Impacts of Warming on the Structure and Functioning of Aquatic Communities. Individual- to Ecosystem-Level Responses

Eoin J. O'Gorman*, Doris E. Pichler, Georgina Adams, Jonathan P. Benstead, Haley Cohen, Nicola Craig, Wyatt F. Cross, Benoît O.L. Demars, Nikolai Friberg, Gísli Már Gíslason, Rakel Gudmundsdóttir, Adrianna Hawczak, James M. Hood, Lawrence N. Hudson, Liselotte Johansson, Magnus P. Johansson, James R. Junker, Anssi Laurila, J. Russell Manson, Efpraxia MavromatiDaniel Nelson, Jón S. ólafsson, Daniel M. Perkins, Owen L. Petchey, Marco Plebani, Daniel C. Reuman, Björn C. Rall, Rebecca Stewart, Murray S.A. Thompson, Guy Woodward

*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceedingChapterpeer-review

108 Citations (Scopus)

Abstract

Environmental warming is predicted to rise dramatically over the next century, yet few studies have investigated its effects in natural, multi-species systems. We present data collated over an 8-year period from a catchment of geothermally heated streams in Iceland, which acts as a natural experiment on the effects of warming across different organisational levels and spatiotemporal scales. Body sizes and population biomasses of individual species responded strongly to temperature, with some providing evidence to support temperature-size rules. Macroinvertebrate and meiofaunal community composition also changed dramatically across the thermal gradient. Interactions within the warm streams in particular were characterised by food chains linking algae to snails to the apex predator, brown trout. These chains were missing from the colder systems, where snails were replaced by much smaller herbivores and invertebrate omnivores were the top predators. Trout were also subsidised by terrestrial invertebrate prey, which could have an effect analogous to apparent competition within the aquatic prey assemblage. Top-down effects by snails on diatoms were stronger in the warmer streams, which could account for a shallowing of mass-abundance slopes across the community. This may indicate reduced energy transfer efficiency from resources to consumers in the warmer systems and/or a change in predator-prey mass ratios. All the ecosystem process rates investigated increased with temperature, but with differing thermal sensitivities, with important implications for overall ecosystem functioning (e.g. creating potential imbalances in elemental fluxes). Ecosystem respiration rose rapidly with temperature, leading to increased heterotrophy. There were also indications that food web stability may be lower in the warmer streams.

Original languageEnglish
Title of host publicationAdvances in Ecological Research
PublisherAcademic Press Inc.
Pages81-176
Number of pages96
DOIs
Publication statusPublished - 2012

Publication series

NameAdvances in Ecological Research
Volume47
ISSN (Print)0065-2504

Bibliographical note

Funding Information:
We would like to thank two anonymous referees for their comments on an earlier draft of the paper, which helped to improve it considerably. E. J. O. G. is funded by NERC Grant NE/I009280/1 awarded to G. W., D. C. R. and O. P. D. E. P. and D. M. P. are funded by NERC Grants NE/F013124/1 and NE/D013305/1 awarded to G. W., respectively. W. F. C., J. P. B., J. M. H., J. R. J., and D. N. acknowledge the support of NSF Grants DEB-0949774 and 0949726. B. O. L. D. was supported by the Scottish Government Rural and Environment Science and Analytical Services (RESAS). L. N. H. was supported by Microsoft Research through its PhD Scholarship Programme. M. J. and A. L. were supported by the Swedish Research Council. M. P. is funded by the University of Zurich. D. C. R. was partly supported by NERC Grants NE/H020705/1, NE/I010963/1, and NE/I011889/1. M. S. A. T. was funded by the John Spedan Lewis Foundation.

Other keywords

  • Allometry
  • Arctic ecology
  • Climate change
  • Community ecology
  • Ecosystems ecology
  • Food webs
  • Global warming
  • Stream ecology

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