Tn3 transposition immunity is conferred by the transposase-binding domain in the terminal inverted-repeat sequence of Tn3

A series of mutant terminal inverted repeats (IRs), having 2 bp substitutions at various sites within the 38-bp IR sequence of the ampicillin-resistance transposon Tn3, were tested for transposition immunity to Tn3. Mutations within region 1-10 in the IR did not affect transposition immunity, while mutations within region 13-38 inactivated the immunity function. These two regions corresponded to domain A which was not bound specifically by Tn3 transposase and to domain B which was bound by the transposase, respectively. This indicates that specific binding of transposase to domain B within the IR sequence is responsible for transposition immunity.     

Absence of direct repeats flanking transposons resulting from intramolecular transposition

Tn2660 is an ampicillin-resistance-conferring transposon with a high degree of homology for the transposon Tn3. The nucleotide sequences flanking the termini of Tn2660 have been determined on plasmids inferred to have resulted from both inter- and intramolecular transposition of Tn2660. In all cases, transposition of Tn2660, as of Tn3, creates 5-bp flanking direct repeats, except following intramolecular transposition resulting from trans ligation. In this case, in R6K replicons, the nucleotide sequence between the two Tn2660 elements is stably inverted from the normal orientation, and 5-bp direct repeats do not flank each transposon, but instead flank opposite ends of the two transposon copies.     

Genetic organization of transposon Tn10

Transposon Tn10 is 9300 bp in length, with 1400 bp inverted repeats at its ends. The inverted repeats are structurally intact IS-like sequences (Ross et al., 1979). Analysis of deletion mutants and structural variants of Tn10, reported below, shows that the two IS10 segments contain all of the Tn10-encoded genetic determinants, both sites and functions, that are required for transposition. Furthermore, the two repeats (IS10-Right and IS10-Left) are not functionally equivalent: IS10-Right is fully functional and is capable by itself of promoting normal levels of Tn10 transposition; IS10-Left functions only poorly by itself, promoting transposition at a very low level when IS10-Right is inactivated. Complementation analysis shows that IS10-Right encodes at least one function, required for Tn10 transposition, which can act in trans and which works at the ends of the element. Also, all of the sites specifically required for normal Tn10 transposition have been localized to the outermost 70 bp at each end of the element; there is no evidence that specific sites internal to the element play an essential role. Finally, Tn10 modulates its own transposition in such a way that transposition-defective point mutants, unlike deletion mutants, are not complemented by functions provided in trans; and wild-type Tn10, unlike deletion mutants, is not affected by functions provided in trans from a "high hopper" Tn10 element.     

Mutational analysis of the inverted repeats of Tn3

The transposase protein and the terminal inverted repeat sequences of the prokaryotic transposon Tn3 are essential for transposition. In order to determine the sequences within the inverted repeat necessary for transposition and interaction with transposase, we have constructed a series of mini-Tn3s in which specific mutations have been introduced into the inverted repeats. The effects of these mutations on transposition have been assayed in vivo using a mating-out transposition assay. Several single base-pair mutations within the transposase binding site reduce transposition frequency. Mutations that affect transposition show a greater effect when present in both inverted repeats than when present in only one inverted repeat.     

Structure-function analysis of the inverted terminal repeats of the sleeping beauty transposon

Translocation of Sleeping Beauty (SB) transposon requires specific binding of SB transposase to inverted terminal repeats (ITRs) of about 230 bp at each end of the transposon, which is followed by a cut-and-paste transfer of the transposon into a target DNA sequence. The ITRs contain two imperfect direct repeats (DRs) of about 32 bp. The outer DRs are at the extreme ends of the transposon whereas the inner DRs are located inside the transposon, 165-166 bp from the outer DRs. Here we investigated the roles of the DR elements in transposition. Although there is a core transposase-binding sequence common to all of the DRs, additional adjacent sequences are required for transposition and these sequences vary in the different DRs. As a result, SB transposase binds less tightly to the outer DRs than to the inner DRs. Two DRs are required in each ITR for transposition but they are not interchangeable for efficient transposition. Each DR appears to have a distinctive role in transposition. The spacing and sequence between the DR elements in an ITR affect transposition rates, suggesting a constrained geometry is involved in the interactions of SB transposase molecules in order to achieve precise mobilization. Transposons are flanked by TA dinucleotide base-pairs that are important for excision; elimination of the TA motif on one side of the transposon significantly reduces transposition while loss of TAs on both flanks of the transposon abolishes transposition. These findings have led to the construction of a more advanced transposon that should be useful in gene transfer and insertional mutagenesis in vertebrates.     

Factors that affect transposition mediated by the Tn21 transposase

The frequencies of one-ended transposition mediated by the Tn21 transposase acting on plasmids containing 38-bp inverted repeat sequences (IRs) of both Tn21 and of Tn501/Tn1721 and Tn2501 were measured. The enzyme acted on all these IRs, but more efficiently on the homologous sequences. These differences were magnified when the enzyme acted on plasmids containing two copies of the IRs, inverted with respect to each other. The Tn21 enzyme did not recognize the IR of Tn3. The Tn501 transposase did not mediate measurable one-ended transposition of any of the plasmids used, including those containing an IR of Tn501.     

Transposition and transposition immunity of transposon Tn3 derivatives having different ends.

Novel Tn1/3 derivatives that contained either two left- or two right-hand ends of the transposon were constructed in a small plasmid. Both transposed at reasonable frequencies to give normal transposition products, suggesting that only the 38-bp inverted repeats of Tn3 are essential for transposition. Plasmids containing transposon derivatives with only one end (either left or right) undergo transposase-dependent transposition between replicons at much lower frequencies, resulting in co-integrate molecules in which there is no substantial duplication of transposon DNA and that appear to be simple fusions of the two plasmids. Both the right and left halves of the transposon are separately able to confer transposition immunity to the plasmid, this immunity being inseparably linked to transposition proficiency and specificity.     

Transposon Tn951 (TnLac) is defective and related to Tn3

Summary Tn951 is flanked by two perfect inverted repeats of 41 bp which include the 38 bp sequence of the IR of Tn3. Tn951 also contains the last 100 bp of the tnpA gene but with at least two mutations. However, beyond nucleotide 137 the sequences diverge and hybridization experiments show that Tn951 lacks at least the first two thirds of the tnpA gene.In agreement with these observations Tn951 does not transpose by itself at a detectable frequency but can be complemented by the tnpA gene of Tn801 or Tn3. Tn501, Tn1721 and gamma delta do not complement Tn951 transposition.Transposition of Tn951 duplicates 5 bp of target DNA sequence.     

The wild-type conformation of the Mos-1 Inverted Terminal Repeats is suboptimal for transposition in bacteria

The two inverted terminal repeats (ITRs) flanking the Mos-1 mariner element differ in sequence at four positions. Gel retardation experiments indicated that each of these differences has a significant impact on the quality of the interaction between the ITR and the Mos-1 transposase. We showed that the transposase binds to the 3' ITR better than to the 5' ITR. The results of transposition assays performed in Escherichia coli indicated that these differences have an influence on the rate of transposition and the stability of the transposition products. Finally, we find that the wild-type configuration of the Mos-1 element, with one 5' ITR and one 3' ITR, is less efficient for transposition in bacteria than that of an element having two 3' ITRs.     

Plasmid-borne cadmium resistance genes in Listeria monocytogenes are present on Tn5422, a novel transposon closely related to Tn917.

The complete (6,449-bp) nucleotide sequence of the first-described natural transposon of Listeria monocytogenes, designated Tn5422, was determined. Tn5422 is a transposon of the Tn3 family delineated by imperfect inverted repeats (IRs) of 40 bp. It contains two genes which confer cadmium resistance (M. Lebrun, A. Audurier, and P. Cossart, J. Bacteriol. 176:3040-3048, 1994) and two open reading frames that encode a transposase (TnpA) and a resolvase (TnpR) of 971 and 184 amino acids, respectively. The cadmium resistance genes and the transposition genes are transcribed in opposite directions and are separated by a putative recombination site (res). The structural elements presumed to be involved in transposition of Tn5422 (IRs, transposase, resolvase, and res) are very similar to those of Tn917, suggesting a common origin. The transposition genes were not induced by cadmium. Analysis of sequences surrounding Tn5422 in nine different plasmids of L. monocytogenes indicated that Tn5422 is a functional transposon, capable of intramolecular replicative transposition, generating deletions. This transposition process is probably the reason for the size diversity of the L. monocytogenes plasmids. Restriction analysis and Southern hybridization revealed the presence of Tn5422 in all the plasmid-mediated cadmium-resistant L. monocytogenes strains tested but not in strains encoding cadmium resistance on the chromosome.     

Cointegrates carrying two copies of a Tn3 derivative in an inverted orientation

We constructed a mutant of Tn3, Tn3 #2, that contains a 55-bp direct repeat of sequences near the amino-terminal coding region of the transposase, and an 8-bp EcoRI linker. This mutant transposase is functional. The plasmid carrying Tn3 #2, pMB8::Tn3 #2, recombines with the plasmid pHS1 at a frequency of 2.8 X 10(-7) recombinants per division cycle. This is similar to the recombination frequency of pHS1 and pMB8::Tn3+ (wild-type) which is 4.5 X 10(-6) recombinants per division cycle. One-third of the recombinants between pMB8::Tn3 #2 and pHS1 were approx. 22 kb in length. Restriction analysis and nucleotide sequencing showed that these large plasmids were Tn3 #2-mediated cointegrates formed by integration of pMB8::Tn3 #2 into pHS1. However, unlike Tn3 tnpR- -mediated cointegrates that contain direct repeats of the incoming element, Tn3 #2-mediated cointegrates carry two copies of Tn3 #2 in the form of inverted repeats. Like the tnpR- repeats, the Tn3 #2 repeats occur at both junctions between the parental plasmids, and are associated with a 5-bp direct duplication of the pHS1 target site. Furthermore, these recombinants contain a small deletion starting precisely at the end of Tn3 #2 and extending into pMB8 sequences. We propose a model for the generation of Tn3 #2-mediated cointegrates.     

DNA sequence analysis of the transposon Tn3: three genes and three sites involved in transposition of Tn3.

The complete nucleotide sequence of the transposon Tn3 and of 20 mutations which affect its transposition are reported. The mutations, generated in vitro by random insertion of synthetic restriction sites, proved to contain small duplications or deletions immediately adjacent to the new restriction site. By determining the phenotype and DNA sequence of these mutations we were able to generate an overlapping phenotypic and nucleotide map. This 4957 bp transposon encodes three polypeptides which account for all but 350 bp of its total coding capacity. These proteins are the transposase, a high molecular weight polypeptide (1015 amino acids) encoded by the tnpA gene; the Tn3-specific repressor, a low molecular weight polypeptide (185 amino acids) encoded by the tnpR gene; and the 286 amino acid beta-lactamase. The 38 bp inverted repeats flanking Tn3 appear to be absolutely required in cis for Tn3 to transpose. Genetic data suggest that Tn3 contains a third site (Gill et al., 1978), designated IRS (internal resolution site), whose absence results in the insertion of two complete copies of Tn3 as direct repeats into the recipient DNA. We suggest that these direct repeats of complete copies of Tn3 are intermediates in transposition, and that the IRS site is required for recombination and subsequent segregation of the direct repeats to leave a single copy of Tn3 (Gill et al., 1978). A 23 nucleotide sequence within the amino terminus of the transposase which shares strong sequence homology with the inverted repeat may be the internal resolution site.     

The IS1111 family members IS4321 and IS5075 have subterminal inverted repeats and target the terminal inverted repeats of Tn21 family transposons

IS5075 and IS4321 are closely related (93.1% identical) members of the IS1111 family that target a specific position in the 38-bp terminal inverted repeats of Tn21 family transposons and that are inserted in only one orientation. They are 1,327 bp long and have identical ends consisting of short inverted repeats of 12 bp with an additional 7 bp (TAATGAG) or 6 bp (AATGAG) to the left of the left inverted repeats and 3 bp (AGA) or 4 bp (AGAT) to the right of the right inverted repeat. Circular forms of IS5075 and IS4321 in which the inverted repeats are separated by abutting terminal sequences (AGATAATGAG) were detected. A similar circular product was found for the related ISPa11. Transposition of IS4321 into the 38-bp target site was detected, but a flanking duplication was not generated. The precisely reconstituted target site was also identified. Over 50 members of the IS1111 family were identified. They encode related transposases, have related inverted repeats, and include related bases that lie outside these inverted repeats. In some, the flanking bases number 5 or 6 on the left and 4 or 3 on the right. Specific target sites were found for several of these insertion sequence (IS) elements. IS1111 family members therefore differ from the majority of IS elements, which are characterized by terminal inverted repeats and a target site duplication, and from members of the related IS110 family, which do not have obvious inverted repeats near their termini.     

Characterization of Tn1546, a Tn3-related transposon conferring glycopeptide resistance by synthesis of depsipeptide peptidoglycan precursors in Enterococcus faecium BM4147.

Sequence determination of the flanking regions of the vancomycin resistance van gene cluster carried by pIP816 in Enterococcus faecium BM4147 revealed similarity to transposons of the Tn3 family. Imperfect inverted repeats (36 of 38 bp) delineated a 10,851-bp element designated Tn1546. The 4-kb region located upstream from the vanR gene contained two open reading frames (ORF) transcribed in opposite directions. The deduced amino acid sequence of ORF1 (988 residues) displayed, respectively, 56 and 42% identity to those of the transposases of Tn4430 from Bacillus thuringiensis and of Tn917 from Enterococcus faecalis. The product of ORF2 (191 residues) was related to the resolvase of Tn917 (33% amino acid identity) and to the Res protein (48%) of plasmid pIP404 from Clostridium perfringens. Tn1546 transposed consecutively in Escherichia coli from plasmid pUC18 into pOX38 and from pOX38 into various sites of pBR329. Transposition was replicative, led to the formation of cointegrates, and produced a 5-bp duplication at the target site. Southern hybridization and DNA amplification revealed the presence of Tn1546-related elements in enterococci highly resistant to glycopeptides. Analysis of sequences surrounding these elements indicated that transposition plays a role in dissemination of the van gene cluster among replicons of human clinical isolates of E. faecium.     

Nucleotide sequences required for Tn3 transposition immunity.

The Tn3 transposon inserts at a reduced frequency into a plasmid already containing a copy of Tn3, a phenomenon known as transposition immunity. The cis-acting site on Tn3 responsible for immunity was mapped by deletions from each side to be within the terminal 38-base-pair sequence that is inversely repeated at the ends of Tn3. Two palindromic sequences are present in the essential part of this region. Some deletions conferred only partial immunity, and others conferred negative immunity. Multiple copies of partially immune ends conferred additional immunity. No other part of Tn3 was necessary for immunity.     

Structural and functional analysis of Tn4430: identification of an integrase-like protein involved in the co-integrate-resolution process

The 4149-bp transposon Tn4430 from Bacillus thuringiensis is delineated by 38-bp inverted repeats and codes for a 113-kd protein that shares homology with the transposases (TnpA) of Tn3, Tn21 and Tn501. Through transpositional recombination, this protein generates the formation of co-integrates between both donor and target replicons, with duplication of Tn4430 molecules. These features are characteristic of transposons of the Tn3 family (class II elements). The second step of the transposition process, the co-integrate resolution, is mediated by a 32-kd protein. This protein (TnpI) displays regional similarities with site-specific recombinases of the integrase family, such as Int of bacteriophage lambda, Cre of bacteriophage P1 or TnpA and TnpB of the Tn554 transposon. Moreover, the 250-bp sequence upstream to the tnpI gene contains several structural features that are reminiscent of the attP attachment site of phage lambda. This unique association between the integrase-like TnpI recombinase and the TnpA transposase qualifies Tn4430 as a member of a new group within the class II mobile genetic elements.     

Two domains in the terminal inverted-repeat sequence of transposon Tn3

Tn3 and related transposons have terminal inverted repeats (IR) of about 38 bp that are needed as sites for transposition. We made mini-Tn3 derivatives which had a wild-type IR of Tn3 at one end and either the divergent IR of the Tn3-related transposon, gamma delta or IS101, or a mutant IR of Tn3 at the other end. We then examined both in vivo transposition (cointegration between transposition donor and target molecules) of these mini-Tn3 elements and in vitro binding of Tn3-encoded transposase to their IRs. None of the elements with an IR of gamma delta or IS101 mediated cointegration efficiently. This was due to inefficient binding of transposase to these IR. Most mutant IR also interfered with cointegration, even though transposase bound to some mutant IR as efficiently as it did to wild type. This permitted the Tn3 IR sequence to be divided into two domains, named A and B, with respect to transposase binding. Domain B, at positions 13-38, was involved in transposase binding, whereas domain A, at positions 1-10, was not. The A domain may contain the sequence recognized by some other (e.g., host) factor(s) to precede the actual cointegration event.     

Transposon Tn5090 of plasmid R751, which carries an integron, is related to Tn7, Mu, and the retroelements.

Integrons confer on bacterial plasmids a capability of taking up antibiotic resistance genes by integrase-mediated recombination. We show here that integrons are situated on genetic elements flanked by 25-bp inverted repeats. The element carrying the integron of R751 has three segments conserved with similar elements in Tn21 and Tn5086. Several characteristics suggest that this element is a transposon, which we call Tn5090. Tn5090 was shown to contain an operon with three open reading frames, of which two, tniA and tniB, were predicted by amino acid similarity to code for transposition proteins. The product of tniA (559 amino acids) is a probable transposase with 25% amino acid sequence identity to TnsB from Tn7. Both of these polypeptides contain the D,D(35)E motif characteristic of a protein family made up of the retroviral and retrotransposon IN proteins and some bacterial transposases, such as those of Tn552 and of a range of insertion sequences. Like the transposase genes in Tn552, Mu, and Tn7, the tniA gene was followed by a gene, tniB, for a probable ATP-binding protein. The ends of Tn5090, like those of most other elements producing D,D(35)E proteins, begin by 5'-TG and also contains a complex structure with four 19-bp repeats at the left end and three at the right end. Similarly organized repeats have been observed earlier at the termini of both Tn7 and phage Mu, where they bind their respective transposases and have a role in holoenzyme assembly. Another open reading frame observed in Tn5090, tniC, codes for a recombinase of the invertase/resolvase family, suggesting a replicative transposition mechanism. The data presented here suggest that Tn5090, Tn7, Tn552, and Mu form a subfamily of bacterial transposons which in parallel to many insertion sequences are related to the retroelements.     

Binding of the Tn3 transposase to the inverted repeats of Tn3

The transposase protein and the inverted repeat sequences of Tn3 are both essential for Tn3 cointegrate formation and transposition. We have developed two assays to detect site-specific binding of transposase to the inverted repeats: (1) a nitrocellulose filter binding assay in which transposase preferentially retains DNA fragments containing inverted repeat sequences, and (2) a DNase 1 protection assay in which transposase prevents digestion of the inverted repeats by DNase 1. Both assays show that transposase binds directly to linear, duplex DNA containing the inverted repeats. The right inverted repeat of Tn3 binds slightly more strongly than the left one. Site-specific binding requires magnesium but does not require a high energy cofactor.