Synergistic effect of microplastics and cadmium on microbial community and functional taxa in wheat rhizosphere soil

Jianhong Ji, Yingying Zhong, Mouliang Xiao, Xianting Wang, Zhi’e Hu, Mianjin Zhan, Jina Ding, Zhenke Zhu, Tida Ge

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Soil Ecology Letters ›› 2025, Vol. 7 ›› Issue (1) : 240260. DOI: 10.1007/s42832-024-0260-4
RESEARCH ARTICLE

Synergistic effect of microplastics and cadmium on microbial community and functional taxa in wheat rhizosphere soil

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Highlights

● Cd alone or combined with microplastics (MPs) enhanced wheat biomass.

● Cd alone or combined with MPs greatly affected soil microorganism activity.

● MPs reduced nutrient cycling functional microbial abundance under Cd treatment.

Abstract

Microplastics and heavy metal contamination poses major threats to soil function and food security; however, their synergistic effects remain largely unclear. This study investigated the effects of single or combined addition of polyethylene (PE) microplastic (1% w/w) and cadmium (Cd; 1.5 and 5 mg kg–1) on functional microbial communities in the wheat rhizosphere soil. We observed that the biomass of wheat increased by 142.44% under high doses of Cd addition. The bacterial alpha diversity in wheat bulk soil reduced by 37.34%–37.83% with the combined addition of microplastic and Cd. The addition of microplastic reduced the relative abundance of Proteus involved in nitrogen fixation by 19.93%, while the relative abundance of Proteus and Actinobacteria involved in nitrogen cycling increased with the increase of Cd concentration, increasing by 27.96%–37.37% and 51.14%–55.04%, respectively. FAPROTAX analysis revealed that increasing Cd concentration promoted the abundance of functional bacterial communities involved in nitrification/denitrification and nitrate/nitrite respiration in rhizosphere soil. A FunGuild analysis showed that the synergy of PE-microplastics and Cd increased the abundance of saprophytic fungi, suggesting an enhanced degradation function. Our findings provide new knowledge on the effects of microplastics and heavy metals on soil microorganisms and functional microbial communities in agricultural soil.

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Keywords

microplastics / cadmium / bacteria and fungi / microbial function taxa

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Jianhong Ji, Yingying Zhong, Mouliang Xiao, Xianting Wang, Zhi’e Hu, Mianjin Zhan, Jina Ding, Zhenke Zhu, Tida Ge. Synergistic effect of microplastics and cadmium on microbial community and functional taxa in wheat rhizosphere soil. Soil Ecology Letters, 2025, 7(1): 240260 https://doi.org/10.1007/s42832-024-0260-4

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]
Aponte, H., Medina, J., Butler, B., Meier, S., Cornejo, P., Kuzyakov, Y., 2020. Soil quality indices for metal(loid) contamination: an enzymatic perspective. Land Degradation & Development31, 2700–2719.
CrossRef Google scholar
[2]
Bosker, T., Bouwman, L.J., Brun, N.R., Behrens, P., Vijver, M.G., 2019. Microplastics accumulate on pores in seed capsule and delay germination and root growth of the terrestrial vascular plant Lepidium sativum. Chemosphere226, 774–781.
CrossRef Google scholar
[3]
Callahan, B.J., McMurdie, P.J., Rosen, M.J., Han, A.W., Johnson, A.J.A., Holmes, S.P., 2016. DADA2: high-resolution sample inference from Illumina amplicon data. Nature Methods13, 581–583.
CrossRef Google scholar
[4]
Caporaso, J.G., Kuczynski, J., Stombaugh, J., Bittinger, K., Bushman, F.D., Costello, E.K., Fierer, N., Peña, A.G., Goodrich, J.K., Gordon, J.I., Huttley, G.A., Kelley, S.T., Knights, D., Koenig, J.E., Ley, R.E., Lozupone, C.A., McDonald, D., Muegge, B.D., Pirrung, M., Reeder, J., Sevinsky, J.R., Turnbaugh, P.J., Walters, W.A., Widmann, J., Yatsunenko, T., Zaneveld, J., Knight, R., 2010. QIIME allows analysis of high-throughput community sequencing data. Nature Methods7, 335–336.
CrossRef Google scholar
[5]
Dai, H.P., Shan, C.J., Jia, G.L., Yang, T.X., Wei, A.Z., Zhao, H., Wu, S.Q., Huo, K.K., Chen, W.Q., Cao, X.Y., 2013. Responses to cadmium tolerance, accumulation and translocation in Populus × canescens. Water, Air, & Soil Pollution224, 1504.
CrossRef Google scholar
[6]
Fan, P.H., Wu, L.W., Wang, Q., Wang, Y., Luo, H.M., Song, J.Y., Yang, M.H., Yao, H., Chen, S.L., 2023. Physiological and molecular mechanisms of medicinal plants in response to cadmium stress: current status and future perspective. Journal of Hazardous Materials450, 131008.
CrossRef Google scholar
[7]
He, S.Y., Wei, Y.F., Li, Z.H., Yang, C.P., 2023. Aging microplastic aggravates the pollution of heavy metals in rhizosphere biofilms. Science of the Total Environment890, 164177.
CrossRef Google scholar
[8]
Hou, J.H., Xu, X.J., Yu, H., Xi, B.D., Tan, W.B., 2021. Comparing the long-term responses of soil microbial structures and diversities to polyethylene microplastics in different aggregate fractions. Environment International149, 106398.
CrossRef Google scholar
[9]
Huang, F.Y., Hu, J.Z., Chen, L., Wang, Z., Sun, S.Y., Zhang, W.M., Jiang, H., Luo, Y., Wang, L., Zeng, Y., Fang, L.C., 2023. Microplastics may increase the environmental risks of Cd via promoting Cd uptake by plants: a meta-analysis. Journal of Hazardous Materials448, 130887.
CrossRef Google scholar
[10]
Ji, L., Tanunchai, B., Wahdan, S.F.M., Schädler, M., Purahong, W., 2022. Future climate change enhances the complexity of plastisphere microbial co-occurrence networks, but does not significantly affect the community assembly. Science of the Total Environment844, 157016.
CrossRef Google scholar
[11]
Kandeler, F., Kampichler, C., Horak, O., 1996. Influence of heavy metals on the functional diversity of soil microbial communities. Biology and Fertility of Soils23, 299–306.
CrossRef Google scholar
[12]
Katoh, K., Misawa, K., Kuma, K.I., Miyata, T., 2002. MAFFT: a novel method for rapid multiple sequence alignment based on fast Fourier transform. Nucleic Acids Research30, 3059–3066.
CrossRef Google scholar
[13]
Kim, S.W., Rillig, M.C., 2022. Research trends of microplastics in the soil environment: comprehensive screening of effects. Soil Ecology Letters4, 109–118.
CrossRef Google scholar
[14]
Kumar, R., Ivy, N., Bhattacharya, S., Dey, A., Sharma, P., 2022. Coupled effects of microplastics and heavy metals on plants: uptake, bioaccumulation, and environmental health perspectives. Science of the Total Environment836, 155619.
CrossRef Google scholar
[15]
Kuypers, M.M.M., Marchant, H.K., Kartal, B., 2018. The microbial nitrogen-cycling network. Nature Reviews Microbiology16, 263–276.
CrossRef Google scholar
[16]
Kuzyakov, Y., Razavi, B.S., 2019. Rhizosphere size and shape: temporal dynamics and spatial stationarity. Soil Biology and Biochemistry135, 343–360.
CrossRef Google scholar
[17]
Li, H.Q., Shen, Y.J., Wang, W.L., Wang, H.T., Li, H., Su, J.Q., 2021. Soil pH has a stronger effect than arsenic content on shaping plastisphere bacterial communities in soil. Environmental Pollution287, 117339.
CrossRef Google scholar
[18]
Li, Y.F., Zhang, S.B., Fang, Y.Y., Hui, D.F., Tang, C.X., Van Zwieten, L., Zhou, J.S., Jiang, Z.H., Cai, Y.J., Yu, B., Hu, J.G., Zhou, G.M., Gu, B.J., Chang, S.X., 2024. Nitrogen deposition-induced stimulation of soil heterotrophic respiration is counteracted by biochar in a subtropical forest. Agricultural and Forest Meteorology349, 109940.
CrossRef Google scholar
[19]
Lin, X.L., Li, Y.J., Xu, G.H., Tian, C.J., Yu, Y., 2022. Biodegradable microplastics impact the uptake of Cd in rice: the roles of niche breadth and assembly process. Science of the Total Environment851, 158222.
CrossRef Google scholar
[20]
Liu, Y.H., Xiao, M.L., Shahbaz, M., Hu, Z., Zhu, Z.K., Lu, S.B., Yu, Y.X., Yao, H.Y., Chen, J.P., Ge, T.D., 2022. Microplastics in soil can increase nutrient uptake by wheat. Journal of Hazardous Materials438, 129547.
CrossRef Google scholar
[21]
Liu, Y.H., Zhong, Y.Y., Hu, C., Xiao, M.L., Ding, F., Yu, Y.X., Yao, H.Y., Zhu, Z.K., Chen, J.P., Ge, T.D., Ding, J.N., 2023. Distribution of microplastics in soil aggregates after film mulching. Soil Ecology Letters5, 230171.
CrossRef Google scholar
[22]
Luo, J.P., Guo, X.Y., Tao, Q., Li, J.X., Liu, Y.K., Du, Y.L., Liu, Y.Y., Liang, Y.C., Li, T.Q., 2021. Succession of the composition and co-occurrence networks of rhizosphere microbiota is linked to Cd/Zn hyperaccumulation. Soil Biology and Biochemistry153, 108120.
CrossRef Google scholar
[23]
McDonald, D., Price, M.N., Goodrich, J., Nawrocki, E.P., DeSantis, T.Z., Probst, A., Andersen, G.L., Knight, R., Hugenholtz, P., 2012. An improved Greengenes taxonomy with explicit ranks for ecological and evolutionary analyses of bacteria and archaea. The ISME Journal6, 610–618.
CrossRef Google scholar
[24]
Mohammad, A., Mittra, B., 2013. Effects of inoculation with stress-adapted arbuscular mycorrhizal fungus Glomus deserticola on growth of Solanum melogena L. and Sorghum sudanese Staph. seedlings under salinity and heavy metal stress conditions. Archives of Agronomy and Soil Science59, 173–183.
CrossRef Google scholar
[25]
Nguyen, N.H., Song, Z.W., Bates, S.T., Branco, S., Tedersoo, L., Menke, J., Schilling, J.S., Kennedy, P.G., 2016. FUNGuild: an open annotation tool for parsing fungal community datasets by ecological guild. Fungal Ecology20, 241–248.
CrossRef Google scholar
[26]
Price, M.N., Dehal, P.S., Arkin, A.P., 2010. FastTree 2 – approximately maximum-likelihood trees for large alignments. PLoS One5, e9490.
CrossRef Google scholar
[27]
Qi, Y.L., Ossowicki, A., Yang, X.M., Huerta Lwanga, E., Dini-Andreote, F., Geissen, V., Garbeva, P., 2020. Effects of plastic mulch film residues on wheat rhizosphere and soil properties. Journal of Hazardous Materials387, 121711.
CrossRef Google scholar
[28]
Razavi, B.S., Hoang, D.T.T., Blagodatskaya, E., Kuzyakov, Y., 2017. Mapping the footprint of nematodes in the rhizosphere: Cluster root formation and spatial distribution of enzyme activities. Soil Biology and Biochemistry115, 213–220.
CrossRef Google scholar
[29]
Rex, D., Clough, T.J., Richards, K.G., de Klein, C., Morales, S.E., Samad, M.S., Grant, J., Lanigan, G.J., 2018. Fungal and bacterial contributions to codenitrification emissions of N2O and N2 following urea deposition to soil. Nutrient Cycling in Agroecosystems110, 135–149.
CrossRef Google scholar
[30]
Rillig, M.C., Ingraffia, R., de Souza Machado, A.A., 2017. Microplastic incorporation into soil in agroecosystems. Frontiers in Plant Science8, 1805.
CrossRef Google scholar
[31]
Rillig, M.C., Lehmann, A., 2020. Microplastic in terrestrial ecosystems. Science368, 1430–1431.
CrossRef Google scholar
[32]
Sansupa, C., Wahdan, S.F.M., Hossen, S., Disayathanoowat, T., Wubet, T., Purahong, W., 2021. Can we use functional annotation of prokaryotic taxa (FAPROTAX) to assign the ecological functions of soil bacteria? Applied Sciences 11, 688.
[33]
Song, B., Shang, S.Y., Cai, F.M., Liu, Z.H., Fang, J., Li, N., Adams, J.M., Razavi, B.S., 2023. Microbial resistance in rhizosphere hotspots under biodegradable and conventional microplastic amendment: community and functional sensitivity. Soil Biology and Biochemistry180, 108989.
CrossRef Google scholar
[34]
Su, P.J., Gao, C.Y., Zhang, X.J., Zhang, D., Liu, X.Y., Xiang, T.T., Luo, Y.F., Chu, K., Zhang, G.H., Bu, N.S., Li, Z.L., 2023. Microplastics stimulated nitrous oxide emissions primarily through denitrification: a meta-analysis. Journal of Hazardous Materials445, 130500.
CrossRef Google scholar
[35]
Tong, Y.Y., Ding, J.N., Xiao, M.L., Shahbaz, M., Zhu, Z.K., Chen, M., Kuzyakov, Y., Deng, Y.W., Chen, J.P., Ge, T.D., 2023. Microplastics affect activity and spatial distribution of C, N, and P hydrolases in rice rhizosphere. Soil Ecology Letters5, 220138.
CrossRef Google scholar
[36]
Wang, F., Wang, Y., Xiang, L.L., Redmile-Gordon, M., Gu, C.G., Yang, X.L., Jiang, X., Barceló, D., 2022. Perspectives on ecological risks of microplastics and phthalate acid esters in crop production systems. Soil Ecology Letters4, 97–108.
CrossRef Google scholar
[37]
Wang, F.L., Wang, X.X., Chen, Q.H., Song, N.N., 2021a. Extension of a biotic ligand model for predicting the toxicity of metalloid selenate to wheat: the effects of pH, phosphate and sulphate. Chemosphere264, 128424.
CrossRef Google scholar
[38]
Wang, M., Han, Y.Y., Xu, Z.W., Wang, S.Z., Jiang, M., Wang, G.D., 2021b. Hummock-hollow microtopography affects soil enzyme activity by creating environmental heterogeneity in the sedge-dominated peatlands of the Changbai Mountains, China. Ecological Indicators121, 107187.
CrossRef Google scholar
[39]
Wu, J., Joergensen, R.G., Pommerening, B., Chaussod, R., Brookes, P.C., 1990. Measurement of soil microbial biomass C by fumigation-extraction—an automated procedure. Soil Biology and Biochemistry22, 1167–1169.
CrossRef Google scholar
[40]
Xiao, M.L., Ding, J., Luo, Y., Zhang, H.Q., Yu, Y.X., Yao, H.Y., Zhu, Z.K., Chadwick, D.R., Jones, D., Chen, J.P., Ge, T.D., 2022. Microplastics shape microbial communities affecting soil organic matter decomposition in paddy soil. Journal of Hazardous Materials431, 128589.
CrossRef Google scholar
[41]
Xiao, M.L., Shahbaz, M., Liang, Y., Yang, J., Wang, S., Chadwicka, D.R., Jones, D., Chen, J.P., Ge, T.D., 2021. Effect of microplastics on organic matter decomposition in paddy soil amended with crop residues and labile C: A three-source-partitioning study. Journal of Hazardous Materials416, 126221.
CrossRef Google scholar
[42]
Xie, Y., Fan, J.B., Zhu, W.X., Amombo, E., Lou, Y.H., Chen, L., Fu, J.M., 2016. Effect of heavy metals pollution on soil microbial diversity and bermudagrass genetic variation. Frontiers in Plant Science7, 755.
CrossRef Google scholar
[43]
Xu, Z.X., Wang, X.F., Wang, L., Xing, J.F., He, X.W., Wang, Z.B., Zhao, P.F., 2023. Distribution characteristics of plastic film residue in long-term mulched farmland soil. Soil Ecology Letters5, 220144.
CrossRef Google scholar
[44]
Zang, H.D., Zhou, J., Marshall, M.R., Chadwick, D.R., Wen, Y., Jones, D.L., 2020. Microplastics in the agroecosystem: are they an emerging threat to the plant-soil system? Soil Biology and Biochemistry 148, 107926.
[45]
Zhang, G.S., Liu, Y.F., 2018. The distribution of microplastics in soil aggregate fractions in southwestern China. Science of the Total Environment642, 12–20.
CrossRef Google scholar
[46]
Zhang, J., Wang, L.H., Yang, J.C., Liu, H., Dai, J.L., 2015. Health risk to residents and stimulation to inherent bacteria of various heavy metals in soil. Science of the Total Environment508, 29–36.
CrossRef Google scholar
[47]
Zhang, S.W., Han, B., Sun, Y.H., Wang, F.Y., 2020. Microplastics influence the adsorption and desorption characteristics of Cd in an agricultural soil. Journal of Hazardous Materials388, 121775.
CrossRef Google scholar
[48]
Zhao, H.C., Lin, J.H., Wang, X.H., Shi, J.C., Dahlgren, R.A., Xu, J.M., 2021. Dynamics of soil microbial N-cycling strategies in response to cadmium stress. Environmental Science & Technology55, 14305–14315.
CrossRef Google scholar
[49]
Zhou, B.Y., Wang, J.Q., Zhang, H.B., Shi, H.H., Fei, Y.F., Huang, S.Y., Tong, Y.Z., Wen, D.S., Luo, Y.M., Barceló, D., 2020. Microplastics in agricultural soils on the coastal plain of Hangzhou Bay, East China: multiple sources other than plastic mulching film. Journal of Hazardous Materials388, 121814.
CrossRef Google scholar
[50]
Zhou, J.S., Zhang, S.B., Hui, D.F., Vancov, T., Fang, Y.Y., Tang, C.X., Jiang, Z.H., Ge, T.D., Cai, Y.J., Yu, B., White, J.C., Li, Y.F., 2024. Pyrogenic organic matter decreases while fresh organic matter increases soil heterotrophic respiration through modifying microbial activity in a subtropical forest. Biology and Fertility of Soils60, 509–524.
CrossRef Google scholar
[51]
Zhu, J.H., Liu, S.Q., Wang, H.Q., Wang, D.R., Zhu, Y.T., Wang, J.W., He, Y., Zheng, Q.P., Zhan, X.H., 2022. Microplastic particles alter wheat rhizosphere soil microbial community composition and function. Journal of Hazardous Materials436, 129176.
CrossRef Google scholar
[52]
Zong, X.Y., Zhang, J.J., Zhu, J.W., Zhang, L.Y., Jiang, L.J., Yin, Y., Guo, H.Y., 2021. Effects of polystyrene microplastic on uptake and toxicity of copper and cadmium in hydroponic wheat seedlings (Triticum aestivum L. ). Ecotoxicology and Environmental Safety217, 112217.
CrossRef Google scholar

Acknowledgements

This study was supported by the Ningbo Science and Technology Bureau (Grant No. 2022S103), the National Natural Science Foundation of China (Grant Nos. 42107341, 42307420), the UK Natural Environment Research Council and the Global Challenges Research Fund (Grant No. NE/V005871/1) and the K. C. Wong Magna Fund at Ningbo University.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Electronic supplementary material

Supplementary material is available in the online version of this article at https://doi.org/10.1007/s42832-024-0260-4 and is accessible for authorized users.

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