Unravelling the environmental drivers of deep-sea nematode biodiversity and its relation with carbon mineralisation along a longitudinal primary productivity gradient
Unravelling the environmental drivers of deep-sea nematode biodiversity and its relation with carbon mineralisation along a longitudinal primary productivity gradient
Alongside a primary productivity gradient between the Galicia Bank region in the Northeast Atlantic and the more oligotrophic eastern Mediterranean Basin, we investigated the bathymetric (1200–3000 m) and longitudinal variation in several measures for nematode taxon (Shannon–Wiener genus diversity, expected genus richness and generic evenness) and functional diversity (trophic diversity, diversity of life history strategies, biomass diversity and phylogenetic diversity). Our goals were to establish the form of the relation between diversity and productivity (measured as seafloor particulate organic carbon or POC flux), and to verify the positive and negative effect of sediment particle size diversity (SED) and the seasonality in POC flux (SVI), respectively, on diversity, as observed for other oceanographic regions and taxa. In addition, we hypothesised that higher taxon diversity is associated with higher functional diversity, which in turn stimulates nematode carbon mineralisation rates (determined from biomass-dependent respiration estimates). Taxon diversity related positively to seafloor POC flux. Phylogenetic diversity (measured as average taxonomic distinctness) was affected negatively by the magnitude and variability in POC flux, and positively by SED. The latter also showed an inverse relation with trophic diversity. Accounting for differences in total biomass between samples, we observed a positive linear relation between taxon diversity and carbon mineralisation in nematode communities. We could, however, not identify the potential mechanism through which taxon diversity may promote this ecosystem function since none of the functional diversity indices related to both diversity and nematode respiration. The present results suggest potential effects of climate change on deep-sea ecosystem functioning, but further also emphasise the need for a better understanding of nematode functions and their response to evolutionary processes.
3127-3143
Pape, E.
54cfd4bd-9e20-4f66-bf0f-b4bb4e47f7aa
Bezerra, T.N.
97a977e2-560b-4671-860d-163bd569f4d4
Jones, D.O.B.
44fc07b3-5fb7-4bf5-9cec-78c78022613a
Vanreusel, A.
086a3d54-88cb-4152-b33a-a0c710b2cd3b
8 May 2013
Pape, E.
54cfd4bd-9e20-4f66-bf0f-b4bb4e47f7aa
Bezerra, T.N.
97a977e2-560b-4671-860d-163bd569f4d4
Jones, D.O.B.
44fc07b3-5fb7-4bf5-9cec-78c78022613a
Vanreusel, A.
086a3d54-88cb-4152-b33a-a0c710b2cd3b
Pape, E., Bezerra, T.N., Jones, D.O.B. and Vanreusel, A.
(2013)
Unravelling the environmental drivers of deep-sea nematode biodiversity and its relation with carbon mineralisation along a longitudinal primary productivity gradient.
Biogeosciences, 10 (5), .
(doi:10.5194/bg-10-3127-2013).
Abstract
Alongside a primary productivity gradient between the Galicia Bank region in the Northeast Atlantic and the more oligotrophic eastern Mediterranean Basin, we investigated the bathymetric (1200–3000 m) and longitudinal variation in several measures for nematode taxon (Shannon–Wiener genus diversity, expected genus richness and generic evenness) and functional diversity (trophic diversity, diversity of life history strategies, biomass diversity and phylogenetic diversity). Our goals were to establish the form of the relation between diversity and productivity (measured as seafloor particulate organic carbon or POC flux), and to verify the positive and negative effect of sediment particle size diversity (SED) and the seasonality in POC flux (SVI), respectively, on diversity, as observed for other oceanographic regions and taxa. In addition, we hypothesised that higher taxon diversity is associated with higher functional diversity, which in turn stimulates nematode carbon mineralisation rates (determined from biomass-dependent respiration estimates). Taxon diversity related positively to seafloor POC flux. Phylogenetic diversity (measured as average taxonomic distinctness) was affected negatively by the magnitude and variability in POC flux, and positively by SED. The latter also showed an inverse relation with trophic diversity. Accounting for differences in total biomass between samples, we observed a positive linear relation between taxon diversity and carbon mineralisation in nematode communities. We could, however, not identify the potential mechanism through which taxon diversity may promote this ecosystem function since none of the functional diversity indices related to both diversity and nematode respiration. The present results suggest potential effects of climate change on deep-sea ecosystem functioning, but further also emphasise the need for a better understanding of nematode functions and their response to evolutionary processes.
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Published date: 8 May 2013
Organisations:
Marine Biogeochemistry
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Local EPrints ID: 356545
URI: http://eprints.soton.ac.uk/id/eprint/356545
ISSN: 1726-4170
PURE UUID: 8b51ad0f-3067-468e-ae0e-2ba034eca2f4
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Date deposited: 06 Sep 2013 12:45
Last modified: 14 Mar 2024 14:49
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Author:
E. Pape
Author:
T.N. Bezerra
Author:
D.O.B. Jones
Author:
A. Vanreusel
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