Impact of nitrate on bacterial structure and function in injection-water biofilms.
Impact of nitrate on bacterial structure and function in injection-water biofilms.
We studied the impact of NO3– on the bacterial community composition, diversity, and function in in situ industrial, anaerobic biofilms by combining microsensor profiling, 15N and 35S labeling, and 16S rRNA gene-based fingerprinting. Biofilms were grown on carbon steel coupons within a system designed to treat seawater for injection into an oil field for pressurized oil recovery. NO3– was added to the seawater in an attempt to prevent bacterial H2S generation and microbially influenced corrosion in the field. Microprofiling of nitrogen compounds and redox potential inside the biofilms showed that the zone of highest metabolic activity was located close to the metal surface, correlating with a high bacterial abundance in this zone. Upon addition, NO3– was mainly reduced to NO2–. In biofilms grown in the absence of NO3–, redox potentials of <–450 mV at the metal surface suggested the release of Fe2+. NO3– addition to previously untreated biofilms induced a decline (65%) in bacterial species richness, with Methylophaga- and Colwellia-related sequences having the highest number of obtained clones in the clone library. In contrast, no changes in community composition and potential NO3– reduction occurred upon subsequent withdrawal of NO3–. Active sulfate reduction was below detection levels in all biofilms, but S isotope fractionation analysis of sulfide deposits suggested that it must have occurred either at low rates or episodically. Scanning electron microscopy revealed that pitting corrosion occurred on all coupons, independent of the treatment. However, uniform corrosion was clearly mitigated by NO3– addition.
2841-2851
Schwermer, Carsten U.
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Lavik, Gaute
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Abed, Raeid M.M.
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Dunsmore, Braden
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Ferdelman, Timothy G.
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Stoodley, Paul
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Gieseke, Armin
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de Beer, Dirk
cb8d8130-86eb-4ecb-9496-41543e1fe536
May 2008
Schwermer, Carsten U.
b4affdc8-2b07-4c11-9698-c1280243e498
Lavik, Gaute
29014780-d97c-41c0-8b59-a230bdfcdb37
Abed, Raeid M.M.
56908498-83e8-440b-9c26-c0eb022320f1
Dunsmore, Braden
ed3c4d23-f98d-4ffe-a948-b710e1a1d4b6
Ferdelman, Timothy G.
608e7e72-65a9-4df1-9333-0dd5cfbe0cbe
Stoodley, Paul
08614665-92a9-4466-806e-20c6daeb483f
Gieseke, Armin
1b9305ea-9172-4681-8667-9f638aac41f2
de Beer, Dirk
cb8d8130-86eb-4ecb-9496-41543e1fe536
Schwermer, Carsten U., Lavik, Gaute, Abed, Raeid M.M., Dunsmore, Braden, Ferdelman, Timothy G., Stoodley, Paul, Gieseke, Armin and de Beer, Dirk
(2008)
Impact of nitrate on bacterial structure and function in injection-water biofilms.
Applied and Environmental Microbiology, 74 (9), .
(doi:10.1128/AEM.02027-07).
Abstract
We studied the impact of NO3– on the bacterial community composition, diversity, and function in in situ industrial, anaerobic biofilms by combining microsensor profiling, 15N and 35S labeling, and 16S rRNA gene-based fingerprinting. Biofilms were grown on carbon steel coupons within a system designed to treat seawater for injection into an oil field for pressurized oil recovery. NO3– was added to the seawater in an attempt to prevent bacterial H2S generation and microbially influenced corrosion in the field. Microprofiling of nitrogen compounds and redox potential inside the biofilms showed that the zone of highest metabolic activity was located close to the metal surface, correlating with a high bacterial abundance in this zone. Upon addition, NO3– was mainly reduced to NO2–. In biofilms grown in the absence of NO3–, redox potentials of <–450 mV at the metal surface suggested the release of Fe2+. NO3– addition to previously untreated biofilms induced a decline (65%) in bacterial species richness, with Methylophaga- and Colwellia-related sequences having the highest number of obtained clones in the clone library. In contrast, no changes in community composition and potential NO3– reduction occurred upon subsequent withdrawal of NO3–. Active sulfate reduction was below detection levels in all biofilms, but S isotope fractionation analysis of sulfide deposits suggested that it must have occurred either at low rates or episodically. Scanning electron microscopy revealed that pitting corrosion occurred on all coupons, independent of the treatment. However, uniform corrosion was clearly mitigated by NO3– addition.
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Published date: May 2008
Organisations:
Engineering Mats & Surface Engineerg Gp
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Local EPrints ID: 155203
URI: http://eprints.soton.ac.uk/id/eprint/155203
ISSN: 0099-2240
PURE UUID: 9e3bbbed-b094-4a27-99a8-23ec1669eb98
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Date deposited: 27 May 2010 10:28
Last modified: 14 Mar 2024 02:55
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Author:
Carsten U. Schwermer
Author:
Gaute Lavik
Author:
Raeid M.M. Abed
Author:
Braden Dunsmore
Author:
Timothy G. Ferdelman
Author:
Armin Gieseke
Author:
Dirk de Beer
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