The persistence of antimicrobial resistance (AMR) in environmental reservoirs, even in the absence of direct antibiotic selection pressure, represents a critical challenge for global health. However, the mechanisms that prevent the unlimited expansion of environmental AMR remain poorly understood. In this study, we explore how quorum sensing (QS) plays a central role in constraining AMR under antibiotic-free conditions. Through long-term evolution experiments with antibiotic-resistant Pseudomonas aeruginosa strains (PAMP and PCIP), we observed the spontaneous emergence and accumulation of lasR-deficient mutants (ΔlasR), which act as social cheaters. These mutants exhibited a 2.44- to 4.88-fold reduction in minimum inhibitory concentration and impaired biofilm formation, leading to a 70-87.5% decrease in biofilm-protected survival against antibiotics. Moreover, the ΔlasR frequency was strongly correlated with the decline in population-level resistance. Importantly, disruption of QS-mediated policing via reactive oxygen species scavengers accelerated the loss of resistance, confirming the role of lasR in maintaining AMR. Furthermore, ΔlasR possessed a growth advantage only in the absence of antibiotics, thus illustrating an evolutionary trade-off that naturally selects against resistance traits when selection pressure is removed. These findings provide a mechanistic explanation for the reversibility of environmental AMR and may aid the development of strategies targeting QS policing to mitigate antibiotic resistance.
Zhu et al. (Fri,) studied this question.