大肠杆菌的cheA、cheB和cheC基因及其在趋化作用中的作用。
cheA, cheB, and cheC genes of Escherichia coli and their role in chemotaxis.
作者信息
Parkinson J S
出版信息
J Bacteriol. 1976 May;126(2):758-70. doi: 10.1128/jb.126.2.758-770.1976.
Abstract
Motile but generally nonchemotatic (che) mutants of Escherichia coli were isolated by a simple screening method. A total of 172 independent mutants were examined, and four genes were defined on the basis of mapping and complemenvestigated by determining their null phenotypes with nonsense or bacteriophage Mu-induced mutations. The cheA and cheB products were essential in producing changes of swimming direction and flagellar rotation. The checC product appeared to be an essential component of the flagellum; however, specific mutational alterations of this component allowed flagellar assembly but prevented directional changes in swimming. Since some cheB mutants changed directions incessantly, this gene product may also serve to control the direction of flagellar rotation in response to chemoreceptor signals. Thus most or all of the common elements in the signalling process were involved in the generation and regulation of changes in the direction of flagellar rotation.
摘要
通过一种简单的筛选方法分离出了大肠杆菌的运动但通常无趋化性(che)的突变体。共检测了172个独立突变体,并根据定位和互补情况定义了四个基因,通过用无义突变或噬菌体Mu诱导的突变确定其无效表型来进行研究。cheA和cheB产物对于产生游动方向和鞭毛旋转的变化至关重要。cheC产物似乎是鞭毛的一个必需成分;然而,该成分的特定突变改变允许鞭毛组装,但阻止了游动方向的改变。由于一些cheB突变体不断改变方向,该基因产物可能也用于响应化学感受器信号来控制鞭毛旋转的方向。因此,信号传导过程中的大多数或所有共同元件都参与了鞭毛旋转方向变化的产生和调节。
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