Archaeal Ammonia Oxidizers Dominate in Numbers, but Bacteria Drive Gross Nitrification in N-amended Grassland Soil

Sterngren, Anna E.; Hallin, Sara; Bengtson, Per

doi:10.3389/fmicb.2015.01350

Cited by 94 publications

(52 citation statements)

References 51 publications

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“…This is thought to be linked to the enzymatic capabilities of different AOB and AOA species, with the former generating higher amounts of N 2 O through both abiotic (nitric oxide oxidation by O 2 ) and biotic (incomplete hydroxylamine oxidation and nitrifier denitrification) mechanisms, while the latter likely emits lower N 2 O using only an abiotic (nitric oxidation by O 2 ) mechanism (Harper et al, 2015;Kozlowski et al, 2016). These results support observations that the AOA Nitrososphaera is associated with low concentrations of ammonia linked to the stronger affinity of the archaeal ammonia monooxygenase for ammonia (Sterngren et al, 2015). More than five AOA Nitrososphaera 16S rRNA OTUs were identified compared to the two AOB Nitrosospira 16S rRNA OTUs; this supports the idea that the conditions in these unfertilized soils normally support the AOA Nitrososphaera rather than the AOB Nitrosospira or Nitrosomonas as the main ammonia oxidizers.…”

Section: Discussionsupporting

confidence: 82%

“…The Nitrosovibrio RY3C species was originally isolated from avocado rhizosphere and its nitrifying activity was susceptible to DCD (Matsuba et al, 2003). The Nitrosospira in general are widespread spiral soil bacteria with generally low specificity for ammonia and, thus, found in soils under high levels of ammonia (Jia and Conrad, 2009;Di et al, 2010a;Sterngren et al, 2015). as the N 2 Ogenerating AOB in tropical soil under sugarcane, and that study applied NH 4 NO 3 as the N source (Lourenço et al, 2018a).…”

Section: Discussionmentioning

confidence: 97%

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Nitrification inhibitors effectively target N₂O‐producing Nitrosospira spp. in tropical soil

Cassman

Soares

Pijl

et al. 2019

Environmental Microbiology

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SummaryThe nitrification inhibitors (NIs) 3,4‐dimethylpyrazole (DMPP) and dicyandiamide (DCD) can effectively reduce N2O emissions; however, which species are targeted and the effect of these NIs on the microbial nitrifier community is still unclear. Here, we identified the ammonia oxidizing bacteria (AOB) species linked to N2O emissions and evaluated the effects of urea and urea with DCD and DMPP on the nitrifying community in a 258 day field experiment under sugarcane. Using an amoA AOB amplicon sequencing approach and mining a previous dataset of 16S rRNA sequences, we characterized the most likely N2O‐producing AOB as a Nitrosospira spp. and identified Nitrosospira (AOB), Nitrososphaera (archaeal ammonia oxidizer) and Nitrospira (nitrite‐oxidizer) as the most abundant, present nitrifiers. The fertilizer treatments had no effect on the alpha and beta diversities of the AOB communities. Interestingly, we found three clusters of co‐varying variables with nitrifier operational taxonomic units (OTUs): the N2O‐producing AOB Nitrosospira with N2O, NO3 −, NH4 +, water‐filled pore space (WFPS) and pH; AOA Nitrososphaera with NO3 −, NH4 + and pH; and AOA Nitrososphaera and NOB Nitrospira with NH4 +, which suggests different drivers. These results support the co‐occurrence of non‐N2O‐producing Nitrososphaera and Nitrospira in the unfertilized soils and the promotion of N2O‐producing Nitrosospira under urea fertilization. Further, we suggest that DMPP is a more effective NI than DCD in tropical soil under sugarcane.

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Section: Discussionsupporting

confidence: 82%

Section: Discussionmentioning

confidence: 97%

Nitrification inhibitors effectively target N₂O‐producing Nitrosospira spp. in tropical soil

Cassman

Soares

Pijl

et al. 2019

Environmental Microbiology

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“…1900 m a.s.l., whereas Entic Podzols, Albic Podzols and Umbric Podzols are dominant in the forest above ( [34], according to [35]). descriptive information about soil quality [25], as they can compete for the same nutrients [26] and due to different pH dependencies of fungi, bacteria and archaea [27]. In order to understand spatial decomposition patterns in a high mountain environment, it would be useful if humus forms could be applied as indicators not only of the distribution of enchytraeid species [9,28], but also of microbiological parameters [29].…”

Section: Study Areamentioning

confidence: 99%

Humus Forms and Soil Microbiological Parameters in a Mountain Forest: Upscaling to the Slope Scale

et al. 2018

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Humus forms are the morphological results of organic matter decay and distribution in the topsoil, and thus important indicators for decomposer activities in forest ecosystems. The first aim was to examine if humus forms are suitable indicators of microbiological properties of the topsoil in a high mountain forest (Val di Rabbi, Trentino, Italian Alps). The second aim was to predict microbiological parameters based on the topsoil pH value on two slopes of the study area (ca. 1200-2200 m a.s.l.). We investigated humus forms and determined pH values and microbiological parameters (enzymatic activities, carbon/nitrogen (C/N) ratio and the ratio of bacterial/archaeal abundance) of the uppermost mineral horizon. The results reveal significant correlations between pH value and microbiological parameters (except for bacterial/archaeal abundance), which enable upscaling to the landscape scale using linear models. Based on a random forest with kriging of model residuals, predictive maps of humus form, pH value and microbiological parameters show that decomposition processes in our study area correspond with the topography. As compared to locations on south-facing slopes or close to the valley bottom, locations on north-facing slopes or close to the upper treeline exhibit Moder (scarcely Mull or Amphimull), more acidic topsoil (around pH 4), a lower activity of leucine-aminopeptidase, a lower ratio of alkaline/acid phosphomonoesterase activity and a higher soil C/N ratio (above 20). Our results suggest a high potential of humus forms to indicate soil microbiological properties in a high mountain forest. Together with the pH values of the topsoil, humus forms proved to be a useful tool as a basis for predictive maps of leucine-aminopeptidase activity, ratio of alkaline/acid phosphomonoesterase activity and C/N ratio of the mineral topsoil.

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“…However, by characterising the conserved amoA gene, which encodes a subunit of the ammonia monooxygenase (AMO), it has been observed that the populations of ammonia oxidisers are largely controlled by soil type, NH 4 + concentration, pH and water content (Nicol et al 2008;Di et al 2009;Chen et al 2010;Norton and Stark 2011). In ammoniumrich soils, AOB abundance and activity increased whereas AOA abudance is unaffected or inhibited in response to a high concentration of ammonium fertilisers (Jia and Conrad 2009;Di et al 2009;Di and Cameron 2011;Sterngren et al 2015;Ouyang et al 2016). In unfertilised or acidic soils, AOA abundance and metabolic activity are much higher than those of AOB (Offre et al 2009;GubryRangin et al 2010;Zhang et al 2012).…”

Section: Introductionmentioning

confidence: 99%

Nitrogen fertiliser-induced changes in N2O emissions are attributed more to ammonia-oxidising bacteria rather than archaea as revealed using 1-octyne and acetylene inhibitors in two arable soils

et al. 2016

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Nitrification is believed to be one of the major sources of N 2 O production emitted from soil. Previous studies showed that both ammonia-oxidising bacteria (AOB) and archaea (AOA) can produce N 2 O via nitrification but their relative contributions are still poorly defined. Here, we used acetylene, an inhibitor of AOB and AOA ammonia monooxygenase (AMO), and 1-octyne, a selective inhibitor that specifically inhibits AOB AMO, to investigate how AOB versus AOA contribute to N 2 O emissions in two distinct arable soils. Soil amended with ammonium (NH 4 + ) increased N 2 O emissions to a greater extent than nitrate (NO 3 − ), and acetylene had a greater impact on N 2 O emissions in NH 4 + -treated soils than that in NO 3 − -amended soils, which indicated that nitrification was the dominant N 2 O emitting process in these two arable soils. In the alluvial and red soil, the percentage of evolved N 2 O after application of NH 4 + by AOB were 70.5~78.1 % and 18.7~19.7 % by AOA, respectively. Quantitative PCR revealed that NH 4 + addition stimulated AOB growth, and the growth could be significantly inhibited by acetylene or 1-octyne in the two soils. The stimulation of N 2 O emissions by NH 4 + and the relative suppression by inhibitors paralleled fluctuations in the AOB growth. In addition, cumulative N 2 O emissions were not correlated with AOA abundance in the two soils. Our results revealed that AOB could contribute more to soil N 2 O production than AOA in the NH 4 + -amended arable soils.

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Archaeal Ammonia Oxidizers Dominate in Numbers, but Bacteria Drive Gross Nitrification in N-amended Grassland Soil

Cited by 94 publications

References 51 publications

Nitrification inhibitors effectively target N₂O‐producing Nitrosospira spp. in tropical soil

Nitrification inhibitors effectively target N₂O‐producing Nitrosospira spp. in tropical soil

Humus Forms and Soil Microbiological Parameters in a Mountain Forest: Upscaling to the Slope Scale

Nitrogen fertiliser-induced changes in N2O emissions are attributed more to ammonia-oxidising bacteria rather than archaea as revealed using 1-octyne and acetylene inhibitors in two arable soils

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Archaeal Ammonia Oxidizers Dominate in Numbers, but Bacteria Drive Gross Nitrification in N-amended Grassland Soil

Cited by 94 publications

References 51 publications

Nitrification inhibitors effectively target N2O‐producing Nitrosospira spp. in tropical soil

Nitrification inhibitors effectively target N2O‐producing Nitrosospira spp. in tropical soil

Humus Forms and Soil Microbiological Parameters in a Mountain Forest: Upscaling to the Slope Scale

Nitrogen fertiliser-induced changes in N2O emissions are attributed more to ammonia-oxidising bacteria rather than archaea as revealed using 1-octyne and acetylene inhibitors in two arable soils

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Nitrification inhibitors effectively target N₂O‐producing Nitrosospira spp. in tropical soil

Nitrification inhibitors effectively target N₂O‐producing Nitrosospira spp. in tropical soil