从根际到生态系统：自然植物群落中生物硝化抑制研究的跨尺度框架

doi:10.7523/j.ucas.2026.024

摘要/Abstract

摘要： 植物通过特定根系分泌物抑制根际氨氧化微生物活性的现象称为生物硝化抑制（BNI）。虽然该现象最早发现于天然草地生态系统,但是当前的研究主要集中在其农业应用方面,而对多物种互作、长期氮限制且环境高度异质的自然生态系统,BNI的生态角色还存在诸多认知空白。在此,我们倡导转变BNI的研究范式,从以作物为中心的BNI筛选转向将BNI视为一种根际过程表达具有情境依赖性的植物功能性状,厘清该性状在塑造根际氮动态、植物间竞争及生态系统氮保留中的作用;采用跨尺度的研究框架,重点回答如下几个方面的科学问题：（1）性状整合：BNI作为根际过程性状,如何纳入植物功能性状谱或性状网络?其表达是否与资源获取策略、根系性状及氮形态偏好存在协同或权衡?（2）根际机制及微生物靶标：BNIs在土壤中的释放、迁移、吸附/降解及其对不同氨氧化微生物类群（如AOA/AOB）的作用路径为何?实验室抑制效应如何转化为可观测的土壤过程响应?（3）群落构建机制及生态后果：种间BNI差异如何通过改变根际NH₄⁺/NO₃^-供给结构影响竞争、共存与植物-土壤反馈,并进一步影响生态系统氮滞留?（4）宏观尺度格局及驱动因素：BNI表达及硝化抑制在更大的空间尺度上呈现何种格局?气候约束、土壤调控、微生物群落结构及系统发育历史分别起何种作用?
融合最新方法学进展（如根系分泌物代谢组学）与生态理论（如基于性状的群落生态学）,该框架提出了三项实操策略：（1）模型改进：将净硝化速率、硝化潜力及硝化通量作为生态系统模型的重要响应变量;（2）实验优化：开展涵盖土壤湿度、pH值及底物异质性梯度的多点联网实验,量化BNI与环境的互作;（3）机制深化：阐明从根系分泌物化学组成、硝化菌群组装到生态系统N₂O排放热点的级联机理。通过将机制认知与生态系统尺度预测相衔接,该框架将BNI从“局部土壤过程”重新定位为理解自然生态系统氮滞留与转化的重要基础概念,并为气候变化背景下的可持续氮管理提供理论依据。

关键词: 生物硝化抑制（BNI）, 根际, 硝化潜力, 氨氧化微生物, 根系分泌物, 群落构建, 生物地理学

Abstract: Biological nitrification inhibition (BNI), a mechanism where plants suppress rhizospheric ammonium oxidation through specialized exudates, was initially identified in unmanaged ecosystems. However, contemporary research predominantly focuses on its agronomic applications for enhancing nitrogen fertilizer use efficiency. To address the critical knowledge gap regarding BNI's ecological roles in chronically nitrogen-limited ecosystems characterized by multispecies interactions and environmental heterogeneity, we advocate a paradigm shift: transitioning from crop-centric BNI screening to recognizing BNI as a plant functional trait whose context-dependent expression modulates rhizosphere nitrogen dynamics, plant-plant competition, and ecosystem nitrogen retention. This perspective necessitates a cross-scale framework addressing four interconnected questions: (1) Trait integration: How can BNI be incorporated as a rhizosphere process trait within plant trait spectra or networks, and how does it co-vary with resource-acquisition strategies, root traits, and nitrogen-form preference? (2) Rhizosphere mechanisms and microbial targets: Through which pathways do BNIs act in soils, including release, transport, sorption/degradation, and differential effects on ammonia-oxidizing microorganisms (e.g., AOA/AOB), and under what conditions are assay-based inhibitory effects translated into observable soil-process responses? (3) Community assembly mechanisms and ecological consequences: How does interspecific variation in BNI reshape rhizosphere NH₄⁺/NO₃^- supply to influence competition, coexistence, plant-soil feedbacks, and ecosystem nitrogen retention? (4) Macro-scale patterns and drivers: What macro-scale patterns are expected for BNI expression and associated nitrification suppression, and how are they shaped by climatic constraints, edaphic regulation, microbial community structure, and phylogenetic history? This framework bridges methodological advances (e.g., root exudate metabolomics) with ecological theory (e.g., trait-based community ecology), while proposing three operational strategies: (1) Modeling integration: Incorporate net nitrification rates, nitrification potential, and nitrification fluxes as core response variables in ecosystem models; (2) Experimental design: Implement gradient network experiments spanning soil moisture, pH, and substrate heterogeneity to quantify BNI-environment interactions; (3) Mechanistic scaling: Develop process-based models linking root exudate chemistry to nitrifier community assembly and N₂O emission hotspots. By linking mechanistic understanding with ecosystem-scale prediction, this framework repositions BNI from a localized soil process to a foundational concept for understanding nitrogen retention and transformation in natural ecosystems, with implications for sustainable nitrogen management under climate change.

Key words: Biological nitrification inhibition (BNI), rhizosphere, nitrification potential, ammonia oxidizers, root exudates, community assembly, biogeography

中图分类号:

Q948.1

于青含, 崔骁勇. 从根际到生态系统：自然植物群落中生物硝化抑制研究的跨尺度框架[J]. 中国科学院大学学报, DOI: 10.7523/j.ucas.2026.024.

YU Qinghan, CUI Xiaoyong. From rhizosphere to ecosystem: a cross-scale framework for biological nitrification inhibition research in natural plant communities^*[J]. Journal of University of Chinese Academy of Sciences, DOI: 10.7523/j.ucas.2026.024.

参考文献

[1] Vitousek P M, Howarth R W.Nitrogen limitation on land and in the sea: How can it occur?[J]. Biogeochemistry, 1991, 13(2): 87-115. DOI:10.1007/BF00002772.
[2] LeBauer D S, Treseder K K. Nitrogen limitation of net primary productivity in terrestrial ecosystems is globally distributed[J]. Ecology, 2008, 89(2): 371-379. DOI:10.1890/06-2057.1.
[3] Coskun D, Britto D T, Shi W M, et al.Nitrogen transformations in modern agriculture and the role of biological nitrification inhibition[J]. Nature Plants, 2017, 3: 17074. DOI:10.1038/nplants.2017.74.
[4] Nardi P, Laanbroek H J, Nicol G W, et al.Biological nitrification inhibition in the rhizosphere: Determining interactions and impact on microbially mediated processes and potential applications[J]. FEMS Microbiology Reviews, 2020, 44(6): 874-908. DOI:10.1093/femsre/fuaa037.
[5] Amanatidou P, Perruchon C, Mavrou E, et al.Dicyandiamide (DCD) and 3,4-dimethylpyrazole phosphate (DMPP) demonstrate distinct inhibitory activity, dissipation patterns and off-target effects in soils under repeated exposure regimes[J]. Biology and Fertility of Soils, 2025, 61(7): 1253-1269. DOI:10.1007/s00374-025-01936-y.
[6] Subbarao G V, Ishikawa T, Ito O, et al.A bioluminescence assay to detect nitrification inhibitors released from plant roots: A case study with Brachiaria humidicola[J]. Plant and Soil, 2006, 288(1): 101-112. DOI:10.1007/s11104-006-9094-3.
[7] Stiven G.Production of antibiotic substances by the roots of a grass (Trachypogon plumosus (H.B.K.) nees) and of Pentanisia variabilis (E. mey.) harv. (rubiaceæ)[J]. Nature, 1952, 170(4330): 712-713. DOI:10.1038/170712a0.
[8] Rice E L.Inhibition of nitrogen-fixing and nitrifying bacteria by seed plants (I.)[J]. Ecology, 1964, 45(4): 824-837. DOI:10.2307/1934928.
[9] Rice E L, Pancholy S K.Inhibition of nitrification by climax ecosystems[J]. American Journal of Botany, 1972, 59(10): 1033-1040. DOI:10.1002/j.1537-2197.1972.tb10183.x.
[10] Lata J C, Durand J, Lensi R, et al.Stable coexistence of contrasted nitrification statuses in a wet tropical savanna ecosystem[J]. Functional Ecology, 1999, 13(6): 762-768. DOI:10.1046/j.1365-2435.1999.00380.x.
[11] Lata J C, Guillaume K, Degrange V, et al.Relationships between root density of the African grass Hyparrhenia diplandra and nitrification at the decimetric scale: An inhibition-stimulation balance hypothesis[J]. Proceedings of the Royal Society of London Series B: Biological Sciences, 2000, 267(1443): 595-600. DOI:10.1098/rspb.2000.1043.
[12] Lata J C, Degrange V, Raynaud X, et al.Grass populations control nitrification in savanna soils[J]. Functional Ecology, 2004, 18(4): 605-611. DOI:10.1111/j.0269-8463.2004.00880.x.
[13] Subbarao G V, Nakahara K, Ishikawa T, et al.Free fatty acids from the pasture grass Brachiaria humidicola and one of their methyl esters as inhibitors of nitrification[J]. Plant and Soil, 2008, 313(1): 89-99. DOI:10.1007/s11104-008-9682-5.
[14] Subbarao G V, Nakahara K, Hurtado M P, et al.Evidence for biological nitrification inhibition in Brachiaria pastures[J]. Proceedings of the National Academy of Sciences of the United States of America, 2009, 106(41): 17302-17307. DOI:10.1073/pnas.0903694106.
[15] Zakir H A K M, Subbarao G V, Pearse S J, et al. Detection, isolation and characterization of a root-exuded compound, methyl 3-(4-hydroxyphenyl) propionate, responsible for biological nitrification inhibition by sorghum (Sorghum bicolor)[J]. New Phytologist, 2008, 180(2): 442-451. DOI:10.1111/j.1469-8137.2008.02576.x.
[16] Tesfamariam T, Yoshinaga H, Deshpande S P, et al.Biological nitrification inhibition in sorghum: The role of sorgoleone production[J]. Plant and Soil, 2014, 379(1): 325-335. DOI:10.1007/s11104-014-2075-z.
[17] Sun L, Lu Y F, Yu F W, et al.Biological nitrification inhibition by rice root exudates and its relationship with nitrogen‐use efficiency[J]. New Phytologist, 2016, 212(3): 646-656. DOI:10.1111/nph.14057.
[18] Egenolf K, Schöne J, Conrad J, et al.Root exudate fingerprint of Brachiaria humidicola reveals vanillin as a novel and effective nitrification inhibitor[J]. Frontiers in Molecular Biosciences, 2023, 10: 1192043. DOI:10.3389/fmolb.2023.1192043.
[19] Wang G, Zhang L H, Guo Z H, et al.Benefits of biological nitrification inhibition of Leymus chinensis under alkaline stress: The regulatory function of ammonium-N exceeds its nutritional function[J]. Frontiers in Plant Science, 2023, 14: 1145830. DOI:10.3389/fpls.2023.1145830.
[20] Issifu S, Acharya P, Schöne J, et al.Metabolome fingerprinting reveals the presence of multiple nitrification inhibitors in biomass and root exudates of Thinopyrum intermedium[J]. Plant-Environment Interactions, 2024, 5(5): e70012. DOI:10.1002/pei3.70012.
[21] Ghatak A, Kanellopoulos A E, López-Hidalgo C, et al.Natural variation of the wheat root exudate metabolome and its influence on biological nitrification inhibition activity[J]. Plant Biotechnology Journal, 2025, 23(11): 4755-4772. DOI:10.1111/pbi.70248.
[22] Sarr P S, Ando Y, Nakamura S, et al.Sorgoleone release from sorghum roots shapes the composition of nitrifying populations, total bacteria, and Archaea and determines the level of nitrification[J]. Biology and Fertility of Soils, 2020, 56(2): 145-166. DOI:10.1007/s00374-019-01405-3.
[23] Kaur-Bhambra J, Wardak D L R, Prosser J I, et al. Revisiting plant biological nitrification inhibition efficiency using multiple archaeal and bacterial ammonia-oxidising cultures[J]. Biology and Fertility of Soils, 2022, 58(3): 241-249. DOI:10.1007/s00374-020-01533-1.
[24] Issifu S, Acharya P, Kaur-Bhambra J, et al.Biological nitrification inhibitors with antagonistic and synergistic effects on growth of ammonia oxidisers and soil nitrification[J]. Microbial Ecology, 2024, 87(1): 143. DOI:10.1007/s00248-024-02456-2.
[25] Boudsocq S, Niboyet A, Lata J C, et al.Plant preference for ammonium versus nitrate: A neglected determinant of ecosystem functioning?[J]. The American Naturalist, 2012, 180(1): 60-69. DOI:10.1086/665997.
[26] Subbarao G V, Kishii M, Bozal-Leorri A, et al.Enlisting wild grass genes to combat nitrification in wheat farming: A nature-based solution[J]. Proceedings of the National Academy of Sciences of the United States of America, 2021, 118(35): e2106595118. DOI:10.1073/pnas.2106595118.
[27] Bozal-Leorri A, Subbarao G V, Kishii M, et al.Biological nitrification inhibitor-trait enhances nitrogen uptake by suppressing nitrifier activity and improves ammonium assimilation in two elite wheat varieties[J]. Frontiers in Plant Science, 2022, 13: 1034219. DOI:10.3389/fpls.2022.1034219.
[28] O’Sullivan C A, Fillery I R P, Roper M M, et al. Identification of several wheat landraces with biological nitrification inhibition capacity[J]. Plant and Soil, 2016, 404(1): 61-74. DOI:10.1007/s11104-016-2822-4.
[29] Vázquez E, Teutscherova N, Dannenmann M, et al.Gross nitrogen transformations in tropical pasture soils as affected by Urochloa genotypes differing in biological nitrification inhibition (BNI) capacity[J]. Soil Biology and Biochemistry, 2020, 151: 108058. DOI:10.1016/j.soilbio.2020.108058.
[30] Lata J C, Le Roux X, Koffi K F, et al.The causes of the selection of biological nitrification inhibition (BNI) in relation to ecosystem functioning and a research agenda to explore them[J]. Biology and Fertility of Soils, 2022, 58(3): 207-224. DOI:10.1007/s00374-022-01630-3.
[31] Coskun D, Britto D T, Shi W M, et al.How plant root exudates shape the nitrogen cycle[J]. Trends in Plant Science, 2017, 22(8): 661-673. DOI:10.1016/j.tplants.2017.05.004.
[32] Di T J, Afzal M R, Yoshihashi T, et al.Further insights into underlying mechanisms for the release of biological nitrification inhibitors from sorghum roots[J]. Plant and Soil, 2018, 423(1): 99-110. DOI:10.1007/s11104-017-3505-5.
[33] Subbarao G V, Wang H Y, Ito O, et al.NH₄+ triggers the synthesis and release of biological nitrification inhibition compounds in Brachiaria humidicola roots[J]. Plant and Soil, 2007, 290(1): 245-257. DOI:10.1007/s11104-006-9156-6.
[34] Pausch J, Kuzyakov Y.Carbon input by roots into the soil: Quantification of rhizodeposition from root to ecosystem scale[J]. Global Change Biology, 2018, 24(1): 1-12. DOI:10.1111/gcb.13850.
[35] Buss W, Verburg K, Garba I I, et al.Harnessing biological nitrification inhibition to reduce soil nitrogen losses-Systematic quantification of plant and soil factors to maximise field-scale benefits[J]. Agriculture, Ecosystems & Environment, 2026, 396: 110002. DOI:10.1016/j.agee.2025.110002.
[36] Konaré S, Boudsocq S, Gignoux J, et al.Effects of mineral nitrogen partitioning on tree-grass coexistence in west African savannas[J]. Ecosystems, 2019, 22(7): 1676-1690. DOI:10.1007/s10021-019-00365-x.
[37] Yuan X Y, She W W, Guo Y P, et al.Linkage between plant nitrogen preference and rhizosphere effects on soil nitrogen transformation reveals a plant resource adaptive strategies in nitrogen-limited soils[J]. Plant and Soil, 2025, 513(1): 883-900. DOI:10.1007/s11104-025-07220-0.
[38] Weemstra M, Mommer L, Visser E J W, et al. Towards a multidimensional root trait framework: A tree root review[J]. New Phytologist, 2016, 211: 1159-1169. DOI:10.1111/nph.14003.
[39] Egenolf K, Verma S, Schöne J, et al.Rhizosphere pH and cation‐anion balance determine the exudation of nitrification inhibitor 3‐epi‐brachialactone suggesting release via secondary transport[J]. Physiologia Plantarum, 2021, 172(1): 116-123. DOI:10.1111/ppl.13300.
[40] Zhu Y Y, Zeng H Q, Shen Q R, et al.Interplay among NH₄+ uptake, rhizosphere pH and plasma membrane H+-ATPase determine the release of BNIs in sorghum roots-possible mechanisms and underlying hypothesis[J]. Plant and Soil, 2012, 358(1): 131-141. DOI:10.1007/s11104-012-1151-5.
[41] Korenblum E, Dong Y H, Szymanski J, et al.Rhizosphere microbiome mediates systemic root metabolite exudation by root-to-root signaling[J]. Proceedings of the National Academy of Sciences of the United States of America, 2020, 117(7): 3874-3883. DOI:10.1073/pnas.1912130117.
[42] Ishikawa T, Subbarao G V, Ito O, et al.Suppression of nitrification and nitrous oxide emission by the tropical grass Brachiaria humidicola[J]. Plant and Soil, 2003, 255(1): 413-419. DOI:10.1023/A:1026156924755.
[43] Srikanthasamy T, Leloup J, N’Dri A B, et al. Contrasting effects of grasses and trees on microbial N-cycling in an African humid savanna[J]. Soil Biology and Biochemistry, 2018, 117: 153-163. DOI:10.1016/j.soilbio.2017.11.016.
[44] Castaldi S, Carfora A, Fiorentino A, et al.Inhibition of net nitrification activity in a Mediterranean woodland: Possible role of chemicals produced by Arbutus unedo[J]. Plant and Soil, 2009, 315(1): 273-283. DOI:10.1007/s11104-008-9750-x.
[45] Ma Y, Jones D L, Wang J Y, et al.Relative efficacy and stability of biological and synthetic nitrification inhibitors in a highly nitrifying soil: Evidence of apparent nitrification inhibition by linoleic acid and linolenic acid[J]. European Journal of Soil Science, 2021, 72(6): 2356-2371. DOI:10.1111/ejss.13096.
[46] Wang X, Bai J H, Wang C, et al.Two newly-identified biological nitrification inhibitors in Suaeda salsa: Synthetic pathways and influencing mechanisms[J]. Chemical Engineering Journal, 2023, 454: 140172. DOI:10.1016/j.cej.2022.140172.
[47] Pichler M, Hartig F.Machine learning and deep learning: A review for ecologists[J]. Methods in Ecology and Evolution, 2023, 14(4): 994-1016. DOI:10.1111/2041-210X.14061.
[48] He B H, Zhao Y H, Mao W.Explainable artificial intelligence reveals environmental constraints in seagrass distribution[J]. Ecological Indicators, 2022, 144: 109523. DOI:10.1016/j.ecolind.2022.109523.
[49] Lee C, Amini F, Hu G P, et al.Machine learning prediction of nitrification from ammonia- and nitrite-oxidizer community structure[J]. Frontiers in Microbiology, 2022, 13: 899565. DOI:10.3389/fmicb.2022.899565.
[50] Cornwallis C K, Griffin A S.A guided tour of phylogenetic comparative methods for studying trait evolution[J]. Annual Review of Ecology, Evolution, and Systematics, 2024, 55: 181-204. DOI:10.1146/annurev-ecolsys-102221-050754.