Alkenone isotopes show evidence of active carbon concentrating mechanisms in coccolithophores as aqueous carbon dioxide concentrations fall below 7 μmol L −1
Coccolithophores and other haptophyte algae acquire the carbon required for metabolic processes from the water in which they live. Whether carbon is actively moved across the cell membrane via a carbon concentrating mechanism, or passively through diffusion, is important for haptophyte biochemistry....
| Published in: | Biogeosciences |
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| Main Author: | |
| Format: | Article in Journal/Newspaper |
| Language: | unknown |
| Published: |
2021
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| Online Access: | https://oro.open.ac.uk/72494/ https://oro.open.ac.uk/72494/1/bg-2020-356-discussion-paper.pdf https://oro.open.ac.uk/72494/8/72494.pdf https://doi.org/10.5194/bg-18-1149-2021 |
| Summary: | Coccolithophores and other haptophyte algae acquire the carbon required for metabolic processes from the water in which they live. Whether carbon is actively moved across the cell membrane via a carbon concentrating mechanism, or passively through diffusion, is important for haptophyte biochemistry. The possible utilisation of carbon concentrating mechanisms also has the potential to over-print one proxy method by which ancient atmospheric CO 2 is reconstructed using alkenone isotopes. Here I show that carbon concentrating mechanisms are likely used when aqueous carbon dioxide concentrations are below 7 μmol L −1 . I use published alkenone based CO 2 reconstructions from multiple sites over the Pleistocene, which allows comparison to be made with ice core CO 2 records. Interrogating these records reveal that the relationship between proxy- and ice core- CO 2 breaks down when local aqueous CO 2 concentration falls below 7 μmol L −1 . The recognition of this threshold explains why many alkenone based CO 2 records fail to accurately replicate ice core CO 2 records, and suggests the alkenone proxy is likely robust for much of the Cenozoic when this threshold was unlikely to be reached in much of the global ocean. |
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