Restricted nitrous oxide emissions by ammonia oxidizers in two agricultural soils following excessive urea fertilization

Purpose Nitrogen (N) fertilizer placement in bands is a widely accepted agricultural practice to increase N use efficiency. An excessive ammonium concentration in a fertilizer band can increase osmotic stress on ammonia oxidizers and potentially affect nitrification and resultant nitrous oxide (N 2...

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Published in	Journal of soils and sediments Vol. 20; no. 3; pp. 1502 - 1512
Main Authors	Chen, Zhaoming, Wang, Qiang, Zhao, Jun, Chen, Yudong, Wang, Huoyan, Ma, Junwei, Zou, Ping, Bao, Li
Format	Journal Article
Language	English
Published	Berlin/Heidelberg Springer Berlin Heidelberg 01.03.2020 Springer Nature B.V
Subjects	Abundance Agricultural land Agricultural practices agricultural soils Ammonia Ammonium Ammonium compounds Anthrosols Archaea bacteria Biological fertilization Climate change DNA Earth and Environmental Science Emission Emission measurements Emissions Environment Environmental Physics Fertilization fertilizer application Fertilizers greenhouse gas emissions Incubation Incubation period Nitrification Nitrogen Nitrous oxide Nucleotide sequence nutrient use efficiency Osmotic stress oxidants Oxidation Oxidizing agents PCR quantitative polymerase chain reaction Sec 3 • Remediation and Management of Contaminated or Degraded Lands • Research Article Soil soil ecology soil function Soil Science & Conservation Soil treatment Soils Urea urea fertilizers urea nitrogen Ammonia-oxidizing archaea Nitrous oxide Agricultural soils Ammonia-oxidizing bacteria High ammonium concentration Nitrification
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Abstract	Purpose Nitrogen (N) fertilizer placement in bands is a widely accepted agricultural practice to increase N use efficiency. An excessive ammonium concentration in a fertilizer band can increase osmotic stress on ammonia oxidizers and potentially affect nitrification and resultant nitrous oxide (N 2 O) emissions, which is of great significance for soil function and climate change. The objectivity of this study was to identify the effects of excessive ammonium concentration on N 2 O emissions and ammonia oxidizers in two agricultural soils. Materials and methods In this study, we established a 56-day soil microcosm receiving a series of high concentrations of urea at 600, 900, and 1200 mg N kg −1 (termed as N600, N900, and N1200, respectively), which simulated high ammonium levels in the center or proximity of a fertilizer band in two types of agricultural soils (fluvo-aquic soil and anthrosol). The mineral N concentrations, net nitrification rate, and N 2 O emissions were measured during the incubation. In addition, the abundances of bacterial and archaeal amoA were determined by using real-time quantitative PCR. Results and discussion Urea fertilization simultaneously increased the net nitrification rate and N 2 O emission at the early stage of incubation in both soils, suggesting N 2 O production was mainly from ammonia oxidation. Ammonia oxidizing bacteria (AOB) but not archaea (AOA) abundance was stimulated following urea fertilization and was positively correlated with N 2 O emission, indicating the dominant role of AOB in ammonia oxidation and N 2 O production in fertilized soils. The cumulative N 2 O emission was significantly higher in N1200 and N900 than N600 in both soils, but no further increase was observed in N1200 in the anthrosol. This implies restricted N 2 O production of ammonia oxidizers at excessive ammonium concentrations in the anthrosol. In the two soils treated with no N addition, the abundances of AOA amoA increased along the incubation time. Conclusions The present study collectively suggested that excessive urea-N addition was more effective in inhibiting N 2 O emission in the anthrosol than in the fluvo-aquci soil. AOB rather than AOA dominated the soil nitrification and N 2 O emissions under high N addition in both soils. The band fertilization regime may reduce the loss of N fertilizer from nitrification without necessarily increasing N 2 O emissions.
AbstractList	PurposeNitrogen (N) fertilizer placement in bands is a widely accepted agricultural practice to increase N use efficiency. An excessive ammonium concentration in a fertilizer band can increase osmotic stress on ammonia oxidizers and potentially affect nitrification and resultant nitrous oxide (N2O) emissions, which is of great significance for soil function and climate change. The objectivity of this study was to identify the effects of excessive ammonium concentration on N2O emissions and ammonia oxidizers in two agricultural soils.Materials and methodsIn this study, we established a 56-day soil microcosm receiving a series of high concentrations of urea at 600, 900, and 1200 mg N kg−1 (termed as N600, N900, and N1200, respectively), which simulated high ammonium levels in the center or proximity of a fertilizer band in two types of agricultural soils (fluvo-aquic soil and anthrosol). The mineral N concentrations, net nitrification rate, and N2O emissions were measured during the incubation. In addition, the abundances of bacterial and archaeal amoA were determined by using real-time quantitative PCR.Results and discussionUrea fertilization simultaneously increased the net nitrification rate and N2O emission at the early stage of incubation in both soils, suggesting N2O production was mainly from ammonia oxidation. Ammonia oxidizing bacteria (AOB) but not archaea (AOA) abundance was stimulated following urea fertilization and was positively correlated with N2O emission, indicating the dominant role of AOB in ammonia oxidation and N2O production in fertilized soils. The cumulative N2O emission was significantly higher in N1200 and N900 than N600 in both soils, but no further increase was observed in N1200 in the anthrosol. This implies restricted N2O production of ammonia oxidizers at excessive ammonium concentrations in the anthrosol. In the two soils treated with no N addition, the abundances of AOA amoA increased along the incubation time.ConclusionsThe present study collectively suggested that excessive urea-N addition was more effective in inhibiting N2O emission in the anthrosol than in the fluvo-aquci soil. AOB rather than AOA dominated the soil nitrification and N2O emissions under high N addition in both soils. The band fertilization regime may reduce the loss of N fertilizer from nitrification without necessarily increasing N2O emissions. PURPOSE: Nitrogen (N) fertilizer placement in bands is a widely accepted agricultural practice to increase N use efficiency. An excessive ammonium concentration in a fertilizer band can increase osmotic stress on ammonia oxidizers and potentially affect nitrification and resultant nitrous oxide (N₂O) emissions, which is of great significance for soil function and climate change. The objectivity of this study was to identify the effects of excessive ammonium concentration on N₂O emissions and ammonia oxidizers in two agricultural soils. MATERIALS AND METHODS: In this study, we established a 56-day soil microcosm receiving a series of high concentrations of urea at 600, 900, and 1200 mg N kg⁻¹ (termed as N600, N900, and N1200, respectively), which simulated high ammonium levels in the center or proximity of a fertilizer band in two types of agricultural soils (fluvo-aquic soil and anthrosol). The mineral N concentrations, net nitrification rate, and N₂O emissions were measured during the incubation. In addition, the abundances of bacterial and archaeal amoA were determined by using real-time quantitative PCR. RESULTS AND DISCUSSION: Urea fertilization simultaneously increased the net nitrification rate and N₂O emission at the early stage of incubation in both soils, suggesting N₂O production was mainly from ammonia oxidation. Ammonia oxidizing bacteria (AOB) but not archaea (AOA) abundance was stimulated following urea fertilization and was positively correlated with N₂O emission, indicating the dominant role of AOB in ammonia oxidation and N₂O production in fertilized soils. The cumulative N₂O emission was significantly higher in N1200 and N900 than N600 in both soils, but no further increase was observed in N1200 in the anthrosol. This implies restricted N₂O production of ammonia oxidizers at excessive ammonium concentrations in the anthrosol. In the two soils treated with no N addition, the abundances of AOA amoA increased along the incubation time. CONCLUSIONS: The present study collectively suggested that excessive urea-N addition was more effective in inhibiting N₂O emission in the anthrosol than in the fluvo-aquci soil. AOB rather than AOA dominated the soil nitrification and N₂O emissions under high N addition in both soils. The band fertilization regime may reduce the loss of N fertilizer from nitrification without necessarily increasing N₂O emissions. Purpose Nitrogen (N) fertilizer placement in bands is a widely accepted agricultural practice to increase N use efficiency. An excessive ammonium concentration in a fertilizer band can increase osmotic stress on ammonia oxidizers and potentially affect nitrification and resultant nitrous oxide (N 2 O) emissions, which is of great significance for soil function and climate change. The objectivity of this study was to identify the effects of excessive ammonium concentration on N 2 O emissions and ammonia oxidizers in two agricultural soils. Materials and methods In this study, we established a 56-day soil microcosm receiving a series of high concentrations of urea at 600, 900, and 1200 mg N kg −1 (termed as N600, N900, and N1200, respectively), which simulated high ammonium levels in the center or proximity of a fertilizer band in two types of agricultural soils (fluvo-aquic soil and anthrosol). The mineral N concentrations, net nitrification rate, and N 2 O emissions were measured during the incubation. In addition, the abundances of bacterial and archaeal amoA were determined by using real-time quantitative PCR. Results and discussion Urea fertilization simultaneously increased the net nitrification rate and N 2 O emission at the early stage of incubation in both soils, suggesting N 2 O production was mainly from ammonia oxidation. Ammonia oxidizing bacteria (AOB) but not archaea (AOA) abundance was stimulated following urea fertilization and was positively correlated with N 2 O emission, indicating the dominant role of AOB in ammonia oxidation and N 2 O production in fertilized soils. The cumulative N 2 O emission was significantly higher in N1200 and N900 than N600 in both soils, but no further increase was observed in N1200 in the anthrosol. This implies restricted N 2 O production of ammonia oxidizers at excessive ammonium concentrations in the anthrosol. In the two soils treated with no N addition, the abundances of AOA amoA increased along the incubation time. Conclusions The present study collectively suggested that excessive urea-N addition was more effective in inhibiting N 2 O emission in the anthrosol than in the fluvo-aquci soil. AOB rather than AOA dominated the soil nitrification and N 2 O emissions under high N addition in both soils. The band fertilization regime may reduce the loss of N fertilizer from nitrification without necessarily increasing N 2 O emissions.
Author	Chen, Yudong Wang, Huoyan Bao, Li Chen, Zhaoming Zhao, Jun Wang, Qiang Ma, Junwei Zou, Ping
Author_xml	– sequence: 1 givenname: Zhaoming surname: Chen fullname: Chen, Zhaoming email: zhmchen@aliyun.com organization: Institute of Environmental Resources and Soil Fertilizer, Zhejiang Academy of Agricultural Sciences – sequence: 2 givenname: Qiang surname: Wang fullname: Wang, Qiang email: qwang0571@126.com organization: Institute of Environmental Resources and Soil Fertilizer, Zhejiang Academy of Agricultural Sciences – sequence: 3 givenname: Jun surname: Zhao fullname: Zhao, Jun organization: State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences – sequence: 4 givenname: Yudong surname: Chen fullname: Chen, Yudong organization: Nanjing Institute of Environmental Sciences, Ministry of Ecological Environment – sequence: 5 givenname: Huoyan surname: Wang fullname: Wang, Huoyan organization: State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences – sequence: 6 givenname: Junwei surname: Ma fullname: Ma, Junwei organization: Institute of Environmental Resources and Soil Fertilizer, Zhejiang Academy of Agricultural Sciences – sequence: 7 givenname: Ping surname: Zou fullname: Zou, Ping organization: Institute of Environmental Resources and Soil Fertilizer, Zhejiang Academy of Agricultural Sciences – sequence: 8 givenname: Li surname: Bao fullname: Bao, Li organization: Yangzhou Branch, Central Agricultural Radio and Television School
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CitedBy_id	crossref_primary_10_1007_s11356_021_14715_7 crossref_primary_10_1080_00380768_2021_1981119 crossref_primary_10_3390_agronomy11102009 crossref_primary_10_1007_s11368_022_03183_2 crossref_primary_10_1016_j_ejsobi_2022_103452 crossref_primary_10_1007_s11368_021_03035_5 crossref_primary_10_3390_agronomy14010223 crossref_primary_10_11648_j_wjast_20240204_17 crossref_primary_10_3390_agronomy13010096 crossref_primary_10_1016_j_apsoil_2022_104723 crossref_primary_10_3390_agriculture12111771
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Snippet	Purpose Nitrogen (N) fertilizer placement in bands is a widely accepted agricultural practice to increase N use efficiency. An excessive ammonium concentration... PurposeNitrogen (N) fertilizer placement in bands is a widely accepted agricultural practice to increase N use efficiency. An excessive ammonium concentration... PURPOSE: Nitrogen (N) fertilizer placement in bands is a widely accepted agricultural practice to increase N use efficiency. An excessive ammonium...
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SubjectTerms	Abundance Agricultural land Agricultural practices agricultural soils Ammonia Ammonium Ammonium compounds Anthrosols Archaea bacteria Biological fertilization Climate change DNA Earth and Environmental Science Emission Emission measurements Emissions Environment Environmental Physics Fertilization fertilizer application Fertilizers greenhouse gas emissions Incubation Incubation period Nitrification Nitrogen Nitrous oxide Nucleotide sequence nutrient use efficiency Osmotic stress oxidants Oxidation Oxidizing agents PCR quantitative polymerase chain reaction Sec 3 • Remediation and Management of Contaminated or Degraded Lands • Research Article Soil soil ecology soil function Soil Science & Conservation Soil treatment Soils Urea urea fertilizers urea nitrogen
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Title	Restricted nitrous oxide emissions by ammonia oxidizers in two agricultural soils following excessive urea fertilization
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