通过改变运动速度进行渗透压调节。

Osmotaxis in through changes in motor speed.

机构信息

Centre for Synthetic and Systems Biology, Institute of Cell Biology, School of Biological Sciences, University of Edinburgh, Edinburgh EH9 3FF, United Kingdom.

Scottish Universities Physics Alliance and School of Physics & Astronomy, University of Edinburgh, Edinburgh EH9 3FD, United Kingdom.

出版信息

Proc Natl Acad Sci U S A. 2017 Sep 19;114(38):E7969-E7976. doi: 10.1073/pnas.1620945114. Epub 2017 Sep 5.

DOI:10.1073/pnas.1620945114

PMID:28874571

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5617246/

Abstract

Bacterial motility, and in particular repulsion or attraction toward specific chemicals, has been a subject of investigation for over 100 years, resulting in detailed understanding of bacterial chemotaxis and the corresponding sensory network in many bacterial species. For most of the current understanding comes from the experiments with low levels of chemotactically active ligands. However, chemotactically inactive chemical species at concentrations found in the human gastrointestinal tract produce significant changes in osmotic pressure and have been shown to lead to taxis. To understand how these nonspecific physical signals influence motility, we look at the response of individual bacterial flagellar motors under stepwise changes in external osmolarity. We combine these measurements with a population swimming assay under the same conditions. Unlike for chemotactic response, a long-term increase in swimming/motor speeds is observed, and in the motor rotational bias, both of which scale with the osmotic shock magnitude. We discuss how the speed changes we observe can lead to steady-state bacterial accumulation.

摘要

细菌的运动性，特别是对特定化学物质的排斥或吸引，已经成为 100 多年来研究的课题，这导致了对许多细菌物种的细菌趋化性和相应的感觉网络的详细了解。目前的大部分理解来自于对低水平趋化性配体的实验。然而，在人类胃肠道中发现的浓度下，趋化性非活性化学物质会导致渗透压发生显著变化，并已被证明会导致趋化性。为了了解这些非特异性物理信号如何影响运动性，我们研究了在外部渗透压逐步变化下单个细菌鞭毛马达的反应。我们将这些测量结果与相同条件下的群体游动测定结合起来。与趋化性反应不同，观察到游动/马达速度的长期增加，以及马达旋转偏差，两者都与渗透压冲击幅度成正比。我们讨论了我们观察到的速度变化如何导致稳态细菌积累。

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