The S gene of bacteriophage encodes the holin required for release of the R endolysin at the onset of phage-induced host lysis. S is the promoter-proximal gene on the single late transcript and spans 107 codons. S has a novel translational initiation region with dual start codons, resulting in the production of two protein products, S105 and S107. Although differing only by the Met-1-Lys-2. . . N-terminal extension present on S107, the two proteins are thought to have opposing functions, with the shorter polypeptide acting as the lysis effector and the longer one acting as an inhibitor. The expression of wild-type and mutant alleles of the holin gene has been assessed quantitatively with respect to the scheduling of lysis. S mRNA accumulates during the late gene expression period to a final level of about 170 molecules per cell and is maintained at that level for at least the last 15 min before lysis. Total S protein synthesis, partitioned at about 2:1 in favor of the S105 protein compared with the other product, S107, accumulates to a final level of approximately 4,600 molecules per cell. The kinetics of accumulation of S is consistent with a constant translational rate of less than one S protein per mRNA per minute. Mutant alleles with alterations in the translational initiation region were studied to determine how the translational initiation region of S achieves the proper partition of initiation events at the two S start codons and how the synthesis of S105 and S107 relates to lysis timing. The results are discussed in terms of a model for the pathway by which the 30S ribosome-fMet-tRNA complex binds to the translational initiation region of S. In addition, analysis of the relationship between lysis timing and the levels of the two S gene products suggests that S107 inhibits S105, the lethal lysis effector, by a stoichiometric titration.
Lysis gene S of phage lambda has a 107 codon reading frame beginning with the codons Met1‐Lys2‐Met3. Genetic data have suggested that translational initiation occurs at both Met1 and Met3, generating two polypeptides, S107 and S105 respectively. We have proposed a model in which the proper scheduling of lysis depends on the partition of translational initiations between the two start codons. Here, using in vitro methods, we show that two stem‐loop structures, one immediately upstream of the reading frame and a second approximately 10 codons within the gene, control the partitioning event. Utilizing primer‐extension inhibition or ‘toeprinting’, we show that the two S start codons are served by two adjacent Shine‐Dalgarno sequences. Moreover, the timing of lysis supported by the wild‐type and a number of mutant alleles in vivo can be correlated with the ratio of ternary complex formation over Met1 and Met3 in vitro. Thus the regulation of the S gene is unique in that the products of two adjacent in‐frame initiation events have opposing function.
The 107 codon reading frame of the lambda lysis gene S begins with the codon sequence Met1‐Lys2‐Met3..., and it has been demonstrated in vitro that both Met codons are used for translational starts. Furthermore, the partition of initiation events at the two start codons strongly affects the scheduling of lysis. We have presented a model in which the longer product, S107, acts as an inhibitor of the shorter product, S105, the lethal lysis effector, despite the fact that the two molecules differ only in the Met‐Lys residues at the amino terminus of S107. Using immunological and biochemical methods, we show in this report that the two predicted protein products, S105 and S107, are detectable in vivo as stable, membrane‐bound molecules. We show that S107 acts as an inhibitor in trans, and that its inhibitory function is entirely defined by the positively charged Lys2 residue. Moreover, our data show that energy poisons abolish the inhibitory function of S107 and simultaneously convert S107 into a lysis effector. We propose a two step model for the lethal action of gene S: first, induction of the S gene results in the accumulation of S105 and S107 molecules in mixed oligomeric patches in the cytoplasmic membrane; second, S monomers rearrange by lateral diffusion within the patch to form an aqueous pore. The R gene product, a transglycosylase, is released through the pore to the periplasm, resulting in destruction of the peptidoglycan and bursting of the cell. According to this model, the lateral diffusion step is inhibited by the energized state of the membrane.(ABSTRACT TRUNCATED AT 250 WORDS)
Gene 13 of bacteriophage P22 is functionally equivalent to lambda lysis gene S. Gene S codes for two products, the polypeptides S105 and S107, produced from translational initiation events at the third and first codon, respectively. We have shown that the two polypeptides have opposing functions in lysis: S105 is the lethal lysis effector, and S107 acts as an inhibitor of lysis (U. Bläsi, K. Nam, D. Hartz, L. Gold, and R. Young, EMBO J. 11:3501-3510, 1989). Gene 13 has a 108-codon reading frame and its product begins with a similar motif: Met-1-Lys-2-Lys-3-Met-4. Here, we present in vivo and in vitro evidence for the expression of a 13(108) and a 13(105) product and show that the lambda lysis control mechanisms is evolutionarily conserved in phage P22. In this case 13(108), like S107 in lambda, functions as the inhibitor of the lysis effector 13(105). Although the DNA sequences upstream of the S and 13 gene starts showed less homology, the same structural characteristics, i.e., stem-loop structures immediately upstream and about 10 codons downstream of the start region, were present in both reading frames. Using in vitro mutagenesis and toeprinting, we show that the upstream stem-loop structures of genes 13 and S, containing the Shine-Dalgarno sequence for initiations at Met-1, are interchangeable. Moreover, our data indicate that the stability of the secondary structures present in the translational initiation regions of genes S and 13 is set to create a particular ratio of initiation events at Met-1 and Met-3 or Met-4. The ratio of effector to inhibitor was much higher in P22 than in lambda. We propose that this reflects less transcriptional readthrough at the late terminator t(R) and suggests that the dual-start motif in genes 13 and S may be important for establishment of maintenance of the lysogenic state.
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