Soil chloride content influences the response of bacterial but not fungal diversity to silver nanoparticles entering soil via wastewater treatment processing

Silver nanoparticles (NPs) are among the most widely used nanomaterials and are entering soil ecosystems, mainly via biosolids in agriculture. When added directly to soils, metallic Ag-NPs have been shown to affect microbial communities, which underpin important ecosystem functions. During wastewater treatment processing, metallic Ag-NPs are rapidly converted to Ag2S, which is relatively insoluble and less toxic. Furthermore, recent evidence indicates that silver bioavailability is influenced by soil chloride content. Hence there is a need to understand the impacts of wastewater treatment processed Ag-NPs at varying levels of salinity on soil microbial diversity. In this study, we examined how the application of 0 g, 1 g and 2 g kg-1 NaCl to soil influence the effects of 0 mg, 1 mg and 10 mg kg-1 Ag, applied as wastewater treatment processed Ag-NPs, on bacterial and fungal diversity over time. Using high-throughput phylogenetic marker gene sequencing we demonstrate that, despite being theoretically less toxic, wastewater treatment processed Ag-NPs can affect the composition of soil bacterial and fungal communities, and influence bacterial alpha diversity. In addition, we found that silver-associated changes in bacterial community composition were affected by soil chloride content, with more acute responses to silver being observed in more saline soils. This work highlights that the release of Ag-NPs into soils via realistic exposure pathways can alter microbial diversity and that these effects may be influenced by soil chloride content.