Coccolithophore responses to environmental variability in the South China Sea: species composition and calcite content
Coccolithophore responses to environmental variability in the South China Sea: species composition and calcite content
Coccolithophore contributions to the global marine carbon cycle are regulated by the calcite content of their scales (coccoliths) and the relative cellular levels of photosynthesis and calcification rates. All three of these factors vary between coccolithophore species and with response to the growth environment. Here, water samples were collected in the northern basin of the South China Sea (SCS) during summer 2014 in order to examine how environmental variability influenced species composition and cellular levels of calcite content. Average coccolithophore abundance and their calcite concentration in the water column were 11.82 cells?mL?1 and 1508.3?pg C?mL?1, respectively, during the cruise. Water samples can be divided into three floral groups according to their distinct coccolithophore communities. The vertical structure of the coccolithophore community in the water column was controlled by the trophic conditions, which were regulated by mesoscale eddies across the SCS basin. The evaluation of coccolithophore-based calcite in the surface ocean also showed that three key species in the SCS (Emiliania huxleyi, Gephyrocapsa oceanica, Florisphaera profunda) and other larger, numerically rare species made almost equal contributions to total coccolith-based calcite in the water column. For Emiliania huxleyi biometry measurements, coccolith size positively correlated with nutrients (nitrate, phosphate), and it is suggested that coccolith length is influenced by light and nutrients through the regulation of growth rates. Larger-sized coccoliths were also linked statistically to low pH and calcite saturation states; however, it is not a simple cause and effect relationship, as carbonate chemistry was strongly co-correlated with the other key environmental factors (nutrients, light).
4843-4861
Jin, Xiaobo
28aad823-1a6f-498c-b2b9-653035c4bac8
Liu, Chuanlian
74d2adfd-8a4f-4dc6-8fa1-c71209a8b501
Poulton, Alex J.
14bf64a7-d617-4913-b882-e8495543e717
Dai, Minhan
45b39f60-fc8a-47cf-9318-258374f389fc
Guo, Xianghui
83168543-f619-426e-b7d2-f9528b7340a5
29 August 2016
Jin, Xiaobo
28aad823-1a6f-498c-b2b9-653035c4bac8
Liu, Chuanlian
74d2adfd-8a4f-4dc6-8fa1-c71209a8b501
Poulton, Alex J.
14bf64a7-d617-4913-b882-e8495543e717
Dai, Minhan
45b39f60-fc8a-47cf-9318-258374f389fc
Guo, Xianghui
83168543-f619-426e-b7d2-f9528b7340a5
Jin, Xiaobo, Liu, Chuanlian, Poulton, Alex J., Dai, Minhan and Guo, Xianghui
(2016)
Coccolithophore responses to environmental variability in the South China Sea: species composition and calcite content.
Biogeosciences, 13 (16), .
(doi:10.5194/bg-13-4843-2016).
Abstract
Coccolithophore contributions to the global marine carbon cycle are regulated by the calcite content of their scales (coccoliths) and the relative cellular levels of photosynthesis and calcification rates. All three of these factors vary between coccolithophore species and with response to the growth environment. Here, water samples were collected in the northern basin of the South China Sea (SCS) during summer 2014 in order to examine how environmental variability influenced species composition and cellular levels of calcite content. Average coccolithophore abundance and their calcite concentration in the water column were 11.82 cells?mL?1 and 1508.3?pg C?mL?1, respectively, during the cruise. Water samples can be divided into three floral groups according to their distinct coccolithophore communities. The vertical structure of the coccolithophore community in the water column was controlled by the trophic conditions, which were regulated by mesoscale eddies across the SCS basin. The evaluation of coccolithophore-based calcite in the surface ocean also showed that three key species in the SCS (Emiliania huxleyi, Gephyrocapsa oceanica, Florisphaera profunda) and other larger, numerically rare species made almost equal contributions to total coccolith-based calcite in the water column. For Emiliania huxleyi biometry measurements, coccolith size positively correlated with nutrients (nitrate, phosphate), and it is suggested that coccolith length is influenced by light and nutrients through the regulation of growth rates. Larger-sized coccoliths were also linked statistically to low pH and calcite saturation states; however, it is not a simple cause and effect relationship, as carbonate chemistry was strongly co-correlated with the other key environmental factors (nutrients, light).
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Accepted/In Press date: 1 August 2016
e-pub ahead of print date: 29 August 2016
Published date: 29 August 2016
Organisations:
Ocean Biochemistry & Ecosystems
Identifiers
Local EPrints ID: 402313
URI: http://eprints.soton.ac.uk/id/eprint/402313
ISSN: 1726-4170
PURE UUID: 8e08291c-1ebb-45a9-ad77-d6af752fabd8
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Date deposited: 03 Nov 2016 13:16
Last modified: 15 Mar 2024 03:13
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Author:
Xiaobo Jin
Author:
Chuanlian Liu
Author:
Alex J. Poulton
Author:
Minhan Dai
Author:
Xianghui Guo
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