High nitrogen fertilizer input enhanced the microbial network complexity in the paddy soil

Yanan Chen, Yan Li, Tianyi Qiu, Haoran He, Ji Liu, Chengjiao Duan, Yongxing Cui, Min Huang, Chunyan Wu, Linchuan Fang

PDF(1175 KB)
PDF(1175 KB)
Soil Ecology Letters ›› 2024, Vol. 6 ›› Issue (2) : 230205. DOI: 10.1007/s42832-023-0205-3
RESEARCH ARTICLE
RESEARCH ARTICLE

High nitrogen fertilizer input enhanced the microbial network complexity in the paddy soil

Author information +
History +

Highlights

● N fertilizer altered bacterial community compositions by changing soil nutrients.

● Bacterial ammonia oxidation became predominated with the increasing N rate.

● Excessive N input caused the information of a more complex microbial network.

● Intensified microbial competition by excessive N was due to negative link increase.

Abstract

Nitrogen (N) fertilization drives the structure and function of soil microbial communities, which are crucial for regulating soil biogeochemical cycling and maintaining ecosystem stability. Despite the N fertilizer effects on soil microbial composition and diversity have been widely investigated, it is generally overlooked that ecosystem processes are carried out via complex associations among microbiome members. Here, we examined the effects of five N fertilization levels (0, 135, 180, 225, and 360 kg N ha−1) on microbial co-occurrence networks and key functional taxa such as ammonia-oxidizers in paddy soils. The results showed that N addition altered microbial community composition, which were positively related to soil total N and available phosphorus (P) contents. The abundance of ammonia-oxidizing archaea (AOA) significantly decreased after N addition, whereas ammonia-oxidizing bacteria (AOB) increased in N360 treatment. Compared with low-N group (N0 and N135), the high-N group (N225 and N360) shaped more complex microbial webs and thus improved the stability of the microbial community. Partial least squares path modeling further revealed that N fertilizer had a higher effect on microbial network complexity in the high-N group (0.83) than the low-N group (0.49). Although there were more positive links across all microbial networks, the proportion of negative links significantly increased in the high-N network, suggesting that excess N addition aggravated the competition among microbial species. Disentangling these interactions between microbial communities and N fertilization advances our understanding of biogeochemical processes in paddy soils and their effects on nutrient supply to rice production. Our findings highlighted that highly N-enriched paddy soils have more stable microbial networks and can better sustain soil ecological functions to cope with the ongoing environmental changes.

Graphical abstract

Keywords

nitrogen fertilizer / paddy soil / co-occurrence network / microbial interaction

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾
Yanan Chen, Yan Li, Tianyi Qiu, Haoran He, Ji Liu, Chengjiao Duan, Yongxing Cui, Min Huang, Chunyan Wu, Linchuan Fang. High nitrogen fertilizer input enhanced the microbial network complexity in the paddy soil. Soil Ecology Letters, 2024, 6(2): 230205 https://doi.org/10.1007/s42832-023-0205-3

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]
Banerjee, S., Kirkby, C.A., Schmutter, D., Bissett, A., Kirkegaard, J.A., Richardson, A.E., 2016. Network analysis reveals functional redundancy and keystone taxa amongst bacterial and fungal communities during organic matter decomposition in an arable soil. Soil Biology & Biochemistry97, 188–198.
CrossRef Google scholar
[2]
Banerjee, S., Schlaeppi, K., Der Heijden, M.G., 2018. Keystone taxa as drivers of microbiome structure and functioning. Nature Reviews Microbiology16, 567–576.
CrossRef Google scholar
[3]
Banerjee, S., Walder, F., Büchi, L., Meyer, M., Held, A.Y., Gattinger, A., Keller, T., Charles, R., Van der Heijden, M.G.A., 2019. Agricultural intensification reduces microbial network complexity and the abundance of keystone taxa in roots. ISME Journal13, 1722–1736.
CrossRef Google scholar
[4]
Bao, S.D., 2000. Soil and Agricultural Chemistry Analysis. China Agriculture Press, Beijing
[5]
Benizri, E., Piutti, S., Verger, S., Pages, L., Vercambre, G., Poessel, J.L., Michelot, P., 2005. Replant diseases: bacterial community structure and diversity in peach rhizosphere as determined by metabolic and genetic fingerprinting. Soil Biology & Biochemistry37, 1738–1746.
CrossRef Google scholar
[6]
Bu, R., Ren, T., Lei, M., Liu, B., Li, X., Cong, R., Zhang, Y., Lu, J., 2020. Tillage and straw-returning practices effect on soil dissolved organic matter, aggregate fraction and bacteria community under rice-rice-rapeseed rotation system. Agriculture, Ecosystems & Environment287, 106681.
CrossRef Google scholar
[7]
Chase, J.M., 2007. Drought mediates the importance of stochastic community assembly. Proceedings of the National Academy of Sciences of the United States of America104, 17430–17434.
CrossRef Google scholar
[8]
Che, R., Wang, Y., Li, K., Xu, Z., Hu, J., Wang, F., Rui, Y., Li, L., Pang, Z., Cui, X., 2019. Degraded patch formation significantly changed microbial community composition in alpine meadow soils. Soil & Tillage Research195, 104426.
CrossRef Google scholar
[9]
Cho, S.J., Kim, M.H., Lee, Y.O., 2016. Effect of pH on soil bacterial diversity. Journal of Ecology and Environment40, 1–9.
CrossRef Google scholar
[10]
Coskun, D., Britto, D., Shi, W., Kronzucker, H., 2017. Nitrogen transformations in modern agriculture and the role of biological nitrification inhibition. Nature Plants3, 1–10.
CrossRef Google scholar
[11]
Coyte, K.Z., Schluter, J., Foster, K.R., 2015. The ecology of the microbiome: networks, competition, and stability. Science350, 663–666.
CrossRef Google scholar
[12]
Cui, Q., Zhang, Z., Beiyuan, J., Cui, Y., Chen, L., Chen, H., Fang, L., 2023. A critical review of uranium in the soil-plant system: Distribution, bioavailability, toxicity, and bioremediation strategies. Critical Reviews in Environmental Science and Technology53, 340–365.
CrossRef Google scholar
[13]
Cui, Y., Bing, H., Fang, L., Jiang, M., Shen, G., Yu, J., Wang, X., Zhu, H., Wu, Y., Zhang, X., 2021. Extracellular enzyme stoichiometry reveals the carbon and phosphorus limitations of microbial metabolisms in the rhizosphere and bulk soils in alpine ecosystems. Plant and Soil458, 7–20.
CrossRef Google scholar
[14]
Cui, Y., Zhang, Y., Duan, C., Wang, X., Zhang, X., Ju, W., Chen, H., Yue, S., Wang, Y., Li, S., Fang, L., 2020. Ecoenzymatic stoichiometry reveals microbial phosphorus limitation decreases the nitrogen cycling potential of soils in semi-arid agricultural ecosystems. Soil & Tillage Research197, 104463.
CrossRef Google scholar
[15]
Daebeler, A., Bodelier, P., Yan, Z., Hefting, M., Jia, Z., Laanbroek, H., 2014. Interactions between Thaumarchaea, Nitrospira and methanotrophs modulate autotrophic nitrification in volcanic grassland soil. ISME Journal8, 2397–2410.
CrossRef Google scholar
[16]
Dai, Z., Su, W., Chen, H., Barberan, A., Zhao, H., Yu, M., Yu, L., Brookes, P.C., Schadt, C.W., Chang, S.X., Xu, J., 2018. Long-term nitrogen fertilization decreases bacterial diversity and favors the growth of Actinobacteria and Proteobacteria in agro-ecosystems across the globe. Global Change Biology24, 3452–3461.
CrossRef Google scholar
[17]
De Vries, F.T., Griffiths, R.I., Bailey, M., Craig, H., Girlanda, M., Gweon, H.S., Hallin, S., Kaisermann, A., Keith, A.M., Kretzschmar, M., Lemanceau, P., Lumini, E., Mason, K.E., Oliver, A., Ostle, N., Prosser, J.I., Thion, C., Thomson, B., Bardgett, R.D., 2018. Soil bacterial networks are less stable under drought than fungal networks. Nature Communications9, 3033.
CrossRef Google scholar
[18]
De Vries, F.T., Wallenstein, M.D., Bardgett, R., 2017. Below-ground connections underlying above-ground food production: a framework for optimising ecological connections in the rhizosphere. Journal of Ecology105, 913–920.
CrossRef Google scholar
[19]
Deng, Y., Zhang, P., Qin, Y., Tu, Q., Yang, Y., He, Z., Schadt, C.W., Zhou, J., 2016. Network succession reveals the importance of competition in response to emulsified vegetable oil amendment for uranium bioremediation. Environmental Microbiology18, 205–218.
CrossRef Google scholar
[20]
Di, H.J., Cameron, K.C., Shen, J.P., Winefield, C., O’Callaghan, M., Bowatte, S., He, J.Z., 2009. Nitrification driven by bacteria and not archaea in nitrogen-rich grassland soils. Nature Geoscience2, 621–624.
CrossRef Google scholar
[21]
Duan, C., Razavi, B.S., Shen, G., Cui, Y., Ju, W., Li, S., Fang, L., 2019. Deciphering the rhizobium inoculation effect on spatial distribution of phosphatase activity in the rhizosphere of alfalfa under copper stress. Soil Biology & Biochemistry137, 107574.
CrossRef Google scholar
[22]
Edgar, R.C., 2013. UPARSE: highly accurate OTU sequences from microbial amplicon reads. Nature Methods10, 996–998.
CrossRef Google scholar
[23]
Eilers, K.G., Lauber, C.L., Knight, R., Fierer, N., 2010. Shifts in bacterial community structure associated with inputs of low molecular weight carbon compounds to soil. Soil Biology & Biochemistry42, 896–903.
CrossRef Google scholar
[24]
Eno, C.F., Blue, W.G., Good, J.M. Jr, 1955. The effect of anhydrous ammonia on nematodes, fungi, bacteria, and nitrification in some Florida soils. Soil Science Society of America Journal19, 55–58.
CrossRef Google scholar
[25]
Fan, K.K., Delgado-Baquerizo, M., Guo, X.S., Wang, D.Z., Zhu, Y.G., Chu, H.Y., 2020. Biodiversity of key-stone phylotypes determines crop production in a 4-decade fertilization experiment. ISME Journal15, 550–561.
CrossRef Google scholar
[26]
Faust, K., Raes, J., 2012. Microbial interactions: from networks to models. Nature Reviews. Microbiology10, 538–550.
CrossRef Google scholar
[27]
Fernandez, C.W., Kennedy, P.G. 2016. Revisiting the ‘Gadgil effect’: do interguild fungal interactions control carbon cycling in forest soils?. New Phytologist209, 1382–1394.
CrossRef Google scholar
[28]
Fierer, N., Bradford, M., Jackson, R., 2007. Toward an ecological classification of soil bacteria. Ecology88, 1354–1364.
CrossRef Google scholar
[29]
Fierer, N., Lauber, C.L., Ramirez, K.S., Zaneveld, J., Bradford, M.A., Knight, R., 2012. Comparative metagenomic, phylogenetic and physiological analyses of soil microbial communities across nitrogen gradients. ISME Journal6, 1007–1017.
CrossRef Google scholar
[30]
Fuhrman, J.A., 2009. Microbial community structure and its functional implications. Nature459, 193–199.
CrossRef Google scholar
[31]
Gao, Y., Sun, S., Xing, F., Mu, X., Bai, Y., 2019. Nitrogen addition interacted with salinity-alkalinity to modify plant diversity, microbial PLFAs and soil coupled elements: A 5-year experiment. Applied Soil Ecology137, 78–86.
CrossRef Google scholar
[32]
Geisseler, D., Scow, K.M., 2014. Long-term effects of mineral fertilizers on soil microorganisms−a review. Soil Biology & Biochemistry75, 54–63.
CrossRef Google scholar
[33]
Gonzalez, A., Germain, R.M., Srivastava, D.S., Filotas, E., Dee, L.E., Gravel, D., Thompson, P.L., Isbell, F., Wang, S., K’efi, S., Montoya, J., Zelnik, Y.R., Loreau, M., 2020. Scaling-up biodiversity-ecosystem functioning research. Ecology Letters23, 757–776.
CrossRef Google scholar
[34]
Jia, Z., Conrad, R., 2009. Bacteria rather than Archaea dominate microbial ammonia oxidation in an agricultural soil. Environmental Microbiology11, 1658–1671.
CrossRef Google scholar
[35]
Jiao, S., Lu, Y., 2020. Abundant fungi adapt to broader environmental gradients than rare fungi in agricultural fields. Global Change Biology26, 4506–4520.
CrossRef Google scholar
[36]
Kögel-Knabner, I., Amelung, W., Cao, Z., Fiedler, S., Frenzel, P., Jahn, R., Kalbitz, K., Kölbl, A., Schloter, M., 2010. Biogeochemistry of paddy soils. Geoderma157, 1–14.
CrossRef Google scholar
[37]
Li, B.B., Roley, S.S., Duncan, D.S., Guo, J., Quensen, J.F., Yu, H.Q., Tiedje, J.M., 2021a. Long-term excess nitrogen fertilizer increases sensitivity of soil microbial community to seasonal change revealed by ecological network and metagenome analyses. Soil Biology & Biochemistry160, 108349.
CrossRef Google scholar
[38]
Li, R., Gao, Y., Chen, Q., Li, Z., Gao, F., Meng, Q., Li, T., Liu, A., Wang, Q., Wu, L., Wang, Y., Liu, Z., Zhang, M., 2021b. Blended controlled-release nitrogen fertilizer with straw returning improved soil nitrogen availability, soil microbial community, and root morphology of wheat. Soil & Tillage Research212, 105045.
CrossRef Google scholar
[39]
Li, X., Zhang, Q., Ma, J., Yang, Y., Wang, Y., Fu, C., 2020. Flooding irrigation weakens the molecular ecological network complexity of soil microbes during the process of dryland-to-paddy conversion. International Journal of Environmental Research and Public Health17, 561.
CrossRef Google scholar
[40]
Li, Y.L., Zhang, Y.L., Hu, J., Shen, Q.R., 2007. Contribution of nitrification happened in rhizospheric soil growing with different rice cultivars to N nutrition. Biology and Fertility of Soils43, 417–425.
CrossRef Google scholar
[41]
Liang, Y., Wu, L., Clark, I.M., Xue, K., Yang, Y., Van Nostrand, J.D., Deng, Y., He, Z., McGrath, S., Storkey, J., Hirsch, P.R., Sun, B., Zhou, J., 2015. Over 150 years of long- term fertilization alters spatial scaling of microbial biodiversity. mBio6, e00240–e15.
CrossRef Google scholar
[42]
Liu, W., Jiang, L., Hu, S., Li, L., Liu, L., Wan, S., 2014. Decoupling of soil microbes and plants with increasing anthropogenic nitrogen inputs in a temperate steppe. Soil Biology & Biochemistry72, 116–122.
CrossRef Google scholar
[43]
Liu, W., Zhang, J., Qiu, C., Bao, Y., Feng, Y., Lin, X., 2020a. Study on community assembly processes under paddy-upland rotation. Soil (Göttingen)52, 710–717.
[44]
Liu, W.B., Ling, N., Guo, J.J., Ruan, Y., Zhu, C., Shen, Q.R., Guo, S.W., 2020b. Legacy effects of N inputs on bacterial diversity of the rhizosphere soil. Biology and Fertility of Soils56, 583–596.
CrossRef Google scholar
[45]
Lu, X., Bottomley, P.J., Myrold, D.D., 2015. Contributions of ammonia-oxidizing archaea and bacteria to nitrification in Oregon forest soils. Soil Biology & Biochemistry85, 54–62.
CrossRef Google scholar
[46]
Mitri, S., Clarke, E., Foster, K.R., 2016. Resource limitation drives spatial organization in microbial groups. ISME Journal10, 1471–1482.
CrossRef Google scholar
[47]
Morriën, E., Hannula, S.E., Snoek, L.B., Helmsing, N.R., Zweers, H., de Hollander, M., Soto, R.L., Bouffaud, M.L., Buée, M., Dimmers, W., Duyts, H., Geisen, S., Girlanda, M., Griffiths, R.T., Jørgensen, H.B., Jensen, J., Plassart, P., Redecker, D., Schmelz, R.M., Schmelz, O., Thomson, B.C., Tisserant, E., Uroz, S., Winding, A., Bailey, M.J., Bonkowski, M., Faber, J.H., Martin, F., Lemanceau, P., de Boer, W., van Veen, J.A., van der Putten, W.H., 2017. Soil networks become more connected and take up more carbon as nature restoration progresses. Nature Communications8, 14349.
CrossRef Google scholar
[48]
Newman, M.E., 2003. The structure and function of complex networks. SIAM Review45, 167–256.
CrossRef Google scholar
[49]
Okuyama, T., Holland, J.N., 2008. Network structural properties mediate the stability of mutualistic communities. Ecology Letters11, 208–216.
CrossRef Google scholar
[50]
Ramirez, K.S., Craine, J.M., Fierer, N., 2012. Consistent effects of nitrogen amendments on soil microbial communities and processes across biomes. Global Change Biology18, 1918–1927.
CrossRef Google scholar
[51]
Roley, S.S., Duncan, D.S., Liang, D., Garoutte, A., Jackson, R.D., Tiedje, J.M., Robertson, G.P., 2018. Associative nitrogen fixation (ANF) in switchgrass (Panicum virgatum) across a nitrogen input gradient. PLoS One13, e0197320.
CrossRef Google scholar
[52]
Santolini, M., Barabási, A.L., 2018. Predicting perturbation patterns from the topology of biological networks. Proceedings of the National Academy of Sciences of the United States of America115, E6375–E6383.
CrossRef Google scholar
[53]
Shen, J.P., Zhang, L.M., Di, H.J., He, J.Z., 2012. A review of ammonia-oxidizing bacteria and archaea in Chinese soils. Frontiers in Microbiology3, 296.
CrossRef Google scholar
[54]
Strogatz, S.H., 2001. Exploring complex networks. Nature410, 268–276.
CrossRef Google scholar
[55]
Stubner, S., 2002. Enumeration of 16S rDNA of Desulfotomaculum lineage 1 in rice field soil by real-time PCR with SybrGreen detection. Journal of Microbiological Methods50, 155–164.
CrossRef Google scholar
[56]
Sun, W.M., Xiao, E.Z., Pu, Z.L., Krumins, V., Dong, Y.R., Li, B.Q., Hu, M., 2018. Paddy soil microbial communities driven by environmental and microbe interactions: a case study of elevation resolved microbial communities in a rice terrace. Science of the Total Environment612, 884–893.
CrossRef Google scholar
[57]
Sun, Y., Wang, Y., Qu, Z., Mu, W., Mi, W., Ma, Y., Su, L., Si, L., Li, J., You, Q., 2022. Microbial communities in paddy soil as influenced by nitrogen fertilization and water regimes. Agronomy Journal114, 379–394.
CrossRef Google scholar
[58]
Trivedi, P., Delgado-Baquerizo, M., Trivedi, C., Hu, H., Anderson, I.C., Jeffries, T.C., Zhou, J., Singh, B.K., 2016. Microbial regulation of the soil carbon cycle: Evidence from gene-enzyme relationships. ISME Journal10, 2593–2604.
CrossRef Google scholar
[59]
Vick-Majors, T.J., Priscu, J.C., Amaral-Zettler, L., 2014. Modular community structure suggests metabolic plasticity during the transition to polar night in ice covered Antarctic lakes. ISME Journal8, 778–789.
CrossRef Google scholar
[60]
Wagg, C., Schlaeppi, K., Banerjee, S., Kuramae, E.E., van der Heijden, M.G.A., 2019. Fungal-bacterial diversity and microbiome complexity predict ecosystem functioning. Nature Communications10, 4841.
CrossRef Google scholar
[61]
Wang, Q., Garrity, G.M., Tiedje, J.M., Cole, J.R., 2007. Naive Bayesian classifier for rapid assignment of rRNA sequences into the new bacterial taxonomy. Applied and Environmental Microbiology73, 5261–5267.
CrossRef Google scholar
[62]
Wei, L., Ge, T., Zhu, Z., Ye, R., Peñuelas, J., Li, Y., Lynn, T.M., Jones, D.L., Wu, J., Kuzyakov, Y., 2022. Paddy soils have a much higher microbial biomass content than upland soils: A review of the origin, mechanisms, and drivers. Agriculture, Ecosystems & Environment326, 107798.
CrossRef Google scholar
[63]
Wu, J., Liu, W., Zhang, W., Shao, Y., Duan, H., Chen, B., Wei, X., Fan, H., 2019. Long-term nitrogen addition changes soil microbial community and litter decomposition rate in a subtropical forest. Applied Soil Ecology142, 43–51.
CrossRef Google scholar
[64]
Xu, A., Li, L., Xie, J., Gopalakrishnan, S., Zhang, R., Luo, Z., Cai, L., Liu, C., Wang, L., Anwar, S., Jiang, Y., 2022. Changes in ammonia-oxidizing Archaea and bacterial communities and soil nitrogen dynamics in response to long-term nitrogen fertilization. International Journal of Environmental Research and Public Health19, 2732.
CrossRef Google scholar
[65]
Xu, N., Tan, G., Wang, H., Gai, X., 2016. Effect of biochar additions to soil on nitrogen leaching, microbial biomass and bacterial community structure. European Journal of Soil Biology74, 1–8.
CrossRef Google scholar
[66]
Yao, M., Rui, J., Li, J., Dai, Y., Bai, Y., Heděnec, P., Wang, J., Zhang, S., Pei, K., Liu, C., Wang, Y., He, Z., Frouz, J., Li, X., 2014. Rate-specific responses of prokaryotic diversity and structure to nitrogen deposition in the Leymus chinensis steppe. Soil Biology & Biochemistry79, 81–90.
CrossRef Google scholar
[67]
Yu, J., Lin, S., Shaaban, M., Ju, W., Fang, L., 2020. Nitrous oxide emissions from tea garden soil following the addition of urea and rapeseed cake. Journal of Soils and Sediments20, 3330–3339.
CrossRef Google scholar
[68]
Yu, Z.H., Li, Y.S., Wang, G.H., Liu, J.J., Liu, J.D., Liu, X.B., Herbert, S.J., Jin, J., 2016. Effectiveness of elevated CO2 mediating bacterial communities in the soybean rhizosphere depends on genotypes. Agriculture, Ecosystems & Environment231, 229–232.
CrossRef Google scholar
[69]
Zeng, J., Liu, X., Song, L., Lin, X., Zhang, H., Shen, C., Chu, H., 2016. Nitrogen fertilization directly affects soil bacterial diversity and indirectly affects bacterial community composition. Soil Biology & Biochemistry92, 41–49.
CrossRef Google scholar
[70]
Zhalnina, K., Dias, R., de Quadros, P.D., Davis-Richardson, A., Camargo, F.A., Clark, I.M., McGrath, S.P., Hirsch, P.R., Triplett, E.W., 2015. Soil pH determines microbial diversity and composition in the park grass experiment. Microbial Ecology69, 395–406.
CrossRef Google scholar
[71]
Zhang, Q., Liang, G., Myrold, D.D., Zhou, W., 2017. Variable responses of ammonia oxidizers across soil particle-size fractions affect nitrification in a long-term fertilizer experiment. Soil Biology & Biochemistry5, 25–36.
CrossRef Google scholar
[72]
Zhao, F., Feng, X., Guo, Y., Ren, C., Wang, J., Doughty, R., 2020. Elevation gradients affect the differences of arbuscular mycorrhizal fungi diversity between root and rhizosphere soil. Agricultural and Forest Meteorology284, 107894.
CrossRef Google scholar
[73]
Zhao, J., Ni, T., Li, Y., Xiong, W., Ran, W., Shen, B., Shen, Q., Zhang, R., 2014. Responses of bacterial communities in arable soils in a rice-wheat cropping system to different fertilizer regimes and sampling times. PLoS One9, 85301.
CrossRef Google scholar
[74]
Zhou, H., Gao, Y., Jia, X., Wang, M., Ding, J., Cheng, L., Bao, F., Wu, B., 2020. Network analysis reveals the strengthening of microbial interaction in biological soil crust development in the Mu Us Sandy Land, northwestern China. Soil Biology & Biochemistry144, 107782.
CrossRef Google scholar
[75]
Zhou, J., Guan, D., Zhou, B., Zhao, B., Ma, M., Qin, J., Jing, X., Chen, S., Cao, F., Shen, D., Li, J., 2015. Influence of 34-years of fertilization on bacterial communities in an intensively cultivated black soil in northeast China. Soil Biology & Biochemistry90, 42–51.
CrossRef Google scholar
[76]
Zhu, Z., Fang, Y., Liang, Y., Li, Y., Liu, S., Li, Y., Li, B., Gao, W., Yuan, H., Kuzyakov, Y., Wu, J., Richter, A., Ge, T., 2022. Stoichiometric regulation of priming effects and soil carbon balance by microbial life strategies. Soil Biology & Biochemistry169, 108669.
CrossRef Google scholar

Acknowledgments

This study was financially supported by the Joint Funds of the National Natural Science of China (U21A20237).

Declaration of competing interest

The authors declare that they have no conflict of interest including any financial, personal or other relationships with other people or organizations.

Electronic supplementary material

Supplementary material is available in the online version of this article at https://doi.org/10.1007/s42832-023-0205-3 and is accessible for authorized users.

RIGHTS & PERMISSIONS

2023 Higher Education Press
AI Summary AI Mindmap
PDF(1175 KB)

Accesses

Citations

Detail
Sections
Recommended

/