Long-term N-addition alters the community structure of functionally important N-cycling soil microorganisms across global grasslands

Beat Frey; Barbara Moser; Bjorn Tytgat; Stephan Zimmermann; Juan Alberti; Lori A. Biederman; Elizabeth T. Borer; Arthur A.D. Broadbent; Maria C. Caldeira; Kendi F. Davies; Nico Eisenhauer; Anu Eskelinen; Philip A. Fay; Frank Hagedorn; Yann Hautier; Andrew S. MacDougall; Rebecca L. McCulley; Joslin L. Moore; Maximilian Nepel; Sally A. Power; Eric W. Seabloom; Eduardo Vázquez; Risto Virtanen; Laura Yahdjian; Anita C. Risch

doi:10.1016/j.soilbio.2022.108887

Long-term N-addition alters the community structure of functionally important N-cycling soil microorganisms across global grasslands

Beat Frey, Barbara Moser, Bjorn Tytgat, Stephan Zimmermann, Juan Alberti, Lori A. Biederman, Elizabeth T. Borer, Arthur A.D. Broadbent, Maria C. Caldeira, Kendi F. Davies, Nico Eisenhauer, Anu Eskelinen, Philip A. Fay, Frank Hagedorn, Yann Hautier, Andrew S. MacDougall, Rebecca L. McCulley, Joslin L. Moore, Maximilian Nepel, Sally A. PowerEric W. Seabloom, Eduardo Vázquez, Risto Virtanen, Laura Yahdjian, Anita C. Risch

Ecology, Evolution and Behavior

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Abstract

Anthropogenic nitrogen (N) input is known to alter the soil microbiome, but how N enrichment influences the abundance, alpha-diversity and community structure of N-cycling functional microbial communities in grasslands remains poorly understood. Here, we collected soils from plant communities subjected to up to 9 years of annual N-addition (10 g N m⁻² per year using urea as a N-source) and from unfertilized plots (control) in 30 grasslands worldwide spanning a large range of climatic and soil conditions. We focused on three key microbial groups responsible for two essential processes of the global N cycle: N₂ fixation (soil diazotrophs) and nitrification (AOA: ammonia-oxidizing archaea and AOB: ammonia-oxidizing bacteria). We targeted soil diazotrophs, AOA and AOB using Illumina MiSeq sequencing and measured the abundance (gene copy numbers) using quantitative PCR. N-addition shifted the structure of the diazotrophic communities, although their alpha-diversity and abundance were not affected. AOA and AOB responded differently to N-addition. The abundance and alpha-diversity of AOB increased, and their community structure shifted with N-addition. In contrast, AOA were not affected by N-addition. AOA abundance outnumbered AOB in control plots under conditions of low N availability, whereas N-addition favoured copiotrophic AOB. Overall, N-addition showed a low impact on soil diazotrophs and AOA while effects for AOB communities were considerable. These results reveal that long-term N-addition has important ecological implications for key microbial groups involved in two critical soil N-cycling processes. Increased AOB abundance and community shifts following N-addition may change soil N-cycling, as larger population sizes may promote higher rates of ammonia oxidation and subsequently increase N loss via gaseous and soil N-leaching. These findings bring us a step closer to predicting the responses and feedbacks of microbial-mediated N-cycling processes to long-term anthropogenic N-addition in grasslands.

Original language	English (US)
Article number	108887
Journal	Soil Biology and Biochemistry
Volume	176
DOIs	https://doi.org/10.1016/j.soilbio.2022.108887
State	Published - Jan 2023

Bibliographical note

Publisher Copyright:
© 2022 The Authors

Keywords

Ammonia oxidizer
Biogeography
Diazotroph
Grassland
N-Fertilization
N-cycling microbial community
N-fixing bacteria
Nutrient network (NutNet)
Urea
nifH

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Frey, B., Moser, B., Tytgat, B., Zimmermann, S., Alberti, J., Biederman, L. A., Borer, E. T., Broadbent, A. A. D., Caldeira, M. C., Davies, K. F., Eisenhauer, N., Eskelinen, A., Fay, P. A., Hagedorn, F., Hautier, Y., MacDougall, A. S., McCulley, R. L., Moore, J. L., Nepel, M., ... Risch, A. C. (2023). Long-term N-addition alters the community structure of functionally important N-cycling soil microorganisms across global grasslands. Soil Biology and Biochemistry, 176, Article 108887. https://doi.org/10.1016/j.soilbio.2022.108887

Frey, B, Moser, B, Tytgat, B, Zimmermann, S, Alberti, J, Biederman, LA, Borer, ET, Broadbent, AAD, Caldeira, MC, Davies, KF, Eisenhauer, N, Eskelinen, A, Fay, PA, Hagedorn, F, Hautier, Y, MacDougall, AS, McCulley, RL, Moore, JL, Nepel, M, Power, SA, Seabloom, EW, Vázquez, E, Virtanen, R, Yahdjian, L & Risch, AC 2023, 'Long-term N-addition alters the community structure of functionally important N-cycling soil microorganisms across global grasslands', Soil Biology and Biochemistry, vol. 176, 108887. https://doi.org/10.1016/j.soilbio.2022.108887

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abstract = "Anthropogenic nitrogen (N) input is known to alter the soil microbiome, but how N enrichment influences the abundance, alpha-diversity and community structure of N-cycling functional microbial communities in grasslands remains poorly understood. Here, we collected soils from plant communities subjected to up to 9 years of annual N-addition (10 g N m−2 per year using urea as a N-source) and from unfertilized plots (control) in 30 grasslands worldwide spanning a large range of climatic and soil conditions. We focused on three key microbial groups responsible for two essential processes of the global N cycle: N2 fixation (soil diazotrophs) and nitrification (AOA: ammonia-oxidizing archaea and AOB: ammonia-oxidizing bacteria). We targeted soil diazotrophs, AOA and AOB using Illumina MiSeq sequencing and measured the abundance (gene copy numbers) using quantitative PCR. N-addition shifted the structure of the diazotrophic communities, although their alpha-diversity and abundance were not affected. AOA and AOB responded differently to N-addition. The abundance and alpha-diversity of AOB increased, and their community structure shifted with N-addition. In contrast, AOA were not affected by N-addition. AOA abundance outnumbered AOB in control plots under conditions of low N availability, whereas N-addition favoured copiotrophic AOB. Overall, N-addition showed a low impact on soil diazotrophs and AOA while effects for AOB communities were considerable. These results reveal that long-term N-addition has important ecological implications for key microbial groups involved in two critical soil N-cycling processes. Increased AOB abundance and community shifts following N-addition may change soil N-cycling, as larger population sizes may promote higher rates of ammonia oxidation and subsequently increase N loss via gaseous and soil N-leaching. These findings bring us a step closer to predicting the responses and feedbacks of microbial-mediated N-cycling processes to long-term anthropogenic N-addition in grasslands.",

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AU - Moser, Barbara

AU - Tytgat, Bjorn

AU - Zimmermann, Stephan

AU - Alberti, Juan

AU - Biederman, Lori A.

AU - Borer, Elizabeth T.

AU - Broadbent, Arthur A.D.

AU - Caldeira, Maria C.

AU - Davies, Kendi F.

AU - Eisenhauer, Nico

AU - Eskelinen, Anu

AU - Fay, Philip A.

AU - Hagedorn, Frank

AU - Hautier, Yann

AU - MacDougall, Andrew S.

AU - McCulley, Rebecca L.

AU - Moore, Joslin L.

AU - Nepel, Maximilian

AU - Power, Sally A.

AU - Seabloom, Eric W.

AU - Vázquez, Eduardo

AU - Virtanen, Risto

AU - Yahdjian, Laura

AU - Risch, Anita C.

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N2 - Anthropogenic nitrogen (N) input is known to alter the soil microbiome, but how N enrichment influences the abundance, alpha-diversity and community structure of N-cycling functional microbial communities in grasslands remains poorly understood. Here, we collected soils from plant communities subjected to up to 9 years of annual N-addition (10 g N m−2 per year using urea as a N-source) and from unfertilized plots (control) in 30 grasslands worldwide spanning a large range of climatic and soil conditions. We focused on three key microbial groups responsible for two essential processes of the global N cycle: N2 fixation (soil diazotrophs) and nitrification (AOA: ammonia-oxidizing archaea and AOB: ammonia-oxidizing bacteria). We targeted soil diazotrophs, AOA and AOB using Illumina MiSeq sequencing and measured the abundance (gene copy numbers) using quantitative PCR. N-addition shifted the structure of the diazotrophic communities, although their alpha-diversity and abundance were not affected. AOA and AOB responded differently to N-addition. The abundance and alpha-diversity of AOB increased, and their community structure shifted with N-addition. In contrast, AOA were not affected by N-addition. AOA abundance outnumbered AOB in control plots under conditions of low N availability, whereas N-addition favoured copiotrophic AOB. Overall, N-addition showed a low impact on soil diazotrophs and AOA while effects for AOB communities were considerable. These results reveal that long-term N-addition has important ecological implications for key microbial groups involved in two critical soil N-cycling processes. Increased AOB abundance and community shifts following N-addition may change soil N-cycling, as larger population sizes may promote higher rates of ammonia oxidation and subsequently increase N loss via gaseous and soil N-leaching. These findings bring us a step closer to predicting the responses and feedbacks of microbial-mediated N-cycling processes to long-term anthropogenic N-addition in grasslands.

AB - Anthropogenic nitrogen (N) input is known to alter the soil microbiome, but how N enrichment influences the abundance, alpha-diversity and community structure of N-cycling functional microbial communities in grasslands remains poorly understood. Here, we collected soils from plant communities subjected to up to 9 years of annual N-addition (10 g N m−2 per year using urea as a N-source) and from unfertilized plots (control) in 30 grasslands worldwide spanning a large range of climatic and soil conditions. We focused on three key microbial groups responsible for two essential processes of the global N cycle: N2 fixation (soil diazotrophs) and nitrification (AOA: ammonia-oxidizing archaea and AOB: ammonia-oxidizing bacteria). We targeted soil diazotrophs, AOA and AOB using Illumina MiSeq sequencing and measured the abundance (gene copy numbers) using quantitative PCR. N-addition shifted the structure of the diazotrophic communities, although their alpha-diversity and abundance were not affected. AOA and AOB responded differently to N-addition. The abundance and alpha-diversity of AOB increased, and their community structure shifted with N-addition. In contrast, AOA were not affected by N-addition. AOA abundance outnumbered AOB in control plots under conditions of low N availability, whereas N-addition favoured copiotrophic AOB. Overall, N-addition showed a low impact on soil diazotrophs and AOA while effects for AOB communities were considerable. These results reveal that long-term N-addition has important ecological implications for key microbial groups involved in two critical soil N-cycling processes. Increased AOB abundance and community shifts following N-addition may change soil N-cycling, as larger population sizes may promote higher rates of ammonia oxidation and subsequently increase N loss via gaseous and soil N-leaching. These findings bring us a step closer to predicting the responses and feedbacks of microbial-mediated N-cycling processes to long-term anthropogenic N-addition in grasslands.

KW - Ammonia oxidizer

KW - Biogeography

KW - Diazotroph

KW - Grassland

KW - N-Fertilization

KW - N-cycling microbial community

KW - N-fixing bacteria

KW - Nutrient network (NutNet)

KW - Urea

KW - nifH

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DO - 10.1016/j.soilbio.2022.108887

M3 - Article

AN - SCOPUS:85143820864

SN - 0038-0717

VL - 176

JO - Soil Biology and Biochemistry

JF - Soil Biology and Biochemistry

M1 - 108887

ER -

Long-term N-addition alters the community structure of functionally important N-cycling soil microorganisms across global grasslands

Abstract

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Keywords

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