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来自基因49(重组内切核酸酶VII)的两种嵌套蛋白以及噬菌体T4的一种类λ RexA蛋白的调控。

Regulation of two nested proteins from gene 49 (recombination endonuclease VII) and of a lambda RexA-like protein of bacteriophage T4.

作者信息

Barth K A, Powell D, Trupin M, Mosig G

机构信息

Department of Molecular Biology, Vanderbilt University, Nashville, Tennessee 37235.

出版信息

Genetics. 1988 Oct;120(2):329-43. doi: 10.1093/genetics/120.2.329.

DOI:10.1093/genetics/120.2.329
PMID:2974005
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1203513/
Abstract

Phage T4 gene 49, encoding recombination endonuclease VII, specifies, by initiation from an AUG and an internal GUG codon, two in-frame overlapping peptides (of 18 and 12 kD). The gene is transcribed early and late, albeit from different promoters. The sequence predicts that in long early transcripts, initiated far upstream of the coding sequence, the Shine-Dalgarno sequence of the first ribosome binding site can be sequestered in a hairpin and/or cleaved. These processes might reduce initiation from the first AUG and facilitate initiation of the 12-kD peptide from the internal GUG. The potential of this hairpin to participate in Y structures or cruciforms suggests possible autoregulation. Shorter, more stable late transcripts initiated from a late promoter immediately upstream of the first ribosome binding site cannot form this hairpin. More efficient translation of the longer 18-kD gene 49 peptide from these late transcripts accounts for the strong dependence of endonuclease VII activity on late gene expression. An ORF downstream from gene 49 can be translated from a motA-dependent transcript that starts inside gene 49 as well as from the gene 49 transcripts. Its initiation codon overlaps the stop codon of gene 49, suggesting some coupling of translation. The deduced protein resembles, among others, the RexA protein of phage lambda. Possible implications for T4 recombination and for the interference of lambda lysogens with T4 gene 49 and rII mutants are discussed.

摘要

噬菌体T4的基因49编码重组内切核酸酶VII,通过从一个AUG和一个内部GUG密码子起始,指定了两个读框内重叠的肽段(18kD和12kD)。该基因在早期和晚期均有转录,尽管来自不同的启动子。序列预测,在编码序列上游很远位置起始的长早期转录本中,第一个核糖体结合位点的Shine-Dalgarno序列可能被封闭在一个发夹结构中并/或被切割。这些过程可能会减少从第一个AUG起始的翻译,并促进从内部GUG起始的12kD肽段的翻译起始。这个发夹结构参与Y结构或十字形结构的可能性表明存在可能的自动调节。从第一个核糖体结合位点上游紧邻的晚期启动子起始的较短、更稳定的晚期转录本不能形成这种发夹结构。从这些晚期转录本中更有效地翻译出较长的18kD基因49肽段,解释了内切核酸酶VII活性对晚期基因表达的强烈依赖性。基因49下游的一个开放阅读框可以从一个依赖motA的转录本翻译而来,该转录本从基因49内部起始,也可以从基因49的转录本翻译而来。它的起始密码子与基因49的终止密码子重叠,表明存在一些翻译偶联。推导的蛋白质与噬菌体λ的RexA蛋白等相似。讨论了对T4重组以及λ溶原菌对T4基因49和rII突变体干扰的可能影响。

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