Revising the nitrogen cycle in the Peruvian oxygen minimum zone
Revising the nitrogen cycle in the Peruvian oxygen minimum zone
The oxygen minimum zone (OMZ) of the Eastern Tropical South Pacific (ETSP) is 1 of the 3 major regions in the world where oceanic nitrogen is lost in the pelagic realm. The recent identification of anammox, instead of denitrification, as the likely prevalent pathway for nitrogen loss in this OMZ raises strong questions about our understanding of nitrogen cycling and organic matter remineralization in these waters. Without detectable denitrification, it is unclear how NH(4)(+) is remineralized from organic matter and sustains anammox or how secondary NO(2)(-) maxima arise within the OMZ. Here we show that in the ETSP-OMZ, anammox obtains 67% or more of NO(2)(-) from nitrate reduction, and 33% or less from aerobic ammonia oxidation, based on stable-isotope pairing experiments corroborated by functional gene expression analyses. Dissimilatory nitrate reduction to ammonium was detected in an open-ocean setting. It occurred throughout the OMZ and could satisfy a substantial part of the NH(4)(+) requirement for anammox. The remaining NH(4)(+) came from remineralization via nitrate reduction and probably from microaerobic respiration. Altogether, deep-sea NO(3)(-) accounted for only approximately 50% of the nitrogen loss in the ETSP, rather than 100% as commonly assumed. Because oceanic OMZs seem to be expanding because of global climate change, it is increasingly imperative to incorporate the correct nitrogen-loss pathways in global biogeochemical models to predict more accurately how the nitrogen cycle in our future ocean may respond.
anammox, dissimilatory nitrate reduction to ammonium, nitrogen loss, functional gene expression, remineralization
4752-4757
Lam, Phyllis
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Lavik, Gaute
29014780-d97c-41c0-8b59-a230bdfcdb37
Jensen, Marlene M.
23ff1ce5-4644-4816-be78-4762c15266e0
van de Vossenberg, Jack
f971907e-7212-4f23-a9c6-931919f9d819
Schmid, Markus
63a9df7e-1168-4825-b341-198aae582104
Woebken, Dagmar
d49f5fc1-c7c6-4a5f-b100-649124387bed
Gutierrez, Dimitri
5791fcaa-efc6-4bce-ab14-96af54edc31a
Amann, Rudolf
315b5cfc-deaa-4283-baf4-7fb655fe5730
Jetten, Mike S.M.
4fffe0a6-b5db-495b-8bae-7d72c64237e0
Kuypers, Marcel M.M.
b6288cfb-42bc-469c-93fe-8fbb40d97bec
24 March 2009
Lam, Phyllis
996aef80-a15d-4827-aed8-1b97b378f6ad
Lavik, Gaute
29014780-d97c-41c0-8b59-a230bdfcdb37
Jensen, Marlene M.
23ff1ce5-4644-4816-be78-4762c15266e0
van de Vossenberg, Jack
f971907e-7212-4f23-a9c6-931919f9d819
Schmid, Markus
63a9df7e-1168-4825-b341-198aae582104
Woebken, Dagmar
d49f5fc1-c7c6-4a5f-b100-649124387bed
Gutierrez, Dimitri
5791fcaa-efc6-4bce-ab14-96af54edc31a
Amann, Rudolf
315b5cfc-deaa-4283-baf4-7fb655fe5730
Jetten, Mike S.M.
4fffe0a6-b5db-495b-8bae-7d72c64237e0
Kuypers, Marcel M.M.
b6288cfb-42bc-469c-93fe-8fbb40d97bec
Lam, Phyllis, Lavik, Gaute, Jensen, Marlene M., van de Vossenberg, Jack, Schmid, Markus, Woebken, Dagmar, Gutierrez, Dimitri, Amann, Rudolf, Jetten, Mike S.M. and Kuypers, Marcel M.M.
(2009)
Revising the nitrogen cycle in the Peruvian oxygen minimum zone.
Proceedings of the National Academy of Sciences, 106 (12), .
(doi:10.1073/pnas.0812444106).
(PMID:19255441)
Abstract
The oxygen minimum zone (OMZ) of the Eastern Tropical South Pacific (ETSP) is 1 of the 3 major regions in the world where oceanic nitrogen is lost in the pelagic realm. The recent identification of anammox, instead of denitrification, as the likely prevalent pathway for nitrogen loss in this OMZ raises strong questions about our understanding of nitrogen cycling and organic matter remineralization in these waters. Without detectable denitrification, it is unclear how NH(4)(+) is remineralized from organic matter and sustains anammox or how secondary NO(2)(-) maxima arise within the OMZ. Here we show that in the ETSP-OMZ, anammox obtains 67% or more of NO(2)(-) from nitrate reduction, and 33% or less from aerobic ammonia oxidation, based on stable-isotope pairing experiments corroborated by functional gene expression analyses. Dissimilatory nitrate reduction to ammonium was detected in an open-ocean setting. It occurred throughout the OMZ and could satisfy a substantial part of the NH(4)(+) requirement for anammox. The remaining NH(4)(+) came from remineralization via nitrate reduction and probably from microaerobic respiration. Altogether, deep-sea NO(3)(-) accounted for only approximately 50% of the nitrogen loss in the ETSP, rather than 100% as commonly assumed. Because oceanic OMZs seem to be expanding because of global climate change, it is increasingly imperative to incorporate the correct nitrogen-loss pathways in global biogeochemical models to predict more accurately how the nitrogen cycle in our future ocean may respond.
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More information
e-pub ahead of print date: 2 March 2009
Published date: 24 March 2009
Keywords:
anammox, dissimilatory nitrate reduction to ammonium, nitrogen loss, functional gene expression, remineralization
Organisations:
Ocean Biochemistry & Ecosystems
Identifiers
Local EPrints ID: 349917
URI: http://eprints.soton.ac.uk/id/eprint/349917
ISSN: 0027-8424
PURE UUID: 4e4b573c-568e-4bfd-a6d9-49524af542c8
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Date deposited: 13 Mar 2013 13:59
Last modified: 15 Mar 2024 03:47
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Contributors
Author:
Gaute Lavik
Author:
Marlene M. Jensen
Author:
Jack van de Vossenberg
Author:
Markus Schmid
Author:
Dagmar Woebken
Author:
Dimitri Gutierrez
Author:
Rudolf Amann
Author:
Mike S.M. Jetten
Author:
Marcel M.M. Kuypers
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