Dual control of lysogeny by bacteriophage P22: An antirepressor locus and its controlling elements

Two distantly linked clusters of genes on the Salmonella typhimurium phage P22 chromosome are involved in the control of lysogeny and superinfection immunity. One cluster consists of genes c1, c2, and c3, which are primarily responsible for the establishment and maintenance of lysogeny. It has been proposed that the second cluster consists of three loci which are responsible for the synthesis and control of an antirepressor substance which overcomes the repression mediated by the c2 gene product. This paper reports the isolation of mutants in a locus designated “ant” having characteristics expected of antirepressor mutants. Evidence is presented that the other loci in this second immunity region, mnt and virA, control the expression of the ant gene as represser and promoter/operator, respectively. The interactions of these three loci with each other and with the other immunity region are discussed.     

Second Locus of Bacteriophage P22 Necessary for the Maintenance of Lysogeny

A temperature-sensitive allele of a locus of phage P22, known to be involved in establishment of lysogeny, has been isolated. This mutant, P22 ts mnt, forms stable lysogens at 30 C which are induced by heating to 43 C. This shows that this locus is involved in the maintenance of lysogeny. The ts mnt locus is about 18 recombination units away from the c region. The wild allele, mnt⁺, is dominant over mnt and is responsible for a cytoplasmically diffusible product.     

A new gene of bacteriophage P22 which regulates synthesis of antirepressor

Two new mutants of bacteriophage P22 are described which define a new regulatory gene, arc (for antirepressor control). The properties of the arc mutants and of 31 phenotypic revertants indicate that the arc gene codes for a trans-acting protein whose primary role is to depress synthesis of P22 antirepressor protein during the lytic cycle of infection. Failure to regulate antirepressor production apparently leads secondarily to a lethal defect (i.e. failure to produce progeny phage).Although under certain conditions the arc function can be expressed by P22 prophages and can act as a weak barrier to superinfecting homologous phage, the arc product is neither necessary nor sufficient for maintenance of the prophage state or superinfection immunity in lysogens. Instead, as shown previously by others (Levine et al., 1975; Botstein et al., 1975), the prophage mnt gene product is responsible for repressing antirepressor synthesis, both by the prophage and by superinfecting phage.     

Repression of ant synthesis early in the lytic cycle of phage P22

Summary Using SDS-polyacrylamide gel electrophoresis to study the early expression of P22 genes we show that early expression of the ant-gene (imm I region) is turned off after 6–8 min, independent of the late acting mnt-repressor. A semi-clear mutant called cir5 is defective for this early ant turn-off. The mutation cir5 maps in the imm I region of P22 between genes mnt and ant. P22 cir5 mutants are defective for a repressor which acts in trans to regulate early ant synthesis. There appears to be no absolute requirement of the cir5 allele for the establishment of lysogeny. The overproduction of ant in the P22 cir5 mutant leads to a marked increase in abortive infections, killing the infected cells. The cir5-phenotype can be suppressed by an ant ^- mutation.     

The activity of ant product of the Salmonella phage P22 against the closely related but heteroimmune phage L.

Summary P22 mutants defective in the early gene 24 are complemented by phage L in mixed infection. P22 12 ^- and P22 23 ^- mutants are not complemented by phage L. Gene function 24 of an L prophage is turned on by a superinfecting P22 24 ^- mutant and complements the missing function of the defective P22 phage. Since this transactivation of prophage gene 24 depends on a functional gene ant in the superinfecting P22 mutant, it indicates derepression for leftward directed gene expression in prophage L. On the contrary neither the rightward directed expression of gene 12 nor of gene 23 in prophage L can be turned on by superinfecting P22 24 ^- 12 ^- or P22 24 ^- 23 ^- mutants (and also not by P22 12 ^- and P22 23 ^-) to a degree sufficient for complementation of simultaneously superinfecting L virB 12 ^- or L virB 23 ^- mutants. The failure to detect release of repression for rightward directed gene expression of prophage L corresponds to the earlier observation (Prell, 1975) that P22 superinfecting L lysogens cannot release replication inhibition for simultaneously infecting phage L. The results are discussed with respect to the mechanism underlying the different action of P22 antirepressor in L and in P22 lysogens.     

Cellular levels of the prophage lambda and 434 repressors.

As a prerequisite to a quantitative study of the inactivation of phage repressors in vivo (Bailone et al., 1979), the cellular concentrations of the bacteriophage λ and 434 repressors have been measured in bacteria with varying repressor levels.Using the DNA-binding assay we have determined the conditions for optimal repressor titration. The sensitivity of the λ repressor assay was increased by adding magnesium ions to the binding mixture; this procedure was without effect on the titration of the 434 repressor. The measures of the cellular repressor concentrations varied with the method of cell disruption.The cellular concentration of λ repressor, about 140 active repressor molecules per monolysogen, was relatively constant under specific cultural conditions. The repressor concentration increased with the number of cI gene copies but not in direct proportion.The 434 repressor concentration, hardly detectable in extracts of lysogens carrying an imm434 prophage, was greatly enhanced in bacteria carrying the newly constructed plasmid pGY101, that encodes the 434 cI gene.The cellular repressor level produced by 434 is lower than that produced by λ: this indicates that the maintenance of the prophage state is ensured by a relatively small number of repressor molecules binding tightly to the operator sites.     

Gene responsible for superinfection exclusion of heteroimmune corynebacteriophage.

Wild-type beta and gamma corynebacteriophages are heteroimmune and infect lysogens of each other productively. Unlike their wild-type counterparts, the bin mutants of each phage are excluded in lysogens carrying the heteroimmune phage. The wild-type phages overcome exclusion by means of the bin gene product which appears to act as an antirepressor. When repression is lifted, exclusion of bin mutants is abolished (N. Groman and M. Rabin, J. Virol. 28:28-33, 1978; J. Virol. 36:526-532, 1980). It has not been clear whether the excluding compound is the immune repressor itself or one whose synthesis is positively regulated by repressor. We have isolated beta exclusion mutants (xcl) that as prophage exhibited normal immune repression but no longer excluded gamma-bin mutants. Furthermore, we have shown that an xcl phage with an active immune repressor acted in trans to continue the positive regulation of exclusion by a second xcl+ prophage whose immune repressor was inactivated. From these results it was concluded that there is a gene distinct from the imm gene which is directly or indirectly responsible for exclusion. The xcl gene, mapped in prophage crosses, was located between imm and bin, that is, in the regulatory region of the phage genome. The simplest hypothesis compatible with the established observations is that beta immune repressor regulates the expression of the xcl and bin genes, the former positively and the latter negatively. It is likely that an analogous regulatory model applies to gamma phage since it has already been shown that both beta and gamma have bin alleles.     

Antirepression System Associated with the Life Cycle Switch in the Temperate Podoviridae Phage SPC32H

Prophages switch from lysogenic to lytic mode in response to the host SOS response. The primary factor that governs this switch is a phage repressor, which is typically a host RecA-dependent autocleavable protein. Here, in an effort to reveal the mechanism underlying the phenotypic differences between the Salmonella temperate phages SPC32H and SPC32N, whose genome sequences differ by only two nucleotides, we identified a new class of Podoviridae phage lytic switch antirepressor that is structurally distinct from the previously reported Sipho- and Myoviridae phage antirepressors. The SPC32H repressor (Rep) is not cleaved by the SOS response but instead is inactivated by a small antirepressor (Ant), the expression of which is negatively controlled by host LexA. A single nucleotide mutation in the consensus sequence of the LexA-binding site, which overlaps with the ant promoter, results in constitutive Ant synthesis and consequently induces SPC32N to enter the lytic cycle. Numerous potential Ant homologues were identified in a variety of putative prophages and temperate Podoviridae phages, indicating that antirepressors may be widespread among temperate phages in the order Caudovirales to mediate a prudent prophage induction.     

Immunity repressor of bacteriophage P2: Identification and DNA-binding activity

The product of gene C of the temperate bacteriophage P2, the immunity repressor, can be detected as a unique band eluting from phosphocellulose columns at 0.12 m-potassium phosphate when differentially labelled with a radioactive amino acid: the band is absent when phages that either have lost gene C through deletion or carry a suppressor-sensitive mutation in the gene are used. The repressor in its monomeric form is about 11,000 in molecular weight. At near physiological salt concentrations, the form predominantly recovered is the dimer.In filter-binding assays, the partially purified repressor binds wild-type P2 DNA strongly. It does not bind DNA of P2 vir94, a deletion that removes all the genetic elements involved in the regulation of lysogeny; it also does not bind, or binds inefficiently, DNA of P2 vir3, a mutation in the operator that controls the early replicative functions of P2. At the concentrations employed, the dimer is the active form in binding.The P2 repressor clearly differs in several features from the well-studied immunity repressor of bacteriophage lambda.     

The c4 repressor of bacteriophage P1 is a processed 77 base antisense RNA.

The c4 repressors of the temperate bacteriophages P1 and P7 inhibit antirepressor synthesis and are essential for establishment and maintenance of lysogeny. Using in vivo complementation tests we have previously shown that c4 is an antisense RNA acting on a target, ant mRNA, which is transcribed from the same promoter. Here we identify the c4 repressor molecule of P1 as a 77 +/- 1 base RNA by mapping its termini and show that the c4 RNA in P7 lysogens has the same or a similar size. P1 c4 RNA is encoded in a region shown to be sufficient for c4 complementation. It covers exactly the 74 bases previously suggested to fold into a stem-loop secondary structure essential for c4 function. Furthermore, we demonstrate that the 5' end of c4 RNA is generated by processing. Thus, c4 is the first example of an antisense RNA to be processed. A possible mechanism of processing is discussed.     

Analysis of a temperature sensitive mutation in gene cII of bacteriophage lambda

Summary The mutation cIIts612 was found to map outside the immunity region of phage imm21 hybrid. As expected of a cII mutation, cIIts612 is unable to stimulate either cI repressor or Int synthesis during the establishment of lysogeny. These results indicate that part of the cII gene of is homologous to that of imm21 phage.     

A new pleiotropic bacteriophage P1 mutation, bof, affecting c1 repression activity, the expression of plasmid incompatibility and the expression of certain constitutive prophage genes.

Summary In bacteriophage P1 an amber mutation in a new gene, bof, has been isolated. The bof-1 phage mutant exhibits a pleiotropic phenotype; bof product is non-essential, and acts as a positive modulator. In P1 bac-1 mutants, in which a dnaB analog product, ban, is expressed constitutively, the bof product activates ban expression both in the prophage state and in lytic growth: P1 bof bac prophages have a reduced ban activity and in lytic growth P1 bof bac phages show a lower ban activity than P1 wild type. This effect on ban activity is observed specifically in P1 bac-1 mutants; it is not mediated by the cl repressor of the lytic functions (repressor of the ban operon) since this effect occurs even if the phage carries a heat sensitive c1 repressor. Thus we concluded that the bac mutation put the ban operon under an abnormal, unknown control, modulated by the bof product. P1 bof lysogens show an increased immunity to superinfecting P1 phage and are affected in their inducibility properties; in the presence of the altered c1-100 repressor, bof product is required for maintenance of lysogeny, as shown by the induction of P1 c1-100 bof-1 lysogens at 30°. P1 bof superinfecting phage can be established together with a resident P1 bof prophage in a recA host, unlike P1 wild type which cannot form double lysogens. P1 bof double lysogens are unstable and segregate one or the other prophage. P1 Cm bof and P1 Km bof lysogens show higher levels of antibiotic resistance than the corresponding bof ⁺ lysogens. The bof gene has been mapped, in an interval defined by P1 prophage deletion end points, far from both ban and c1. All bof phenotypes are reversed by single mutations.     

Role of the cro gene in bacteriophage lambda development

Previous experiments have shown that the product of the cro gene of baeteriophage λ can exert an anti-repression activity, defined by the capacity of certain “cro-constitutive” defective lysogens to channel a superinfecting λ phage toward lytic development. We have used a combination of biological and biochemical assays to draw two main conclusions concerning this anti-repression activity: (1) after infection of a cro-constitutive cell, the superinfecting phage is unable to establish repression because it is unable to commence synthesis of cI protein (λ repressor) at a substantial rate; (2) the cause of this diminished synthesis of cI protein is the capacity of cro product to repress synthesis of the cII and cIII proteins, which normally activate the cI gene to establish repression in an infected cell. From our experiments and those of others, we suggest that cro product possesses a repression activity which is similar to that of the cI protein itself, but normally exerts a very different physiological role: the turnoff of synthesis of replication, recombination and regulation proteins as the virus enters the late stage of lytic development.     

Effects of mutations in the immunity system of bacteriophage P1.

A mutant of bacteriophage P1 that made an altered c1 repressor is described. The mutant c1 product had two configurations: in lysogens, at high temperatures, it permitted constitutive expression of the normally repressed DNA replication function ban and was insensitive to the action of ant, a product expressed by the virulent mutant P1virs and by the heteroimmune phage P7 (formerly phiamp+) and normally able to overcome c1 repression; in mutant lysogens at low temperatures, the mutant repressor was apparently normal (able to repress ban and sensitive to ant action). Genetic studies of this mutant led to the isolation of a derivative that formed unstable lysogens. These studies suggested that the ban product was normally under c1 control; they further showed that ant overcame c1 repression by inactivating c1 rather than by creating a bypass of repressor activity.     

lambdaimm P22dis: a hybrid of coliphage lambda with both immunity regions of Salmonella phage P22.

Summary Genetically marked and P22 phages were recombined in Escherichia coli-Salmonella typhimurium hybrid WR4028, a host sensitive to infection by both of these phages. Hybrid phages that acquired the immC region of P22, but retained the genes for the protein coat were selected on WR4027 (), a -immune, P22-resistant derivative of WR4028. In these immP22 hybrids, at least the c through P genes of were replaced with functionally related P22 genes. Phage recombinants with more extensive regions of the P22 genome were selected on the double lysogen WR4027 (, immP22). One such hybrid, immP22dis, was determined by heteroduplex analysis to contain approximately 40% of the P22 genome. Genetic studies established that immP22dis possesses the two widely separated immunity control regions of P22 (immC and immI) and that these loci are expressed in E. coli K-12 lysogenic for immP22dis. In addition, immP22dis contains the P22 a1 locus responsible for somatic 0–1 antigen conversion in Salmonella. Although the immP22dis phage particle has the head and tail, the phage genome also carries P22 tail gene 9 as evidenced by the production of free P22 tails. It also has the P22 att site as indicated by the integration of the immP22dis prophage near the proA locus on the bacterial chromosome.     

Control of lysogenization by phage P22 I. The P22 cro gene

P22 cro^? mutants were isolated as one class of phage P22 mutants (cly mutants) that have a very high frequeney of lysogeny relative to wild-type P22. These mutants: (1) do not form plaques and over-lysogenize relative to wild-type P22 after infection of a wild-type Salmonella host; (2) are defective in anti-immunity; and (3) fail to turn off high-level synthesis of P22 c2-repressor after infection.P22 cro^? mutations are recessive and map between the P22 c2 and c1 genes. P22 cro^? mutations are suppressed by clear-plaque mutations in the c1 gene, one of which is simultaneously cy^?. They are also suppressed, but incompletely, by mutations in the c2 (repressor) gene, especially those that do not completely abolish c2 gene function.Salmonella host mutants have been isolated that are permissive for the lytic growth of the P22 cro^? mutants.