Expression of the genome of Mu-like phage D3112 specific for Pseudomonas aeruginosa in Escherichia coli and Pseudomonas putida cells

The behavior of Escherichia coli cells carrying RP4 plasmid which contains the genome of a Mu-like D3112 phage specific for Pseudomonas aeruginosa was studied. Two different types of D3112 genome expression were revealed in E. coli. The first is BP4-dependent expression. In this case, expression of certain D3112 genes designated as "kil" only takes place when RP4 is present. As a result, cell division stops at 30 degrees C and cells form filaments. Cell division is not blocked at 42 degrees C. The second type of D3112 genome expression is RP4-independent. A small number of phage is produced independently of RP4 plasmid but this does not take place at 42 degrees C. No detectable quantity of the functionally active repressor of the phage was determined in E. coli (D3112). It is possible that the only cause for cell stability of E. coli (D3112) or E. coli (RP4::D3112) at 42 degrees C in the absence of the repressor is the fact of an extremely poor expression of D3112. In another heterologous system, P. putida both ways of phage development (lytic and lysogenic) are observed. This special state of D3112 genome in E. coli cells is proposed to be named "conditionally expressible prophage" or, in short, "conex-phage", to distinguish it from a classical lysogenic state when stability is determined by repressor activity. Specific blockade of cell division, due to D3112 expression, was also found in P. putida cells. It is evident that the kil function of D3112 is not specific to recognize the difference between division machinery of bacteria belonging to distinct species or genera. Protein synthesis is needed to stop cell division and during a short time period this process could be reversible. Isolation of E. coli (D3112) which lost RP4 plasmid may be regarded as an evidence for D3112 transposition in E. coli. Some possibilities for using the system to look for E. coli mutants with modified expression of foreign genes are considered.     

Features of genome expression of phage transposon D3112 of Pseudomonas aeruginosa in Escherichia coli bacteria: dependence of bacterial phenotype on copy number of D3112 genome]

Escherichia coli (RP4 :: D3112) bacteria manifest Tcs phenotype (thirty centigrade sensitivity), i.e. the cells do not divide and form colonies under conditions of lowered temperature (30 degrees C and lower), while cells grow normally at 42 degrees C. In this work it is demonstrated that replication-transposition of D3112 and the Tcs phenotype depend on no recA system of E.coli. Following events lead to the loss of the Tcs phenotype (in E.coli (RP4 :: D3112) cells survived after growing at 30 degrees C): occurrence of mutations in bacterial, phage and plasmid genomes, elimination of DNA of hybrid plasmid or RP4 DNA (a portion of DNA) as well as integration of the hybrid plasmid into bacterial chromosome. In the latter case, the E.coli (D3112) cells acquired the properties shared by the initial bacteria and those with the Tcs phenotype. Such clones are designated tcl (thirty centigrade low sensitivity), they are able to form colonies at 30 degrees C but their growth is more slow, they maintain instability at lowered temperature and continue to produce D3112 phage. The tcl clones in which replication-transposition of D3112 DNA in less effective than in the tcs clones are a suitable object for the study of genetic rearrangements caused by D3112 phage transposon. It is shown that either complete RP4 genome or its portion are comprised between direct repeats of D3112 and are built into various chromosomal sites, i.e. cointegrates are being formed. Two types of deletions are revealed: eliminating sites of RP4 plasmid adjacent to the left end of D3112 genome as well as deletions of the D3112 genome. It is demonstrated that alteration in the growth nature of E.coli, carrying D3112 DNA, at 30 degrees C depends on the copy number of D3112 per bacterial cell.     

Integration of phage Mu into the RP4::D3112A-plasmid in Escherichia coli cells

Hybrid plasmids obtained as a result of Mu phage insertions into the RP4::D3112 plasmid in Escherichia coli cells were studied. Stable maintenance of RP4::D3112 plasmid in E. coli cells was provided by using the D3112 phage genome with a point polar mutation in the A gene which prevented early genes' expression. The presence of D3112A- in the RP4 plasmid has been shown to have no effect on efficiency of phage Mu transposition into this plasmid. Moreover, RP4 and D3112 genomes were equivalent targets for Mu integration. The integration of transposable phage into genome of nonrelated phage can be used as one of the approaches to construct recombinant phage genomes in vivo in the absence of DNA homology.     

Compatibility of transposable phages of Escherichia coli and Pseudomonas aeruginosa. I. Co-development of phages Mu and D3112 and integration of phage D3112 into RP4::Mu plasmid in Pseudomonas aeruginosa cells

The possibility of using a model system (which included RP4::Mu plasmid and D3112 phage in Pseudomonas aeruginosa cells) for analysis of compatibility of transposable Escherichia coli phage Mu and P. aeruginosa phage D3112, as phages and transposons, was studied. No interaction was observed during the vegetative growth of phages. The majority of the hybrid RP4::Mu plasmids lost the Mu DNA after insertion of D3112 into RP4::Mu. The phenomenon was not a result of transposition immunity. We consider the loss of the Mu DNA as a consequence either of plasmid RP4::Mu instability in P. aeruginosa cells, because of the lack of functional Mu repressor, or of some D3112-encoded activity involved in its transposition. For the inambiguous conclusion on compatibility of two phages as transposons, it is necessary to modify the model system, eliminating the possibility of Mu phage replication--transposition.     

Effective, plasmid RP4-dependent replication-transposition of DNA of the transposable phage D3112 of Pseudomonas aeruginosa in a heterologous Escherichia coli system

The processes of replication and transposition of Pseudomonas aeruginosa transposable phage D3112 in cells of Escherichia coli (D3112) and E. coli (RP4::D3112) were studied. D3112 genome is a "silent cassette" ("conex-phage"--conditionally expressible) in E. coli cells incubated at 42 degrees C. Two compulsory conditions for D3112 genome expression are incubation at 30 degrees C and the presence in cells of RP4 plasmid. Processes of replication and transposition in E. coli are coupled. RP4 plasmid stimulates D3112 DNA synthesis in E. coli at least by two order of magnitude. In correspondence with this observation is the fact that when Mg2+ is present in high concentration (0.1 M) in a cultural medium, the production of mature phage is enhanced by two order of magnitude in E. coli (RP4::D3112) or in E. coli (D3112, RP4) cells, and is approx. 10(-1)-10(-2) phage per cell. No influence of Mg on phage production is observed in E. coli (D3112) cells.     

Insertion and replication of the Pseudomonas aeruginosa mutator phage D3112

D3112 is a temperate bacteriophage of P. aeruginosa with heterogeneous sequences at one extremity of the virion DNA molecule. Infection of strain PAOl with phage D3112 results in a 40- to 65-fold increase in the frequency of ami mutants resistant to fluoroacetamide. Nine ami::D3112 prophages have been mapped to distinct sites within the ami locus by Southern blotting experiments with a cloned ami+ probe. All prophages have the same restriction map as the D3112 genome extracted from phage particles. The position of D3112 insertions correlates with the phenotype and reversion behavior of the ami mutants. Induction of D3112cts prophages results in amplification of internal prophage segments as discrete restriction fragments before the terminal viral fragments are visible as sharp hybridizing species. This indicates that D3112 replication is accompanied by recombination of prophage termini to numerous sites in the bacterial genome. Chromosomal junction fragments of an ami::D3112cts prophage are maintained through most of the replication cycle but are cleaved shortly before cell lysis, apparently by the viral encapsidation system.     

Genetic map of the transposable phage D3112 of Pseudomonas aeruginosa

Using a large group of newly isolated deletion mutants of prophage D3112 the location of all known mutations of D3112 phage was more precisely defined. The mutations affecting establishment of lysogenic state were mapped in two regions of the genome- 0-1.3 and 29-30 kb. The replicative A gene is mapped between 1.3 and 4.9 kb, the second replicative B gene being situated on the right of the A gene, between 4.9 and 9.4 kb. The C gene which is responsible for positive regulation of phage late genes' expression is mapped within the 9-12 kb region. It is suggested that promoter of the gene C is situated within the same interval. Mutations were isolated in the Lys gene which is responsible for host cell lysis. The gene is located within the interval 14-22 kb of the physical map. The order of morphogenetic genes in the late genome region was also established.     

Introduction of the hybrid plasmid RP4::D3112 into Pseudomonas putida cells requires the presence of specific mutation in the phage genome

The wild type of D3112, a transposable phage of Pseudomonas aeruginosa can not be introduced as a portion of the hybrid plasmid RP4::D3112 into Pseudomonas putida cells. It is only possible when phage D3112 carries mutations designated lpc (lethal for P. putida and Escherichia coli). Analysis of heteroduplex molecules between DNAs of phages D3112w+ and D3112lpc demonstrated the absence of nonhomology regions, which suggests that lpc is a point mutation. The lpc2 mutation was located within the interval 20-29.9 kb of the phage genome.     

Genetic control of morphogenesis of Pseudomonas aeruginosa transposable phage D3112

The influence of ts mutations in the early and late genes of transposable phage D3112 on phage morphogenesis was studied. The mutations in the early genes A, B and C were shown to suppress morphogenesis of D3112. Six genes (D, E, F, G, H and I), located from 14 to 29 kbp of the phage physical map, control morphogenesis of phage head. Five genes (J, K, L, M and N), clustered in the 29-36 kbp region of the map, control morphogenesis of tail. The similarity of genetic organization of the Escherichia coli transposable phage Mu and the Pseudomonas aeruginosa phage D3112 is discussed.     

Coupling and rec-independence of the processes of replication and transposition of Pseudomonas aeruginosa phage D3112. The effect of the phage genes controlling the replication of DNA of D3112

D3112 phage was shown to replicate via the process of coupled replication--transposition: the phage DNA is not excised from the chromosome after prophage induction and new phage copies insert into many different sites. The transposition is controlled by two D3112 early genes--A (mapped in the 1.5-3 kbp region) and B (3-4.5 kbp), and requires intact attL site (involvement of the phage right end attR not studied). D3112 is capable to transpose RP4 plasmid into the chromosome; both the D3112 and RP4 transpositions are rec-independent. The product of the early C gene which is not required for D3112 transposition has pleiotropic effect on the development of D3112 and is necessary for the process of D3112 DNA excision from the chromosome, for cell lysis as well as for mature phage production. We suggest that this gene is responsible for positive regulation of D3112 late genes expression, similar to the C gene of Mu phage or Q gene of lambda. Mutations in four D3112 late genes ts25, ts35, ts73 and ts110 do not affect transposition or excision processes. No detectable (less than 0.02 copies per cell) amount of linear or circular D3112 DNA is formed during the replication--transposition. Hence, in the course of replication and transposition processes D3112 genome has its ends permanently bound covalently to the chromosome. The excision of the D3112 DNA takes place at late stages.     

Minigenomes of the transposable phage D3112 of Pseudomonas aeruginosa and their properties

Two derivatives of D3112 prophage with large internal deletions (mini-D3112) have been constructed. Mini-D3112 delta H is about 3.5 kb long, containing the repressor c1 gene. Mini-D3112 delta E is about 12 kb long, contains the c1 gene, several structural genes and replication gene A. These mini-D3112 are unable to replicate. However, they could replicate and maturated in the presence of the helper D3112cts. Mini-D3112 mediate translocation of the gene argH from the chromosome into the R' plasmids, the translocated fragment being sandwiched between two mini-D3112 genomes.     

Transposition of the Tn5 and Tn10 elements and duplications in Escherichia coli K12 genome

The kinetics of accumulation of resident transposon copies in a dividing population has been defined using a special experimental system. Analysis of the kinetics made it possible to estimate the probability of transposition for Tn5 as 2.5 X 10(-4) and for Tn10 as 2.3 X 10(-6) per cell per generation. Transposition of the composite elements does not depend on RecBC or RecF pathways of recombination. The fraction of the bacterial population with tandem duplications in the proA region of the genome is permanent for Escherichia coli. It is independent of the recombination pathways (RecBC of RecF) and the integrity of DNA polymerase I.     

Organization of the Escherichia coli genome

A review of literature data reveals that for the last years, the molecular biology techniques have been of an increasing use in the study of the Escherichia coli genome, having supplemented the standard genetic mapping. For the proper understanding of the Escherichia coli genome organization, recombinational events occurring in the course of evolution should be considered. The bacterial genome seems to carry traces of both "long-term" evolution, possibly responsible for appearance of the bacterial cell itself, and "current" evolution, consisting mainly of periodic genome entering by new plasmid-originated genes. It is supposed that in the process of stabilization within a genome, every new gene undergoes a stage of the "transgene", that is the gene situated in a transposon on the chromosome. In parallel with integration of new genes into the genome, some genes deleting should also take place. The formation of deletions could occur by unequal crossing over in segments of direct homologous repeats which seem to be ordinarily revealed in the experimental study of the tandem gene duplications.