Integration of bacteriophages lambda and phi 80 in wild-type Escherichia coli at secondary attachment sites. II. Genetic structure and mechanism of polylysogen formation for lambda, phi 80 and the lambda att80 hybrid

Summary The frequency of occurrence and the genetic structure of polylysogens were studied for phages , 80 and att80. In the case of , frequency of polylysogenization is high (0.20 to 0.41) with a tandem integration of prophages at the primary att site (att). With 80 and att80, this frequency is about 10 times lower, and usually one prophage becomes integrated at the primary att site (att80-I) while another (sometimes two others) integrates at one of the secondary sites. At least four secondary att80 sites have been found in wild-type Escherichia coli , two of which (near the his and tolC loci) are preferred. The frequency of secondary integration of 80 and att80 does not differ significantly in the wild-type host and in that deleted for the primary att site (0.041 and 0.045, respectively, among surviving cells at an MOI of 10).Homoimmune superinfection has revealed a constitutive cI-independent expression of the 80 int gene in the prophage state. The only 80 tandem detected proved to be unstable. With the 80int ^- mutant, we observed stabilization of 80 tandems; as a consequence, their frequency of occurrence during coinfection with 80int ⁺ was up to the level and no nontandem insertions were found. A model is proposed for the 80 and att80 nontandem integration.Abbreviations TP transducing phage(s) - PFU plaque-forming units - PC pink clear-resistant colonies on EMBO plates - MOI multiplicity of infection - O origin of Hfr transfer

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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.     

Integration of bacteriophages lambda and phi 80 in wild-type Escherichia coli at secondary attachment sites. I. Formation of secondary lysogens

Summary The family of lambdoid phages displays a varying specificity of integration into the host chromosome. The phage DNA failed to get inserted at the secondary site(s) of the gal operon (frequency <2.6x10^-8) in the presence of the primary (normal) att site. By contrast, 80 and the att80 hybrid (x80) became integrated into wild-type Escherichia coli at at least two secondary att sites of the btuB locus, and the latter near purE and purC as well (frequency 2x10^-3-10^-4). The integration of 80 and att80 into btuB occurred with about the same frequency as in cells in which the normal insertion site had been deleted (0.7-4.0x10^-6). An analysis of the secondary lysogens with the prophage in btuB showed them to be polylysogens; the additional prophage(s) was found at the primary att site. We also failed to observe the integration into other loci of 80 and att80 with the formation of secondary monolysogens (frequency <0.0035 at MOI-10^-3 or 10). It is presumed that these prophages become integrated at secondary att sites only if the primary site is occupied.Abbreviations MOI multiplicity of infection (PFU/cell) - PFU plaque-forming unit - TP transducing phage - P1/HfrH P1vir multiplied on HfrH - Rif-R rifampin-resistance - Int int protein     

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.     

Mechanism of non-tandem integration of prophage phi 80 into the chromosome of the wild-type Escherichia coli

We studied the ability of lambda, phi 80 and their hybrid lambda att80 to lysogenize homoimmune monolysogens and examined the prophage locations on the chromosome of the resulting polylysogens. We observed an effective integration of phi 80 and lambda att80, in contrast to lambda, into the host chromosome, exclusively, at the attachment sites that were not occupied by the resident prophage (nontandem). Besides, the lambda att80 (int+) prophage was observed to ensure effective nontandem integration of a homoimmune int mutant DNA. Hence, we inferred that the expression of the int gene in the phi 80 prophage is constitutive, cI-independent and results in nontandem integration of the homoimmune prophage. The validity of this inference has been supported experimentally: (i) the only lysogen that was found to contain a phi 80 tandem was highly unstable (spontaneous segregation of monolysogens occurred 6-7 times more frequently than with the lambda tandem); (ii) an int inactivating mutation stabilized the phi 80 tandem; as a result, the int mutant has the frequency of tandem integration as high as that of lambda, while no nontandem integration was observed. A hypothesis is proposed which accounts for the instability of the phi 80 tandems and explains the relation between this phenomenon and the prophage ability to integrate into secondary attachment sites in the presence of the primary (normal) one.     

Integration of the plasmid prophages P1 and P7 into the chromosome of Escherichia coli.

The prophages of the related temperate bacteriophages P1 and P7, which normally exist as plasmids, suppress Escherichia coli dnaA (ts) mutants by integrating into the host chromosome. The locations of the sites on the prophage used for integrative recombination were identified by restriction nuclease analysis and DNA-DNA hybridization techniques. The integration of P1 and P7 often involves a specific site on the host DNA and a specific site on the phage DNA; the latter is probably the end of the phage genetic map. When this site is utilized, the host Rec⁺ function is not required. In Rec⁺ strains, P1 and P7 may also recombine with homologous regions on the host chromosome; at least one of these regions is an IS1 element. In some integration events, prophage deletions are observed which are often associated with inverted repeat structures on the phage DNA. Thus, P1 and P7 may employ one of several different mechanisms for integration.     

DNA targets for the Escherichia coli K restriction system analysed genetically in recombinants between phages phi80 and lambda

Summary Genetic analyses demonstrate the segregation of three targets for the K restriction system in h ⁸⁰ i hybrid phages. Mutations in each of these three targets have been isolated and shown to confer resistance in cis but not in trans. Two of the three targets (sk-1 and sk-2) have been located on the genome: sk-1 is right of gene R and sk-2 is between genes cIII and N. The third target is in the phi80 genome right of, but close to, att. Phage lacking both sk-1 and sk-2 retains at least 3 targets for the K restriction system.     

Preferred secondary attachment site of prophage phi80 on Escherichia coli K-12 chromosome]

The integration frequency of phage att80 immlambdac1857 into the chromosome of a mutant strain H47 Escherichia coli K-12 deleted for the normal prophage insertion site is found to be about 20-fold decreased as compared with its integration into the wild type strain. The most of the resulting lysogens contain the prophage at the secondary attachment site of the mutant bacterial chromosome which is preferentially utilized for prophage insertion. This attachment site (att80-II) is located close to his-genes on the chromosome of H47 strain. Prophage curing procedure of such abnormal lysogens results in the appearance of rare auxotrophic heat-resistant survivors with the His- phenotype. In some cases the prophage insertion can induce an inversion of a neighbouring genetic region. Such lysogens contain the purC gene near prophage located at the att80-II site, and after curing they segregate the heat-resistant His- and Pur- colonies.     

Lambda H-lambda T 80 hybrid study of the DNA structural gene region in lambda and phi 80 phages

Hybrids lambda H lambda T80 are formed due to recombination of the phage lambda att80 and phi 80 prophage partially deleted in the region of structural genes. Genetic structure of 22 independently isolated lambda H lambda T80 hybrids was determined by the restriction method and it was shown that recombination took place in the genes A, C, D and H. The frequencies of hybrid formation diminish from 1.10(-3) to 4.10(-5) for this gene order, which suggests that the polar divergence of nucleotide sequencies in the region of structural genes exists. It was found that formation of hybrids with recombination in the region of "weak" homology (gene H) was possible only when the region of "strong" homology was present in the deleted phi 80 prophage to initiate recombination.     

Analysis of insertions of the determinant of drug resistance to kanamycin and chloramphenicol into bacteriophage lambda att80

The insertion sites of elements Tn9 and Tn601 which determine chloramphenicol and kanamycin resistance have been detected restriction analysis. The functioning of transposons i.e. their stability or instability, has been found to influence the specificity of their insertions into the genome of lambda att80 bacteriophage. During transposition from stable integration sites both transposons are inserted into the regions of the lambda att80 bacteriophage genome, definite for each transposon. However, during transposition from the site of unstable integration both determinants of drug resistance are inserted into different regions of the phage genome.     

Evidence for common binding sites for ferrichrome compounds and bacteriophage phi 80 in the cell envelope of Escherichia coli.

Mutants ton A and ton B of Escherichia coli K12, known to be resistant to bacteriophage phi80, were found to be insensitive as well to albomycin, an analogue of the specific siderochrome ferrichrome. Ferrichrome at micromolar concentrations strongly inhibited plaque production by phi80. Preincubation with ferrichrome did not inactivate the phage. At a concentration at which ferrichrome allowed 90% inhibition of plaque formation, the chromium analogue of ferrichrome showed no detectable activity. Similarly, ethylenediaminetetraacetic acid, ferrichrome A, and certain siderochromes structurally distinct from ferrichrome, such as ferrioxamine B, schizokinen, citrate, and enterobactin, did not show detectable inhibitory activity. However, rhodotorulic acid showed moderate activity. A host range mutant of phi80, phi80h, was also inhibited by ferrichrome, as was a hybrid of phage lambda possessing the host range of phi80. However, phage lambdacI- and a hybrid of phi80 possessing the host range of lambda were not affected by ferrichrome. Finally, ferrichrome and chromic deferriferrichrome were shown to inhibit adsorption of phi80 to sensitive cells, ferrichrome giving 50% inhibition of adsorption at a minimal concentration of 8 nM. It is suggested that a component of the ferrichrome uptake system may reside in the outer membrane of E. coli K12 and may also function as a component of the receptor site for bacteriophage phi80, and that ferrichrome inhibition of the phage represents a competition for this common site.     

The phi 80 and P22 attachment sites. Primary structure and interaction with Escherichia coli integration host factor

Although the lambdoid bacteriophage phi 80 and P22 possess site-specific recombination systems analogous to bacteriophage lambda, they have different attachment (att) site specificities. We have identified and determined the nucleotide sequences of the att sites of phi 80 and P22 and have examined the interaction of these sites with purified Escherichia coli integration host factor (IHF). The sizes of the homologous core regions of the att sites vary greatly: P22 has a 46-base pair core, while phi 80 and lambda have 17- and 15-base pair cores, respectively. The core sequences of the three phage show no significant homology, although dispersed regions of homology in arm sequences indicate that the three phage att sites are related. All three att sites have a high A + T composition, and restriction fragments carrying these sites migrate anomalously upon polyacrylamide gel electrophoresis. IHF binds to a site to the left of the common core in the phi 80 and P22 phage att sites (attP) and to a site to the right of the core in P22 attP and attB (the bacterial att site). In the lambda system, IHF interacts with three regions on attP (designated H1, H2, and H') and none on attB (Craig N., and Nash, H.A. (1984) Cell 39, 707-716). Alignment of the IHF sites of all three phage results in a consensus sequence for IHF binding, Pyr-AANNNNTTGATAT. Among the three phage, the number of IHF sites differs; however, the location and orientation of the binding sites in relation to the respective core regions are well conserved. An IHF site analogous to lambda H2 is present in both phi 80 and P22 attP, while a site analogous to lambda H' is present in P22 attP. This conservation suggests that IHF plays a very similar role in the site-specific recombination pathways of all three phage, and that the flanking arm sequences are necessary for phi 80 and P22 attP function, as is the case for lambda attP function. These structural similarities presumably reflect a conservation of the mechanism of site-specific recombination for the three phage.     

Specificity of Tn9 insertion into the genome of bacteriophage lambda att80 depending on its preceding location

It was shown that the site of previous integration (the donor site) of Tn9 affects the specificity of its next integration into the target molecule--phage lambda att80 DNA. The transposon integration sites were mapped by restriction and heteroduplex analysis following Tn9 transposition from chromosomal sites of Escherichia coli K-12 differing in location and Tn9 stability. When transposed from chromosomal galT::IS1 gene, Tn9 inserted into the site with coordinates 44,5 +/- 2 kb of lambda att80; when transposed from chromosomal attTn9A site, the transposon inserted into the sites with coordinates 31 +/- 0,7 kb or 33,3 +/- 0,5 kb. In the course of transposition of Tn9 from chromosomal attTn9N site the transposon inserted into the lambda att80 site with coordinates 26,5 +/- 5 kb. In the latter case, the increase of Tn9 single-stranded loop and the appearance of two new HindIII cleavage sites were observed in heteroduplex experiments. The data were interpreted as indicating structural rearrangements of Tn9 or linked sequences in the course of transposition.     

Site-specific recombination in Escherichia coli between the att sites of plasmid pSE211 from Saccharopolyspora erythraea

Summary pSE211 fromSaccharopolyspora erythraea integrates site-specifically into the chromosome through conservative recombination betweenattP andattB, the plasmid and chromosomal attachment sites. Integration depends on the presence ofint, an open reading frame (ORF) that lies adjacent toattP and encodes the putative integrase. Immediately upstream ofint liesxis (formerly calledorf2) which encodes a basic protein that is thought to exhibit DNA binding.xis andint were cloned in various combinations in pUC18 and expressed constitutively inEscherichia coli from thelac promoter.attP andattB were cloned inStreptomyces orE. coli plasmids containing kanamycin resistance (Km^R) or chloramphenicol resistance (Cm^R) markers. Stable Km^R Cm^R cointegrates formed byattP ×attB orattP ×attP recombination (integration) were obtained inE. coli hosts that expressedint. Co-integrates were not found in hosts expressingint+xis. Excision (intraplasmidatt site recombination) was examined by constructing plasmids carryingattL andattR or twoattP sites separating Cm^R from Km^R and by following segregation of the markers in various hosts. BothattL ×attR andattP ×attP excision depended on bothxis andint inE. coli. pSE211att site integration and excision were not affected by a deletion inhimA, the gene encoding a subunit of integration host factor.     

Prophage lambda at unusual chromosomal locations: III. The components of the secondary attachment sites

The integration of phage λ occurs by a reciprocal genetic exchange, promoted by the product of phage int gene, at specific sites on the phage and bacterial genomes (att's). Lysogenic bacteria thus contain two att's which bracket the inserted prophage. Genetically, the phage, bacterial and prophage att's differ from each other, indicating that each site has specific elements which segregate during recombination.In hosts that lack the bacterial att, phage integration occurs at about 0.5% the normal frequency. It results from Int-promoted recombination between the phage att and any one of many secondary sites in the bacterial genome. To analyze these sites, we measured Int-promoted recombination at the secondary prophage att's. We found that they differed from the normal prophage att's and from the phage att. The secondary sites, therefore, do not appear to carry any of the specific elements of the phage or bacterial att's.The transducing phage isolated from secondary site lysogens integrate at two loci. In the absence of helper, they insert via homology with the bacterial DNA. Co-infection with helper results in their integration at the normal bacterial att.     

Isolation of Escherichia coli K-12 mutants that affect the development of phage phi m173 (imm phi 80)

Escherichia coli mutants which block the development of a number of lambdoid phages, particularly, phi m173 and phi 80 were selected. These mutants have different phenotypes, being resistant to different groups of lambdoid phages. There are also differences between new mutants and gro mutants of E. coli studied earlier. The results obtained support the suggestion that no replication of different lambdoid phages takes place in these mutants.