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大肠杆菌Trg和Tap化学感受器的驱避反应功能

Repellent response functions of the Trg and Tap chemoreceptors of Escherichia coli.

作者信息

Yamamoto K, Macnab R M, Imae Y

机构信息

Department of Molecular Biology, Faculty of Science, Nagoya University, Japan.

出版信息

J Bacteriol. 1990 Jan;172(1):383-8. doi: 10.1128/jb.172.1.383-388.1990.

DOI:10.1128/jb.172.1.383-388.1990
PMID:2403544
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC208443/
Abstract

The chemoreceptors responsible for the repellent response of Escherichia coli to phenol were investigated. In the absence of all four known methyl-accepting chemoreceptors (Tar, Tsr, Trg, and Tap), cells showed no response to phenol. However, when Trg, which mediates the attractant response to ribose and galactose, was introduced via a plasmid, the cells acquired a repellent response to phenol. About 1 mM phenol induced a clear repellent response; this response was suppressed by 1 mM ribose. Thus, Trg mediates the repellent response to phenol. Mutant Trg proteins with altered sensing for ribose and galactose showed a normal response to phenol, indicating that the interaction site for phenol differs from that for the ribose- and galactose-binding proteins. Tap, which mediates the attractant response to dipeptides, mediated a weaker repellent response to phenol. Tsr, which mediates the attractant response to serine, mediated an even weaker response to phenol. Trg and Tap were also found to function as intracellular pH sensors. Upon a pH decrease, Trg mediated an attractant response, whereas Tap mediated a repellent response. These results indicate that all the receptors in E. coli have dual functions, mediating both attractant and repellent responses.

摘要

对负责大肠杆菌对苯酚驱避反应的化学感受器进行了研究。在缺乏所有四种已知的甲基接受化学感受器(Tar、Tsr、Trg和Tap)的情况下,细胞对苯酚无反应。然而,当通过质粒导入介导对核糖和半乳糖吸引反应的Trg时,细胞获得了对苯酚的驱避反应。约1 mM苯酚诱导出明显的驱避反应;该反应被1 mM核糖抑制。因此,Trg介导对苯酚的驱避反应。对核糖和半乳糖传感改变的Trg突变蛋白对苯酚显示出正常反应,表明苯酚的相互作用位点与核糖和半乳糖结合蛋白的不同。介导对二肽吸引反应的Tap介导对苯酚较弱的驱避反应。介导对丝氨酸吸引反应的Tsr介导对苯酚更弱的反应。还发现Trg和Tap可作为细胞内pH传感器。pH降低时,Trg介导吸引反应,而Tap介导驱避反应。这些结果表明大肠杆菌中的所有感受器都具有双重功能,介导吸引和驱避反应。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/79ee/208443/bbb3fd1ffcec/jbacter01043-0408-a.jpg

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