大肠杆菌转录调控适应的多样性。

IF 11 1区 生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY
Christopher Dalldorf, Ying Hefner, Richard Szubin, Josefin Johnsen, Elsayed Mohamed, Gaoyuan Li, Jayanth Krishnan, Adam M Feist, Bernhard O Palsson, Daniel C Zielinski
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引用次数: 0

摘要

细菌中的转录调控网络(TRN)被认为会随着选择压力的变化而快速进化,从而调节转录因子(TF)的活性和相互作用。为了探究围绕转录调控网络短期适应性的限制和机制,我们在大肠杆菌中产生、进化并鉴定了根据在葡萄糖最小培养基上测量的生长影响选出的 11 种调控因子的基因敲除(KO)菌株。除一个基因敲除菌株(Δlrp)外,其他所有菌株都能恢复生长,而且只需要很少的趋同突变。我们发现,TF 基因敲除适应性可分为四类:1)菌株(ΔargR、ΔbasR、Δlon、ΔzntR、Δzur)在恢复生长过程中没有发生任何调控因子特异性适应,这可能是由于调控因子对生长条件的影响极小;2)菌株(ΔcytR、ΔmlrA、ΔybaO)在恢复生长过程中没有发生 TF 特异性突变,但与 KO'ed TF 有重叠调控子的调控因子有不同的表达、3)利用其调控网络(包括受调控的启动子和连接的调控因子)中的趋同突变恢复生长的菌株(Δcrp、Δfur);以及 4)无法完全恢复生长的菌株(Δlrp),这似乎是由于 TF 在 TRN 中具有广泛的连接性。对进化和未进化菌株生长能力的分析表明,尽管缺乏特异性 TF 突变,但生长适应往往能恢复对不同基质的适应性。这项工作揭示了 TRN 适应机制的广度,并表明可以根据受干扰 TF 的网络和功能背景来预测这些机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Diversity of Transcriptional Regulatory Adaptation in E. coli.

The transcriptional regulatory network (TRN) in bacteria is thought to rapidly evolve in response to selection pressures, modulating transcription factor (TF) activities and interactions. In order to probe the limits and mechanisms surrounding the short-term adaptability of the TRN, we generated, evolved, and characterized knockout (KO) strains in Escherichia coli for 11 regulators selected based on measured growth impact on glucose minimal media. All but one knockout strain (Δlrp) were able to recover growth and did so requiring few convergent mutations. We found that the TF knockout adaptations could be divided into four categories: (i) Strains (ΔargR, ΔbasR, Δlon, ΔzntR, and Δzur) that recovered growth without any regulator-specific adaptations, likely due to minimal activity of the regulator on the growth condition, (ii) Strains (ΔcytR, ΔmlrA, and ΔybaO) that recovered growth without TF-specific mutations but with differential expression of regulators with overlapping regulons to the KO'ed TF, (iii) Strains (Δcrp and Δfur) that recovered growth using convergent mutations within their regulatory networks, including regulated promoters and connected regulators, and (iv) Strains (Δlrp) that were unable to fully recover growth, seemingly due to the broad connectivity of the TF within the TRN. Analyzing growth capabilities in evolved and unevolved strains indicated that growth adaptation can restore fitness to diverse substrates often despite a lack of TF-specific mutations. This work reveals the breadth of TRN adaptive mechanisms and suggests these mechanisms can be anticipated based on the network and functional context of the perturbed TFs.

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来源期刊
Molecular biology and evolution
Molecular biology and evolution 生物-进化生物学
CiteScore
19.70
自引率
3.70%
发文量
257
审稿时长
1 months
期刊介绍: Molecular Biology and Evolution Journal Overview: Publishes research at the interface of molecular (including genomics) and evolutionary biology Considers manuscripts containing patterns, processes, and predictions at all levels of organization: population, taxonomic, functional, and phenotypic Interested in fundamental discoveries, new and improved methods, resources, technologies, and theories advancing evolutionary research Publishes balanced reviews of recent developments in genome evolution and forward-looking perspectives suggesting future directions in molecular evolution applications.
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