Linking methanotroph phenotypes to genotypes using a simple spatially resolved model ecosystem

Delaney G Beals, Aaron W Puri
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Abstract

Connecting genes to phenotypic traits in bacteria is often challenging because of a lack of environmental context in laboratory settings. Laboratory-based model ecosystems offer a means to better account for environmental conditions compared to standard planktonic cultures, and can help link genotypes and phenotypes. Here, we present a simple, cost-effective, laboratory-based model ecosystem to study aerobic methane-oxidizing bacteria (methanotrophs) within the methane-oxygen counter gradient typically found in the natural environment of these organisms. Culturing the methanotroph Methylomonas sp. strain LW13 in this system resulted in formation of a distinct horizontal band at the intersection of the counter gradient, which we discovered was not due to increased numbers of bacteria at this location but instead to an increased amount of polysaccharides. We also discovered that different methanotrophic taxa form polysaccharide bands with distinct locations and morphologies when grown in the methane-oxygen counter gradient. By comparing transcriptomic data from LW13 growing within and surrounding this band, we identified genes upregulated within the band and validated their involvement in growth and band formation within the model ecosystem using knockout strains. Notably, deletion of these genes did not negatively affect growth using standard planktonic culturing methods. This work highlights the use of a laboratory-based model ecosystem that more closely mimics the natural environment to uncover bacterial phenotypes missing from standard laboratory conditions, and to link these phenotypes with their genetic determinants.
利用简单的空间分辨率模型生态系统将甲烷营养体表型与基因型联系起来
由于缺乏实验室环境背景,将细菌的基因与表型特征联系起来往往具有挑战性。与标准浮游生物培养物相比,基于实验室的模式生态系统能更好地反映环境条件,并有助于将基因型与表型联系起来。在这里,我们介绍了一种简单、经济、基于实验室的模型生态系统,用于研究这些生物自然环境中典型的甲烷-氧气反梯度条件下的需氧甲烷氧化细菌(甲烷嗜氧菌)。在该系统中培养甲烷营养菌 Methylomonas sp. 菌株 LW13,结果在逆梯度的交叉点上形成了一个明显的水平带,我们发现这并不是因为该位置的细菌数量增加,而是因为多糖的数量增加。我们还发现,不同的甲烷营养类群在甲烷-氧气反梯度中生长时,会形成位置和形态各异的多糖带。通过比较生长在多糖带内和周围的 LW13 的转录组数据,我们确定了多糖带内上调的基因,并利用基因敲除菌株验证了这些基因在模型生态系统中参与生长和多糖带形成的情况。值得注意的是,使用标准浮游生物培养方法,删除这些基因不会对生长产生负面影响。这项工作强调了利用更接近自然环境的实验室模型生态系统来发现标准实验室条件下缺失的细菌表型,并将这些表型与其遗传决定因素联系起来。
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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