Combined effects of resistant rice cultivar and organic fertilizer on plant–soil responses to aboveground brown planthopper

Qian Yang; Jinghua Huang; Nan Jin; Jiting Wu; Zhengkun Hu; Feng Hu; Bryan Griffiths; Xiaoyun Chen; Manqiang Liu

doi:10.1007/s42832-026-0390-y

Soil Ecology Letters ›› 2026, Vol. 8 ›› Issue (2) : 260390 DOI: 10.1007/s42832-026-0390-y

RESEARCH ARTICLE

Combined effects of resistant rice cultivar and organic fertilizer on plant–soil responses to aboveground brown planthopper

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Abstract

Plant–herbivore interactions are strongly shaped by plant genotype and soil resource availability, but studies that jointly consider these factors within an integrated aboveground–belowground framework remain limited. This knowledge gap constrains the optimization of cultivar breeding and fertilizer management for sustainable agriculture. We conducted a factorial greenhouse experiment with three factors, brown planthopper (BPH, Nilaparvata lugens Stål) infestation (present/absent), rice cultivar (resistant or susceptible), and fertilizer type (chemical or organic), to test how cultivar and fertilizer affect rice resistance to BPH and, in turn, how BPH alters soil nutrient availability, microbial biomass, and nematode communities through plant-mediated pathways. Both resistant cultivar and organic fertilizer significantly suppressed BPH performance relative to susceptible cultivar and chemical fertilizer. They also mitigated BPH-induced reductions in plant growth, microbial biomass, soil resources, and bacterial- and fungal-feeding nematodes. In contrast, chemical fertilizer exacerbated BPH impacts, particularly on susceptible rice, and promoted root-feeding nematodes. Cultivar and fertilizer independently affected plant and soil responses without showing synergistic interaction. Our findings suggest that combining resistant cultivars with organic fertilizer strengthens resistance to aboveground herbivores and belowground root-feeding nematodes, while enhancing soil resources and food web stability. This integrated strategy provides an effective approach for sustainable pest management and nutrient regulation in rice systems.

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Keywords

plant resistance / aboveground-belowground / Nilaparvata lugens / plant growth / nematodes community

Highlight

	● Resistant rice cultivar and organic fertilizer suppressed brown planthopper performance.
	● Both factors mitigated BPH-induced declined in plant growth and soil microbial biomass.
	● Organic fertilizer reduced root-feeding nematodes and stabilized soil food web structure.
	● Cultivar and fertilizer acted independently, offering a sustainable pest–nutrient strategy.

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Qian Yang, Jinghua Huang, Nan Jin, Jiting Wu, Zhengkun Hu, Feng Hu, Bryan Griffiths, Xiaoyun Chen, Manqiang Liu. Combined effects of resistant rice cultivar and organic fertilizer on plant–soil responses to aboveground brown planthopper. Soil Ecology Letters, 2026, 8(2): 260390 DOI:10.1007/s42832-026-0390-y

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Altieri, M.A., Nicholls, C.I., 2003. Soil fertility management and insect pests: harmonizing soil and plant health in agroecosystems. Soil and Tillage Research72, 203–211.

[2]	Bardgett, R.D., Wardle, D.A., 2010. Aboveground-Belowground Linkages: Biotic Interactions, Ecosystem Processes, and Global Change. Oxford: Oxford University Press.

[3]	Berruto, C.A., Demirer, G.S., 2024. Engineering agricultural soil microbiomes and predicting plant phenotypes. Trends in Microbiology32, 858–873.

[4]	Biere, A., Goverse, A., 2016. Plant-mediated systemic interactions between pathogens, parasitic nematodes, and herbivores above- and belowground. Annual Review of Phytopathology54, 499–527.

[5]	Blundell, R., Schmidt, J.E., Igwe, A., Cheung, A.L., Vannette, R.L., Gaudin, A.C.M., Casteel, C.L., 2020. Organic management promotes natural pest control through altered plant resistance to insects. Nature Plants6, 483–491.

[6]	Cosmo, L.G., Yamaguchi, L.F., Felix, G.M.F., Kato, M.J., Cogni, R., Pareja, M., 2021. From the leaf to the community: distinct dimensions of phytochemical diversity shape insect-plant interactions within and among individual plants. Journal of Ecology109, 2475–2487.

[7]	Cui, S.Y., Liang, S.W., Zhang, X.K., Li, Y.B., Liang, W.J., Sun, L.J., Wang, J.K., Bezemer, T.M., Li, Q., 2018. Long-term fertilization management affects the C utilization from crop residues by the soil micro-food web. Plant and Soil429, 335–348.

[8]	Gao, L.L., Wei, C.Q., He, Y.F., Tang, X.F., Chen, W., Xu, H., Wu, Y.Q., Wilschut, R.A., Lu, X.M., 2023. Aboveground herbivory can promote exotic plant invasion through intra- and interspecific aboveground–belowground interactions. New Phytologist237, 2347–2359.

[9]	Han, P., Lavoir, A.V., Rodriguez-Saona, C., Desneux, N., 2022. Bottom-up forces in agroecosystems and their potential impact on arthropod pest management. Annual Review of Entomology67, 239–259.

[10]	He, H.M., Liu, L.N., Munir, S., Bashir, N.H., Wang, Y., Yang, J., Li, C.Y., 2019. Crop diversity and pest management in sustainable agriculture. Journal of Integrative Agriculture18, 1945–1952.

[11]	Horgan, F.G., 2018. Integrating gene deployment and crop management for improved rice resistance to Asian planthoppers. Crop Protection110, 21–33.

[12]	Horgan, F.G., de Freitas, T.F.S., Crisol-Martínez, E., Mundaca, E.A., Bernal, C.C., 2021. Nitrogenous fertilizer reduces resistance but enhances tolerance to the brown planthopper in fast-growing, moderately resistant rice. Insects12, 989.

[13]	Horgan, F.G., Peñalver-Cruz, A., 2022. Compatibility of insecticides with rice resistance to planthoppers as influenced by the timing and frequency of applications. Insects13, 106.

[14]	Hu, Z.K., Zhu, C.W., Chen, X.Y., Bonkowski, M., Griffiths, B., Chen, F.J., Zhu, J.G., Hu, S.J., Hu, F., Liu, M.Q., 2017. Responses of rice paddy micro-food webs to elevated CO₂ are modulated by nitrogen fertilization and crop cultivars. Soil Biology and Biochemistry114, 104–113.

[15]	Huang, F., Mo, C.H., Li, L.F., Shi, J.L., Yang, Y.W., Liao, X.D., 2022. Organic fertilizer application mediates tomato defense against Pseudomonas syringae pv. Tomato, possibly by reshaping the soil microbiome. Frontiers in Microbiology13, 939911.

[16]

Huang, J.H., Liu, M.Q., Chen, F.J., Griffiths, B.S., Chen, X.Y., Johnson, S.N., Hu, F., 2012. Crop resistance traits modify the effects of an aboveground herbivore, brown planthopper, on soil microbial biomass and nematode community via changes to plant performance. Soil Biology and Biochemistry49, 157–166.

[17]	Huang, J.H., Liu, M.Q., Chen, X.Y., Chen, J., Chen, F.J., Li, H.X., Hu, F., 2013. Intermediate herbivory intensity of an aboveground pest promotes soil labile resources and microbial biomass via modifying rice growth. Plant and Soil367, 437–447.

[18]	Huang, J.H., Liu, M.Q., Chen, X.Y., Chen, J., Li, H.X., Hu, F., 2015. Effects of intraspecific variation in rice resistance to aboveground herbivore, brown planthopper, and rice root nematodes on plant yield, labile pools of plant, and rhizosphere soil. Biology and Fertility of Soils51, 417–425.

[19]	Huberty, M., Choi, Y.H., Heinen, R., Bezemer, T.M., 2020. Above-ground plant metabolomic responses to plant-soil feedbacks and herbivory. Journal of Ecology108, 1703–1712.

[20]	Jenkinson, D.S., 1988. Determination of microbial biomass carbon and nitrogen in soil. In: Wilson, J.R., ed. Advances in Nitrogen Cycling in Agricultural Ecosystems. Wallingford: CAB International, 368–386.

[21]

Jiang, L.H., Bonkowski, M., Luo, L., Kardol, P., Zhang, Y., Chen, X.Y., Li, D.M., Xiao, Z.G., Hu, F., Liu, M.Q., 2020. Combined addition of chemical and organic amendments enhances plant resistance to aboveground herbivores through increasing microbial abundance and diversity. Biology and Fertility of Soils56, 1007–1022.

[22]	Joergensen, R.G., 1995. Microbial biomass. In: Alef, K., Nannipieri, P., eds. Methods in Applied Soil Microbiology and Biochemistry. London: Academic Press, 375–417.

[23]	Jones, D.L., Willett, V.B., 2006. Experimental evaluation of methods to quantify dissolved organic nitrogen (DON) and dissolved organic carbon (DOC) in soil. Soil Biology and Biochemistry38, 991–999.

[24]	Juventia, S.D., Rossing, W.A.H., Ditzler, L., van Apeldoorn, D.F., 2021. Spatial and genetic crop diversity support ecosystem service delivery: a case of yield and biocontrol in Dutch organic cabbage production. Field Crops Research261, 108015.

[25]	Lee, B., Lee, S., Ryu, C.M., 2012. Foliar aphid feeding recruits rhizosphere bacteria and primes plant immunity against pathogenic and non-pathogenic bacteria in pepper. Annals of Botany110, 281–290.

[26]

Lin, S.C., Li, Y., Hu, F.Y., Wang, C.L., Kuang, Y.H., Sung, C.L., Tsai, S.F., Yang, Z.W., Li, C.P., Huang, S.H., Liao, C.T., Hechanova, S.L., Jena, K.K., Chuang, W.P., 2022. Effect of nitrogen fertilizer on the resistance of rice near-isogenic lines with BPH resistance genes. Botanical Studies63, 16.

[27]	Liu, L., Li, S.Y., Wilson, G.W.T., Cobb, A.B., Zhou, C.Y., Li, J.S., Li, J.H., Guo, L.Z., Huang, D., 2021. Nematode communities indicate anthropogenic alterations to soil dynamics across diverse grasslands. Ecological Indicators132, 108338.

[28]	Liu, M.Q., Chen, X.Y., Qin, J.T., Wang, D., Griffiths, B., Hu, F., 2008. A sequential extraction procedure reveals that water management affects soil nematode communities in paddy fields. Applied Soil Ecology40, 250–259.

[29]

Liu, M.Q., Hu, F., Chen, X.Y., Huang, Q.R., Jiao, J.G., Zhang, B., Li, H.X., 2009. Organic amendments with reduced chemical fertilizer promote soil microbial development and nutrient availability in a subtropical paddy field: the influence of quantity, type and application time of organic amendments. Applied Soil Ecology42, 166–175.

[30]	Malacrinò, A., Bennett, A.E., 2024. Soil microbiota and herbivory drive the assembly of tomato plant-associated microbial communities through different mechanisms. Communications Biology7, 564.

[31]	Martinez, D.A., Loening, U.E., Graham, M.C., Gathorne-Hardy, A., 2021. When the medicine feeds the problem; Do nitrogen fertilisers and pesticides enhance the nutritional quality of crops for their pests and pathogens. Frontiers in Sustainable Food Systems5, 701310.

[32]	Megali, L., Glauser, G., Rasmann, S., 2014. Fertilization with beneficial microorganisms decreases tomato defenses against insect pests. Agronomy for Sustainable Development34, 649–656.

[33]

Melakeberhan, H., Maung, Z., Lartey, I., Yildiz, S., Gronseth, J., Qi, J.G., Karuku, G.N., Kimenju, J.W., Kwoseh, C., Adjei-Gyapong, T., 2021. Nematode community-based soil food web analysis of ferralsol, lithosol and nitosol soil groups in Ghana, Kenya and Malawi reveals distinct soil health degradations. Diversity13, 101.

[34]	Morrow, C.J., Jaeger, S.J., Lindroth, R.L., 2022. Intraspecific variation in plant economic traits predicts trembling aspen resistance to a generalist insect herbivore. Oecologia199, 119–128.

[35]	Nalam, V.J., Shah, J., Nachappa, P., 2013. Emerging role of roots in plant responses to aboveground insect herbivory. Insect Science20, 286–296.

[36]	Peñalver-Cruz, A., Horgan, F.G., 2022. Interactions between rice resistance to planthoppers and honeydew-related egg parasitism under varying levels of nitrogenous fertilizer. Insects13, 251.

[37]	Puissant, J., Villenave, C., Chauvin, C., Plassard, C., Blanchart, E., Trap, J., 2021. Quantification of the global impact of agricultural practices on soil nematodes: a meta-analysis. Soil Biology and Biochemistry161, 108383.

[38]	Reverchon, F., Méndez-Bravo, A., 2021. Plant-mediated above-belowground interactions: a phytobiome story. In: Del-Claro, K., Torezan-Silingardi, H.M., eds. Plant-Animal Interactions: Source of Biodiversity. Cham: Springer, 205–231.

[39]	Sun, F., Coulibaly, S.F.M., Cheviron, N., Mougin, C., Hedde, M., Maron, P.A., Recous, S., Trap, J., Villenave, C., Chauvat, M., 2023. The multi-year effect of different agroecological practices on soil nematodes and soil respiration. Plant and Soil490, 109–124.

[40]	Thoden, T.C., Korthals, G.W., Termorshuizen, A.J., 2011. Organic amendments and their influences on plant-parasitic and free-living nematodes: a promising method for nematode management. Nematology13, 133–153.

[41]	Tomita, K.M., Manlick, P.J., Makoto, K., Fujii. S., Hyodo, F., Miyashita, T., Tsunoda, T., 2025. The underappreciated roles of aboveground vertebrates on belowground communities. Trends in Ecology & Evolution40, 364–374.

[42]

Veen, G.F., Wubs, E.R.J., Bardgett, R.D., Barrios, E., Bradford, M.A., Carvalho, S., De Deyn, G.B., de Vries, F.T., Giller, K.E., Kleijn, D., Landis, D.A., Rossing, W.A.H., Schrama, M., Six, J., Struik, P.C., van Gils, S., Wiskerke, J.S.C., van der Putten, W.H., Vet, L.E.M., 2019. Applying the aboveground-belowground interaction concept in agriculture: spatio-temporal scales matter. Frontiers in Ecology and Evolution7, 300.

[43]	Wang, L., Chen, X., Tang, Z.H., 2023. Arbuscular mycorrhizal symbioses improved biomass allocation and reproductive investment of cherry tomato after root-knot nematodes infection. Plant and Soil482, 513–527.

[44]	Wang, M.G., Biere, A., van der Putten, W.H., Bezemer, T.M., Brinkman, E.P., 2017. Timing of simulated aboveground herbivory influences population dynamics of root-feeding nematodes. Plant and Soil415, 215–228.

[45]	Whitham, T.G., Allan, G.J., Cooper, H.F., Shuster, S.M., 2020. Intraspecific genetic variation and species interactions contribute to community evolution. Annual Review of Ecology, Evolution, and Systematics51, 587–612.

[46]	Wilschut, R.A., Geisen, S., 2021. Nematodes as drivers of plant performance in natural systems. Trends in Plant Science26, 237–247.

[47]	Wu, X., Hu, H., Li, S.J., Zhao, J.N., Li, J., Zhang, G.L., Li, G., Xiu, W.M., 2022. Chemical fertilizer reduction with organic material amendments alters co-occurrence network patterns of bacterium-fungus-nematode communities under the wheat-maize rotation regime. Plant and Soil473, 605–623.

[48]	Xiang, W.H., Zhao, L., Xu, X., Qin, Y.H., Yu, G.H., 2012. Mutual information flow between beneficial microorganisms and the roots of host plants determined the bio-functions of biofertilizers. American Journal of Plant Sciences3, 1115–1120.

[49]	Ye, Y.D., Xiong, S.Y., Guan, X., Tang, T.X., Zhu, Z.H., Zhu, X., Hu, J., Wu, J.G., Zhang, S., 2024. Insight into rice resistance to the brown planthopper: gene cloning, functional analysis, and breeding applications. International Journal of Molecular Sciences25, 13397.

[50]	Yeates, G.W., Bongers, T., De Goede, R.G.M., Freckman, D.W., Georgieva, S.S., 1993. Feeding habits in soil nematode families and genera - an outline for soil ecologists. Journal of Nematology25, 315–331.

[51]	Zeigler, R.S., 2009. Preface. In: Heong, K.L., Hardy, B., eds. Planthoppers: New Threats to the Sustainability of Intensive Rice Production Systems in Asia. Los Baños, Philippines: International Rice Research Institute, V-VI.