Micro-nanoscale bone char alters Cd accumulation and rhizosphere functional genes to enhance rice yield and quality

Anqi Liang , Yi Hao , Zeyu Cai , Weitao Wu , Xinxin Xu , Weili Jia , Yini Cao , Lanfang Han , Luca Pagano , Marta Marmiroli , Elena Maestri , Nelson Marmiroli , Jason C. White , Chuanxin Ma , Baoshan Xing

Biochar ›› 2026, Vol. 8 ›› Issue (1) : 45

PDF
Biochar ›› 2026, Vol. 8 ›› Issue (1) :45 DOI: 10.1007/s42773-025-00548-x
Original Research
research-article

Micro-nanoscale bone char alters Cd accumulation and rhizosphere functional genes to enhance rice yield and quality

Author information +
History +
PDF

Abstract

This work investigates the impact of micro-nanoscale bone char (MNBC) soil amendment on Cd-stressed rice over a full life cycle, aiming to develop a sustainable remediation strategy integrating yield improvement and soil health. MNBC was sourced from widely available pork bones in the waste stream, and was generated by pyrolysis at 400 °C and 600 °C, followed by ball-milling to reduce the particle size to micro-nanoscale. A 140-day full-life-cycle experiments was conducted under greenhouse conditions, and soil samples across all the treatments were collected at different growth periods for metagenomic analysis. At harvest, rice grains were sampled for metabolomic analysis. Results showed that treatment with 600 °C MNBC significantly increased grain yield by 49.72%, while 400 °C MNBC increased the effective tiller number by 23.08%, compared to Cd treatment. Both types of MNBCs reduced Cd accumulation in rice tissues, with reductions of 65.0–68.7% in polished rice relative to the Cd treatment. Metabolomic analysis highlights MNBC modulated the nutritional value of the grains, effectively slowing down the biochemical processes of carbohydrates and branched-chain amino acids into simple sugars or polyols in rice grains. In the aerobic phase of soil, the acid-soluble Cd with MNBC treatments decreased by 31.56–35.51% as compared to the Cd treatment. Metagenomic analyses show that MNBC had a significant impact on the microbial communities involved in soil carbon, nitrogen, and phosphorus cycling, such as Actinomycetota, Cyanobacteria, and Gemmatimonadota, as well as on related genes; particularly enhancing the complexity of the phosphorus gene network. Overall, these findings demonstrate the significant potential of MNBC-enabled agriculture practices as a sustainable crop strategy.

Keywords

Micro-nanoscale bone char / Cadmium / Phosphorus / Grain yield / Metabolites / Soil metagenomics

Highlight

Micro/nano-scale bone biochar (MNBC) significantly increased rice yield and tiller number.

MNBC effectively fixed soil Cd, reduced the Cd bioavailability, and significantly reduced Cd accumulation in rice.

MNBC positively affected the composition of soil organic matter and microbial communities at different rice growth phases.

Soil P-cycling genes were highly sensitive to long-term MNBC application.

Cite this article

Download citation ▾
Anqi Liang, Yi Hao, Zeyu Cai, Weitao Wu, Xinxin Xu, Weili Jia, Yini Cao, Lanfang Han, Luca Pagano, Marta Marmiroli, Elena Maestri, Nelson Marmiroli, Jason C. White, Chuanxin Ma, Baoshan Xing. Micro-nanoscale bone char alters Cd accumulation and rhizosphere functional genes to enhance rice yield and quality. Biochar, 2026, 8(1): 45 DOI:10.1007/s42773-025-00548-x

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]

Alori ET, Glick BR, Babalola OO. Microbial phosphorus solubilization and its potential for use in sustainable agriculture. Front Microbiol, 2017, 8: 971

[2]

Arao T, Kawasaki A, Baba K, Mori S, Matsumoto S. Effects of water management on cadmium and arsenic accumulation and dimethylarsinic acid concentrations in Japanese rice. Environ Sci Technol, 2009, 43(24): 9361-9367

[3]

Azeem M, Ali A, Jeyasundar PGSA, Li YM, Abdelrahman H, Latif A, Li RH, Basta N, Li G, Shaheen SM, Rinklebe J, Zhang ZQ. Bone-derived biochar improved soil quality and reduced Cd and Zn phytoavailability in a multi-metal contaminated mining soil. Environ Pollut, 2021, 277 116800
[4]

Azeem M, Ali A, Jeyasundar PGSA, Bashir S, Hussain Q, Wahid F, Ali EF, Abdelrahman H, Li RH, Antoniadis V, Rinklebe J, Shaheen SM, Li G, Zhang Z. Effects of sheep bone biochar on soil quality, maize growth, and fractionation and phytoavailability of Cd and Zn in a mining-contaminated soil. Chemosphere, 2021, 282 131016
[5]

Azeem M, Shaheen SM, Ali A, Jeyasundar PGSA, Latif A, Abdelrahman H, Li RH, Almazroui M, Niazi NK, Sarmah AK, Li G, Rinklebe J, Zhu YG, Zhang ZQ. Removal of potentially toxic elements from contaminated soil and water using bone char compared to plant- and bone-derived biochars: a review. J Hazard Mater, 2022, 427 128131
[6]

Azeem M, Jeyasundar PGSA, Ali A, Riaz L, Khan KS, Hussain Q, Kareem HA, Abbas F, Latif A, Majrashi A, Ali EF, Li RH, Shaheen SM, Li G, Zhang ZQ, Zhu YG. Cow bone-derived biochar enhances microbial biomass and alters bacterial community composition and diversity in a smelter contaminated soil. Environ Res, 2023, 216 114278
[7]

Balindong JL, Ward RM, Liu L, Rose TJ, Pallas LA, Ovenden BW, Snell PJ, Waters DLE. Rice grain protein composition influences instrumental measures of rice cooking and eating quality. J Cereal Sci, 2018, 79: 35-42

[8]

Bünemann EK. Assessment of gross and net mineralization rates of soil organic phosphorus—a review. Soil Biol Biochem, 2015, 89: 82-98

[9]

Cai MF, Li KM, Xie DP. The status and protection strategy of farmland soils polluted by heavy metals. Environ Sci Technol, 2014, 37(120): 223-230

[10]

Chen W, Gong L, Guo ZL, Wang WS, Zhang HY, Liu XQ, Yu SB, Xiong LZ, Luo J. A novel integrated method for large-scale detection, identification, and quantification of widely targeted metabolites: application in the study of rice metabolomics. Mol Plant, 2013, 6(6): 1769-1780

[11]

Chen XP, Cui ZL, Fan MS, Vitousek P, Zhao M, Ma WQ, Wang ZL, Zhang WJ, Yan XY, Yang JC, Deng XP, Gao Q, Zhang Q, Guo SW, Ren J, Li SQ, Ye YL, Wang ZH, Huang JL, Tang QY, Sun YX, Peng XL, Zhang JW, He MR, Zhu YJ, Xue JQ, Wang GL, Wu L, An N, Wu LQ, Ma L, Zhang WF, Zhang FS. Producing more grain with lower environmental costs. Nature, 2014, 514(7523): 486-489

[12]

Chen HY, Teng YG, Lu SJ, Wang YY, Wang JS. Contamination features and health risk of soil heavy metals in China. Sci Total Environ, 2015, 512: 143-153

[13]

Chen WF, Meng J, Han XR, Lan Y, Zhang WM. Past, present, and future of biochar. Biochar, 2019, 1(1): 75-87

[14]

Chen Y, Chen FF, Xie MD, Jiang QQ, Chen WQ, Ao TQ. The impact of stabilizing amendments on the microbial community and metabolism in cadmium-contaminated paddy soils. Chem Eng J, 2020, 395 125132
[15]

Chen X, Yang SH, Ding J, Jiang ZW, Sun X. Effects of biochar addition on rice growth and yield under water-saving irrigation. Water, 2021, 13(2): 209

[16]

Chen MY, Teng WK, Zhao L, Hu CX, Zhou YK, Han BP, Song LR, Shu WS. Comparative genomics reveals insights into cyanobacterial evolution and habitat adaptation. ISME J, 2021, 151211-227

[17]

Cordell D, Drangert JO, White S. The story of phosphorus: global food security and food for thought. Glob Environ Change, 2009, 19(2): 292-305

[18]

Daskalakis KD, Helz GR. Solubility of cadmium sulfide (greenockite) in sulfidic waters at 25.degree.C. Environ Sci Technol, 1992, 26(12): 2462-2468

[19]

Dhillon J, Torres G, Driver E, Figueiredo B, Raun WR. World phosphorus use efficiency in cereal crops. Agron J, 2017, 109(4): 1670-1677

[20]

Ghosh S, Das AP. Metagenomic insights into the microbial diversity in manganese-contaminated mine tailings and their role in biogeochemical cycling of manganese. Sci Rep, 2018, 8: 8257

[21]

Gul S, Whalen JK, Thomas BW, Sachdeva V, Deng HY. Physico-chemical properties and microbial responses in biochar-amended soils: mechanisms and future directions. Agric Ecosyst Environ, 2015, 206: 46-59

[22]

Hamilton JG, Grosskleg J, Higer D, Dhillon GS, Bradshaw K, Carlson T, Siciliano SD, Peak D. In situ transformations of bonechar and tri-poly phosphate amendments in phosphorus-limited subsurface soils. Appl Geochem, 2019, 109 104398
[23]

Han Y, Choi B, Chen XW. Adsorption and desorption of phosphorus in biochar-amended black soil as affected by freeze-thaw cycles in Northeast China. Sustainability, 2018, 10(5): 1574

[24]

Honma T, Ohba H, Kaneko-Kadokura A, Makino T, Nakamura K, Katou H. Optimal soil Eh, pH, and water management for simultaneously minimizing arsenic and cadmium concentrations in rice grains. Environ Sci Technol, 2016, 5084178-4185

[25]

Hu PJ, Ouyang YN, Wu LH, Shen LB, Luo YM, Christie P. Effects of water management on arsenic and cadmium speciation and accumulation in an upland rice cultivar. J Environ Sci, 2015, 27: 225-231

[26]

Huang BY, Zhao FJ, Wang P. Implications in simultaneously controlling grain Cd and As accumulation using a segmented water management strategy. Environ Pollut, 2022, 293 118497
[27]

Illakwahhi DT, Vegi MR, Srivastava BBL. Phosphorus’ future insecurity, the horror of depletion, and sustainability measures. Int J Environ Sci Technol, 2024, 21(14): 9265-9280

[28]

Jiao Y, Li YT, Dou WY, Zhang WL, Liu H. Biochar alleviates the crop failure of rice production induced by low-nitrogen cultivation mode by regulating the soil microbes taxa composition. Arch Microbiol, 2023, 205(12): 361

[29]

Lee JI, Kim DW, Jang GJ, Song S, Park KJ, Lim JH, Kim BM, Lee HJ, Chen F, Ryu YB, Kim HJ. Effects of different storage conditions on the metabolite and microbial profiles of white rice (Oryza sativa L.). Food Sci Biotechnol, 2019, 283623-631

[30]

Li HY, Ye XX, Geng ZG, Zhou HJ, Guo XS, Zhang YX, Zhao HJ, Wang GH. The influence of biochar type on long-term stabilization for Cd and Cu in contaminated paddy soils. J Hazard Mater, 2016, 304: 40-48

[31]

Liang JL, Liu J, Jia P, Yang TT, Zeng QW, Zhang SC, Liao B, Shu WS, Li JT. Novel phosphate-solubilizing bacteria enhance soil phosphorus cycling following ecological restoration of land degraded by mining. ISME J, 2020, 14(6): 1600-1613

[32]

Liang AQ, Ma CX, Xiao J, Hao Y, Li H, Guo YZ, Cao YN, Jia WL, Han LF, Chen GC, Tan Q, White JC, Xing BS. Micro/nanoscale bone char alleviates cadmium toxicity and boosts rice growth via positively altering the rhizosphere and endophytic microbial community. J Hazard Mater, 2023, 454 131491
[33]

Liu S, Zhu X, Zhao Y, Wang B, Han Y, Yang B, Lu Z, Jia H. Cotton stalk biochar retarding stress of cadmium on growth of rice. J Agric Sci Technol, 2020, 22(4): 139-146

[34]

Liu L, Gao ZY, Yang Y, Gao Y, Mahmood M, Jiao HJ, Wang ZH, Liu JS. Long-term high-P fertilizer input shifts soil P cycle genes and microorganism communities in dryland wheat production systems. Agric Ecosyst Environ, 2023, 342 108226
[35]

Majee M, Maitra S, Dastidar KG, Pattnaik S, Chatterjee A, Hait NC, Das KP, Majumder AL. A novel salt-tolerant L-myo-inositol-1-phosphate synthase from Porteresia coarctata (Roxb.) Tateoka, a halophytic wild rice: molecular cloning, bacterial overexpression, characterization, and functional introgression into tobacco-conferring salt tolerance phenotype. J Biol Chem, 2004, 279(27): 28539-28552

[36]

McCloskey D, Xu SB, Sandberg TE, Brunk E, Hefner Y, Szubin R, Feist AM, Palsson BO. Adaptation to the coupling of glycolysis to toxic methylglyoxal production in tpiA deletion strains of Escherichia coli requires synchronized and counterintuitive genetic changes. Metab Eng, 2018, 48: 82-93

[37]

Mei HY, Huang WF, Wang Y, Xu T, Zhao LW, Zhang DY, Luo YM, Pan XL. Bone char as a cost-effective material for stabilizing multiple heavy metals in soil and promoting crop growth. Sci Total Environ, 2022, 840 156163
[38]

Muthayya S, Sugimoto JD, Montgomery S, Maberly GF. An overview of global rice production, supply, trade, and consumption. Ann N Y Acad Sci, 2014, 1324(1): 7-14

[39]

Nawaz T, Saud S, Gu LP, Khan I, Fahad S, Zhou RB. Cyanobacteria: harnessing the power of microorganisms for plant growth promotion, stress alleviation, and phytoremediation in the era of sustainable agriculture. Plant Stress, 2024, 11 100399
[40]

Normile D. Reinventing rice to feed the world. Science, 2008, 321(5887): 330-333

[41]

Rai PK, Lee SS, Zhang M, Tsang YF, Kim KH. Heavy metals in food crops: health risks, fate, mechanisms, and management. Environ Int, 2019, 125: 365-385

[42]

Ramanayaka S, Vithanage M, Alessi DS, Liu WJ, Jayasundera ACA, Ok YS. Nanobiochar: production, properties, and multifunctional applications. Environ Sci Nano, 2020, 7(11): 3279-3302

[43]

Rawat P, Das S, Shankhdhar D, Shankhdhar SC. Phosphate-solubilizing microorganisms: mechanism and their role in phosphate solubilization and uptake. J Soil Sci Plant Nutr, 2021, 21(1): 49-68

[44]

Ren DY, Ding CQ, Qian Q. Molecular bases of rice grain size and quality for optimized productivity. Sci Bull, 2023, 68(3): 314-350

[45]

Sebastian A, Prasad MNV. Photosynthetic light reactions in Oryza sativa L. under Cd stress: influence of iron, calcium, and zinc supplements. EuroBiotech J, 2019, 3(4): 175-181

[46]

Sen S, Chakraborty R, Kalita P. Rice-not just a staple food: a comprehensive review on its phytochemicals and therapeutic potential. Trends Food Sci Technol, 2020, 97: 265-285

[47]

Shan SP, Guo ZH, Lei P, Wang YS, Li YL, Cheng W, Zhang M, Wu SD, Yi HW. Simultaneous mitigation of tissue cadmium and lead accumulation in rice via sulfate-reducing bacterium. Ecotoxicol Environ Saf, 2019, 169: 292-300

[48]

Sharif MK, Butt MS, Anjum FM, Khan SH. Rice bran: a novel functional ingredient. Crit Rev Food Sci Nutr, 2014, 54(6): 807-816

[49]

Siebers N, Leinweber P. Bone char: a clean and renewable phosphorus fertilizer with cadmium immobilization capability. J Environ Qual, 2013, 42(2): 405-411

[50]

Song WE, Chen SB, Liu JF, Chen L, Song NN, Li N, Liu B. Variation of Cd concentration in various rice cultivars and derivation of cadmium toxicity thresholds for paddy soil by species-sensitivity distribution. J Integr Agric, 2015, 14(9): 1845-1854

[51]

Sui L, Tang CY, Cheng K, Yang F. Biochar addition regulates soil phosphorus fractions and improves release of available phosphorus under freezing-thawing cycles. Sci Total Environ, 2022, 848 157748
[52]

Tang X, Li Q, Wu M, Lin L, Scholz M. Review of remediation practices regarding cadmium-enriched farmland soil with particular reference to China. J Environ Manage, 2016, 181: 646-662

[53]

Tong C, Gao HY, Luo SJ, Liu L, Bao JS. Impact of postharvest operations on rice grain quality: a review. Compr Rev Food Sci Food Saf, 2019, 18(3): 626-640

[54]

Usero J, Gamero M, Morillo J, Gracia I. Comparative study of three sequential extraction procedures for metals in marine sediments. Environ Int, 1998, 24(4): 487-496

[55]

Wang P, Chen HP, Kopittke PM, Zhao FJ. Cadmium contamination in agricultural soils of China and the impact on food safety. Environ Pollut, 2019, 249: 1038-1048

[56]

Warren GP, Robinson JS, Someus E. Dissolution of phosphorus from animal bone char in 12 soils. Nutr Cycl Agroecosyst, 2009, 84(2): 167-178

[57]

Wu WX, Yang M, Feng QB, McGrouther K, Wang HL, Lu HH, Chen YX. Chemical characterization of rice straw-derived biochar for soil amendment. Biomass Bioenergy, 2012, 47: 268-276

[58]

Xiao J, Hu R, Chen GC. Micro-nano-engineered nitrogenous bone biochar developed with a ball-milling technique for high-efficiency removal of aquatic Cd(II), Cu(II) and Pb(II). J Hazard Mater, 2020, 387 121980
[59]

Xiao J, Li X, Cao Y, Chen G. Does micro/nano biochar always good to phytoremediation? A case study from multiple metals contaminated acidic soil using Salix jiangsuensis ‘172’. Carbon Res, 2023, 2(1): 21

[60]

Xu WJ, Xie XC, Li Q, Yang X, Ren JJ, Shi YP, Liu D, Shaheen SM, Rinklebe J. Biogeochemical investigations. J Hazard Mater, 2024, 466 133486
[61]

Yadav SPS, Bhandari S, Bhatta D, Poudel A, Bhattarai S, Yadav P, Ghimire N, Paudel P, Paudel P, Shrestha J, Oli B. Biochar application: a sustainable approach to improve soil health. J Agric Food Res, 2023, 11 100498
[62]

Yang JJ, Jiang LH, Guo ZW, Sarkodie EK, Li KW, Shi JX, Peng YL, Liu HW, Liu XD. The Cd immobilization mechanisms in paddy soil through ureolysis-based microbial induced carbonate precipitation: emphasis on the coexisting cations and metatranscriptome analysis. J Hazard Mater, 2024, 465 133174
[63]

Yu HY, Li FB, Liu CS, Huang W, Liu TX, Yu WM. Chapter five—Iron redox cycling coupled to transformation and immobilization of heavy metals: implications for paddy rice safety in the red soil of South China. Adv Agron, 2016, 137: 279-317

[64]

Yuan JH, Xu RK, Zhang H. The forms of alkalis in the biochar produced from crop residues at different temperatures. Bioresour Technol, 2011, 102(3): 3488-3497

[65]

Yue L, Lian F, Han Y, Bao QL, Wang ZY, Xing BS. The effect of biochar nanoparticles on rice plant growth and the uptake of heavy metals: implications for agronomic benefits and potential risk. Sci Total Environ, 2019, 656: 9-18

[66]

Zeng JX, Tu QC, Yu XL, Qian L, Wang C, Shu LF, Liu F, Liu SW, Huang ZJ, He JG, Yan QY, He ZL. PCycDB: a comprehensive and accurate database for fast analysis of phosphorus cycling genes. Microbiome, 2022, 10(1): 101

[67]

Zhang HL, Huang M, Zhang WH, Gardea-Torresdey JL, White JC, Ji R, Zhao LJ. Silver nanoparticles alter soil microbial community compositions and metabolite profiles in unplanted and cucumber-planted soils. Environ Sci Technol, 2020, 5463334-3342

[68]

Zheng JF, Chen JH, Pan GX, Liu XY, Zhang XH, Li LQ, Sian RJ, Cheng K, Zheng JW. Biochar decreased microbial metabolic quotient and shifted community composition 4 years after a single incorporation in a slightly acid rice paddy from southwest China. Sci Total Environ, 2016, 571: 206-217

Funding

the Basic Science Center Project of the National Natural Science Foundation of China(52388101)

National Natural Science Foundation of China(52261135625)

the Program for Guangdong Introducing Innovative and Entrepreneurial Teams(2019ZT08L213)

the MAECI-NSFC Italy-China Joint Research Program 2023-2025, Project FUNCHARS(PGR02026)

the USDA Hatch Program(MAS 00616)

RIGHTS & PERMISSIONS

The Author(s)

PDF

3

Accesses

0

Citation

Detail
Sections
Recommended

/