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Biochar-bacteria partnership improves rice growth and soil microbial community diversity while decreasing antimony accumulation and in-vitro bio-accessibility in contaminated soil

Muhammad Hassan, Lorenzo Barbanti, Luigimaria Borruso, Paola Mattarelli, Monica Modesto, Huang Guoqin, Duan Renyan, Haiying Tang, Faizah Amer Altihani

2025Environmental Chemistry and Ecotoxicology5 citationsDOIOpen Access PDF

Abstract

Antimony (Sb) is a toxic metalloid impacting on plants, humans and ecosystem stability. Biochar (BC) is a promising amendment to mitigate toxic metals/metalloids. However, the role of BC and bacterial inoculation in mitigating Sb toxicity and bio-accessibility, and reshaping soil bacterial community has not yet been explored. To investigate this subject, a rice pot experiment was set up involving six treatments: unstressed soil (Ctrl); 1200 mg Sb kg −1 (Sb stress); Sb stress +1 % BC (1 % BC); Sb stress +2.5 % BC (2.5 % BC); Sb stress +1 % BC + Bacillus subtilis bio-inoculum (1 % BC + BI); Sb stress +2.5 % BC + BI (2.5 % BC + BI). The serious impairment in rice growth, physiology and final yield determined by Sb stress was reduced by BC and associated BI. The maximum stress relief was obtained with 2.5 % BC + BI, which increased rice growth and final grain yield (+85 %) by improving several plant traits and soil properties, while decreasing Sb availability. 2.5 % BC + BI curbed Sb concentration in plant organs (−43 % in the whole plant), whereas Sb whole plant content was moderately reduced (−13 %), due to a growth driven Sb uptake effect. Upon 2.5 % BC + BI, soil total Sb concentration and in vitro bio-accessibility were similarly reduced (average, −35 %) due to increases in soil total carbon (+61 %), microbial biomass carbon (+37 %), and enzymatic activities (+72 % in the average of urease and catalase). The addition of BC + BI significantly boosted the relative abundance of soil bacteria involved in reducing Sb toxicity. Our findings highlight BC + BI potential to improve rice production, reduce Sb plant accumulation, soil in-vitro bio-accessibility, and ameliorate soil bacterial community diversity. • Antimony (Sb) toxicity reduced rice growth, and yield. • Bacillus subtilis bio-inoculum (BI) reshaped soil bacterial community diversity. • 2.5 % biochar (BC) + BI enhanced antioxidant activity and recovered 3/4 of Sb stress. • BC + BI curbed Sb concentration in plant organs and Sb bio-accessibility. • BC + BI influenced soil bacteria relative abundance prompting resistance to Sb stress.

Topics & Concepts

BiocharEnvironmental scienceMicrobial population biologyAntimonyEnvironmental chemistryContaminationSoil contaminationAgronomyBacteriaEcologyBiologySoil waterChemistrySoil scienceWaste managementEngineeringInorganic chemistryPyrolysisGeneticsHeavy metals in environmentArsenic contamination and mitigationMine drainage and remediation techniques
Biochar-bacteria partnership improves rice growth and soil microbial community diversity while decreasing antimony accumulation and in-vitro bio-accessibility in contaminated soil | Litcius