@Article{phyton.2025.064632,
AUTHOR = {Hua Zhang, Ganghua Li},
TITLE = {Microbial Strategies for Enhancing Nickel Nanoparticle Detoxification in Plants to Mitigate Heavy Metal Stress},
JOURNAL = {Phyton-International Journal of Experimental Botany},
VOLUME = {94},
YEAR = {2025},
NUMBER = {5},
PAGES = {1367--1399},
URL = {http://www.techscience.com/phyton/v94n5/61381},
ISSN = {1851-5657},
ABSTRACT = {Soil naturally contains various heavy metals, however, their concentrations have reached toxic levels due to excessive agrochemical use and industrial activities. Heavy metals are persistent and non-biodegradable, causing environmental disruption and posing significant health hazards. Microbial-mediated remediation is a promising strategy to prevent heavy metal leaching and mobilization, facilitating their extraction and detoxification. Nickel (Ni), being a prevalent heavy metal pollutant, requires specific attention in remediation efforts. Plants have evolved defense mechanisms to cope with environmental stresses, including heavy metal toxicity, but such stress significantly reduces crop productivity. Beneficial microorganisms play a crucial role in enhancing plant yield and mitigating abiotic stress. The impact of heavy metal abiotic stress on plants’ growth and productivity requires thorough investigation. Bioremediation using Nickel nanoparticles (Ni NPs) offers an effective approach to mitigating environmental pollution. Microorganisms contribute to nanoparticle bioremediation by immobilizing metals or inducing the synthesis of remediating microbial enzymes. Understanding the interactions between microorganisms, contaminants, and nanoparticles (NPs) is essential for advancing bioremediation strategies. This review focuses on the role of <i>Bacillus subtilis</i> in the bioremediation of nickel nanoparticles to mitigate environmental pollution and associated health risks. Furthermore, sustainable approaches are necessary to minimize metal contamination in seeds. The current review discusses bacterial inoculation in enhancing heavy metal tolerance, plant signal transduction pathways, and the transition from molecular to genomic research in metal stress adaptation. Moreover, the inoculation of advantageous bacteria is crucial for preserving plants under severe mental stress. Different researchers develop a complex, vibrant relationship with plants through a series of events known as plant-microbe interactions. It increases metal stress resistance through the creation of phytohormones. In general, the defensive responses of plants to heavy metal stress, mediated by microbial inoculation require further in-depth research. Further studies should explore the detoxification mechanism of nickel through bioremediation to develop more effective and sustainable remediation strategies.},
DOI = {10.32604/phyton.2025.064632}
}