Environmental warming and biodiversity-ecosystem functioning in freshwater microcosms: partitioning the effects of species identity, richness and metabolism
Environmental warming and biodiversity-ecosystem functioning in freshwater microcosms: partitioning the effects of species identity, richness and metabolism
Predicting the effects of global warming on biodiversity–ecosystem functioning (B–EF) relationships is complicated by potential interactions among abiotic and biotic variables at multiple levels of organisation, including adaptation within regional species populations and changes in community composition and species richness. We investigated the capacity for assemblages of three freshwater invertebrate consumer species (Asellus aquaticus, Nemoura cinerea and Sericostoma personatum) from temperate (southern England) and boreal (northern Sweden) regions to respond to expected shifts in temperature and basal resources, and quantified rates of a key ecosystem process (leaf-litter decomposition). Predictions of assemblage metabolism, derived from allometric-body size and temperature scaling relationships, accounted for approximately 40% of the variance in decomposition rates. Assemblage species composition accounted for further variance, but species richness per se had no discernible effect. Regional differences were evident in rates of leaf decomposition across temperature and resource manipulations, and in terms of the processing efficiency of temperate and boreal consumers of the same species (i.e. after correcting for body size and metabolic capacity), suggesting that intraspecific variation among local populations could modulate B–EF effects. These differences have implications for extrapolating how environmental warming and other aspects of climate change (e.g. species range shifts) might affect important drivers of ecosystem functioning over large biogeographical scales
9780123850058
177-205
Perkins, Daniel M.
0f5f0f17-6657-403b-989c-d43242958467
McKie, Brendan G.
e79abb64-deab-4d90-bdb2-b7a8e86228bc
Malmqvist, Bjorn
a66bd0ab-6819-4e49-9e02-bd777b15a076
Gilmour, S.G.
984dbefa-893b-444d-9aa2-5953cd1c8b03
Reiss, Julia
55738099-44b4-4364-a050-d97904329773
Woodward, Guy
a1cceef5-20c3-4cc1-8564-dc0ca8e84c1b
2010
Perkins, Daniel M.
0f5f0f17-6657-403b-989c-d43242958467
McKie, Brendan G.
e79abb64-deab-4d90-bdb2-b7a8e86228bc
Malmqvist, Bjorn
a66bd0ab-6819-4e49-9e02-bd777b15a076
Gilmour, S.G.
984dbefa-893b-444d-9aa2-5953cd1c8b03
Reiss, Julia
55738099-44b4-4364-a050-d97904329773
Woodward, Guy
a1cceef5-20c3-4cc1-8564-dc0ca8e84c1b
Perkins, Daniel M., McKie, Brendan G., Malmqvist, Bjorn, Gilmour, S.G., Reiss, Julia and Woodward, Guy
(2010)
Environmental warming and biodiversity-ecosystem functioning in freshwater microcosms: partitioning the effects of species identity, richness and metabolism.
In,
Woodward, Guy
(ed.)
Integrative Ecology: From Molecules to Ecosystems.
(Advances in Ecological Research, 43)
Oxford, GB.
Elsevier Science, .
(doi:10.1016/S0065-2504(10)43005-6).
Record type:
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Abstract
Predicting the effects of global warming on biodiversity–ecosystem functioning (B–EF) relationships is complicated by potential interactions among abiotic and biotic variables at multiple levels of organisation, including adaptation within regional species populations and changes in community composition and species richness. We investigated the capacity for assemblages of three freshwater invertebrate consumer species (Asellus aquaticus, Nemoura cinerea and Sericostoma personatum) from temperate (southern England) and boreal (northern Sweden) regions to respond to expected shifts in temperature and basal resources, and quantified rates of a key ecosystem process (leaf-litter decomposition). Predictions of assemblage metabolism, derived from allometric-body size and temperature scaling relationships, accounted for approximately 40% of the variance in decomposition rates. Assemblage species composition accounted for further variance, but species richness per se had no discernible effect. Regional differences were evident in rates of leaf decomposition across temperature and resource manipulations, and in terms of the processing efficiency of temperate and boreal consumers of the same species (i.e. after correcting for body size and metabolic capacity), suggesting that intraspecific variation among local populations could modulate B–EF effects. These differences have implications for extrapolating how environmental warming and other aspects of climate change (e.g. species range shifts) might affect important drivers of ecosystem functioning over large biogeographical scales
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Published date: 2010
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Local EPrints ID: 174559
URI: http://eprints.soton.ac.uk/id/eprint/174559
ISBN: 9780123850058
PURE UUID: f54eeec1-07fb-4b13-9596-a12ff9084d46
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Date deposited: 15 Feb 2011 09:44
Last modified: 14 Mar 2024 02:34
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Author:
Daniel M. Perkins
Author:
Brendan G. McKie
Author:
Bjorn Malmqvist
Author:
S.G. Gilmour
Author:
Julia Reiss
Author:
Guy Woodward
Editor:
Guy Woodward
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