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2

Ribosome stalling during translation elongation induces cleavage of mRNA being translated in Escherichia coli.

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3

Intraribosomal regulation of expression and fate of proteins.

Chembiochem. 2004 Jan 3;5(1):48-51. doi: 10.1002/cbic.200300751.

4

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Nature. 2004 Jan 1;427(6969):36-44. doi: 10.1038/nature02218. Epub 2003 Dec 3.

5

Nucleotide and phospholipid-dependent control of PPXD and C-domain association for SecA ATPase.

Biochemistry. 2003 Nov 25;42(46):13468-75. doi: 10.1021/bi035099b.

6

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J Bacteriol. 2003 Nov;185(22):6719-22. doi: 10.1128/JB.185.22.6719-6722.2003.

7

Cleavage of the A site mRNA codon during ribosome pausing provides a mechanism for translational quality control.

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8

The chemistry of protein synthesis and voyage through the ribosomal tunnel.

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Biochemical characterization of a mutationally altered protein translocase: proton motive force stimulation of the initiation phase of translocation.

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10

Nucleotide control of interdomain interactions in the conformational reaction cycle of SecA.

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SecM的翻译停滞对于SecA的基础表达和调控表达至关重要。

Translation arrest of SecM is essential for the basal and regulated expression of SecA.

作者信息

Murakami Akiko, Nakatogawa Hitoshi, Ito Koreaki

机构信息

Institute for Virus Research and Core Research for Evolutional Science and Technology, Japan Science and Technology Agency, Kyoto University, Kyoto 606-8507, Japan.

出版信息

Proc Natl Acad Sci U S A. 2004 Aug 17;101(33):12330-5. doi: 10.1073/pnas.0404907101. Epub 2004 Aug 9.

DOI:10.1073/pnas.0404907101

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC514405/

Abstract

The SecM protein of Escherichia coli contains an arrest sequence (F(150)XXXXWIXXXXGIRAGP(166)), which interacts with the ribosomal exit tunnel to halt translation elongation beyond Pro-166. This inhibition is reversed by active export of the nascent SecM chain. Here, we studied the physiological roles of SecM. Arrest-alleviating mutations in the arrest sequence reduced the expression of secA, a downstream gene on the same mRNA. Among such mutations, the arrest-abolishing P166A substitution mutation on the chromosomal secM gene proved lethal unless the mutant cells are complemented with excess SecA. Whereas secretion defect due either to azide addition, a secY mutation, or low temperature leads to up-regulated SecA biosynthesis, this regulation was lost by a secM mutation, which synergistically retarded growth of cells with lowered secretion activity. Finally, an arrest-alleviating rRNA mutation affecting the constricted part of the exit tunnel lowered the basal level of SecA as well as its secretion defect-induced up-regulation. Thus, the arrest sequence of SecM has at least two roles in SecA translation. First, the transient elongation arrest in normal cells is required for the synthesis of SecA at levels sufficient to support cell growth. Second, the prolonged SecM elongation arrest under conditions of unfavorable protein secretion is required for the enhanced expression of SecA to cope with such conditions.

摘要

大肠杆菌的SecM蛋白包含一个停滞序列（F(150)XXXXWIXXXXGIRAGP(166)），该序列与核糖体出口通道相互作用，使翻译延伸在Pro-166之后停止。新生SecM链的主动输出可逆转这种抑制作用。在此，我们研究了SecM的生理作用。停滞序列中减轻停滞的突变降低了secA的表达，secA是同一mRNA上的下游基因。在这些突变中，染色体secM基因上消除停滞的P166A替代突变被证明是致死性的，除非突变细胞用过量的SecA进行互补。虽然叠氮化物添加、secY突变或低温导致的分泌缺陷会导致SecA生物合成上调，但这种调节因secM突变而丧失，secM突变协同阻碍了分泌活性降低的细胞的生长。最后，影响出口通道收缩部分的减轻停滞的rRNA突变降低了SecA的基础水平及其分泌缺陷诱导的上调。因此，SecM的停滞序列在SecA翻译中至少有两个作用。第一，正常细胞中的短暂延伸停滞是合成足以支持细胞生长水平的SecA所必需的。第二，在蛋白质分泌不利的条件下，SecM的长时间延伸停滞是增强SecA表达以应对此类条件所必需的。