DNA sequences at the ends of the genome of bacteriophage Mu essential for transposition

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.

Functional characterization of the competence protein DprA/Smf inEscherichia coli

In several bacterial species that show natural transformation, dprA has been described as a competence gene. The DprA protein has been suggested to be involved in the protection of incoming DNA. However, members of the dprA gene family (also called smf) can be detected in virtually all bacterial species, which suggests that their gene products have a more general function. We examined the function of the DprA/Smf homologue of Escherichia coli. Escherichia coli dprA/smf is able to partially restore transformation in a Haemophilus influenzae dprA mutant, which shows that dprA/smf genes from competent and noncompetent species are interchangeable with respect to their involvement in natural transformation. From this, we conclude that natural transformation is probably an additional function of these genes. Subsequently, the dprA/smf gene was deleted in various recombination mutants of E. coli, and the resultant phenotype was tested. All the resultant E. coli dprA/smf mutants did not differ from their parent strains with respect to transformation, Hfr-conjugation, recombination and DNA repair. Therefore, a role of DprA/Smf in DNA recombination could not be established and the basic function of dprA/smf remains unclear.

Towards integrating vectors for gene therapy: expression of functional bacteriophage MuA and MuB proteins in mammalian cells

Bacteriophage Mu has one of the best studied, most efficient and largest transposition machineries of the prokaryotic world. To harness this attractive integration machinery for use in mammalian cells, we cloned the coding sequences of the phage factors MuA and MuB in a eukaryotic expression cassette and fused them to a FLAG epitope and a SV40-derived nuclear localization signal. We demonstrate that these N-terminal extensions were sufficient to target the Mu proteins to the nucleus, while their function in Escherichia coli was not impeded. In vivo transposition in mammalian cells was analysed by co-transfection of the MuA and MuB expression vectors with a donor construct, which contained a miniMu transposon carrying a Hygromycin-resistance marker (Hyg(R)). In all co-transfections, a significant but moderate (up to 2.7-fold) increase in Hyg(R) colonies was obtained if compared with control experiments in which the MuA vector was omitted. To study whether the increased efficiency was the result of bona fide Mu transposition, integrated vector copies were cloned from 43 monoclonal and one polyclonal cell lines. However, in none of these clones, the junction between the vector and the chromosomal DNA was localized precisely at the border of the Att sites. From our data we conclude that expression of MuA and MuB increases the integration of miniMu vectors in mammalian cells, but that this increase is not the result of bona fide Mu-induced transposition.

Molecular and evolutionary analysis of two divergent subfamilies of a novel miniature inverted repeat transposable element in the yellow fever mosquito, Aedes aegypti

A novel family of miniature inverted repeat transposable elements (MITEs) named Pony was discovered in the yellow fever mosquito, Aedes aegypti. It has all the characteristics of MITEs, including terminal inverted repeats, no coding potential, A+T richness, small size, and the potential to form stable secondary structures. Past mobility of PONY: was indicated by the identification of two Pony insertions which resulted in the duplication of the TA dinucleotide targets. Two highly divergent subfamilies, A and B, were identified in A. aegypti based on sequence comparison and phylogenetic analysis of 38 elements. These subfamilies showed less than 62% sequence similarity. However, within each subfamily, most elements were highly conserved, and multiple subgroups could be identified, indicating recent amplifications from different source genes. Different scenarios are presented to explain the evolutionary history of these subfamilies. Both subfamilies share conserved terminal inverted repeats similar to those of the Tc2 DNA transposons in Caenorhabditis elegans, indicating that Pony may have been borrowing the transposition machinery from a Tc2-like transposon in mosquitoes. In addition to the terminal inverted repeats, full-length and partial subterminal repeats of a sequence motif TTGATTCAWATTCCGRACA represent the majority of the conservation between the two subfamilies, indicating that they may be important structural and/or functional components of the Pony elements. In contrast to known autonomous DNA transposons, both subfamilies of PONY: are highly reiterated in the A. aegypti genome (8,400 and 9, 900 copies, respectively). Together, they constitute approximately 1. 1% of the entire genome. Pony elements were frequently found near other transposable elements or in the noncoding regions of genes. The relative abundance of MITEs varies in eukaryotic genomes, which may have in part contributed to the different organizations of the genomes and reflect different types of interactions between the hosts and these widespread transposable elements.

Molecular characterization of the tia invasion locus from enterotoxigenic Escherichia coli

Enterotoxigenic Escherichia coli (ETEC) shares with other diarrheal pathogens the capacity to invade epithelial cell lines originating from the human ileum or colon, although the role of invasion in ETEC pathogenesis remains undefined. Two distinct loci (tia and tib) that direct noninvasive E. coli to adhere to and invade intestinal epithelial cell lines have previously been isolated from cosmid libraries of the classical ETEC strain H10407. Here, we report the molecular characterization of the tia locus. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of cellular fractions of E. coli DH5alpha carrying the tia-positive cosmids and recombinant plasmid subclones revealed that this locus directs the production of a 25-kDa protein (the Tia protein) that is localized to the outer membrane. The tia locus was subcloned to a maximum of 2 kb and mutagenized with bacteriophage Mud. Synthesis of this protein was directly correlated with the ability of subclones and Mud transposon mutants to adhere to and invade epithelial cells. Sequencing of the tia locus identified a 756-bp open reading frame. All transposon insertions resulting in an invasion-negative phenotype mapped to this open reading frame. The open reading frame was amplified and directionally cloned behind the lac promoter of pHG165. This construct directed DHalpha to express a 25-kDa protein and to adhere to and invade epithelial cells. The role of the tia gene in directing epithelial adherence and invasion was further assessed by the construction of chromosomal tia deletion derivatives of the parent ETEC strain, H10407. These tia deletion strains were noninvasive and lacked the ability to adhere to human ileocecal cells. The tia gene shares limited homology with the Yersinia ail locus and significant homology with the hra1 agglutinin gene cloned from a porcine ETEC strain. Additionally, tia probes hybridized to geographically diverse ETEC strains, as well as some enteropathogenic E. coli, enteroaggregative E. coli, and Shigella sonnei strains.

Thiamine pyrophosphate (TPP) negatively regulates transcription of some thi genes of Salmonella typhimurium

In Salmonella typhimurium, thiamine is a required nutrient that is synthesized de novo. Labeling studies have demonstrated probable precursors for both the 4-amino-5-hydroxymethyl-2-methylpyrimidine pyrophosphate moiety and the 4-methyl-5-(beta-hydroxyethyl) thiazole monophosphate moiety. The isolation of thiamine auxotrophs with mutations in at least five different genetic loci is reported. The majority (22 of 25) of the mutants required only the thiazole moiety of thiamine to satisfy their growth requirement. Most (14 of 25) of the mutants were affected in the thi cluster at min 90 on the S. typhimurium genetic map. Data provided herein indicate that this cluster encodes an operon whose transcription is regulated by thiamine and suggest that thiamine pyrophosphate, or a molecule derived form it, is the effector molecule. Mutants with altered regulation of this operon were isolated, and we propose that they are defective in thiamine phosphate kinase, the product of the thiL gene.

The end of the cob operon: evidence that the last gene (cobT) catalyzes synthesis of the lower ligand of vitamin B12, dimethylbenzimidazole

The cob operon of Salmonella typhimurium includes 20 genes devoted to the synthesis of adenosyl-cobalamin (coenzyme B12). Mutants with lesions in the promoter-distal end of the operon synthesize vitamin B12 only if provided with 5,6-dimethylbenzimidazole (DMB), the lower ligand of vitamin B12. In the hope of identifying a gene(s) involved in synthesis of DMB, the DNA base sequence of the end of the operon has been determined; this completes the sequence of the cob operon. The cobT gene is the last gene in the operon. Four CobII (DMB-) mutations mapping to different deletion intervals of the CobII region were sequenced; all affect the cobT open reading frame. Both the CobT protein of S. typhimurium and its Pseudomonas homolog have been shown in vitro to catalyze the transfer of ribose phosphate from nicotinate mononucleotide to DMB. This reaction does not contribute to DMB synthesis but rather is the first step in joining DMB to the corrin ring compound cobinamide. Thus, the phenotype of Salmonella cobT mutants conflicts with the reported activity of the affected enzyme, while Pseudomonas mutants have the expected phenotype. J. R. Trzebiatowski, G. A. O'Toole, and J. C. Escalante Semerena have suggested (J. Bacteriol. 176:3568-3575, 1994) that S. typhimurium possesses a second phosphoribosyltransferase activity (CobB) that requires a high concentration of DMB for its activity. We support that suggestion and, in addition, provide evidence that the CobT protein catalyzes both the synthesis of DMB and transfer of ribose phosphate. Some cobT mutants appear defective only in DMB synthesis, since they grow on low levels of DMB and retain their CobII phenotype in the presence of a cobB mutation. Other mutants including those with deletions, appear defective in transferase, since they require a high level of DMB (to activate CobB) and, in combination with a cobB mutation, they eliminate the ability to join DMB and cobinamide. Immediately downstream of the cob operon is a gene (called ORF in this study) of unknown function whose mutants have no detected phenotype. Just counterclockwise of ORF is an asparagine tRNA gene (probably asnU). Farther counterclockwise, a serine tRNA gene (serU or supD) is weakly cotransducible with the cobT gene.

Neighboring plasmid sequences can affect Mini-Mu DNA transposition in the absence of expression of the bacteriophage Mu semi-essential early region

Bacteriophage Mu DNA, like other transposable elements, requires DNA sequences at both extremities to transpose. It has been previously demonstrated that the transposition activity of various transposons can be influenced by sequences outside their ends. We have found that alterations in the neighboring plasmid sequences near the right extremity of a Mini-Mu, inserted in the plasmid pSC101, can exert an influence on the efficiency of Mini-Mu DNA transposition when an induced helper Mu prophage contains a polar insertion in its semi-essential early region (SEER). The SEER of Mu is known to contain several genes that can affect DNA transposition, and our results suggest that some function(s), located in the SEER of Mu, may be required for optimizing transposition (and thus, replication) of Mu genomes from restrictive locations during the lytic cycle.

Transposase A binding sites in the attachment sites of bacteriophage Mu that are essential for the activity of the enhancer and A binding sites that promote transposition towards Fpro-lac

In this paper we determine which of the A binding sites in the attachment sites of phage Mu are required for the stimulatory activity of the transpositional enhancer (IAS). For this purpose the transposition frequencies of mini-Mu's with different truncated attachment sites to an Ftet target were measured both in the presence and the absence of the IAS. The results show that in our in vivo assay the L3 and R3 sites are dispensable for functioning of the IAS. An additional deletion of L2 or R2 however abolishes the stimulating activity of the enhancer suggesting an interaction between A molecules bound to these sites and the IAS. The residual transposition activity of a IAS-containing mini Mu in which R2 (and R3) are deleted is much lower than the activity of the comparable construct without the IAS. This means that in the absence of R2 the IAS is inhibiting transposition. Such an inhibition is not observed when L2 (and L3) are deleted. This suggests that the IAS interacts with the attachment sites in an ordered fashion, first with attL and then with attR. Furthermore we show that mini-Mu transposition is enhanced when Fpro-lac is used as a target instead of Ftet. We show that this elevated transposition is dependent on the Mu A binding sites L2,L3 and R2. These sequences could possibly mediate an interaction between the mini-Mu plasmid and sequences present on Fpro-lac.

YscN, the putative energizer of the Yersinia Yop secretion machinery

Pathogenic yersiniae secrete a set of 11 antihost proteins called Yops. Yop secretion appears as the archetype of the type III secretion pathway. Several components of this machinery are encoded by the virA (lcrA) and virC (lcrC) loci of the 70-kb pYV plasmid. In this paper, we describe yscN, another gene involved in this pathway. It is the first gene of the virB locus. It encodes a 47.8-kDa protein similar to the catalytic subunits of F0F1 and related ATPases, as well as to products of other genes presumed to be involved in a type III secretion pathway. YscN contains the two consensus nucleotide-binding motifs (boxes A and B) described by Walker et al. (J. E. Walker, M. Saraste, M. J. Runswick, and N. J. Gay, EMBO J. 1:945-951, 1982). We engineered a pYV mutant encoding a modified YscN protein lacking box A. This mutant, impaired in Yop secretion, can be complemented in trans by a cloned yscN gene. We conclude that YscN is a component of the Yop secretion machinery using ATP. We hypothesize that it is either the energizer of this machinery or a part of it.

Inhibition of bacteriophage Mu transposition by Mu repressor and Fis

In this paper we show that the Escherichia coli protein Fis has a regulatory function in Mu transposition in the presence of Mu repressor. Fis can lower the transposition frequency of a mini-Mu 3-80-fold, but only if the Mu repressor is expressed simultaneously. In this novel type of regulation of transposition by the concerted action of Fis and repressor, the IAS, the internal activating sequence, is also involved as deletion of this site lead to the loss of the Fis effect. As the IAS contains strong repressor binding sites these are probably the target for the repressor in the observed negative regulation by Fis and repressor. However, the role of Fis and repressor is not only to inactivate the IAS, since a 4 bp insertion in the IAS, which changes the spacing of the repressor-binding site, abolishes the enhancing function of the IAS but leaves the repressor-Fis effect intact. A likely target for Fis in this regulation is a strong Fis-binding site, which is located adjacent to the L2 transposase-binding site. However, when this Fis-binding sequence was substituted by a random sequence and Fis no longer showed specific binding to this site, the Fis effect was still observed. Although it is still possible that Fis can function by binding to this non-specific site in a particular complex, it seems more likely that Fis is directly or indirectly involved in determining the level of the repressor.

Involvement of Escherichia coli FIS protein in maintenance of bacteriophage mu lysogeny by the repressor: control of early transcription and inhibition of transposition

The Escherichia coli FIS (factor for inversion stimulation) protein has been implicated in assisting bacteriophage Mu repressor, c, in maintaining the lysogenic state under certain conditions. In a fis strain, a temperature-inducible Mucts62 prophage is induced at lower temperatures than in a wild-type host (M. Bétermier, V. Lefrère, C. Koch, R. Alazard, and M. Chandler, Mol. Microbiol. 3:459-468, 1989). Increasing the prophage copy number rendered Mucts62 less sensitive to this effect of the fis mutation, which thus seems to depend critically on the level of repressor activity. The present study also provides evidence that FIS affects the control of Mu gene expression and transposition. As judged by the use of lac transcriptional fusions, repression of early transcription was reduced three- to fourfold in a fis background, and this could be compensated by an increase in cts62 gene copy number. c was also shown to inhibit Mu transposition two- to fourfold less strongly in a fis host. These modulatory effects, however, could not be correlated to sequence-specific binding of FIS to the Mu genome, in particular to the strong site previously identified on the left end. We therefore speculate that a more general function of FIS is responsible for the observed modulation of Mu lysogeny.

DNA-promoted assembly of the active tetramer of the Mu transposase

A stable tetramer of the Mu transposase (MuA) bound to the ends of the Mu DNA promotes recombination. Assembly of this active protein-DNA complex from monomers of MuA requires an intricate array of MuA protein-binding sites on supercoiled DNA, divalent metal ions, and the Escherichia coli HU protein. Under altered reaction conditions, many of these factors stimulate assembly of the MuA tetramer but are not essential, allowing their role in formation of the complex to be analyzed. End-type MuA-binding sites and divalent metal ions are most critical and probably promote a conformational change in MuA that is necessary for multimerization. Multiple MuA-binding sites on the DNA contribute synergistically to tetramer formation. DNA superhelicity assists cooperativity between the sites on the two Mu DNA ends if they are properly oriented. HU specifically promotes assembly involving the left end of the Mu DNA. In addition to dissecting the assembly pathway, these data demonstrate that the tetrameric conformation is intrinsic to MuA and constitutes the form of the protein active in catalysis.

Cloning and characterization of a gene required for the secretion of extracellular enzymes across the outer membrane by Xanthomonas campestris pv. campestris

Nonpathogenic mutants of Xanthomonas campestris pv. campestris, generated from transposon mutagenesis, accumulated extracellular polygalacturonate lyase, alpha-amylase, and endoglucanase in the periplasm. The transposon Tn5 was introduced by a mobilizable, suicidal plasmid, pSUP2021 or pEYDG1. Genomic banks of wild-type X. campestris pv. campestris, constructed on the broad-host-range, mobilizable cosmid pLAFR1 or pLAFR3, were conjugated with one of the mutants, designated XC1708. Recombinant plasmids isolated by their ability to complement XC1708 can be classified into two categories. One, represented by pLASC3, can complement some mutants, whereas the other, represented by a single plasmid, pLAHH2, can complement all of the other mutants. Restriction mapping showed that the two recombinant plasmids shared an EcoRI fragment of 8.9 kb. Results from subcloning, deletion mapping, and mini-Mu insertional mutation of the 8.9-kb EcoRI fragment suggested that a 4.2-kb fragment was sufficient to complement the mutant XC1708. Sequence analysis of this 4.2-kb fragment revealed three consecutive open reading frames (ORFs), ORF1, ORF2, and ORF3. Hybridization experiments showed that Tn5 in the genome of XC1708 and other mutants complemented by pLASC3 was located in ORF3, which could code for a protein of 83.5 kDa. A signal peptidase II processing site was identified at the N terminus of the predicted amino acid sequence. Sequence homology of 51% was observed between the amino acid sequences predicted from ORF3 and the pulD gene of Klebsiella species.

Molecular analysis of the aidD6::Mu d1 (bla lac) fusion mutation of Escherichia coli K12

In this report we present genetic and biochemical evidence indicating that the aidD6::Mu d1 (bla lac) fusion is an insertion of Mu d1 (bla lac) into the alkB coding sequence. We describe the phenotypic effects resulting from this mutation and compare them with the effects of alkB22, alkA and ada mutations. We also constructed an alkA alkB double mutant and compared its phenotype with that of the single mutant strains. The observation that the methyl methanesulfonate (MMS) and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) resistance of the double mutant is approximately at the level predicted from the additive sensitivity of each of the single mutants suggests that these two gene products act in different pathways of DNA repair.

The cis-acting DNA sequences required in vivo for bacteriophage Mu helper-mediated transposition and packaging

The 37,000 bp double-stranded DNA genome of bacteriophage Mu behaves as a plaque-forming transposable element of Escherichia coli. We have defined the cis-acting DNA sequences required in vivo for transposition and packaging of the viral genome by monitoring the transposition and maturation of Mu DNA-containing pSC101 and pBR322 plasmids with an induced helper Mu prophage to provide the trans-acting functions. We found that nucleotides 1 to 54 of the Mu left end define an essential domain for transposition, and that sequences between nucleotides 126 and 203, and between 203 and 1,699, define two auxiliary domains that stimulate transposition in vivo. At the right extremity, the essential sequences for transposition require not more than the first 62 base pairs (bp), although the presence of sequences between 63 and 117 bp from the right end increases the transposition frequency about 15-fold in our system. Finally, we have delineated the pac recognition site for DNA maturation to nucleotides 32 to 54 of the Mu left end which reside inside of the first transposase binding site (L1) located between nucleotides 1-30. Thus, the transposase binding site and packaging domains of bacteriophage Mu DNA can be separated into two well-defined regions which do not appear to overlap.

Identification of phosphate starvation-inducible genes in Escherichia coli K-12 by DNA sequence analysis of psi::lacZ(Mu d1) transcriptional fusions

Twenty-four independent phosphate starvation-inducible (psi) transcriptional fusions made with Mu d1(lacZbla) were analyzed by sequencing the psi::lacZ(Mu d1) chromosomal junctions by using DNAs amplified with the polymerase chain reaction or mini-Mu cloning. Our DNA sequence analysis showed that the MuR DNA in Mu d1 has an unexpected structure that is comprised of 104 bases of MuR DNA in the form of a large inverted repeat, which we denoted Mu d1-R. Also, Mu d1s in the phoA and phn (psiD) loci of the phosphate regulon showed regional specificities for the insertion sites despite the randomness of Mu d1 insertions into the genome as a whole. Gene products or open reading frames were identified for seven unknown psi::lacZ(Mu d1) transcriptional fusions by searching DNA data bases with the sequences adjacent and upstream of the Mu d1s. One psiC::lacZ(Mu d1) lies in the ugpB gene of the ugpBAEC operon, which encodes a periplasmic sn-glycerol-3-phosphate-binding protein; two psiQ::lacZ(Mu d1)s lie in the gltB gene, and one psiQ::lacZ(Mu d1) lies in the gltD gene of the gltBDF operon, encoding the large and small subunits of glutamate synthase, respectively; and the psi-51::lacZ(Mu d1) lies in the glpB gene of the glpABC operon, which codes for the anaerobically regulated glycerol-3-phosphate dehydrogenase. psiE and psiF::lacZ(Mu d1)s lie in uncharacterized open reading frames near the xylE and phoA genes, respectively. Six other psi::lacZ(Mu d1)s lie in yet unreported Escherichia coli sequences.

Nucleotide sequence and transcriptional analysis of the Escherichia coli agp gene encoding periplasmic acid glucose-1-phosphatase

The nucleotide sequence of the agp gene, which encodes a periplasmic glucose-1-phosphatase, was determined. The deduced amino acid sequence corresponds to a 413-amino-acid-residue polypeptide with a typical hydrophobic signal sequence of 22 amino acids. The mature protein lacks the N-terminal signal peptide and has a calculated Mr of 43,514. Its promoter was defined by primer extension of the mRNA made in vivo. Like many genes under positive control, its -35 promoter region does not match the consensus. The agp gene is both preceded and followed by transcription termination signals, so it appears to be transcribed as a single unit.

Secondary structural features of the bacteriophage Mu-encoded A and B transposition proteins

The role of the bacteriophage Mu-encoded A and B proteins is to direct the transposition of Mu DNA. These are the first active DNA transposition proteins to have been purified and their mechanism of action at the biochemical level is under intensive study. Structural studies on these proteins, however, have lagged behind their biochemical characterization. We report here near- and far-u.v. c.d. spectra for these proteins and their secondary structural features derived from these data. The Mu A protein appears to be composed of primarily beta-sheet (40%) with 24% alpha-helix, 9% beta-turn and 27% random coil. In contrast, the Mu B protein contains 55% alpha-helix with only 13% beta-sheet and 3+ beta-turn and 29% random coil. The near-u.v. c.d. spectrum of the A protein was not unusual; however, the profile of the B protein suggested either buried or restricted chromophores within the protein or short-range interactions between aromatic residues.

Mini-D3112 bacteriophage transposable elements for genetic analysis of Pseudomonas aeruginosa

Small bacteriophage D3112 transposable elements deleted for most of the phage-lytic functions while retaining the sites required for transposition and packaging were constructed to facilitate genetic studies in Pseudomonas aeruginosa. These mini-D derivatives were constructed with the terminal 1.85 kilobases (kb) of the phage left end and 1.4 kb of the phage right end and either the Tn5 kanamycin resistance or the pSC101 (pBR322) tetracycline resistance determinant. Thermally induced lysates of strains lysogenic for both a mini-D element and D3112 cts (temperature-sensitive repressor) transduced P. aeruginosa PAO recipients to drug resistance at frequencies of between 10(-4) and 10(-5)/PFU of the helper phage. As for the parent plaque-forming D3112 phage, the mini-D171 element could insert itself into many different sites in the chromosome but the frequency of insertion into particular genes varied widely. Among 1,000 insertions, none resulted in auxotrophy but 10 resulted in pigment production. Insertions were also selected in a cloning plasmid with a transduction scheme. At least eight different insertion sites were found to have been used among 10 individual insertions. Transductants harboring these mini-D elements were immune to infection by D3112, since they contained the D3112 repressor gene in the left 1.85-kb terminal fragment. Chromosomal genes were transduced in a generalized fashion 100 to 1,000 times more frequently by the mini-D-D3112 cts lysates than by the D3112 cts phage alone. Mini-D171-D3112 cts lysates also yielded some transductants that retained the drug resistance marker of the mini-D element and which were unstable for the chromosomal transduced marker. This is consistent with the miniduction properties of Mu whereby transduced genes are flanked by two mini-D elements in the same orientation.

In vivo cloning of Pseudomonas aeruginosa genes with mini-D3112 transposable bacteriophage

The transposition properties of the Pseudomonas aeruginosa mutator bacteriophage D3112 were exploited to develop an in vivo cloning system. Mini-D replicon derivatives of D3112 were constructed by incorporating broad host range plasmid replicons between short terminal D3112 sequences. These elements were made with small replication regions from the RK2, Sa, and pVS1 plasmids and selectable genes for tetracycline, carbenicillin, kanamycin, and gentamicin resistance. Some of the mini-D replicons also contain the RK2 oriT origin-of-transfer sequence, which allows them to be mobilized by conjugation to many different species of gram-negative bacteria. These elements were used to clone DNA by preparing lysates from P. aeruginosa cells harboring an inducible D3112 cts prophage and a mini-D replicon plasmid. These lysates were used to infect sensitive P. aeruginosa recipients and select recombinant plasmids as drug-resistant transductant colonies. These transductants form a gene library from which particular clones can be selected, such as by their ability to complement specific mutations. This system was used to clone nine different genes from the PAO chromosome. The ability of this system to precisely identify a gene was demonstrated by isolating clones of the argF+ and cys-59+ genes. Restriction maps of clones of these genes, which have different amounts of flanking DNA, located the positions of these genes. The sizes of the chromosomal DNA segments from 10 individual clones examined ranged from 6 to 21 kilobases (kb), with an average of about 10 kb. This is consistent with the approximately 40-kb DNA-packaging size of the D3112 phage.

cis-acting DNA sequence requirements for P-element transposition

The P transposable element of Drosophila melanogaster has a complex array of cis-acting DNA sequences necessary for efficient transposition. At the 3' end these sequences extend over more than 150 bp and include 11- and 31-bp sequences found repeated in inverted orientation at the 5' end. The P element's 5' end, however, cannot function as its 3' end. When two 3' P-element ends are present, the more proximal end is used preferentially. We found also that the duplication of the target site does not appear to play a role in forward transposition.

Interaction of distinct domains in Mu transposase with Mu DNA ends and an internal transpositional enhancer

Bacteriophage Mu is the largest and most efficient transposable element known. The Mu transposase (A protein) of relative molecular mass 75,000 is a central component of the transposition machinery. We report here that the N-terminal region of Mu transposase contains two distinct DNA-binding domains, one which binds the two Mu DNA ends, and another which binds an internal operator region. This internal operator is required for the transposase-mediated synapsis and nicking of Mu ends in vitro, and stimulates transposition more than 100-fold in vivo. The orientation of the operator with respect to the ends is critical to its function, whereas its distance from the ends seems to be relatively unimportant. We propose that the operator enhances transposition by transiently interacting with the transposase and Mu DNA end(s) to form a complex in which synapsis of the ends occurs.

A subsequence-specific DNA-binding domain resides in the 13 kDa amino terminus of the bacteriophage Mu transposase protein

We have previously reported that the 13 kDa amino terminus of the 70 kDa bacteriophage D108 transposase protein (A gene product) contains a two-component, sequence-specific DNA-binding domain which specifically binds to the related bacteriophage Mu's right end (attR) in vitro. To extend these studies, we examined the ability of the 13 kDa amino terminus of the Mu transposase protein to bind specifically to Mu attR in crude extracts. Here we report that the Mu transposase protein also contains a Mu attR specific DNA-binding domain, located in a putative alpha-helix-turn-alpha-helix region, in the amino terminal 13 kDa portion of the 70 kDa transposase protein as part of a 23 kDa fusion protein with beta-lactamase. We purified for this attR-specific DNA-binding activity and ultimately obtained a single polypeptide of the predicted molecular weight for the A'--'bla fusion protein. We found that the pure protein bound to the Mu attR site in a different manner compared with the entire Mu transposase protein as determined by DNase I-footprinting. Our results may suggest the presence of a potential primordial DNA-binding site (5'-PuCGAAA-3') located several times within attR, at the ends of Mu and D108 DNA, and at the extremities of other prokaryotic class II elements that catalyze 5 base pair duplications at the site of element insertion. The dissection of the functional domains of the related phage Mu and D108 transposase proteins will provide clues to the mechanisms and evolution of DNA transposition as a mode of mobile genetic element propagation.

Bacteriophage Mu sites required for transposition immunity

Plasmids with bacteriophage Mu sequences receive additional Mu insertions 20-700 times less frequently than plasmids without Mu sequences. The Mu sites required for this transposition immunity were mapped near each end, either of which was sufficient. The left site was between 127 and 203 base pairs from the left end, and the right site was between 22 and 93 base pairs from the right end. These sequences include the innermost but not the outermost of the three binding sites for the Mu A transposition protein at each end of Mu. Transposition immunity was cis-acting and independent of its location on a target plasmid. An additional copy of an immunity site reduced transposition a factor of 10 further. Transposition immunity was seen both during full phage lytic growth, with all the bacteriophage Mu genes, and during normal cellular growth, with a mini-Mu element containing only the Mu c and ner regulatory and A and B transposition genes.

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.

Interactions of the transposase with the ends of Mu: formation of specific nucleoprotein structures and non-cooperative binding of the transposase to its binding sites

Transposition of the E. coli bacteriophage Mu requires the phage encoded A and B proteins, the host protein HU and the host replication proteins. The ends of the genome of the phage, on which some of these proteins act, both contain three transposase (A) binding sites. The organization of these binding sites on each end, however, is different. Here we show, using DNase footprinting experiments with purified A protein, that mutant A binding sites, which affect transposition, have decreased affinity for the transposase. Furthermore the transposase binds non-cooperatively to all A binding sites both in the left and right end of Mu. Electron microscopic studies show that the A protein forms specific nucleoprotein structures upon binding to the ends of Mu. The A and B proteins interact with the ends of Mu to generate larger structures than with the A protein alone.

The right end of transposable bacteriophage D108 contains a 520 base pair protein-encoding sequence not present in bacteriophage Mu

We have cloned and characterized the right end terminal 796 bp of the transposable Mu-like bacteriophage D108. This region encompasses a 520 bp region of D108-specific sequences not present in phage Mu that contain an open reading frame encoding a 12 KDa protein. This protein can be visualized in vivo when the region is placed downstream from the strong lac UV5 promoter. The open reading frame can be expressed from the dam-regulated mod promoter (for modification of D108 DNA), yet also contains its own dam-independent promoter for expression that is detectable by northern blot analysis late in the D108 lytic cycle. Comparison of this region of D108 DNA with the corresponding region of Mu DNA suggests that a complex rearrangement has occurred at the phages' right ends during their evolution.

B protein of bacteriophage mu is an ATPase that preferentially stimulates intermolecular DNA strand transfer

A DNA strand-transfer reaction is an early step in the transposition of phage Mu. It has been shown that an efficient reaction in vitro requires, in addition to buffer and salt, only the Mu A protein, Mu B protein, host protein HU, ATP, and Mg2+. We have determined that, of the three protein factors involved, only the Mu B protein has an ATPase activity. The Mu B ATPase is stimulated by Mu A protein and DNA but not by either of these factors alone. Double-stranded DNA is a much better cofactor than single-stranded DNA, but there is no apparent sequence specificity. In the absence of the Mu B protein and/or ATP, the intermolecular Mu DNA strand-transfer reaction is extremely inefficient, and the strand-transfer products are predominantly the result of an intramolecular reaction. This contrasts with the efficient intermolecular reaction that occurs if Mu B protein and ATP are provided. The Mu B protein, in the presence of Mu A protein and protein HU, therefore, seems to facilitate interactions between potential DNA target sites and pairs of Mu DNA ends.

Mini-mu bacteriophage with plasmid replicons for in vivo cloning and lac gene fusing

New mini-Mu transposons with plasmid replicons were constructed with additional features for in vivo DNA cloning and lac gene fusing in Escherichia coli. These mini-Mu replicons can be used to clone DNA by growing them with a complementing Mu bacteriophage and by using the resulting lysate to transduce Mu-lysogenic cells. These mini-Mu phage have selectable genes for resistance to kanamycin, chloramphenicol, and spectinomycin-streptomycin, and replicons from the high-copy-number plasmids pMB1 and P15A and the low-copy, broad-host-range plasmid pSa. The most efficient of these elements can be used to clone genes 100 times more frequently than with the previously described mini-Mu replicon Mu dII4042, such that complete gene banks can be made with as little as 1 microliter of a lysate containing 10(6) helper phage. The 39-kilobase-pair Mu headful DNA packaging mechanism limits the size of the clones formed. The smallest of the mini-Mu elements is only 7.9 kilobase pairs long, allowing the cloning of DNA fragments of up to 31.1 kilobase pairs, and the largest of them is 21.7 kilobase pairs, requiring that clones carry insertions of less than 17.3 kilobase pairs. Elements have been constructed to form both transcriptional and translational types of lac gene fusions to promoters present in the cloned fragment. Two of these elements also contain the origin-of-transfer sequence oriT from the plasmid RK2, so that clones obtained with these mini-Mu bacteriophage can be efficiently mobilized by conjugation.

Mutants of Escherichia coli defective for replicative transposition of bacteriophage Mu

We isolated 142 Hir- (host inhibition of replication) mutants of an Escherichia coli K-12 Mu cts Kil- lysogen that survived heat induction and the killing effect of Mu replicative transposition. All the 86 mutations induced by insertion of Tn5 or a kanamycin-resistant derivative of Tn10 and approximately one-third of the spontaneous mutations were found by P1 transduction to be linked to either zdh-201::Tn10 or Tn10-1230, indicating their location in or near himA or hip, respectively. For a representative group of these mutations, complementation by a plasmid carrying the himA+ gene or by a lambda hip+ transducing phage confirmed their identification as himA or hip mutations, respectively. Some of the remaining spontaneously occurring mutations were located in gyrA or gyrB, the genes encoding DNA gyrase. Mutations in gyrA were identified by P1 linkage to zei::Tn10 and a Nalr gyrA allele; those in gyrB were defined by linkage to tna::Tn10 and to a gyrB(Ts) allele. In strains carrying these gyrA or gyrB mutations, pBR322 plasmid DNA exhibited altered levels of supercoiling. The extent of growth of Mu cts differed in the various gyrase mutants tested. Phage production in one gyrA mutant was severely reduced, but it was only delayed and slightly reduced in other gyrA and gyrB mutants. In contrast, growth of a Kil- Mu was greatly reduced in all gyrase mutant hosts tested.

Isolation of point mutations in bacteriophage Mu attachment regions cloned in a lambda::mini-Mu phage

Twenty-one derivatives of a lambda::mini-Mu phage containing point mutations in the Mu attachment regions were isolated after mutD mutagenesis and selection for relief from Mu-specific replicative interference of lambda growth. DNA sequence analysis revealed that the single left-end mutant had suffered a T----C transition at position 1 of the Mu sequence, while the remaining 20 right-end mutants contained single base-pair insertions or deletions within the terminal 19 base pairs. A genetic assay showed that the right-end mutations revealed by sequencing were necessary for relief of the replicative inhibition of lambda growth. The properties of these mutants suggest that the terminal 2-base-pair and subterminal 8-base-pair inverted repeats are important for Mu-specific replicative transposition.

Primary structure of phage mu transposase: homology to mu repressor

The phage Mu transposase is essential for integration, replication-transposition, and excision of Mu DNA. We present the complete nucleotide and derived amino acid sequence of the transposase and analyze implications for transposase/DNA interaction. The NH2 terminus of the Mu transposase has considerable sequence homology with the Mu repressor and with the NH2 terminus of the transposase of the Mu-like phage D108. These three proteins are known to share binding sites on DNA. The protein sequence and predicted secondary structural similarities at the NH2 termini of the three proteins suggest a common DNA-binding region similar to the regions found in proteins of known structure. An internal sequence in the Mu A protein also shares these features. We anticipate that these regions will be involved in DNA recognition during transposition.

A defined system for the DNA strand-transfer reaction at the initiation of bacteriophage Mu transposition: protein and DNA substrate requirements

An early step in the transposition of bacteriophage Mu DNA in vitro is a DNA strand-transfer reaction that generates an intermediate DNA structure in which the Mu donor DNA and the target DNA are covalently joined. DNA replication, initiated at the DNA forks in this intermediate, generates a cointegrate product; simple insert products can also be formed from the same intermediate by degradation of a specific segment of the structure, followed by gap repair. This DNA strand-transfer reaction requires ATP, magnesium, the Mu A and Mu B proteins, and a factor supplied by an Escherichia coli cell extract. We have now shown that the host protein factor requirement can be satisfied by purified protein HU. The defined system has been used to determine the DNA substrate requirements for the reaction. The reaction requires the two Mu ends, located on the same DNA molecule, in the same relative orientation to one another as in the phage Mu genome. To participate in the strand-transfer reaction efficiently the mini-Mu plasmid, used as the transposon donor, must be supercoiled; the target DNA molecule may be supercoiled, relaxed circular, or linear.

DNA sequence at the end of IS1 required for transposition

The insertion sequence IS1 belongs to a class of bacterial transposable genetic elements that can form compound transposons in which two copies of IS1 flank an otherwise non-transposable segment of DNA. IS1 differs from other known elements of this class (such as IS10, IS50 and IS903) in several respects. It is one of the smallest known insertion elements, exhibits a relatively complex array of open reading frames, is present in the chromosomes of various Enterobacteria, in some cases in many copies, and its insertion can result in the duplication of either 8 or 9 base pairs (bp) in the target DNA. Furthermore, although, like other members of the compound class, it seems to undergo direct transposition, IS1 also promotes replicon fusion (co-integrate formation) at a relatively high frequency. Like all other elements studied to date, the integrity of the extremities of IS1 are essential for efficient transposition. We have constructed a test system to determine the minimal DNA sequences at the extremities of IS1 required for transposition. Sequential deletions of the end sequences reveal that 21-25 bp of an isolated extremity are sufficient for transposition. A specific sequence 13-23 bp from the ends, defining the edge of the minimal sequence, is implicated as an essential site. The sites, symmetrically arrayed at both ends of IS1, correspond to the apparent consensus sequence of the known binding sites for the Escherichia coli DNA-binding protein (called integration host factor or IHF) which is required for the site-specific recombination that leads to integration of bacteriophage lambda into the bacterial genome. The sites at the ends of IS1 may thus bind a host protein, such as JHF or a related protein, that is involved in regulating the transposition apparatus.

Mapping of a site for packaging of bacteriophage Mu DNA

Mini-Mu containing variable DNA sequences at the left end, were tested for their ability to be packaged by a helper Mu phage. It was shown that a packaging site of Mu is situated between nucleotides 35 and 58 of the left end.