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.     

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.     

Intermolecular Transposition of Is10 Causes Coupled Homologous Recombination at the Transposition Site

Interplasmid and chromosome to plasmid transposition of IS10 were studied by assaying inactivation of the phage 434 cI gene, carried on a low copy number plasmid. This was detected by the activity of the tet gene expressed from the phage 434 P(R) promoter. Each interplasmid transposition resulted in the fusion of the donor and acceptor plasmids into cointegrate structure, with a 9-bp duplication of the target DNA at the insertion site. Cointegrate formation was abolished in δrecA strains, although simple insertions of IS10 were observed. This suggests a two-stage mechanism involving IS10 conservative transposition, followed by homologous recombination between the donor and the acceptor. Two plasmids carrying inactive IS10 sequences were fused to cointegrates at a 100-fold lower frequency, suggesting that homologous recombination is coupled to and stimulated by the transposition event. Each IS10 transposition from the chromosome to the acceptor plasmid involved replicon fusion, providing a mechanism for IS10-mediated integration of extrachromosomal elements into the chromosome. This was accompanied by the formation of an additional copy of IS10 in the chromosome. Thus, like replicative transposition, conservative transposition of IS10 is accompanied by cointegrate formation and results in duplication of the IS10.     

Structure and stability of Tn9-mediated cointegrates. Evidence for two pathways of transposition

We have measured the frequency of Tn9 transposition and cointegrate formation in several different ways and have examined the stability of the cointegrates. We have also physically analyzed the structure of 40 independently derived cointegrate molecules. We present evidence here that Tn9, unlike the transposable element Tn3, does not transpose via an obligate cointegrate intermediate. We suggest that transposition of Tn9 leads to two, mutually exclusive, end-products: either direct insertion of the element into a recipient replicon (transposition), or fusion between donor and recipient replicons (cointegrate formation). This conclusion is based on our observations that, while Tn9-mediated cointegrates are very stable, they are formed at a rate lower than the transposition frequency. This finding is discussed in terms of current models for transposition.We also present evidence that clearly demonstrates the compound nature of Tn9. We find that the individual flanking IS1 elements are more active than the entire Tn9 transposon in cointegrate formation. In addition, we find that one IS1 element that is proximal to the cam gene promoter, is more active than the other, and suggest that the difference in activity might be due to differences in nucleotide sequence at their extremities.     

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.     

A cos-mini-Mu vector for in vivo DNA cloning

Construction of a mini-Mu plasmid vector containing a cosmid replicon is described. Upon derepression of mini-Mu transposition, bacterial DNA sequences can be flanked by the integrated mini-Mu. These sequences can then be packaged into lambda heads by superinfection with a lambda helper phage. Cosmid clones carrying particular bacterial genes can be recovered by selection after infection of appropriate strains with the cosmid transducing lambda lysate. We report here the successful in vivo cloning of several Escherichia coli genes using the transposoncosmid vector.     

Efficient insertion mutagenesis strategy for bacterial genomes involving electroporation of in vitro-assembled DNA transposition complexes of bacteriophage mu

An efficient insertion mutagenesis strategy for bacterial genomes based on the phage Mu DNA transposition reaction was developed. Incubation of MuA transposase protein with artificial mini-Mu transposon DNA in the absence of divalent cations in vitro resulted in stable but inactive Mu DNA transposition complexes, or transpososomes. Following delivery into bacterial cells by electroporation, the complexes were activated for DNA transposition chemistry after encountering divalent metal ions within the cells. Mini-Mu transposons were integrated into bacterial chromosomes with efficiencies ranging from 10(4) to 10(6) CFU/microg of input transposon DNA in the four species tested, i.e., Escherichia coli, Salmonella enterica serovar Typhimurium, Erwinia carotovora, and Yersinia enterocolitica. Efficiency of integration was influenced mostly by the competence status of a given strain or batch of bacteria. An accurate 5-bp target site duplication flanking the transposon, a hallmark of Mu transposition, was generated upon mini-Mu integration into the genome, indicating that a genuine DNA transposition reaction was reproduced within the cells of the bacteria studied. This insertion mutagenesis strategy for microbial genomes may be applicable to a variety of organisms provided that a means to introduce DNA into their cells is available.     

A facile and reversible method to decrease the copy number of the ColE1-related cloning vectors commonly used in Escherichia coli.

We report a technique which uses the cointegrate intermediate of transposon Tn1000 transposition as a means to lower the copy number of ColE1-type plasmids. The transposition of Tn1000 from one replicon to another is considered a two-step process. In the first step, the transposon-encoded TnpA protein mediates fusion of the two replicons to produce a cointegrate. In the second step, the cointegrate is resolved by site-specific recombination between the two transposon copies to yield the final transposition products: the target replicon with an integrated transposon plus the regenerated donor replicon. Using in vitro techniques, the DNA sequence of the Tn1000 transposon was altered so that cointegrate formation occurs but resolution by the site-specific recombination pathway is blocked. When this transposon was resident on an F factor-derived plasmid, a cointegrate was formed between a multicopy ColE1-type target plasmid and the conjugative F plasmid. Conjugational transfer of this cointegrate into a polA strain resulted in a stable cointegrate in which replication from the ColE1 plasmid origin was inhibited and replication proceeded only from the single-copy F factor replication origin. We assayed isogenic strains which harbored plasmids encoding chloramphenicol acetyltransferase to measure the copy number of such F factor-ColE1-type cointegrate plasmids and found that the copy number was decreased to the level of single-copy chromosomal elements. This method was used to study the effect of copy number on the expression of the fabA gene (which encodes the key fatty acid-biosynthetic enzyme beta-hydroxydecanoylthioester dehydrase) by the regulatory protein encoded by the fadR gene.     

Efficient Insertion Mutagenesis Strategy for Bacterial Genomes Involving Electroporation of In Vitro-Assembled DNA Transposition Complexes of Bacteriophage Mu

An efficient insertion mutagenesis strategy for bacterial genomes based on the phage Mu DNA transposition reaction was developed. Incubation of MuA transposase protein with artificial mini-Mu transposon DNA in the absence of divalent cations in vitro resulted in stable but inactive Mu DNA transposition complexes, or transpososomes. Following delivery into bacterial cells by electroporation, the complexes were activated for DNA transposition chemistry after encountering divalent metal ions within the cells. Mini-Mu transposons were integrated into bacterial chromosomes with efficiencies ranging from 10⁴ to 10⁶ CFU/μg of input transposon DNA in the four species tested, i.e., Escherichia coli, Salmonella enterica serovar Typhimurium, Erwinia carotovora, and Yersinia enterocolitica. Efficiency of integration was influenced mostly by the competence status of a given strain or batch of bacteria. An accurate 5-bp target site duplication flanking the transposon, a hallmark of Mu transposition, was generated upon mini-Mu integration into the genome, indicating that a genuine DNA transposition reaction was reproduced within the cells of the bacteria studied. This insertion mutagenesis strategy for microbial genomes may be applicable to a variety of organisms provided that a means to introduce DNA into their cells is available.     

Simultaneous expression of a bacteriophage Mu transposase and repressor: a way of preventing killing due to mini-Mu replication

In vitro studies of bacteriophage Mu transposition have shown that the phage-encoded transposase and repressor bind the same sequences on the phage genome. We attempted to test that prediction in vivo and found that Mu repressor directly inhibits transposition. We also found that, in the absence of repressor, constitutive expression of Mu transposition functions pA and pB is lethal in Escherichia coli strains lysogenic for a mini-Mu and that this is the result of intensive replication of the mini-Mu. These findings have important consequences where such mini-Mus are used as genetic tools. We also tested whether in Erwinia chrysanthemi the effect of transposition functions on a resident mini-Mu was the same as in E. coli. We observed that expression of pA alone was lethal in E. chrysanthemi and that a large fraction of the survivors underwent precise excision of the mini-Mu.     

Mutational Analysis of the Open Reading Frames in the Transposable Element Is1

IS1 is one of the smallest transposable elements found in bacteria (768 bp). It contains eight overlapping open-reading-frames (ORFs) greater than 50 codons, designated insA to insG and insB'. To determine which of the ORFs actually code for proteins involved in transposition, we have introduced amber codons into each ORF by site-directed mutagenesis which make neutral changes in the overlapping ORFs. Each mutant IS1 was then tested for its ability to mediate cointegrate formation in Su+ and Su- backgrounds. The mutant elements were also tested for trans-complementation in an IS1-free Salmonella background. Our results show that the products of the insA and insB genes are the only ones essential for cointegrate formation. We suggest that other ORFs may, however, encode accessory proteins.     

Transposon-mediated site-specific recombination: A defined in vitro system

Transposition of the insertion element γδ is thought to involve formation of intermediates in which the element is present at each junction between donor and target replicons. In vivo these cointegrate structures are rapidly converted to the end products of transposition by site-specific recombination at a defined sequence, res, that is present in each directly repeated γδ element. Resolvase, an element encoded protein of molecular weight 21,000 is required for cointegrate resolution. I have demonstrated site-specific recombination in vitro using purified resolvase and a cointegrate analog substrate. The required components of the system described here are resolvase, negatively supercoiled substrate DNA, buffer and Mg²⁺. Neither host-encoded products nor high energy cofactors appear to be required for resolution in vitro. Catenated, resolved molecules are the major products of the reaction. Elimination of Mg²⁺ from the reaction yields different product molecules. The in vitro system described here provides an opportunity for detailed study of the resolution reaction.     

Requirement of IS911 replication before integration defines a new bacterial transposition pathway

Movement of transposable elements is often accompanied by replication to ensure their proliferation. Replication is associated with both major classes of transposition mechanisms: cut-and-paste and cointegrate formation (paste-and-copy). Cut-and-paste transposition is often activated by replication of the transposon, while in cointegrate formation replication completes integration. We describe a novel transposition mechanism used by insertion sequence IS911, which we call copy-and-paste. IS911 transposes using a circular intermediate (circle), which then integrates into a target. We demonstrate that this is derived from a branched intermediate (figure-eight) in which both ends are joined by a single-strand bridge after a first-strand transfer. In vivo labelling experiments show that the process of circle formation is replicative. The results indicate that the replication pathway not only produces circles from figure-eight but also regenerates the transposon donor plasmid. To confirm the replicative mechanism, we have also used the Escherichia coli terminators (terC) which, when bound by the Tus protein, inhibit replication forks in a polarised manner. Finally, we demonstrate that the primase DnaG is essential, implicating a host-specific replication pathway.     

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.     

Effects of deletions in transposon Tn7 on its frequency of transposition.

Deletions in transposon Tn7 either abolished transposition or reduced transposition frequency. Except for a deletion in the right-hand terminus, these deletions could be complemented in trans. A 2.1-kilobase fragment of Tn7 encodes a diffusible gene product which stimulates transposition above the wild-type frequency. No cointegrate formation was detected.     

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.     

Mechanism of transposition of bacteriophage Mu: structure of a transposition intermediate

Mu transposition works efficiently in vitro and generates both cointegrate and simple insert products. We have examined the reaction products obtained under modified in vitro reaction conditions that do not permit efficient initiation of DNA replication. The major product is precisely the intermediate structure predicted from one of the current models of DNA transposition. Both cointegrates and simple inserts can be made in vitro using this intermediate as the DNA substrate, demonstrating that it is indeed a true transposition intermediate. The requirements for efficient formation of the intermediate include the Mu A protein, the Mu B protein, an unknown number of E. coli host proteins, ATP, and divalent cation. Only E. coli host proteins are required for conversion of the intermediate to cointegrate or simple insert products. Structures resulting from DNA strand transfer at only one end of the transposon are not observed, suggesting that the strand transfers at each end of the transposon are tightly coupled.     

The istA gene of insertion sequence IS21 is essential for cleavage at the inner 3'' ends of tandemly repeated IS21 elements in vitro.

The bacterial 2.1 kb insertion sequence IS21 occurs as a tandem repeat [=(IS21)2] on the broad host range plasmid R68.45. In (IS21)2, the two IS21 elements are separated by 3 bp termed junction sequence. Plasmids carrying (IS21)2 form cointegrates with other replicons at high frequencies. The two IS21 genes, istA and istB, were found to be necessary for cointegrate formation in vivo. Since the outer ends of (IS21)2 are dispensable for cointegrate formation, we favor a transposition model according to which a plasmid carrying (IS21)2 is cleaved at the junction sequence; the opened plasmid is then inserted into a target replicon. Here we show that Escherichia coli cell extracts, which contained over-produced IstA protein, nicked a supercoiled (IS21)2 plasmid precisely at the inner 3' termini of IS21; the resulting staggered cut generated 5' protrusions. The istA gene, but not the istB gene, was required for in vitro cleavage of an IS21-IS21 junction. Because of this cleavage and our previous findings (generation of 4 bp target duplications and loss of the junction sequence after cointegrate formation in vivo) we propose that plasmids with (IS21)2 produce cointegrates by a mechanism which involves joining of the inner 3' ends of IS21 to the 5' ends of the target.     

Molecular genetic analysis of the Tn5041 transposition system

A study was made of the transposition of the mercury resistance transposon Tn5041 which, together with the closely related toluene degradation transposon Tn4651, forms a separate group in the Tn3 family. Transposition of Tn5041 was host-dependent: the element transposed in its original host Pseudomonas sp. KHP41 but not in P. aeruginosa PAO-R and Escherichia coli K12. Transposition of Tn5041 in these strains proved to be complemented by the transposase gene (tnpA) of Tn4651. The gene region determining the host dependence of Tn5041 transposition was localized with the use of a series of hybrid (Tn5041 x Tn4651) tnpA genes. Its location in the 5'-terminal one-third of the transposase gene is consistent with the data that this region is involved in the formation of the transposition complex in transposons of the Tn3 family. As in other transposons of this family, transposition of Tn5041 occurred via cointegrate formation, suggesting its replicative mechanism. However, neither of the putative resolution proteins encoded by Tn5041 resolved the cointegrates formed during transposition or an artificial cointegrate in E. coli K12. Similar data were obtained with the mercury resistance transposons isolated from environmental Pseudomonas strains and closely related to Tn5041 (Tn5041 subgroup).     

Four genes, two ends, and a res region are involved in transposition of Tn5053: a paradigm for a novel family of transposons carrying either a mer operon or an integron

The complete nucleotide sequence of an 8447 bp-long mercury-resistance transposon (Tn 5053 ) has been determined. Tn 5053 is composed of two modules: (i) the mercury-resistance module and (ii) the transposition module. The mercury-resistance module carries a mer operon, merRTPFAD , and appears to be a single-ended relic of a transposon closely related to the classical mercury-resistance transposons Tn 21 and Tn 501 . The transposition module of Tn 5053 is bounded by 25 bp terminal inverted repeats and contains four genes involved in transposition, i.e. tniA, tniB, tniQ , and tniR . Transposition of Tn 5053 occurs via cointegrate formation mediated by the products of the tniABQ genes, followed by site-specific cointegrate resolution. This is catalysed by the product of the tniR gene at the res region, which is located upstream of tniR . The same pathway of transposition is used by Tn 402 (Tn 5090 ) which carries the integron of R751. Transposition genes of Tn 5053 and Tn 402 are interchangeable. Sequence analysis suggests that Tn 5053 and Tn 402 are representatives of a new family of transposable elements, which fall into a recently recognized superfamily of transposons including retroviruses, insertion sequences of the IS 3 family, and transposons Tn 552 and Tn 7 . We suggest that the tni genes were involved in the dissemination of integrons.