Bacillus subtilis immobilization on biochars produced from different feedstocks and pyrolysis temperatures: performance, mechanisms, and salt tolerance

Zhixiang Jiang; Bin Liu; Rui Chen; Liankai Zhang; Guiren Chen

doi:10.1186/s40643-026-01070-z

Bioresources and Bioprocessing ›› 2026, Vol. 13 ›› Issue (1) :85 DOI: 10.1186/s40643-026-01070-z

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Bacillus subtilis immobilization on biochars produced from different feedstocks and pyrolysis temperatures: performance, mechanisms, and salt tolerance

Zhixiang Jiang ¹^,²^,^a
, Bin Liu ²
, Rui Chen ¹^,³
, Liankai Zhang ¹^,³
, Guiren Chen ¹^,³^,^b

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Abstract

Using biochar as a carrier to enhance the adaptability and survival of inoculated microorganisms under harsh environmental conditions is considered as a promising strategy. However, the immobilization performance and underlying mechanisms of microorganisms on different biochars remain insufficiently understood. In this study, a series of biochars were prepared from various feedstocks and at different temperatures, and their capacities to immobilize Bacillus subtilis (B.subtilis) were evaluated. The results demonstrated that high-temperature (700 °C) biochars exhibited 14.40%–60.00% greater loading capacity for B.subtilis, compared to low-temperature (400 °C) biochars. Analyses of surface morphology, functional groups, hydrophobicity, and Zeta potential before and after immobilization indicated that B.subtilis loading significantly altered the surface properties of biochar, including increases in C and N contents, enhanced richness and diversity of functional groups, and a transformation from hydrophobicity to hydrophilicity. Adsorption kinetics and isotherm modeling revealed that the immobilization process was dominated by chemical adsorption, characterized by monolayer adsorption on a homogeneous surface. Interface interaction analysis further confirmed that the electrostatic interaction, hydrogen bonding, and hydrophobic forces between the functional groups of biochar and those on B.subtilis cells synergistically facilitated microbial immobilization. Based on these findings, a two-stage adsorption process of B.subtilis on biochar was proposed: initial surface adhesion and pore filling, followed by extracellular polymer and surface functional group complexation. Biochar properties, including specific surface area, pore volume, Zeta potential, hydrophobicity, C/N ratio, and surface functional groups, were further identified as key factors influencing immobilization. Finally, the salt tolerance of B.subtilis was significantly enhanced when immobilized on biochars, particularly corn straw biochars with large specific surface areas and developed pore structures. This improved salt tolerance suggests that the biochar-based microbial fertilizers could serve as a promising approach for the amelioration of salt-alkaline soil.

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Adsorption kinetics / Adsorption isotherm / Biochar-based microbial fertilizer / Biochar properties / Pyrolysis temperature / Salt tolerance test

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Zhixiang Jiang, Bin Liu, Rui Chen, Liankai Zhang, Guiren Chen. Bacillus subtilis immobilization on biochars produced from different feedstocks and pyrolysis temperatures: performance, mechanisms, and salt tolerance. Bioresources and Bioprocessing, 2026, 13 (1) : 85 DOI:10.1186/s40643-026-01070-z

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References

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[1]	Angeles DM, Scheffers DJ. The cell wall of Bacillus subtilis. Curr Issues Mol Biol, 2021, 41: 539-596.

[2]	Bazihizina N, Papenbrock J, Aronsson H, Ben Hamed K, Elmaz O, Dafku Z, Custodio L, Rodrigues MJ, Atzori G, Negacz K. The sustainable use of halophytes in salt-affected land: State-of-the-art and next steps in a saltier world. Plants (Basel), 2024, 13: 2322.

[3]	Bejarano A, Sauer U, Mitter B, Preininger C. Parameters influencing adsorption of Paraburkholderia phytofirmans PsJN onto bentonite, silica and talc for microbial inoculants. Appl Clay Sci, 2017, 141: 138-145.

[4]	Bolan S, Hou D, Wang L, Hale L, Egamberdieva D, Tammeorg P, Li R, Wang B, Xu J, Wang T, Sun H, Padhye LP, Wang H, Siddique KHM, Rinklebe J, Kirkham MB, Bolan N. The potential of biochar as a microbial carrier for agricultural and environmental applications. Sci Total Environ, 2023, 886: 163968.

[5]	Boukhelata N, Taguett F, Kaci Y. Characterization of an extracellular polysaccharide produced by a Saharan bacterium Paenibacillus tarimensis REG 0201 M. Ann Microbiol, 2018, 69: 93-106.

[6]	Boyandin AN, Lobova TI, Krylova TY, Kargatova TV, Popova LY, Pechurkin NS (2000) Effect of salinity on the adaptive capacity of recombinant strains of Escherichia coli and Bacillus subtilis. Microbiolog 69(2): 196‒199 http://dx.doi.org/10.1007/BF02756198

[7]	Brosh T, Kalman H, Levy A, Peyron I, Ricard F. DEM–CFD simulation of particle comminution in jet-mill. Powder Technol, 2014, 257: 104-112.

[8]	Cam S, Badilli I. The effect of NaCl, pH, and phosphate on biofilm formation and exopolysaccharide production by high biofilm producers of Bacillus strains. Folia Microbiol (Praha), 2023, 69: 613-624.

[9]	Chen SS, Rotaru AE, Shrestha PM, Malvankar NS, Liu FH, Fan W, Nevin KP, Lovley DR (2014) Promoting interspecies electron transfer with biochar. Sci Rep 4: 5019 https://doi.org/10.1038/srep05019

[10]	Dai Y, Zheng H, Jiang Z, Xing B. Combined effects of biochar properties and soil conditions on plant growth: A meta-analysis. Sci Total Environ, 2020, 713: 136635.

[11]	Deng Z, Wang J, Yan Y, Wang J, Shao W, Wu Z. Biochar-based Bacillus subtilis inoculants promote plant growth: Regulating microbial community to improve soil properties. J Environ Manage, 2025, 373: 123534.

[12]	Dubois T, Krzewinski F, Yamakawa N, Lemy C, Hamiot A, Brunet L, Lacoste AS, Knirel Y, Guerardel Y, Faille C. The sps genes encode an original legionaminic acid pathway required for crust assembly in Bacillus subtilis. mBio, 2020, 11: 17.

[13]	Du Z, Chen H, Yao Y, An Y (2022) Research progress of biochar immobilized microorganism in soil pollution remediation. J Agro-Environ Sci 41: 2584–2592. https://link.cnki.net/urlid/12.1347.S.20221213.1246.002 (in Chinese with English abstract)

[14]	Feng H, Chen L, Ding Y, Ma X, How SW, Wu D. Mechanism on the microbial salt tolerance enhancement by electrical stimulation. Bioelectrochemistry, 2022, 147: 108206.

[15]	Gong Y, Niu Q, Liu Y, Dong J, Xia M. Development of multifarious carrier materials and impact conditions of immobilised microbial technology for environmental remediation: A review. Environ Pollut, 2022, 314: 120232.

[16]	Hrenovic J, Ivankovic T, Tibljas D. The effect of mineral carrier composition on phosphate-accumulating bacteria immobilization. J Hazard Mater, 2009, 166: 1377-1382.

[17]	Hu H, Tan W, Xi B. Lignin-phenol monomers govern the pyrolytic conversion of natural biomass from lignocellulose to products. Environ Sci Ecotechnol, 2021, 8: 100131.

[18]	Ippolito JA, Cui L, Kammann C, Wrage-Mönnig N, Estavillo JM, Fuertes-Mendizabal T, Cayuela ML, Sigua G, Novak J, Spokas K, Borchard N. Feedstock choice, pyrolysis temperature and type influence biochar characteristics: a comprehensive meta-data analysis review. Biochar, 2020, 2(4): 421-438.

[19]	Jia L, Yu Y, Guo JR, Qin SN, Wang YL, Shen X, Fan BG, Jin Y (2020) Study of the molecular structure and elemental mercury adsorption mechanism of biomass char. Energy Fuels 34: 12743–12756. https://dx.doi.org/10.1021/acs.energyfuels.0c02626

[20]	Jia P, Wang X, Liu S, Hua Y, Zhou S, Jiang Z. Combined use of biochar and microbial agent can promote lignocellulose degradation and humic acid formation during sewage sludge-reed straw composting. Bioresour Technol, 2023, 370: 128525.

[21]	Khan MA, Sahile AA, Jan R, Asaf S, Hamayun M, Imran M, Adhikari A, Kang SM, Kim KM, Lee IJ. Halotolerant bacteria mitigate the effects of salinity stress on soybean growth by regulating secondary metabolites and molecular responses. BMC Plant Biol, 2021, 21: 176.

[22]	Khan N, Bano A, Rahman MA, Guo J, Kang Z, Babar MA (2019) Comparative physiological and metabolic analysis reveals a complex mechanism involved in drought tolerance in chickpea (Cicer arietinum L.) induced by PGPR and PGRs. Sci Rep 9: 2097. https://doi.org/10.1038/s41598-019-38702-8

[23]	Kopittke PM, Menzies NW, Wang P, McKenna BA, Lombi E. Soil and the intensification of agriculture for global food security. Environ Int, 2019, 132: 105078.

[24]	Krachler R, Krachler R, Valda A, Keppler BK. Natural iron fertilization of the coastal ocean by blackwater rivers. Sci Total Environ, 2019, 656: 952-958.

[25]	Lehmann J, Rillig MC, Thies J, Masiello CA, Hockaday WC, Crowley D. Biochar effects on soil biota – A review. Soil Biol Biochem, 2011, 43: 1812-1836.

[26]	Li J, Yu Y, Guo J, Qin S, Wang Y, Shen X, Fan B, Jin Y. Study of the molecular structure and elemental mercury adsorption mechanism of biomass char. Energy Fuels, 2020, 34: 12743-12756.

[27]	Lin RY, Liu RQ, Wang LJ, Wang YY, Zhu NM, Chen DY. Effects of B-doping on the physicochemical structure and CO₂ adsorption property of the walnut shell biochar. J Anal Appl Pyrol, 2025, 189: 107114.

[28]	Li Q, Jia Z, Fu J, Yang X, Shi X, Chen R. Biochar enhances partial denitrification/anammox by sustaining high rates of nitrate to nitrite reduction. Bioresour Technol, 2022, 349: 126869.

[29]	Li T, He Y, An X, Li C, Wu Z. Elucidating adhesion behaviors and the interfacial interaction mechanism between plant probiotics and modified bentonite carriers. ACS Sustain Chem Eng, 2021, 9: 8125-8135.

[30]	Liu B, Jia P, Zou J, Ren H, Xi M, Jiang Z. Improving soil properties and Sesbania growth through combined organic amendment strategies in a coastal saline-alkali soil. J Environ Manage, 2025, 374: 124041.

[31]	Liu P, Liu H, Semenec L, Yuan D, Yan S, Cain AK, Li M. Length-based separation of Bacillus subtilis bacterial populations by viscoelastic microfluidics. Microsyst Nanoeng, 2022, 8: 7.

[32]	Mohammed NAS, Abu-Zurayk RA, Hamadneh I, Al-Dujaili AH. Phenol adsorption on biochar prepared from the pine fruit shells: Equilibrium, kinetic and thermodynamics studies. J Environ Manage, 2018, 226: 377-385.

[33]	Mukherjee P, Mitra A, Roy M. Halomonas rhizobacteria of avicennia marina of Indian Sundarbans promote rice growth under saline and heavy metal stresses through exopolysaccharide production. Front Microbiol, 2019, 10: 1207.

[34]	Ortiz LR, Torres E, Zalazar D, Zhang H, Rodriguez R, Mazza G. Influence of pyrolysis temperature and bio-waste composition on biochar characteristics. Renew Energ, 2020, 155: 937-847.

[35]	Palansooriya KN, Li J, Dissanayake PD, Suvarna M, Li L, Yuan X, Sarkar B, Tsang DCW, Rinklebe J, Wang X, Ok YS. Prediction of soil heavy metal immobilization by biochar using machine learning. Environ Sci Technol, 2022, 56: 4187-4198.

[36]	Ren L, Hong Z, Liu Z, Xu R. ATR-FTIR investigation of mechanisms of Bacillus subtilis adhesion onto variable- and constant-charge soil colloids. Colloid Surf B, 2018, 162: 288-295.

[37]	Sar T, Stark BC, Akbas MY. Effective ethanol production from whey powder through immobilized E. coli expressing Vitreoscilla hemoglobin. Bioengineered, 2017, 8: 171-181.

[38]	Schommer VA, Nazari MT, Melara F, Braun JCA, Rempel A, Dos Santos LF, Ferrari V, Colla LM, Dettmer A, Piccin JS. Techniques and mechanisms of bacteria immobilization on biochar for further environmental and agricultural applications. Microbiol Res, 2024, 278: 127534.

[39]	Schommer VA, Vanin AP, Nazari MT, Ferrari V, Dettmer A, Colla LM, Piccin JS. Biochar-immobilized Bacillus spp for heavy metals bioremediation: A review on immobilization techniques, bioremediation mechanisms and effects on soil. Sci Total Environ, 2023, 881: 163385.

[40]	Sharma A, Kumar AA, Mohanty B, Khanam S. Synthesis, characterization and thermo-kinetic analysis of sawdust biochar for adsorbent and combustion drives. Bioresour Technol Rep, 2023, 22: 101485.

[41]	Song B, Chen M, Zhao L, Qiu H, Cao X. Physicochemical property and colloidal stability of micron- and nano-particle biochar derived from a variety of feedstock sources. Sci Total Environ, 2019, 661: 685-695.

[42]	Tao S, Wu Z, He X, Ye B, Li C. Characterization of biochar prepared from cotton stalks as efficient inoculum carriers for Bacillus subtilis SL-13. BioRes, 2018, 13: 1773-1786.

[43]	Tomczyk A, Sokołowska Z, Boguta P. Biochar physicochemical properties: pyrolysis temperature and feedstock kind effects. Rev Environ Sci Biotechnol, 2020, 19: 191-215.

[44]	Ton-That L, Huynh TN, Duong BN, Nguyen DK, Nguyen NA, Pham VH, Ho TH, Dinh VP. Kinetic studies of the removal of methylene blue from aqueous solution by biochar derived from jackfruit peel. Environ Monit Assess, 2023, 195: 1266.

[45]	Tounsadi H, Khalidi A, Farnane M, Machrouhi A, Elhalil A, Barka N. Adsorptive removal of heavy metals from aqueous solution using chemically activated Diplotaxis Harra biomass. Surf Interfaces, 2016, 4: 84-94.

[46]	Uroić Štefanko A, Leszczynska D. Impact of biomass source and pyrolysis parameters on physicochemical properties of biochar manufactured for innovative applications. Front Energy Res, 2020, 8: 138.

[47]	Vu B, Chen M, Crawford RJ, Ivanova EP. Bacterial extracellular polysaccharides involved in biofilm formation. Molecules, 2009, 14: 2535-2554.

[48]	Wang Q, Wang J, Wang X, Kumar N, Pan Z, Peiffer S, Wang Z. Transformations of ferrihydrite-extracellular polymeric substance coprecipitates driven by dissolved sulfide: Interrelated effects of carbon and sulfur loadings. Environ Sci Technol, 2023, 57: 4342-4353.

[49]	Wang X, Jia P, Hua Y, Xu H, Xi M, Jiang Z. Natural organic matter changed the capacity and mechanism of Pb and Cd adsorptions on iron oxide modified biochars. Sep Purif Technol, 2023, 314: 123625.

[50]	Wang X, Wang W, Wang W, Dong L, Zhai T, Gao Z, Wang K, Wang W, Wang S, Kong F. Enhanced effect and mechanism of nano Fe-Ca bimetallic oxide modified substrate on Cu(II) and Ni(II) removal in constructed wetland. Hazard Mater, 2023, 456: 131689.

[51]	Wang Z, Chen B, Cao Y, Xing S, Zhang B, Wang S, Tian H. Insights into the interfacial dynamics and interaction mechanisms between phosphate-solubilizing bacteria and straw-derived biochar. Biochar, 2025, 7: 55.

[52]	Xie Y, He N, Wei M, Wen T, Wang X, Liu H, Zhong S, Xu H. Cadmium biosorption and mechanism investigation using a novel Bacillus subtilis KC6 isolated from pyrite mine. J Clean Prod, 2021, 312: 127749.

[53]	Xiong B, Zhang Y, Hou Y, Arp HPH, Reid BJ, Cai C. Enhanced biodegradation of PAHs in historically contaminated soil by M. gilvum inoculated biochar. Chemosphere, 2017, 182: 316-324.

[54]	Yin X, Xi M, Li Y, Kong F, Jiang Z. Improvements in physicochemical and nutrient properties of sewage sludge biochar by the co-pyrolysis with organic additives. Sci Total Environ, 2021, 779: 146565.

[55]	Yuan Z, Liu Q, Pang Z, Fallah N, Liu Y, Hu C, Lin W. Sugarcane rhizosphere bacteria community migration correlates with growth stages and soil nutrient. Int J Mol Sci, 2022, 23: 10303.

[56]	Yu C, Wang W, Li C, Wang J, Chu G, Wang Z, Si Y. Mechanisms of contaminant transformation mediated by environmental carbonaceous materials through extracellular electron transfer. Environ Chem, 2024, 43: 2944-2955. in Chinese with English abstract).

[57]	Zhang M, Liu Y, Wei Q, Gu X, Liu L, Gou J. Biochar application ameliorated the nutrient content and fungal community structure in different yellow soil depths in the karst area of Southwest China. Front Plant Sci, 2022, 13: 1020832.

[58]	Zhang M, Zhu Y, Lyu Y, Luo Y, Duan T, Li W, Li P. Impact of deashing treatment on biochar physicochemical properties and sorption mechanisms of naphthalene and 1-naphthol. Environ Technol Inno, 2021, 24: 101960.

[59]	Zhang S, Wang J. Removal of chlortetracycline from water by Bacillus cereus immobilized on Chinese medicine residues biochar. Environ Technol Inno, 2021, 24: 101930.

[60]	Zhang Y, Liu S, Niu L, Su A, Li M, Wang Y, Xu Y. Sustained and efficient remediation of biochar immobilized with Sphingobium abikonense on phenanthrene-copper co-contaminated soil and microbial preferences of the bacteria colonized in biochar. Biochar, 2023, 5: 43.

[61]	Zhang Y, Qu M, Li J, Ren L, Wang F, Wang J, Yang F, Cheng F. Relationship of CO₂ adsorption performance and physicochemical property of biochar prepared by different types of biomass waste. J Environ Chem Eng, 2024, 12: 114571.

[62]	Zhu P, Zhang H, Pivarčiová E, Sfarra S, Maldague X. Characterization of water content and inspection of delamination in spruce, oak and meranti woods after pyrolysis processing using a new terahertz time-domain spectroscopy method. NDT E Int, 2023, 139: 102938.

[63]	Zhu Y, Wang J, Dai Y, Jiang Z. Effects of feedstock type and pyrolysis temperature on chemical and molecular characteristics of biochar-dissolved organic matter. J Anal Appl Pyrol, 2026, 194: 107602.