Impact of biodiversity-climate futures on primary production and metabolism in a model benthic estuarine system
Impact of biodiversity-climate futures on primary production and metabolism in a model benthic estuarine system
Background
Understanding the effects of anthropogenically-driven changes in global temperature, atmospheric carbon dioxide and biodiversity on the functionality of marine ecosystems is crucial for predicting and managing the associated impacts. Coastal ecosystems are important sources of carbon (primary production) to shelf waters and play a vital role in global nutrient cycling. These systems are especially vulnerable to the effects of human activities and will be the first areas impacted by rising sea levels. Within these coastal ecosystems, microalgal assemblages (microphytobenthos: MPB) are vital for autochthonous carbon fixation. The level of in situ production by MPB mediates the net carbon cycling of transitional ecosystems between net heterotrophic or autotrophic metabolism. In this study, we examine the interactive effects of elevated atmospheric CO2 concentrations (370, 600, and 1000 ppmv), temperature (6°C, 12°C, and 18°C) and invertebrate biodiversity on MPB biomass in experimental systems. We assembled communities of three common grazing invertebrates (Hydrobia ulvae, Corophium volutator and Hediste diversicolor) in monoculture and in all possible multispecies combinations. This experimental design specifically addresses interactions between the selected climate change variables and any ecological consequences caused by changes in species composition or richness.
Results
The effects of elevated CO2 concentration, temperature and invertebrate diversity were not additive, rather they interacted to determine MPB biomass, and overall this effect was negative. Diversity effects were underpinned by strong species composition effects, illustrating the importance of individual species identity.
Conclusions
Overall, our findings suggest that in natural systems, the complex interactions between changing environmental conditions and any associated changes in invertebrate assemblage structure are likely to reduce MPB biomass. Furthermore, these effects would be sufficient to affect the net metabolic balance of the coastal ecosystem, with important implications for system ecology and sustainable exploitation.
Hicks, Natalie
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Bulling, Mark T.
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Solan, Martin
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Raffaelli, Dave
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White, Piran C. L.
f5623b1d-deab-4e08-8f44-ca733a43d569
Paterson, David M.
cb3a1995-cd31-46b5-970c-71d0f571d63b
2011
Hicks, Natalie
34ffb8be-c88c-4539-8c56-8d75bdab91ea
Bulling, Mark T.
0a9186c7-5457-46f4-8c83-1b26a571e402
Solan, Martin
c28b294a-1db6-4677-8eab-bd8d6221fecf
Raffaelli, Dave
b6fc5f11-fb9a-420a-bcd3-7d5d7c6f8260
White, Piran C. L.
f5623b1d-deab-4e08-8f44-ca733a43d569
Paterson, David M.
cb3a1995-cd31-46b5-970c-71d0f571d63b
Hicks, Natalie, Bulling, Mark T., Solan, Martin, Raffaelli, Dave, White, Piran C. L. and Paterson, David M.
(2011)
Impact of biodiversity-climate futures on primary production and metabolism in a model benthic estuarine system.
BMC Ecology, 11, [7].
(doi:10.1186/1472-6785-11-7).
Abstract
Background
Understanding the effects of anthropogenically-driven changes in global temperature, atmospheric carbon dioxide and biodiversity on the functionality of marine ecosystems is crucial for predicting and managing the associated impacts. Coastal ecosystems are important sources of carbon (primary production) to shelf waters and play a vital role in global nutrient cycling. These systems are especially vulnerable to the effects of human activities and will be the first areas impacted by rising sea levels. Within these coastal ecosystems, microalgal assemblages (microphytobenthos: MPB) are vital for autochthonous carbon fixation. The level of in situ production by MPB mediates the net carbon cycling of transitional ecosystems between net heterotrophic or autotrophic metabolism. In this study, we examine the interactive effects of elevated atmospheric CO2 concentrations (370, 600, and 1000 ppmv), temperature (6°C, 12°C, and 18°C) and invertebrate biodiversity on MPB biomass in experimental systems. We assembled communities of three common grazing invertebrates (Hydrobia ulvae, Corophium volutator and Hediste diversicolor) in monoculture and in all possible multispecies combinations. This experimental design specifically addresses interactions between the selected climate change variables and any ecological consequences caused by changes in species composition or richness.
Results
The effects of elevated CO2 concentration, temperature and invertebrate diversity were not additive, rather they interacted to determine MPB biomass, and overall this effect was negative. Diversity effects were underpinned by strong species composition effects, illustrating the importance of individual species identity.
Conclusions
Overall, our findings suggest that in natural systems, the complex interactions between changing environmental conditions and any associated changes in invertebrate assemblage structure are likely to reduce MPB biomass. Furthermore, these effects would be sufficient to affect the net metabolic balance of the coastal ecosystem, with important implications for system ecology and sustainable exploitation.
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1472-6785-11-7
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Published date: 2011
Identifiers
Local EPrints ID: 455589
URI: http://eprints.soton.ac.uk/id/eprint/455589
ISSN: 1472-6785
PURE UUID: a97b4130-76da-4f40-a9d7-e0113ba4fe4d
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Date deposited: 28 Mar 2022 16:41
Last modified: 17 Mar 2024 03:15
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Contributors
Author:
Natalie Hicks
Author:
Mark T. Bulling
Author:
Dave Raffaelli
Author:
Piran C. L. White
Author:
David M. Paterson
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