National Centre for Biological Sciences, Bangalore, India.
National Centre for Biological Sciences, Bangalore, India
mSphere. 2020 Apr 15;5(2):e00092-20. doi: 10.1128/mSphere.00092-20.
populations undergo repeated replacement of parental genotypes with fitter variants deep in stationary phase. We isolated one such variant, which emerged after 3 weeks of maintaining an K-12 population in stationary phase. This variant displayed a small colony phenotype and slow growth and was able to outcompete its ancestor over a narrow time window in stationary phase. The variant also shows tolerance to beta-lactam antibiotics, though not previously exposed to the antibiotic. We show that an RpoC(A494V) mutation confers the slow growth and small colony phenotype on this variant. The ability of this mutation to confer a growth advantage in stationary phase depends on the availability of the stationary-phase sigma factor σ The RpoC(A494V) mutation upregulates the σ regulon. As shown over 20 years ago, early in prolonged stationary phase, σ attenuation, but not complete loss of activity, confers a fitness advantage. Our study shows that later mutations enhance σ activity, either by mutating the gene for σ directly or via mutations such as RpoC(A494V). The balance between the activities of the housekeeping major sigma factor and σ sets up a trade-off between growth and stress tolerance, which is tuned repeatedly during prolonged stationary phase. An important general mechanism of a bacterium's adaptation to its environment involves adjusting the balance between growing fast and tolerating stresses. One paradigm where this plays out is in prolonged stationary phase: early studies showed that attenuation, but not complete elimination, of the general stress response enables early adaptation of the bacterium to the conditions established about 10 days into stationary phase. We show here that this balance is not static and that it is tilted back in favor of the general stress response about 2 weeks later. This can be established by direct mutations in the master regulator of the general stress response or by mutations in the core RNA polymerase enzyme itself. These conditions can support the development of antibiotic tolerance although the bacterium is not exposed to the antibiotic. Further exploration of the growth-stress balance over the course of stationary phase will necessarily require a deeper understanding of the events in the extracellular milieu.
在稳定期,种群会反复用适应性更强的变异体替代亲代基因型。我们分离到了这样一个变异体,它是在维持 K-12 种群处于稳定期 3 周后出现的。该变异体表现出小菌落表型和生长缓慢的特征,并且能够在稳定期的一个狭窄时间窗口内与祖先竞争。该变异体对β-内酰胺类抗生素也有耐受性,尽管它以前没有接触过这种抗生素。我们表明,RpoC(A494V)突变赋予了该变异体生长缓慢和小菌落表型的特征。这种突变在稳定期赋予生长优势的能力取决于稳定期σ因子σ的可用性。RpoC(A494V)突变上调了σ调控基因。正如 20 多年前所示,在长时间的稳定期早期,σ衰减而不是完全丧失活性赋予了适应性优势。我们的研究表明,后期的突变通过直接突变σ基因或通过 RpoC(A494V)等突变来增强σ的活性。管家主要σ因子和σ之间的活性平衡在生长和应激耐受性之间建立了一种权衡,这种权衡在长时间的稳定期中反复进行调整。细菌适应环境的一个重要一般机制涉及调整快速生长和耐受压力之间的平衡。这种情况的一个范例是在长时间的稳定期中:早期的研究表明,衰减而不是完全消除一般应激反应使细菌能够在大约 10 天进入稳定期后适应环境。我们在这里表明,这种平衡不是静态的,大约 2 周后,它又向一般应激反应倾斜。这种平衡可以通过直接突变一般应激反应的主调控因子或核心 RNA 聚合酶本身的突变来建立。尽管细菌没有接触抗生素,但这些条件可以支持抗生素耐受性的发展。进一步探索稳定期中的生长-应激平衡必然需要更深入地了解细胞外环境中的事件。
