Critical insights into the Hormesis of antibiotic resistome in saline soil: Implications from salinity regulation

Abstract

Soil is recognized as an important reservoir of antibiotic resistance genes (ARGs). However, the effect of salinity on the antibiotic resistome in saline soils remains largely misunderstood. In this study, high-throughput qPCR was used to investigate the impact of low-variable salinity levels on the occurrence, health risks, driving factors, and assembly processes of the antibiotic resistome. The results revealed 206 subtype ARGs across 10 categories, with medium-salinity soil exhibiting the highest abundance and number of ARGs. Among them, high-risk ARGs were enriched in medium-salinity soil. Further exploration showed that bacterial interaction favored the proliferation of ARGs. Meanwhile, functional genes related to reactive oxygen species production, membrane permeability, and adenosine triphosphate synthesis were upregulated by 6.9%, 2.9%, and 18.0%, respectively, at medium salinity compared to those at low salinity. With increasing salinity, the driver of ARGs in saline soils shifts from bacterial community to mobile gene elements, and energy supply contributed 28.2% to the ARGs at extreme salinity. As indicated by the neutral community model, stochastic processes shaped the assembly of ARGs communities in saline soils. This work emphasizes the importance of salinity on antibiotic resistome, and provides advanced insights into the fate and dissemination of ARGs in saline soils. Environmental ImplicationsSaline soil is a widely distributed soil type in which contaminants can directly and extensively affect the health of a huge population. In contrast, as an emerging contaminant, ARGs have not received enough attention for a long time in terms of their occurrence and health risks in saline soils. In this study, the deterministic effect of salinity on the antibiotic resistomein saline soil and its potential mechanisms were deeply explored. This work expanded our understanding of the neglected health risks of antibiotic resistance, and provided advanced insights for maintaining ecological security in saline soils.