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.     

Superinfection exclusion and changes in cellular transport processes in phage infected Salmonella typhimurium.

Summary The changes induced by bacteriophage P22 in the cellular transport process(es) of the host Salmonella typhimurium (Taneja et al., 1975; Khandekar et al., 1975; Bandyopadhyay and Chakravorty, 1976) involve interactions between the superinfection exclusion system of the resident prophage and the C immunity region of the superinfecting phage. The sieA gene of the prophage interferes with the changes in the cellular transport process induced by the superinfecting phage. However, if the superinfecting phage carries active C ₁ and C ₂ genes of the superinfecting phage seem to be expressed in the sie A⁺ lysogen.     

Ant-mediated inactivation of Salmonella phage L-specified repression at OR of prophage L.

Summary Ant product of phage P22 inactivates repression of prophage L at the right-hand operator o_R and allows for transactivation of prophage gene 12. The transactivation efficiency observed with a series of phage and prophage recombinants, using single superinfection of a lysogenic bacterium, is about the same as that recently observed at o_L of prophage L. This finding is in contrast to the failure to demonstrate derepression at o_R of prophage L in an experimental system employing double superinfection (Prell, 1978a). The reasons for the differing results are discussed and it is shown that derepression by the ant product in trans at o_R of the prophage is not modified to any significant degree by the immunity specificity (L or P22) of the prophage or of the superinfecting phage.     

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.     

Superinfection exclusion by heteroimmune corynebacteriophages.

Superinfection of Corynebacterium diphtheriae C7(beta) by heteroimmune phage gamma is productive, whereas superinfection by gamma-bin mutants is for the most part nonproductive. Exclusion of gamma-bin phage occurred after its DNA had penetrated and was partially expressed in the heteroimmune lysogen. All of the infected cells were killed, and lysis was observed. The beta inhibitor causing exclusion was produced during the prophage state and appeared to be distinct from immune repressor. The ability of gamma-bin phage to superinfect C7(beta) productively could be restored by recombination with beta phage, indicating that both beta and gamma phages contain either indentical or similar alleles of the bin gene. The bin gene was mapped by vegetative and prophage crosses and found to be located in the region of the phage genome concerned with regulation. Both beta and gamma wild-type phages induced the resident prophage in a significant fraction of superinfeted heteroimmune lysogens. This, coupled with the fact that induction of C7(beta) abolished exclusion, suggests that the bin gene product acts as antirepressor, i.e., it reduces the level of heteroimmune repressor either directly or indirectly. The gamma-bin mutants either failed to produce antirepressor or did so with reduced efficiency. Antirepressor activity was negatively controlled by homoimmune repressor. The isolation of beta mutants that appeared bin-like suggests that beta and gamma phages contain homologous systems of exclusion and antiexclusion. Exclusion of gamm-bin by beta phage in gram-positive C. diphtheriae exhibited striking parallels to the sieB exclusion described for phages P22 and lambda in gram-negative organisms. The extended similarities of these coryngephages to lambda bacteriophage is noted.     

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.     

Ant-mediated transactivation of early genes in Salmonella prophage P22 by superinfecting virulent P22 mutants

Summary The virulent mutants P22 vir B vy and P22 vy mutants, both insensitive to mnt-repressor, transactivate the early genes of a P22 prophage. The transactivation of early P22 prophage genes depends strictly on the expression of gene ant (antirepressor-protein) by the superinfecting P22 mutant and therefore occurs by derepression.     

Regulation of gene expression in Salmonella phage P22. II. Regulation of expression of late functions

Transactivation experiments were performed involving the genetically related Salmonella phages P22, L and Px1 in order to find out if more than one positively acting regulatory product is engaged in the expression of vegetative gene functions of each of these phages. The results obtained with Px1- and L-lysogenic cells superinfected with P22 suggest the following conclusions: 1. The expression of the early genes 12 and 23 and of the late gene 19 (lysozyme synthesis) is positively regulated by two different regulatory products, since P22 transactivates in prophage Px1 both early and late genes (Prell, 1973), in prophage L only late genes. 2. The transactivation by P22 of the lysozyme gene of prophage L takes place in the presence of L repressor. This conclusion is suggested, since the superinfecting P22 does not derepress early gene expression (see 1.), and is confirmed by demonstration of replication inhibition for L phage in L lysogenic cells doubly superinfected with L and P22 phages (Thomas-Bertani-experiment). 3. The late gene regulatory protein seems to be synthesized by gene 23, as transactivation experiments with both L- and Px1 prophages suggest. 4. The expression of gene 23 itself is turned on by an early regulatory product. The gene which codes for it is still unidentified. However its product seems to by highly specific, since it is active on Px1- but not on L-prophage.     

Head length determination in bacteriophage T4: The role of the core protein P22

We have found that two different temperature-sensitive mutations in gene 22, tsA74 and ts22-2, produce high frequencies (up to 85%) of petite phage particles when grown at a permissive or intermediate temperature. Moreover, the ratio of petite to normal particles in a lysate depends upon the temperature at which the phage are grown. These petite phage particles appear to have approximately isometric heads when viewed in the electron microscope, and can be distinguished from normal particles by their sedimentation coefficient and by their buoyant density in CsCl. They are biologically active as detected by their ability to complement a co-infecting amber helper phage. Lysates of both mutants grown at a permissive temperature reveal not only a significant number of petite phage particles in the electron microscope, but also sizeable classes of wider-than-normal particles, particles having abnormally attached tails, and others having more than one tail.Striking protein differences exist between the purified phage particles of tsA74 or ts22-2 and wild-type T4. B1¹, a 61,000 molecular weight head protein, is completely absent from the phage particles of both mutants, and the internal protein IPIII¹ is present in reduced amounts as compared to wild type. The precursor to B1¹ is present in the lysates, but these mutations appear to prevent its incorporation into heads, so it does not become cleaved.The product of gene 22 (P22) is known to be the major protein of the morphogenetic core of the T4 head. Besides the mutations reported here, several mutations which affect head length have been found in gene 23, which codes for the major capsid protein (Doermann et al., 1973b). We suggest a model in which head length is determined by an interaction between the core (P22 and IPIII) and the outer shell (P23).     

Isolation of P22 Specialized Transducing Phage following F''-Episome Fusion

A P22 specialized transducing phage has been constructed which carries the structural gene for aspartate transcarbamylase (ATCase). This gene (pyrB) was first brought close to the P22 attachment site by fusing an F' pyrB⁺ episome to an F' prolac episome which carries a P22 prophage attachment site. A prophage was added to these fused F' episomes and the lysogen was UV-induced. The specialized transducing phage was isolated from the resulting lysate. The phage also carries argI, the structure gene for ornithine transcarbamylase.     

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.     

Superinfection Exclusion by P22 Prophage and the Replication Complex

Wild-type sie(+) P22 prophage converted Salmonella typhimurium lysogens to exclude deoxyribonucleic acid (DNA) injected by superinfecting phage. DNA from a P22 superinfecting virulent phage associated with the replication complex in a sie(-) lysogen but not in a sie(+) lysogen.     

Role of antirepressor in the bipartite control of repression and immunity by bacteriophage P22

The bipartite immunity and repression system of the temperate Salmonella bacteriophage P22 has been analyzed by genetic means. Both parts of the immunity system, immI and immC, are necessary to confer upon lysogens immunity to superinfection with P22. The product of the c2 gene (which lies in immC) is a repressor which apparently regulates directly the expression of phage genes in a manner analogous (if not identical) with that found for coliphage λ.The immI region contains three genetic elements. One of these (mnt; Gough, 1968) appears to specify another repressor whose specific activity is continuously required for the maintenance of lysogeny. We have identified two new regulatory elements in immI through the isolation of mutants. Virulent mutations (virA) in the Vy element confer the ability to grow in immune P22 lysogens by destroying or inactivating the repression functions of the lysogen (possibly the c2-repressor itself). The third element in immI is a structural gene (ant) for a protein (antirepressor) which is regulated by mnt (repressor) and Vy (promoter/operator).We have shown that the ability of P22 to grow on immI-deletion lysogens, the dominant virulence of virA virulents, and the requirement for mnt for the maintenance of lysogeny, all depend on an intact ant⁺ gene. It is proposed that P22 antirepressor represents a new type of regulatory protein which acts by controlling other regulatory proteins.     

MB78, a virulent bacteriophage of Salmonella typhimurium

The isolation and some properties of a virulent bacteriophage of Salmonella typhimurium, MB78, which is morphologically, serologically, and physiologically unrelated to P22, are reported. The phage has a noncontractile long tail with partite ends. It cannot multiply in minimal medium in the presence of citrate. MB78-infected cells are, however, killed in such medium. This phage cannot grow in rifampin-resistant mutants of the host. The latent period of growth of this phage is much shorter than that of P22. Both sieA and sieB genes of the resident P22 prophage are required to exclude the superinfecting MB78 phage, whereas all temperate phages related to P22 are excluded by either one or both of the genes individually. Restriction endonuclease cleavage patterns of P22 and MB78 are distinctly different. The absence of homology between the two phages P22 and MB78 suggests that MB78 is not related to phage P22.     

Prophage lambda at unusual chromosomal locations. II. Mutations induced by bacteriophage lambda in Escherichia coli K12

An Escherichia coli strain deleted for the primary λ attachment site was lysogenized with λ at secondary sites. Some lysogens became mutants because of prophage insertion in the affected gene. Mutagenesis by phage λ is not random with respect to the gene affected: most mutants were pro, although certain other genes could be mutated at lower frequencies. In the case of several independent ilv and gal mutants, the sites of prophage insertion were in the same segment of the ilv region and galT gene respectively. The galT location may also be a preferred site for the insertion of DNAs other than prophage λ. Insertion of prophage λ within an operon can reduce the expression of operator-distal genes. A trpC λ insertion mutant expresses the operator-distal trpB function constitutively at a low level. This expression probably derives from a promoter located in the left arm of the prophage.     

Role of the ø11 Phage Genome in Competence of Staphylococcus aureus

Both phage ?11 and 83A, when present as prophage or when used as helper phage, induce competence for transfection and transformation to the same level in Staphylococcus aureus, strain 8325-4. Cells lysogenized with certain temperature-sensitive (ts) mutants of phage ?11 show competence at the nonpermissive temperature (41 C) without production of infectious phages. Phage ?11ts allele 31 can neither as a prophage nor as a helper phage develop competence under nonpermissive conditions. This mutant appears, therefore, to be mutated in the region of the phage genome controlling competence. The competence level for both transfection and transformation is increased by superinfecting strain 8325-4 (?11) or 8325-4 (83A) at high multiplicities with phage ?11 with some of its mutants or with phage 83A. This superinfection enhancement appears to require protein synthesis but not deoxyribonucleic acid synthesis as judged from studies with inhibitors of macromolecular synthesis. Besides the phage particle, no extracellular or cell-bound factors so far detected can induce competence. The phage-induced product conferring competence is rapidly synthesized by strain 8325-4 (ts?11(31)) after shift to permissive conditions, but requires deoxyribonucleic acid and protein synthesis to be expressed. Recombination between the sus mutants of phage ?11 of Kretschmer and Egan and ts?11(31) indicate that competence is controlled by an early gene in the lytic cycle which may be expressed also in lysogenic cells. The phage product inducing competence appears to have a half-life of 10 to 15 min in the conditional lethal mutant at shift to nonpermissive temperature. Ultraviolet inactivation of phage ?11 infectivity occurs more rapidly than inactivation of competence induction. In fact, the number of transformants is increased at low doses of irradiation. Competence induction is, however, decreased at high does of ultraviolet irradiation.     

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.     

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.