超突变体在实验大肠杆菌群体中的出现是依赖于压力类型的。

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Martijn Callens, Caroline J Rose, Michael Finnegan, François Gatchitch, Léna Simon, Jeanne Hamet, Léa Pradier, Marie-Pierre Dubois, Stéphanie Bedhomme
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引用次数: 0

摘要

表现出更高突变率的基因型,称为超突变体,可以在微生物种群中繁殖,因为它们具有优势,因为适应所需的有益突变供应更多。虽然这是在自然和实验室种群中经常观察到的现象,但对诸如适应不良程度、应激强度和适应的遗传结构等参数对超突变体出现的影响知之甚少。为了解决这一知识差距,我们测量了暴露于不同水平渗透或抗生素胁迫下的实验大肠杆菌种群中超过1000代的超突变体的出现。我们选择的压力类型是基于它们之间适应的遗传结构不同的假设。事实上,我们表明,与抗生素胁迫相比,渗透胁迫适应的遗传基础的大小更大。在我们的实验中,我们观察到在暴露于渗透胁迫的人群中超突变体的出现增加,而在暴露于抗生素胁迫的人群中则没有,这表明超突变体的出现率与胁迫类型有关。这些结果支持了我们的假设,即超突变体的出现与适应的遗传基础的大小有关。此外,我们还确定了与应激类型(应激水平和IS转位率)共变的其他参数,这些参数可能有助于增加超突变体的供应和选择。我们的研究结果首次比较了不同胁迫条件下的超突变体出现率,并指出了多种胁迫相关因素对突变率进化的复杂相互作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Hypermutator emergence in experimental <i>Escherichia coli</i> populations is stress-type dependent.

Hypermutator emergence in experimental <i>Escherichia coli</i> populations is stress-type dependent.

Hypermutator emergence in experimental <i>Escherichia coli</i> populations is stress-type dependent.

Hypermutator emergence in experimental Escherichia coli populations is stress-type dependent.

Genotypes exhibiting an increased mutation rate, called hypermutators, can propagate in microbial populations because they can have an advantage due to the higher supply of beneficial mutations needed for adaptation. Although this is a frequently observed phenomenon in natural and laboratory populations, little is known about the influence of parameters such as the degree of maladaptation, stress intensity, and the genetic architecture for adaptation on the emergence of hypermutators. To address this knowledge gap, we measured the emergence of hypermutators over ~1,000 generations in experimental Escherichia coli populations exposed to different levels of osmotic or antibiotic stress. Our stress types were chosen based on the assumption that the genetic architecture for adaptation differs between them. Indeed, we show that the size of the genetic basis for adaptation is larger for osmotic stress compared to antibiotic stress. During our experiment, we observed an increased emergence of hypermutators in populations exposed to osmotic stress but not in those exposed to antibiotic stress, indicating that hypermutator emergence rates are stress type dependent. These results support our hypothesis that hypermutator emergence is linked to the size of the genetic basis for adaptation. In addition, we identified other parameters that covaried with stress type (stress level and IS transposition rates) that might have contributed to an increased hypermutator provision and selection. Our results provide a first comparison of hypermutator emergence rates under varying stress conditions and point towards complex interactions of multiple stress-related factors on the evolution of mutation rates.

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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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