The Genome Reduction Excludes the Ribosomal Rescue System in Acholeplasmataceae.

Pub Date : 2022-01-01 Epub Date: 2022-01-31 DOI:10.1159/000520450
Christina Zübert, Anna-Marie Ilic, Bojan Duduk, Michael Kube
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引用次数: 1

Abstract

The trans-translation process is a ribosomal rescue system for stalled ribosomes processing truncated mRNA. The genes ssrA and smpB fulfil the key functions in most bacteria, but some species have either lost these genes or the function of the ribosomal rescue system is taken over by other genes. To date, the ribosomal rescue system has not been analysed in detail for the Acholeplasmataceae. This family, in the Mollicutes class, comprises the genus Acholeplasma and the provisional taxon "Candidatus Phytoplasma". Despite their monophyletic origin, the two clades can be separated by traits such as not representing primary pathogens for acholeplasmas versus being phytopathogenic for the majority of phytoplasmas. Both taxa share reduced genomes, but only phytoplasma genomes are characterised by a remarkable level of instability and reduction. Despite the general relevance of the ribosomal rescue system, information is lacking on coding, the genomic context and pseudogenisation of smpB and ssrA and their possible application as a phylogenetic marker. Herein, we provide a comprehensive analysis of the ribosomal rescue system in members of Acholeplasmataceae. The examined Acholeplasmataceae genomes encode a ribosomal rescue system, which depends on tmRNA encoded by ssrA acting in combination with its binding protein SmpB. Conserved gene synteny is evident for smpB, while ssrA shows a less conserved genomic context. Analysis of the tmRNA sequences highlights the variability of proteolysis tag sequences and short conserved sites at the 5'- and 3'-ends. Analyses of smpB provided no hints regarding the coding of pseudogenes, but they did suggest its application as a phylogenetic marker of Acholeplasmataceae - in accordance with 16S rDNA topology. Sequence variability of smpB provides sufficient information for species assignment and phylogenetic analysis.

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麦草科植物基因组还原不包括核糖体拯救系统。
反翻译过程是一个核糖体救援系统,用于停止核糖体处理截断的mRNA。基因ssrA和smpB在大多数细菌中发挥关键作用,但一些物种要么失去了这些基因,要么核糖体拯救系统的功能被其他基因接管。迄今为止,核糖体救援系统还没有被详细分析过。本科属在Mollicutes纲中,包括木浆属和暂定分类群Candidatus Phytoplasma。尽管它们的起源是单系的,但这两个分支可以通过一些特征来区分,比如不代表植物原体的主要病原体,而不是大多数植物原体的植物致病性。这两个类群都有减少的基因组,但只有植原体基因组具有显著的不稳定性和减少的特征。尽管核糖体救援系统具有普遍的相关性,但关于smpB和ssrA的编码、基因组背景和假原化以及它们作为系统发育标记的可能应用的信息缺乏。在此,我们提供了一个全面的分析核糖体救援系统的成员在水藻科。所研究的草浆科基因组编码一个核糖体救援系统,该系统依赖于ssrA编码的tmRNA与其结合蛋白SmpB联合作用。保守的基因同源性在smpB中很明显,而ssrA则表现出不那么保守的基因组背景。对tmRNA序列的分析强调了蛋白质水解标签序列的可变性以及5'端和3'端的短保守位点。对smpB的分析没有提供关于假基因编码的线索,但它们确实表明它可以作为一种系统发育标记-符合16S rDNA拓扑结构。smpB的序列变异性为物种分配和系统发育分析提供了充分的信息。
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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