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产生翻译抑制剂微菌素C7所需的质粒基因的结构与组织

Structure and organization of plasmid genes required to produce the translation inhibitor microcin C7.

作者信息

González-Pastor J E, San Millán J L, Castilla M A, Moreno F

机构信息

Unidad de Genética Molecular, Hospital Ramón y Cajal, Madrid, Spain.

出版信息

J Bacteriol. 1995 Dec;177(24):7131-40. doi: 10.1128/jb.177.24.7131-7140.1995.

Abstract

The translation inhibitor microcin C7 (MccC7) is a linear heptapeptide whose N terminus has been replaced by an N-formyl group and whose C terminus has been replaced by the phosphodiester of 5'-adenylic acid and n-aminopropanol (J. I. Guijarro, J. E. González-Pastor, F. Baleux, J. L. San Millán, M. A. Castilla, M. Rico, F. Moreno, and M. Delepierre, J. Biol. Chem. 270:23520-23532, 1995). MccC7 production and immunity determinants lie on a 6.2-kb region of the Escherichia coli plasmid pMccC7. This region was entirely sequenced. It contains six open reading frames, which were shown to be true genes by different complementary approaches. Five genes, mccABCDE, which are transcribed in the same direction, are required to produce mature extracellular microcin. The sixth gene, mccF, adjacent to mccE, is transcribed in the opposite direction and encodes specific self-immunity. Genes mccA to -E constitute an operon transcribed from a promoter (mccp) located upstream of mccA. mccA is 21 nucleotides long and encodes the unmodified heptapeptide (J. E. González-Pastor, J. L. San Millán, and F. Moreno, Nature [London] 369:281, 1994). A comparison of predicted gene polypeptide products with those included in databases shows that an 81-amino-acid stretch of MccB is strikingly homologous to fragments of the same length of proteins ThiF and ChlN from E. coli, HesA from Anabaena sp. strain PCC7120, and UBA1, the ubiquitin-activating enzyme from different eukaryotic species. MccC displays several hydrophobic domains, suggesting a transmembrane location. The carboxyl end of MccE displays 41.2% identity with RimL, a protein required to acetylate the ribosome protein L12 from E. coli. In the absence of the other mcc genes, mccA impairs the growth of host cells, suggesting that unmodified MccA has antibiotic activity. A model for MccC7 biosynthesis, export, and immunity is proposed.

摘要

翻译抑制剂微菌素C7(MccC7)是一种线性七肽,其N端被N-甲酰基取代,C端被5'-腺苷酸和n-氨基丙醇的磷酸二酯取代(J. I. 吉哈罗、J. E. 冈萨雷斯-帕斯托、F. 巴勒克斯、J. L. 圣米兰、M. A. 卡斯蒂利亚、M. 里科、F. 莫雷诺和M. 德莱皮埃尔,《生物化学杂志》270:23520 - 23532,1995年)。MccC7的产生和免疫决定簇位于大肠杆菌质粒pMccC7的一个6.2 kb区域。该区域已被完全测序。它包含六个开放阅读框,通过不同的互补方法证明这些阅读框是真正的基因。五个基因,mccABCDE,以相同方向转录,是产生成熟细胞外微菌素所必需的。第六个基因,mccF,与mccE相邻,以相反方向转录并编码特异性自身免疫。基因mccA至 -E构成一个从位于mccA上游的启动子(mccp)转录的操纵子。mccA长21个核苷酸,编码未修饰的七肽(J. E. 冈萨雷斯-帕斯托、J. L. 圣米兰和F. 莫雷诺,《自然》[伦敦]369:281,1994年)。将预测的基因多肽产物与数据库中包含的产物进行比较表明,MccB的一段81个氨基酸的序列与来自大肠杆菌的ThiF和ChlN、鱼腥藻属菌株PCC7120的HesA以及来自不同真核生物物种的泛素激活酶UBA1等蛋白质相同长度片段具有显著同源性。MccC显示出几个疏水结构域,表明其具有跨膜定位。MccE的羧基末端与RimL具有41.2%的同一性,RimL是一种使大肠杆菌核糖体蛋白L12乙酰化所需的蛋白质。在没有其他mcc基因的情况下,mccA会损害宿主细胞的生长,这表明未修饰的MccA具有抗生素活性。提出了一个MccC7生物合成、输出和免疫的模型。

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