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. 1988 Oct;120(2):329–343. doi: 10.1093/genetics/120.2.329

Regulation of Two Nested Proteins from Gene 49 (Recombination Endonuclease Vii) and of a λ Rexa-like Protein of Bacteriophage T4

K A Barth 1, D Powell 1, M Trupin 1, G Mosig 1
PMCID: PMC1203513  PMID: 2974005

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 λ. Possible implications for T4 recombination and for the interference of λ lysogens with T4 gene 49 and rII mutants are discussed.

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Selected References

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