Increased ammonification, nitrogenase, soil respiration and microbial biomass N in the rhizosphere of rice plants inoculated with rhizobacteria

doi:10.1016/S2095-3119(20)63454-2

Journal of Integrative Agriculture ›› 2021, Vol. 20 ›› Issue (10): 2781-2796.DOI: 10.1016/S2095-3119(20)63454-2

所属专题：农业生态环境-土壤微生物合辑Agro-ecosystem & Environment—Soil microbe

收稿日期:2020-04-08 出版日期:2021-10-01 发布日期:2021-08-09

Increased ammonification, nitrogenase, soil respiration and microbial biomass N in the rhizosphere of rice plants inoculated with rhizobacteria

ZHANG Jun-hua^1*, HUANG Jing^1*, Sajid HUSSAIN¹, ZHU Lian-feng¹, CAO Xiao-chuang¹, ZHU Chun-quan¹, JIN Qian-yu¹, ZHANG Hui²

¹ State Key Laboratory of Rice Biology, China National Rice Research Institute, Hangzhou 310006, P.R.China
² Agricultural Resources and Environment Institute, Jiangsu Academy of Agricultural Sciences, Nanjing 210014, P.R.China

Received:2020-04-08 Online:2021-10-01 Published:2021-08-09
Contact: Correspondence ZHANG Hui, E-mail: hzhanga@126.com; JIN Qian-yu, E-mail: jingqianyun@126.com
About author:ZHANG Jun-hua, E-mail: zhangjunhua@caas.cn; HUANG Jing, E-mail: 769672695@qq.com; * These authors contributed equally to this study.
Supported by:
This study was financially supported by the National Key Research and Development Program of China (2016YFD0200801, 2016YFD0200805), the National Natural Science Foundation of China (31872857), the Foundation of State Key Laboratory of Rice Biology, China National Rice Research Institute (2017ZZKT10404), and the Zhejiang Provincial Natural Science Foundation of China (LY16C130007).

摘要/Abstract

摘要：

Azospirillum brasilense与Pseudomonas fluorescens是应用广泛的植物根际促生菌。目前Azospirillum brasilense与Pseudomonas fluorescens对稻田土壤氮循环和水稻生长发育的影响尚不清楚。本研究通过两年田间试验（2016-2017）解析了Azospirillum brasilense与Pseudomonas fluorescens对水稻根际土壤氮素转化和供氮能力的影响，明确了Azospirillum brasilense与Pseudomonas fluorescens在稻田肥料减施增效中的作用。微生物接种包括4个处理，分别为生理盐水接种（对照，M₀），水稻幼苗接种Azospirillum brasilense（M_b），水稻幼苗接种Pseudomonas fluorescens（M_p），水稻幼苗接种Azospirillum brasilense与Pseudomonas fluorescens的混合物（M_bp）。氮肥施用水平包括4个处理，分别为0 kg N hm^-2（N₀）)，90 kg N hm^-2（N₉₀），180 kg N hm^-2（N₁₈₀），270 kg N hm^-2 （N₂₇₀）。结果表明，与M₀相比，M_bp与M_p处理显著增强了水稻根际土壤氨化作用强度，高氮条件下提升作用更显著。与M₀相比，M_bp与M_b处理显著增强了水稻根际土壤固氮酶活性，低氮条件下提升作用更显著。接种用的Azospirillum brasilense与Pseudomonas fluorescens不参与水稻根际土壤的硝化和反硝化过程。根际促生菌与氮肥的交互作用对土壤呼吸速率与微生物量氮有显著影响。在M_bp处理中，N₉₀、N₁₈₀、N₂₇₀处理的土壤供氮能力与水稻产量无显著差异。水稻幼苗接种Azospirillum brasilense与Pseudomonas fluorescens的混合物，可将该地区氮肥施用量降至90 kg N hm^-2。

Abstract:

Azospirillum brasilense and Pseudomonas fluorescens are well-known plant growth promoting rhizobacteria. However, the effects of A. brasilense and P. fluorescens on the N cycles in the paddy field and rice plant growth are little known. This study investigated whether and how A. brasilense and P. fluorescens contribute to the N transformations and N supply capacities in the rhizosphere, and clarified the effects of A. brasilense and P. fluorescens on the N application rate in rice cultivation. Inoculations with A. brasilense and P. fluorescens coupled with N application rate trials were conducted in the paddy field in 2016 and 2017. The inoculations of rice seedlings included four treatments: sterile saline solution (M₀), A. brasilense (M_b), P. fluorescens (M_p), and co-inoculation with a mixture of A. brasilense and P. fluorescens (M_bp). The N application rate included four levels: 0 kg N ha^–1 (N₀), 90 kg N ha^–1 (N₉₀), 180 kg N ha^–1 (N₁₈₀), and 270 kg N ha^–1 (N₂₇₀). The results indicated that the M_bp and M_p treatments significantly enhanced the ammonification activities in the rhizosphere compared with the M₀ treatment, especially for higher N applications, while the M_bp and M_b treatments greatly enhanced the nitrogenase activities in the rhizosphere compared with the M₀ treatments, especially for lower N applications. Azospirillum brasilense and P. fluorescens did not participate in the nitrification processes or the denitrification processes in the soil. The soil respiration rate and microbial biomass N were greatly affected by the interactions between the rhizobacteria inoculations and the N fertilizer applications. In the M_bp treatment, N supply capacities and rice grain yields showed no significant differences among the N₉₀, N₁₈₀, and N₂₇₀ applications. The N application rate in the study region can be reduced to 90 kg N ha^–1 for rice seedlings co-inoculated with a mixture of A. brasilense and P. fluorescens.

Key words: N transformation , paddy soil , plant growth promoting rhizobacteria , rice productivity

. [J]. Journal of Integrative Agriculture, 2021, 20(10): 2781-2796.

ZHANG Jun-hua, HUANG Jing, Sajid HUSSAIN, ZHU Lian-feng, CAO Xiao-chuang, ZHU Chun-quan, JIN Qian-yu, ZHANG Hui. Increased ammonification, nitrogenase, soil respiration and microbial biomass N in the rhizosphere of rice plants inoculated with rhizobacteria[J]. Journal of Integrative Agriculture, 2021, 20(10): 2781-2796.

参考文献

Bhardwaj D, Ansari M W, Sahoo R K, Tuteja N. 2014. Biofertilizers function as key player in sustainable agriculture by improving soil fertility, plant tolerance and crop productivity. Microbial Cell Factories, 13, 66–76.
Cao Y, Tian Y, Yin B, Zhu Z. 2014. Improving agronomic practices to reduce nitrate leaching from the rice–wheat rotation system. Agriculture Ecosystems and Environment, 195, 61–67.
Craig M E, Fraterrigo J M. 2017. Plant-microbial competition for nitrogen increases microbial activities and carbon loss in invaded soils. Oecologia, 184, 583–596.
Cui P Y. 2016. The effect of fertilization, nitrification inhibitor and temperature on N2O emissions in cropland soils and its associated micorobes. Ph D thesis, Chinese Academy of Agricultural Sciences, Beijing, China. (in Chinese)
Dai S Y, Wang J, Cheng Y, Zhang J B, Cai Z C. 2017. Effects of long-term fertilization on soil gross N transformation rates and their implications. Journal of Integrative Agriculture, 16, 2863–2870.
Etesami H, Alikhani H A. 2016. Co-inoculation with endophytic and rhizosphere bacteria allows reduced application rates of N-fertilizer for rice plant. Rhizosphere, 2, 5–12.
Flores P, Fenoll J, Hellin P, Aparicio-Tejo P. 2010. Isotopic evidence of significant assimilation of atmospheric-derived nitrogen fixed by Azospirillum brasilense co-inoculated with phosphate-solubilising Pantoea dispersa in pepper seedling. Applied Soil Ecology, 46, 335–340.
Gao W L, Yang H, Kou L, Li S G. 2015. Effects of nitrogen deposition and fertilization on N transformations in forest soils: A review. Journal of Soils and Sediments, 15, 863–879.
Haque S M S, Ferdoshi R, Miah S, Anwar M N. 2012. Clear felling and burning effects on soil nitrogen transforming bacteria and actinomycetes population in Chittagong University campus, Bangladesh. Journal of Forest Research, 23, 123–130.
Herridge D F, Peoples M B, Boddey R M. 2008. Global inputs of biological nitrogen fixation in agricultural systems. Plant and Soil, 311, 1–18.
Inselsbacher E, Ripka K, Klaubauf S, Fedosoyenko D, Hackl E. 2009. A cost-effective high-throughput microcosm system for studying nitrogen dynamics at the plant-microbe-soil interface. Plant and Soil, 317, 293–307.
Iovieno P, Morra L, Leone A, Pagano L, Alfani A. 2009. Effect of organic and mineral fertilizers on soil respiration and enzyme activities of two Mediterranean horticultural soils. Biology and Fertility of Soils, 45, 555–561.
Kanerva S, Smolande A. 2007. Microbial activities in forest floor layers under silver birch, Norway spruce and Scots pine. Soil Biology and Biochemistry, 39, 1459–1467.
Kox M A R, Jetten M S M. 2015. The nitrogen cycle. In: Lugtenberg B, ed., Principles of Plant-Microbe Interactions. Springer, Switzerland. pp. 205–214.
Leite R C, dos Santos J G D, Silva E L, Alves C R C R, Hungria M, Leite R C, dos Santos A C. 2019. Productivity increase, reduction of nitrogen fertilizer use and drought-stress mitigation by inoculation of Marandu grass (Urochloa brizantha) with Azospirillum brasilense. Crop & Pasture Science, 70, 61–67.
Levy-Booth D J, Prescott C E, Grayston S J. 2014. Microbial functional genes involved in nitrogen fixation, nitrification and denitrification in forest ecosystems. Soil Biology and Biochemistry, 75, 11–25.
Li Z G, Luo Y M, Teng Y. 2008. Methods for Studying Microorganisms in Soil and Environment. Science Press, Beijing. (in Chinese)
Lou W P, Wu L H, Chen H Y, Ji Z W. 2012. Assessment of rice yield loss due to torrential rain: A case study of Yuhang County, Zhejiang Province, China. Natural Hazards, 60, 311–320.
Lu R K. 1999. The Agricultural Chemical Analysis Methods in Soil. China Agricultural Science and Technology Press, Beijing, China. (in Chinese)
Mahanty T, Bhattacharjee S, Goswami M, Bhattacharyya P, Das B, Ghosh A, Tribedi P. 2017. Biofertilizers: A potential approach for sustainable agriculture development. Environmental Science and Pollution Research, 24, 3315–3335.
Mamai A V, Stepanov A L, Fedorets N G. 2013. Microbial transformation of nitrogen compounds in Middle Taiga soils. Moscow University Soil Science Bulletin, 68, 174–179.
Martikainen P J, Palojärvi A. 1990. Evaluation of the fumigation extraction method for the determination of microbial C and N in a range of forest soils. Soil Biology and Biochemistry, 22, 797–802.
Pedraza R O, Bellone C H, Bellone S C D, Sorte P M F B, Teixeira K R D S. 2009. Azospirillum inoculation and nitrogen fertilization effect on grain yield and on the diversity of endophytic bacteria in the phyllosphere of rice rainfed crop. European Journal of Soil Biology, 45, 36–43.
Perelomov L V, Chulin A N. 2014. Molecular mechanisms of interaction of microelements with microorganisms in the environment.direct biological transformation of microelement compounds. Biology Bulletin Reviews, 4, 285–299.
Piccinin G G, Braccini A L, Dan L G M, Scapim C A, Ricci T T, Bazo G L. 2013. Efficiency of seed inoculation with Azospirillum brasilense on agronomic characteristics and yield of wheat. Industrial Crops and Products, 43, 393–397.
Pii Y, Mimmo T, Tomasi N, Terzano R, Cesco S, Crecchio C. 2015. Microbial interactions in the rhizosphere: beneficial influences of plant growth-promoting rhizobacteria on nutrient acquisition process. A review. Biology and Fertility of Soils, 51, 403–415.
Prabhukarthikeyan S R, Keerthana U, Raguchander T. 2018. Antibiotic-producing Pseudomonas fluorescens mediates rhizome rot disease resistance and promotes plant growth in turmeric plants. Microbiological Research, 210, 65–73.
Rêgo M C F, Cardoso A F, Ferreira T C, de Filippi M C C, Batista T F V, Viana R G, Silva G B. 2018. The role of rhizobacteria in rice plants: Growth and mitigation of toxicity. Journal of Integrative Agriculture, 17, 2636–2647.
Rodrigues E P, Rodrigues L S, Oliveira A L M, Baldani V L D, Teixeira K R S, Urquiaga S, Reis V M. 2008. Azospirillum amazonense inoculation: Effects on growth, yield and N2 fixation of rice (Oryza sativa L.). Plant and Soil, 302, 249–261.
Salamone I E G, Salvo L P D, Ortega J S E, Sorte P M F B, Urquiaga S, Tixeira K R S. 2010. Field response of rice paddy crop to Azospirillum inoculation: Physiology of rhizosphere bacterial communities and the genetic diversity of endophytic bacteria in different parts of the plants. Plant and Soil, 336, 351–362.
Singh J S. 2013. Plant growth promoting rhizobacteria. Resonance, 18, 275–281.
Souza R, Beneduzi A, Ambrosini A, Costa P B, Meyer J, Vargas L K, Schoenfeld R, Passaglia L M P. 2013. The effect of plant growth-promoting rhizobacteria on the growth of rice (Oryza sativa L.) cropped in southern Brazilian fields. Plant and Soil, 366, 585–603.
Wang J. 2017. Mechanistic insights into the role of soil nitrogen transformation processes in regulating soil nitrogen fate. Ph D thesis, Nanjing Normal University, Nanjing, China. (in Chinese)
Yadav B K, Akhtar M S, Panwar J. 2015. Rhizospheric plant–microbe interactions: Key factors to soil fertility and plant nutrition. In: Arora N, ed., Plant Microbes Symbiosis: Applied Facets. Springer, New Delhi. pp. 127–145.
Yu Y L, Yang L Z, Hou F, Xue L H, Odindo A O. 2018. Nitrogen management in the rice–wheat system of China and South Asia. Sustainable Agriculture Reviews, 32, 135–167.
Yuan H Z, Zhu Z K, Wei X M, Liu S L, Peng P Q, Gunina A, Shen J L, Kuzyakov Y, Ge T D, Wu J S, Wang J R. 2019. Straw and biochar strongly affect functional diversity of microbial metabolism in paddy soils. Journal of Integrative Agriculture, 18, 1474–1485.
Zhang J H, Hussain S, Zhao F T, Zhu L F, Cao X C, Yu S M, Jin Q Y. 2018. Effects of Azospirillum brasilense and Pseudomonas fluorescens on nitrogen transformation and enzyme activity in the rice rhizosphere. Journal of Soils and Sediments, 18, 1453–1465.
Zhou Z M, Takaya N, Sakairi M A C, Shoun H. 2001. Oxygen requirement for denitrification by the fungus Fusarium oxysporum. Archives of Microbiology, 175, 19–25.

Increased ammonification, nitrogenase, soil respiration and microbial biomass N in the rhizosphere of rice plants inoculated with rhizobacteria

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

编辑推荐

Metrics