Dominant oceanic bacteria secure phosphate using a large extracellular buffer
Dominant oceanic bacteria secure phosphate using a large extracellular buffer
The ubiquitous SAR11 and Prochlorococcus bacteria manage to maintain a sufficient supply of phosphate in phosphate-poor surface waters of the North Atlantic subtropical gyre. Furthermore, it seems that their phosphate uptake may counter-intuitively be lower in more productive tropical waters, as if their cellular demand for phosphate decreases there. By flow sorting 33P-phosphate-pulsed 32P-phosphate-chased cells, we demonstrate that both Prochlorococcus and SAR11 cells exploit an extracellular buffer of labile phosphate up to 5–40 times larger than the amount of phosphate required to replicate their chromosomes. Mathematical modelling is shown to support this conclusion. The fuller the buffer the slower the cellular uptake of phosphate, to the point that in phosphate-replete tropical waters, cells can saturate their buffer and their phosphate uptake becomes marginal. Hence, buffer stocking is a generic, growth-securing adaptation for SAR11 and Prochlorococcus bacteria, which lack internal reserves to reduce their dependency on bioavailable ambient phosphate.
7878
Zubkov, M.V.
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Martin, A.P.
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Hartmann, M.
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Grob, C.
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Scanlan, D.J.
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22 July 2015
Zubkov, M.V.
b1dfb3a0-bcff-430c-9031-358a22b50743
Martin, A.P.
9d0d480d-9b3c-44c2-aafe-bb980ed98a6d
Hartmann, M.
5b175765-fde7-40dc-bcd6-83248285ef86
Grob, C.
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Scanlan, D.J.
490e6b20-efac-4150-9f3a-418ac8658c00
Zubkov, M.V., Martin, A.P., Hartmann, M., Grob, C. and Scanlan, D.J.
(2015)
Dominant oceanic bacteria secure phosphate using a large extracellular buffer.
Nature Communications, 6, .
Abstract
The ubiquitous SAR11 and Prochlorococcus bacteria manage to maintain a sufficient supply of phosphate in phosphate-poor surface waters of the North Atlantic subtropical gyre. Furthermore, it seems that their phosphate uptake may counter-intuitively be lower in more productive tropical waters, as if their cellular demand for phosphate decreases there. By flow sorting 33P-phosphate-pulsed 32P-phosphate-chased cells, we demonstrate that both Prochlorococcus and SAR11 cells exploit an extracellular buffer of labile phosphate up to 5–40 times larger than the amount of phosphate required to replicate their chromosomes. Mathematical modelling is shown to support this conclusion. The fuller the buffer the slower the cellular uptake of phosphate, to the point that in phosphate-replete tropical waters, cells can saturate their buffer and their phosphate uptake becomes marginal. Hence, buffer stocking is a generic, growth-securing adaptation for SAR11 and Prochlorococcus bacteria, which lack internal reserves to reduce their dependency on bioavailable ambient phosphate.
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NCOMMS-15-00997A_R2-1_for library.pdf
- Accepted Manuscript
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NCOMMS-15-00997A_Suppl_R2.pdf
- Accepted Manuscript
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ncomms8878.pdf
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Accepted/In Press date: June 2015
Published date: 22 July 2015
Organisations:
Marine Biogeochemistry
Identifiers
Local EPrints ID: 378220
URI: http://eprints.soton.ac.uk/id/eprint/378220
PURE UUID: 94be65ab-0d6b-443f-8f08-7232645629c0
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Date deposited: 22 Jun 2015 09:20
Last modified: 14 Mar 2024 20:19
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Author:
M.V. Zubkov
Author:
A.P. Martin
Author:
M. Hartmann
Author:
C. Grob
Author:
D.J. Scanlan
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