Completing the BASEL phage collection to unlock hidden diversity for systematic exploration of phage-host interactions.

IF 9.8 1区生物学 Q1 Agricultural and Biological Sciences

PLoS Biology Pub Date : 2025-04-07 eCollection Date: 2025-04-01 DOI:10.1371/journal.pbio.3003063

Dorentina Humolli, Damien Piel, Enea Maffei, Yannik Heyer, Elia Agustoni, Aisylu Shaidullina, Luc Willi, Patrick Imwinkelried, Fabienne Estermann, Aline Cuénod, Dominik P Buser, Carola Alampi, Mohamed Chami, Adrian Egli, Sebastian Hiller, Matthew Dunne, Alexander Harms

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Abstract

Research on bacteriophages, the viruses infecting bacteria, has fueled the development of modern molecular biology and inspired their therapeutic application to combat bacterial multidrug resistance. However, most work has so far focused on a few model phages which impedes direct applications of these findings in clinics and suggests that a vast potential of powerful molecular biology has remained untapped. We have therefore recently composed the BASEL collection of Escherichia coli phages (BActeriophage SElection for your Laboratory), which made a relevant diversity of phages infecting the E. coli K-12 laboratory strain accessible to the community. These phages are widely used, but their assorted diversity has remained limited by the E. coli K-12 host. We have therefore now genetically overcome the two major limitations of E. coli K-12, its lack of O-antigen glycans and the presence of resident bacterial immunity. Restoring O-antigen expression resulted in the isolation of diverse additional viral groups like Kagunavirus, Nonanavirus, Gordonclarkvirinae, and Gamaleyavirus, while eliminating all known antiviral defenses of E. coli K-12 additionally enabled us to isolate phages of Wifcevirus genus. Even though some of these viral groups appear to be common in nature, no phages from any of them had previously been isolated using E. coli laboratory strains, and they had thus remained largely understudied. Overall, 37 new phage isolates have been added to complete the BASEL collection. These phages were deeply characterized genomically and phenotypically with regard to host receptors, sensitivity to antiviral defense systems, and host range. Our results highlighted dominant roles of the O-antigen barrier for viral host recognition and of restriction-modification systems in bacterial immunity. We anticipate that the completed BASEL collection will propel research on phage-host interactions and their molecular mechanisms, deepening our understanding of viral ecology and fostering innovations in biotechnology and antimicrobial therapy.

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完成巴塞尔噬菌体收集，为系统探索噬菌体-宿主相互作用解锁隐藏的多样性。

对噬菌体（感染细菌的病毒）的研究推动了现代分子生物学的发展，并激发了它们在对抗细菌多药耐药性方面的治疗应用。然而，到目前为止，大多数工作都集中在几种模型噬菌体上，这阻碍了这些发现在临床中的直接应用，并表明强大的分子生物学的巨大潜力尚未开发。因此，我们最近编写了大肠杆菌噬菌体的巴塞尔收集（您实验室的噬菌体选择），这使得社区可以获得感染大肠杆菌K-12实验室菌株的相关噬菌体多样性。这些噬菌体被广泛使用，但它们的多样性仍然受到大肠杆菌K-12宿主的限制。因此，我们现在已经从基因上克服了大肠杆菌K-12的两个主要限制，即缺乏o抗原聚糖和存在常驻细菌免疫。恢复o抗原表达导致分离出不同的其他病毒群，如卡古纳病毒、Nonanavirus、戈登克拉克病毒和贾马利病毒，同时消除大肠杆菌K-12的所有已知抗病毒防御，使我们能够分离出wicevirth属噬菌体。尽管这些病毒群中的一些似乎在自然界中很常见，但以前没有使用大肠杆菌实验室菌株分离出其中任何一种噬菌体，因此它们在很大程度上仍未得到充分研究。总的来说，37个新的噬菌体分离物被添加到巴塞尔收集中。这些噬菌体在宿主受体、对抗病毒防御系统的敏感性和宿主范围方面具有深刻的基因组和表型特征。这些结果强调了o抗原屏障在病毒宿主识别和限制修饰系统在细菌免疫中的主导作用。我们预计，完成巴塞尔收集将推动噬菌体-宿主相互作用及其分子机制的研究，加深我们对病毒生态学的理解，促进生物技术和抗菌治疗的创新。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

PLoS Biology BIOCHEMISTRY & MOLECULAR BIOLOGY-BIOLOGY

CiteScore

15.40

自引率

2.00%

发文量

359

审稿时长

3-8 weeks

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