DNA polymerase swapping in Caudoviricetes bacteriophages.

IF 4 3区医学 Q2 VIROLOGY

Virology Journal Pub Date : 2024-08-26 DOI:10.1186/s12985-024-02482-z

Natalya Yutin, Igor Tolstoy, Pascal Mutz, Yuri I Wolf, Mart Krupovic, Eugene V Koonin

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引用次数: 0

Abstract

Background: Viruses with double-stranded (ds) DNA genomes in the realm Duplodnaviria share a conserved structural gene module but show a broad range of variation in their repertoires of DNA replication proteins. Some of the duplodnaviruses encode (nearly) complete replication systems whereas others lack (almost) all genes required for replication, relying on the host replication machinery. DNA polymerases (DNAPs) comprise the centerpiece of the DNA replication apparatus. The replicative DNAPs are classified into 4 unrelated or distantly related families (A-D), with the protein structures and sequences within each family being, generally, highly conserved. More than half of the duplodnaviruses encode a DNAP of family A, B or C. We showed previously that multiple pairs of closely related viruses in the order Crassvirales encode DNAPs of different families.

Methods: Groups of phages in which DNAP swapping likely occurred were identified as subtrees of a defined depth in a comprehensive evolutionary tree of tailed bacteriophages that included phages with DNAPs of different families. The DNAP swaps were validated by constrained tree analysis that was performed on phylogenetic tree of large terminase subunits, and the phage genomes encoding swapped DNAPs were aligned using Mauve. The structures of the discovered unusual DNAPs were predicted using AlphaFold2.

Results: We identified four additional groups of tailed phages in the class Caudoviricetes in which the DNAPs apparently were swapped on multiple occasions, with replacements occurring both between families A and B, or A and C, or between distinct subfamilies within the same family. The DNAP swapping always occurs "in situ", without changes in the organization of the surrounding genes. In several cases, the DNAP gene is the only region of substantial divergence between closely related phage genomes, whereas in others, the swap apparently involved neighboring genes encoding other proteins involved in phage genome replication. In addition, we identified two previously undetected, highly divergent groups of family A DNAPs that are encoded in some phage genomes along with the main DNAP implicated in genome replication.

Conclusions: Replacement of the DNAP gene by one encoding a DNAP of a different family occurred on many independent occasions during the evolution of different families of tailed phages, in some cases, resulting in very closely related phages encoding unrelated DNAPs. DNAP swapping was likely driven by selection for avoidance of host antiphage mechanisms targeting the phage DNAP that remain to be identified, and/or by selection against replicon incompatibility.

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噬菌体中的DNA聚合酶交换。

背景：具有双链（ds）DNA基因组的双螺旋病毒（Duplodnaviria）共享一个保守的结构基因模块，但它们的DNA复制蛋白库却显示出广泛的差异。一些双螺旋病毒编码（几乎）完整的复制系统，而另一些则缺乏（几乎）复制所需的所有基因，只能依赖宿主的复制机制。DNA 聚合酶（DNAPs）是 DNA 复制装置的核心。复制型 DNAP 可分为 4 个不相关或关系较远的家族（A-D），每个家族的蛋白质结构和序列一般都高度保守。半数以上的双螺旋病毒编码 A、B 或 C 族的 DNAP。我们以前曾发现，克拉斯病毒目中有多对密切相关的病毒编码不同族的 DNAP：方法：在包括具有不同科 DNAP 的噬菌体的有尾噬菌体综合进化树中，将可能发生 DNAP 交换的噬菌体组确定为具有一定深度的子树。在大终结酶亚基系统进化树上进行的约束树分析验证了 DNAP 交换，并使用 Mauve 对编码交换 DNAP 的噬菌体基因组进行了比对。使用 AlphaFold2 对发现的异常 DNAPs 的结构进行了预测：结果：我们发现了 Caudoviricetes 类中另外四组有尾噬菌体，它们的 DNAPs 显然多次发生了互换，互换发生在 A 和 B 家族之间，或 A 和 C 家族之间，或同一家族中的不同亚家族之间。DNAP 交换总是在 "原位 "发生，周围基因的组织没有发生变化。在一些情况下，DNAP 基因是密切相关的噬菌体基因组之间出现实质性差异的唯一区域，而在另一些情况下，交换显然涉及到编码参与噬菌体基因组复制的其他蛋白质的邻近基因。此外，我们还发现了两组以前未被发现的、差异很大的 A 族 DNAP，它们与涉及基因组复制的主要 DNAP 一起在一些噬菌体基因组中编码：结论：在有尾噬菌体不同家族的进化过程中，用编码不同家族 DNAP 的基因替换 DNAP 基因的情况多次独立发生，在某些情况下，导致编码不相关 DNAP 的噬菌体非常接近。DNAP互换可能是为了避免宿主针对噬菌体DNAP的反噬菌体机制，和/或为了避免复制子不相容。

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

Virology Journal 医学-病毒学

CiteScore

7.40

自引率

2.10%

发文量

186

审稿时长

1 months

期刊介绍： Virology Journal is an open access, peer reviewed journal that considers articles on all aspects of virology, including research on the viruses of animals, plants and microbes. The journal welcomes basic research as well as pre-clinical and clinical studies of novel diagnostic tools, vaccines and anti-viral therapies. The Editorial policy of Virology Journal is to publish all research which is assessed by peer reviewers to be a coherent and sound addition to the scientific literature, and puts less emphasis on interest levels or perceived impact.