Synergistic biochar‑Bacillus consortium enhances phosphorus availability, root architecture, and inflorescence development in greenhouse cherry tomato

Sainan Liu; Yongjia Shi; Aijia Zhang; Yuwei Huang; Dianyun Cao; Yu Lan

doi:10.1007/s42773-026-00586-z

Biochar ›› 2026, Vol. 8 ›› Issue (1) :66 DOI: 10.1007/s42773-026-00586-z

Original Research

research-article

Synergistic biochar‑Bacillus consortium enhances phosphorus availability, root architecture, and inflorescence development in greenhouse cherry tomato

Sainan Liu ¹^,²
, Yongjia Shi ¹^,²
, Aijia Zhang ¹^,²
, Yuwei Huang ¹^,²
, Dianyun Cao ¹^,²^,^a
, Yu Lan ¹^,²^,^b

Author information +

History +

PDF

Abstract

Mobilizing legacy phosphorus (P) in greenhouse soils offers a strategy to alleviate P limitation and enhance crop productivity. This study applied biochar-Bacillus consortium as a bio-organic soil amendment. By altering the soil bacterial community, it improved P availability and plant P uptake, promoted root and inflorescence development, and ultimately increased cherry tomato yield. Specifically, soil application of biochar-Bacillus consortium (BM) significantly enhanced soil available phosphorus by 10.16%, microbial biomass phosphorus by 174.76%, and alkaline phosphatase activity by 68.52% in the rhizosphere relative to the control (CK). This enhancement in P bioavailability was significantly correlated with shifts in the soil bacterial community. Compared to treatments with biochar alone (B) or Bacillus liquid culture (M) alone, the enhanced P availability promoted plant P uptake and improved root architecture, as reflected by significant increases in root length, surface area, volume, and tip number. In addition, the improvement of inflorescence development was reflected in a substantial increase in the proportion of effective fruit branches, thereby contributing to a significant yield enhancement of 23.53%. Collectively, this work demonstrates that amending soils with a biochar-Bacillus consortium effectively enhances P bioavailability and cherry tomato productivity, thus emphasizing its potential for sustainable intensification in controlled agricultural systems.

Graphical Abstract

Keywords

Microbial phosphorus mobilization / Biochar‑microbe interaction / Inflorescence development / Root morphology / Protected cultivation

Cite this article

Download citation ▾

Sainan Liu, Yongjia Shi, Aijia Zhang, Yuwei Huang, Dianyun Cao, Yu Lan. Synergistic biochar‑Bacillus consortium enhances phosphorus availability, root architecture, and inflorescence development in greenhouse cherry tomato. Biochar, 2026, 8(1): 66 DOI:10.1007/s42773-026-00586-z

登录浏览全文

4963

注册一个新账户忘记密码

References

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

[1]	Ajeng AA, Abdullah R, Ling TC. Biochar-Bacillus consortium for a sustainable agriculture: physicochemical and soil stability analyses. Biochar. 2023, 5(1): 17.

[2]	Asaf S, Numan M, Khan AL, Al-Harrasi A. Sphingomonas: from diversity and genomics to functional role in environmental sustainability and plant growth promotion. J Hazard Mater. 2020, 389122086

[3]	Azeem M, Hassan TU, Tahir MI, Ali A, Zhang Z. Tea leaves biochar as a carrier of Bacillus cereus improves the soil function and crop productivity. Appl Soil Ecol. 2021, 157. 103732

[4]	Bao SD. Method for soil agricultural chemistry. 20003Beijing, China Agriculture Press

[5]	Batista E, Juliana S, Matos T, Fornari MR, Ferreira TM, Bruno S, De FRA, Mangrich AS. Effect of surface and porosity of biochar on water holding capacity aiming indirectly at preservation of the Amazon biome. Entific Reports. 2018, 8110677

[6]	Beltran-Medina I, Romero-Perdomo F, Molano-Chavez L, Gutiérrez AY, Silva AMM, Estrada-Bonilla G. Inoculation of phosphate-solubilizing bacteria improves soil phosphorus mobilization and maize productivity. Nutr Cycl Agroecosyst. 2023, 126: 21-34.

[7]	Bolan SD, 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.

[8]	Canal SB, Bozkurt MA, Ucar CP. The effects of endophytic bacteria along with humic acid and biochar on phytoremediation of rapeseed (Brassica napus L.). J Crop Health. 2024, 76: 1615-1625.

[9]	Chang L, Ju TH, Liang K, Li YF. Biochar-influenced solubilization and mineralization mechanisms of phosphorus in saline-sodic soils. Soil Biol Biochem. 2025, 209. 109890

[10]	Chen X, Jiang N, Condron LM, Dunfield KE, Chen Z, Wang J, Chen L. Impact of long-term phosphorus fertilizer inputs on bacterial phoD gene community in a maize field, Northeast China. Sci Total Environ. 2019, 669: 1011-1018.

[11]	Cho H, Choi I, Bouain N, Nawaz A, Zheng L, Shahzad Z, Brandizzi F, Rhee SY, Rouached H. Phosphorus availability controls flowering time through subcellular reprogramming of bGLU25 and GRP7 in Arabidopsis. Dev Cell. 2025, 10: 005

[12]	Deng L, Tu P, Ahmed N, Zhang G, Cen Y, Huang B, Deng L, Yuan H. Biochar-based phosphate fertilizer improve phosphorus bioavailability, microbial functioning, and citrus seedling growth. Sci Hortic. 2024.

[13]	Dixon MM, Afkairin A, Davis JG, Chitwood-Brown J, Buchanan CM, Ippolito JA, Manter DK, Vivanco JM. Tomato domestication rather than subsequent breeding events reduces microbial associations related to phosphorus recovery. Sci Rep. 2024, 381-9

[14]	Dziewit K, Amakorová P, Novák O, Szal B, Podgórska A. Systemic strategies for cytokinin biosynthesis and catabolism in Arabidopsis roots and leaves under prolonged ammonium nutrition. Plant Physiol Biochem. 2024.

[15]	Edgar RC, Haas BJ, Clemente JC, Quince C, Knight R. UCHIME improves sensitivity and speed of chimera detection. Bioinformatics. 2011, 27: 2194-2200.

[16]	Gao L 2019. Current situation of cultivation techniques of facility vegetables and problems in production also its sustainable development strategies. IOP conference series. Earth and environmental science 252 5 52069.

[17]	Gurdeep K, Reddy MS. Effects of phosphate-solubilizing bacteria, rock phosphate and chemical fertilizers on maize-wheat cropping cycle and economics. Pedosphere. 2015, 253428-437.

[18]

Harish MN, Choudhary AK, Dass A, Singh VK, Rajanna GA, Bana RS, Paramesh V, Varatharajan T, Bhupenchandra I, Sadhukhan R, Kumar A, Sachin KS, Teli KG, Singh SRK, Sannagoudar MS, Muniyappa L, Prasad HPN. Double zero-tilled bed-planting and optimized P-fertilization in maize-wheat rotation: An empirical investigation on root architecture, carbon-phosphorus dynamics, and soil carbon pools. J Environ Manage. 2025, 392. 126668

[19]	Hou Q, Wang W, Yang Y, Hu J, Bian C, Jin L, Li G, Xiong X. Rhizosphere microbial diversity and community dynamics during potato cultivation. Eur J Soil Biol. 2020, 98. 103176

[20]	Hu W, Zhang Y, Xiangmin R, Fei J, Peng J, Luo G. Coupling amendment of biochar and organic fertilizers increases maize yield and phosphorus uptake by regulating soil phosphatase activity and phosphorus-acquiring microbiota. Agric Ecosyst Environ. 2023.

[21]	Hui H, Qian TT, Liu WJ, Jiang H, Yu HQ. Biological and chemical phosphorus solubilization from pyrolytical biochar in aqueous solution. Chemosphere. 2014, 113: 175-181.

[22]	Jiang H, Yuan C, Wu Q, Heděnec P, Zhao Z, Yue K, Ni X, Wu F, Peng Y. Effects of transforming multiple ecosystem types to tree plantations on soil microbial biomass carbon, nitrogen, phosphorus and their ratios in China. Appl Soil Ecol. 2024, 193. 105145

[23]	Jin X, Rahman MK, Ma C, Zheng X, Wu F, Zhou X. Silicon modification improves biochar’s ability to mitigate cadmium toxicity in tomato by enhancing root colonization of plant-beneficial bacteria. Ecotoxicol Environ Saf. 2023, 249. 114407

[24]	Keru Y, Zhaokun X, Xianzhi F, Jiawei M, Yongjun W, Dan L, Zhengqian Y. Effects of biochar inoculation with Bacillus megaterium on rice soil phosphorus fraction transformation and bacterial community dynamics. Rice Sci. 2024, 31: 361-365.

[25]	Leite ADA, Cardoso AAS, Leite RA, Barrera AMV, Queiroz DDL, Viana TC, Oliveira-Longatti SM, Silva CA, Moreira FMS, Lehmann J, Melo LCA. Phosphate-solubilizing bacteria increase maize phosphorus uptake from magnesium-enriched poultry manure biochar. Biol Fertil Soils. 2024, 60: 421-436.

[26]	Li J, Xu Y, Liu H. Variations of soil quality from continuously planting greenhouses in North China. Int J Agric Biol Eng. 2019, 12(1): 139-145

[27]	Li H, Ren R, Zhang H, Zhang G, He Q, Han Z, Meng S, Zhang Y, Zhang X. Factors regulating interaction among inorganic nitrogen and phosphorus species, plant uptake, and relevant cycling genes in a weakly alkaline soil treated with biochar and inorganic fertilizer. Sci Total Environ. 2023.

[28]	Li M, He X, Zhang P, Wang R, Wang J, Zhang X, Yin H. Close linkage between available and microbial biomass phosphorus in the rhizosphere of alpine coniferous forests along an altitudinal gradient. Rhizosphere. 2024, 30. 100904

[29]	Lidbury IDEA, Scanlan DJ, Murphy ARJ, Christie-Oleza JA, Aguilo-Ferretjans MM, Hitchcock A, Daniell TJ. A widely distributed phosphate-insensitive phosphatase presents a route for rapid organophosphorus remineralization in the biosphere. PNAS. 2022, 119(5. e2118122119

[30]	Liu SN, Du HT, Huang YW, Lan Y, Lu JK, Wang SY, Meng J. Effects of biochar application and phosphorus-solubilizing bacteria on rice seedling growth and rhizosphere phosphorus availability under phosphorus stress. Chin J Ecol. 2022, 418): 1560-1569

[31]

Minchev Z, Ramírez-Serrano B, Dejana L, Lee Díaz AS, Zitlalpopoca-Hernandez G, Orine D, Saha H, Papantoniou D, García JM, González-Céspedes A, Garbeva P, Dam NM, Soler R, Giron D, Martínez-Medina A, Biere A, Hauser T, Meyling NV, Rasmann S, Pozo MJ. Beneficial soil fungi enhance tomato crop productivity and resistance to the leaf-mining pest Tuta absoluta in agronomic conditions. Agron for Sustain Dev. 2024, 44(6): 55.

[32]	Orozco-Mosqueda MC, Flores A, Rojas-Sánchez B, Urtis-Flores CA, Morales-Cedeño LR, Valencia-Marin MF, Chávez-Avila S, Rojas-Solis D, Santoyo G. Plant growth-promoting bacteria as bioinoculants: attributes and challenges for sustainable crop improvement. Agron. 2021, 11: 1-15

[33]	Parasar BJ, Agarwala N. Unravelling the role of biochar-microbe-soil tripartite interaction in regulating soil carbon and nitrogen budget: a panacea to soil sustainability. Biochar. 2025, 7: 37.

[34]	Quadros PDD, Zhalnina K, Davis-Richardson AG, Drew JC, Menezes FB, Camargo FADO, Triplett EW. Coal mining practices reduce the microbial biomass, richness and diversity of soil. Appl Soil Ecol. 2016, 98195-203.

[35]	Raven JA, Lambers H, Smith SE, Westoby M. Costs of acquiring phosphorus by vascular land plants: patterns and implications for plant coexistence. New Phytol. 2018, 21741420-1427.

[36]

Silva PC, Ferreira AFA, Araújo ES, Neto JVB, Costa AR, Fernandes LS, Martins AAS, Cândido RS, Jardim AMRF, Pandorfi H, Silva MV. Cherry tomato crop management under irrigation levels: morphometric characteristics and their relationship with fruit production and quality. Gesunde Pflanz. 2022, 75: 1277-1288.

[37]	Soyk S, Lemmon ZH, Oved M, Fisher J, Liberatore KL, Park SJ, Goren A, Jiang K, Ramos A, Knaap E, Eck JV, Zamir D, Eshed Y, Lippman ZB. Bypassing negative epistasis on yield in tomato imposed by a domestication gene. Cell. 2017, 169: 1142-1155.

[38]	Spohn M, Kuzyakov Y. Distribution of microbial- and root-derived phosphatase activities in the rhizosphere depending on P availability and C allocation – coupling soil zymography with ¹⁴C imaging. Soil Biol Biochem. 2013, 67: 106-113.

[39]	Sun S, Liu Z, Wang X, Song J, Fang S, Kong J, Li R, Wang H, Cui X. Genetic control of thermomorphogenesis in tomato inflorescences. Nat Commun. 2024, 1511472.

[40]	Tu C, Wei J, Guan F, Liu Y, Sun Y, Luo Y. Biochar and bacteria inoculated biochar enhanced Cd and Cu immobilization and enzymatic activity in a polluted soil. Environ Int. 2020.

[41]	Tumbure A, Schmalenberger A. Struvites with comparable nitrogen and phosphorus composition have similar agronomic response but shape cherry tomato rhizosphere bacterial community structure differently. Appl Soil Ecol. 2024.

[42]	Wan W, Yang Y, Grossart HP, Xiong X, He D. Soil alkaline phosphatase-encoding bacteria relate closely to microbial biomass phosphorus in changing environments. Environ Res. 2025, 282. 122078

[43]	Wang J, Wu Y, Zhou J, Bing H, Sun H, He Q, Li J, Wilcke W. Soil microbes become a major pool of biological phosphorus during the early stage of soil development with little evidence of competition for phosphorus with plants. Plant Soil. 2019, 446: 259-274.

[44]	Wang L, Chen X, Tang Z. Arbuscular mycorrhizal symbioses improved biomass allocation and reproductive investment of cherry tomato after root-knot nematodes infection. Plant Soil. 2022, 482: 513-527.

[45]	Wang Y, Zou L, Lou C, Geng X, Zhang S, Chen X, Zhang Y, Huang D, Liang A. No-tillage with straw retention influenced maize root growth morphology by changing soil physical properties and aggregate structure in Northeast China: a ten-year field experiment. Geoderma Reg. 2024.

[46]	Wu WJ, Chen YJ, Li GY 2021. Mechanism of rice straw biochar on tomato yield and quality in cadmium polluted farmland. Journal of Agricultural Environmental Sciences 1–17.

[47]	Yang L, Shen P, Liang H, Wu Q. Biochar relieves the toxic effects of microplastics on the root-rhizosphere soil system by altering root expression profiles and microbial diversity and functions. Ecotoxicol Environ Saf. 2024.

[48]	Zhai Y, Hu X, Zhao X, Xu M, Li W, Guo S. Phosphorous and arbuscular mycorrhizal fungi improve snapdragon flowering through regulating root architecture and phosphorus nutrition. J Soil Sci Plant Nutr. 2023, 23: 4279-4289.

[49]	Zhang X, Feng Q, Adamowski JF, Biswas A, Cao J, Liu W, Qin Y, Zhu M. Conversion of grassland to abandoned land and afforested land alters soil bacterial and fungal communities on the Loess Plateau. Appl Soil Ecol. 2023, 183. 104758