biotic (e.g. woodlouse presence) and abiotic conditions (e.g. temperature) may be critical to anticipate changes in ecosystem dynamics.
topic Behavior
Grasshopper
Habitat domain
Individual-based model
Isopod
Old field
url https://peerj.com/articles/9184.pdf
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