Surface conversion of the dynamics of bacteria escaping chemorepellents

IF 1.8 4区 物理与天体物理 Q4 CHEMISTRY, PHYSICAL
Asma Braham, Laurence Lemelle, Romain Ducasse, Houyem Toukabri, Eleonore Mottin, Benoit Fabrèges, Vincent Calvez, Christophe Place
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Abstract

Flagellar swimming hydrodynamics confers a recognized advantage for attachment on solid surfaces. Whether this motility further enables the following environmental cues was experimentally explored. Motile E. coli (OD ~ 0.1) in a 100 µm-thick channel were exposed to off-equilibrium gradients set by a chemorepellent Ni(NO3)2-source (250 mM). Single bacterial dynamics at the solid surface was analyzed by dark-field videomicroscopy at a fixed position. The number of bacteria indicated their congregation into a wave escaping from the repellent source. Besides the high velocity drift in the propagation direction within the wave, an unexpectedly high perpendicular component drift was also observed. Swimming hydrodynamics CW-bends the bacteria trajectories during their primo approach to the surface (< 2 µm), and a high enough tumbling frequency likely preserves a notable lateral drift. This comprehension substantiates a survival strategy tailored to toxic environments, which involves drifting along surfaces, promoting the inception of colonization at the most advantageous sites.

Abstract Image

细菌逃逸化合剂动态的表面转换
摘要鞭毛虫的游动流体力学为其附着在固体表面提供了公认的优势。实验探究了这种运动性是否能进一步使其跟随环境线索。在一个 100 µm 厚的通道中,运动的大肠杆菌(OD ~ 0.1)暴露在由趋化性 Ni(NO3)2 源(250 mM)设定的非平衡梯度下。在固定位置通过暗视野显微镜分析固体表面单个细菌的动态。细菌的数量表明它们聚集成一个波逃离了斥力源。除了波内传播方向的高速漂移外,还观察到了意想不到的高垂直分量漂移。游动的流体力学使细菌在接近表面(2 微米)时的运动轨迹发生 CW 弯曲,而足够高的翻滚频率很可能会保持显著的横向漂移。这种理解证实了一种适应有毒环境的生存策略,即沿着表面漂移,促进在最有利的地点开始定殖。
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来源期刊
The European Physical Journal E
The European Physical Journal E CHEMISTRY, PHYSICAL-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
2.60
自引率
5.60%
发文量
92
审稿时长
3 months
期刊介绍: EPJ E publishes papers describing advances in the understanding of physical aspects of Soft, Liquid and Living Systems. Soft matter is a generic term for a large group of condensed, often heterogeneous systems -- often also called complex fluids -- that display a large response to weak external perturbations and that possess properties governed by slow internal dynamics. Flowing matter refers to all systems that can actually flow, from simple to multiphase liquids, from foams to granular matter. Living matter concerns the new physics that emerges from novel insights into the properties and behaviours of living systems. Furthermore, it aims at developing new concepts and quantitative approaches for the study of biological phenomena. Approaches from soft matter physics and statistical physics play a key role in this research. The journal includes reports of experimental, computational and theoretical studies and appeals to the broad interdisciplinary communities including physics, chemistry, biology, mathematics and materials science.
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