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Bünemann EK, Bongiorno G, Bai Z, Creamer RE, De Deyn G, et al. 2018. Soil quality – a critical review. Soil Biology and Biochemistry 120:105−125

Hou D, Jia X, Wang L, McGrath SP, Zhu YG, et al. 2025. Global soil pollution by toxic metals threatens agriculture and human health. Science 388:316−321

Wang H, Ren W, Xu Y, Wang X, Ma J, Sun Y, et al. 2024. Long-term herbicide residues affect soil multifunctionality and the soil microbial community. Ecotoxicology and Environmental Safety 283:116783

Wen X, Fu Y, Xiang L, He C, Harindintwali JD, Wang Y, et al. 2025. Impact of long-term use of multiple herbicides on soil microbial communities and nutrient cycling across different agricultural land-use types. Agriculture, Ecosystems & Environment 394:109879

Wang K, Ren Y, Pan X, Wu X, Xu J, Zheng Y, et al. 2025. Insights on persistent herbicides in cropland soils in northern China: occurrence, ecological risks, and phytotoxicity to subsequent crops. Journal of Hazardous Materials 490:137794

Arias-Estévez M, López-Periago E, Martínez-Carballo E, Simal-Gándara J, Mejuto JC, et al. 2008. The mobility and degradation of pesticides in soils and the pollution of groundwater resources. Agriculture, Ecosystems & Environment 123:247−260

Hernandez-Tenorio F, Miranda AM, Rodríguez CA, Giraldo-Estrada C, Sáez AA. 2022. Potential strategies in the biopesticide formulations: a bibliometric analysis. Agronomy 12:2665

Chen Y, Hajslova J, Schusterova D, Uttl L, Vymazal J, et al. 2025. Influence of arbuscular mycorrhizal fungi symbiosis on S-metolachlor and its metabolites dynamics in constructed wetlands. Process Safety and Environmental Protection 198:107109

García Carriquiry I, Silva V, Inchausti P, Niell S, Berro Pizzarossa A, Medina M, et al. 2025. The effects of sequential herbicide applications on phosphorus cycling and mycorrhization in soybean: a two-year field study. Agriculture, Ecosystems & Environment 392:109754

Ruuskanen S, Fuchs B, Nissinen R, Puigbò P, Rainio M, et al. 2023. Ecosystem consequences of herbicides: the role of microbiome. Trends in Ecology & Evolution 38:35−43

Devendrapandi G, Liu X, Balu R, Ayyamperumal R, Valan Arasu M, et al. 2024. Innovative remediation strategies for persistent organic pollutants in soil and water: a comprehensive review. Environmental Research 249:118404

Parven A, Meftaul IM, Venkateswarlu K, Megharaj M. 2025. Herbicides in modern sustainable agriculture: environmental fate, ecological implications, and human health concerns. International Journal of Environmental Science and Technology 22:1181−1202

Amarnath K, Narla AV, Pontrelli S, Dong J, Reddan J, et al. 2023. Stress-induced metabolic exchanges between complementary bacterial types underly a dynamic mechanism of inter-species stress resistance. Nature Communications 14:3165

Johns NI, Blazejewski T, Gomes AL, Wang HH. 2016. Principles for designing synthetic microbial communities. Current Opinion in Microbiology 31:146−153

Vergel-Castro C, Boom-Cárcamo E. 2025. Challenges and opportunities in the use of microbial inoculants in hydroponic crops: a literature review. The Microbe 9:100556

Bhardwaj P, Singh KR, Jadeja NB, Phale PS, Kapley A. 2020. Atrazine bioremediation and its influence on soil microbial diversity by metagenomics analysis. Indian Journal of Microbiology 60:388−391

Cycoń M, Mrozik A, Piotrowska-Seget Z. 2017. Bioaugmentation as a strategy for the remediation of pesticide-polluted soil: a review. Chemosphere 172:52−71

Urseler N, Bachetti R, Morgante V, Agostini E, Morgante C. 2022. Atrazine behavior in an agricultural soil: adsorption–desorption, leaching, and bioaugmentation with Arthrobacter sp. strain AAC22. Journal of Soils and Sediments 22:93−108

Jablonowski ND, Hamacher G, Martinazzo R, Langen U, Köppchen S, et al. 2010. Metabolism and persistence of atrazine in several field soils with different atrazine application histories. Journal of Agricultural and Food Chemistry 58:12869−12877

Krutz LJ, Shaner DL, Zablotowicz RM. 2010. Enhanced degradation and soil depth effects on the fate of atrazine and major metabolites in Colorado and Mississippi soils. Journal of Environmental Quality 39:1369−1377

Fenner K, Canonica S, Wackett LP, Elsner M. 2013. Evaluating pesticide degradation in the environment: blind spots and emerging opportunities. Science 341:752−758

Chen G, Yang Y, Yan J, Löffler FE. 2024. Metabolite cross-feeding enables concomitant catabolism of chlorinated methanes and chlorinated ethenes in synthetic microbial assemblies. The ISME Journal 18:wrae090

Wang Z, Wang S, He Q, Yang X, Zhao B, et al. 2025. Ecological design of high-performance synthetic microbial communities: from theoretical foundations to functional optimization. ISME Communications 5:ycaf133

Pileggi M, Pileggi SAV, Sadowsky MJ. 2020. Herbicide bioremediation: from strains to bacterial communities. Heliyon 6:e05767

de Souza ML, Newcombe D, Alvey S, Crowley DE, Hay A, et al. 1998. Molecular basis of a bacterial consortium: interspecies catabolism of atrazine. Applied and Environmental Microbiology 64:178−184

Strong LC, Rosendahl C, Johnson G, Sadowsky MJ, Wackett LP. 2002. Arthrobacter aurescens TC1 metabolizes diverse s-triazine ring compounds. Applied and Environmental Microbiology 68:5973−5980

Sun Y, Zhao L, Li X, Hao Y, Xu H, Weng L, et al. 2019. Stimulation of earthworms (Eisenia fetida) on soil microbial communities to promote metolachlor degradation. Environmental Pollution 248:219−228

Baćmaga M, Wyszkowska J, Borowik A, Kucharski J. 2022. Effects of tebuconazole application on soil microbiota and enzymes. Molecules 27:7501

Cui N, Wang S, Khorram MS, Fang H, Yu Y. 2018. Microbial degradation of fomesafen and detoxification of fomesafen-contaminated soil by the newly isolated strain Bacillus sp. FE-1 via a proposed biochemical degradation pathway. Science of The Total Environment 616−617:1612−1619

Billet L, Devers M, Rouard N, Martin-Laurent F, Spor A. 2019. Labour sharing promotes coexistence in atrazine degrading bacterial communities. Scientific Reports 9:18363

Smith D, Alvey S, Crowley DE. 2005. Cooperative catabolic pathways within an atrazine-degrading enrichment culture isolated from soil. FEMS Microbiology Ecology 53:265−275

Elsayed OF, Maillard E, Vuilleumier S, Millet M, Imfeld G. 2015. Degradation of chloroacetanilide herbicides and bacterial community composition in lab-scale wetlands. Science of The Total Environment 520:222−231

Liu X, Chen K, Chuang S, Xu X, Jiang J. 2019. Shift in bacterial community structure drives different atrazine-degrading efficiencies. Frontiers in Microbiology 10:88

Kundu K, Marozava S, Ehrl B, Merl-Pham J, Griebler C, et al. 2019. Defining lower limits of biodegradation: atrazine degradation regulated by mass transfer and maintenance demand in Arthrobacter aurescens TC1. The ISME Journal 13:2236−2251

Patel SS, Shree T, Kumar A. 2026. Microbial consortia interactions and bioremediation of pesticides: a review on designing, mechanism and efficacy. Pesticide Biochemistry and Physiology 219:106993

Slanzon GS, Yuan M, Estera-Molina K, Chew A, Blazewicz SJ, et al. 2025. Quantitative stable isotope probing (qSIP) and cross-domain networks reveal bacterial-fungal interactions in the hyphosphere. Microbiome 13:109

Xiang Q, Stryhanyuk H, Schmidt M, Kümmel S, Richnow HH, et al. 2024. Stable isotopes and nanoSIMS single-cell imaging reveals soil plastisphere colonizers able to assimilate sulfamethoxazole. Environmental Pollution 355:124197

Schaible GA, Cliff JB, Crandall JA, Bougoure JJ, Mathuri MN, et al. 2025. Comparing Raman and NanoSIMS for heavy water labeling of single cells. Microbiology Spectrum 13:e01659-24

Meng L, Sun T, Li M, Saleem M, Zhang Q, et al. 2019. Soil-applied biochar increases microbial diversity and wheat plant performance under herbicide fomesafen stress. Ecotoxicology and Environmental Safety 171:75−83

Shahid M, Khan MS, Singh UB. 2023. Pesticide-tolerant microbial consortia: potential candidates for remediation/clean-up of pesticide-contaminated agricultural soil. Environmental Research 236:116724

Shayanthan A, Ordoñez PAC, Oresnik IJ. 2022. The role of synthetic microbial communities (SynCom) in sustainable agriculture. Frontiers in Agronomy 4:896307

Fedorec AJH, Karkaria BD, Sulu M, Barnes CP. 2021. Single strain control of microbial consortia. Nature Communications 12:1977

Chang X, Liang J, Sun Y, Zhao L, Zhou B, et al. 2020. Isolation, degradation performance and field application of the metolachlor-degrading fungus Penicillium oxalicum MET-F-1. Applied Sciences 10:8556

Rice PJ, Anderson TA, Coats JR. 2002. Degradation and persistence of metolachlor in soil: effects of concentration, soil moisture, soil depth, and sterilization. Environmental Toxicology and Chemistry 21:2640−2648

Sarnaik A, Liu A, Nielsen D, Varman AM. 2020. High-throughput screening for efficient microbial biotechnology. Current Opinion in Biotechnology 64:141−150

Xu X, Zarecki R, Medina S, Ofaim S, Liu X, et al. 2019. Modeling microbial communities from atrazine contaminated soils promotes the development of biostimulation solutions. The ISME Journal 13:494−508

Kostka JE, Green SJ, Rishishwar L, Prakash O, Katz LS, et al. 2012. Genome sequences for six rhodanobacter strains, isolated from soils and the terrestrial subsurface, with variable denitrification capabilities. Journal of Bacteriology 194:4461−4462

Liu YX, Qin Y, Bai Y. 2019. Reductionist synthetic community approaches in root microbiome research. Current Opinion in Microbiology 49:97−102

Northen TR, Kleiner M, Torres M, Kovács ÁT, Nicolaisen MH, et al. 2024. Community standards and future opportunities for synthetic communities in plant–microbiota research. Nature Microbiology 9:2774−2784