大肠杆菌RNA聚合酶在体内的亚基组装：α亚基氨基末端组装结构域的作用

Subunit assembly in vivo of Escherichia coli RNA polymerase: role of the amino-terminal assembly domain of alpha subunit.

作者信息

Kimura M, Ishihama A

机构信息

Department of Molecular Genetics, National Institute of Genetics, Shizuoka, Japan.

出版信息

Genes Cells. 1996 Jun;1(6):517-28. doi: 10.1046/j.1365-2443.1996.d01-258.x.

DOI:10.1046/j.1365-2443.1996.d01-258.x

PMID:9078382

Abstract

BACKGROUND

The RNA polymerase core enzyme of Escherichia coli is assembled in the sequence alpha--> alpha 2-->alpha 2 beta-->alpha 2 beta beta'. The amino-terminal domain down to residue 235 of the Escherichia coli RNA polymerase alpha subunit plays a key role in enzyme assembly. In vitro reconstitution studies from mutant alpha subunits have indicated the involvement of multiple sites for alpha dimerization, two regions (one near residue 45 and the other near residue 80) for beta' association, and two regions (one around residue 80 and the other between residues 180 and 200) for beta association. The mechanism of RNA polymerase assembly in vivo, however, remains largely unknown.

RESULTS

RNA polymerase assembly in vivo was analysed for E. coli strains carrying expression plasmids for four amino-terminal deletion and 11 Ala-Ser (AS) dipeptide-insertion mutant alpha subunits. For detection of RNA polymerase complexes, a hexa-histidine (H6) tag was added to all these mutant alpha at their carboxy-termini, and subunit complexes containing the H6-tagged alpha were isolated by passing cell extracts through Ni(2+)-affinity columns. The assembly properties of most alpha mutants were consistent with those observed in in vitro reconstitution studies. Some mutants defective in beta' association in vitro such as those carrying mutations at residues 80 and 200 were, however, assembled in vivo, suggesting that a specific condition(s) or factor(s) supports RNA polymerase assembly in vivo. One possible candidate supporting the RNA polymerase assembly is the molecular chaperon(s), because DnaK (hsp70) was always associated with assembly-defective RNA polymerase mutants. Most assembly competent mutants complemented two temperature-sensitive mutant alleles of rpoA, but two assembly competent mutants, one (alpha delta N20) carrying a deletion at the extreme amino-terminal region and the other (alpha I-60) with AS insertion at residue 60, failed to complement these ts mutants. The failure suggests that these assembly competent but complementation-negative alpha mutants lack an as yet unidentified function(s). In the case of these two mutants, DnaK was associated, with apparently assembled RNA polymerase.

CONCLUSION

The alpha-alpha, alpha-beta and alpha-beta' contact sites on the RNA polymerase alpha subunit identified in in vitro reconstitution studies also participate in the subunit assembly in vivo. Some alpha mutants defective in assembly in vitro are, however, assembled in vivo. A factor(s) such as the molecular chaperon DnaK or a specific intracellular condition(s) may affect RNA polymerase assembly in vivo.

摘要

背景

大肠杆菌的RNA聚合酶核心酶按α→α₂→α₂β→α₂ββ'的顺序组装。大肠杆菌RNA聚合酶α亚基的氨基末端结构域直至第235位残基在酶组装中起关键作用。对突变α亚基的体外重组研究表明，α二聚化存在多个位点参与，β'结合有两个区域（一个靠近第45位残基，另一个靠近第80位残基），β结合有两个区域（一个在第80位残基附近，另一个在第180和200位残基之间）。然而，RNA聚合酶在体内的组装机制在很大程度上仍然未知。

结果

对携带四个氨基末端缺失和11个丙氨酸-丝氨酸（AS）二肽插入突变α亚基表达质粒的大肠杆菌菌株进行了体内RNA聚合酶组装分析。为了检测RNA聚合酶复合物，在所有这些突变α亚基的羧基末端添加了一个六组氨酸（H6）标签，并通过使细胞提取物通过镍（2+）亲和柱来分离含有H6标签α亚基的亚基复合物。大多数α突变体的组装特性与体外重组研究中观察到的一致。然而，一些在体外β'结合有缺陷的突变体，如那些在第80和200位残基处携带突变的突变体，在体内能够组装，这表明特定条件或因子支持RNA聚合酶在体内的组装。一个可能支持RNA聚合酶组装的候选者是分子伴侣，因为DnaK（热休克蛋白70）总是与组装缺陷的RNA聚合酶突变体相关联。大多数组装能力强的突变体补充了rpoA的两个温度敏感突变等位基因，但有两个组装能力强的突变体，一个（αδN20）在极端氨基末端区域有缺失，另一个（αI-60）在第60位残基处有AS插入，未能补充这些温度敏感突变体。这种失败表明这些组装能力强但互补阴性的α突变体缺乏一种尚未确定的功能。在这两个突变体的情况下，DnaK与明显组装好的RNA聚合酶相关联。