Emergence and spread patterns of antibiotic resistance genes during cultivating aerobic granular sludge under different feeding modes

Abstract

Aerobic granular sludge (AGS) technology, which is a promising approach for wastewater treatment, encounters challenges associated with antibiotic resistance genes (ARGs) in biological treatment systems. This study investigates the dynamics of ARGs during AGS cultivation under anaerobic plug-flow (APM), anaerobic mixed-flow (AMM), and aerobic feeding mode (AFM). Significant differences (P < 0.05) are observed in the shifts of ARGs among these modes. The abundance of ARGs notably increases under all modes, with AMM exhibiting a lower average relative abundance (0.063 ± 0.025) compared to that of APM (0.148 ± 0.061) and AFM (0.147 ± 0.047). The observed variations in bacterial communities and the co-selection of ARGs among the feeding modes are likely influential factors contributing to the documented variations of ARGs. Furthermore, the study identifies tnpA and intl1 as key contributors to horizontal gene transfer (HGT) during APM and AFM operations. Additionally, a heightened level of HGT is observed in both APM and AFM, with a larger potential host range (12 hosts each) harboring ARGs, in contrast to AMM (4 hosts). The study highlights the pivotal role played by distinct bacterial communities and the co-selection of ARGs in ARG variations across feeding modes. AMM emerges as an effective strategy for mitigating ARG proliferation, thereby enhancing the safety and sustainability of AGS technology in wastewater treatment.