A domain sharing model for active site assembly within the Mu A tetramer during transposition: the enhancer may specify domain contributions.

The functional configuration of Mu transposase (A protein) is its tetrameric form. We present here a model for the organization of a functional Mu A tetramer. Within the tetramer, assembly of each of the two active sites for Mu end cleavage requires amino acid contributions from the central and C-terminal domains (domains II and III respectively) of at least two Mu A monomers in a trans configuration. The Mu enhancer is likely to function in this assembly process by specifying the two monomers that provide their C-terminal domains for strand cleavage. The Mu B protein is not required in this step. Each of the two active sites for the strand transfer reaction is also organized by domain sharing (but in the reverse mode) between Mu A monomers; i.e. a donor of domain II (also the recipient of domain III) during cleavage is a recipient of domain II (and the donor of domain III) during strand transfer. The function of the Mu B protein (which is required at the strand transfer step) and that of the enhancer element may be analogous in that their interactions with Mu A (domain III and domain I alpha respectively) promote conformations of Mu A conducive to strand cleavage or strand transfer.     

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 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.     

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.     

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.     

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.     

Chromosome mobilization of Legionella pneumophila with RK2::Mu and Tn5-Mob.

RK2::Mu plasmids and transposon Tn5-Mob were used to mobilize the Legionella pneumophila chromosome. Plate matings between L. pneumophila donors that contained RK2::Mu plasmids and auxotrophic recipients yielded recombinants at frequencies ranging from 10(-6) to 10(-7) per recipient for the markers tested. The presence of a Mu insertion in the chromosome of donors that harbored RK2::Mu plasmids increased the frequency of chromosome transfer of certain selected markers as compared with strains that contained RK2::Mu alone. Cotransfer experiments with Mu-containing donors and a thymidine and tryptophan auxotroph failed to reveal any linkage between the thy and trp loci in L. pneumophila. A strain that contained a chromosomal Tn5-Mob insertion and helper plasmid pRK24.4 transferred chromosomal markers at frequencies of 10(-7) per recipient. These findings suggest that RK2::Mu plasmids and Tn5-Mob may be useful for genetic mapping experiments with L. pneumophila.     

Transduction of bacteriophage Mu by bacteriophage T1.

Phage T1 transduces phage Mu PFU from Mu-lysogenic donor cells to sensitive recipient cells. The efficiency of transduction depends on the chromosomal location of the Mu prophage. T1, therefore, appears to package different regions of the bacterial chromosome with different efficiencies. Although T1 transduces bacterial markers with different efficiencies, there is no direct correlation between the efficiency of transduction of a bacterial marker and the efficiency of transduction of Mu PFU from donor cells with the Mu prophage located in that marker.     

Rec dependence of mu transposition from P22-transduced fragments.

Derivatives of bacteriophage Mu carrying a lac operon and a selectable drug resistance element (Mu d phages) are frequently used tools of bacterial genetics. Mu d prophages used in this way can be treated as transposons, in that the inserted material can be transduced from one strain to another by general transducing phages, such as P1 and P22. When a Mu d prophage is transduced into a new recipient by P1 or P22, the Mu d element can transpose from the transduced fragment into the bacterial chromosome. Transposition of the Mu d element from a P22-transduced fragment shows several striking differences from transposition of a Mu d genome injected by a Mu virion. First, the frequency of transposition from a transduced fragment is greatly enhanced by a P22 helper genome. Second, transposition requires the host recA, B, and C functions. Transposition of Mu following injection by a Mu virion is rec independent. While the basis of these observations is not understood, we suggest that the Mu X protein, a 65-kilodalton protein injected by a Mu virion and required for Mu transposition, may not be packaged by P22. We suggest that the effects seen reflect the behavior of a Mu genome in the absence of the X protein.     

Transduction of multi-copy plasmid pBR322 by bacteriophage Mu

Summary The temperate bacteriophage Mu transduces the 4363 bp multi-copy plasmid pBR322 at frequencies similar to those of chromosomal markers. Plasmid transducing particles contain DNA molecules of Mu DNA length. Plasmid DNA is transduced as a head-to-tail oligomer that becomes circularized in the recipient cell. The rec system of the donor strain participates in oligomer formation and the rec system of the recipient strain is required for oligomer circularization. Possible mechanisms that may explain the origin of plasmid transducing particles are discussed.     

Silent mischief: bacteriophage Mu insertions contaminate products of Escherichia coli random mutagenesis performed using suicidal transposon delivery plasmids mobilized by broad-host-range RP4 conjugative machinery

Random transposon mutagenesis is the strategy of choice for associating a phenotype with its unknown genetic determinants. It is generally performed by mobilization of a conditionally replicating vector delivering transposons to recipient cells using broad-host-range RP4 conjugative machinery carried by the donor strain. In the present study, we demonstrate that bacteriophage Mu, which was deliberately introduced during the original construction of the widely used donor strains SM10 λpir and S17-1 λpir, is silently transferred to Escherichia coli recipient cells at high frequency, both by hfr and by release of Mu particles by the donor strain. Our findings suggest that bacteriophage Mu could have contaminated many random-mutagenesis experiments performed on Mu-sensitive species with these popular donor strains, leading to potential misinterpretation of the transposon mutant phenotype and therefore perturbing analysis of mutant screens. To circumvent this problem, we precisely mapped Mu insertions in SM10 λpir and S17-1 λpir and constructed a new Mu-free donor strain, MFDpir, harboring stable hfr-deficient RP4 conjugative functions and sustaining replication of Π-dependent suicide vectors. This strain can therefore be used with most of the available transposon-delivering plasmids and should enable more efficient and easy-to-analyze mutant hunts in E. coli and other Mu-sensitive RP4 host bacteria.     

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.     

Mini-Mu-duction as a test for genetic complementation in Escherichia coli.

In mini-Mu-duction, segments of host DNA bracketed between two copies of an internally deleted Mu phage (a mini-Mu) can be packaged within Mu phage particles. Upon infection of a second host strain, the DNA injected by these particles can insert into the chromosomal DNA in a reaction catalyzed by the phage A gene product (transposase), which is independent of homologous recombination. This results in a partially diploid host strain in which the duplicated host DNA is bracketed by two copies of the mini-Mu phage (Faelen et al., Mol. Gen. Genet. 176:191-197, 1979). The frequency of mini-Mu-duction reported previously was low (10(-8) to 10(-9) per recipient cell) thus limiting its use to rather stable mutational lesions. I have increased the frequency of mini-Mu-duction 10- to 100-fold by use of a helper phage lacking the kil gene and by UV irradiation of the phage stocks. I have also shown that mini-Mu-duction is a reliable complementation assay in rec+ as well as recA recipient strains. This genetic complementation test does not require prior gene localization and (due to the extended host range of phage Mu) should be applicable to many enterobacterial species.     

Genetic study of prophage excision with a temperature inducible mutant of Mu-1

Summary Escherichia coli strains, carrying F'episomes with a thermoinducible prophage of Mu were used to study the effect of heat induction on the ability of the cells to transfer these episomes to recipient cells. With this method information was obtained on the excision of the prophage after induction. Control studies were done with an episome containing a thermoinducible lambda prophage.The heat induction has opposite effects on the transfer of episomes containing Mu or : in the case of the number of sexductants in a -immune recipient is not significantly affected while sexduction into a non-immune recipient is increased by a factor 10–20. In contrast, the transfer of Mu-containing episomes into Mu-immune and also non-immune recipients is decreased by a factor of 100–200.The presented data exclude a precise -like excision of prophage Mu upon induction. A possible model for Mu excision is discussed.Colony forming units.     

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.     

Transposon mutagenesis and strain construction in Zymomonas mobilis

Conjugative or mobilizable plasmids carrying the transposable elements Tn5, Tn501 or mini Mu were readily transferred from Escherichia coli donors into Zymomonas mobilis recipients with frequencies depending both on donor and recipient strain used. With the exception of pULB113 (RP4::mini Mu), all foreign plasmids exhibited high instability in Z. mobilis transconjugants under both selective and non-selective conditions. Transposition events and consequent mutagenesis occurred readily in Z. mobilis transconjugant strains, with Tn5 and Tn501 being far less successful than mini Mu. Transposon mutagenesis with the help of mini Mu resulted in the isolation of a large number of independent auxotrophs with polyauxotrophs, cysteine, methionine and isoleucine requiring-isolates being the most frequent. When chromosomal DNA from all these mutants was digested with various restriction enzymes and the resulting restriction patterns were hybridized with a mini Mu probe, the majority of these mutants appeared to have insertions at different sites of the chromosome. Thus, transposon mutagenesis by mini Mu is proven to be a simple and efficient tool for mutant production and the genetic analysis of Z. mobilis.     

Transposition of mini-Mu containing only one of the ends of bacteriophage Mu.

Transposition of mini-Mu containing only one of the ends of bacteriophage Mu was studied. Transposition was observed when plasmids containing this mini-Mu were used as the donor in a mating-out assay with the F factor POX38, which lacks all known transposable elements, as the target. Analysis of the plasmids isolated from the recipient strain showed that in most cases the mini-Mu containing plasmid and POX38 were fused and that a part of the plasmid had been duplicated, indicating the formation of co-integrates. To obtain the DNA sequences of the junctions between donor and recipient DNA, an F factor was constructed that made it possible to analyse these junctions directly. The results showed that several sequences can be used as an alternative end in transposition and that these alternative ends show homology with the consensus for a strong A binding site. Moreover, the first base pair at the junction was always a (TA) base pair. This base pair is situated at exactly the same position with respect to the sequence which has homology with the consensus for a strong A binding site as in the ends of Mu.     

Transfer of plasmids fromEscherichia coli andPseudomonas aeruginosa to methylotrophic bacteria and their detection in the new hosts

Several plasmids of incompatibility group P were transferred fromEscherichia coli andPseudomonas aeruginosa strains toMethylophilus methylotrophus and two other methylotrophs to test their recipient ability. The presence of plasmids in transconjugants was confirmed by electrophoretic analysis. Optimal conditions for detection of plasmid DNA in the strains tested based on alkaline lysis of cells at elevated temperature were established. Special behaviour of plasmids carrying the Mu phage in methylotrophic hosts is described.     

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.     

Effect of the polymerase activity of DNA polymerase I on the development of moderate bacteriophages Mu, lambda red- and lambda red-gam-. II. The effect of the polymerase activity of DNA polymerase I on the development of bacteriophage Mu

The paper reports on the influence of polymerizing activity of DNA-polymerase I on different developmental stages of temperate bacteriophage Mu in Escherichia coli K-12 cells. This activity is shown to be necessary for optimization of phage Mu primary integration into cell chromosomes. The relative frequency of Mu integration into bacterial chromosomes is 5-6 times lower in polA cells than in isogenic polA+ control strains, the phage yield from cells being delayed during the phage infectious development, but not in the course of induction from the prophage state. Data have been obtained that show the process of phage Mu DNA integration into the plasmid pRP1 .2 and the process of Mu transposition from the cell chromosome into the plasmid to be independent of the polymerizing activity of DNA-polymerase I.