Conjugative transposition of the vancomycin resistance carrying Tn1549: enzymatic requirements and target site preferences

Rapid spread of resistance to vancomycin has generated difficult to treat bacterial pathogens worldwide. Though vancomycin resistance is often conferred by the conjugative transposon Tn1549, it is yet unclear whether Tn1549 moves actively between bacteria. Here we demonstrate, through development of an in vivo assay system, that a mini‐Tn1549 can transpose in E. coli away from its natural Gram‐positive host. We find the transposon‐encoded INT enzyme and its catalytic tyrosine Y380 to be essential for transposition. A second Tn1549 protein, XIS is important for efficient and accurate transposition. We further show that DNA flanking the left transposon end is critical for excision, with changes to nucleotides 7 and 9 impairing movement. These mutations could be partially compensated for by changing the final nucleotide of the right transposon end, implying concerted excision of the two ends. With changes in these essential DNA sequences, or without XIS, a large amount of flanking DNA transposes with Tn1549. This rescues mobility and allows the transposon to capture and transfer flanking genomic DNA. We further identify the transposon integration target sites as TTTT‐N6‐AAAA. Overall, our results provide molecular insights into conjugative transposition and the adaptability of Tn1549 for efficient antibiotic resistance transfer.     

Tn5037, a Tn21-like Mercury Resistance transposon from Thiobacillus ferrooxidans

The 6645-bp mercury resistance transposon of the chemolithotrophic bacterium Thiobacillus ferrooxidanswas cloned and sequenced. This transposon, named Tn5037, belongs to the Tn21branch of the Tn21subgroup, many members of which have been isolated from clinical sources. Having the minimum set of the genes (merRTPA), the mercury resistance operon of Tn5037is organized similarly to most of the Gram-negative bacteria meroperons and is closest to that of ThiobacillusT3.2. The operator-promoter region of the meroperon of Tn5037also has the common (Tn21/Tn501-like) structure. However, its inverted, presumably MerR protein binding repeats in the operator/promoter element are two base pairs shorter than in Tn21/Tn501. In the merA region, this transposon shares 77.4, 79.1, 83.2 and 87.8% identical bases with Tn21, Tn501, T. ferrooxidansE-15, and ThiobacillusT3.2, respectively. No inducibility of the Tn5037 meroperon was detected in the in vivo experiments. The transposition system (terminal repeats plus gene tnpA) of Tn5037was inactive in Escherichia coliK12, in contrast to its resolution system (ressite plus gene tnpR). However, transposition of Tn5037in this host was provided by the tnpAgene of Tn5036, a member of the Tn21subgroup. Sequence analysis of the Tn5037 ressite suggested its recombinant nature.     

DNA inversion mediated by the r-determinant of plasmid NR1: evidence for the intramolecular replicative transposition of a 23 kb IS1-flanked transposon?

Summary The r-determinant (r-det) of the R plasmid NR1-Basel is a 23 kb, IS1-flanked transposon, called Tn2671, which has been shown to transpose to the genome of bacteriophage P7. Among the derivatives of phage P7::r-det we found one which carried two copies of the r-det as inverted repeats and which also contained the P7 genome segment between them in inverted orientation. Its generation is best explained by assuming that the entire 23 kb Tn2671 transposon has undergone intramolecular replicative transposition.     

A Tn21 terminal sequence within Tn501: complementation of tnpA gene function and transposon evolution

Summary The prokaryotic mercury-resistance transposon Tn501 contains a sequence, 80 nucleotides from one end, which is identical with an inverted terminal repeat (IR) of Tn21. This Tn21 IR sequence is used when Tn21 complements a TnpA^- derivative of Tn501, but not when Tn501 is used for the complementation. Complementation by Tn1721 shows a preference for the normal Tn501 IRs. The element (Tn820) transposed when Tn21 is used to complement a Hg^- TnpR^- TnpA^- Res^- deletion mutant of Tn501 contains the Tn21 IR sequence at one terminus and a Tn501 IR at the other. Transposition of Tn820 can be complemented by Tn501 and Tn1721, but at a much lower frequency than transposition of the parental element (Tn819) which has two Tn501 IRs. The relationship between the transposition functions of Tn501, Tn21 and Tn1721, and available nucleotide sequence data suggest that Tn501 evolved by the transposition of a Tn21-like element into another transposable element (similar to that found within Tn1721) followed by deletion of the Tn21-like transposition functions.Abbreviations used (IR) Inverted repeat - (Cb) carbenicillin - (Cm) chloramphenicol - (Sm) streptomycin - (Su) sulphonamide - (Tc) tetracycline - (Tp) trimethoprim     

Genetic analysis of Tn7 transposition

Summary The purpose of this work was to localize the DNA regions necessary for the transposition of Tn7. Several deletions of Tn7 were constructed by the excision of DNA fragments between restriction sites. The ability of these deleted Tn7s to transpose onto the recipient plasmid RP4 was examined. All the deleted Tn7s isolated in this work had lost their transposing capability. The possibility of complementing them was studied using plasmids containing all or part of Tn7. Two deleted Tn7s could not be complemented by an entire Tn7 indicating that a DNA sequence greater than the 42 bp terminal sequence is needed for recognition of the transposon by a transposition function. Four other deleted Tn7s could be complemented by Tn7. One of these was studied intensively in complementation experiments using different parts of Tn7 to obtain transposition. The results obtained allow us to propose that all genes needed for transposition of Tn7 onto plasmids are contained in a DNA segment of between 6.0 and 7.4 kb. Furthermore, one essential function must be contained in a DNA fragment longer than 2.5 kb on the right-hand end of Tn7. The classification of Tn7 with regard to the other transposable elements is discussed.     

Analysis of the reduction in expression of tetracycline resistance determined by transposon Tn10 in the multicopy state

The tet genes of transposon Tn10 have been mapped in a 2,200 bp DNA sequence by analysing deletion and Tn5 insertion mutations. When the tet genes were present on multi-copy plasmids the level of resistance expressed was about ten-fold lower than that determined by a single copy of Tn10 in the E. coli chromosome. The 36K tet protein known to be encoded by R100 in E. coli minicells was not detected when they harboured a multicopy tet plasmid. However, normal high levels of resistance were expressed when the tet genes were recombined into the host chromosome as part of a lambda lysogen, showing that the multicopy effect was phenotypic. Most of the Tn5 insertions and deletions in tet which caused Tc^s mutations also prevented expression of high level Tc^r from a chromosomal Tn10 element present in the same cell. Only those insertions in the promoter-proximal 90–130 bp of a 1,275 bp HindII fragment known to carry the gene encoding the 36K tet protein did not reduce the single copy Tn10 resistance level.A gene fusion system that results in the constitutive synthesis of -galactosidase from a tet promoter has been used to assay tet repressor activity. The basal (uninduced) -galactosidase level in cells carrying multicopy tet plasmids was 10–20 fold lower than those carrying a single copy. The tet:: Tn5 mutants defective in the trans-dominant multicopy effect still made normal amounts of tet repressor showing that repressor overproduction was not responsible for this effect. In addition a repressor-defective constitutive mutant did not exhibit a higher resistance level when located on a multicopy plasmid vector. We postulate that a regulatory mechanism recognises the amino-terminus of the tet structural gene product when attempts are being made to overproduce the protein and prevents further translation.     

Marking of a Sym plasmid of Rhizobium with Tn7

Summary Transposon Tn7 was inserted into wide host range plasmid pSUP202 and used as a suicide plasmid vehicle for transposon mutagenesis in Rhizobium leguminosarum. Tn7 is transposed with high frequency into the self-transmissible plasmid pJB5JI without affecting the transfer, nodulation and nitrogen fixation functions. Tn7 transposition provides a useful tool for marking symbiotic plasmids.     

The transposable elements resident on the plasmids of Pseudomonas putida strain H, Tn 5501 and Tn 5502 , are cryptic transposons of the Tn 3 family

Genes for (methyl)phenol degradation in Pseudomonas putida strain H (phl genes) are located on the plasmid pPGH1. Adjacent to the phl catabolic operon we identified a cryptic transposon, Tn5501, of the Tn3 family (class II transposons). The genes encoding the resolvase and the transposase are transcribed in the same direction, as is common for the Tn501 subfamily. The enzymes encoded by Tn5501, however, show only the overall homology characteristic for resolvases/integrases and transposases of Tn3-type transposons. Therefore it is likely that Tn5501 is not a member of one of the previously defined subfamilies. Inactivation of the conditional lethal sacB gene was used to detect transposition of Tn5501. While screening for transposition events we found another transposon integrated into sacB in one of the sucrose-resistant survivors. This element, Tn5502, is a composite transposon consisting of Tn5501 and an additional DNA fragment. It is flanked by inverted repeats identical to those of Tn5501 and the additional fragment is separated from the Tn5501 portion by an internal repeat (identical to the left terminal repeat). Transposition of phenol degradation genes could not be detected. Analysis of sequence data revealed that the phl genes are not located on a Tn5501-like transposon. Received: 21 July 1997 / Accepted: 7 July 1998     

Characterization of the transposon carrying the STII gene of enterotoxigenic Escherichia coli

Summary The Escherichia coli enterotoxin STII gene is carried by Tn4521. The terminal repeats of Tn4521 are composed of IS2 sequences; however, neither repeat is a complete IS2. In order to determine how this seemingly defective transposon could transpose, mutations were generated within Tn4521 to determine the regions essential for transposition. The left terminal repeat region was found to be non-essential, but the right terminal repeat area was demonstrated to be crucial for transposition. Within the right terminal repeat area is an open reading frame (ORF), capable of encoding a 159 amino acid protein, which was shown by frameshift mutation analysis to be required for transposition. This protein may be the transposase of Tn4521. A pair of 11 bp repeat sequences flanking the ORF was also found to be important. The right 11 bp repeat is part of the left IS2 terminal sequence, and the left 11 bp repeat is located about 300 bp upstream from the right IS2 terminal sequence located within the right terminal repeat region. The results of this study suggest that Tn4521 is a functional transposon and that the sequence including this pair of 11 bp sequences plus the intervening sequence is a transposable element which may be responsible for Tn4521 transposition.     

Tn10 mutagenesis in Azotobacter vinelandii

Summary The tetracycline-resistant transposon Tn10 and its high-hopper derivative Tn10HH104 were introduced into the Azotobacter vinelandii genome using suicide conjugative plasmids derived from pRK2013. Several types of mutants induced by either of these elements are described. Nif^- mutants (deficient in nitrogen fixation) were easily isolated, whereas the isolation of other mutant types (auxotrophs, sugar non-users) required special selection conditions. The characterization of the mutations as transposon insertions was often complicated and sometimes required a combination of genetic and physical tests. A common source of complication, the existence of double inserts, was found among the mutants induced by Tn10HH104 but not among those induced by Tn10. Both the high-hopper and the wild-type element proved to undergo secondary transpositions, albeit at different frequencies. Another type of complication, the existence of heterozygotes, occurred because of the high level of redundancy of the A. vinelandii genome.     

细菌中介导多重耐药的Tn7转座子研究进展

转座子是介导细菌耐药性传播的重要可移动遗传元件。Tn7转座子与细菌耐药密切相关,其携带转座模块和Ⅱ类整合子系统。Tn7编码转座相关蛋白TnsABCDE进行“剪切-粘贴”机制转座,转座核心TnsABC也可与三链DNA或Cas-RNA复合物结合实现转座。近年来新发现了多种介导多重耐药的Tn7转座子,其在介导细菌抗生素、消毒剂和重金属抗性基因的获得、传播扩散等方面发挥了重要作用。本文综述了细菌中Tn7转座子的遗传结构、转座机制、流行以及新发现的介导多重耐药的Tn7转座子,以期为细菌中Tn7转座子的深入研究提供参考。     

Control of Tn7 transposition

Summary Our isolate of Tn7 (named Tn7S) contains an IS1 insertion, and this IS1 can be converted into Tn9. In vitro and in vivo deletions of Tn7S and Tn7S:: Tn9 define regions of the transposon required for antibiotic resistance and transposition. Complementation of deletion mutants by cloned Tn7 fragments indicates the existence of two regions, denoted tnp7A and tnp7B, required for all transposition events. Another region, denoted tnp7C, is required for transposition from the chromosome to RP1 but not for transposition from a small IncP-1 replicon to the chromosome. The presence of Tn7S terminal sequences in an RP1 replicon reduces the transposition of a second Tn7S derivative from the chromosome by about one order of magnitude. The measured frequency of Tn7S transpositions from a small IncP-1 replicon to the chromosome depends on the particular incompatibility system used to eliminate that replicon. Genetic and physical data indicate that high frequencies of Tn7S transposition to the chromosome (40%) are triggered by the IncP-1 incompatibility reaction, thus suggesting the existence of a Tn7 mechanism for sensing the state of the carrier replicon.     

Resolution of a hybrid cointegrate between transposons Tn501 and Tn1721 defines the recombination site

Summary The related transposons Tn501 and Tn1721 have a 3.8 kb region in common that contains two genes (tnpA and tnpR) and a resolution site (res) required for transposition. Resolvase, the product of tnpR, catalyses site-specific recombination at res, a 186 base pair (bp) sequence located adjacent to tnpR at one end of the homology region. We describe here identification of the crossover site within res. It involved the construction of a plasmid containing copies of res (Tn501) and res (Tn1721) in direct orientation and tnpR-mediated intramolecular recombination between the two homologous (but non-identical) sites. The resulting hybrid contained Tn501 and Tn1721 fused at the crossover point. DNA sequence analysis of the recombinant indicates that recombination occurs in an 11 bp region of exact homology between Tn501 and Tn1721. The recombination site lies 161–172 bp upstream of tnpR at the transition from homology to non-homology between Tn501 and Tn1721 suggesting that site-specific recombination may have played a role in the evolution of these elements.     

Does Tn10 transpose via the cointegrate molecule?

Summary It has been well established that Tn3 and its relatives transpose from one replicon to another by two successive reactions: formation of the cointegrate molecule and resolution from it. Whether or not the 9300 base pair tetracycline resistance transposon Tn10 transposes in the same manner as Tn3 was investigated by two methods.In the first method, 55, a lambda phage carrying Tn10 was lysogenized in an Escherichia coli strain carrying a Tn10 insertion; the phage has a deletion in attP, hence it was lysogenized in a Tn10 sequence in the E. coli chromosome by reciprocal recombination. The chromosomal structure in these lysogens is equivalent to the Tn10-mediated cointegrate molecule of lambda and the E. coli chromosomal DNA. The stability of the cointegrate molecule was examined by measuring the rate of excision of lambda from the host chromosome, and was found to be stable, especially in a Rec^- strain. Because of this stability, the cointegrate molecule should be accumulated if Tn10 transposes via the cointegrate molecule. Then, we examined the configuration of products made by transposition of Tn10 from 55 to the E. coli chromosome. The cointegrate molecule was found in products of Tn10 transposition in a Rec⁺ strain at a frequency of 5% per Tn10 transposition, but this molecule could not be found in a Rec^- strain. Since transposition of Tn10 was recA-independent, absence of the cointegrate molecule formed in a RecA^- strain strongly suggested that the cointegrate molecule is not an obligatory intermediate of transposition of Tn10.In the second method, mobilization of pACYC177 by R388 and by R388:: Tn10 was examined. The pACYC177 plasmid was mobilized by R388::Tn10 at a frequency of 10^-4 per donor but not by R388. It occurred, in most cases, by inverse transposition of R388::Tn10 to pACYC177 forming plasmids such as pACYC177::IS10-R388-IS10. Mobilization of pACYC177 by a Tn10-mediated cointegrate in the form of pACYC177::Tn10-R388-Tn10 was not observed in crosses using a Rec^- donor. These observations also suggested that transposition of Tn10 in Rec^- cells does not occur via the cointegrate molecule.     

Generation of new transposons in vivo: an evolutionary role for the “staggered” head-to-head dimer and one-ended transposition

From a plasmid carrying the tnpA gene and one inverted repeat sequence (IR) of transposon Tn3, plasmids containing a structure characteristic of transposons, i.e., two IRs flanking a tnpA gene, were generated spontaneously in vivo. They appear to have arisen either through the formation of a “staggered” head-to-head dimer or by so-called one-ended transposition. These putative transposons could indeed transpose to, or form cointegrates with, a recipient plasmid. Based on these findings it is proposed that a primeval transposase gene and its target site evolved first, and subsequently gave rise to a “fully-fledged” transposon by head-to-head dimerization or one-ended transposition. Received: 30 October 1998 / Accepted: 1 April 1999     

Construction of a transposon containing a gene for polygalacturonate trans-eliminase from Klebsiella oxytoca

A DNA fragment containing a Klebsiella oxytoca gene for polygalacturonate trans-eliminase was cloned into the kanamycin resistance transposon Tn5. This new transposon, designated Tn5-Pga ⁺, had a transposition frequency of 1×10^-6. The broad host range plasmid pR751::Tn5-Pga ⁺ was conjugally transferred to a variety of genetic backgrounds. The ability to degrade polygalacturonate was expressed in Aeromonas hydrophila, Alcaligenes eutrophus, Azotomonas insolita, Escherichia coli, Pseudomonas putida and Rhodopseudomonas sphaeroides, but not in Zymomonas mobilis.Abbreviations PGA polygalacturonate - UGA unsaturated galacturonic acid - PATE polygalacturonate trans-eliminase - PG polygalacturonase - CVP crystal-violet pectate     

Identification of Tn4430, a transposon of Bacillus thuringiensis functional in Escherichia coli

Summary The mobile genetic element Tn4430, originating from the gram-positive bacterium, Bacillus thuringiensis, and previously described as the Th-sequence, is the first transposon isolated from the genus Bacillus. In the present work a gene (APH-III) conferring resistance to kanamycin was inserted into this 4.2 kb transposon. Transposition experiments showed that Tn4430APH-III could transpose in the gram-negative host Escherichia coli when its insertion functions were supplied by an intact copy of Tn4430. By transposing Tn4430APH-III directly onto pBR322, it was possible to determine the nucleotide sequence of the terminal inverted repeats of Tn4430 and of the target DNA site. Identical 38 bp in inverted orientation are situated at each end of the transposon and there is a direct duplication of 5 bp at the insertion site. Thus, it is clear that Tn4430 is closely related to the transposons belonging to the Tn3 family (class II elements).     

Intermolecular and intramolecular transposition and transposition immunity in Tn3 and Tn2660

Summary Intermolecular transposition of Tn2660 into pCR1 was measured at 30°C in recA ^– and recA ⁺ hosts as between 2.6 and 5.5x10^–3, a similar value to that previously found for Tn3. No cointegrate structures were found under conditions where 10⁴ transposition events occurred. Immunity to intermolecular transposition of Tn2660, similar to that found for Tn3 was demonstrated by showing that the above transposition frequency was reduced by a factor of between 10^–3 and 10^–4 when a mutant Tn2660 (resulting in the synthesis of a temperaturesensitive -lactamase) was present in the recipient plasmid. Intramolecular transposition of Tn3 was found to occur under the same conditions as previously demonstrated for Tn2660 giving rise to similar end products, in which the newly introduced Tn3 is oriented inversely to the resident Tn3 and the DNA sequence between the two transposons has been inverted. Thus, in all respects functional identity of the transposition activities of Tn3 and Tn2660 is shown, thereby identifying characteristics of intramolecular transposition that are not readily accommodated by current models of transposition.     

Specificity of Transposon Tn5 Insertion

Genetic mapping studies had shown that the bacterial transposon Tn5 can insert into many sites in a gene, but that some sites are preferred. To begin understanding Tn5's insertion specificity at the molecular level, we selected transpositions of Tn5 from the Escherichia coli chromosome to the plasmid pBR322 and analyzed the resultant pBR322::Tn5 plasmids by restriction endonuclease digestion and DNA sequencing. Seventy-five insertions in the tet gene were found at 28 sites including one major hotspot (with 21 insertions) and four lesser hotspots (with four to ten insertions each). All five hotspots are within the first 300 of the 1250-base pair (bp) tet gene. In contrast, 31 independent insertions in the amp gene were found in at least 27 distinct sites.—Tn5 generates 9 bp target sequence duplications when it transposes. Such transposon-induced duplications are generally taken to indicate that cleavages of complementary target DNA strands are made 9 bp apart during transposition. DNA sequence analysis indicated that GC base pairs occupy positions 1 and 9 in the duplications at each of the five hotspots examined, suggesting a GC-cutting preference during Tn5 transposition.     

The transposable elements resident on the plasmids of Pseudomonas putida strain H, Tn5501 and Tn5502, are cryptic transposons of the Tn3 family

Genes for (methyl)phenol degradation in Pseudomonas putida strain H (phl genes) are located on the plasmid pPGH1. Adjacent to the phl catabolic operon we identified a cryptic transposon, Tn5501, of the Tn3 family (class II transposons). The genes encoding the resolvase and the transposase are transcribed in the same direction, as is common for the Tn501 subfamily. The enzymes encoded by Tn5501, however, show only the overall homology characteristic for resolvases/integrases and transposases of Tn3-type transposons. Therefore it is likely that Tn5501 is not a member of one of the previously defined subfamilies. Inactivation of the conditional lethal sacB gene was used to detect transposition of Tn5501. While screening for transposition events we found another transposon integrated into sacB in one of the sucrose-resistant survivors. This element, Tn5502, is a composite transposon consisting of Tn5501 and an additional DNA fragment. It is flanked by inverted repeats identical to those of Tn5501 and the additional fragment is separated from the Tn5501 portion by an internal repeat (identical to the left terminal repeat). Transposition of phenol degradation genes could not be detected. Analysis of sequence data revealed that the phl genes are not located on a Tn5501-like transposon.