通过渗透挑战使生长中的大肠杆菌细胞收缩。

Shrinkage of growing Escherichia coli cells by osmotic challenge.

作者信息

Koch A L

出版信息

J Bacteriol. 1984 Sep;159(3):919-24. doi: 10.1128/jb.159.3.919-924.1984.

DOI:10.1128/jb.159.3.919-924.1984

PMID:6384186

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC215747/

Abstract

The immediate response of growing Escherichia coli to changing external osmotic pressure was studied with stopped-flow turbidimetric measurements with a narrow-beam spectrophotometer. It is shown theoretically that in such a photometer rod-shaped bacteria have an apparent absorbance which is proportional to the inverse of the surface area. The apparent optical density, corrected for effects of alteration of the index of refraction of the medium, increased continuously as the external osmotic pressure was raised. Because of the short time scale of the measurements, the turbidity increases could result either from shrinkage of the cells or from plasmolysis, or both, but not from growth or metabolic adaptation. With low concentrations of pentose such that the external osmotic pressure was not greater than that inside the cells, plasmolysis would not occur and, consequently, only shrinkage of the previously stretched sacculus remains to account for the observed optical effects. Taking the osmotic pressure of the growing cells as 5 atmospheres (506 kPa), the turbidity changes correspond to the murein fabric having been stretched 20% beyond its unstressed equilibrium area during growth under the conditions used.

摘要

利用窄束分光光度计通过停流比浊法测量研究了生长中的大肠杆菌对外部渗透压变化的即时反应。从理论上表明，在这种光度计中，杆状细菌具有与表面积倒数成正比的表观吸光度。校正介质折射率变化影响后的表观光密度随着外部渗透压的升高而持续增加。由于测量的时间尺度较短，浊度增加可能是由于细胞收缩或质壁分离，或两者兼而有之，但不是由于生长或代谢适应。在戊糖浓度较低以至于外部渗透压不大于细胞内渗透压的情况下，不会发生质壁分离，因此，观察到的光学效应仅由先前伸展的细胞壁的收缩来解释。以生长中的细胞的渗透压为5个大气压（506千帕）计算，浊度变化对应于在所用条件下生长期间，胞壁质结构被拉伸至超出其无应力平衡面积20%。

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