Isolation of phage P2-186 intervarietal hybrids and 186 insertion mutants

The late-expressed region of the temperate coliphage 186 genome

The late-lytic region of the genome of bacteriophage 186 encodes the phage proteins that synthesize the complex viral particle and lyse the bacterial host. We report the completion of the DNA sequence of the late region and the assignment of 18 previously identified genes to open reading frames in the sequence. The 186 late region is similar to the late region of phage P2, sharing 26 genes of known function: the single gene for activation of late gene transcription, 6 genes for construction of DNA-containing heads, 16 for tail morphogenesis, and 3 for cell lysis. We identified two 186 late genes with unknown function; one is homologous to previously unrecognised genes in P2, HP1, and phiCTX, and the other may modulate DNA packaging. The 186 late region, like the rest of the genome, lacks the lysogenic conversion genes that are carried by P2, allowing the 186 late region to be transcribed from only three late promoters rather than four. The relative absence of lysogenic conversion genes in 186 suggests that the two phages have evolved to use the lytic and lysogenic reproductive modes to different extents.

A substrate of the centisome 63 type III protein secretion system of Salmonella typhimurium is encoded by a cryptic bacteriophage

Salmonella enterica has evolved a type III protein secretion system that allows these enteropathogens to translocate effector molecules directly into the host cell cytoplasm. These effectors mediate a variety of responses, including cytoskeletal rearrangements, cytokine production, and in certain cells, the induction of apoptosis. We report here the characterization of a substrate of this secretion system in S. enterica serovar typhimurium (Salmonella typhimurium) that is homologous to the SopE protein of Salmonella dublin implicated in bacterial entry into cultured epithelial cells. The sopE locus is located within a cluster of genes that encode tail and tail fiber proteins of a cryptic P2-like prophage, outside of the centisome 63 pathogenicity island that encodes the invasion-associated type III secretion system. Southern hybridization analysis revealed that sopE is present in only a subset of S. enterica serovars and that the flanking bacteriophage genes are also highly polymorphic. Encoding effector proteins that are delivered through type III secretion systems in highly mobile genetic elements may allow pathogens to adapt rapidly by facilitating the assembly of an appropriate set of effector proteins required for successful replication in a new environment.

The Cro-like Apl repressor of coliphage 186 is required for prophage excision and binds near the phage attachment site

The Apl protein of the temperature coliphage 186 represses transcription of the immunity repressor gene and down-regulates lytic transcription. It is shown here that an apl- mutant is competent for lytic development and establishes lysogeny normally but is defective in excision of the prophage. The Apl protein binds between the lytic and lysogenic promoters and also near the phage attachment site, suggesting that its role in excision is direct. Apl thus appears to act as an excisionase as well as a repressor. The pattern of Apl-induced DNase I enhancements indicates that the DNA is bent by Apl. Potential Apl recognition sequences are identified; these sequences are directly repeated several times across each binding region and are spaced 10 or 11 bases apart, suggesting that Apl binds to one face of the DNA helix.

Mechanisms of genome propagation and helper exploitation by satellite phage P4

Temperate coliphage P2 and satellite phage P4 have icosahedral capsids and contractile tails with side tail fibers. Because P4 requires all the capsid, tail, and lysis genes (late genes) of P2, the genomes of these phages are in constant communication during P4 development. The P4 genome (11,624 bp) and the P2 genome (33.8 kb) share homologous cos sites of 55 bp which are essential for generating 19-bp cohesive ends but are otherwise dissimilar. P4 turns on the expression of helper phage late genes by two mechanisms: derepression of P2 prophage and transactivation of P2 late-gene promoters. P4 also exploits the morphopoietic pathway of P2 by controlling the capsid size to fit its smaller genome. The P4 sid gene product is responsible for capsid size determination, and the P2 capsid gene product, gpN, is used to build both sizes. The P2 capsid contains 420 capsid protein subunits, and P4 contains 240 subunits. The size reduction appears to involve a major change of the whole hexamer complex. The P4 particles are less stable to heat inactivation, unless their capsids are coated with a P4-encoded decoration protein (the psu gene product). P4 uses a small RNA molecule as its immunity factor. Expression of P4 replication functions is prevented by premature transcription termination effected by this small RNA molecule, which contains a sequence that is complementary to a sequence in the transcript that it terminates.

Genes for the establishment and maintenance of lysogeny by the temperate coliphage 186

To identify the genes in coliphage 186 that are required for lysogeny, we isolated clear-plaque mutants. Complementation studies and DNA sequencing identified two genes, the cI gene for the immunity maintenance repressor and the cII gene, which is required only for the establishment of lysogeny. One mutant carried a change in the LexA-binding site controlling expression of the antirepression protein Tum.

UV induction of coliphage 186: prophage induction as an SOS function

Our results show that UV induction of the 186 prophage depends upon the phage function Tum, with the mutant phenotype of turbid plaques on mitomycin plates and the expression of which is controlled by the host LexA protein. Tum function, encoded near the right-hand end of the coliphage 186 chromosome, is under the control of promoter p95. This promoter is overlapped by a sequence closely related to the consensus sequence of the LexA-binding site. It is proposed that inactivation of LexA after UV irradiation (or by genetic means) leads to prophage induction by permitting expression of Tum which, by unknown means, induces prophage. This mechanism is basically different from that seen with the UV-inducible lambdoid coliphages, which are not regulated by LexA.

DNA replication studies with coliphage 186. II. Depression of host replication by a 186 gene

Using pre-labelling rather than pulse-labelling studies to determine rates of replication, we have shown that coliphage 186 infection is accompanied by a depression in host DNA replication. We have isolated mutants of the phage gene involved and mapped them in the early region of the phage genome. Sequencing the mutants ultimately led us to the identification of the gene that we have named the dhr gene.

Control of gene expression in the P2-related template coliphages. III. DNA sequence of the major control region of phage 186

The PstI fragment (65.5% to 77.4%) of coliphage 186, known genetically to encode the major control genes, has been sequenced, and an analysis performed to assess coding capacity, transcription-translation signals, and to identify any other significant features. Our analysis indicates that the region encodes: seven genes, including the int and cI genes, which overlap, the late control gene B, and two genes, named CP75 and CP76, encoding potential DNA-binding proteins; a promoter pB and terminator tB for the rightward transcription of the B gene, and we predict the existence of this transcript in a lysogen; a promoter pL and terminator tL for leftward transcription that encodes the int and cI genes, and represents the presumed lysogenic transcript; a promoter pR for rightward transcription to give the presumed (early) lytic transcript that is overlapping and convergent with the lysogenic transcript; and finally, a potential operator site for repressor binding in the region of the pR promoter. Preliminary evidence is presented to support this analysis.

Genetic studies of coliphage 186. I. Genes associated with phage morphogenesis

In coliphage 186, 22 essential genes were defined by complementation studies with amber mutants. Eighteen genes were associated with phage morphogenesis: 11 with phage tail formation, and 7 with phage head formation. The remaining four genes are discussed in the accompanying paper (S. M. Hocking and J. B. Egan, J. Virol. 44:1068-1071, 1982).

Coliphage 186 Replication is delayed when the host cell is UV irradiated before infection

In contrast to results with injections by lambda and P2, the latent period for infection by coliphage 186 is extended when the host cell is UV irradiated before infection. We find that 186 replication is significantly delayed in such a cell, even though the phage itself has not been irradiated. In contrast, replication of the closely related phage P2 under the same conditions is not affected.

In vivo transcription studies of coliphage 186

The temporal apperance of transcripts from the 186 chromosome has been determined by pulse-labeling at different times after prophage induction and hybridization of RNA extracts to cloned restriction fragments of 186. Studies with different mutants and induction in the presence of chloramphenicol suggested a controlled pattern of transcription and led us to propose the existence of a primary control gene analogous to the lambda gene N.

Restriction cleavage maps of coliphages 186 and P2

The restriction enzymes BamHI, Bg/II, EcoRI, HindIII, PstI, XbaI and XhoI have been used to cleave DNA isolated from the related coliphages P2 and 186 for analysis on 1% agarose gels. Three approaches were used to map the sites of cleavage: a) analysis dependent upon the existence of cohesive termini and availability of viable P2-186 hybrids; b) analysis of double digests and redigests of isolated fragments with a second enzyme and c) analysis of partial digests by transfer to nitrocellulose and hybridization with a single fragment. This last approach and the results obtained from it are detailed in a separate paper (Saint and Egan, 1979). The number of sites of each enzyme are as follows: a) 186, BamHI-7, Bg/II-1, EcoRI-3, HindIII-2, PstI-22, XbaI-0 and Xho-I-1; b) P2, BamHI-3, Bg/II-2, EcoRI-3, HindIII-0, PstI-O, XbaI-1 and XhoI-O. All of these sites have been mapped with the exception of PstI for 186, where only the five sites in the right 35% (the control region) have been mapped.

Isolation of recombinants between T7 and T3 bacteriophages and their use in vitro transcriptional mapping

A variety of T3 X T7 recombinants were isolated from crosses between T3 and T7 parental phages carrying amber markers in various genes (gene 1 to gene 19). The genetic constitution of these recombinants was determined by reference to the selected markers and also directly by analysis of the proteins translated from the T3 X T7 recombinants in vivo. Although T3 and TM phages are closely related, most T3 and T7 proteins differ slightly in size, and hence the genetic origin of a gene can be determined by protein analysis. The major transcripts read by T3 and T7 RNA polymerases from T3 X T7 recombinant phage DNAs vary, depending on which regions of the T3 or T7 chromosome are present. T7 RNA polymerase is unable to utilize major promoter sites employed by T3 polymerase at an appreciable rate, and the converse is also true. Hence the transcriptional pattern for a recombinant phage DNA obtained with the T3 or T7 polymerase allows a determination of the identity of the different promoter sites on the genome. The transcriptional analysis of T3 X T7 recombinant DNAs together with earlier observations has been used to map the promoter sites for five out of seven major T3 and T7 RNA species on the genetic maps of T3 and T7. The promoter sites for the T7 and T3 RNA species IIIa, IV, and V originate at the beginning of genes 7, 9, and 10, respectively; the promoter sites for the T7 and T3 RNA species I and II are located to the left of gene 11 and gene 13, respectively. No T3 X T7 recombinants were found for which the specificity of the phage RNA polymerase was not correlated with the corresponding promoter sites for species IIIa and I (the transcription of which covers 60% of the genome). That means that the RNA polymerase specified by the recombinant genome is able to read all of the information encoded in sequences read normally from major promoters by the enzyme on the wild-type phage genome. This suggests that the in vitro specificity for promoter site selection by the phage polymerases is also maintained in vivo.

Characterization of the DNA from bacteriophage P2-186 hybrids and physical mapping of the 186 chromosome

The DNA from two P2-186 hybrid phages and three 186 Insertion mutants have been characterized by heteroduplex analysis and denaturation mapping. The results allow the orientation of the physical and genetic maps of bacteriophage 186 DNA and put physical limits on the chromosomal locations of the phage attachment sites, immunity genes and tail genees.