Construction and characteristics of mini-Mu phages

The paper reports on the principles of construction, physical characterization and results of preliminary genetic investigation of hybrid plasmids containing Mu DNA sequences or deletion derivatives of phage Mu, the so-called mini-Mu phages. The mini-Mu were obtained by joining both phage ends within one plasmid in a regular orientation. A collection obtained by in vitro manipulations included 14 recombinant plasmids containing different DNA fragments of the Mu genome. Seven plasmids have both ends of phage Mu, three plasmids containing regularly oriented ends, i.e. mini-phages of different size: the mini-Mu5 (11 kb) within pRM8 plasmid, the mini-Mu4 Ap (18 kb) within pRM6 and the mini-mini-Mu (4.4 kb) within pRM5. The collection comprises mini-Mu phages with the gene kil inactivated after treatment with hydroxylamine. Biological properties of the hybrid plasmids have been preliminary studied.     

The isolation and characteristics of plasmids derived from the insertion of MupAp1 into pML2: their behavior during transposition

Three independent insertions of the phage Mu variant MupAp1 into the ColE1 derivative pML2 have been isolated. From one of these hybrid plasmids (pSU1), two mini-Mu plasmids have been generated. These have lost internal regions of the Mu genome but retain the ends of the prophage. In pSU17 all but one kilobase pair of the early region and most of the late region have been deleted whereas in pSU123 most of the early region is still present but the deletion covers nearly all the late region. Mu immunity, host killing, and transposition functions are located in the DNA present in pSU123 but absent from pSU17. Transposition of Mu and the mini-Mu from the hybrid plasmids to the sex factor R388 is usually associated with the formation of cointegrates between the two parental plasmids.     

Cloning of genes from members of the family Enterobacteriaceae with mini-Mu bacteriophage containing plasmid replicons.

An in vivo cloning system that uses derivatives of the Escherichia coli bacteriophage Mu with plasmid replicons has been extended to five different species of the family Enterobacteriaceae. Mu and these mini-Mu replicon elements were introduced into strains of E. coli, Shigella flexneri, Salmonella typhimurium, Citrobacter freundii, and Proteus mirabilis by infection, by transformation, or by conjugation with newly constructed broad-host-range plasmids containing insertions of these elements. Lysates from these cells, lysogenic for Mu and mini-Mu elements, were used to infect sensitive recipient strains of E. coli, S. typhimurium, and C. freundii. Drug-resistant transductants had mini-Mu replicon elements with inserts of different DNA sequences. All of the lysogens made could be induced to yield high phage titers, including those coming from strains that were resistant to Mu and Mu derivatives. Clones of 10 particular genes were isolated by their ability to complement specific mutations in the recipient strains, even in the presence of the E. coli K-12 restriction system. Some of the mini-Mu replicon elements used contained lac gene fusing segments and resulted in fusions of the lac operon to control regions in the cloned sequences.     

Mini-Mu transduction: cis-inhibition of the insertion of Mud transposons

Mud (mini-Mu) transposons are defective phage Mu genomes that conserve the Mu ends. The transduction of Mud transposons is strictly dependent on Mu complementation, inefficient, and affected by modifications in the Mud internal sequences. The transduction of Mud transposons depends on transposition, which appears to be low, relative to wild-type Mu. Insertions of Mud into a plasmid can be frequently recovered among transductants; new Mud insertions into plasmids that already have both Mu ends, or just one, are rarely found. This suggests that the presence of Mu ends "immunizes" the plasmid against further insertion. This phenomenon may be similar to the transposition immunity of Tn3.     

Stimulation of the Mu A protein-mediated strand cleavage reaction by the Mu B protein, and the requirement of DNA nicking for stable type 1 transpososome formation. In vitro transposition characteristics of mini-Mu plasmids carrying terminal base pair mutations.

We have examined the effects of a T----C point mutation at the terminal nucleotide of the Mu ends in a mini-Mu plasmid on the early steps in the in vitro transposition reaction. These mutations inhibit the introduction of nicks at the Mu ends in a reaction with Mu A, HU, and integration host factor proteins. The presence of the point mutation at either the left end or the right end is sufficient to block the nicking reaction at both ends, indicating that the reaction is normally concerted. Addition of Mu B and ATP, however, dramatically stimulates the reaction of mutant mini-Mu plasmids carrying the mutation at one end but not at both ends. The data suggest that the Mu B protein mediates its effect through direct interaction with Mu A and that Mu B may play a role in an earlier step in the transposition process than previously proposed. In the presence of Mu B, two products are observed with the left end or right end mutant mini-Mu plasmids, a normal protein-DNA intermediate (Type 1 complex) which contains nicks at both Mu ends and an abortive product composed of free relaxed plasmid which is nicked only at the wild-type end. Furthermore, stable protein-DNA complexes characteristic of the first step in the in vitro transposition reaction are not observed in the absence of nicking or when only one end is a nicked; the introduction of nicks at both Mu ends is a prerequisite for stable transpososome assembly.     

Transposition immunity in bacteriophage Mu. The effect of a mutation at the kil gene on the establishment of immunity

Bacteriophage Mu is characterized by a phenomenon similar to the transposition immunity of TnA: the frequency of transposition of Mu or mini-Mu into plasmids containing certain phage sequences is reduced by two orders of magnitude. In order to lend transposition immunity to Mu, the recipient replicon must contain a sequence of phage DNA including a 5.1 kb early region from the c-end of Mu. The product of the kil (or cim) gene takes part in establishing the immunity. The transposition immunity of Mu is connected with the disturbance of cointegrate formation.     

Stimulation of the Mu DNA strand cleavage and intramolecular strand transfer reactions by the Mu B protein is independent of stable binding of the Mu B protein to DNA.

Interactions between the Mu A and Mu B proteins are important in the early steps of the in vitro transposition of a mini-Mu plasmid. We have examined these interactions by assaying Mu B stimulation of Mu A-mediated strand cleavage and strand transfer reactions. We have previously shown that in the presence of ATP the Mu B protein can stimulate the Mu A-directed cleavage reaction of mini-Mu plasmids carrying a terminal base pair mutation (Surette, M.G., Harkness, T., and Chaconas, G. (1991) J. Biol. Chem. 266, 3118-3124). Here we demonstrate that in the absence of a non-Mu DNA target molecule the Mu B protein stimulates intramolecular integration of a mini-Mu in an ATP-dependent fashion. Furthermore, modification of the Mu B protein with N-ethylmaleimide severely compromises the ability of B to form a stable complex with DNA; however, the modified protein stimulates the strand cleavage and intramolecular strand transfer reactions as efficiently as the untreated protein. These results indicate that the Mu B protein is capable of stimulating the Mu A protein through direct interaction in the absence of stable Mu B-DNA complex formation. Our results increase the spectrum of Mu B protein activities and uncouple the stimulatory properties of the Mu B protein from stable DNA binding but not the ATP cofactor requirement.     

Mini-muduction: A new mode of gene transfer mediated by mini-Mu

Summary We compared the transducing properties of Mucts62 and Mucts62/mini-Mu lysates, using Mu immune and non immune Rec⁺ and recA recipient strains. The Mu/mini-Mu lysates transduced all bacterial markers tested 10 times more efficiently than the Mucts62 lysates in Rec⁺ recipients. Most of the transductants obtained after infection with the Mu/mini-Mu lysates result from the substitution of the mutated gene of the recipient by the wild type allele from the donor, most probably carried on the gigantic variable end linked to the mini-Mu genome.Moreover the Mu/mini-Mu lysates gave a new type of Rec-independent transduction that we called mini-muduction. Mini-muduction requires the activity of Mu gene A and provides transductants which carry the transduced marker surrounded by two mini-Mu genomes similarly oriented, and inserted at random location in the recipient chromosome. The mini-Mu/transduced DNA/mini-Mu structures are able to transpose spontaneously, for instance into a transmissible plasmid, in the presence of Mu gene A product.     

Transposition studies of mini-Mu plasmids constructed from the chemically synthesized ends of bacteriophage Mu

We describe below the chemical synthesis of the right and left ends of bacteriophage Mu and characterize the activity of these synthetic ends in mini-Mu transposition. Mini-Mu plasmids were constructed which carry the synthetic Mu ends together with the Mu A and B genes under control of the bacteriophage λ p_L promoter. Derepression of p_L leads to a high frequency of mini-Mu transposition (5.6 × 10⁻²) which is dependent on the presence of the Mu ends and the Mu A and B proteins. Five deletion mutants in the Mu ends were tested in the mini-Mu transposition system and their effects on transposition are described.     

Mutagenesis of dimeric plasmids by the transposon gamma delta (Tn1000).

The Escherichia coli F factor mediates conjugal transfer of a plasmid such as pBR322 primarily by replicative transposition of transposon gamma delta (Tn1000) from F to that plasmid to form a cointegrate intermediate. Although resolution of this cointegrate always yields a plasmid containing a single gamma delta insertion, the occasional recovery of transposon-free plasmids after conjugal transfer has led to alternative hypotheses for F mobilization. We show here that gamma delta-free plasmids are found after F-mediated conjugal transfer only when the donor plasmid is a dimer and the recipient is Rec+.     

Transpososomes: stable protein-DNA complexes involved in the in vitro transposition of bacteriophage Mu DNA

We report that two types of stable protein-DNA complexes, or transpososomes, are generated in vitro during the Mu DNA strand transfer reaction. The Type 1 complex is an intermediate in the reaction. Its formation requires a supercoiled mini-Mu donor plasmid, Mu A and HU protein, and Mg2+. In the Type 1 complex the two ends of Mu are held together, creating a figure eight-shaped molecule with two independent topological domains; the Mu sequences remain supercoiled while the vector DNA is relaxed because of nicking. In the presence of Mu B protein, ATP, target DNA, and Mg2+, the Type 1 complex is converted into the protein-associated product of the strand transfer reaction. In this Type 2 complex, the target DNA has been joined to the Mu DNA ends held in the synaptic complex at the center of the figure eight. Supercoils are not required for the latter reaction.     

In vivo DNA cloning with a mini-Mu replicon cosmid and a helper lambda phage

A mini-Mu bacteriophage, containing the cohesive-end packaging site (cos) from a lambda-phi 80 hybrid phage, a high-copy-number plasmid replicon, and a kanamycin-resistance gene for independent selection, was constructed to clone genes in vivo. This mini-Mu element can be derepressed to transpose at a high frequency. DNA segments that become flanked by copies of this mini-Mu element in the same orientation can be packaged by a helper lambda phage. The resulting lambda lysate can be used to infect recipient cells where the injected DNA can circularize by annealing at the cos termini. Drug-resistant transductants obtained carry the mini-Mu-replicon cosmid element with inserts of different nucleotide sequences. These are analogous to recombinant DNA clones generated in vitro with restriction endonuclease cutting and ligase joining reactions replaced by the Mu transposition process. Clones of particular genes were isolated by their ability to complement specific mutations. Both recA+ and recA- recipient cells can be used with equal efficiency. Clones obtained with a helper lambda phage require the presence of the cos site in the mini-Mu replicon. They carry larger inserts than those isolated with the same mini-Mu element and Mu as a helper phage. The mini-Mu replicon-cosmid bacteriophage contains a lac-gene fusing segment for isolating fusions of lac operon DNA to gene control regions in the cloned sequences. Independent clones of a particular gene can be used to prepare a restriction map of the gene and its flanking regions.     

Terminal nucleotide sequences of Tn551, a transposon specifying erythromycin resistance in Staphylococcus aureus: homology with Tn3

The erythromycin resistance determinant of Staphylococcus aureus plasmid pI258 resides on a 5.3 kb transposon, Tn551. We have determined DNA sequences surrounding the junctions between the transposon and the flanking DNA in the wild-type plasmid, in an insertion into a second plasmid, and in two transposon-related deletions. The ends of the transposon consist of an inverted repeat of 40 base pairs flanked by a direct repeat of 5, thus placing the transposon in the same class as Tn3, IS2, Tn501, gamma delta, and bacteriophage Mu. Interestingly, we find that the terminal sequences of the 40 base pairs inverted repeat are very similar to the ends of Tn3, a transposon which one would not have expected to show any relation to Tn551. This result suggests common ancestry for Tn3 and Tn551. The inverted repeat sequence of Tn551 also contains (with one additional inserted base) the internal heptanucleotide sequence which has been found to be common to most of the transposable elements that generate 5-base pair direct repeat sequences.     

Flanking host sequences can exert an inhibitory effect on the cleavage step of the in vitro mu DNA strand transfer reaction.

The effect of flanking host sequences on the cleavage step of the in vitro Mu DNA strand transfer reaction was investigated. Insertion of a mini-Mu molecule into certain sites in pUC19 results in insertions that demonstrate a decreased ability to form Type 1 complexes in subsequent rounds of transposition. Similarly, changes in the flanking host sequences directly adjacent to the Mu ends by in vitro mutagenesis can also result in Type 1-deficient mini-Mu molecules. Further examination of the inhibition revealed that Type 1 deficient mini-Mu molecules are capable of forming uncut synaptic complexes at normal levels but are compromised in their ability to serve as substrates for phosphodiester bond hydrolysis at the Mu ends. This cleavage defect can be overcome by addition of the Mu B protein and ATP to the reaction. Our data suggest that one of the roles of the B protein may be to provide a mechanism whereby Mu prophages with inhibitory flanking sequences can overcome this obstacle and avoid being trapped at unproductive locations.     

Mini-Mu mediates deletion-inversions in vivo by intra-transposon transposition

We have shown that a mini-Mu can transpose into itself in vivo to generate a circle containing only transposon sequences. This deletion-inversion product, which has previously been observed in vitro, is formed by non-replicative transposition and has directly repeated Mu ends. It therefore cannot undergo further rounds of transposition and retains the two copies of the target sequence duplicated in the event. Thus we have been able to confirm that a mini-Mu can undergo non-replicative reactions in vivo and that these generate a 5 bp target site duplication, as has been shown to occur following replicative transposition and lysogenization with Mu.     

Transfer of chimeric plasmids among Salmonella typhimurium strains by P22 transduction

Salmonella typhimurium bacteriophage P22 transduced plasmids having P22 sequences inserted in the vector pBR322 with high frequency. Analysis of the structure of the transducing particle DNA and the transduced plasmids indicates that this plasmid transduction involves two homologous recombination events. In the donor cell, a single recombination between the phage and the homologous sequences on the plasmid inserted the plasmid into the phage chromosome, which was then packaged by headfuls into P22 particles. The transducing particle DNA contained duplications of the region of homology flanking the integrated plasmid vector sequences and lacked some phage genes. When these defective phage genomes containing the inserted plasmid infected a recipient cell, recombination between the duplicated regions regenerated the plasmid. A useful consequence of this sequence of events was that genetic markers in the region of homology were readily transferred from phage to plasmid. Plasmid transduction required homology between the phage and the plasmid, but did not depend on the presence of any specific P22 sequence in the plasmid. When the infecting P22 carried a DNA sequence homologous to the ampicillin resistance region of pBR322, the vector plasmid having no P22 insert could be transduced. P22-mediated transduction is a useful way to transfer chimeric plasmids, since most S. typhimurium strains are poorly transformed by plasmid DNA.     

Transposition of Mu DNA: joining of Mu to target DNA can be uncoupled from cleavage at the ends of Mu

Transposition of Mu involves transfer of the 3' ends of Mu DNA to the 5' ends of a staggered cut in the target DNA. We find that cleavage at the 3' ends of Mu DNA precedes cutting of the target DNA. The resulting nicked species exists as a noncovalent nucleoprotein complex in which the two Mu ends are held together. This cleaved donor complex completes strand transfer when a target DNA, Mu B protein, and ATP are provided. Mu end DNA sequences that have been precisely cut at their 3' ends by a restriction endonuclease, instead of by Mu A protein and HU, are efficiently transferred to a target DNA upon subsequent incubation with Mu A protein, Mu B protein, and ATP. Cleavage of the Mu ends therefore cannot be energetically coupled with joining these ends to a target DNA. We discuss the DNA strand transfer mechanism in view of these results, and propose a model involving direct transfer of the 5' ends of the cut target DNA, from their original partners, to the 3' ends of Mu.     

Application of the bacteriophage Mu-driven system for the integration/amplification of target genes in the chromosomes of engineered Gram-negative bacteria—mini review

The advantages of phage Mu transposition-based systems for the chromosomal editing of plasmid-less strains are reviewed. The cis and trans requirements for Mu phage-mediated transposition, which include the L/R ends of the Mu DNA, the transposition factors MuA and MuB, and the cis/trans functioning of the E element as an enhancer, are presented. Mini-Mu(LR)/(LER) units are Mu derivatives that lack most of the Mu genes but contain the L/R ends or a properly arranged E element in cis to the L/R ends. The dual-component system, which consists of an integrative plasmid with a mini-Mu and an easily eliminated helper plasmid encoding inducible transposition factors, is described in detail as a tool for the integration/amplification of recombinant DNAs. This chromosomal editing method is based on replicative transposition through the formation of a cointegrate that can be resolved in a recombination-dependent manner. (E-plus)- or (E-minus)-helpers that differ in the presence of the trans-acting E element are used to achieve the proper mini-Mu transposition intensity. The systems that have been developed for the construction of stably maintained mini-Mu multi-integrant strains of Escherichia coli and Methylophilus methylotrophus are described. A novel integration/amplification/fixation strategy is proposed for consecutive independent replicative transpositions of different mini-Mu(LER) units with “excisable” E elements in methylotrophic cells.