Effects of long-term no-tillage on the functional potential of microorganisms involved in the nitrogen, phosphorus and sulfur cycles of black soil

doi:10.13287/j.1001-9332.202304.011

Abstract

Abstract: Understanding the effects of different tillage practices on functional microbial abundance and composition in nitrogen (N), phosphorus (P) and sulfur (S) cycles are essential for the sustainable utilization of black soils. Based on an 8-year field experiment located in Changchun, Jilin Province, we analyzed the abundance and composition of N, P and S cycling microorganisms and their driving factors in different depths of black soil under no til-lage (NT) and conventional tillage (CT). Results showed that compared with CT, NT significantly increased soil water content (WC) and microbial biomass carbon (MBC) at soil depth of 0-20 cm. Compared with CT, NT significantly increased the abundances of functional and encoding genes related to N, P and S cycling, including the nosZ gene encoding N₂O reductase, the ureC gene performing organic nitrogen ammoniation, the nifH gene encoding nitrogenase ferritin, the functional genes phnK and phoD driving organic phosphorus mineralization, the encoding pyrroloquinoline quinone synthase ppqC gene and the encoding exopolyphosphate esterase ppX gene, and the soxY and yedZ genes driving sulfur oxidation. The results of variation partitioning analysis and redundancy analysis showed that soil basic properties were the main factors affecting the microbial composition of N, P and S cycle functions (the total interpretation rate was 28.1%), and that MBC and WC were the most important drivers of the functional potential of soil microorganisms in N, P and S cycling. Overall, long-term no tillage could increase the abundance of functional genes of soil microorganisms by affecting soil environment. From the perspective of molecular biology, our results elucidated that no tillage could be used as an effective soil management measure to improve soil health and maintain green agricultural development.

Key words: no tillage, residue returned, biogeochemical cycling, functional genes, quantitative microbial element cycling (QMEC)

GAO Yan, LIANG Aizhen, HUANG Dandan, ZHANG Yan, ZHANG Yang, WANG Yang, ZHANG Shixiu, CHEN Xuewen. Effects of long-term no-tillage on the functional potential of microorganisms involved in the nitrogen, phosphorus and sulfur cycles of black soil[J]. Chinese Journal of Applied Ecology, 2023, 34(4): 913-920.

References 40

[1]	Liu WL, Jiang YL, Wang GX, et al. Effects of N addition and clipping on above and belowground plant biomass, soil microbial community structure, and function in an alpine meadow on the Qinghai-Tibetan Plateau. European Journal of Soil Biology, 2021, 106: 103344
[2]	Yang HS, Li Y, Zhai S, et al. Long term ditch-buried straw return affects soil fungal community structure and carbon-degrading enzymatic activities in a rice-wheat rotation system. Applied Soil Ecology, 2020, 155: 103660
[3]	朱利霞, 岳善超, 沈玉芳, 等. 施氮和覆膜对旱作春玉米农田土壤微生物量和土壤酶活性的影响. 干旱地区农业研究, 2019, 37(1): 130-136
[4]	宋长青, 吴金水, 陆雅海, 等. 中国土壤微生物学研究10年回顾. 地球科学进展, 2013, 28(10): 1087-1105
[5]	Zhang Y, Li XJ, Gregorich EG, et al. No-tillage with continuous maize cropping enhances soil aggregation and organic carbon storage in Northeast China. Geoderma, 2018, 330: 204-211
[6]	徐蒋来, 尹思慧, 胡乃娟, 等. 周年秸秆还田对稻麦轮作农田土壤养分、微生物活性及产量的影响. 应用与环境生物学报, 2015, 21(6): 1100-1105
[7]	张俊伶, 张江周, 申建波, 等. 土壤健康与农业绿色发展: 机遇与对策. 土壤学报, 2020, 57(4): 783-796
[8]	Wang W, Akhtar K, Ren G, et al. Impact of straw mana-gement on seasonal soil carbon dioxide emissions, soil water content, and temperature in a semi-arid region of China. Science of the Total Environment, 2019, 652: 471-482
[9]	Hobbs PR. Conservation agriculture: What is it and why is it important for future sustainable food production. Journal of Agricultural Science, 2007, 145: 127-137
[10]	Sun BJ, Jia SX, Zhang SX, et al. No tillage combined with crop rotation improves soil microbial community composition and metabolic activity. Environmental Science and Pollution Research, 2016, 23: 6472-6482
[11]	Liang AZ, Zhang Y, Zhang XP, et al. Investigations of relationships among aggregate pore structure, microbial biomass, and soil organic carbon in a Mollisol using combined non-destructive measurements and phospholi-pid fatty acid analysis. Soil and Tillage Research, 2019, 185: 94-101
[12]	Jia SX, Zhang XP, Chen XW, et al. Long-term conservation tillage influences the soil microbial community and its contribution to soil CO2 emissions in a Mollisol in Northeast China. Journal of Soils and Sediments, 2016, 16: 1-12
[13]	Sun BJ, Jia SX, Zhang SX, et al. Tillage, seasonal and depths effects on soil microbial properties in black soil of Northeast China. Soil and Tillage Research, 2016, 155: 421-428
[14]	Wei Y, Wang YT, Hou WH, et al. Continuous application of conservation tillage affects in situ N2O emissions and nitrogen cycling gene abundances following nitrogen fertilization. Soil Biology and Biochemistry, 2021, 157: 108239
[15]	Wang WY, Yang M, Shen PF, et al. Conservation til-lage reduces nitrous oxide emissions by regulating functional genes for ammonia oxidation and denitrification in a winter wheat ecosystem. Soil and Tillage Research, 2019, 194: 104347
[16]	Behnke GD, Zabaloy MC, Riggins CW, et al. Acidification in corn monocultures favor fungi, ammonia oxidizing bacteria, and nirK-denitrifier groups. Science of the Total Environment, 2020, 720: 137514
[17]	Ge TD, Wu XH, Liu Q, et al. Effect of simulated til-lage on microbial autotrophic CO2 fixation in paddy and upland soils. Scientific Reports, 2016, 6: 19784
[18]	Zheng BX, Zhu YG, Sardans J, et al. QMEC: A tool for high-throughput quantitative assessment of microbial functional potential in C, N, P, and S biogeochemical cycling. Science China Life Sciences, 2018, 61: 1451-1462
[19]	Pfaffl MW. A new mathematical model for relative quantification in real-time RTPCR. Nucleic Acids Research, 2021, 9: e25
[20]	Chhabra S, Hogan J, Ryan D, et al. Analysis of microbial communities under long-term conventional and reduced-input management of tillage soil. The 3rd International Conference on Environmental, Industrial, and Applied Microbiology, Portugal, 2011: 8-11
[21]	Yang L, Zhang X, Ju X, et al. Linkage between N2O emission and functional gene abundance in an intensively managed calcareous fluvo-aquic soil. Scientific Reports, 2017, 7: 43283
[22]	Schulz S, Kolbl A, Ebli M, et al. Field-scale pattern of denitrifying microorganisms and N2O emission rates indicate a high potential for complete denitrification in an agriculturally used organic soil. Microbial Ecology, 2017, 74: 765-770
[23]	Zhang X, Hua X, Yue X, et al. Comparison of bacterial community characteristics between complete and shortcut denitrification systems for quinoline degradation. Applied Microbiology and Biotechnology, 2017, 101: 1697-1707
[24]	Shiina Y, Itakura M, Choi H, et al. Relationship between soil type and N2O reductase genotype (nosZ) of indigenous soybean bradyrhizobia: nosZ-minus populations are dominant in Andosols. Microbes and Environments, 2014, 29: 420-426
[25]	Fisher KA, Yarwood SA, James BR, et al. Soil urease activity and bacterial ureC gene copy numbers: Effect of pH. Geoderma, 2017, 285: 1-8
[26]	Carlos FS, Schaffer N, Marcolin E, et al. A long-term no-tillage system can increase enzymatic activity and maintain bacterial richness in paddy fields. Land Degradation and Development, 2021, 32: 2257-2268
[27]	Chen J, Sinsabaugh RL. Linking microbial functional gene abundance and soil extracellular enzyme activity: Implications for soil carbon dynamics. Global Change Biology, 2020, 27: 1322-1325
[28]	Tang HM, Li C, Cheng KK, et al. Effect of different short-term tillage management on nitrogen-fixing bacteria community in a double-cropping paddy field of southern China. Journal of Basic Microbiology, 2021, 61: 241-252
[29]	Zibilske LM, Bradford JM. Tillage effects on phosphorus mineralization and microbial activity. Soil Science, 2003, 168: 677-685
[30]	Bolo P, Kihara J, Mucheru-Muna M, et al. Application of residue, inorganic fertilizer and lime affect phospho-rus solubilizing microorganisms and microbial biomass under different tillage and cropping systems in a Ferralsol. Geoderma, 2021, 390: 114962
[31]	Kumar A, Rana KS, Choudhary AK, et al. Sole- or dual-crop basis residue mulching and Zn fertilization lead to improved productivity, rhizo-modulation, and soil health in zero-tilled pigeonpea-wheat cropping system. Journal of Soil Science and Plant Nutrition, 2022, 22: 1193-1214
[32]	Singh U, Choudhary AK, Varatharajan T, et al. Agricultural management practices affect the abundance of markers of phosphorus cycle in soil: Case study with pigeonpea and soybean. Journal of Soil Science and Plant Nutrition, 2022, 22: 3012-3020
[33]	幸颖, 刘常宏, 安树青. 海岸盐沼湿地土壤硫循环中的微生物及其作用. 生态学杂志, 2007, 26(4): 577-581
[34]	He CQ, Cheng LY, Wang DY, et al. Spartina alterniflora raised soil sulfide content by regulating sulfur cycle-associated bacteria in the Jiuduansha Wetland of China. Plant and Soil, 2021, 469: 107-121
[35]	Liu ZX, Gu HD, Liang AZ, et al. Conservation tillage regulates soil bacterial community assemblies, network structures and ecological functions in black soils. Plant and Soil, 2022, 472: 207-223
[36]	Liu X, Dong W, Si P, et al. Linkage between soil organic carbon and the utilization of soil microbial carbon under plastic film mulching in a semi-arid agroecosystem in China. Archives of Agronomy and Soil Science, 2019, 65: 1788-1801
[37]	杨山, 李小彬, 王汝振, 等. 氮水添加对中国北方草原土壤细菌多样性和群落结构的影响. 应用生态学报, 2015, 26(3): 739-746
[38]	Yang JJ, Li GH, Qian Y, et al. Microbial functional gene patterns related to soil greenhouse gas emissions in oil contaminated areas. Science of the Total Environment, 2018, 628: 94-102
[39]	Qi JH, Liu YB, Wang ZR, et al. Variations in microbial functional potential associated with phosphorus and sulfur cycling in biological soil crusts of different ages at the Tengger Desert, China. Applied Soil Ecology, 2021, 165: 104022
[40]	Cederlund H, Thierfelder T, Stenström J. Functional microbial diversity of the railway track bed. Science of the Total Environment, 2008, 397: 205-214