Cell-free synthesis of infective phages from in vitro assembled phage genomes for efficient phage engineering and production of large phage libraries.

IF 2.6 Q2 BIOCHEMICAL RESEARCH METHODS

Synthetic biology (Oxford, England) Pub Date : 2024-08-24 eCollection Date: 2024-01-01 DOI:10.1093/synbio/ysae012

Camilla S Kristensen, Anders Ø Petersen, Mogens Kilstrup, Eric van der Helm, Adam Takos

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Abstract

Bacteriophages are promising alternatives to traditional antimicrobial treatment of bacterial infections. To further increase the potential of phages, efficient engineering methods are needed. This study investigates an approach to phage engineering based on phage rebooting and compares selected methods of assembly and rebooting of phage genomes. GG assembly of phage genomes and subsequent rebooting by cell-free transcription-translation reactions yielded the most efficient phage engineering and allowed production of a proof-of-concept T7 phage library of 1.8 × 10⁷ phages. We obtained 7.5 × 10⁶ different phages, demonstrating generation of large and diverse libraries suitable for high-throughput screening of mutant phenotypes. Implementing versatile and high-throughput phage engineering methods allows vastly accelerated and improved phage engineering, bringing us closer to applying effective phages to treat infections in the clinic.

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从体外组装的噬菌体基因组中无细胞合成感染性噬菌体，用于高效的噬菌体工程和大型噬菌体文库的生产。

噬菌体是治疗细菌感染的传统抗菌剂的有前途的替代品。为了进一步提高噬菌体的潜力，需要高效的工程方法。本研究调查了一种基于噬菌体重启的噬菌体工程方法，并比较了噬菌体基因组组装和重启的选定方法。噬菌体基因组的 GG 组装和随后的无细胞转录-翻译反应重启产生了最有效的噬菌体工程，并生产出了一个由 1.8 × 107 个噬菌体组成的概念验证 T7 噬菌体文库。我们获得了 7.5 × 106 种不同的噬菌体，证明了大型多样化文库的生成适合高通量筛选突变表型。采用多功能和高通量噬菌体工程方法可以大大加快和改进噬菌体工程，使我们更接近在临床上应用有效的噬菌体治疗感染。

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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Synthetic biology (Oxford, England)

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