Evolution recovers the fitness of Acinetobacter baylyi strains with large deletions through mutations in deletion-specific targets and global post-transcriptional regulators.

IF 4 2区 生物学 Q1 GENETICS & HEREDITY
PLoS Genetics Pub Date : 2024-09-16 eCollection Date: 2024-09-01 DOI:10.1371/journal.pgen.1011306
Isaac Gifford, Gabriel A Suárez, Jeffrey E Barrick
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引用次数: 0

Abstract

Organelles and endosymbionts have naturally evolved dramatically reduced genome sizes compared to their free-living ancestors. Synthetic biologists have purposefully engineered streamlined microbial genomes to create more efficient cellular chassis and define the minimal components of cellular life. During natural or engineered genome streamlining, deletion of many non-essential genes in combination often reduces bacterial fitness for idiosyncratic or unknown reasons. We investigated how and to what extent laboratory evolution could overcome these defects in six variants of the transposon-free Acinetobacter baylyi strain ADP1-ISx that each had a deletion of a different 22- to 42-kilobase region and two strains with larger deletions of 70 and 293 kilobases. We evolved replicate populations of ADP1-ISx and each deletion strain for ~300 generations in a chemically defined minimal medium or a complex medium and sequenced the genomes of endpoint clonal isolates. Fitness increased in all cases that were examined except for two ancestors that each failed to improve in one of the two environments. Mutations affecting nine protein-coding genes and two small RNAs were significantly associated with one of the two environments or with certain deletion ancestors. The global post-transcriptional regulators rnd (ribonuclease D), csrA (RNA-binding carbon storage regulator), and hfq (RNA-binding protein and chaperone) were frequently mutated across all strains, though the incidence and effects of these mutations on gene function and bacterial fitness varied with the ancestral deletion and evolution environment. Mutations in this regulatory network likely compensate for how an earlier deletion of a transposon in the ADP1-ISx ancestor of all the deletion strains restored csrA function. More generally, our results demonstrate that fitness lost during genome streamlining can usually be regained rapidly through laboratory evolution and that recovery tends to occur through a combination of deletion-specific compensation and global regulatory adjustments.

通过缺失特异性靶标和全局转录后调控因子的突变,进化恢复了具有大量缺失的巴氏不动杆菌菌株的适应性。
与自由生活的祖先相比,细胞器和内共生体在自然进化过程中的基因组体积大幅缩小。合成生物学家有目的地设计精简的微生物基因组,以创建更高效的细胞底盘,并确定细胞生命的最小组成部分。在自然或工程基因组精简过程中,许多非必要基因的联合删除往往会因特殊或未知原因降低细菌的适应性。我们研究了实验室进化如何以及在多大程度上可以克服无转座子的刺胞杆菌菌株 ADP1-ISx 的这些缺陷,该菌株的六个变体分别缺失了 22 至 42 千碱基的不同区域,还有两个菌株缺失了 70 和 293 千碱基的更大区域。我们在化学定义的最小培养基或复合培养基中对 ADP1-ISx 和每个缺失菌株的重复群体进行了约 300 代的进化,并对终点克隆分离物的基因组进行了测序。除了两个祖先在两种环境中的一种环境中都没有得到改善外,所有被检测的情况下的适合度都有所提高。影响九个蛋白编码基因和两个小 RNA 的突变与两种环境中的一种或某些缺失祖先显著相关。全球转录后调控因子 rnd(核糖核酸酶 D)、csrA(RNA 结合碳储存调控因子)和 hfq(RNA 结合蛋白和伴侣蛋白)在所有菌株中频繁发生突变,但这些突变的发生率及其对基因功能和细菌适应性的影响随祖先缺失和进化环境的不同而不同。这一调控网络中的突变很可能弥补了所有缺失菌株的 ADP1-ISx 祖先中一个转座子的早期缺失是如何恢复 csrA 功能的。更广泛地说,我们的研究结果表明,在基因组精简过程中丧失的适应性通常可以通过实验室进化迅速恢复,而且恢复往往是通过缺失特异性补偿和全局调控调整相结合的方式实现的。
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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来源期刊
PLoS Genetics
PLoS Genetics GENETICS & HEREDITY-
自引率
2.20%
发文量
438
期刊介绍: PLOS Genetics is run by an international Editorial Board, headed by the Editors-in-Chief, Greg Barsh (HudsonAlpha Institute of Biotechnology, and Stanford University School of Medicine) and Greg Copenhaver (The University of North Carolina at Chapel Hill). Articles published in PLOS Genetics are archived in PubMed Central and cited in PubMed.
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