模型革兰氏阴性菌对基因组重组反应的生理稳健性。

Pub Date : 2022-01-01 Epub Date: 2022-08-30 DOI:10.1159/000526651
Charles J Dorman, Matthew J Dorman
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引用次数: 2

摘要

DNA超卷绕和核相关蛋白(nap)是控制细菌基因组结构的两个因素,影响其包含的遗传信息的表达。DNA拓扑结构的改变,以及nap的数量和类型的改变,对基因表达有多效性影响,这表明DNA拓扑异构酶和/或nap的产生模式的改变可能会对细菌生理产生显著影响。编码这些蛋白质的基因的敲除突变(突变体仍然存活)会产生明显的生理效应。然而,涉及拓扑异构酶或NAP基因重新布线或重新定位的基因修饰会产生更微妙的结果。这些发现表明,面对基因组重排,细菌的高级调控回路是强大的,而基因组重排可能会先验地产生细菌生活方式的重大变化。基因组重组实验的例子,主要是用革兰氏阴性模型细菌大肠杆菌K-12和肠炎沙门氏菌血清型鼠伤寒杆菌进行的,将用来说明这些特征。研究结果不仅显示了天然细菌耐受调控性重组的能力,还表明了合成生物学实验设计的限度。
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Physiological Robustness of Model Gram-Negative Bacteria in Response to Genome Rewiring.

DNA supercoiling and nucleoid-associated proteins (NAPs) are two of the factors that govern the architecture of the bacterial genome, influencing the expression of the genetic information that it contains. Alterations to DNA topology, and to the numbers and types of NAPs, have pleiotropic effects on gene expression, suggesting that modifications to the production patterns of DNA topoisomerases and/or NAPs are likely to result in marked impacts on bacterial physiology. Knockout mutations in the genes encoding these proteins (where the mutants remain viable) result in clear physiological effects. However, genetic modifications that involve rewiring, or repositioning, of topoisomerase or NAP genes produce much more subtle outcomes. These findings demonstrate that the high-level regulatory circuitry of bacteria is robust in the face of genomic rearrangements that, a priori, might be expected to produce significant changes in bacterial lifestyle. Examples from genomic rewiring experiments, performed chiefly with the Gram-negative model bacteria Escherichia coli K-12 and Salmonella enterica serovar Typhimurium, will be used to illustrate these features. The results show not only the ability of naturally occurring bacteria to tolerate regulatory rewiring but also indicate the limits within which experiments in synthetic biology may be designed.

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