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65年间,四环素抗性质粒pT181从独立的多拷贝复制子转变为主要整合的染色体元件。

Transition of tetracycline resistance plasmid pT181 from independent multicopy replicon to predominantly integrated chromosomal element over 65 years.

作者信息

Phillips Megan A, Petit Robert A, Weissman Daniel B, Read Timothy D

机构信息

Population Biology, Ecology, and Evolution Program, Graduate Division of Biological and Biomedical Sciences, Laney Graduate School, Emory University, Atlanta, Georgia, USA.

Wyoming Public Health Laboratory, Cheyenne, Wyoming, USA.

出版信息

bioRxiv. 2025 Sep 15:2025.09.14.675889. doi: 10.1101/2025.09.14.675889.

DOI:10.1101/2025.09.14.675889
PMID:41000802
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12458440/
Abstract

Mobile genetic elements (MGEs), including plasmids, phages and genome islands, are major sources of bacterial genetic diversity. The small plasmid pT181 confers tetracycline resistance in bacterial pathogen via an efflux pump, TetK. pT181 was one of the earliest sequenced plasmids, and has been isolated in both clinical and livestock-associated strains for decades, both as an independent replicon and integrated in the chromosome as part of staphylococcal cassette chromosome (SCC). Bacterial genome analysis tools and high-quality sequences with metadata are publicly available, but these resources remain underleveraged for examining historical data, especially when studying the spread of MGEs across a species and over time. Using publicly available reads and metadata, we explored the evolution of pT181 over almost seven decades of samples to identify temporal trends in sequence evolution, copy number changes, and spread across and beyond. pT181 was prevalent across (found in 9.5% of 83,366 genomes tested), with a conserved sequence outside of three hypervariable regions. The history of pT181 since 1954 is characterized by spread across strains, significant variation in plasmid copy number of the independent replicon, and increasing frequency of integration of the plasmid into the chromosome. We have identified multiple chromosomal integration locations of the plasmid, including outside of the previously characterized SCC. We find that pT181 has been transferred across staphylococcaceae and into a Gram-negative species. The repeated integration of pT181 into the chromosome may indicate co-evolution of the plasmid and the host, potentially to facilitate increased antibiotic resistance.

摘要

移动遗传元件(MGEs),包括质粒、噬菌体和基因组岛,是细菌遗传多样性的主要来源。小质粒pT181通过一种外排泵TetK赋予细菌病原体四环素抗性。pT181是最早测序的质粒之一,几十年来在临床菌株和与家畜相关的菌株中都有分离,既作为独立的复制子,也作为葡萄球菌盒式染色体(SCC)的一部分整合到染色体中。细菌基因组分析工具以及带有元数据的高质量序列是公开可用的,但这些资源在用于检查历史数据方面仍未得到充分利用,尤其是在研究MGEs在一个物种内随时间的传播时。利用公开可用的读数和元数据,我们探索了pT181在近七十年的样本中的进化情况,以确定序列进化、拷贝数变化以及在不同菌株间传播的时间趋势。pT181在多种菌株中普遍存在(在测试的83366个基因组中有9.5%的基因组中发现),在三个高变区之外有一个保守序列。自1954年以来,pT181的历史特征是在不同菌株间传播、独立复制子的质粒拷贝数有显著变化,以及该质粒整合到染色体中的频率增加。我们确定了该质粒的多个染色体整合位置,包括在先前已鉴定的SCC之外。我们发现pT181已在葡萄球菌科内转移并进入了一个革兰氏阴性物种。pT181反复整合到染色体中可能表明该质粒与宿主共同进化,这可能有助于增强抗生素抗性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fc75/12458440/6c5532bc57e6/nihpp-2025.09.14.675889v1-f0013.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fc75/12458440/6c5532bc57e6/nihpp-2025.09.14.675889v1-f0013.jpg

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