Nitrogen content and C/N ratio in straw are the key to affect biological nitrogen fixation in a paddy field

Background and aims Straw amendment can increase nitrogen fixation in paddy field, however, the efficiency of carbon sources with different biochemical properties to enhance N 2 fixation and nitrogen fixation activity is still unclear. Methods A 15 N 2 -labelling system was used in the field environ...

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Published in	Plant and soil Vol. 481; no. 1-2; pp. 535 - 546
Main Authors	Zhang, Yanhui, Hu, Tianlong, Wang, Hui, Jin, Haiyang, Liu, Qi, Chen, Zhe, Xie, Zubin
Format	Journal Article
Language	English
Published	Cham Springer International Publishing 01.12.2022 Springer Springer Nature B.V
Subjects	Abundance Agricultural land Agricultural research Agriculture Biomedical and Life Sciences Carbon Carbon sources Carbon/nitrogen ratio Chemical properties Community composition community structure Cyanobacteria DNA Ecology Environmental aspects Fixation Fluorescence genes Genetic aspects Labeling Life Sciences Microorganisms Next-generation sequencing NifH gene Nitrogen nitrogen content Nitrogen fixation Nitrogen-fixing bacteria Nitrogenation paddies Physiological aspects Plant Physiology Plant Sciences Poplar Populus quantitative polymerase chain reaction Research Article Rice RNA soil Soil Science & Conservation Straw Wheat Wheat straw China direct labelling RNA gene Biological nitrogen fixation gene N Carbon sources
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Abstract	Background and aims Straw amendment can increase nitrogen fixation in paddy field, however, the efficiency of carbon sources with different biochemical properties to enhance N 2 fixation and nitrogen fixation activity is still unclear. Methods A 15 N 2 -labelling system was used in the field environment to determine biological nitrogen fixation (BNF) under the addition of three kinds of straw. The nifH gene (DNA) and nifH RNA gene (cDNA) of soil were amplified by real-time fluorescent quantitative PCR. The diversity and community composition of nitrogen fixing microorganisms were studied by high-throughput sequencing. The study is expected to reveal how different carbon sources impact biological nitrogen fixation and its mechanism in the paddy field system. Results Results showed that the absolute abundance diazotrophs in the treatment of mature stage wheat straw (MWS) was 4.88 times as high as that in the CK treatment, but jointing stage wheat straw (JWS) and poplar branch (PB) did not induce any significant changes. Straw amendment had no impact on cyanobacteria abundance. The proportion of N 2 fixation increased by MWS was 2.07 times, but which was much lower than the increase proportion of the heterotrophic diazotrophs, leading to a decrease of diazotrophic nitrogen fixation activity. Conclusions Mature wheat straw addition increased biologically fixed nitrogen in paddy field by increasing the number of heterotrophic nitrogen fixing bacteria. The results indicated that to increase biological N 2 fixation in paddy system, straws with low nitrogen content and high C/N ratio were recommended.
AbstractList	Abstract Background and aimsStraw amendment can increase nitrogen fixation in paddy field, however, the efficiency of carbon sources with different biochemical properties to enhance N2 fixation and nitrogen fixation activity is still unclear.MethodsA 15N2-labelling system was used in the field environment to determine biological nitrogen fixation (BNF) under the addition of three kinds of straw. The nifH gene (DNA) and nifH RNA gene (cDNA) of soil were amplified by real-time fluorescent quantitative PCR. The diversity and community composition of nitrogen fixing microorganisms were studied by high-throughput sequencing. The study is expected to reveal how different carbon sources impact biological nitrogen fixation and its mechanism in the paddy field system.ResultsResults showed that the absolute abundance diazotrophs in the treatment of mature stage wheat straw (MWS) was 4.88 times as high as that in the CK treatment, but jointing stage wheat straw (JWS) and poplar branch (PB) did not induce any significant changes. Straw amendment had no impact on cyanobacteria abundance. The proportion of N2 fixation increased by MWS was 2.07 times, but which was much lower than the increase proportion of the heterotrophic diazotrophs, leading to a decrease of diazotrophic nitrogen fixation activity.ConclusionsMature wheat straw addition increased biologically fixed nitrogen in paddy field by increasing the number of heterotrophic nitrogen fixing bacteria. The results indicated that to increase biological N2 fixation in paddy system, straws with low nitrogen content and high C/N ratio were recommended. Background and aims Straw amendment can increase nitrogen fixation in paddy field, however, the efficiency of carbon sources with different biochemical properties to enhance N 2 fixation and nitrogen fixation activity is still unclear. Methods A 15 N 2 -labelling system was used in the field environment to determine biological nitrogen fixation (BNF) under the addition of three kinds of straw. The nifH gene (DNA) and nifH RNA gene (cDNA) of soil were amplified by real-time fluorescent quantitative PCR. The diversity and community composition of nitrogen fixing microorganisms were studied by high-throughput sequencing. The study is expected to reveal how different carbon sources impact biological nitrogen fixation and its mechanism in the paddy field system. Results Results showed that the absolute abundance diazotrophs in the treatment of mature stage wheat straw (MWS) was 4.88 times as high as that in the CK treatment, but jointing stage wheat straw (JWS) and poplar branch (PB) did not induce any significant changes. Straw amendment had no impact on cyanobacteria abundance. The proportion of N 2 fixation increased by MWS was 2.07 times, but which was much lower than the increase proportion of the heterotrophic diazotrophs, leading to a decrease of diazotrophic nitrogen fixation activity. Conclusions Mature wheat straw addition increased biologically fixed nitrogen in paddy field by increasing the number of heterotrophic nitrogen fixing bacteria. The results indicated that to increase biological N 2 fixation in paddy system, straws with low nitrogen content and high C/N ratio were recommended. Background and aims Straw amendment can increase nitrogen fixation in paddy field, however, the efficiency of carbon sources with different biochemical properties to enhance N.sub.2 fixation and nitrogen fixation activity is still unclear. Methods A .sup.15N.sub.2-labelling system was used in the field environment to determine biological nitrogen fixation (BNF) under the addition of three kinds of straw. The nifH gene (DNA) and nifH RNA gene (cDNA) of soil were amplified by real-time fluorescent quantitative PCR. The diversity and community composition of nitrogen fixing microorganisms were studied by high-throughput sequencing. The study is expected to reveal how different carbon sources impact biological nitrogen fixation and its mechanism in the paddy field system. Results Results showed that the absolute abundance diazotrophs in the treatment of mature stage wheat straw (MWS) was 4.88 times as high as that in the CK treatment, but jointing stage wheat straw (JWS) and poplar branch (PB) did not induce any significant changes. Straw amendment had no impact on cyanobacteria abundance. The proportion of N.sub.2 fixation increased by MWS was 2.07 times, but which was much lower than the increase proportion of the heterotrophic diazotrophs, leading to a decrease of diazotrophic nitrogen fixation activity. Conclusions Mature wheat straw addition increased biologically fixed nitrogen in paddy field by increasing the number of heterotrophic nitrogen fixing bacteria. The results indicated that to increase biological N.sub.2 fixation in paddy system, straws with low nitrogen content and high C/N ratio were recommended. BACKGROUND AND AIMS: Straw amendment can increase nitrogen fixation in paddy field, however, the efficiency of carbon sources with different biochemical properties to enhance N₂ fixation and nitrogen fixation activity is still unclear. METHODS: A ¹⁵N₂-labelling system was used in the field environment to determine biological nitrogen fixation (BNF) under the addition of three kinds of straw. The nifH gene (DNA) and nifH RNA gene (cDNA) of soil were amplified by real-time fluorescent quantitative PCR. The diversity and community composition of nitrogen fixing microorganisms were studied by high-throughput sequencing. The study is expected to reveal how different carbon sources impact biological nitrogen fixation and its mechanism in the paddy field system. RESULTS: Results showed that the absolute abundance diazotrophs in the treatment of mature stage wheat straw (MWS) was 4.88 times as high as that in the CK treatment, but jointing stage wheat straw (JWS) and poplar branch (PB) did not induce any significant changes. Straw amendment had no impact on cyanobacteria abundance. The proportion of N₂ fixation increased by MWS was 2.07 times, but which was much lower than the increase proportion of the heterotrophic diazotrophs, leading to a decrease of diazotrophic nitrogen fixation activity. CONCLUSIONS: Mature wheat straw addition increased biologically fixed nitrogen in paddy field by increasing the number of heterotrophic nitrogen fixing bacteria. The results indicated that to increase biological N₂ fixation in paddy system, straws with low nitrogen content and high C/N ratio were recommended.
Audience	Academic
Author	Wang, Hui Zhang, Yanhui Jin, Haiyang Xie, Zubin Chen, Zhe Hu, Tianlong Liu, Qi
Author_xml	– sequence: 1 givenname: Yanhui surname: Zhang fullname: Zhang, Yanhui organization: State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences, School of Geography, Nanjing Normal University – sequence: 2 givenname: Tianlong surname: Hu fullname: Hu, Tianlong organization: State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences, University of Chinese Academy of Sciences – sequence: 3 givenname: Hui surname: Wang fullname: Wang, Hui organization: State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences, University of Chinese Academy of Sciences – sequence: 4 givenname: Haiyang surname: Jin fullname: Jin, Haiyang organization: Wheat Research Institute, Henan Academy of Agricultural Sciences – sequence: 5 givenname: Qi surname: Liu fullname: Liu, Qi organization: Co-Innovation Center for Sustainable Forestry in Southern China, Nanjing Forestry University – sequence: 6 givenname: Zhe surname: Chen fullname: Chen, Zhe organization: State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences, University of Chinese Academy of Sciences – sequence: 7 givenname: Zubin orcidid: 0000-0002-9610-2874 surname: Xie fullname: Xie, Zubin email: zbxie@issas.ac.cn organization: State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences
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Snippet	Background and aims Straw amendment can increase nitrogen fixation in paddy field, however, the efficiency of carbon sources with different biochemical... Background and aims Straw amendment can increase nitrogen fixation in paddy field, however, the efficiency of carbon sources with different biochemical... Abstract Background and aimsStraw amendment can increase nitrogen fixation in paddy field, however, the efficiency of carbon sources with different biochemical... BACKGROUND AND AIMS: Straw amendment can increase nitrogen fixation in paddy field, however, the efficiency of carbon sources with different biochemical...
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SubjectTerms	Abundance Agricultural land Agricultural research Agriculture Biomedical and Life Sciences Carbon Carbon sources Carbon/nitrogen ratio Chemical properties Community composition community structure Cyanobacteria DNA Ecology Environmental aspects Fixation Fluorescence genes Genetic aspects Labeling Life Sciences Microorganisms Next-generation sequencing NifH gene Nitrogen nitrogen content Nitrogen fixation Nitrogen-fixing bacteria Nitrogenation paddies Physiological aspects Plant Physiology Plant Sciences Poplar Populus quantitative polymerase chain reaction Research Article Rice RNA soil Soil Science & Conservation Straw Wheat Wheat straw
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Title	Nitrogen content and C/N ratio in straw are the key to affect biological nitrogen fixation in a paddy field
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