Mode of insertion of the broad-host-range plasmid RP4 and its derivatives into the chromosome of Myxococcus xanthus

The mode of insertion of the broad-host-range plasmid RP4 into the chromosome of Myxococcus xanthus strain DZ1 has been analyzed. The plasmid integrated in numerous sites of the chromosome and generated insertional mutations. There is a hot spot of integration located between 31.5 and 34.5 kb clockwise from the EcoRI site of the plasmid. In the absence of this segment the insertion can, however, take place, but much less efficiently. The presence of transposable elements on the plasmid decreases severely the insertion frequency. Once integrated, RP4 could be transferred back to Escherichia coli, either by precise excision or with a segment of the Myxococcus chromosome. The role of site-specific recombination in RP4 integration is discussed.     

High-frequency chromosome transfer in Rhodopseudomonas sphaeroides promoted by broad-host-range plasmid RP1 carrying mercury transposon Tn501.

Insertion of the mercury resistance transposon Tn501 into broad-host-range plasmid RP1 greatly enhanced the ability of this plasmid to promote chromosome transfer in the photosynthetic bacterium Rhodopseudomonas sphaeroides. Compared with the wild-type RP1, which produced less than 10(-8) recombinants per donor cell, RP1::Tn501 produced between 10(-3) and 10(-7) recombinants per donor cell depending upon the marker selected. Plasmid RP1::Tn501 promoted polarized transfer of the chromosome from one or perhaps two origins on the chromosome, giving rise to two linkage groups. All of the biosynthetic and antibiotic resistance genes that have been mapped, including those involved in photosynthesis, occur on one or another of these linkage groups.     

Isolation of a Tn501 insertion mutant lacking porin protein P of Pseudomonas aeruginosa

Summary In order to demonstrate a role for anion-specific protein P channels in phosphate transport in Pseudomonas aeruginosa PAO, we wished to isolate a transposon insertion mutant deficient in protein P. A number of transposon delivery systems were tested which yielded, for the most part, whole plasmid inserts. Plasmid pMT1000 (Tsuda et al. 1984), a temperature-sensitive R68 plasmid carrying the transposon Tn501, was successfully employed in the isolation of a Tn501 insertion mutant lacking protein P under normally inducing conditions. To identify the mutant deficient in protein P, a protein P-specific polyclonal antiserum was used. This mutant, strain H576, was deficient in high-affinity phosphate transport exhibiting a Km for uptake (3.60±0.64 M) almost ten times greater than that of the wild type strain (Km=0.39 M). There was, however, no change in the V_max for high-affinity phosphate transport as a result of the loss of protein P in this mutant. The protein P-deficiency of the mutant correlated with a growth defect in a phosphate-limited medium resulting in an 18%–35% decrease in growth when compared with the wild type.     

Characterization of Pseudomonas mercury-resistance transposon Tn502, which has a preferred insertion site in RP1

Tn502mer differs in size and restriction map from the well-characterized Tn501mer. It also differs in its preferential and high-frequency insertion into the 6 kb PstI-C region of RP1. The affinity for this region is perpetuated in pVS76, a clone of RP1 PstI-C in pBR322. Restriction mapping of independent pVS76::Tn502 derivatives revealed that Tn502 inserted at the same site (or small region) in PstI-C corresponding to the 35 kb coordinate in RP1. Insertion occurred in both orientations, but one was preferred. When PstI-C was deleted from RP1, acquisition of Tn502 was reduced and the sites of insertion randomized.     

Tn1 insertion mutagenesis in Escherichia coli K-12 using a temperature-sensitive mutant of plasmid RP4

Summary A method for Tn1 insertion mutagenesis in Escherichia coli has been developed using pTH10, a mutant plasmid of RP4 temperature-sensitive for maintenance. The mutagenesis involves three steps. Firstly, from strains carrying pTH10 showing resistance to the antibiotics kanamycin, tetracycline, and ampicillin at 30° C but not at 42° C, clones are isolated resistant to kanamycin at 42° C. Such temperature-independent, drug resistant clones probably carry pTH10 integrated into the host chromosome. Secondly, they are cultivated at 30° C. At this temperature segregants carrying pTH10, which has been excised from the host chromosome, accumulate. Thirdly, to cure such segregants of autonomous pTH10, they are cultivated at 42° C. By these procedures, clones free of pTH10, but carrying Tn1 insertions on the host chromosome, were obtained.About 3% of the clones carrying Tn1 insertions were auxotrophic. Distribution of auxotrophic mutations was not random, indicating the existence of preferential integration sites of Tn1 on the host chromosome. The frequency of precise excision of Tn1 was less than 10^-10.The pTH10 plasmid has a wide host range among Gram-negative bacteria and thus may serve as a excellent vector for insertion mutagenesis of Tn₁ in many Gram-negative bacterial species.     

Tn1 insertion in Col Ib plasmid

Eight clones ColIb::Tn1 were isolated by means of transformation of E. coli 921 with DNA ColIb, RP4. Linkage between markers controlling ampicillin-resistance and synthesis of colicine was found in conjugation and transduction experiments.     

Introduction of the mercury transposon Tn501 into Rhizobium japonicum strains 31 and 110

Abstract Transposon Tn 501 , which encodes resistance to mercuric ions, was introduced into Rhizobium japonicum 110 and 31 by conjugal transfer. The transposon donor plasmid (pMD100) was able to mobilize into R. japonicum , but could not be maintained. Hg²⁺-resistant colonies were recovered at a frequency of 1.9 × 10⁻⁸/recipient for strain 110, and 1.7 × 10⁻⁷/recipient for strain 31. Presence of Tn 501 in Hg-resistant isolates was verified by Southern analysis and demonstrating transposition of Hg resistance. Transposon mutagenesis has been used to generate auxotrophic mutations at low frequency.     

DNA sequences of and complementation by the tnpR genes of Tn21, Tn501 and Tn1721

DNA sequences that encode the tnpR genes and internal resolution (res) sites of transposons Tn21 and Tn501, and the res site and the start of the tnpR gene of Tn1721 have been determined. There is considerable homology between all three sequences. The homology between Tn21 and Tn501 extends further than that between Tn1721 and Tn501 (or Tn21), but in the homologous regions, Tn1721 is 93% homologous with Tn501, while Tn21 is only 72-73% homologous. The tnpR genes of Tn21 and Tn501 encode proteins of 186 amino acids which show homology with the tnpR gene product of Tn3 and with other enzymes that carry out site-specific recombination. However, in all three transposons, and in contrast to Tn3, the tnpR gene is transcribed towards tnpA gene, and the res site is upstream of both. The res site of Tn3 shows no obvious homology with the res regions of these three transposons. Just upstream of the tnpR gene and within the region that displays common homology between the three elements, there is a 50 bp deletion in Tn21, compared to the other two elements. A TnpR- derivative of Tn21 was complemented by Tn21, Tn501 and Tn1721, but not by Tn3.     

Tn7 and Tn501 Insertions into Pseudomonas aeruginosa plasmid R91-5: mapping of two transfer regions.

We constructed a restriction endonuclease map of the Pseudomonas aeruginosa narrow-host-range plasmid R91-5. Insertions of transposons Tn7 and Tn501 into the plasmid DNA were characterized physically and genetically. The distribution of sites of insertion showed some regional specificity for the insertion of these transposons, especially TN501. The insertion of Tn7 was unusual in that all 42 of 43 insertions were in the same orientation. By relating phenotypic changes to the site of insertion, the Tn1 transposon that was already present on R91-5 and coded for carbenicillin resistance was mapped, and its orientation was determined. Two major transfer regions were identified. We believe that Tra1 is involved in conjugal DNA metabolism, whereas Tra2 is involved mainly in production of the sex pili.     

Complementation of transposition of tnpA mutants of Tn3, Tn21, Tn501, and Tn1721

The transposons Tn21, Tn501, and Tn1721 are related to Tn3. Transposition-deficient mutants (tnpA) of these elements were used to test for complementation of transpostion. Transposition of tnpA mutants of Tn501 and Tn1721 was restored by the presence in trans of Tn21, Tn501, and Tn1721, but transposition of a tnpA mutant of Tn21 was restored in trans only by Tn21 itself. Tn3 did not complement transposition of Tn21, Tn501, or Tn1721, and these elements did not complement transposition of Tn3.     

The conjugative transposon Tn5397 has a strong preference for integration into its Clostridium difficile target site

Tn5397 is a conjugative transposon, originally isolated from Clostridium difficile. The Tn5397 transposase TndX is related to the phage-encoded serine integrases and the Clostridium perfringens Tn4451 transposase TnpX. TndX is required for the insertion and excision of the transposon. Tn5397 inserts at one locus, attB(Cd), in C. difficile but at multiple sites in Bacillus subtilis. Apart from a conserved 5' GA dinucleotide at the recombination site, there appears to be little sequence conservation between the known target sites. To test the target site preference of Tn5397, attB(Cd) was introduced into the B. subtilis genome. When Tn5397 was transferred into this strain, 100% of the 50 independent transconjugants tested had Tn5397 inserted into attB(Cd). This experiment was repeated using a 50-bp attB(Cd) with no loss of target preference. The mutation of the 5' GA to 5' TC in the attB(Cd) target site caused a switch in the polarity of insertion of Tn5397, which is consistent with this dinucleotide being at the crossover site and in keeping with the mechanism of other serine recombinases. Tn5397 could also transpose into 50-bp sequences encoding the end joints attL and attR but, surprisingly, could not recombine into the circular joint of Tn5397, attTn. Purified TndX was shown to bind specifically to 50-bp attB(Cd), attL, attR, attTn, and attB(Bs)(3) with relative binding affinities attTn approximately attR > attL > attB(Cd) > attB(Bs3). We conclude that TndX has a strong preference for attB(Cd) over other potential recombination sites in the B. subtilis genome and therefore behaves as a site-specific recombinase.     

IS8- and Tn2353-mediated cointegration of the plasmids R15 and RP4::Tn1

Summary The plasmids R15 and RP4:: Tn1 form fused structures (85 Md and 92 Md cointegrates). The cointegrates do not resolve practically in recA ^– Escherichia coli cells and have a mean life-time of more than 50 generations in a recA ⁺ background.The 85 Md cointegrates were generated at a frequency of 4×10^–4 per R15 transconjugant during a mating between E. coli [R15; RP4:: Tn1] and E. coli [FColVBtrp:: Tn1755]. These plasmids carry two directly repeated copies of the mobile element IS8 at the junctions between R15 and RP4:: Tn1. The transposition of IS8 from RP4:: Tn1 to the R15 plasmid and the formation of hybrid molecules promoted by this process appear to be induced by the IS8 element of the Tn1755 structure during or after conjugal transfer of FColVBtrp:: Tn1755 into E. coli [R15; RP4:: Tn1] cells.The formation of the 92 Md cointegrates occurs at a frequency of 2×10^–5. The fused molecules of R15 and RP4:: Tn1 carry two direct copies of an 8.65 Md R15 fragment at the junctions between these replicons. The fragment has specific features of a new transposon. This element designated Tn2353 determines resistance to Hg, Sm and Su and contains two sites for each BamHI, BglII and SalI and three sites for both EcoRI and PstI. The physical map and some other characteristics of Tn2353 are presented.Abbreviations Ap ampicillin - EtBr ethidium bromide - Km kanamycin - Md megadaltons - Sm streptomycin - Su sulfanilamide - Tc tetracycline - [] brackets indicate plasmid-carrier state     

Modified RP4 and Tn5-Mob derivatives for facilitated manipulation of large plasmids in Gram-negative bacteria

We have constructed a set of RP4 (NmS/TcS) and Tn5-Mob derivatives which have applications in experiments involving mobilization of replicons in many Gram-negative organisms. The different selection markers of the RP4 and Tn5-Mob derivatives include streptomycin, chloramphenicol, gentamicin, and spectinomycin resistance as well as mercury resistance, and a constitutively expressed lacZ gene. This choice of markers allows the use of these derivatives in bacteria which are naturally resistant to many antibiotics, and in strains which contain pre-existing resistance plasmids, transposons, or antibiotic cassette insertions. In addition, a RP4 derivative carrying the sacB gene of Bacillus subtilis was constructed. This allows the selection for the loss of RP4 after it has been used to mobilize other plasmids. A Tn5-Mob-sacB derivative with a new marker (Gm) was also developed, as were vectors which take advantage of the sacB gene to facilitate replacement of existing Tn5 inserts with other Tn5 derivatives. As an example of the use of these tools, three Rhizobium leguminosarum bv. viciae VF39 plasmids which have been shown to be involved in symbiosis were differentially tagged and mobilized (individually and in various combinations) to the plasmid-free Agrobacterium tumefaciens strain UBAPF2. None of the resultant Agrobacterium strains was able to fix nitrogen in symbiosis with peas.     

C-terminal cysteines of Tn501 mercuric ion reductase.

Mercuric ion reductase (MerA) catalyzes the reduction of Hg(II) to Hg(0) as the last step in the bacterial mercury detoxification pathway. A member of the flavin disulfide oxidoreductase family, MerA contains an FAD prosthetic group and redox-active disulfide in its active site. However, the presence of these two moieties is not sufficient for catalytic Hg(II) reduction, as other enzyme family members are potently inhibited by mercurials. We have previously identified a second pair of active site cysteines (Cys558 Cys559 in the Tn501 enzyme) unique to MerA, that are essential for high levels of mercuric ion reductase activity [Moore, M. J., & Walsh, C. T. (1989) Biochemistry 28, 1183; Miller, S. M., et al. (1989) Biochemistry 28, 1194]. In this paper, we have examined the individual roles of Cys558 and Cys559 by site-directed mutagenesis of each to alanine. Phenotypic analysis indicates that both merA mutations result in a total disruption of the Hg(II) detoxification pathway in vivo, while characterization of the purified mutant enzymes in vitro shows each to have differential effects on catalytic function. Compared to wild-type enzyme, the C558A mutant shows a 20-fold reduction in kcat and a 10-fold increase in Km, for an overall decrease in catalytic efficiency of 200-fold in kcat/Km. In contrast, mutation of Cys559 to alanine results in less than a 2-fold reduction in kcat and an increase in Km of only 4-5 fold for an overall decrease in catalytic efficiency of only ca. 10-fold in vitro. From these results, it appears that Cys558 plays a more important role in forming the reducible complex with Hg(II), while both Cys558 and Cys559 seem to be involved in efficient scavenging (i.e., tight binding) of Hg(II).     

Specificity of Tn9 insertion into the genome of bacteriophage lambda att80 depending on its preceding location

It was shown that the site of previous integration (the donor site) of Tn9 affects the specificity of its next integration into the target molecule--phage lambda att80 DNA. The transposon integration sites were mapped by restriction and heteroduplex analysis following Tn9 transposition from chromosomal sites of Escherichia coli K-12 differing in location and Tn9 stability. When transposed from chromosomal galT::IS1 gene, Tn9 inserted into the site with coordinates 44,5 +/- 2 kb of lambda att80; when transposed from chromosomal attTn9A site, the transposon inserted into the sites with coordinates 31 +/- 0,7 kb or 33,3 +/- 0,5 kb. In the course of transposition of Tn9 from chromosomal attTn9N site the transposon inserted into the lambda att80 site with coordinates 26,5 +/- 5 kb. In the latter case, the increase of Tn9 single-stranded loop and the appearance of two new HindIII cleavage sites were observed in heteroduplex experiments. The data were interpreted as indicating structural rearrangements of Tn9 or linked sequences in the course of transposition.