Nitrogen cycling in the secondary nitrite maximum of the eastern tropical North Pacific off Costa Rica

Nitrite is a central intermediate in the marine nitrogen cycle and represents a critical juncture where nitrogen can be reduced to the less bioavailable N2 gas or oxidized to nitrate and retained in a more bioavailable form. We present an analysis of rates of microbial nitrogen transformations in th...

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Veröffentlicht in:	Global biogeochemical cycles 2015-12, Vol.29 (12), p.2061-2081
Hauptverfasser:	Buchwald, Carolyn, Santoro, Alyson E., Stanley, Rachel H. R., Casciotti, Karen L.
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Sprache:	eng
Schlagworte:	Bioavailability Biogeochemistry Isotopes nitrate Nitrate reduction Nitrates nitrite Nitrogen Nitrogen cycle Oceans Oxidation stable isotopes
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container_issue	12
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container_title	Global biogeochemical cycles
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creator	Buchwald, Carolyn Santoro, Alyson E. Stanley, Rachel H. R. Casciotti, Karen L.
description	Nitrite is a central intermediate in the marine nitrogen cycle and represents a critical juncture where nitrogen can be reduced to the less bioavailable N2 gas or oxidized to nitrate and retained in a more bioavailable form. We present an analysis of rates of microbial nitrogen transformations in the oxygen deficient zone (ODZ) within the eastern tropical North Pacific Ocean (ETNP). We determined rates using a novel one‐dimensional model using the distribution of nitrite and nitrate concentrations, along with their natural abundance nitrogen (N) and oxygen (O) isotope profiles. We predict rate profiles for nitrate reduction, nitrite reduction, and nitrite oxidation throughout the ODZ, as well as the contributions of anammox to nitrite reduction and nitrite oxidation. Nitrate reduction occurs at a maximum rate of 25 nM d−1 at the top of the ODZ, at the same depth as the maximum rate of nitrite reduction, 15 nM d−1. Nitrite oxidation occurs at maximum rates of 10 nM d−1 above the secondary nitrite maximum, but also in the secondary nitrite maximum, within the ODZ. Anammox contributes to nitrite oxidation within the ODZ but cannot account for all of it. Nitrite oxidation within the ODZ that is not through anammox is also supported by microbial gene abundance profiles. Our results suggest the presence of nitrite oxidation within the ETNP ODZ, with implications for the distribution and physiology of marine nitrite‐oxidizing bacteria, and for total nitrogen loss in the largest marine ODZ. Key Points Isotope tracers and concentrations can predict N cycling rates Nitrate isotope profiles suggest a nitrate sink by denitrification Nitrite isotopes predict that up to 50% of nitrite is reoxidized
doi_str_mv	10.1002/2015GB005187
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Nitrate reduction occurs at a maximum rate of 25 nM d−1 at the top of the ODZ, at the same depth as the maximum rate of nitrite reduction, 15 nM d−1. Nitrite oxidation occurs at maximum rates of 10 nM d−1 above the secondary nitrite maximum, but also in the secondary nitrite maximum, within the ODZ. Anammox contributes to nitrite oxidation within the ODZ but cannot account for all of it. Nitrite oxidation within the ODZ that is not through anammox is also supported by microbial gene abundance profiles. Our results suggest the presence of nitrite oxidation within the ETNP ODZ, with implications for the distribution and physiology of marine nitrite‐oxidizing bacteria, and for total nitrogen loss in the largest marine ODZ. 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R.</creatorcontrib><creatorcontrib>Casciotti, Karen L.</creatorcontrib><title>Nitrogen cycling in the secondary nitrite maximum of the eastern tropical North Pacific off Costa Rica</title><title>Global biogeochemical cycles</title><addtitle>Global Biogeochem. Cycles</addtitle><description>Nitrite is a central intermediate in the marine nitrogen cycle and represents a critical juncture where nitrogen can be reduced to the less bioavailable N2 gas or oxidized to nitrate and retained in a more bioavailable form. We present an analysis of rates of microbial nitrogen transformations in the oxygen deficient zone (ODZ) within the eastern tropical North Pacific Ocean (ETNP). We determined rates using a novel one‐dimensional model using the distribution of nitrite and nitrate concentrations, along with their natural abundance nitrogen (N) and oxygen (O) isotope profiles. We predict rate profiles for nitrate reduction, nitrite reduction, and nitrite oxidation throughout the ODZ, as well as the contributions of anammox to nitrite reduction and nitrite oxidation. Nitrate reduction occurs at a maximum rate of 25 nM d−1 at the top of the ODZ, at the same depth as the maximum rate of nitrite reduction, 15 nM d−1. Nitrite oxidation occurs at maximum rates of 10 nM d−1 above the secondary nitrite maximum, but also in the secondary nitrite maximum, within the ODZ. Anammox contributes to nitrite oxidation within the ODZ but cannot account for all of it. Nitrite oxidation within the ODZ that is not through anammox is also supported by microbial gene abundance profiles. Our results suggest the presence of nitrite oxidation within the ETNP ODZ, with implications for the distribution and physiology of marine nitrite‐oxidizing bacteria, and for total nitrogen loss in the largest marine ODZ. Key Points Isotope tracers and concentrations can predict N cycling rates Nitrate isotope profiles suggest a nitrate sink by denitrification Nitrite isotopes predict that up to 50% of nitrite is reoxidized</description><subject>Bioavailability</subject><subject>Biogeochemistry</subject><subject>Isotopes</subject><subject>nitrate</subject><subject>Nitrate reduction</subject><subject>Nitrates</subject><subject>nitrite</subject><subject>Nitrogen</subject><subject>Nitrogen cycle</subject><subject>Oceans</subject><subject>Oxidation</subject><subject>stable isotopes</subject><issn>0886-6236</issn><issn>1944-9224</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2015</creationdate><recordtype>article</recordtype><recordid>eNp90M1OGzEUBWCrAqkBuusDWOqGBQP-98ySpBCQUKhaqi4tx7lOHGbGqT0R5O1rmqpCLFhZsr9zdX0Q-kzJOSWEXTBC5XRMiKS1_oBGtBGiahgTB2hE6lpVinH1ER3lvCaECimbEfKzMKS4hB67nWtDv8Shx8MKcAYX-4VNO9wXEQbAnX0O3bbD0f8FYPMAqeAUN8HZFs9iGlb4m3XBB1eUx5OYB4u_l9cTdOhtm-HTv_MY_by-epjcVHf309vJ5V1lpRa8EqJx0oOf17Vj5UvaWsm8o8ouuIa6nntqG-6B6lo4S1y5bQA8cxyEAr3gx-h0P3eT4u8t5MF0ITtoW9tD3GZDtVZKSqaaQr-8oeu4TX3ZriipmdJEvKizvXIp5pzAm00KXanFUGJeSjevSy-c7flTaGH3rjXT8YQRrnkJVftQKI0-_w_Z9GiU5lqaX7Op-fHQfKXXRJox_wNaUJG4</recordid><startdate>201512</startdate><enddate>201512</enddate><creator>Buchwald, Carolyn</creator><creator>Santoro, Alyson E.</creator><creator>Stanley, Rachel H. 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R.</au><au>Casciotti, Karen L.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Nitrogen cycling in the secondary nitrite maximum of the eastern tropical North Pacific off Costa Rica</atitle><jtitle>Global biogeochemical cycles</jtitle><addtitle>Global Biogeochem. Cycles</addtitle><date>2015-12</date><risdate>2015</risdate><volume>29</volume><issue>12</issue><spage>2061</spage><epage>2081</epage><pages>2061-2081</pages><issn>0886-6236</issn><eissn>1944-9224</eissn><abstract>Nitrite is a central intermediate in the marine nitrogen cycle and represents a critical juncture where nitrogen can be reduced to the less bioavailable N2 gas or oxidized to nitrate and retained in a more bioavailable form. We present an analysis of rates of microbial nitrogen transformations in the oxygen deficient zone (ODZ) within the eastern tropical North Pacific Ocean (ETNP). 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subjects	Bioavailability Biogeochemistry Isotopes nitrate Nitrate reduction Nitrates nitrite Nitrogen Nitrogen cycle Oceans Oxidation stable isotopes
title	Nitrogen cycling in the secondary nitrite maximum of the eastern tropical North Pacific off Costa Rica
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