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β-葡萄糖苷利用操纵子的调节因子AscG参与丙酸分解代谢操纵子的调节。

Participation of regulator AscG of the beta-glucoside utilization operon in regulation of the propionate catabolism operon.

作者信息

Ishida Yuji, Kori Ayako, Ishihama Akira

机构信息

Department of Frontier Bioscience, Hosei University, Tokyo, Japan.

出版信息

J Bacteriol. 2009 Oct;191(19):6136-44. doi: 10.1128/JB.00663-09. Epub 2009 Jul 24.

DOI:10.1128/JB.00663-09
PMID:19633077
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2747900/
Abstract

The asc operon of Escherichia coli is one of the cryptic genetic systems for beta-D-galactoside utilization as a carbon source. The ascFB genes for beta-D-galactoside transport and catabolism are repressed by the AscG regulator. After genomic SELEX screening, AscG was found to recognize and bind the consensus palindromic sequence TGAAACC-GGTTTCA. AscG binding was detected at two sites upstream of the ascFB promoter and at three sites upstream of the prpBC operon for propionate catabolism. In an ascG-disrupted mutant, transcription of ascFB was enhanced, in agreement with the repressor model of AscG. This repression was indicated to be due to interference of binding of cyclic AMP-CRP to the CRP box, which overlaps with the AscG-binding site 1, as well as binding of RNA polymerase to the promoter. Under conditions of steady-state E. coli growth in a rich medium, the intracellular level of AscG stayed constant at a level supposedly leading to tight repression of the ascFB operon. The level of prpR, encoding the activator of prpBCDE, was also increased in the absence of AscG, indicating the involvement of AscG in repression of prpR. Taken together, these data suggest a metabolic link through interplay between the asc and prp operons.

摘要

大肠杆菌的asc操纵子是利用β-D-半乳糖苷作为碳源的隐秘遗传系统之一。用于β-D-半乳糖苷转运和分解代谢的ascFB基因受到AscG调节因子的抑制。经过基因组SELEX筛选,发现AscG能够识别并结合共有回文序列TGAAACC-GGTTTCA。在ascFB启动子上游的两个位点以及用于丙酸盐分解代谢的prpBC操纵子上游的三个位点检测到了AscG的结合。在ascG缺失突变体中,ascFB的转录增强,这与AscG的阻遏模型一致。这种抑制作用表明是由于环腺苷酸-CRP与CRP框的结合受到干扰,该CRP框与AscG结合位点1重叠,以及RNA聚合酶与启动子的结合受到干扰。在富含培养基中大肠杆菌稳态生长的条件下,AscG的细胞内水平保持恒定,这一水平可能导致对ascFB操纵子的紧密抑制。在没有AscG的情况下,编码prpBCDE激活剂的prpR水平也有所增加,表明AscG参与了对prpR的抑制。综上所述,这些数据表明asc操纵子和prp操纵子之间通过相互作用存在代谢联系。

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