Carboxyl-terminal mutants of phage Mu transposase

A study of the properties of deletion mutants at the 3’ end ofA, the gene encoding the transposase protein of phage Mu, shows that the mutants are defective in the high-frequency non-replicative transposition observed early after Mu infection as well as the high-frequency replicative transposition observed during Mu lytic growth. They show near-normal levels of lysogenization, low frequency transposition and precise excision. The mutants behave as if they are “blind” to the presence of Mu B, a protein whose function is essential for the high frequency of both replicative and non-replicative Mudna transposition. We have sequenced these deletion mutants as well as the amber mutant A 7110 which is known to be defective in replicative transposition.A 7110 maps at the 3’ end of geneA. We suggest that the carboxyl-terminal region of the A-protein is involved in protein-protein interactions, especially with the B-protein. We also show in this study that mutations upstream of the Shine-Dalgarno sequence of geneA and within the preceding genener, perturb the synthesis of A-protein and that higher levels of A-protein cause an inhibition ofA activity.     

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.     

Behaviour of temperate phage Mu in Salmonella typhi

We have developed a convenient system for genetic analysis of Salmonella typhi exploiting the properties of the mutator phage Mu. In spite of the fact that wild-type Salmonella typhi strains do not allow Mu to form plaques on them, we have shown that these strains are actually sensitive to the phage. It proved possible to use Mu to induce mutations and to promote intra- and interspecific genetic transfer, without having to introduce the phage into the bacteria by means other than infection. Furthermore, we isolated Salmonella typhi derivatives on which Mu formed plaques, and studied the behaviour of Mu in these and wild-type strains.     

Cloning of a restriction fragment of phage Mu DNA coding for early functions

Summary The DNA of an E. coli K12 strain harboring ten wildtype Mu prophages was restricted with endonuclease EcoRI, and the fragments ligated into the plasmid vector pMB9. Upon transformation of a strain carrying a heat inducible (Mu cts62) prophage, one temperature-resistant transformant was isolated. This transformant strain harbors the hybrid plasmid pKN001, containing the EcoRI.C fragment of Mu DNA as shown by restriction and heteroduplex analysis. Stable transformants of pKN001 are immune to superinfection with phage Mu. Transformation of superinfection with phage Mu. Transformation of Mu sensitive bacteria with pKN001 results in killing of the recipients (10^-4 surviving bacteria). The killing function is not expressed upon transformation of Mu-immune (lysogenic) bacteria.This paper is dedicated by EGB to Dr. Luis F. Leloir, on the occasion of his 70th birthday     

Cloning and characterization of restriction fragments of phage Mu DNA

Abstract The Eco RI-A and B, the Bam HI-C and the two Eco RI- Bam HI restriction fragments of transposing phage Mu DNA were inserted into vector plasmids pRSF2124 and pBR322. Quantitative marker rescue experiments for five genes located on the Eco RI-A fragment revealed complementation of phages carrying amber mutations in genes C , E , H , F and L . The in vitro coding capacity of the recombinant plasmids was assayed in a DNA-directed protein synthesizing system.     

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.     

Transposition of the phage D3112 genome in Escherichia coli cells

It has been demonstrated that the genome of phage D3112 of Preudomonas aeruginosa can be transposed into Escherichia coli chromosome as a component of the hybrid plasmid RP4 TcrKms::D3112. Also, transposition of D3112 from E. coli (D3112) chromosome into RP4 plasmid occurs. The phage stimulates the chromosome mobilizing activity of RP4 plasmid, similar to other transposons. E. coli (RP4::D3112) cells were previously shown to form no colonies at 30 degrees C. Auxotrophic mutants and mutants incapable of utilizing different carbohydrates were found among E. coli clones survived after a long incubation at 30 degrees C (at frequencies approximately 10(-3) - 10(-4). These mutants inherited stably the capability to produce D3112 phage. E. coli auxotrophic mutants have arisen indeed as a consequence of phage integration into the E. coli chromosome, since prototrophic transductants derived from these mutants after their treatment with generalized transducing P1 phage have lost the ability to produce D3112 phage. Clones with mutations in Km or Tc genes of RP4 plasmid, occurring at high frequencies (about 3%) were found after introduction of RP4 into E. coli (D3112). These mutant RP4 plasmids carry insertions of D3112 genomes. Clones of E. coli which lost mutant plasmids still produce D3112 and retain their initial auxotrophic mutations.     

The Escherichia coli protein, Fis: specific binding to the ends of phage Mu DNA and modulation of phage growth

We show, using gel retardation, that crude Escherichia coli cell extracts contain a protein which binds specifically to DNA fragments carrying either end of the phage Mu genome. We have identified this protein as Fis, a factor involved in several site-specific recombinational switches. Furthermore, we show that induction of a Mucts62 prophage in a fis lysogen occurs at a lower temperature than that of a wild-type strain, and that spontaneous induction of Mucts62 is increased in the fis mutant. DNasel footprinting using either crude extracts or purified Fis indicate that binding on the left end of Mu occurs at a site which overlaps a weak transposase binding site. Thus, Fis may modulate Mu growth by influencing the binding of transposase, or other proteins, to the transposase binding site(s), in a way similar to its influence on Xis binding in phage lambda.     

Solution structure of the Mu end DNA-binding ibeta subdomain of phage Mu transposase: modular DNA recognition by two tethered domains.

The phage Mu transposase (MuA) binds to the ends of the Mu genome during the assembly of higher order nucleoprotein complexes. We investigate the structure and function of the MuA end-binding domain (Ibetagamma). The three-dimensional solution structure of the Ibeta subdomain (residues 77-174) has been determined using multidimensional NMR spectroscopy. It comprises five alpha-helices, including a helix-turn-helix (HTH) DNA-binding motif formed by helices 3 and 4, and can be subdivided into two interacting structural elements. The structure has an elongated disc-like appearance from which protrudes the recognition helix of the HTH motif. The topology of helices 2-4 is very similar to that of helices 1-3 of the previously determined solution structure of the MuA Igamma subdomain and to that of the homeodomain family of HTH DNA-binding proteins. We show that each of the two subdomains binds to one half of the 22 bp recognition sequence, Ibeta to the more conserved Mu end distal half (beta subsite) and Igamma to the Mu end proximal half (gamma subsite) of the consensus Mu end-binding site. The complete Ibetagamma domain binds the recognition sequence with a 100- to 1000-fold higher affinity than the two subdomains independently, indicating a cooperative effect. Our results show that the Mu end DNA-binding domain of MuA has a modular organization, with each module acting on a specific part of the 22 bp binding site. Based on the present binding data and the structures of the Ibeta and Igamma subdomains, a model for the interaction of the complete Ibetagamma domain with DNA is proposed.     

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.     

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 att DNA-binding domain of phage Mu transposase.

The transposase (A protein) of phage Mu encodes binding to two families of DNA sites, att sites located at the Mu ends and enhancer sites located internally. Separate subdomains in the N-terminal domain I of Mu A protein are known to be involved in recognition of the att and enhancer sites. We have delineated an approximately 135 aa region within domain I beta gamma that specifies binding to Mu att sites. This peptide was overexpressed and its properties compared with that of the larger domain I beta gamma as well as the intact Mu A protein. Extensive mutagenesis of residues around a putative helix-turn-helix DNA-binding motif within the I beta domain identified several mutants defective in DNA transposition in vivo. Of these, Mu A(K157Q) was completely defective in att DNA-binding. Mu A(F131S) and Mu A(R146N) had a lower affinity for att DNA and low levels of transposition in vitro. Our results indicate that residues in the gamma region are required for activity and that residues outside the beta gamma region must also influence discrimination between the multiple att sites.