Magnetotactic bacterial abundance in pelagic marine environments is limited by organic carbon flux and availability of dissolved iron
Magnetotactic bacterial abundance in pelagic marine environments is limited by organic carbon flux and availability of dissolved iron
Magnetotactic bacteria intracellularly biomineralize magnetite of an ideal grain size for recording palaeomagnetic signals. However, bacterial magnetite has only been reported in a few pre-Quaternary records because progressive burial into anoxic diagenetic environments causes its dissolution. Deep-sea carbonate sequences provide optimal environments for preserving bacterial magnetite due to low rates of organic carbon burial and expanded pore-water redox zonations. Such sequences often do not become anoxic for tens to hundreds of metres below the seafloor. Nevertheless, the biogeochemical factors that control magnetotactic bacterial populations in such settings are not well known. We document the preservation of bacterial magnetite, which dominates the palaeomagnetic signal throughout Eocene pelagic carbonates from the southern Kerguelen Plateau, Southern Ocean. We provide evidence that iron fertilization, associated with increased aeolian dust flux, resulted in surface water eutrophication in the late Eocene that controlled bacterial magnetite abundance via export of organic carbon to the seafloor. Increased flux of aeolian iron-bearing phases also delivered iron to the seafloor, some of which became bioavailable through iron reduction. Our results suggest that magnetotactic bacterial populations in pelagic settings depend crucially on particulate iron and organic carbon delivery to the seafloor.
Magnetotactic bacteria, Magnetofossils, Magnetite, Productivity, Iron, Organic carbon
441-452
Roberts, Andrew P.
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Florindo, Fabio
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Villa, Giuliana
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Chang, Liao
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Jovane, Luigi
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Bohaty, Steven M.
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Larrasoaña, Juan C.
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Heslop, David
f32aae36-7f51-40e1-bf7d-54a561369a8d
Fitz Gerald, John D.
d3ce84a5-666c-4acc-821b-d3508b3a1af9
15 October 2011
Roberts, Andrew P.
4f062491-5408-4edb-8dd1-140c6a42e93f
Florindo, Fabio
5953170b-79f7-431e-9e08-824a47e0fbd5
Villa, Giuliana
5f30b6b7-f12e-4ebd-b4e4-12dea37c45ee
Chang, Liao
83123f49-dd71-43a9-a0b1-d80777231b44
Jovane, Luigi
7e165ffb-8e06-4ac1-9c47-d3edf3e0ddd8
Bohaty, Steven M.
af9dbe78-8b9f-44f2-ba1d-20795837d2d1
Larrasoaña, Juan C.
6bf2e75f-54a1-42b8-96e0-b80d2462de2c
Heslop, David
f32aae36-7f51-40e1-bf7d-54a561369a8d
Fitz Gerald, John D.
d3ce84a5-666c-4acc-821b-d3508b3a1af9
Roberts, Andrew P., Florindo, Fabio, Villa, Giuliana, Chang, Liao, Jovane, Luigi, Bohaty, Steven M., Larrasoaña, Juan C., Heslop, David and Fitz Gerald, John D.
(2011)
Magnetotactic bacterial abundance in pelagic marine environments is limited by organic carbon flux and availability of dissolved iron.
Earth and Planetary Science Letters, 310 (3-4), .
(doi:10.1016/j.epsl.2011.08.011).
Abstract
Magnetotactic bacteria intracellularly biomineralize magnetite of an ideal grain size for recording palaeomagnetic signals. However, bacterial magnetite has only been reported in a few pre-Quaternary records because progressive burial into anoxic diagenetic environments causes its dissolution. Deep-sea carbonate sequences provide optimal environments for preserving bacterial magnetite due to low rates of organic carbon burial and expanded pore-water redox zonations. Such sequences often do not become anoxic for tens to hundreds of metres below the seafloor. Nevertheless, the biogeochemical factors that control magnetotactic bacterial populations in such settings are not well known. We document the preservation of bacterial magnetite, which dominates the palaeomagnetic signal throughout Eocene pelagic carbonates from the southern Kerguelen Plateau, Southern Ocean. We provide evidence that iron fertilization, associated with increased aeolian dust flux, resulted in surface water eutrophication in the late Eocene that controlled bacterial magnetite abundance via export of organic carbon to the seafloor. Increased flux of aeolian iron-bearing phases also delivered iron to the seafloor, some of which became bioavailable through iron reduction. Our results suggest that magnetotactic bacterial populations in pelagic settings depend crucially on particulate iron and organic carbon delivery to the seafloor.
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More information
Published date: 15 October 2011
Keywords:
Magnetotactic bacteria, Magnetofossils, Magnetite, Productivity, Iron, Organic carbon
Organisations:
Paleooceanography & Palaeoclimate
Identifiers
Local EPrints ID: 205477
URI: http://eprints.soton.ac.uk/id/eprint/205477
ISSN: 0012-821X
PURE UUID: 0d4bf729-28d4-4ef4-9cf3-f755c2bee9d4
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Date deposited: 08 Dec 2011 09:47
Last modified: 15 Mar 2024 03:27
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Contributors
Author:
Andrew P. Roberts
Author:
Fabio Florindo
Author:
Giuliana Villa
Author:
Liao Chang
Author:
Luigi Jovane
Author:
Juan C. Larrasoaña
Author:
David Heslop
Author:
John D. Fitz Gerald
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