Polypeptides expressed in Escherichia coli K-12 minicells by transposition elements Tn1 and Tn3.

Escherichia coli K-12 minicells were employed to examine polypeptides encoded by plasmids carrying wild-type and mutant Tn1 or Tn3 transposition elements. Tn1- and Tn3-containing minicells express high levels of four transposon-specified polypeptides. Three, of molecular weights 30,000, 28,000, and 25,000, are related immunologically to beta-lactamase, the enzyme responsible for ampicillin hydrolysis. A fourth polypeptide of molecular weight 19,000 is encoded by the Tn1 or Tn3 region which spans the BamHI cleavage site. Mutant transposons which no longer produce this polypeptide transpose at higher than wild-type frequencies to give aberrant transposition products (Gill et al., J. Bacteriol. 136: 742--756, 1978; Heffron et al., Proc. Natl. Acad. Sci U.S.A. 72:3632--3627, 1975). No expression could be detected from a region of the transposons extending from the inverted repeat sequence distal to the beta-lactamase gene to more than half the distance into the Tn1 or Tn3 sequence.     

Location of an ampicillin resistance transposon, Tn1701, in a group of small, nontransferring plasmids.

By restriction endonuclease cleavage mapping and electron microscopic examination of heteroduplexes, we have identified an ampicillin resistance determinant transposon, designated Tn1701, in a group of small, nontransferring plasmids which confer resistance to ampicillin (Ap), sulfonamide (Su), and streptomycin (Sm). Plasmid NTP1, which mediates Ap resistance, contains Tn1701. Recombinant plasmids NTP3 (Ap Su) and NTP4 (Ap Su Sm) contain Tn1701, indicating that they were derived by transposition of Tn1701 from NTP1 to an unrelated plasmid, NTP2 (Su Sm). The transposon Tn1701 is very similar to the known ampicillin resistance transposons Tn1, Tn2, and Tn3 in its size (3.2 x 10(6) daltons), base sequence homology observed by heteroduplex formation, restriction endonuclease cleavage sites, and possession of a short inverted repeat sequence at both ends. Like the other TnA elements, Tn1701 also specifies a type TEM beta-lactamase.     

Characteristics of Tn3611 and Tn3613 transposons discovered in the chromosome of the BS205 strain of Pseudomonas aeruginosa

The transposons Tn3611 (HgR, 9.0 kb) and Tn3613 (SmRCmRKmRSuRHgR, 24.0 kb) were discovered in the chromosome of Pseudomonas aeruginosa BS205. The physical and genetic maps of these transposons were constructed using restriction endonucleases EcoRI, BamHI, SalI, HindIII. Genes of the mer operon, tnpA and tnpR were localized in the Tn3611 transposon, the genes DHPS-II, aad, tnpA, tnpR being situated in the map of the Tn3613 transposon. It was established that the Tn3611 belongs to the class of Tn3-like transposons and the Tn3613 is a complex transposon flanked by inverted repeats 2.2 kb in size, the transposon comprising both Tn3611 and a migrating sequence.     

Characterization of Tn2411 and Tn2410, two transposons derived from R-plasmid R1767 and related to Tn2603 and Tn21

Two transposable elements, Tn2410 and Tn2411, were isolated from Salmonella typhimurium R-factor R1767. They have sizes of 18.5 and 18.0 kilobases, respectively. Tn2411 mediates resistance to streptomycin, sulfonamides, and mercury. In Tn2410, the streptomycin resistance gene was replaced by a gene coding for the production of the beta-lactamase OXA-2, which is responsible for ampicillin resistance. Physical and functional maps of both transposons were compared with those of Tn21, Tn4, and Tn2603. From these data it appeared that Tn21 could be an ancestral transposon from which Tn2411, Tn2410, Tn2603, and Tn4 were evolved by the addition or deletion of small DNA segments.     

Construction of a physical map of a kanamycin (Km) transposon, Tn5, and a comparison to another km transposon, Tn903

Summary A cleavage map of Tn5, a kanamycin (Km) transposon from plasmid JR67, was constructed from pMKI, a composite plasmid of ColE1 and Tn5, and compared to that of Tn903, a Km transposon from plasmid R6-5. The two transposons showed marked heterogeneity in both the structural gene for Km resistance and the inverted repeat regions as evidenced by their distinctly different restriction maps. This result suggests separate paths of evolution for the two Km transposons.     

Genetic properties of transposons Tn6-1, Tn6-2 and Tn19-1

The level and range transposition of the transposons Tn6-1, Tn6-2, Tn19-1, and their ability to influence plasmid transfer has been studied. The widest range of transposition was shown for transposon Tn6-2. Insertions of each of the studied transposons into different conjugative plasmids genomes resulted in change of frequencies of plasmids transfer and change of plasmids mobilization activity.     

Tn2301, a transposon construct carrying the entire transfer region of the F plasmid.

The largest R . BamHI fragment of the plasmid F, which carries the entire F conjugation system, has been cloned into the single R . BamHI site of the ampicillin (Ap) resistance transposon TN1. pDS1106 (ColE1 mob::Tn1) was the vector plasmid, and the resultant conjugative plasmid, pED830, was characterized both genetically and by restriction enzyme analysis. The transposon construct, denoted Tn2301, was transposable at frequencies similar to Tn1 to small nonconjugative plasmids or to the Escherichia coli host chromosome. In the former case, Apr conjugative plasmids were obtained, whereas in the latter case, Hfr strains resulted. Representative Hfr strains were characterized by quantitative and interrupted mating experiments. Extension of this technique for Hfvr formation should aid chromosome mapping both in E. coli and in other bacterial genera.     

Definition of three resolvase binding sites at the res loci of Tn21 and Tn1721.

The dual functions of resolvase, site-specific recombination and the regulation of its own expression from tnpR, both require the interaction of this protein with the DNA sequence at res, but the specificity of this interaction differs between groups of Tn3-like elements. In this study, DNA fragments that contained res from Tn21 or Tn1721 were subjected to either cleavage by DNase I or methylation by dimethyl sulphate in the presence of the purified resolvase from Tn21 or Tn1721. These experiments showed that each resolvase bound to the same three sites (I, II and III) within res from Tn1721 and to an equivalent series of three sites on Tn21: the differences in the amino acid sequences of the two proteins did not affect their interaction with either DNA. The DNA sequences at each site had some similarities and, in conjunction with data from the related transposon Tn501, a consensus was established. However, the three sites are functionally distinct: site I (tnpR-distal) spans the recombination cross-over point and sites II and III (tnpR-proximal) overlap the promoter of tnpR. The binding sites on these transposons were compared with those in the gamma delta/Tn3 system: the similarities between the two groups of transposons revealed some general features of resolvase-DNA interactions while the differences in fine structure elucidated the specificity of each resolvase.     

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.     

Restriction enzyme cleavage map of Tn10, a transposon which encodes tetracycline resistance.

A cleavage map of a recombinant plasmid carrying Tn10 was constructed for 13 different restriction enzymes. The Tn10 region of this plasmid contains cleavage sites for BamHI, AvaI, BglI, BglII, EcoRI, XbaI, HincII, HindIII, and HpaI. Restriction enzymes PstI, SmaI, KpnI, XhoI, SalI, and PvuI do not cleave within the Tn10 element. This map confirms the previously reported structure of this transposon; it is composed of a unique sequence (approximately6,400 base pairs long), which in part codes for the tetracycline resistance functions and is bounded by inverted repeats (approximately 1,450 base pairs long).     

Relationships among the streptothricin resistance transposons Tn1825 and Tn1826 and the trimethoprim resistance transposon Tn7

The streptothricin resistance transposons Tn1825 and Tn1826 are closely related, based on physical and genetic characteristics, to the trimethoprim resistance transposon Tn7. These transposons may be considered to be members of a transposon family sharing in common the transposition functions and a basic streptomycin/spectinomycin resistance determinant but differing from one another with respect to particular additional resistance genes inserted to the left of the aadA gene.     

Isolation and characteristics of compound transposons Tn1000::Tn5

Two types of compound transposons were derived. In the first case, transposon Tn5 is inserted into the gene responsible for Tn1000 transposase synthesis. In the other, Tn5 is inserted into the region near the left end of Tn1000, where no functionally significant genes were found. It is known that translocation of the compound transposons does not depend on their size and takes place with the efficiency close to that characteristic of the intact Tn1000. Insertion of Tn5 into the gene coding for Tn1000 transposase results in sharp decrease in the efficiency of Tn1000 translocations. This effect, however, may be eliminated by introduction into the cell of the intact Tn1000.     

Pulling apart catalytically active Tn5 synaptic complexes using magnetic tweezers

The Tn5 transposase is an example of a class of proteins that move DNA sequences (transposons) via a process called transposition. DNA transposition is a widespread genetic mobility mechanism that has profoundly affected the genomes of nearly all organisms. We have used single-DNA micromanipulation experiments to study the process by which Tn5 DNA transposons are identified and processed by their transposase protein. We have determined that the energy barrier to disassemble catalytically active synaptic complexes is 16 kcal mol(-1). However, we have found that the looping organization of DNA segments by transposase is less sequence-driven than previously thought. Loops anchored at some non-transposon end sequences display a disassembly energy barrier of 14 kcal mol(-1), nearly as stable as the synapses formed at known transposon end sequences. However, these non-transposon end sequence independent complexes do not mediate DNA cleavage. Therefore, the sequence-sensitivity for DNA binding and looping by Tn5 transposase is significantly less than that required for DNA cleavage. These results have implications for the in vivo down regulation of transposition and the cis-transposition bias of transposase.     

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.     

Analysis of sequences transposed by complementation of two classes of transposition-deficient mutants of Tn3.

The Tn1 and Tn3 elements are closely related transposons which carry the structural gene for ampicillin resistance. Two classes of deletion mutants of the plasmid pMB8::Tn3 (RSF1050) are unable to transpose ampicillin resistance but can be complemented in trans by a coresident Tn1 or Tn3 element. The analysis of the sequences transposed upon complementation of one class of mutants (type I) showed that the mutant element had undergone bona fide transposition. Complementation of the type II mutants led to the transposition of a sequence analogous to bacteriophage mu-promoted integration of non-mu DNA. The transposed sequence consisted of two Tn3 elements which flanked a single copy of the pMB8 portion of the RSF1050 genome. Complementation data indicated that the type II mutants are defective in at least one trans-acting function which must be supplied for transposition to occur. The nature of sequence transposed from the type II mutant is the consequence of a defective cis-acting function (or site). In addition, the type II mutants were defective in a trans-acting function which regulated the frequency of transposition.     

pIF21, a versatile donor of transposons Tn1, Tn5 and Tn7 for tagging and mobilizing cryptic and non-selectable plasmids

A plasmid, pIF21, has been constructed that is able to donate transposons Tn1, Tn5 and Tn7. The transposons are located on a temperature-sensitive derivative of the incP1 plasmid pRP1, which is transferable to a wide range of Gram-negative genera.     

Transposons Tn916 and Tn925 can transfer from Enterococcus faecalis to Leuconostoc oenos

Abstract The streptococcal transposons Tn916 and Tn925 were transferred to several strains of Leuconostoc (Ln.) oenos using the filter mating method. The insertion of both transposons into the chromosome occurred at different sites. Transconjugants of Ln. oenos carrying Tn916 could serve as donors in mating experiments with Lactococcus lactis LM2301. Further analysis of L. lactis LM2301 transconjugants showed that the insertion of the transposon Tn916 into the chromosome was site-specific. These studies establish a basis for the initiation of genetic studies in this Leuconostoc species since there are no efficient conjugal or transformation systems previously described for this microorganism.     

Distribution of transposons Tn5044 and Tn5070 with unusual mer operons in environmental bacterial populations

The distribution of unusual mercury resistance transposons, Tn5044 and Tn5070, was examined. A characteristic feature of Tn5044 is temperature sensitivity of its mercury operon and the presence in the mer operon of the gene homologous to RNA polymerase a subunit. Structural organization of mercury operon Tn5070, containing minimum gene set (merRTPA), differs from mer operons of both Gram-negative and Gram-positive bacteria. None of more than two thousand environmental bacterial strains displaying mercury resistance and isolated from the samples selected from different geographical regions hybridized to Tn5040- and Tn5070-specific probes. A concept on the existence of cosmopolite, endemic, and rare transposons in environmental bacterial populations was formulated.     

Characterization of the transposons Tn1822 (Tc) and Tn1824 (TpSm) and the light they throw on the natural spread of resistance genes

The transposons Tn1822 (Tc) and Tn1824 (TpSm) described in this paper are very similar or identical to the transposons Tn1771 and Tn1721 (Tc), and Tn7 (TpSm), respectively. They were isolated from different sources and replicons, however, suggesting a wide distribution of these types of transposons. The method used to isolate and characterize the transposons, involving a temperature-sensitive P1 phage as their transient vehicle, is particularly suitable for epidemiological studies on transposon distribution.