What does this research mean for the field?

Human activity significantly drives the distribution and risk of virus-carried antibiotic resistance genes, with artificial habitats harboring approximately 15 times higher abundance of high-risk resistance genes compared to natural environments. Novelty: ClaimNovelty.SYNTHESIS. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The study aims to assess the distribution and risk levels of virus-carried antibiotic resistance genes across different habitats.

May 17, 2026

Virus-carried Antibiotic Resistance Genes in Diverse Habitats: Risk and Divergence

Key Points

The study aims to assess the distribution and risk levels of virus-carried antibiotic resistance genes across different habitats.
Collected metagenomic data from 780 environmental samples including wastewater, soil, and wetlands.
Employed a unified analysis workflow to evaluate the composition and risk levels of viral antibiotic resistance genes.
Conducted core resistance group analysis across different habitats.
High-risk antibiotic resistance gene abundance in artificial habitats was 15 times greater than in natural environments.
Plastic interfaces showed the highest subtype diversity of resistance genes.
Uroviricota viruses dominate in artificial habitats, indicating a major role in resistance gene distribution.

Abstract

抗生素抗性基因在环境中广泛传播，对公共健康和生态系统构成威胁。病毒作为抗性基因的储存与传播载体，其作用日益受到关注。但病毒携带抗性基因在不同生境中的空间格局、风险水平及驱动因素，仍缺乏系统认知。本研究汇总了780份来自污水处理厂、垃圾渗滤液、塑料际、土壤、湖泊沉积物、降雨及湿地的环境样品宏基因组数据，采用统一分析流程，系统分析了病毒抗性基因的组成特征、风险等级、宿主关联及主要来源。结果表明，病毒抗性基因的分布受生境影响明显。人工生境中，高风险抗性基因丰度显著高于自然环境，约为其15倍；自然生境则是低风险抗性基因占优。塑料际环境的抗性基因亚型多样性最高，可能成为抗性基因的潜在储存与交换热区。跨生境的核心抗性组为20个低风险抗性基因。病毒类群分析显示，Uroviricota病毒在人工生境中占主导，是抗性基因的主要携带者。湿地病毒抗性组溯源结果表明，土壤是其主要来源。本研究揭示，人类活动强度显著调控病毒携带抗性基因的分布，环境管理和公共卫生策略中，应优先关注人类高强度活动区域，以便识别关键耐药扩散节点并实施分区防控，降低抗性基因传播风险。

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