氧化磷酸化
铋
硒
青枯病
形态学(生物学)
纳米复合材料
化学
微生物学
生物
材料科学
纳米技术
生物化学
有机化学
动物
作者
Yanyu Hu,Er-Wen Yang,Yanping Qiu,Bing Yang,Shang Gao,Sha Li,Yuanyuan Cao,Dongdong Sun
标识
DOI:10.1016/j.jclepro.2025.145455
摘要
Tobacco bacterial wilt significantly impacts tobacco yield and quality, despite traditional control methods such as chemical fungicides and resistant cultivar breeding. However, these approaches suffer from limitations including monotonousness, residue concerns, and lengthy breeding cycles. In search of alternative solutions, nanomaterials have emerged as promising agents for enhancing agricultural productivity. Bismuth (Bi), a stable metal element with potent antibacterial properties , can effectively inhibit bacterial infections. Selenium (Se), an essential trace element for plants, exists in organic forms like selenocysteine within plants and enhances stress resistance . In this study, we designed cluster-like Bi-Se nanoparticles (Bi-Se NPs) by combining lamellar Bi NPs and spherical Se NPs via electrostatic interaction under nitrogen protection using a redox method. The optimal dosage was determined to be 128 ± 5 μg/mL based on antibacterial inhibition tests. Application of Bi-Se NPs through root irrigation increased selenium and reducing sugar contents in tobacco leaves, indicating a substantial nutrient boost in the plant body. Multi-omics analysis of the leaves revealed significant upregulation of succinic acid and flavin mononucleotide (FMN), components of the oxidative phosphorylation pathway. This upregulation enhanced pathway efficiency, accelerated oxygen and ATP production in leaves, and notably improved metabolic efficiency, thereby fostering tobacco growth and development . Furthermore, toxicity evaluations confirmed the non-toxic nature of Bi-Se NPs to mice . Collectively, these findings offer valuable insights and support for the management and yield enhancement of nanoscale agricultural systems. Bi-Se NPs inhibit tobacco bacterial wilt by disrupting bacterial morphology and promoting vegetative oxidative phosphorylation . • Clustered Bi-Se nanoparticles (Bi-Se NPs) were designed under redox conditions. • Bi-Se NPs would inhibit the growth of R. solanacearum by increasing ROS content, removing biofilm and so on. • Bi-Se NPs significantly increased the nutrient content and improved the metabolic efficiency through plant root irrigation.
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