在大肠杆菌K-12中携带己糖醛酸系统结构基因的特异性转导噬菌体的分离:exu区域
Isolation of specialized transducing bacteriophages carrying the structural genes of the hexuronate system in Escherichia coli K-12: exu region.
作者信息
Mata M, Delstanche M, Robert-Baudouy J
出版信息
J Bacteriol. 1978 Feb;133(2):549-57. doi: 10.1128/jb.133.2.549-557.1978.
Abstract
In Escherichia coli HfrH 58, isolated by Shimada et al., a heat-inducible phage has been integrated in a secondary attachment site. We have characterized tha nature of the lambda integration. The exuR regulatory gene is inactivated by prophage integration. Genetic and biochemical analysis indicated a gene order: uxaA-uxaC-exuT-(exuR')-lambdaNRAJ (exuR''). By induction of HfrH 58, one class of deletions extending into the exu region was obtained. Analysis of these deletions confirms the exu region topography and the regulatory mechanism of the hexuronate system previously described. It has been possible to regenerate a functional exuR gene by prophage exision. Various lambda transducing particles plaque-forming and defective transducing phages carrying the left part or the right part of the exu region, have been derived from the secondary site lysogen HfrH 58. A phage carrying the entire exuR region was constructed by a cross between these two types of phage. The construction and characterization of these exu transducing phages are presented.
摘要
在岛田等人分离出的大肠杆菌HfrH 58中,一个热诱导噬菌体已整合到一个二级附着位点。我们已经对λ整合的性质进行了表征。exuR调控基因因原噬菌体整合而失活。遗传和生化分析表明基因顺序为:uxaA - uxaC - exuT - (exuR') - λNRAJ (exuR'')。通过诱导HfrH 58,获得了一类延伸到exu区域的缺失。对这些缺失的分析证实了先前描述的exu区域拓扑结构和己糖醛酸系统的调控机制。通过原噬菌体切除有可能再生一个功能性的exuR基因。各种λ转导颗粒、形成噬菌斑的噬菌体以及携带exu区域左半部分或右半部分的缺陷转导噬菌体,均源自二级位点溶原菌HfrH 58。通过这两种类型噬菌体之间的杂交构建了一个携带整个exuR区域的噬菌体。本文介绍了这些exu转导噬菌体的构建和表征情况。
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