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.     

Early events in the replication of Mu prophage DNA.

To determine whether the early replication of Mu prophage DNA proceeds beyond the termini of the prophage into hose DNA, the amounts of both Mu DNA and the prophage-adjacent host DNA sequences were measured using a DNA-DNA annealing assay after induction of the Mu vegetative cycle. Whereas Mu-specific DNA synthesis began 6 to 8 min after induction, no amplification of the adjacent DNA sequences was observed. These data suggest that early Mu-induced DNA synthesis is constrained within the boundaries of the Mu prophage. Since prophage Mu DNA does not undergo a prophage lambda-like excision from its original site after induction (E. Ljungquist and A. I. Bukhari, Proc. Natl. Acad. Sci. U.S.A. 74:3143--3147, 1977), we propose the existence of a control mechanism which excludes prophage-adjacent sequences from the initial mu prophage replication. The frequencies of the Mu prophage-adjacent DNA sequences, relative to other Escherichia coli genes, were not observed to change after the onset of Mu-specific DNA replication. This suggests that these regions remain associated with the host chromosome and continue to be replicated by the chromosomal replication fork. Therefore, we conclude that both the Mu prophage and adjacent host sequences are maintained in the host chromosome, rather than on an extrachromosomal form containing Mu and host DNA.     

Evolution of the long range structure of satellite DNAs in the genus Apodemus.

The temperate bacteriophage Mu causes mutations by inserting its DNA randomly into the genes of its host bacterium Escherichia coli. It is shown here that Mu DNA can be precisely excised from the different integration sites and that as a result wild-type function of the gene into which Mu was inserted is restored. The excision of Mu DNA is observable only if the Mu prophage carries mutations at the X locus. Thus, lac⁺ revertants from six strains, containing heat-inducible prophage Mu cts62 at different locations in the Z gene of the lac operon, were readily obtained by first introducing the X mutation into Mu cts62. The lac⁺ revertants produced wild-type β-galactosidase, and no trace of Mu DNA could be detected in them; this indicates that the junction of Mu DNA and host DNA can be specifically recognized. However, the excision of Mu DNA is generally not perfect, because in most cases it does not lead to the wild-type genotype. The function of gene A of Mu appears to be required for excision. Since the lethal functions of Mu are completely blocked in the Mu cts62 X prophage, the X locus probably has a regulatory function. At least one X mutation is caused by an insertion of about 900 base-pairs in Mu DNA. The discovery of the X mutants opens the way for studying the reversible interaction of the host and Mu chromosomes, and for using Mu to manipulate the host genome in various ways.     

Model for the enchancement of lambde-gal integration into partially induced Mu-1 lysogens.

Temperate phage Mu-1, which is able to integrate at random in its host chromosome, is also able to mediate integration of other circular deoxyribonucleic acid, as a lambda-gal mutant unable to integrate by itself. After mixed infection with lambda-gal and Mucplus, galplus transductants are recovered that have the lambda-gal integrated in any circular permutation, sandwiched between two complete Mu genomes in the same orientation, the whole Mu-lambda-gal-Mu structure being found at any location in the bacterial chromosome. Here we show that such a lambda-gal can integrate in an induced Mu lysogen. In this case the lambda-gal is again in any circular permutation, between two Mu in the same orientation, but it is always located at the site of the original Mu prophage, and the two surrounding Mu have always the same genotype as the original Mu prophage. Active Mu replication functions are not essential for that process to occur. This suggests that bacterial replication may generate two Mu copies that in some way can regenerate a Mu attachment site that recombines with the lambda-gal. A model is presented that accounts for these observations, may be helpful for understanding some complex features of Mu development, and may possibly offer a basis for explaining spontaneous duplications.     

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).     

Mu-induced deletions and mutations of Erwinia carotovora chromosomes, including resident prophages E105 and 59]

The plasmid RP4::Mu cts62 in stably inherited by Erwinia carotovora 268 strain. Under the conditions of thermoinduction bacteriophage Mu is segregated and completely eliminated more intensively than in Escherichia coli cells. At thermoinduction the transposition of bacteriophage Mu cts62 into different chromosomal sites takes place, causing the induction of chlorate resistant and auxotrophic mutants with the frequency of 10(-4). Two clones deficient in production of 2 of the 4 resident prophages of Erwinia carotovora 268 strain were found among Mu-induced mutants. The deleted prophages are E105 and 59. DNA-DNA hybridization has revealed the complete and partial deletions of bacteriophage E105 with the level of L-asparaginase production in the cells remaining intact. The damage of the prophage 59 is probably caused by point mutations or short deletions.     

Neighboring plasmid sequences can affect Mini-Mu DNA transposition in the absence of expression of the bacteriophage Mu semi-essential early region

Bacteriophage Mu DNA, like other transposable elements, requires DNA sequences at both extremities to transpose. It has been previously demonstrated that the transposition activity of various transposons can be influenced by sequences outside their ends. We have found that alterations in the neighboring plasmid sequences near the right extremity of a Mini-Mu, inserted in the plasmid pSC101, can exert an influence on the efficiency of Mini-Mu DNA transposition when an induced helper Mu prophage contains a polar insertion in its semi-essential early region (SEER). The SEER of Mu is known to contain several genes that can affect DNA transposition, and our results suggest that some function(s), located in the SEER of Mu, may be required for optimizing transposition (and thus, replication) of Mu genomes from restrictive locations during the lytic cycle.     

Mapping of a Temperate Bacteriophage Active on Bacillus subtilis

Bacteriophage phi105 is a temperate bacteriophage for Bacillus subtilis 168. Temperature-sensitive and plaque mutants of phi105 were isolated. The results of two- and three-factor crosses with these mutants suggest the vegetative map of phi105 to be circular. The location of prophage phi105 between bacterial markers phe-1 and ilvA1 was shown by means of PBS1 transduction. Five markers in the prophage were linearly ordered with respect to the bacterial markers. Linkage between bacterial and prophage markers was demonstrated in transformation experiments with deoxyribonucleic acid extracted from lysogenic bacteria. The data demonstrate that prophage phi105 is linearly inserted into the bacterial chromosome.     

Transposable lambda placMu bacteriophages for creating lacZ operon fusions and kanamycin resistance insertions in Escherichia coli.

We have constructed several derivatives of bacteriophage lambda that translocate by using the transposition machinery of phage Mu (lambda placMu phages). Each phage carries the c end of Mu, containing the Mu cIts62, ner (cII), and A genes, and the terminal sequences from the Mu S end (beta end). These sequences contain the Mu attachment sites, and their orientation allows the lambda genome to be inserted into other chromosomes, resulting in a lambda prophage flanked by the Mu c and S sequences. These phages provide a means to isolate cells containing fusions of the lac operon to other genes in vivo in a single step. In lambda placMu50, the lacZ and lacY genes, lacking a promoter, were located adjacent to the Mu S sequence. Insertion of lambda placMu50 into a gene in the proper orientation created an operon fusion in which lacZ and lacY were expressed from the promoter of the target gene. We also introduced a gene, kan, which confers kanamycin resistance, into lambda placMu50 and lambda placMu1, an analogous phage for constructing lacZ protein fusions (Bremer et al., J. Bacteriol. 158:1084-1093, 1984). The kan gene, located between the cIII and ssb genes of lambda, permitted cells containing insertions of these phages to be selected independently of their Lac phenotype.     

Reversal of Mu gem2ts-induced mutations

Abstract: Mutations induced by the integration of a Mu gem 2ts mutant prophage can revert at frequencies around 1 × 10⁻⁶, more than 10⁴-fold higher than that obtained with Mu wild-type. Several aspects characterize Mu gem 2ts precise excision: (i) the phage transposase is not involved; (ii) the RecA protein is not necessary; and (iii) revertants remain lysogenic with the prophage inserted elsewhere in the host genome. In addition, prophage re-integration seems to be non-randomly distributed, whereas Mu insertion into the host genome is a transposition event without any sequence specificity. In this paper, we describe that the site of re-integration somehow depends on the original site of insertion. Two alternative models are proposed to explain the strong correlation between donor and receptor sites.     

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.     

Localized mutagenesis with bacteriophage Mu: method for increasing the frequency of specific bacterial mutants.

A method is described for markedly enriching a bacterial population for cells containing any given Mu insertion mutation. The method involves the transfer of a small piece of deoxyribonucleic acid from a Mu-infected Hfr donor donor strain to a suitable F- strain and a subsequent selection of those recombinant organisms that have received a Mu prophage from the donor. The method is particularly usefule for isolating mutants whose selection requires "brute-force" assay, since only a few hundred colonies have to be screened.     

Low-Frequency Rescue of a Genetic Marker in Deoxyribonucleic Acid from Bacillus Bacteriophage φ105 by Superinfecting Bacteriophage

Markers in gene L, which maps at the right end of the vegetative and prophage maps, are rescued at a strongly reduced frequency from mature 105 deoxyribonucleic acid (DNA) by superinfecting phage but at high frequency from vegetative and prophage DNA. It is suggested that the ends of mature DNA are degraded when DNA is taken up by competent cells.     

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.     

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.     

Mechanism of Transfection with Deoxyribonucleic Acid from the Temperate Bacillus Bacteriophage φ105

Bacteriophage phi105 is a temperate phage for the transformable Bacillus subtilis 168. The infectivity of deoxyribonucleic acid (DNA) extracted from mature phi105 phage particles, from bacteria lysogenic for phi105 (prophage DNA), and from induced lysogenic bacteria (vegetative DNA) was examined in the B. subtilis transformation system. About one infectious center was formed per 10(8) mature DNA molecules added to competent cells, but single markers could be rescued from mature DNA by a superinfecting phage at a 10(3)- to 10(4)-fold higher frequency. Single markers in mature DNA were inactivated at an exponential rate after uptake by a competent cell. Prophage and vegetative DNA gave about one infectious center per 10(3) molecules added to competent cells. Infectious prophage DNA entered competent cells as a single molecule; it gave a majority of lytic responses. Single markers in sheared prophage DNA were inactivated at the same rate as markers in mature DNA. Prophage DNA was dependent on the bacterial rec-1 function for its infectivity, whereas vegetative DNA was not. The mechanism of transfection of B. subtilis with viral DNA is discussed, and a model for transfection with phi105 DNA is proposed.     

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.