Lysogenization of Escherichia coli him+, himA, and himD hosts by bacteriophage Mu.

The possible outcomes of infection of Escherichia coli by bacteriophage Mu include lytic growth, lysogen formation, nonlysogenic surviving cells, and perhaps simple killing of the host. The influence of various parameters, including host himA and himD mutations, on lysogeny and cell survival is described. Mu does not grow lytically in or kill him bacteria but can lysogenize such hosts. Mu c+ lysogenizes about 8% of him+ bacteria infected at low multiplicity at 37 degrees C. The frequency of lysogens per infected him+ cell diminishes with increasing multiplicity of infection or with increasing temperature over the range from 30 to 42 degrees C. In him bacteria, the Mu lysogenization frequency increases from about 7% at low multiplicity of infection to approach a maximum where most but not all cells are lysogens at high multiplicity of infection. Lysogenization of him hosts by an assay phage marked with antibiotic resistance is enhanced by infection with unmarked auxiliary phage. This helping effect is possible for at least 1 h, suggesting that Mu infection results in formation of a stable intermediate. Mu immunity is not required for lysogenization of him hosts. We argue that in him bacteria, all Mu genomes which integrate into the host chromosome form lysogens.     

Participation of hup gene product in replicative transposition of Mu phage in Escherichia coli

The closely related Escherichia coli genes hupA and hupB each encode a bacterial histone-like protein HU. We report here that mutator phage Mucts62 was unable to replicate in a hupA hupB double mutant, although it could replicate in hupA or hupB single mutant as efficiently as in the wild-type strain. Mucts62 was able to lysogenize the double mutant at 30 degrees C; cell killing occurred when the lysogen was incubated at 42 degrees C, but did not result in phage production. High-frequency non-replicative integration of Mu into host genomic DNA soon after infection could not be detected in the hupAB double mutant. These results provide the evidence that HU protein is essential for replicative transposition of Mu phage in E. coli, and also participates in high-frequency conservative integration.     

Instability of transposase activity: Evidence from bacteriophage Mu DNA replication

Transposition of genetic elements involves coupled replication and integration events catalyzed in part by a class of proteins called transposases. We have asked whether the transposase activity of bacteriophage Mu (the Mu A protein) is stable and capable of catalyzing multiple rounds of coupled replication/integration, or whether its continued synthesis is required to maintain Mu DNA replication. Inhibition of protein synthesis during the lytic cycle with chloramphenicol inhibited Mu DNA synthesis with a half-life of approximately 3 min, demonstrating a need for continued protein synthesis to maintain Mu DNA replication. Synthesis of specific Mu-encoded proteins was inhibited by infecting a host carrying a temperature-sensitive suppressor, at permissive temperature, with Mu amber phages, then shifting to nonpermissive temperature. When Aam phages were used, Mu DNA replication was inhibited with kinetics essentially identical to those with chloramphenicol addition; hence, it is likely that continued synthesis of the Mu A protein is required to maintain Mu DNA replication. The data suggest that the activity of the Mu A protein is unstable, and raise the possibility that the Mu A protein and other transposases may be used stoichiometrically rather than catalytically.     

Lysogenization of Escherichia coli by bacteriophage Lambda: complementary activity of the host's DNA polymerase I and ligase and bacteriophage replication proteins Q and P.

When bacteriophage lambda DNA replication is blocked by mutation in phage genes O or P, the efficiency of lysogenization drops to a very low value unless high multiplicities of infecting phage are used. Our results show that even at high multiplicity, lambda O or P mutants cannot efficiently lysogenize some hosts that are defective in either DNA polymerase I or DNA ligase. Covalent closure of infecting DNA molecules, a preliminary step for insertion according to Campbell's model and an obvious candidate for this lysogenization defect, appears to occur normally under our conditions. In addition, prophage excision as measured by the frequency of curing O- and P- lysogens seemed normal when tested in the poll- strain. These results suggest that the Escherichia coli enzymes DNA polymerase I and ligase, and phage proteins O and P, are able to provide some complementary activity whose function is required specifically for prophage integration.     

Involvement of Escherichia coli K-12 DNA polymerase I in the growth of bacteriophage Mu.

We examined several aspects of bacteriophage Mu development in Escherichia coli strains that carry mutations in the polA structural gene for DNA polymerase I (PolI). We found that polA mutants were markedly less efficient than PolI wild-type (PolI+) strains in their capacity to form stable Mu lysogens and to support normal lytic growth of phage Mu. The frequency of lysogenization was determined for polA mutants and their isogenic PolI+ derivatives, with the result that mutants were lysogenized 3 to 8 times less frequently than were PolI+ cells. In one-step growth experiments, we found that phage Mu grew less efficiently in polA cells than in PolI+ cells, as evidenced by a 50 to 100% increase in the latent period and a 20 to 40% decrease in mean burst size in mutant cells. A further difference noted in infected polA strains was a 10-fold reduction in the frequency of Mu-mediated transposition of chromosomal genes to an F plasmid. Pulse labeling and DNA-DNA hybridization assays to measure the rate of phage Mu DNA synthesis after the induction of thermosensitive prophages indicated that phage Mu replication began at about the same time in both polA and PolI+ strains, but proceeded at a slower rate in polA cells. We conclude that PolI is normally involved in the replication and integration of phage Mu. However, since phage Mu does not exhibit an absolute requirement for normal levels of PolI, it appears that residual PolI activity in the mutant strains, other cellular enzymes, or both can partially compensate for the absence of normal PolI activity.     

Characterization of Temperate Actinophage φC31 Isolated from Streptomyces coelicolor A3(2)

Actinophage phiC31 isolated from Streptomyces coelicolor A3(2), the only strain among actinomycetes for which a genetic map had been constructed, appears to be a typical temperate phage. After phiC31 infection, true lysogenic cultures arose which liberated phage and were immune to infection with homologous phage after repeated single-colony isolations and treatment with phage-specific antiserum. Clear-plaque (c) mutants were derived from phiC31 phage which failed to lysogenize sensitive cultures. Actinophage phiC31 has a temperature-sensitive stage of reproduction. A phage which reproduces with the same effectiveness at high (37 C) and low (28 C) temperatures has also been obtained. Heat-inducible (ct) mutants were isolated from this phage which were able to lysogenize sensitive cultures at 28 C but failed to do so at 37 C. Properties of ct mutants suggest that ct mutations involve a gene controlling maintenance of the lysogenic state in actinomycetes and synthesizing repressor, which may become heat-sensitive as a result of mutation.     

Conditionally replicating plasmid vectors that can integrate into the Klebsiella pneumoniae chromosome via bacteriophage P4 site-specific recombination.

P4 is a satellite phage of P2 and is dependent on phage P2 gene products for virion assembly and cell lysis. Previously, we showed that a virulent mutant of phage P4 (P4 vir1) could be used as a multicopy, autonomously replicating plasmid vector in Escherichia coli and Klebsiella pneumoniae in the absence of the P2 helper. In addition to establishing lysogeny as a self-replicating plasmid, it has been shown that P4 can also lysogenize E. coli via site-specific integration into the host chromosome. In this study, we show that P4 also integrates into the K. pneumoniae chromosome at a specific site. In contrast to that in E. coli, however, site-specific integration in K. pneumoniae does not require the int gene of P4. We utilized the alternative modes of P4 lysogenization (plasmid replication or integration) to construct cloning vectors derived from P4 vir1 that could exist in either lysogenic mode, depending on the host strain used. These vectors carry an amber mutation in the DNA primase gene alpha, which blocks DNA replication in an Su- host and allows the selection of lysogenic strains with integrated prophages. In contrast, these vectors can be propagated as plasmids in an Su+ host where replication is allowed. To demonstrate the utility of this type of vector, we show that certain nitrogen fixation (nif) genes of K. pneumoniae, which otherwise inhibit nif gene expression when present on multicopy plasmids, do not exhibit inhibitory effects when introduced as merodiploids via P4 site-specific integration.     

Localization of prophages of serological group B and F on restriction fragments defined in the restriction map of Staphylococcus aureus NCTC 8325

Abstract Several Staphylococcus aureus strains were lysogenized by the phages of serological group B (phages φ53, φ85) as well as by some of serological group F (phages φ77, φ84) and macrorestriction fragment patterns of genomic DNA were estimated in the lysogenized, non-lysogenic and delysogenized (cured of prophages) strains. It was shown that the integration of phage DNA into chromosome of S. aureus leads to specific changes in restriction fragment pattern in all the lysogenized strains. These changes correlate well with the Sma I restriction map of S. aureus NCTC 8325 since they concern the restriction fragments defined in this map. Phages φ53 and φ85 integrate into Sma I fragment B. On the other hand, phages φ77 and φ84 integrate into Smal fragment E of the S. aureus restriction map. The prophages of strain NCTC 8511 have their integration sites, as follows: the phage designated by us φM integrates in fragment A, whereas the integration site for phage φJ lies in fragment E. Phage φM was estimated to be genetically related to phages of serological group A and phage φJ to those of serological group F. Evidence was given that lysogenization of S. aureus strains by at least four prophages does not cast any doubt upon the estimation of their genetic relatedness based on their similarity in restriction pattern.     

Isolation and characterization of a plaque-forming lambda bacteriophage carrying a ColE1 plasmid

A plaque-forming lambdaimm434 bacteriophage carrying the entire genome of colicinogenic factor E1 has been isolated and characterized. This phage, lambdaimm434ColE1, can lysogenize as a stable plasmid within a recombination-deficient Escherichia coli cell that lacks the normal attachment site for lambda phage. Furthermore, it has been found that lambdaimm434ColE1 phage carrying amber mutations in the O and P genes of the lambda genome, i.e., lambdaimm434OamPamColE1, behaves as a plaque-forming phage, and this finding suggests that the ColE1 factor DNA permits replication of the DNA of the plaque-forming phage.     

Lethal Transposition of Mud Phages in Rec(-) Strains of Salmonella Typhimurium

Under several circumstances, the frequency with which Mud prophages form lysogens is apparently reduced in rec strains of Salmonella typhimurium. Lysogen formation by a MudI genome (37 kb) injected by a Mu virion is unaffected by a host rec mutation. However when the same MudI phage is injected by a phage P22 virion, lysogeny is reduced in a recA or recB mutant host. A host rec mutation reduces the lysogenization of mini-Mu phages injected by either Mu or P22 virions. When lysogen frequency is reduced by a host rec mutation, the surviving lysogens show an increased probability of carrying a deletion adjacent to the Mud insertion site. We propose that the rec effects seen are due to a failure of conservative Mu transposition. Replicative Mud transposition from a linear fragment causes a break in the host chromosome with a Mu prophage at both broken ends. These breaks are lethal unless repaired; repair can be achieved by Rec functions acting on the repeated Mu sequences or by secondary transposition events. In a normal Mu infection, the initial transposition from the injected fragment is conservative and does not break the chromosome. To account for the conditions under which rec effects are seen, we propose that conservative transposition of Mu depends on a protein that must be injected with the DNA. This protein can be injected by Mu but not by P22 virions. Injection or function of the protein may depend on its association with a particular Mu DNA sequence that is present and properly positioned in Mu capsids containing full-sized Mu or MudI genomes; this sequence may be lacking or abnormally positioned in the mini-Mud phages tested.     

Use of lambda pMu bacteriophages to isolate lambda specialized transducing bacteriophages carrying genes for bacterial chemotaxis.

A general method for constructing lambda specialized transducing phages is described. The method, which is potentially applicable to any gene of Escherichia coli, is based on using Mu DNA homology to direct the integration of a lambda pMu phage near the genes whose transduction is desired. With this method we isolated a lambda transducing phage carrying all 10 genes in the che gene cluster (map location, 41.5 to 42.5 min). The products of the cheA and tar genes were identified by using transducing phages with amber mutations in these genes. It was established that tar codes for methyl-accepting chemotaxis protein II (molecular weight, 62,000) and that cheA codes for two polypeptides (molecular weights, 76,000 and 66,000). Possible origins of the two cheA polypeptides are discussed.     

Genetic mapping and characteristics of the actinophage phi C31 deletion mutants of Streptomyces coelicolor A3(2) incapable of lysogenization

Actinophage phi C31 deletion c mutants with impaired ability to make repressor were genetically studied. Genetic crosses indicate that the c28 deletion mutant is situated with the c-region of the phi C31 genetic map. Based on the results of a qualitive test for recombination between several c mutants, a scheme of their order relative to deletion mutants was presented. The approximate distances between eight c mutants have been represented in units of the physical DNA map estimation. Genetic studies of actinophage lyg deletion mutants which cannot lysogenize sensitive cultures were carried out. Mutants failed to lysogenize upon mixed infection with lyg+ phages. The absence of the effect of lyg+ gene in trans suggests that lyg deletions cause a structural defect in an integration site of the phage. Preliminary data on alignment of lyg positions on physical and genetic maps of phi C31 phage have been obtained. According to evidence from genetic crosses, lyg mutation has been located in the right half of the phi C31 genome.     

Cloning of the A gene of bacteriophage Mu and purification of its product, the Mu transposase

The bacteriophage Mu transposase (the Mu A gene product), which is absolutely required for both integration of Mu and replicative transposition during the lytic cycle, has been overproduced by cloning the gene on a plasmid under the control of the phage lambda PL promoter. The protein has been purified to near homogeneity from the lysate of heat-induced cells of a strain carrying the plasmid. The purified protein is active as judged by its ability to complement Mu A- cell extracts for supporting Mu transposition in a cell-free reaction.     

Lysogenization by bacteriophage lambda: II. - Identification of genes involved in the multiplicity dependent processes

We previously showed that, under conditions of rapid exponential growth, lysogenization of E. coli cells by phage λ requires that the cell is infected by at least 2 phages able to replicate their DNA, or 3 or 4 phages unable to replicate their DNA [ref. 4]. Since genes dealing with prophage integration appear not to be involved in these multiplicity dependent processes, a determination was made as to whether more than one copy of the genes involved in repressor synthesis or its activation are needed for lysogenization. The complementation patterns which we obtained indicate multiplicity effects involving gene cII (and, perhaps, cIII) in lysogenization by both phage able or unable to replicate. In the former case, we propose that cII protein (and, perhaps, cIII) both induces repressor synthesis and inhibits phage DNA replication. In lysogenization by phage unable to replicate, the data suggest that the expression of early phage genes and repressor synthesis in the course of lysogenization are mutually exclusive processes which do not take place on the same phage chromosome.     

Genetic analysis of Escherichia coli min81 mutation blocking the development of bacteriophage Mu

Data characterizing mim81 mutation obtained by the method for direct selection of transposition mutations are presented. The development of Mu is shown to be dramatically suppressed in the mutant strain both upon infection and after induction from the lysogenic state. Frequencies of lysogenization and mini-Mu-dependent formation of cointegrates in the mutant strain are comparable with those in the wild-type strain. Mu development prohibition is removed if expression of early Mu gene is provided from the modified Pe promoter. The results obtained make us believe that the mechanism of mim81 mutation action involves reduction of early gene expression to the level that is sufficient for Mu DNA integration into the chromosome during infection and for single replicative events, but insufficient for vegetative development of bacteriophage Mu.     

Regulation of Bacteriophage P22 DNA synthesis and repressor levels in P22cly infections.

A rifampin-resistant mutant of Salmonella typhimurium carries an altered RNA polymerase. Wild-type (c+) phage P22 displays clear plaques and a reduced lysogenization frequency on this mutant host. The cly mutants of P22 were isolated on the basis of their ability to lysogenize such mutant hosts. Two classes of regulatory events, both of which are dependent on P22 gene c1 activity, are necessary for the establishment of lysogeny in P22. The positive events culminate in repressor synthesis; the negative events cause a retardation in phage DNA synthesis. Neither the positive nor the negative events are observed in P22c+ infections of the mutant host. Both effects are found in P22cly infections of the mutant host. Observable results of both the negative and the positive events are exaggerated in P22cly infections of wild-type hosts as compared to P22c+ infections. The cly mutation apparently increases the positive and negative regulatory events so that they are detectable in the mutant host and exaggerated in wild-type hosts. Possible mechanisms that result in the high frequency of lysogenization that characterizes the cly mutation and the nature of the cly mutation are discussed.     

Role of the tof gene in the production and perpetuation of the lambdadv plasmid.

A series of lambda derivatives carrying tof mutations were tested for their ability to give rise to plasmid lambda dv. Phages carrying tof mutations that distorted expression of the pRoR-tof-OP operon, were unable to produce lambda dv. Phages carrying an altered tof gene, having only a moderate effect on the same operon, produced unstable lambdadv's. On the other hand, those tof mutants were only the expression of the pLoL-N-exo operon, but not that of the pRoR-tof-OP operon was affected, produced stable lambdadv's.     

An Escherichia coli mutant unable to support site-specific recombination of bacteriophage lambda

We report the isolation of mutations in, and the characterization of, an Escherichia coli gene, hip, that is required for site-specific recombination of phage lambda. hip mutants are recessive and are located near minute 20 on the linkage map. The gene product is not vital to bacterial growth, since deletion mutants are viable. The absence of hip product reduces lambda integration to barely detectable levels and also reduces prophage excision, but less drastically. Certain mutations in the lambda int gene partially restore integration and excision in hip- hosts. Homologous recombination promoted by recA does not require hip function. In addition to their defect in site-specific recombination, hip mutants are unable to support lytic growth of phage Mu or of certain lambda mutants. Their pleiotropic phenotype closely resembles that of himA mutants, but complementation, mapping and DNA sequencing show that hip and himA are different genes.