Effect of round-shaped silver nanoparticles on the genetic and functional diversity of soil microbial community in soil and soil-plant systems

Silver and silver nanoparticles (AgNPs) are extensively used as antimicrobial agents in various products and consequently enter the soil ecosystem, in which they accumulate and can have adverse effects on above and belowground organisms. Since the composition of the soil microbiome could have a significant impact on soil fertility, we focused, in this study, on the effect of AgNPs on soil microbial communities. We evaluated the biomass, plant growth-promoting activities, and microbial genetic (taxonomical) and functional diversity in the soil and the soil-plant system using chemical, microbiological, and molecular biological methods, especially qPCR, RFLP, and REP-PCR. By compiling the results of the applied assays, we were able to correlate the changes in genetic diversity with the changes in functional diversity and their impact on the composition of soil organic matter. The effect of AgNPs was predominantly dose-dependent, whereas the concentration 100 mg kg(dw)(-1) had the highest effect on all followed parameters. From the taxonomical point of view, AgNPs had the most significant impact on the relative abundance of Bacteroidetes, which increased in a dose-dependent manner, and Firmicutes, which decreased in a dose-dependent manner, and they caused the predominance of Ascomycota among Fungi. These changes in taxonomic diversity result in a significant decrease in the functional diversity of the microbial communities. Especially for the concentration 100 mg kg(dw)(-1), we detected a significant decrease in the ability of the microbial community to utilize simple carbon substrates, determined by Biolog EcoPlates. We detected also a significant alteration in enzyme activity. The activity of enzymes responsible for depolymerization of complex organic matter was in a dose-dependent manner increased, whereas the highest activity reach samples amended with AgNPs at 100 mg kg(dw)(-1). All these changes result in the accumulation of simple organic matter, which could increase osmotic pressure and have severe consequences on soil fertility. In amended soils, we detected alterations of activity of plant growth-promoting bacteria, specifically in the production of indole-3-acetic acid, 1aminocyclopropane-1-carboxylic acid deaminase, and siderophores. All these activities are related to mitigating abiotic stress. The presence of plants in experimental soil had both a mitigating and deepening effect on the toxicity of AgNPs. Both effects probably relate to the influence of AgNPs on the selection of different microbial communities in the soil and the soil-plant system.

Automated summary

Silver and silver nanoparticles (AgNPs) are widely used as antimicrobial agents, entering the soil ecosystem and affecting soil microbial communities. This study found that the effects of AgNPs on soil microbiota are dose-dependent, resulting in changes in genetic and functional diversity, particularly impacting certain microbial taxa. High concentrations of AgNPs led to reduced microbial community ability to utilize carbon substrates, altered enzyme activity, and potential negative effects on soil fertility. The presence of plants in experimental soil had both mitigating and exacerbating effects on AgNPs toxicity, possibly due to the influence of AgNPs on microbial community selection.