Synergistic Effects of Bacillus cereus Mn-5 PGPR-Derived Silver Oxide Nanoparticles on Tomato Plant Growth, Stress Resilience and Nutritional Enhancement

Journal of Sustainable Agriculture and Environment Pub Date : 2025-09-30 DOI:10.1002/sae2.70090

Indu Bhardwaj, Nidhi Bhardwaj, Vijay Kumar, Shikha Kumari, Kanika Dulta, Junaid Aman, Helen Onyeaka, Soumya Ghosh

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引用次数: 0

Abstract

Introduction

Agricultural crops face increasing environmental stresses, such as soil salinity and heavy metal contamination, aggravated by climate change and threatening food security. While PGPRs are eco-friendly agrochemical substitutes, their efficacy in the field is inconsistent. Integrating microbial biotechnology with green nanotechnology presents a solution. This in vitro research investigates a multifunctional Bacillus cereus strain that functions as both a PGPR and a green synthesizer of silver oxide nanoparticles (Ag₂O NPs) to enhance early tomato seedling growth sustainably.

Materials and Methods

Bacterial isolates from tomato rhizosphere were tested for PGPR traits, biocontrol activities and stress tolerance. The most effective PGPR isolates were identified by 16S rRNA sequencing and also employed for Ag₂O NPs biosynthesis, followed by characterization using XRD, SEM, TEM and FTIR. Tomato seeds were treated with Mn-5-derived Ag₂O NPs (1–100 ppm) and evaluated for in vitro germination and seedling growth.

Results

The B. cereus Mn-5 PGPR exhibited strong growth-promoting characteristics, including phosphate solubilization (18.91–187.47 µg/mL), siderophores production, nitrogen fixation, protease production and antagonism against Rosellinia necatrix. It tolerated 8% salinity and heavy metals up to 100 µg/mL. Mn-5 PGPR was employed for Ag₂O NP synthesis and characterization. XRD, SEM, TEM and FTIR revealed spherical, agglomerated NPs with a crystallite size of 30.26 nm and a particle diameter of 80.16 ± 1.51 nm, with FTIR bands ranging from 400 to 4000 cm⁻¹. In vitro, 5 ppm Mn-5 PGPR-derived Ag₂O NPs concentrations notably promoted tomato seed germination, shoot–root growth, seed vigour index and biomass by 200% over controls and a 44.4% over PGPR alone. Conversely, higher concentrations (50 and 100 ppm) were phytotoxic inhibiting seedling growth.

Conclusion

The study demonstrates the potential of B. cereus Mn-5 PGPR and biosynthesized Ag₂O NPs as eco-friendly bio-stimulants for tomato growth under stress. The findings establish a baseline for future in vivo studies on dosage optimization toward sustainable agriculture.

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蜡样芽孢杆菌Mn-5 pgpr衍生氧化银纳米颗粒对番茄植株生长、抗逆性和营养增强的协同效应

农业作物面临着日益严重的环境压力，如土壤盐碱化和重金属污染，气候变化加剧了这些压力，并威胁着粮食安全。虽然PGPRs是环保的农用化学品替代品，但它们在田间的效果却不一致。将微生物生物技术与绿色纳米技术相结合提供了一种解决方案。本研究研究了一种多功能蜡样芽孢杆菌菌株，该菌株既可以作为PGPR，也可以作为氧化银纳米颗粒（Ag₂O NPs）的绿色合成器，以可持续地促进番茄早期幼苗的生长。材料与方法对番茄根际分离菌株的PGPR性状、生物防治活性和抗逆性进行了研究。通过16S rRNA测序鉴定了最有效的PGPR分离株，并将其用于Ag₂O NPs的生物合成，随后使用XRD， SEM， TEM和FTIR对其进行了表征。用mn -5衍生的Ag₂O NPs （1-100 ppm）处理番茄种子，评价其离体萌发和幼苗生长情况。结果蜡样芽孢杆菌Mn-5 PGPR具有较强的促生长作用，包括增磷作用（18.91 ~ 187.47µg/mL）、产铁载体、固氮、产蛋白酶和拮抗玫瑰孢。耐8%的盐度和高达100 μ g/mL的重金属。利用Mn-5 PGPR合成并表征Ag₂O NP。XRD、SEM、TEM和FTIR检测结果表明，纳米粒子呈球形、团聚状，晶粒尺寸为30.26 nm，粒径为80.16±1.51 nm， FTIR波段范围为400 ~ 4000 cm−¹。在体外，5 ppm Mn-5 PGPR衍生的Ag₂O NPs浓度显著促进了番茄种子萌发、茎根生长、种子活力指数和生物量，比对照提高了200%，比PGPR单独提高了44.4%。相反，较高浓度（50和100 ppm）的植物毒性抑制幼苗生长。结论蜡样芽孢杆菌Mn-5 PGPR和生物合成的Ag₂O NPs具有促进番茄逆境生长的生态友好型生物刺激物的潜力。这些发现为未来可持续农业的剂量优化体内研究奠定了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Sustainable Agriculture and Environment

CiteScore

2.60

自引率

0.00%

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