Metagenomics reveals divergent functional profiles of soil carbon and nitrogen cycling under long-term addition of chemical and organic fertilizers in the black soil region

•Biogeographic distance rather than fertilization dominated microbial functional profiles in Mollisols.•Chemical fertilization promoted processes of methane oxidation, soil N degradation, nitrification and anammox.•Manure fertilization shifted C fixation and degradation processes and facilitated nit...

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Published inGeoderma Vol. 418; p. 115846
Main Authors Hu, Xiaojing, Gu, Haidong, Liu, Junjie, Wei, Dan, Zhu, Ping, Cui, Xi'an, Zhou, Baoku, Chen, Xueli, Jin, Jian, Liu, Xiaobing, Wang, Guanghua
Format Journal Article
LanguageEnglish
Published Elsevier B.V 15.07.2022
Subjects
acetyl coenzyme A
agroecosystems
anaerobic ammonium oxidation
Carbon and nitrogen cycling
China
denitrification
Functional genes
genes
geographical distribution
Long-term fertilization
metagenomics
methane
Mollisols
nitrates
nitrogen
oxidation
Planctomycetes
Proteobacteria
soil
soil carbon
Soil metagenomics
soil nutrients
Verrucomicrobia
China
Long-term fertilization
Soil metagenomics
Carbon and nitrogen cycling
Mollisols
Functional genes
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Abstract •Biogeographic distance rather than fertilization dominated microbial functional profiles in Mollisols.•Chemical fertilization promoted processes of methane oxidation, soil N degradation, nitrification and anammox.•Manure fertilization shifted C fixation and degradation processes and facilitated nitrate reduction.•Chemical plus manure fertilization could potentially enhance N2O emission via denitrification.•Soil P contents were the most influential factor in controlling microbial functional profiles. The long-term effects of different fertilization regimes on the microbial functional potential of soils involving nutrient cycling remain largely unknown. Here, metagenomic sequencing was applied to investigate the influences of long-term chemical and organic fertilization on soil microbial C and N cycling across southern, middle and northern sites of black soil region in Northeast China. The results showed that biogeographic distance induced the most influential on the microbial functional profiles of soil C and N cycling, and significant effects of manure fertilization were detected across three experimental sites. Organic fertilization enriched the relative abundances of Proteobacteria and Planctomycetes that carry C and N cycling genes, while inhibited the growth of oligotrophic groups such as Verrucomicrobia. Chemical fertilization increased the gene abundances involved in methane oxidation, but had little effect on soil C degradation and fixation. Contrarily, manure fertilization, particularly the combination of chemical and organic fertilizers (CFM), significantly decreased the abundance of cooC (reductive acetyl-CoA pathway) and coxS (CO oxidation) while enhanced the abundance of icd (rTCA cycle), which are involved in C fixation. Additionally, chemical fertilization enriched the gene abundance that involved in soil N degradation, nitrification and anammox, whereas manure fertilization was beneficial for the functional potentials of assimilatory and dissimilatory nitrate reductions across the black soils. However, CFM significantly promoted the soil denitrification potential, possibly due to excess N input, which might result in soil N loss via the emission of nitrogenous gas in this region. Furthermore, the substantial enhancement in soil P contents induced by manure addition predominantly affected the C and N cycling profiles, abundance of functional genes and microbial taxa. Moreover, diverse correlations between C and N cycling genes suggested the synergetic or antagonistic interactions of C and N metabolic potentials in the black soils. Overall, this study provided in-depth insights into distinct microbial functional potentials under long-term chemical and organic fertilization that may have predictable consequences for soil nutrient cycling in agroecosystems of black soil region.
AbstractList The long-term effects of different fertilization regimes on the microbial functional potential of soils involving nutrient cycling remain largely unknown. Here, metagenomic sequencing was applied to investigate the influences of long-term chemical and organic fertilization on soil microbial C and N cycling across southern, middle and northern sites of black soil region in Northeast China. The results showed that biogeographic distance induced the most influential on the microbial functional profiles of soil C and N cycling, and significant effects of manure fertilization were detected across three experimental sites. Organic fertilization enriched the relative abundances of Proteobacteria and Planctomycetes that carry C and N cycling genes, while inhibited the growth of oligotrophic groups such as Verrucomicrobia. Chemical fertilization increased the gene abundances involved in methane oxidation, but had little effect on soil C degradation and fixation. Contrarily, manure fertilization, particularly the combination of chemical and organic fertilizers (CFM), significantly decreased the abundance of cooC (reductive acetyl-CoA pathway) and coxS (CO oxidation) while enhanced the abundance of icd (rTCA cycle), which are involved in C fixation. Additionally, chemical fertilization enriched the gene abundance that involved in soil N degradation, nitrification and anammox, whereas manure fertilization was beneficial for the functional potentials of assimilatory and dissimilatory nitrate reductions across the black soils. However, CFM significantly promoted the soil denitrification potential, possibly due to excess N input, which might result in soil N loss via the emission of nitrogenous gas in this region. Furthermore, the substantial enhancement in soil P contents induced by manure addition predominantly affected the C and N cycling profiles, abundance of functional genes and microbial taxa. Moreover, diverse correlations between C and N cycling genes suggested the synergetic or antagonistic interactions of C and N metabolic potentials in the black soils. Overall, this study provided in-depth insights into distinct microbial functional potentials under long-term chemical and organic fertilization that may have predictable consequences for soil nutrient cycling in agroecosystems of black soil region.
•Biogeographic distance rather than fertilization dominated microbial functional profiles in Mollisols.•Chemical fertilization promoted processes of methane oxidation, soil N degradation, nitrification and anammox.•Manure fertilization shifted C fixation and degradation processes and facilitated nitrate reduction.•Chemical plus manure fertilization could potentially enhance N2O emission via denitrification.•Soil P contents were the most influential factor in controlling microbial functional profiles. The long-term effects of different fertilization regimes on the microbial functional potential of soils involving nutrient cycling remain largely unknown. Here, metagenomic sequencing was applied to investigate the influences of long-term chemical and organic fertilization on soil microbial C and N cycling across southern, middle and northern sites of black soil region in Northeast China. The results showed that biogeographic distance induced the most influential on the microbial functional profiles of soil C and N cycling, and significant effects of manure fertilization were detected across three experimental sites. Organic fertilization enriched the relative abundances of Proteobacteria and Planctomycetes that carry C and N cycling genes, while inhibited the growth of oligotrophic groups such as Verrucomicrobia. Chemical fertilization increased the gene abundances involved in methane oxidation, but had little effect on soil C degradation and fixation. Contrarily, manure fertilization, particularly the combination of chemical and organic fertilizers (CFM), significantly decreased the abundance of cooC (reductive acetyl-CoA pathway) and coxS (CO oxidation) while enhanced the abundance of icd (rTCA cycle), which are involved in C fixation. Additionally, chemical fertilization enriched the gene abundance that involved in soil N degradation, nitrification and anammox, whereas manure fertilization was beneficial for the functional potentials of assimilatory and dissimilatory nitrate reductions across the black soils. However, CFM significantly promoted the soil denitrification potential, possibly due to excess N input, which might result in soil N loss via the emission of nitrogenous gas in this region. Furthermore, the substantial enhancement in soil P contents induced by manure addition predominantly affected the C and N cycling profiles, abundance of functional genes and microbial taxa. Moreover, diverse correlations between C and N cycling genes suggested the synergetic or antagonistic interactions of C and N metabolic potentials in the black soils. Overall, this study provided in-depth insights into distinct microbial functional potentials under long-term chemical and organic fertilization that may have predictable consequences for soil nutrient cycling in agroecosystems of black soil region.
ArticleNumber 115846
Author Liu, Xiaobing
Jin, Jian
Wang, Guanghua
Gu, Haidong
Wei, Dan
Cui, Xi'an
Hu, Xiaojing
Zhu, Ping
Zhou, Baoku
Liu, Junjie
Chen, Xueli
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– sequence: 2
  givenname: Haidong
  surname: Gu
  fullname: Gu, Haidong
  organization: Key Laboratory of Mollisols Agroecology, Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, Harbin 150081, China
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  givenname: Junjie
  surname: Liu
  fullname: Liu, Junjie
  organization: Key Laboratory of Mollisols Agroecology, Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, Harbin 150081, China
– sequence: 4
  givenname: Dan
  surname: Wei
  fullname: Wei, Dan
  organization: Institute of Soil and Fertilizer and Environment Resources, Heilongjiang Academy of Agricultural Sciences, Harbin 150086, China
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  surname: Zhu
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  organization: Institute of Agricultural Resource and Environment, Jilin Academy of Agricultural Sciences, Changchun 130033, China
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  fullname: Cui, Xi'an
  organization: Heihe Branch of Heilongjiang Academy of Agricultural Sciences, Heihe 164300, China
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  surname: Zhou
  fullname: Zhou, Baoku
  organization: Institute of Soil and Fertilizer and Environment Resources, Heilongjiang Academy of Agricultural Sciences, Harbin 150086, China
– sequence: 8
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  surname: Chen
  fullname: Chen, Xueli
  organization: Institute of Soil and Fertilizer and Environment Resources, Heilongjiang Academy of Agricultural Sciences, Harbin 150086, China
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  givenname: Jian
  surname: Jin
  fullname: Jin, Jian
  organization: Key Laboratory of Mollisols Agroecology, Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, Harbin 150081, China
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– sequence: 11
  givenname: Guanghua
  surname: Wang
  fullname: Wang, Guanghua
  email: wanggh@iga.ac.cn
  organization: Key Laboratory of Mollisols Agroecology, Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, Harbin 150081, China
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Keywords Long-term fertilization
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PublicationDate_xml – month: 07
  year: 2022
  text: 2022-07-15
  day: 15
PublicationDecade 2020
PublicationTitle Geoderma
PublicationYear 2022
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Snippet •Biogeographic distance rather than fertilization dominated microbial functional profiles in Mollisols.•Chemical fertilization promoted processes of methane...
The long-term effects of different fertilization regimes on the microbial functional potential of soils involving nutrient cycling remain largely unknown....
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SubjectTerms acetyl coenzyme A
agroecosystems
anaerobic ammonium oxidation
Carbon and nitrogen cycling
China
denitrification
Functional genes
genes
geographical distribution
Long-term fertilization
metagenomics
methane
Mollisols
nitrates
nitrogen
oxidation
Planctomycetes
Proteobacteria
soil
soil carbon
Soil metagenomics
soil nutrients
Verrucomicrobia
Title Metagenomics reveals divergent functional profiles of soil carbon and nitrogen cycling under long-term addition of chemical and organic fertilizers in the black soil region
URI https://dx.doi.org/10.1016/j.geoderma.2022.115846
https://www.proquest.com/docview/2648876264
Volume 418
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