Dominance, Biomass and Extinction Resistance Determine the Consequences of Biodiversity Loss for Multiple Coastal Ecosystem Processes
Dominance, Biomass and Extinction Resistance Determine the Consequences of Biodiversity Loss for Multiple Coastal Ecosystem Processes
Key ecosystem processes such as carbon and nutrient cycling could be deteriorating as a result of biodiversity loss. However, currently we lack the ability to predict the consequences of realistic species loss on ecosystem processes. The aim of this study was to test whether species contributions to community biomass can be used as surrogate measures of their contribution to ecosystem processes. These were gross community productivity in a salt marsh plant assemblage and an intertidal macroalgae assemblage; community clearance of microalgae in sessile suspension feeding invertebrate assemblage; and nutrient uptake in an intertidal macroalgae assemblage. We conducted a series of biodiversity manipulations that represented realistic species extinction sequences in each of the three contrasting assemblages. Species were removed in a subtractive fashion so that biomass was allowed to vary with each species removal, and key ecosystem processes were measured at each stage of community disassembly. The functional contribution of species was directly proportional to their contribution to community biomass in a 1:1 ratio, a relationship that was consistent across three contrasting marine ecosystems and three ecosystem processes. This suggests that the biomass contributed by a species to an assemblage can be used to approximately predict the proportional decline in an ecosystem process when that species is lost. Such predictions represent “worst case scenarios” because, over time, extinction resilient species can offset the loss of biomass associated with the extinction of competitors. We also modelled a “best case scenario” that accounts for compensatory responses by the extant species with the highest per capita contribution to ecosystem processes. These worst and best case scenarios could be used to predict the minimum and maximum species required to sustain threshold values of ecosystem processes in the future.
e28362
Davies, Thomas W.
6f296068-0c5c-422a-8cee-ed11e71184fd
Jenkins, Stuart R.
63f5521f-fe3a-4dae-b582-4a6a8d3aa936
Kingham, Rachel
4be508f5-7080-46da-8f72-b8a24043cfd3
Kenworthy, Joseph
275fb800-f2cf-453d-9a25-9362b1653f19
Hawkins, Stephen J.
758fe1c1-30cd-4ed1-bb65-2471dc7c11fa
Hiddink, Jan G.
10e4b1e4-7a7a-4027-8489-4de1916e9504
2011
Davies, Thomas W.
6f296068-0c5c-422a-8cee-ed11e71184fd
Jenkins, Stuart R.
63f5521f-fe3a-4dae-b582-4a6a8d3aa936
Kingham, Rachel
4be508f5-7080-46da-8f72-b8a24043cfd3
Kenworthy, Joseph
275fb800-f2cf-453d-9a25-9362b1653f19
Hawkins, Stephen J.
758fe1c1-30cd-4ed1-bb65-2471dc7c11fa
Hiddink, Jan G.
10e4b1e4-7a7a-4027-8489-4de1916e9504
Davies, Thomas W., Jenkins, Stuart R., Kingham, Rachel, Kenworthy, Joseph, Hawkins, Stephen J. and Hiddink, Jan G.
(2011)
Dominance, Biomass and Extinction Resistance Determine the Consequences of Biodiversity Loss for Multiple Coastal Ecosystem Processes.
PLoS ONE, 6 (12), .
(doi:10.1371/journal.pone.0028362).
Abstract
Key ecosystem processes such as carbon and nutrient cycling could be deteriorating as a result of biodiversity loss. However, currently we lack the ability to predict the consequences of realistic species loss on ecosystem processes. The aim of this study was to test whether species contributions to community biomass can be used as surrogate measures of their contribution to ecosystem processes. These were gross community productivity in a salt marsh plant assemblage and an intertidal macroalgae assemblage; community clearance of microalgae in sessile suspension feeding invertebrate assemblage; and nutrient uptake in an intertidal macroalgae assemblage. We conducted a series of biodiversity manipulations that represented realistic species extinction sequences in each of the three contrasting assemblages. Species were removed in a subtractive fashion so that biomass was allowed to vary with each species removal, and key ecosystem processes were measured at each stage of community disassembly. The functional contribution of species was directly proportional to their contribution to community biomass in a 1:1 ratio, a relationship that was consistent across three contrasting marine ecosystems and three ecosystem processes. This suggests that the biomass contributed by a species to an assemblage can be used to approximately predict the proportional decline in an ecosystem process when that species is lost. Such predictions represent “worst case scenarios” because, over time, extinction resilient species can offset the loss of biomass associated with the extinction of competitors. We also modelled a “best case scenario” that accounts for compensatory responses by the extant species with the highest per capita contribution to ecosystem processes. These worst and best case scenarios could be used to predict the minimum and maximum species required to sustain threshold values of ecosystem processes in the future.
Text
Davies_etal_2011_PlosOne.pdf
- Version of Record
More information
Published date: 2011
Organisations:
Ocean Biochemistry & Ecosystems
Identifiers
Local EPrints ID: 205655
URI: http://eprints.soton.ac.uk/id/eprint/205655
ISSN: 1932-6203
PURE UUID: 0690d74c-5eb7-485c-9567-3c28982eefc7
Catalogue record
Date deposited: 09 Dec 2011 10:27
Last modified: 14 Mar 2024 04:34
Export record
Altmetrics
Contributors
Author:
Thomas W. Davies
Author:
Stuart R. Jenkins
Author:
Rachel Kingham
Author:
Joseph Kenworthy
Author:
Jan G. Hiddink
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics