Experimental whole-stream warming alters community size structure

Daniel Nelson; Jonathan P. Benstead; Alexander D. Huryn; Wyatt F. Cross; James M. Hood; Philip W. Johnson; James R. Junker; Gísli M. Gíslason; Jón S. Ólafsson

doi:10.1111/gcb.13574

Experimental whole-stream warming alters community size structure

Daniel Nelson
, Jonathan P. Benstead
, Alexander D. Huryn
, Wyatt F. Cross
, James M. Hood
, Philip W. Johnson
, James R. Junker
, Gísli M. Gíslason
, Jón S. Ólafsson

Faculty of Life and Environmental Sciences

University of Iceland

Research output: Contribution to journal › Article › peer-review

Abstract

How ecological communities respond to predicted increases in temperature will determine the extent to which Earth's biodiversity and ecosystem functioning can be maintained into a warmer future. Warming is predicted to alter the structure of natural communities, but robust tests of such predictions require appropriate large-scale manipulations of intact, natural habitat that is open to dispersal processes via exchange with regional species pools. Here, we report results of a two-year whole-stream warming experiment that shifted invertebrate assemblage structure via unanticipated mechanisms, while still conforming to community-level metabolic theory. While warming by 3.8 °C decreased invertebrate abundance in the experimental stream by 60% relative to a reference stream, total invertebrate biomass was unchanged. Associated shifts in invertebrate assemblage structure were driven by the arrival of new taxa and a higher proportion of large, warm-adapted species (i.e., snails and predatory dipterans) relative to small-bodied, cold-adapted taxa (e.g., chironomids and oligochaetes). Experimental warming consequently shifted assemblage size spectra in ways that were unexpected, but consistent with thermal optima of taxa in the regional species pool. Higher temperatures increased community-level energy demand, which was presumably satisfied by higher primary production after warming. Our experiment demonstrates how warming reassembles communities within the constraints of energy supply via regional exchange of species that differ in thermal physiological traits. Similar responses will likely mediate impacts of anthropogenic warming on biodiversity and ecosystem function across all ecological communities.

Original language	English
Pages (from-to)	2618-2628
Number of pages	11
Journal	Global Change Biology
Volume	23
Issue number	7
DOIs	https://doi.org/10.1111/gcb.13574
Publication status	Published - Jul 2017

Bibliographical note

Funding Information: This work was supported by the National Science Foundation (DEB-0949774 and DEB-0949726). JMH was supported by the Icelandic Research Fund (i. Rannsóknasjóður) 141840-051 during manuscript preparation. We thank Lauren Davis, David Hernandez, Amanda Keasberry, Elena Nava, Camille Perrett, and Jackie Pitts for help in the laboratory, and Friðþjófur Árnason, Liliana García, Ragnhildur Magnúsdóttir, Ryan McClure, Vija Pelekis, Adam Toomey, Chau Tran, Brooke Weigel, and Tanner Williamson for assistance in the field. We are grateful to Sigurður Guðjónsson, Guðni Guðbergsson, and the rest of the staff at the Veiðimálastofnun for providing laboratory space and logistical support. Many thanks to Sveinbjörn Steinþórsson at the University of Iceland and the Hveragerði rescue squad for super-jeep transport to our field sites during the winter. James H. Brown, Robert O. Hall, Eoin J. O'Gorman, and Gabriel Yvon-Durocher provided insightful comments on earlier versions of this manuscript. We also thank Bob Clarke for his suggestions regarding the multivariate analysis of our data. Publisher Copyright: © 2016 John Wiley & Sons Ltd

Other keywords

body size
community structure
energy demand
metabolic theory
stream warming
thermal preference

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10.1111/gcb.13574

Cite this

@article{d5a08e1314684160b35376fa4f4b2667,

title = "Experimental whole-stream warming alters community size structure",

abstract = "How ecological communities respond to predicted increases in temperature will determine the extent to which Earth's biodiversity and ecosystem functioning can be maintained into a warmer future. Warming is predicted to alter the structure of natural communities, but robust tests of such predictions require appropriate large-scale manipulations of intact, natural habitat that is open to dispersal processes via exchange with regional species pools. Here, we report results of a two-year whole-stream warming experiment that shifted invertebrate assemblage structure via unanticipated mechanisms, while still conforming to community-level metabolic theory. While warming by 3.8 °C decreased invertebrate abundance in the experimental stream by 60\% relative to a reference stream, total invertebrate biomass was unchanged. Associated shifts in invertebrate assemblage structure were driven by the arrival of new taxa and a higher proportion of large, warm-adapted species (i.e., snails and predatory dipterans) relative to small-bodied, cold-adapted taxa (e.g., chironomids and oligochaetes). Experimental warming consequently shifted assemblage size spectra in ways that were unexpected, but consistent with thermal optima of taxa in the regional species pool. Higher temperatures increased community-level energy demand, which was presumably satisfied by higher primary production after warming. Our experiment demonstrates how warming reassembles communities within the constraints of energy supply via regional exchange of species that differ in thermal physiological traits. Similar responses will likely mediate impacts of anthropogenic warming on biodiversity and ecosystem function across all ecological communities.",

keywords = "body size, community structure, energy demand, metabolic theory, stream warming, thermal preference",

author = "Daniel Nelson and Benstead, \{Jonathan P.\} and Huryn, \{Alexander D.\} and Cross, \{Wyatt F.\} and Hood, \{James M.\} and Johnson, \{Philip W.\} and Junker, \{James R.\} and G{\'i}slason, \{G{\'i}sli M.\} and {\'O}lafsson, \{J{\'o}n S.\}",

note = "Funding Information: This work was supported by the National Science Foundation (DEB-0949774 and DEB-0949726). JMH was supported by the Icelandic Research Fund (i. Ranns{\'o}knasj{\'o}{\dh}ur) 141840-051 during manuscript preparation. We thank Lauren Davis, David Hernandez, Amanda Keasberry, Elena Nava, Camille Perrett, and Jackie Pitts for help in the laboratory, and Fri{\dh}{\th}j{\'o}fur {\'A}rnason, Liliana Garc{\'i}a, Ragnhildur Magn{\'u}sd{\'o}ttir, Ryan McClure, Vija Pelekis, Adam Toomey, Chau Tran, Brooke Weigel, and Tanner Williamson for assistance in the field. We are grateful to Sigur{\dh}ur Gu{\dh}j{\'o}nsson, Gu{\dh}ni Gu{\dh}bergsson, and the rest of the staff at the Vei{\dh}im{\'a}lastofnun for providing laboratory space and logistical support. Many thanks to Sveinbj{\"o}rn Stein{\th}{\'o}rsson at the University of Iceland and the Hverager{\dh}i rescue squad for super-jeep transport to our field sites during the winter. James H. Brown, Robert O. Hall, Eoin J. O'Gorman, and Gabriel Yvon-Durocher provided insightful comments on earlier versions of this manuscript. We also thank Bob Clarke for his suggestions regarding the multivariate analysis of our data. Publisher Copyright: {\textcopyright} 2016 John Wiley \& Sons Ltd",

year = "2017",

month = jul,

doi = "10.1111/gcb.13574",

language = "English",

volume = "23",

pages = "2618--2628",

journal = "Global Change Biology",

issn = "1354-1013",

publisher = "Wiley-Blackwell Publishing Ltd",

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TY - JOUR

T1 - Experimental whole-stream warming alters community size structure

AU - Nelson, Daniel

AU - Benstead, Jonathan P.

AU - Huryn, Alexander D.

AU - Cross, Wyatt F.

AU - Hood, James M.

AU - Johnson, Philip W.

AU - Junker, James R.

AU - Gíslason, Gísli M.

AU - Ólafsson, Jón S.

N1 - Funding Information: This work was supported by the National Science Foundation (DEB-0949774 and DEB-0949726). JMH was supported by the Icelandic Research Fund (i. Rannsóknasjóður) 141840-051 during manuscript preparation. We thank Lauren Davis, David Hernandez, Amanda Keasberry, Elena Nava, Camille Perrett, and Jackie Pitts for help in the laboratory, and Friðþjófur Árnason, Liliana García, Ragnhildur Magnúsdóttir, Ryan McClure, Vija Pelekis, Adam Toomey, Chau Tran, Brooke Weigel, and Tanner Williamson for assistance in the field. We are grateful to Sigurður Guðjónsson, Guðni Guðbergsson, and the rest of the staff at the Veiðimálastofnun for providing laboratory space and logistical support. Many thanks to Sveinbjörn Steinþórsson at the University of Iceland and the Hveragerði rescue squad for super-jeep transport to our field sites during the winter. James H. Brown, Robert O. Hall, Eoin J. O'Gorman, and Gabriel Yvon-Durocher provided insightful comments on earlier versions of this manuscript. We also thank Bob Clarke for his suggestions regarding the multivariate analysis of our data. Publisher Copyright: © 2016 John Wiley & Sons Ltd

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N2 - How ecological communities respond to predicted increases in temperature will determine the extent to which Earth's biodiversity and ecosystem functioning can be maintained into a warmer future. Warming is predicted to alter the structure of natural communities, but robust tests of such predictions require appropriate large-scale manipulations of intact, natural habitat that is open to dispersal processes via exchange with regional species pools. Here, we report results of a two-year whole-stream warming experiment that shifted invertebrate assemblage structure via unanticipated mechanisms, while still conforming to community-level metabolic theory. While warming by 3.8 °C decreased invertebrate abundance in the experimental stream by 60% relative to a reference stream, total invertebrate biomass was unchanged. Associated shifts in invertebrate assemblage structure were driven by the arrival of new taxa and a higher proportion of large, warm-adapted species (i.e., snails and predatory dipterans) relative to small-bodied, cold-adapted taxa (e.g., chironomids and oligochaetes). Experimental warming consequently shifted assemblage size spectra in ways that were unexpected, but consistent with thermal optima of taxa in the regional species pool. Higher temperatures increased community-level energy demand, which was presumably satisfied by higher primary production after warming. Our experiment demonstrates how warming reassembles communities within the constraints of energy supply via regional exchange of species that differ in thermal physiological traits. Similar responses will likely mediate impacts of anthropogenic warming on biodiversity and ecosystem function across all ecological communities.

AB - How ecological communities respond to predicted increases in temperature will determine the extent to which Earth's biodiversity and ecosystem functioning can be maintained into a warmer future. Warming is predicted to alter the structure of natural communities, but robust tests of such predictions require appropriate large-scale manipulations of intact, natural habitat that is open to dispersal processes via exchange with regional species pools. Here, we report results of a two-year whole-stream warming experiment that shifted invertebrate assemblage structure via unanticipated mechanisms, while still conforming to community-level metabolic theory. While warming by 3.8 °C decreased invertebrate abundance in the experimental stream by 60% relative to a reference stream, total invertebrate biomass was unchanged. Associated shifts in invertebrate assemblage structure were driven by the arrival of new taxa and a higher proportion of large, warm-adapted species (i.e., snails and predatory dipterans) relative to small-bodied, cold-adapted taxa (e.g., chironomids and oligochaetes). Experimental warming consequently shifted assemblage size spectra in ways that were unexpected, but consistent with thermal optima of taxa in the regional species pool. Higher temperatures increased community-level energy demand, which was presumably satisfied by higher primary production after warming. Our experiment demonstrates how warming reassembles communities within the constraints of energy supply via regional exchange of species that differ in thermal physiological traits. Similar responses will likely mediate impacts of anthropogenic warming on biodiversity and ecosystem function across all ecological communities.

KW - body size

KW - community structure

KW - energy demand

KW - metabolic theory

KW - stream warming

KW - thermal preference

UR - https://www.scopus.com/pages/publications/85006958936

U2 - 10.1111/gcb.13574

DO - 10.1111/gcb.13574

M3 - Article

C2 - 27868314

SN - 1354-1013

VL - 23

SP - 2618

EP - 2628

JO - Global Change Biology

JF - Global Change Biology

IS - 7

ER -

Experimental whole-stream warming alters community size structure

Abstract

Bibliographical note

Other keywords

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