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大肠杆菌RNA聚合酶与无机多聚磷酸的功能相互作用

Functional interaction of Escherichia coli RNA polymerase with inorganic polyphosphate.

作者信息

Kusano S, Ishihama A

机构信息

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

出版信息

Genes Cells. 1997 Jul;2(7):433-41. doi: 10.1046/j.1365-2443.1997.13203301320330.x.

DOI:10.1046/j.1365-2443.1997.13203301320330.x
PMID:9366549
Abstract

BACKGROUND

RNA polymerase from the stationary growth phase cells of Escherichia coli is tightly associated with an acidic compound(s) and exhibits altered promoter selectivity, with reduced transcriptional activity of the genes highly expressed in the exponentially growing cells. Here we have examined the nature of the RNA polymerase-associated acidic compound(s).

RESULTS

RNA polymerase isolated from stationary-phase cells of E. coli was found to be tightly associated with inorganic polyphosphates (poly P), and cannot be dissociated even after chromatography on phosphocellulose or DNA-cellulose columns. Since RNA polymerase-poly P complexes reconstituted in vitro showed similar properties, poly P was not binding covalently. The inhibitory effects of poly P on transcription were examined using two forms of the holoenzyme, one containing sigma70, the major sigma for transcription of the genes expressed during exponential cell growth and the other containing sigma38, the principal sigma in the stationary growth phase. At low salt concentrations, poly P inhibited transcription by both Esigma70 and Esigma38 holoenzymes. With an increase in the concentration of potassium glutamate, the poly P inhibition was relieved. At high salt concentrations, the Esigma70 holoenzyme is not able to function, but the Esigma38 holoenzyme is however activated.

CONCLUSIONS

These results show that poly P may play a role in the promoter selectivity control of RNA polymerase in E. coli which is growing under conditions of high osmolarity and in the stationary growth phase.

摘要

背景

来自大肠杆菌稳定期细胞的RNA聚合酶与一种酸性化合物紧密结合,并表现出改变的启动子选择性,在指数生长期高表达的基因转录活性降低。在此,我们研究了与RNA聚合酶相关的酸性化合物的性质。

结果

从大肠杆菌稳定期细胞中分离出的RNA聚合酶被发现与无机多聚磷酸盐(多聚P)紧密结合,即使在磷酸纤维素或DNA纤维素柱上进行层析后也不能解离。由于体外重建的RNA聚合酶-多聚P复合物表现出相似的性质,多聚P不是共价结合的。使用两种形式的全酶研究了多聚P对转录的抑制作用,一种含有σ70,这是指数生长期表达基因转录的主要σ因子,另一种含有σ38,这是稳定期的主要σ因子。在低盐浓度下,多聚P抑制了Eσ70和Eσ38全酶的转录。随着谷氨酸钾浓度增加,多聚P的抑制作用得到缓解。在高盐浓度下,Eσ70全酶无法发挥作用,但Eσ38全酶却被激活。

结论

这些结果表明,多聚P可能在高渗透压条件下生长的大肠杆菌和稳定期的RNA聚合酶启动子选择性控制中发挥作用。

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