Abstract

Antimicrobial resistance has gained increasing attention, because of the awareness of its potential health risks. Strategies for the removal of antibiotic resistance genes (ARGs) are urgently required. In the present study, UV-LEDs at wavelength of 265 and 285 nm were integrated at five conditions, including single 265 nm UV-LED, single 285 nm UV-LED, and combined 265 nm and 285 nm UV-LED at different intensities, to remove tet A, cat 1, and amp C. The ARGs removal efficiency, gene behavior, and possible cellular mechanism were analyzed using real-time quantitative PCR, flow cytometry, and transmission electron microscopy (TEM). The 265 nm UV-LED is more effective than the 285 nm UV-LED and their combinations in terms of ARGs control, in which 1.91, 1.71, and 1.45 log were removed for tet A, cat 1, and amp C, respectively, at a UV dosage of 500 mJ/cm2. The intracellular gene leakage was detected in all five UV-LED experiment scenarios even when the cell membrane damage was insignificant with the highest increase of 0.69 log ARGs. ROS was generated during the irradiation, and the ROS was strongly negative correlated with intracellular ARGs, which could promote the degradation and removal of ARGs. This study provides a new insight of intracellular ARGs removal, because direct irradiation, ROS oxidation, and leakage to the extracellular serve as the three main pathways under high-dosage UV-LED irradiation. Further research should be focused on the mechanism and optimization of UV technology with 265 nm UV-LED for ARG control.

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