沙门氏菌基因组重排对基因表达的影响。

IF 3.4 1区 生物学 Q2 EVOLUTIONARY BIOLOGY Evolution Letters Pub Date : 2022-11-19 eCollection Date: 2022-12-01 DOI:10.1002/evl3.305
Emma V Waters, Liam A Tucker, Jana K Ahmed, John Wain, Gemma C Langridge
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引用次数: 0

摘要

除核苷酸变异外,许多细菌还通过围绕长重复序列的基因组结构(GS)重排发生更大范围的变化。这些重排导致基因组片段在基因组中的位置和/或方向发生变化,而不一定影响基本的核苷酸序列。迄今为止,可扩展的技术尚未应用于 GS 鉴定,因此这种变异的范围有多大及其对基因表达的影响程度仍不清楚。不过,多路复用长读数测序技术的出现克服了这一规模问题,因为它通常能产生几千个碱基的读数,可以跨越长的重复序列来识别侧翼染色体 DNA,从而进行 GS 鉴定。肠炎沙门氏菌(Salmonella enterica serovar Typhi)通过在环境温度下长期培养产生了基因组重排。通过长程聚合酶链式反应(PCR)鉴定出有基因重排的菌落,并进行长线程纳米孔测序以确认基因组变异。利用转录组学研究了四个重排基因的差异表达。与母株相比,所有基因组排列发生变化的分离株都伴随着基因表达的变化。具有相似片段移动的重排表现出相似的基因表达变化。最极端的重排导致复制原点和终点之间出现巨大的不平衡,并且随着向复制原点移动或远离复制原点的距离因子的增加,基因表达也出现差异。基因组结构变异可能是细菌快速适应新环境的一种机制,值得与传统的核苷酸级变异措施一起进行常规评估。
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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Impact of Salmonella genome rearrangement on gene expression.

In addition to nucleotide variation, many bacteria also undergo changes at a much larger scale via rearrangement of their genome structure (GS) around long repeat sequences. These rearrangements result in genome fragments shifting position and/or orientation in the genome without necessarily affecting the underlying nucleotide sequence. To date, scalable techniques have not been applied to GS identification, so it remains unclear how extensive this variation is and the extent of its impact upon gene expression. However, the emergence of multiplexed, long-read sequencing overcomes the scale problem, as reads of several thousand bases are routinely produced that can span long repeat sequences to identify the flanking chromosomal DNA, allowing GS identification. Genome rearrangements were generated in Salmonella enterica serovar Typhi through long-term culture at ambient temperature. Colonies with rearrangements were identified via long-range PCR and subjected to long-read nanopore sequencing to confirm genome variation. Four rearrangements were investigated for differential gene expression using transcriptomics. All isolates with changes in genome arrangement relative to the parent strain were accompanied by changes in gene expression. Rearrangements with similar fragment movements demonstrated similar changes in gene expression. The most extreme rearrangement caused a large imbalance between the origin and terminus of replication and was associated with differential gene expression as a factor of distance moved toward or away from the origin of replication. Genome structure variation may provide a mechanism through which bacteria can quickly adapt to new environments and warrants routine assessment alongside traditional nucleotide-level measures of variation.

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来源期刊
Evolution Letters
Evolution Letters EVOLUTIONARY BIOLOGY-
CiteScore
13.00
自引率
2.00%
发文量
35
审稿时长
10 weeks
期刊介绍: Evolution Letters publishes cutting-edge new research in all areas of Evolutionary Biology. Available exclusively online, and entirely open access, Evolution Letters consists of Letters - original pieces of research which form the bulk of papers - and Comments and Opinion - a forum for highlighting timely new research ideas for the evolutionary community.
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