Evidence of bar minigene expression and tRNA2Ile sequestration as peptidyl-tRNA2Ile during lambda bacteriophage development.

Lambda bacteriophage development is impaired in Escherichia coli cells defective for peptidyl (pep)-tRNA hydrolase (Pth). Single-base-pair mutations (bar(-)) that affect translatable two-codon open reading frames named bar minigenes (barI or barII) in the lambda phage genome promote the development of this phage in Pth-defective cells (rap cells). When the barI minigene is cloned and overexpressed from a plasmid, it inhibits protein synthesis and cell growth in rap cells by sequestering tRNA(2)(Ile) as pep-tRNA(2)(Ile). Either tRNA(2)(Ile) or Pth may reverse these effects. In this paper we present evidence that both barI and barII minigenes are translatable elements that sequester tRNA(2)(Ile) as pep-tRNA(2)(Ile). In addition, overexpression of the barI minigene impairs the development even of bar(-) phages in rap cells. Interestingly, tRNA or Pth may reestablish lambda phage development. These results suggest that lambda bar minigenes are expressed and tRNA(2)(Ile) is sequestered as pep-tRNA(2)(Ile) during lambda phage development.

Increased bar minigene mRNA stability during cell growth inhibition.

Bacteriophage lambda is unable to grow vegetatively on Escherichia coli mutants defective in peptidyl-tRNA hydrolase (Pth) activity. Mutations which allow phage growth on the defective host have been located at regions named bar in the lambda genome. Expression of wild-type bar regions from plasmid constructs results in inhibition of protein synthesis and lethality to Pth-defective cells. Two of these wild-type bar regions, barI+ and barII+, contain minigenes with similar AUG-AUA-stop codon sequences preceded by different Shine-Dalgarno (SD) and spacer regions. The induced expression of barI+ and barII+ regions from plasmid constructs resulted in similar patterns of protein synthesis inhibition and cell growth arrest. Therefore, these deleterious effects may stem from translation of the transcripts containing the minigene two-codon 'ORF' (open reading frame). To test for this possibility, we assayed the effect of point mutations within the barI minigene. The results showed that a base pair substitution within the SD and the two-codon 'ORF' sequences affected protein synthesis and cell growth inhibition. In addition, mRNA stability was altered in each mutant. Higher mRNA stability correlated with the more toxic minigenes. We argue that this effect may be caused by ribosome protection of the mRNA in paused complexes as a result of deficiency of specific tRNA.

Genetic and physical location of the Escherichia coli rap locus, which is essential for growth of bacteriophage lambda.

The Escherichia coli rap mutant does not support the growth of bacteriophage lambda (D. Henderson and J. Weil, Virology 71:546-559, 1976). We located the rap site at 26 min in the E. coli genetic map and determined the gene order fadR-rap-supF-trp from our transduction experiments. Plasmid pHO1 harbors a 5.6-kilobase-pair segment of the E. coli chromosome which contains the pth gene (B. Hove-Jensen, Mol. Gen. Genet. 201:269-276, 1985). This plasmid complemented rap bacteria, suggesting that it carries the dominant allele rap+. Subcloning experiments reduced the rap-complementing segment to 1.5 kilobase pairs. This segment still contained pth; thus, both loci are tightly linked. The lit mutations that inhibit phage T4 growth in E. coli are located nearby at 25 min (W. Cooley, K. Sirotkin, R. Green, and L. Snyder, J. Bacteriol. 140:83-91, 1979). We showed that rap and lit mutations are phenotypically and genetically different.