Co-Existence Slows Diversification in Experimental Populations of E. coli and P. fluorescens

IF 4.3 2区生物学 Q2 MICROBIOLOGY

Environmental microbiology Pub Date : 2025-02-23 DOI:10.1111/1462-2920.70061

Gareth Howells, Aysha L. Sezmis, Christopher Blake, Michael J. McDonald

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Abstract

Microbes grown in heterogeneous laboratory environments can rapidly diversify into multiple, coexisting variants. While the genetic and evolutionary mechanisms of laboratory adaptive radiations are well studied, how the presence of other species alters the outcomes of diversification is less well understood. To test the effect of co-culture growth on the Pseudomonas fluorescens SBW25 adaptive radiation, Escherichia coli and P. fluorescens were cultured in monoculture and co-culture for 8 weeks. In P. fluorescens monoculture, Wrinkly and Smooth Spreader types rapidly evolved and were maintained over 8 weeks, while E. coli monocultures evolved two colony types, a big and a small colony variant. In contrast, we found that in co-culture, E. coli did not evolve small colony variants. Whole genome sequencing revealed the genetic basis of possible co-culture specific adaptations in both E. coli and P. fluorescens. Altogether, our data support that the presence of multiple species changed the outcome of adaptive radiation.

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共存减缓了大肠杆菌和荧光杆菌实验群体的多样化

在异质实验室环境中生长的微生物可以迅速分化成多种共存的变体。虽然实验室适应性辐射的遗传和进化机制已经得到了很好的研究，但其他物种的存在如何改变多样化的结果却知之甚少。为了检验共培养对荧光假单胞菌SBW25适应性辐射的影响，将大肠杆菌和荧光假单胞菌分别进行单培养和共培养8周。在单培养的荧光假单胞菌中，皱纹型和平滑型菌落进化迅速，并维持了8周以上，而大肠杆菌单培养则进化出两种菌落类型，一个大菌落变体和一个小菌落变体。相比之下，我们发现在共培养中，大肠杆菌没有进化出小菌落变异。全基因组测序揭示了大肠杆菌和荧光杆菌可能的共培养特异性适应的遗传基础。总之，我们的数据支持多物种的存在改变了适应性辐射的结果。

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

Environmental microbiology 环境科学-微生物学

CiteScore

9.90

自引率

3.90%

发文量

427

审稿时长

2.3 months

期刊介绍： Environmental Microbiology provides a high profile vehicle for publication of the most innovative, original and rigorous research in the field. The scope of the Journal encompasses the diversity of current research on microbial processes in the environment, microbial communities, interactions and evolution and includes, but is not limited to, the following: the structure, activities and communal behaviour of microbial communities microbial community genetics and evolutionary processes microbial symbioses, microbial interactions and interactions with plants, animals and abiotic factors microbes in the tree of life, microbial diversification and evolution population biology and clonal structure microbial metabolic and structural diversity microbial physiology, growth and survival microbes and surfaces, adhesion and biofouling responses to environmental signals and stress factors modelling and theory development pollution microbiology extremophiles and life in extreme and unusual little-explored habitats element cycles and biogeochemical processes, primary and secondary production microbes in a changing world, microbially-influenced global changes evolution and diversity of archaeal and bacterial viruses new technological developments in microbial ecology and evolution, in particular for the study of activities of microbial communities, non-culturable microorganisms and emerging pathogens