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组成型系统的进一步诱导性:半乳糖操纵子的超诱导

Further inducibility of a constitutive system: ultrainduction of the gal operon.

作者信息

Tokeson J P, Garges S, Adhya S

机构信息

Laboratory of Molecular Biology, National Cancer Institute, National Institutes of Health, Bethesda, Maryland 20892.

出版信息

J Bacteriol. 1991 Apr;173(7):2319-27. doi: 10.1128/jb.173.7.2319-2327.1991.

DOI:10.1128/jb.173.7.2319-2327.1991
PMID:2007555
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC207785/
Abstract

In wild-type Escherichia coli, expression of the gal operon is negatively regulated by the Gal repressor and is induced 10- to 15-fold when the repressor is inactivated by an inducer. In strains completely deleted for galR, the gene which encodes the Gal repressor, the operon is derepressed by only 10-fold without an inducer. But this derepression is increased further by threefold during cell growth in the presence of an inducer, D-galactose or D-fucose. This phenomenon of extreme induction in the absence of Gal repressor is termed ultrainduction--a manifestation of further inducibility in a constitutive setup. Construction and characterization of gene and operon fusion strains between galE and lacZ, encoding beta-galactosidase as a reporter gene, show that ultrainduction occurs at the level of transcription and not translation. Transcription of the operon, from both the cyclic AMP-dependent P1 and the cyclic nucleotide-independent P2 promoters, is subject to ultrainduction. The wild-type galR+ gene has an epistatic effect on ultrainducibility: ultrainduction is observed only in cells devoid of Gal repressor protein. Titration experiments show the existence of an ultrainducibility factor that acts like a repressor and functions by binding to DNA segments (operators) to which Gal repressor also binds to repress the operon.

摘要

在野生型大肠杆菌中,半乳糖操纵子的表达受半乳糖阻遏物负调控,当阻遏物被诱导剂失活时,其表达会被诱导10至15倍。在完全缺失编码半乳糖阻遏物的基因galR的菌株中,即使没有诱导剂,操纵子的阻遏也仅解除10倍。但是,在存在诱导剂D-半乳糖或D-岩藻糖的情况下,细胞生长过程中这种阻遏的解除会进一步增加三倍。在没有半乳糖阻遏物的情况下这种极端诱导的现象被称为超诱导——这是组成型状态下进一步可诱导性的一种表现。构建并表征了galE与编码β-半乳糖苷酶作为报告基因的lacZ之间的基因和操纵子融合菌株,结果表明超诱导发生在转录水平而非翻译水平。操纵子从依赖环磷酸腺苷的P1启动子和不依赖环核苷酸的P2启动子转录时,均会受到超诱导。野生型galR⁺基因对超诱导具有上位效应:仅在缺乏半乳糖阻遏蛋白的细胞中观察到超诱导。滴定实验表明存在一种超诱导因子,其作用类似于阻遏物,通过与半乳糖阻遏物也结合以阻遏操纵子的DNA片段(操纵基因)结合而起作用。

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