抵抗性
蛋白质组
基因组
生物
流出
生物膜
微生物学
抗生素耐药性
抗性(生态学)
土壤微生物学
微生物生态学
微生物群
操作分类学单元
生态学
细菌
无脊椎动物
抗生素
原核生物
微生物
肠道菌群
焦测序
代谢组
生态系统
胞外聚合物
细菌遗传学
生物利用度
无脊椎动物
多重耐药
作者
Yi‐Fei Wang,Yaning Wang,Da Lin,Jiayang Xu,Fuzhen Qi,Hui‐Ling Cui,Huijie Lü,Min Qiao,Edward Topp,Dong Zhu,Matthias C. Rillig,Yong‐Guan Zhu
标识
DOI:10.1002/advs.202518849
摘要
The environmental accumulation of non-antibiotic pharmaceuticals is an emerging driver of antibiotic resistance. While individual compounds are known to shape the soil resistome, and contaminant diversity also plays a role, the impact of pharmaceutical diversity on the gut resistome of soil invertebrates remains unclear. Here, we combined metagenomics and metaproteomics to examine the collembolan gut and soil resistome across a gradient of pharmaceutical diversity under diurnal warming. Increasing pharmaceutical diversity at a constant total concentration significantly enriched antibiotic resistance genes (ARGs) in the gut microbiome, with no comparable effect in surrounding soils. This enrichment was mainly driven by multidrug resistance associated with efflux activity and biofilm-related processes, accompanied by increases in ARG-carrying taxa such as Gordonia and Ochrobactrum. Notably, Ochrobactrum encoded biofilm-related aryl polyene pathways. In vitro experiments confirmed that biofilm formation promotes resistance through coordinated cellular responses. Metaproteomic data indicated that Ochrobactrum initiates early biofilm formation by recruiting extracellular matrix producers such as Bacillus and Pseudomonas. Diurnal warming modulated these responses, indicating an interaction between chemical diversity and climate stress. These findings identify pharmaceutical diversity as an independent driver of ARG enrichment in host-associated microbiomes and establish chemical complexity as a key factor in assessing the ecological risks of pharmaceutical pollution.
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