Integration of bacteriophage lambda into the cryptic lambdoid prophages of Escherichia coli.

Bacteriophage lambda missing its chromosomal attachment site will integrate into recA+ Escherichia coli K-12 and C at the sites of cryptic prophages. The specific regions in which these recombination events occur were identified in both lambda and the bacterial chromosomes. A NotI restriction site on the prophage allowed its physical mapping. This allowed us to identify the locations of Rac, Qin, and Qsr' cryptic prophages on the NotI map of E. coli K-12 and, by analogy, to identify the cryptic prophage in E. coli C as Qin. No new cryptic prophages were detected in E. coli K-12.     

Genetic studies of coliphage P1. I. Mapping by use of prophage deletions.

One hundred and ten amber mutants of coliphage P1 were isolated and localized into groups with respect to the existing genetic map by use of nonpermissive Escherichia coli K-12 strains lysogenic for P1 with deletions. These lysogens contain one of three types of deletion prophages: P1cry and its derivatives, P1dlacs, and P1dpros. Fourteen such lysogens were tested for their ability to rescue the amber mutants which were then assigned to one of nine deletion segments of the P1 genome defined by the termini of the various prophage deletions. The relationship of the nine deletion segments with the published P1 map is described, two new segments having been added. The deletions of the 14 prophages overlapped sufficiently to indicate that the P1 genetic prophage map should be represented in circular form, which is consistent with the fact that P1 is normally a circular plasmid in the prophage state. The distribution of mutants into deletion segments is nonrandom for at least one segment. In addition, the deletion termini of the 14 defective prophages coincided in five out of nine regions separating the nine deletion segments. Various possible explanations are discussed for the nonrandom recurrence of these deletion termini, including the evidence of hot spots of recombination.     

Xis and Fis proteins prevent site-specific DNA inversion in lysogens of phage HK022.

HK022, a temperate coliphage related to lambda, forms lysogens by inserting its DNA into the bacterial chromosome through site-specific recombination. The Escherichia coli Fis and phage Xis proteins promote excision of HK022 DNA from the bacterial chromosome. These two proteins also act during lysogenization to prevent a prophage rearrangement: lysogens formed in the absence of either Fis or Xis frequently carried a prophage that had suffered a site-specific internal DNA inversion. The inversion is a product of recombination between the phage attachment site and a secondary attachment site located within the HK022 left operon. In the absence of both Fis and Xis, the majority of lysogens carried a prophage with an inversion. Inversion occurs during lysogenization at about the same time as prophage insertion but is rare during lytic phage growth. Phages carrying the inverted segment are viable but have a defect in lysogenization, and we therefore suggest that prevention of this rearrangement is an important biological role of Xis and Fis for HK022. Although Fis and Xis are known to promote excision of lambda prophage, they had no detectable effect on lambda recombination at secondary attachment sites. HK022 cIts lysogens that were blocked in excisive recombination because of mutation in fis or xis typically produced high yields of phage after thermal induction, regardless of whether they carried an inverted prophage. The usual requirement for prophage excision was bypassed in these lysogens because they carried two or more prophages inserted in tandem at the bacterial attachment site; in such lysogens, viable phage particles can be formed by in situ packaging of unexcised chromosomes.     

Integration defective mutants of bacteriophage P2

Summary Mutants of phage P2 unable by themselves to be integrated as prophages have been isolated. These mutants (int) are complemented by the wild type allele and may then yield stable lysogenic strains carrying an int prophage at location I in Escherichia coli C. These lysogens produce either no phage or little phage, depending on the int mutant used. All int mutants isolated appear to belong to a single complementation group.Exceptional lysogens carrying two or more int prophages may be obtained: they may produce spontaneously even more phage than normal lysogens, and they segregate out defective, singly lysogenic clones at low frequency. These exceptional lysogens carry both prophages in location I, presumably in tandem.Strains carrying two or more int prophages but defective in phage production were also isolated. One of these carries its prophages at two different, not closely linked, chromosomal locations.     

Influence of Transformability on the Formation of Superinfection Double Lysogens in Haemophilus influenzae

Superinfection of growing (nontransformable) cells of defectively lysogenic strains of Haemophilus influenzae with wild-type or with mutant phage HP1 resulted in a number of double lysogens and a small number of monolysogens with altered prophage. The double lysogens were identified by analysis of their monolysogenic segregants and by examining their deoxyribonucleic acid in certain test crosses. The results indicate that the majority had been formed by insertion of the infecting phage genome within the resident prophage. Superinfection of transformable bacteria gave rise to cells with altered prophages (presumably transformants) and to double lysogens which had gained or lost wild-type prophage loci.     

Inactivation of prophage in ultraviolet-irradiated Escherichia coli: dependence on recA gene activity.

The fate of the prophage part of the lysogenic chromosome was followed in the course of post-ultraviolet incubation. For this purpose, lambda cI857 ind prophage, which can be induced by heat but not by ultraviolet light, was used. The prophage, intially more resistant than its repair-proficient host cell, was rapidly inactivated. This inactivation was not caused by the impaired capacity of irradiated cells to support growth of the phage. Over the entire dose range tested, little, if any, sensitivity difference between the host and the prophage was found at the end of cell division delay. Rapid inactivation of the prophage was also observed in uvr cells after small doses of ultraviolet light. The same small doses did not cause inactivation in lysogens carrying a mutation in the gene recA. This suggests that the functional gene recA is required for inactivation of the prophage part of the lysogenic chromosome.     

Evidence that the outer membrane protein gene nmpC of Escherichia coli K-12 lies within the defective qsr'' prophage.

Recombinants between phage lambda and the defective qsr' prophage of Escherichia coli K-12 were made in an nmpC (p+) mutant strain and in the nmpC+ parent. The outer membrane of strains lysogenic for recombinant qsr' phage derived from the nmpC (p+) strain contained a new protein identical in electrophoretic mobility to the NmpC porin and to the Lc porin encoded by phage PA-2. Lysogens of qsr' recombinants from the nmpC+ strain and lysogens of lambda p4, which carries the qsr' region, did not produce this protein. When observed by electron microscopy, the DNA acquired from the qsr' prophage showed homology with the region of the DNA molecule of phage PA-2 which contains the lc gene. Relative to that of the recombinant from the nmpC (p+) mutant, the DNA molecule of the recombinant from the nmpC+ parent contained an insertion near the lc gene. These results were supported by blot hybridization analysis of the E. coli chromosome with probes derived from the lc gene of phage PA-2. A sequence homologous to the lc gene was found at the nmpC locus, and the parental strains contained an insertion, tentatively identified as IS5B, located near the 3' end of the porin coding sequence. We conclude that the structural gene for the NmpC porin protein is located within the defective qsr' prophage at 12.5 min on the E. coli K-12 map and that this gene can be activated by loss of an insertion element.     

The CI repressors of Shiga toxin-converting prophages are involved in coinfection of Escherichia coli strains, which causes a down regulation in the production of Shiga toxin 2

Shiga toxins (Stx) are the main virulence factors associated with a form of Escherichia coli known as Shiga toxin-producing E. coli (STEC). They are encoded in temperate lambdoid phages located on the chromosome of STEC. STEC strains can carry more than one prophage. Consequently, toxin and phage production might be influenced by the presence of more than one Stx prophage on the bacterial chromosome. To examine the effect of the number of prophages on Stx production, we produced E. coli K-12 strains carrying either one Stx2 prophage or two different Stx2 prophages. We used recombinant phages in which an antibiotic resistance gene (aph, cat, or tet) was incorporated in the middle of the Shiga toxin operon. Shiga toxin was quantified by immunoassay and by cytotoxicity assay on Vero cells (50% cytotoxic dose). When two prophages were inserted in the host chromosome, Shiga toxin production and the rate of lytic cycle activation fell. The cI repressor seems to be involved in incorporation of the second prophage. Incorporation and establishment of the lysogenic state of the two prophages, which lowers toxin production, could be regulated by the CI repressors of both prophages operating in trans. Although the sequences of the cI genes of the phages studied differed, the CI protein conformation was conserved. Results indicate that the presence of more than one prophage in the host chromosome could be regarded as a mechanism to allow genetic retention in the cell, by reducing the activation of lytic cycle and hence the pathogenicity of the strains.     

Efficiency of induction of prophage lambda mutants as a function of recA alleles.

Mutants of the cI gene of prophage lambda have been defined phenotypically in a recA+ host as noninducible (Ind-), inducible (Ind+), or induction sensitive (Inds). We showed that a phage lambda cI+ carrying operator mutations v2 and v3 displays an Inds phenotype, as does lambda cI inds-1. We characterized a fourth induction phenotype called induction resistant (Indr). Using these four prophage types, we tested the influence of bacterial recA mutations on prophage induction. Indr prophages were fully induced in recA441 bacteria whose RecA441 protein is activated constitutively. Indr prophages were not induced in a mutant overproducing RecA+ protein, confirming that RecA+ protein must be activated to promote prophage induction. Inds prophages were induced in recA142 and recA453-441 lysogens, previously described as deficient in prophage induction.     

Formation and genetic structure of polylysogens for lambda and phi 80 and their lambda att80 hybrid infecting wild-type Escherichia coli

The frequency of polylysogeny and the genetic structure of polylysogens were studied for phages lambda, phi 80 and lambda att80. For none of these phages does frequency of polylysogeny vary by more than a factor of 2 within a wide range of multiplicities of infection (from 10(-3) up to 10) but the relative location of the prophages on the host chromosome is different. In the case of lambda, polylysogens are formed with a high frequency (0.20-0.41) and the prophages are inserted in tandem into the primary (normal) att site. In the case of phi 80 and lambda att80, polylysogens occur about 10 times less frequently and usually have one prophage inserted into the primary attachment site and another (sometimes, also a third) in one of the secondary ones. Wild-type Escherichia coli was shown to possess at least four secondary att80 sites, two of which (close to the his and tolC loci) are preferred. The frequency of secondary integration of phi 80 and lambda att80 does not differ significantly in the wild-type host and in cells deleted for the primary att site (0.041 and 0.045, respectively, among surviving cells at MOI 10). Certain properties of the phi 80 lysogens make it more difficult to decode their genetic structure.     

Reproductive fitness of P1, P2, and Mu lysogens of Escherichia coli.

P1, P2, and Mu lysogens of Escherichia coli reproduce more rapidly than nonlysogens during aerobic growth in glucose-limited chemostats. Thus, prophage-containing stains of E. coli are reproductively more fit than the corresponding nonlysogens. If mixed populations are grown by serial dilution under conditions in which growth is not limited, both the lysogen and nonlysogen manifest identical growth rates. The increased fitness of the lysogens in glucose-limited chemostats correlates with a higher metabolic activity of the lysogen as compared with the nonlysogen during glucose exhaustion. We propose that P1, P2, Mu, and lambda prophage all confer an evolutionarily significant reproductive growth advantage to E. coli lysogenic strains.     

Carbohydrate metabolism and transport in Bacillus subtilis. A study of ctr mutations

Summary Indirect ultraviolet induction of prophage occurs when lysogenic E. coli K12 cells are mated with ultraviolet-irradiated donor strains carrying a transmissible episome such as F lac ⁺. Indirect induction occurs in wild type, uvrA, or recB recipient lysogens, but not in recA lysogens. When nonpermissive lysogens carrying prophages susO or susP are similarly mated, the defective prophages are induced and indirect curing takes place.Although indirect induction is independent of the capacity of the lysogen for repair by pyrimidine dimer excision, indirect curing (and hence indirect induction) is subject to photoreactivation when the recipient lysogen is exposed to visible light after mating. This confirms that the structure initiating indirect ultraviolet induction is a damaged transferred episome consisting of one DNA strand containing ultraviolet photoproducts and a newly synthesized discontinuous DNA strand such that pyrimidine dimers remain in single-stranded regions.F^- lac ⁺ recombinants are formed in either nonlysogenic or lysogenic Lac^- cells receiving damaged F lac ⁺ episomes from ultraviolet irradiated F lac ⁺ donors. prophage induction occurs more frequently in zygotes that form Lac⁺ recombinants than in zygotes that remain Lac^-. In contrast, cells receiving intact (undamaged) episomes are converted to F lac ⁺ secondary donors, but are rarely induced or cured.     

Transposition of the heat-stable toxin astA gene into a gifsy-2-related prophage of Salmonella enterica serovar Abortusovis

The horizontal transfer and acquisition of virulence genes via mobile genetic elements have been a major driving force in the evolution of Salmonella pathogenicity. Serovars of Salmonella enterica carry variable assortments of phage-encoded virulence genes, suggesting that temperate phages play a pivotal role in this process. Epidemic isolates of S. enterica serovar Typhimurium are consistently lysogenic for two lambdoid phages, Gifsy-1 and Gifsy-2, carrying known virulence genes. Other serovars of S. enterica, including serovars Dublin, Gallinarum, Enteritidis, and Hadar, carry distinct prophages with similarity to the Gifsy phages. In this study, we analyzed Gifsy-related loci from S. enterica serovar Abortusovis, a pathogen associated exclusively with ovine infection. A cryptic prophage, closely related to serovar Typhimurium phage Gifsy-2, was identified. This element, named Gifsy-2AO, was shown to contribute to serovar Abortusovis systemic infection in lambs. Sequence analysis of the prophage b region showed a large deletion which covers genes encoding phage tail fiber proteins and putative virulence factors, including type III secreted effector protein SseI (GtgB, SrfH). This deletion was identified in most of the serovar Abortusovis isolates tested and might be dependent on the replicative transposition of an adjacent insertion sequence, IS1414, previously identified in pathogenic Escherichia coli strains. IS1414 encodes heat-stable toxin EAST1 (astA) and showed multiple genomic copies in isolates of serovar Abortusovis. To our knowledge, this is the first evidence of intergeneric transfer of virulence genes via insertion sequence elements in Salmonella. The acquisition of IS1414 (EAST1) and its frequent transposition within the chromosome might improve the fitness of serovar Abortusovis within its narrow ecological niche.     

Base substitutions in transposable element IS1 cause DNA duplication of variable length at the target site for plasmid co-integration.

We demonstrate that base substitutions in the IS1 sequence affect the length of the nucleotide sequence which is duplicated during IS1-mediated co-integration. IS1K, an IS1 variant present in the Escherichia coli chromosome, has seven base substitutions in its sequence as compared with that of IS1R derived from the plasmid R100. All substitutions are located in the internal region of IS1K. We have constructed plasmids containing IS1R, IS1K and hybrids between them: one contains four base substitutions causing an amino acid substitution in the insA gene and the other has three substitutions producing an amino acid substitution in the insB gene. We have isolated co-integrate plasmids formed by each IS1 and analysed nucleotide sequences of the target sites duplicated at the co-integration junctions. The results show that IS1K generates duplications of 8 or 14 bp as well as 9 bp, while IS1R exclusively generates the 9-bp duplications. Both hybrid IS1s also create 8- or 7-bp target duplications in addition to 9-bp duplications. These results indicate that the base substitutions in either insA or insB are sufficient for the occurrence of unusual target duplications, suggesting that both genes are involved in the target duplication.     

Suppression of a thermosensitive dnaA mutation of Escherichia coli by bacteriophage P1 and P7.

Like other plasmids, the P1 and P7 prophages suppress E. coli dnaA(Ts) mutations by integrating into the host chromosome. This conclusion is supported by three lines of evidence: (1) Alkaline sucrose gradients reveal the absence of plasmid DNA in suppressed lysogens; (2) the prophage is linked to host chromosomal markers in conjugation; and (3) auxotrophs whose defect is linked to the prophage are found among suppressed colonies. No phage or bacterial mutation is required for suppression. Integrative suppression by P1 and P7, unlike suppression by F, does not require the host recA⁺ function. Among suppressed P7 lysogens are some that do not produce phage; these contain defective prophages. The genetic extent of the deletions contained by these defective prophages delineates the prophage regions which are not necessary for suppression of dnaA(Ts). The possible mechanisms of integration and deletion formation are discussed.     

Maintenance of bacteriophage P1 plasmid.

Three mutants of bacteriophage P1 affected in their ability to maintain the lysogenic state stably are described here. These mutants were normal in lytic growth, but lysogenic derivatives segregated nonlysogens at abnormally high rates (1 to 30% per division). Cells harboring these mutant prophages were elongated or filamentous. The mutations responsible for this prophage instability fell into two classes on the bases of their genetic location, their effect on the ability to lysogenize recA bacteria, and their suppressibility by ant mutations eliminating antirepressor activity. The two mutants that were able to form recA lysogens showed the same prophage instability and partial inhibition of cell division in recA as in rec+ lysogens. The fact that plasmid-linked mutations can cause prophage instability suggests that P1 codes for at least some of the functions determining its own autonomy and segregation.     

Stimulation of mutations suppressing the loss of replication control by small alcohols

Transient exposure of lysogenic Escherichia coli cells to small alcohols stimulated the frequency of mutations suppressing the lethal loss of replication control from a prophage fragment of bacteriophage lambda. The stimulation in mutation frequency paralleled the effect of mutagenic agents, and in this sense the alcohols behaved as mutagens. 10-min treatments above distinct threshold concentrations at 23%, 18%, 10% and 4% (v/v) were required in order for methanol, ethanol, isopropanol and propanol to evoke mutagenic effects. The selected mutant cells were, in general, equally or more sensitive to ethanol than the starting cells. The mutagenicity of methanol and ethanol was detected only with E. coli strains with lambda fragments that included the site-specific and general recombination genes found within the phage int-kil gene interval; whereas, stimulation of the frequency of phenotypically identical mutations by nitrosoguanidine or ionizing radiation did not require that the lambda fragment encode these genes. Treatments of lysogenic cells with mutagenic concentrations of ethanol did not trigger prophage induction and were concluded not to induce a cellular SOS response nor to denature the prophage repressor, or to disrupt repressor-operator binding. The toxicity of ethanol was pH-dependent. Cellular sensitivity to ethanol toxicity was unaffected by the integrated lambda fragment(s) or by an intact lambda prophage; but, it was increased by deletions of the E. coli chromosome extending rightward from bio into uvrB, and rightward from chlA.     

Integration of the related prophages lambda, phi 80 and their hybrid lambda att80 into the secondary chromosomal att sites of wild-type Escherichia coli

The family of lambdoid phages displays a varying specificity of integration into the host chromosome. The lambda phage DNA failed to get inserted at the secondary attachment site(s) of the gal operon (frequency less than 2.6 X 10(-8)) in the presence of the primary (normal) one. By contrast, phi 80 and the lambda att80 hybrid integrated into wild-type Escherichia coli at least, at two secondary att sites of the btuB locus, the latter phage being also capable of integration in the vicinity of purE and purC (frequency 2 X 10(-3) to 10(-4)). Integration of phi 80 and lambda att80 into btuB occurred with about the same frequency as in cells deleted for normal insertion site (0.7 divided by 4.0 X 10(-6)). An analysis of the secondary lysogens with the prophage in btuB showed them to be polylysogens; the additional prophage(s) was found in the primary att site. We also failed to observe integration of phi 80 and lambda att80 with formation of secondary monolysogens into other foci (frequency less than 0.0035, if multiplicity of infection was 10(-3) or 10). It is presumed that phi 80 and lambda att80 prophages get only integrated at secondary att sites in case the primary site is occupied.     

Operator-promoter functions in the threonine operon of Escherichia coli.

The prophage curing properties of secondary-site lysogens of coliphage lambda have been studied. The site of integration in the original lysogen (L79) is within the ooerator-promoter region of the thr operon. As a result, expression of the thr enzymes is reduced, and the strain is a leaky threonine auxotroph. Heat pulse curing of strain L79 and a thr+ lysogenic revertant (L79-20) showed that heat pulse curing of both lysogens was int and xis dependent and occurred by correct excisions of the prophage. The heat pulse curing restored strain L79 to prototrophy whereas strain L79-20 synthesized the thr enzymes constitutively and at high levels. This indicates that the reversion mutation in strain L79-20 occurred outside of the prophage and within the operator-promoter region of the thr operon. In contrast, spontaneous curing of both lysogens occurred by both correct and incorrect excisions. Spontaneously cured derivatives of strain L79-20 gave rise to three classes of regulatory mutants affecting operator and promoter functions to the thr operon.