A truncated form of the bacteriophage Mu B protein promotes conservative integration, but not replicative transposition, of Mu DNA

The phage-encoded proteins required for conservative integration of infecting bacteriophage Mu DNA were investigated. Our findings show that functional gpA, an essential component of the phage transposition system, is required for integration. The Mu B protein, which greatly enhances replicative transposition of Mu DNA, is also required. Furthermore, a truncated form of gpB lacking 18 amino acids from the carboxy terminus is blocked in replicative transposition, but not conservative integration. Our results point to a more prominent role for gpB than simply a replication enhancer in Mu DNA transposition. The ability of a truncated form of B to function in conservative integration, but not replicative transposition, also suggests a key role for the carboxy-terminal domain of the protein in the replicative reaction. The existence of a shortened form of gpB, which uncouples conservative integration from replicative transposition, should be invaluable for future dissection of Mu DNA transposition.     

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.     

Mu insertions are repaired by the double-strand break repair pathway of Escherichia coli

Mu is both a transposable element and a temperate bacteriophage. During lytic growth, it amplifies its genome by replicative transposition. During infection, it integrates into the Escherichia coli chromosome through a mechanism not requiring extensive DNA replication. In the latter pathway, the transposition intermediate is repaired by transposase-mediated resecting of the 5' flaps attached to the ends of the incoming Mu genome, followed by filling the remaining 5 bp gaps at each end of the Mu insertion. It is widely assumed that the gaps are repaired by a gap-filling host polymerase. Using the E. coli Keio Collection to screen for mutants defective in recovery of stable Mu insertions, we show in this study that the gaps are repaired by the machinery responsible for the repair of double-strand breaks in E. coli-the replication restart proteins PriA-DnaT and homologous recombination proteins RecABC. We discuss alternate models for recombinational repair of the Mu gaps.     

Single-stranded DNA intermediates in IS91 rolling-circle transposition

IS91 displays a number of characteristics unique among insertion sequence (IS) elements, suggesting that it transposes by a novel mechanism called rolling-circle (RC) transposition. We reported previously that IS91 transposase (TnpA) amino acid sequence shares a series of five conserved signatures with A proteins of RC replicating phages, including a pair of invariant tyrosines that catalyse two successive transesterification reactions during replication initiation and termination. To analyse their role in IS91 transposition, we constructed a series of TnpA derivatives in which the invariant Tyr-249 and/or Tyr-253 were mutated to either phenylalanine or serine. Mutation of either tyrosine resulted in complete loss of transposition activity in vivo. This result was taken as a first new line of evidence that TnpA is a functional analogue of phiX174 phage A protein. Secondly, RC replication plasmids and phages accumulate single-stranded DNA (ssDNA) intermediates as a result of uncoupled leading and lagging DNA strand synthesis. Using a plasmid carrying an IS91-derived IRLkan-IRR transposable cassette, in which the left (IRL)- and right (IRR)-terminal sequences of IS91 flank a kanamycin resistance gene (kan), we demonstrated the in vivo formation of two new DNA species after induction of transposase expression. The first was a circular ssDNA that contained the transposable cassette covalently joined at its exact termini, whereas the second was a double-stranded circle of the same element. When this experiment was repeated using the mutant transposases described above, the ssDNA and dsDNA intermediates could not be observed, indicating that the integrity of both Y249 and Y253 was essential for their appearance. The presence of ssDNA intermediate products is the first biochemical evidence for a RC mechanism of IS91 transposition.     

Repair of transposable phage Mu DNA insertions begins only when the E. coli replisome collides with the transpososome

We report a new cellular interaction between the infecting transposable phage Mu and the host Escherichia coli replication machinery during repair of Mu insertions, which involves filling‐in of short target gaps on either side of the insertion, concomitant with degradation of extraneous long flanking DNA (FD) linked to Mu. Using the FD as a marker to follow repair, we find that after transposition into the chromosome, the unrepaired Mu is indefinitely stable until the replication fork arrives at the insertion site, whereupon the FD is rapidly degraded. When the fork runs into a Mu target gap, a double strand end (DSE) will result; we demonstrate fork‐dependent DSEs proximal to Mu. These findings suggest that Pol III stalled at the transpososome is exploited for co‐ordinated repair of both target gaps flanking Mu without replicating the intervening 37 kb of Mu, disassembling the stable transpososome in the process. This work is relevant to all transposable elements, including retroviral elements like HIV‐1, which share with Mu the common problem of repair of their flanking target gaps.     

The bacteriophage Mu transposase protein can form high-affinity protein-DNA complexes with the ends of transposable elements of the Tn 3 family

The 37 kb transposable bacteriophage Mu genome encodes a transposase protein which can recognize and bind to a consensus sequence repeated three times at each extremity of its genome. A subset of this consensus sequence (5'-PuCGAAA(A)-3') is found in the ends of many class II prokaryotic transposable elements. These elements, like phage Mu, cause 5 bp duplications at the site of element insertion, and transpose by a cointegrate mechanism. Using the band retardation assay, we have found that crude protein extracts containing overexpressed Mu transposase can form high-affinity protein-DNA complexes with Mu att R and the ends of the class II elements Tn 3 (right) and IS101. No significant protein-DNA complex formation was observed with DNA fragments containing the right end of the element IS102, or a non-specific pBR322 fragment of similar size. These results suggest that the Mu transposase protein can specifically recognize the ends of other class II transposable elements and that these elements may be evolutionarily related.     

Differential role of the Mu B protein in phage Mu integration vs. replication: mechanistic insights into two transposition pathways

The Mu B protein is an ATP-dependent DNA-binding protein and an allosteric activator of the Mu transposase. As a result of these activities, Mu B is instrumental in efficient transposition and target-site choice. We analysed in vivo the role of Mu B in the two different recombination reactions performed by phage Mu: non-replicative transposition, the pathway used during integration, and replicative transposition, the pathway used during lytic growth. Utilizing a sensitive PCR-based assay for Mu transposition, we found that Mu B is not required for integration, but enhances the rate and extent of the process. Furthermore, three different mutant versions of Mu B, Mu BC99Y, Mu BK106A, and Mu B1-294, stimulate integration to a similar level as the wild-type protein. In contrast, these mutant proteins fail to support Mu growth. This deficiency is attributable to a defect in formation of an essential intermediate for replicative transposition. Biochemical analysis of the Mu B mutant proteins reveals common features: the mutants retain the ability to stimulate transposase, but are defective in DNA binding and target DNA delivery. These data indicate that activation of transposase by Mu B is sufficient for robust non-replicative transposition. Efficient replicative transposition, however, demands that the Mu B protein not only activate transposase, but also bind and deliver the target DNA.     

DNA intermediates in transposition of phage Mu

Transposable genetic elements can insert into DNA sites that have no homology to themselves. Evidence that there is a physical linkage between a transposable element and its target DNA sequence during transposition comes from studies on bacteriophage Mu DNA transposition in which plasmids containing Mu DNA have been shown to attach to host DNA. We report the isolation of key structures, seen after induction of Mu DNA replication, after cloning lac operator into Mu DNA and using the lac repressor-operator interaction to trap Mu DNA on nitrocellulose filters. We have localized Mu sequences within these structures in the electron microscope by visualizing the lac operator-repressor interaction after binding with ferritin-conjugated antibody. This analysis shows that key structures contain replicating Mu DNA linked to non-Mu DNA and that replication can begin at either end of Mu.     

DNA gyrase requirements distinguish the alternate pathways of Mu transposition

The MuA transposase mediates transposition of bacteriophage Mu through two distinct mechanisms. The first integration event following infection occurs through a non-replicative mechanism. In contrast, during lytic growth, multiple rounds of replicative transposition amplify the phage genome. We have examined the influence of gyrase and DNA supercoiling on these two transposition pathways using both a gyrase-inhibiting drug and several distinct gyrase mutants. These experiments reveal that gyrase activity is not essential for integration; both lysogens and recombination intermediates are detected when gyrase is inhibited during Mu infection. In contrast, gyrase inhibition causes severe defects in replicative transposition. In two of the mutants, as well as in drug-treated cells, replicative transposition is almost completely blocked. Experiments probing for formation of MuA-DNA complexes in vivo reveal that this block occurs very early, during assembly of the transposase complex required for the catalytic steps of recombination. The findings establish that DNA structure-based signals are used differently for integrative and replicative transposition. We propose that transposase assembly, the committed step for recombination, has evolved to depend on different DNA /architectural signals to control the reaction outcome during these two distinct phases of the phage life cycle.     

Mechanism of Is1 Transposition in E. COLI: Choice between Simple Insertion and Cointegration

Insertion element IS1 and IS1-based transposon Tn9 generate cointegrates (containing vector and target DNAs joined by duplicate copies of IS1 or Tn9) and simple insertions (containing IS1 or Tn9 detached from vector sequences). Based on studies of transposon Tn5 we had proposed a conservative (non-replicative) model for simple insertion. Others had proposed that all transposition is replicative, occurring in a rolling circle structure, and that the way DNA strands are joined when replication terminates determines whether a simple insertion or a cointegrate is formed.--We selected for the transposition of amp and cam resistance markers from pBR322::Tn9 plasmids to an F factor in recA-E. coli and identified products containing three and four copies of IS1, corresponding to true cointegrates (from monomeric plasmids), and simple insertions (from dimeric plasmids). The simple insertions with four copies of IS1 outnumbered those with three by a ratio of about 3:1, whereas true cointegrates containing three copies of IS1 were more numerous than those with four.--A straightforward rolling circle model had predicted that the simple insertions containing three copies of IS1 should be more frequent than those with four. Because we obtained the opposite result we propose that simple insertions only arise when the element fails to replicate or if replication starts but then terminates prematurely. The two classes of products, simple insertions and cointegrates, reflect alternative conservative and replicative fates, respectively, of an early intermediate in transposition.     

The left end of IS2: a compromise between transpositional activity and an essential promoter function that regulates the transposition pathway

Cut-and-paste (simple insertion) and replicative transposition pathways are the two classical paradigms by which transposable elements are mobilized. A novel variation of cut and paste, a two-step transposition cycle, has recently been proposed for insertion sequences of the IS3 family. In IS2 this variation involves the formation of a circular, putative transposition intermediate (the minicircle) in the first step. Two aspects of the minicircle may involve its proposed role in the second step (integration into the target). The first is the presence of a highly reactive junction formed by the two abutted ends of the element. The second is the assembly at the minicircle junction of a strong hybrid promoter which generates higher levels of transposase. In this report we show that IS2 possesses a highly reactive minicircle junction at which a strong promoter is assembled and that the promoter is needed for the efficient completion of the pathway. We show that the sequence diversions which characterize the imperfect inverted repeats or ends of this element have evolved specifically to permit the formation and optimal function of this promoter. While these sequence diversions eliminate catalytic activity of the left end (IRL) in the linear element, sufficient sequence information essential for catalysis is retained by the IRL in the context of the minicircle junction. These data confirm that the minicircle is an essential intermediate in the two-step transposition pathway of IS2.     

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.     

Is10 Promotes Adjacent Deletions at Low Frequency

Some transposable elements move by a replicative mechanism involving cointegrate formation. Intramolecular cointegration can generate a product called an ``adjacent deletion' in which a contiguous chromosomal segment adjacent to the transposon is deleted while the element responsible remains intact. Insertion sequence IS10 is thought to transpose by a nonreplicative mechanism. In the simplest models, nonreplicative transposition cannot give rise to an adjacent deletion because an intrinsic feature of such transposition is excision of the IS element from the donor location. We report here that IS10 can generate adjacent deletions, but at a frequency which is approximately 1/30th the frequency of transposition for the same element. We suggest that these deletions might arise either by nonreplicative transposition events that involve two IS10 elements located on sister chromosomes or by aberrant nonreplicative events involving cleavage and ligation at only one end of the element.     

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.     

Stoichiometric use of the transposase of bacteriophage Mu

The transposase of bacteriophage Mu (gene A protein) mediates the coupled replication and integration processes that constitute transposition during the lytic cycle. Our previous results showed that the activity of the A protein is unstable, as its continued synthesis is required to maintain Mu DNA replication throughout the lytic cycle. We present here the results of experiments in which the A protein is used stoichiometrically and must be synthesized de novo for each round of Mu DNA replication. Induction of a Mu lysogen in the absence of DNA replication allows accumulation of potential for a single round of Mu DNA replication. Once achieved, this potential is stable even in the absence of further protein synthesis. Release of inhibition of DNA replication leads to a single semi-conservative replicative transposition event, followed by later rounds only if additional synthesis of the A protein is allowed.     

Synchronization of bacteriophage Mu DNA replicative transposition: analysis of the first round after induction.

The lytic cycle of bacteriophage Mu includes a large number of coupled DNA replication and integration events, each of which is equivalent in several respects to the process of transposition of genetic elements. To aid us in studying the process of Mu DNA replicative transposition, we developed a technique for synchronizing the first round of replication following induction of a lysogen. Synchronization was achieved by inducing a lysogen in the absence of DNA replication for a time sufficient to develop the potential for Mu DNA replication in all cells in the population; upon release of the inhibition of replication, a synchronized round of Mu DNA replication was observed. Development of the potential for Mu DNA replication in the entire population took approximately 12 min. Protein synthesis was required for development of the potential, but the requirement for protein synthesis was satisfied by approximately 9 min suggesting that other, as yet unspecified, reactions occupied the last 3 min. Replication proceeded predominantly from the left end of the prophage, though a significant amount of initiation from the right end was observed. The usefulness of the technique for studying the mechanism of replicative transposition and the end products of a single round of replication are discussed.     

IS10/Tn10 transposition efficiently accommodates diverse transposon end configurations.

Transposon Tn10 and its component insertion sequence IS10 move by non-replicative transposition. We have studied the array of reaction intermediates and products in a high efficiency in vitro IS10/Tn10 transposition reaction. Synapsis of two transposon ends, followed by cleavage and strand transfer, can occur very efficiently irrespective of the relative locations and orientations of the two ends. The two participating ends can occur in inverted or direct orientation on the same molecule or, most importantly, on two different molecules. This behavior contrasts sharply with that of Mu, in which transposition is strongly biased in favor of inverted repeat synapsis. Mechanistically, the absence of discrimination amongst various end configurations implies that the architecture within the IS10/Tn10 synaptic complex is relatively simple, i.e. lacking any significant intertwining of component DNA strands. Biologically these observations are important because they suggest that the IS10 insertion sequence module has considerable flexibility in the types of DNA rearrangements that it can promote. Most importantly, it now seems highly probable that a single non-replicative IS10 element can promote DNA rearrangements usually attributed to replicative transposition, i.e. adjacent deletions and cointegrates, by utilizing transposon ends on two sister chromosomes. Other events which probably also contribute to the diversity of IS10/Tn10-promoted rearrangements are discussed.     

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.