动态的流体景观有助于细菌的传播

Divakar Badal, Aloke Kumar, Varsha Singh, Danny Raj M
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摘要

微生物相互作用调节它们在竞争环境中的传播和生存。目前尚不清楚环境的物理参数是否调节了这些相互作用的结果。在这项工作中,我们表明机会性病原体铜绿假单胞菌在酵母菌(如新型隐球菌)存在的基质上占据了比没有酵母菌的更大的面积。在显微镜下,细菌细胞在酵母细胞附近表现出增强的活性。我们观察到这种行为,甚至当活酵母细胞被热杀死的细胞或类似形态的球形玻璃珠取代时,这表明观察到的行为不是微生物生物学所特有的。经过仔细的研究,我们发现在酵母细胞周围形成了液体池,这有利于有鞭毛的铜绿假单胞菌的游动,使其运动性增强。利用数学模型,我们证明了细菌运动的局部增强如何导致在平板水平上观察到的传播增强。我们发现,在生长的酵母草坪的介导下,细菌周围流体景观的动态影响了传播。例如,当酵母草坪生长得更快时,细菌菌落倾向于较低的酵母细胞初始负荷,以最佳地增强传播。我们用不同初始成分的念珠菌和新生念珠菌证实了我们的预测。总之,我们的工作显示了在复杂环境中研究细菌运动时考虑动态变化的物理环境的重要性。
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A dynamic fluid landscape mediates the spread of bacteria
Microbial interactions regulate their spread and survival in competitive environments. It is not clear if the physical parameters of the environment regulate the outcome of these interactions. In this work, we show that the opportunistic pathogen Pseudomonas aeruginosa occupies a larger area on the substratum in the presence of yeast such as Cryptococcus neoformans , than without it. At the microscopic level, bacterial cells show an enhanced activity in the vicinity of yeast cells. We observe this behaviour even when the live yeast cells are replaced with heat-killed cells or with spherical glass beads of similar morphology, which suggests that the observed behaviour is not specific to the biology of microbes. Upon careful investigation, we find that a fluid pool is formed around yeast cells which facilitates the swimming of the flagellated P. aeruginosa , causing their enhanced motility. Using mathematical modeling we demonstrate how this local enhancement of bacterial motility leads to the enhanced spread observed at the level of the plate. We find that the dynamics of the fluid landscape around the bacteria, mediated by the growing yeast lawn, affects the spreading. For instance, when the yeast lawn grows faster, a bacterial colony prefers a lower initial loading of yeast cells for optimum enhancement in the spread. We confirm our predictions using Candida albicans and C. neoformans, at different initial compositions. In summary, our work shows the importance of considering the dynamically changing physical environment while studying bacterial motility in complex environments.
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