Pathways and key intermediates required for obligate aerobic ammonia-dependent chemolithotrophy in bacteria and Thaumarchaeota

Kozlowski, Jessica A.; Stieglmeier, Michaela; Schleper, Christa; Klotz, Martin G.; Stein, Lisa Y.

doi:10.1038/ismej.2016.2

Cited by 277 publications

(351 citation statements)

References 38 publications

(62 reference statements)

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“…Ammonium oxidizing archaea may also participate in N 2 O production (Martens-Habbena et al, 2009;Santoro et al, 2010Santoro et al, , 2011Jung et al, 2014). In this sense, the large dominance of 45 N 2 O over 46 N 2 O observed could be explained by the recently described "hybrid" pathway (Kozlowski et al, 2016), in which labelled hydroxylamine ( 15 NH 2 OH) produced from AO might be combined with NO reduced from the NO − 2 present in the native pool of the incubations. The coupling between AO and NiR after the formation of NO − 2 is less plausible, because any labelled NO − 2 that is produced would be diluted by the existing pool of NO − 2 in the environment.…”

Section: N 2 O Productionmentioning

confidence: 99%

“…4c, d). The O 2 -limited incubations carried out during September, relative to in situ O 2 conditions during the January experiments, could, together with a greater availability of particles occurring at the sampling depth, generate an O 2 -depleted environment, in which the yield of N 2 O formed through nitrifier denitrification Goreau et al, 1980;Lipschultz et al, 1981;de Wilde and de Bie, 2000) or through the "hybrid" pathway (Kozlowski et al, 2016) will increase. There is ample evidence that N 2 O production via nitrification in aquatic systems is increased under conditions of reduced oxygen and abundant ammonium availability McElroy et al, 1978;de Wilde and de Bie, 2000;Löscher et al, 2012).…”

Section: N 2 O Productionmentioning

confidence: 99%

“…N 2 O can also be produced during ammonium (NH + 4 ) oxidation, a chemolithoautotrophic process by which NH + 4 is oxidized aerobically either by bacteria or archaea. However, the pathways of N 2 O production appear to differ between ammonium oxidizers from these two domains (Blainey et al, 2011;Kim et al, 2011;Spang et al, 2012;Kozlowski et al, 2016). While N 2 O is a minor product in ammonium oxidation (up to 10 % relative to NO − 2 production; Goreau et al, 1980), the yield of N 2 O produced by nitrifiers relative to NO − 2 increases ∼ 20 times as O 2 saturation in the atmosphere diminishes to 1 % (Kester et al, 1977).…”

Section: Introductionmentioning

confidence: 99%

“…Conversely, and despite several reports suggesting that archaeal ammonium oxidizers are an important source of N 2 O based on their ubiquity, abundance, activity and high NH + 4 affinity (Könneke et al, 2005;Wuchter et al, 2006;MartensHabbena et al, 2009;Santoro et al, 2011;Jung et al, 2014), the pathway through which the N 2 O is produced by this group is still not fully understood. Nonetheless, it was recently demonstrated that archaea involved in ammonium oxidation do not have the enzymatic capacity to reduce NO to N 2 O through nitrifier denitrification, and N 2 O formation was suggested to occur through a hybrid pathway pairing nitrogen from NH 2 OH and NO (Stieglmeier et al, 2014;Kozlowski et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Vertical segregation among pathways mediating nitrogen loss (N2 and N2O production) across the oxygen gradient in a coastal upwelling ecosystem

2017

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Abstract. The upwelling system off central Chile (36.5 • S) is seasonally subjected to oxygen (O 2 )-deficient waters, with a strong vertical gradient in O 2 (from oxic to anoxic conditions) that spans a few metres (30-50 m interval) over the shelf. This condition inhibits and/or stimulates processes involved in nitrogen (N) removal (e.g. anammox, denitrification, and nitrification). During austral spring (September 2013) and summer (January 2014), the main pathways involved in N loss and its speciation, in the form of N 2 and/or N 2 O, were studied using 15 N-tracer incubations, inhibitor assays, and the natural abundance of nitrate isotopes along with hydrographic information. Incubations were developed using water retrieved from the oxycline (25 m depth) and bottom waters (85 m depth) over the continental shelf off Concepción, Chile. Results of 15 N-labelled incubations revealed higher N removal activity during the austral summer, with denitrification as the dominant N 2 -producing pathway, which occurred together with anammox at all times. Interestingly, in both spring and summer maximum potential N removal rates were observed in the oxycline, where a greater availability of oxygen was observed (maximum O 2 fluctuation between 270 and 40 µmol L −1 ) relative to the hypoxic bottom waters (< 20 µmol O 2 L −1 ). Different pathways were responsible for N 2 O produced in the oxycline and bottom waters, with ammonium oxidation and dissimilatory nitrite reduction, respectively, as the main source processes. Ammonium produced by dissimilatory nitrite reduction to ammonium (DNiRA) could sustain both anammox and nitrification rates, including the ammonium utilized for N 2 O production. The temporal and vertical variability of δ 15 N-NO − 3 confirms that multiple N-cycling processes are modulating the isotopic nitrate composition over the shelf off central Chile during spring and summer. N removal processes in this coastal system appear to be related to the availability and distribution of oxygen and particles, which are a source of organic matter and the fuel for the production of other electron donors (i.e. ammonium) and acceptors (i.e. nitrate and nitrite) after its remineralization. These results highlight the links between several pathways involved in N loss. They also establish that different mechanisms supported by alternative N substratesPublished by Copernicus Publications on behalf of the European Geosciences Union. 4796A. Galán et al.: Vertical segregation among pathways mediating nitrogen loss are responsible for substantial accumulation of N 2 O, which are frequently observed as hotspots in the oxycline and bottom waters. Considering the extreme variation in oxygen observed in several coastal upwelling systems, these findings could help to understand the ecological and biogeochemical implications due to global warming where intensification and/or expansion of the oceanic OMZs is projected.

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Section: N 2 O Productionmentioning

confidence: 99%

Section: N 2 O Productionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Vertical segregation among pathways mediating nitrogen loss (N2 and N2O production) across the oxygen gradient in a coastal upwelling ecosystem

2017

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“…Such experiments provide key insights into the instantaneous rate of ammonia oxidation (or nitrification) but still have the following potential defects: (i) potential stimulation of nitrification by added tracers, (ii) underestimation of the ammonia oxidation rate by isotope dilution of nitrite arising from the concurrency of nitrification and denitrification, and (iii) potential change in microbial community composition during incubation. Experiments involving incubation with selective inhibitors of AOB or AOA activity (e.g., allylthiourea, 1-octyne, and 2-phenyl-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide) could be useful to assess bacterial and archaeal contributions to total nitrification (15)(16)(17), but it is still uncertain to what extent the ammonia oxidation rates measured in the inhibition experiments represent bacterial and archaeal ammonia oxidation rates in nature, as the minimum concentrations of the inhibitors to stop ammonia oxidation activity in natural environments with complex physical and ecological characteristics (e.g., permeability and cell density in the local environment) are largely unknown (16,18).…”

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confidence: 99%

Nitrogen and Oxygen Isotope Effects of Ammonia Oxidation by Thermophilic Thaumarchaeota from a Geothermal Water Stream

Nishizawa

Sakai

Konno

et al. 2016

Appl Environ Microbiol

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Ammonia oxidation regulates the balance of reduced and oxidized nitrogen pools in nature. Although ammonia-oxidizing archaea have been recently recognized to often outnumber ammonia-oxidizing bacteria in various environments, the contribution of ammonia-oxidizing archaea is still uncertain due to difficulties in the in situ quantification of ammonia oxidation activity. Nitrogen and oxygen isotope ratios of nitrite (␦ 15 N NO2؊ and ␦ 18 O NO2؊ , respectively) are geochemical tracers for evaluating the sources and the in situ rate of nitrite turnover determined from the activities of nitrification and denitrification; however, the isotope ratios of nitrite from archaeal ammonia oxidation have been characterized only for a few marine species. We first report the isotope effects of ammonia oxidation at 70°C by thermophilic Thaumarchaeota populations composed almost entirely of "Candidatus Nitrosocaldus." The nitrogen isotope effect of ammonia oxidation varied with ambient pH (25‰ to 32‰) and strongly suggests the oxidation of ammonia, not ammonium. The ␦ 18 O value of nitrite produced from ammonia oxidation varied with the ␦ 18 O value of water in the medium but was lower than the isotopic equilibrium value in water. Because experiments have shown that the half-life of abiotic oxygen isotope exchange between nitrite and water is longer than 33 h at 70°C and pH >6.6, the rate of ammonia oxidation by thermophilic Thaumarchaeota could be estimated using ␦ 18 O NO2؊ in geothermal environments, where the biological nitrite turnover is likely faster than 33 h. This study extended the range of application of nitrite isotopes as a geochemical clock of the ammonia oxidation activity to high-temperature environments. IMPORTANCEBecause ammonia oxidation is generally the rate-limiting step in nitrification that regulates the balance of reduced and oxidized nitrogen pools in nature, it is important to understand the biological and environmental factors underlying the regulation of the rate of ammonia oxidation. The discovery of ammonia-oxidizing archaea (AOA) in marine and terrestrial environments has transformed the concept that ammonia oxidation is operated only by bacterial species, suggesting that AOA play a significant role in the global nitrogen cycle. However, the archaeal contribution to ammonia oxidation in the global biosphere is not yet completely understood. This study successfully identified key factors controlling nitrogen and oxygen isotopic ratios of nitrite produced from thermophilic Thaumarchaeota and elucidated the applicability and its limit of nitrite isotopes as a geochemical clock of ammonia oxidation rate in nature. Oxygen isotope analysis in this study also provided new biochemical information on archaeal ammonia oxidation.

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Nitrous oxide production in surface waters of the mid‐latitude North Atlantic Ocean

Ward

2017

JGR Oceans

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The ocean is a major source of atmospheric nitrous oxide (N2O), an important greenhouse gas and ozone‐depleting agent. The oceanic flux of N2O varies regionally, and in the midlatitude North Atlantic, the production of N2O is poorly constrained. Incubation experiments with 15N‐ammonium and 15N‐nitrite revealed active N2O production from ammonium oxidation and nitrite reduction in the surface ocean, suggesting the midlatitude North Atlantic could be a net source for N2O, with a flux density of 0.06 µmol‐N2O m−2 d−1 in the top 120 m. The peak of N2O production was detected in the upper 100 m, shallower than the depth at which highest rates of ammonium oxidation to nitrite occurred. Oxygen was not depleted in the water column, but its concentration minimum corresponded to highest N2O oversaturation and low in situ N2O production. The apparent N2O yield, i.e., the molar ratio of N2O‐N production over nitrite production was 1.7% at the peak N2O production depths in the surface layer and decreased to less than 0.1% at peak ammonium oxidation depths. The majority of N2O production was apparently through “hybrid formation,” in which ammonium and nitrite each contribute one nitrogen atom to N2O formation, a process that is proposed to be mediated by ammonia oxidizing archaea.

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Pathways and key intermediates required for obligate aerobic ammonia-dependent chemolithotrophy in bacteria and Thaumarchaeota

Cited by 277 publications

References 38 publications

Vertical segregation among pathways mediating nitrogen loss (N<sub>2</sub> and N<sub>2</sub>O production) across the oxygen gradient in a coastal upwelling ecosystem

Vertical segregation among pathways mediating nitrogen loss (N<sub>2</sub> and N<sub>2</sub>O production) across the oxygen gradient in a coastal upwelling ecosystem

Nitrogen and Oxygen Isotope Effects of Ammonia Oxidation by Thermophilic Thaumarchaeota from a Geothermal Water Stream

Nitrous oxide production in surface waters of the mid‐latitude North Atlantic Ocean

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Pathways and key intermediates required for obligate aerobic ammonia-dependent chemolithotrophy in bacteria and Thaumarchaeota

Cited by 277 publications

References 38 publications

Vertical segregation among pathways mediating nitrogen loss (N&lt;sub&gt;2&lt;/sub&gt; and N&lt;sub&gt;2&lt;/sub&gt;O production) across the oxygen gradient in a coastal upwelling ecosystem

Vertical segregation among pathways mediating nitrogen loss (N&lt;sub&gt;2&lt;/sub&gt; and N&lt;sub&gt;2&lt;/sub&gt;O production) across the oxygen gradient in a coastal upwelling ecosystem

Nitrogen and Oxygen Isotope Effects of Ammonia Oxidation by Thermophilic Thaumarchaeota from a Geothermal Water Stream

Nitrous oxide production in surface waters of the mid‐latitude North Atlantic Ocean

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Vertical segregation among pathways mediating nitrogen loss (N<sub>2</sub> and N<sub>2</sub>O production) across the oxygen gradient in a coastal upwelling ecosystem

Vertical segregation among pathways mediating nitrogen loss (N<sub>2</sub> and N<sub>2</sub>O production) across the oxygen gradient in a coastal upwelling ecosystem