Synthesis of the Genome of Bacteriophage N4

Problems of Particularly Dangerous Infections Pub Date : 2024-04-04 DOI:10.21055/0370-1069-2024-1-182-191

G. Y. Fisunov, T. A. Semashko, D. Evsyutina, E. A. Tsoy, D. R. Kharrasov, K. S. Gumayunova, I. Tuchkov, K. A. Nikiforov, D. A. Rybalchenko, V. V. Kutyrev, V. M. Govorun

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Abstract

At present, bacteriophages are considered as an alternative to antibiotics in prevention and treatment of bacterial infections, in particular cholera.The aim of the work was to demonstrate a method to obtain synthetic bacteriophage against Vibrio cholerae. Vibriophage N4 was selected as a subject for the study.Materials and methods. The genome sequence of vibriophage N4 (38.5 kb) was taken from the NCBI GenBank database. The sequence was divided into gene blocks of 1500–2000 bp. The gene blocks, in turn, were split into oligonucleotides. Sequence partitioning was carried out using the BAC-browser software that we have developed. Oligonucleotides were chemically synthesized; gene blocks were assembled from them. After that, the complete genome of vibriophage N4 was synthesized from the obtained gene blocks. The assembly of the synthetic genome took place in two stages. At the first stage, gene block cassettes of 5–7 pieces with sizes ranging from 7 to 10.5 thousand bp were generated via homologous recombination in yeast. The resulting cassettes were then amplified and used for in vitro assembly using 5’-3’ exonuclease and thermostable DNA polymerase. The resulting preparation was used for electroporation of V. cholerae cells.Results and discussion. The synthetic genome of vibriophage N4 was delivered into the V. cholerae strain M818 O1 biovar El Tor using electroporation. As a result, the formation of lytic plaques on the lawn of V. cholerae was observed. The range of technologies we have developed: software for assembly design, enzymes and buffers for the synthesis of gene blocks and their crosslinking by homologous recombination in vitro, the method for producing large-sized assemblies in yeast can be used to obtain artificial bacteriophages with a rational genome design.

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噬菌体 N4 基因组的合成

目前，噬菌体被认为是预防和治疗细菌感染（尤其是霍乱）的抗生素替代品。这项工作的目的是展示一种获得抗霍乱弧菌合成噬菌体的方法。噬菌体 N4 被选为研究对象。噬菌体 N4 的基因组序列（38.5 kb）来自 NCBI GenBank 数据库。该序列被分为 1500-2000 bp 的基因块。基因块又被分成寡核苷酸。序列分割使用我们开发的 BAC 浏览器软件进行。寡核苷酸由化学合成，基因块由化学合成的寡核苷酸组装而成。然后，用获得的基因块合成噬菌体 N4 的完整基因组。合成基因组的组装分为两个阶段。第一阶段，在酵母中通过同源重组产生 5-7 个大小为 7 至 10.5 千 bp 的基因块盒。然后，利用 5'-3' 外切酶和恒温 DNA 聚合酶对产生的基因盒进行扩增和体外组装。结果和讨论。利用电穿孔将合成的噬菌体 N4 基因组传递到霍乱弧菌菌株 M818 O1 生物变种 El Tor 中。结果观察到霍乱弧菌草坪上形成了裂解斑块。我们开发的一系列技术：组装设计软件、用于合成基因块和在体外通过同源重组交联基因块的酶和缓冲液、在酵母中产生大尺寸组装的方法，可用于获得具有合理基因组设计的人工噬菌体。

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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Problems of Particularly Dangerous Infections

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