导致不依赖配体的转录激活和ATP水解的fhlA突变的特征分析。
Characterization of fhlA mutations resulting in ligand-independent transcriptional activation and ATP hydrolysis.
作者信息
Korsa I, Böck A
机构信息
Lehrstuhl für Mikrobiologie der Universität München, Munich, Germany.
出版信息
J Bacteriol. 1997 Jan;179(1):41-5. doi: 10.1128/jb.179.1.41-45.1997.
Abstract
The FhlA protein belongs to the NtrC family of transcriptional regulators. It induces transcription from the -12/-24 promoters of the genes of the formate regulon by sigma54 RNA polymerase. FhlA is activated by binding of the ligand formate and does not require phosphorylation. A mutational analysis of the fhLA gene portion coding for the A and C domains was conducted with the aim of gaining information on the interaction between formate binding and ATP hydrolysis plus transcription activation. Four mutations were identified, all located in the A domain; one of them rendered transcription completely independent from the presence of formate, and the others conferred a semiconstitutive phenotype. The FhlA protein of one of the semiconstitutive variants was purified. Catalytic efficiency of ATP hydrolysis of the mutant FhlA was increased in the absence of formate in the same manner as formate influences the activity of wild-type FhlA. Moreover, in vitro transcription occurred at much lower threshold concentrations of the mutant protein and of nucleoside triphosphates than with the wild-type FhlA.
摘要
FhlA蛋白属于转录调节因子的NtrC家族。它通过σ54 RNA聚合酶诱导甲酸调节子基因的-12 / -24启动子转录。FhlA通过配体甲酸的结合而被激活,且不需要磷酸化。为了获取有关甲酸结合与ATP水解以及转录激活之间相互作用的信息,对编码A和C结构域的fhLA基因部分进行了突变分析。鉴定出四个突变,均位于A结构域;其中一个使转录完全独立于甲酸的存在,其他的则赋予半组成型表型。纯化了其中一个半组成型变体的FhlA蛋白。在没有甲酸的情况下,突变型FhlA的ATP水解催化效率以与甲酸影响野生型FhlA活性相同的方式增加。此外,与野生型FhlA相比,突变蛋白和核苷三磷酸在低得多的阈值浓度下即可发生体外转录。
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