Genetic analysis of heterogeneous DNA circles formed after prophage Mu induction.

Induction of a Mu prophage in Escherichia coli Hfr strains lyosgenic for Mu cts62 leads to the generation of F' episomes. Each episome thus formed carries at least one copy of the Mu genome. These results suggest that integration of Mu is mandatory for the formation of the heterogeneous circles during the lytic cycle. The circles may be precursors for phage maturation.     

The sensitivity of Yersinia to bacteriophage Mu

Various representatives of the genus Yersinia were found to differ in their sensitivity to the lytic action of bacteriophage Mu cts62, which could serve as an auxiliary test for the differentiation of Y. pestis and Y. pseudotuberculosis. Among the strains under study, the causative agents of plague (34 strains) were sensitive to phage Mu cts62, while the causative agents of enteric yersiniosis (42 strains) and pseudotuberculosis (73 strains), except 3 strains with the properties of Y. pestis, were resistant to this phage.     

Erwinia carotovora as a recipient system for the natural hybrid plasmid RP4::Mu cts62

The plasmid RP4::Mu cts62 is transferred from Escherichia coli cells into a recipient strain Erwinia carotovora 268 by conjugation with the frequency 1.5-5 x 10(-7) per donor cell. The maximal frequencies of transfer are obtained by cultivation of donor and recipient cells for 3-5 h on the filters. Structural and functional validity of the plasmid in transconjugants is expressed in preservation of all antibiotic-resistant markers of RP4, thermosensitivity to growth at 42 degrees C as well as spontaneous and thermally-induced production and zygotic induction of bacteriophage determined by the genome of Mu cts62, total length of the plasmid restricts. Location and orientation of Mu cts62 genome in the plasmid restricts. Location and orientation of Mu cts62 genome in the plasmid RP4::Mu cts62 in Erwinia carotovora transconjugant cells has been determined. A single bacteriophage genome has been shown to transpose into the chromosome of the cell with the elimination of RP4 fragment under the conditions of thermal induction.     

Mutagenesis of Erwinia carotovora subsp. carotovora with bacteriophage Mu d1 (Apr lac cts62): construction of his-lac gene fusions.

The bacteriophage Mu d1(Apr lac cts62 ) obtained from an Escherichia coli double lysogen carrying the defective Mu d1 phage and a Mu-P1 hybrid phage was utilized as a vector for phage mutagenesis in Erwinia carotovora subsp. carotovora. Among ampicillin-resistant transductants. 1.4% were auxotrophs. The synthesis of beta-galactosidase was derepressed upon starvation for histidine in two different his-lac fusion strains.     

Inversion induced by temperature bacteriophage mu-1 in the chromosome of Escherichia coli K-12.

Induction of the Mu prophage of a lysogenic HfrP4X strongly stimulates the early transfer of the purE gene, which is located far from the origin of transfer. By using a rec- Mu cts62 X lysogenic donor, it was established that this process reflects the inversion of the origin of transfer in part of the Hfr population. Hfr's with inverted polarity of gene transfer were isolated; their analysis suggests that two Mu genomes in opposite orientation surround the inverted DNA fragment. Due to the presence of the Mu genome of the invertible G segment, homologous regions in the same orientation can appear in Mu genomes in opposite orientation. In a Rec+ background, Hfr's with inverted polarity (i) return to their original polarity of transfer by recomination between the two inverted Mu and (ii) produce new F' strains by recombination between the two similarly oriented G segments.     

Events following prophage Mu induction.

Escherichia coli strains lysogenic for a thermoinducible Mu prophage (Mu cts62) undergo rapid lysis about 50 min after heat induction. Induction of Mu cts62 apparently causes damage to the host sequences in which Mu is inserted. The normal expression of A, BU, and X genes of Mu is needed for this specific deleterious effect on the prophage-containing host sequences. Mu deoxyribonucleic acid can be shown to reintegrate extensively at different sites on the host genome during the lytic cycle after prophage induction or after infection of sensitive cells by clear-plaque mutants of Mu. We estimate that approximately 10 copies of Mu deoxyribonucleic acid are inserted per chromosome during vegetative growth. The episome rescue method for detecting vegetative Mu deoxyribonucleic acid insertion, in which an episome is transferred from the lytically infected cells to F- receipient cells, can be applied to study Mu integration without requiring the host cells to survive. It also provides an easy system to isolate Mu insertions in transmissible episomes and plasmids.     

Introduction of bacteriophage Mu into bacteria of various genera and intergeneric gene transfer by RP4::Mu.

The host range of coliphage Mu was greatly expanded to various genera of gram-negative bacteria by using the hybrid plasmic RP4::Mu cts, which is temperature sensitive and which confers resistance to ampicillin, kanamycin, and tetracycline. These drug resistance genes were transferred from Escherichia coli to members of the general Klebsiella, Enterobacter, Citrobacter, Salmonella, Proteus, Erwinia, Serratia, Alcaligenes, Agrobacterium, Rhizobium, Pseudomonas, Acetobacter, and Bacillus. Mu phage was produced by thermal induction from the lysogens of all these drug-resistant bacteria except Bacillus. Mu phage and RP4 or the RP4::Mu plasmid were used to create intergeneric recombinant strains by transfer of some genes, including the arylsulfatase gene, between Klebsiella aerogenes and E. coli. Thus, genetic analysis and intergeneric gene transfer are possible in these RP4::Mu-sensitive bacteria.     

The genetic transfer, heredity and phenotypic expression of plasmid RP4::Mu cts genes in Bacillus cereus

The transcipients were obtained in intrageneric matings of E.coli donor harbouring the plasmid PR4::Mu cts 62 with Bac. cereus GP7 recipient cells with the frequency 10(-9). The transcipient clone Bac. cereus 682 was selected having stably inherited and expressed the hybrid plasmid PR4::Mu cts 62 genes for antibiotic resistance and temperature sensitivity. Production of the bacteriophage Mu cts 62 particles was not registered in the bacillary transcipient cells. The plasmid RP4::Mu cts 62 genes were localized in the chromosome of Bac. cereus 682 transcipient by the blot-hybridization technique with 32P-labelled DNA of the bacteriophage Mu cts 62 and the plasmid PR4. The transcipient of Bac. cereus 682 has the donor properties and transfers the RP4::Mu cts 62 genes to recipient cells of Bac. cereus DSM 318 with the frequency of 10(-6)-10(-7). The expression and transfer of the gram-negative plasmid genes in gram-positive bacterial cells are discussed.     

Conditionally transposition-defective derivative of Mu d1(Amp Lac).

A Mu d1 derivative is described which is useful for genetic manipulation of Mu-lac fusion insertions. A double mutant of the specialized transducing phage Mu d1(Amp Lac c62ts) was isolated which is conditionally defective in transposition ability. The Mu d1 derivative, designated Mu d1-8(Tpn[Am] Amp Lac c62ts), carries mutations which virtually eliminate transposition in strains lacking an amber suppressor. In such strains, the Mu d1-8 prophage behaves like a standard transposon. It can be moved from one strain of Salmonella typhimurium to another by the general transducing phage P22 with almost 100% inheritance of the donor insertion mutation. When introduced into a recipient carrying supD, supE, or supF, 89 to 94% of the Ampr transductants were transpositions of the donor Mu d1-8, from the transduced fragment into new sites. The stability of Mu d1-8 in a wild-type, suppressor-free background was sufficient to permit use of the fusion to select constitutive mutations without prior isolation of deletions to stabilize the fusion. Fusion strains could be grown at elevated temperature without induction of the Mu d prophage. The transposition defect of Mu d1-8 was corrected by a plasmid carrying the Mu A and B genes.     

Conjugation in Rhodopseudomonas sphaeroides mediated by R plasmids

Plasmids R68.45, RP4, RP4::Mu cts62, RP1ts::Tn10, RP1ts::Tn9, Rts1 and RP41 were transferred into cells of photosynthetic nitrogen-fixation bacterium Rhodopseudomonas sphaeroides from Escherichia coli and Pseudomonas aeruginosa. The transfer of plasmids occurred with high frequency of 10(-1) to 10(-2) per donor cell in all cases. Mobilization of R. sphaeroides 2R chromosome was obtained by RP4 and Rts1 plasmids at a frequency of 10(-7) to 10(-8) per donor cell in all cases. Mobilization of R. sphaeroides 2R chromosome was obtained by RP4 and Rts1 plasmids at a frequency of 10(-7) to 10(-8) per donor cell. Bacteriophage Mu cts62 could be induced from the plasmid DNA in R. sphaeroides 2R cells and was capable of the lytic growth and producing phage progeny. It was demonstrated that an increase in the efficiency of donor chromosomal genes transfer into recipient cells could be achieved in crosses with the donor carrying RP4::Mcts62 plasmid.     

Genetic study of the effect of lambda phage on Mu phage production in Escherichia coli K-12 strains with Mu--lambda--Mu structures

The interaction of temperate bacteriophages Mu and lambda is studied during their simultaneous induction in specially constructed heterolysogenic strains of Escherichia coli bearing trimeric Mu--lambda--Mu structures. These strains were obtained by the MU-mediated integration of phage lambda circular genomes. Heterolysogenic strains of E. coli were used for studying phage lambda eliminating effect on Mu development with a simultaneous induction of prophages in the same cell. The results of the study allow the localization of the region of phage lambda genome incorporating gene (genes) lambda, which produces an eliminating effect on Mu development.     

Transfer of prophage Mu into methylotrophic bacteria in the plasmid RP4

Bacteriophage Mu genome has been transferred into the cells of Pseudomonas methanolica and Methylobacterium sp. SKF240, that are naturally resistant to the bacteriophage, as a fragment of a hybrid plasmid RP4::Mu cts62. Temperature induction of the bacteriophage results in host cell lysis. Plasmid RP::Mu cis62 is maintained in methylotrophic cells presenting a cointegrative structure.The genetic and electrophoretic, analyses of the DNA isolated from transconjugant cells have confirmed the conclusion. Bacteriophage Mu propagation has been shown to be restricted in methylotrophic cells.     

Transposition of lambda placMu is mediated by the A protein altered at its carboxy-terminal end

Lambda placMu phages are derivatives of bacteriophage lambda that use the transposition machinery of phage Mu to insert into chromosomal and cloned genes. When inserted in the proper fashion, these phages yield stable fusions to the Escherichia coli lac operon in a single step. We have determined the amount of DNA from the c end of phage Mu present in one of these phages, lambda placMu3, and have shown that this phage carries a 3137-bp fragment of Mu DNA. This DNA segment carries the Mu c-end attachment site and encodes the Mu genes cts62, ner+, and gene A lacking 179 bp at its 3' end (A'). The product of this truncated gene A' retains transposase activity and is sufficient for the transposition of lambda placMu. This was demonstrated by showing that lambda placMu derivatives carrying the A am1093 mutation in the A' gene are unable to transpose by themselves in a Su- strain, but their transposition can be triggered by coinfection with lambda pMu507(A+ B+). We have constructed several new lambda placMu phages that carry the A' am1093 gene and the kan gene, which confers resistance to kanamycin. Chromosomal insertions of these new phages are even more stable than those of the previously reported lambda placMu phages, which makes them useful tools for genetic analysis.     

Behaviour of temperate phage Mu in Salmonella typhi

We have developed a convenient system for genetic analysis of Salmonella typhi exploiting the properties of the mutator phage Mu. In spite of the fact that wild-type Salmonella typhi strains do not allow Mu to form plaques on them, we have shown that these strains are actually sensitive to the phage. It proved possible to use Mu to induce mutations and to promote intra- and interspecific genetic transfer, without having to introduce the phage into the bacteria by means other than infection. Furthermore, we isolated Salmonella typhi derivatives on which Mu formed plaques, and studied the behaviour of Mu in these and wild-type strains.     

Stimulation of deletions in the Escherichia coli chromosome by partially induced Mucts62 prophages.

Deletion of bacterial DNA fragments is stimulated in induced Mucts62 lysogens. The host genes located proximally to the prophage are more frequently lost than those which are unlinked to the Mu genome. Genes located on either side of a Mu genome are deleted in the same manner. Like the other Mu-induced rearrangements, this process is recA independent and requires the participation of Mu DNA, as indicated by the fact that a phage genome always replaces the deleted genes. Data are presented which strongly suggest that both ends of the Mu genome are involved in deletion formation.     

Introduction of bacteriophage Mu into Pseudomonas solanacearum and Rhizobium meliloti using the R factor RP4.

Phage Mu-1 and a thermoinducible derivative, Mu-1 cts 62 were inserted into the broad host range R factor RP4. These hybrid plasmids were transferred by conjugation to a phytopathogenic bacterium Pseudomonas solanacearum GMI 1000 and a legume-root nodule bacterium Rhizobium meliloti 2011. The Mu genome is transcribed and tranlated in these new hosts: P. solanacearum (RP4:Mu cts) cultures have a spontaneous production of about 5 X 10(5) plaque-forming units ml-1 which is similar to the frequency of spontaneous Mu production in E. coli; the Mu production of R. meliloti is lower (about 10(2) plaque-forming units ml-1).     

Interaction of Yersinia pestis bacteria with bacteriophage mu

Yersinia pestis cells are shown to be sensitive to bacteriophage Mu cts62 infection. Lysis of bacteria has been shown to be more efficient on solid nutrient medium than in LB broth. 10(-5) pfu per ml is the maximal concentration of bacteriophage particles yielded from the broth cultures of bacteria. Moi 0.1 has been used to obtain such yields of bacteriophage. Lysogenization of Yersinia pestis cells has not been achieved when the standard methods of bacteriophage infection have been used. It was accomplished by the conjugal transfer of plasmid RP4::MU cts62 to Yersinia pestis from Escherichia coli. The deficiency of Yersinia pestis in producing bacteriophage Mu cts62 mature particles during the lytic cycle of bacteriophage is discussed.     

Internal EcoRI-generated deletion in prophage Mu DNA

The hybrid plasmid consisting of the plasmid pRP1.2 (derivative of RP4) genome and deleted prophage Mucts 62 genome which lost the central EcoRI fragment of DNA was constructed. The ability of deleted Mu phage to carry out E. coli chromosomal genes transposition was still retained.     

Isolation of transmissible cointegrates of Yersinia pestis plasmids pYV and pYT with the plasmid RP4::Mu cts 62, IncP1

The transmissible cointegrates of the Yersinia pestis plasmids pYV and pYT with the broad host range plasmid RP4::Mu cts62 of the incompatibility group IncP have been constructed by the in vivo recombination. The cointegrative plasmid pKR14 (pYV76 omega RP4::Mu cts62) conferred on the transconjugants the properties of Ca2(+)-dependence at 37 degrees C, V-antigen synthesis, RP4 plasmid markers (ApR, KmR, TcR), immunity to the lysis by the bacteriophage Mu cts62 and incompatibility with the homologous replicon pYV76. Cointegrates pKR103 and pKR106 (pYT omega RP4::Mu cts62) conferred on the transconjugant clones the ability to synthesize the "mouse" toxin and fraction I. The capability of Escherichia coli cells to synthesize the latter products has been demonstrated together with the deficiency of these cells to transport the synthesized fraction I to the cell surface.