多粘菌素
生物
水平基因转移
串扰
多粘菌素B
质粒
细菌
微生物学
抗生素
生物物理学
基因
细菌外膜
细胞生物学
基因转移
氧化应激
抵抗性
抗生素耐药性
渗透性休克
脂质A
微生物生态学
微生物
作者
Meng-Qi Liang,L. Yuan,Qian-He Liu,Jianmin Wu,Dong-Feng Liu,G. Sheng
标识
DOI:10.1093/ismejo/wrag046
摘要
Although it is increasingly recognized that anthropogenic chemicals modulate horizontal gene transfer (HGT), the nature of these interactions is often more complex than a simple promotion or inhibition. The potential for a single chemical to exert opposing, concentration-dependent effects represents a critical and less-explored frontier in microbial ecology. Here, we investigate the last-resort antibiotic polymyxin B, a membrane-targeting peptide, and reveal a concentration-dependent, biphasic regulation of plasmid conjugation. Subinhibitory concentrations (0.125-0.5 mg/l) consistently inhibited the transfer of antibiotic resistance genes (ARGs) by up to 65.4%, whereas bactericidal concentrations (≥ 1 mg/l) strongly promoted it by up to 15.9-fold. This regulatory switch is driven by distinct physiological states: low-level exposure triggers defensive responses including reduced membrane permeability, whereas high-level exposure causes catastrophic membrane damage, inducing a synergistic stress response involving oxidative damage (> two-fold ROS increase) and a surge in cellular energy (up to 83.0% ATP increase) that facilitates HGT. High-concentration polymyxin B also promotes plasmid transfer in complex microbial communities derived from activated-sludge biofilms. Our findings reveal a new paradigm for the interaction between chemical stressors and microbial evolution, demonstrating that the ecological impact of contaminants on HGT cannot be predicted by monotonic models and highlighting the role of environmental hotspots in shaping the dissemination of antibiotic resistome.
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