DNA sequence analysis of five genes; tnsA, B, C, D and E, required for Tn7 transposition

Insight into the molecular mechanism of the transposon-encoded type I-F CRISPR-Cas system

CRISPR-Cas9 is a popular gene-editing tool that allows researchers to introduce double-strand breaks to edit parts of the genome. CRISPR-Cas9 system is used more than other gene-editing tools because it is simple and easy to customize. However, Cas9 may produce unintended double-strand breaks in DNA, leading to off-target effects. There have been many improvements in the CRISPR-Cas system to control the off-target effect and improve the efficiency. The presence of a nuclease-deficient CRISPR-Cas system in several bacterial Tn7-like transposons inspires researchers to repurpose to direct the insertion of Tn7-like transposons instead of cleaving the target DNA, which will eventually limit the risk of off-target effects. Two transposon-encoded CRISPR-Cas systems have been experimentally confirmed. The first system, found in Tn7 like-transposon (Tn6677), is associated with the variant type I-F CRISPR-Cas system. The second one, found in Tn7 like-transposon (Tn5053), is related to the variant type V-K CRISPR-Cas system. This review describes the molecular and structural mechanisms of DNA targeting by the transposon-encoded type I-F CRISPR-Cas system, from assembly around the CRISPR-RNA (crRNA) to the initiation of transposition.

The treatment of wastewater containing pharmaceuticals in microcosm constructed wetlands: the occurrence of integrons (int1-2) and associated resistance genes (sul1-3, qacEΔ1)

The aim of this study was to analyze the occurrence of sulfonamide resistance genes (sul1-3) and other genetic elements as antiseptic resistance gene (qacEΔ1) and class 1 and class 2 integrons (int1-2) in the upper layer of substrate and in the effluent of microcosm constructed wetlands (CWs) treating artificial wastewater containing diclofenac and sulfamethoxazole (SMX), which is a sulfonamide antibiotic. The bacteria in the substrate and in the effluents were equipped with the sul1-2, int1, and qacEΔ1 resistance determinants, which were introduced into the CW system during inoculation with activated sludge and with the soil attached to the rhizosphere of potted seedlings of Phalaris arundinacea 'Picta' roots (int1). By comparing the occurrence of the resistance determinants in the upper substrate layer and the effluent, it can be stated that they neither were lost nor emerged along the flow path. The implications of the presence of antibiotic resistance genes in the effluent may entail a risk of antibiotic resistance being spread in the receiving environment. Additionally, transformation products of SMX were determined. According to the obtained results, four (potential) SMX transformation products were identified. Two major metabolites of SMX, 2,3,5-trihydroxy-SMX and 3,5-dihydroxy-SMX, indicated that SMX may be partly oxidized during the treatment. The remaining two SMX transformation products (hydroxy-glutathionyl-SMX and glutathionyl-SMX) are conjugates with glutathione, which suggests the ability of CW bacterial community to degrade SMX and resist antimicrobial stress.

Conformational toggling controls target site choice for the heteromeric transposase element Tn7

The bacterial transposon Tn7 facilitates horizontal transfer by directing transposition into actively replicating DNA with the element-encoded protein TnsE. Structural analysis of the C-terminal domain of wild-type TnsE identified a novel protein fold including a central V-shaped loop that toggles between two distinct conformations. The structure of a robust TnsE gain-of-activity variant has this loop locked in a single conformation, suggesting that conformational flexibility regulates TnsE activity. Structure-based analysis of a series of TnsE mutants relates transposition activity to DNA binding stability. Wild-type TnsE appears to naturally form an unstable complex with a target DNA, whereas mutant combinations required for large changes in transposition frequency and targeting stabilized this interaction. Collectively, our work unveils a unique structural proofreading mechanism where toggling between two conformations regulates target commitment by limiting the stability of target DNA engagement until an appropriate insertion site is identified.

Tn7

The bacterial transposon Tn7 is distinguished by the levels of control it displays over transposition and its capacity to utilize different kinds of target sites. Transposition is carried out using five transposon-encoded proteins, TnsA, TnsB, TnsC, TnsD, and TnsE, which facilitate transfer of the element while minimizing the chances of inactivating host genes by using two pathways of transposition. One of these pathways utilizes TnsD, which targets transposition into a single site found in bacteria ( attTn7 ), and a second utilizes TnsE, which preferentially directs transposition into plasmids capable of moving between bacteria. Control of transposition involves a heteromeric transposase that consists of two proteins, TnsA and TnsB, and a regulator protein TnsC. Tn7 also has the ability to inhibit transposition into a region already occupied by the element in a process called target immunity. Considerable information is available about the functional interactions of the Tn7 proteins and many of the protein–DNA complexes involved in transposition. Tn7-like elements that encode homologs of all five of the proteins found in Tn7 are common in diverse bacteria, but a newly appreciated larger family of elements appears to use the same core TnsA, TnsB, and TnsC proteins with other putative target site selector proteins allowing different targeting pathways.

Achromobacter xylosoxidans: an emerging pathogen carrying different elements involved in horizontal genetic transfer

In the last few years, numerous cases of multidrug-resistant Achromobacter xylosoxidans infections have been documented in immunocompromised and cystic fibrosis patients. To gain insights into the molecular mechanisms and mobile elements related to multidrug resistance in this bacterium, we studied 24 non-epidemiological A. xylosoxidans clinical isolates from Argentina. Specific primers for plasmids, transposons, insertion sequences, bla_ampC, intI1, and intI2 genes were used in PCR reactions. The obtained results showed the presence of wide host range IncP plasmids in ten isolates and a high dispersion of class 1 integrons (n = 10) and class 2 integrons (n = 3). Four arrays in the variable region (vr) of class 1 integrons were identified carrying different gene cassettes as the aminoglycoside resistance aac(6′)-Ib and aadA1, the trimethoprim resistance dfrA1 and dfrA16, and the β-lactamase bla_OXA-2. In only one of the class 2 integrons, a vr was amplified that includes sat2-aadA1. The bla_ampC gene was found in all isolates, confirming its ubiquitous nature. Our results show that A. xylosoxidans clinical isolates contain a rich variety of genetic elements commonly associated with resistance genes and their dissemination. This supports the hypothesis that A. xylosoxidans is becoming a reservoir of horizontal genetic transfer elements commonly involved in spreading antibiotic resistance.

Novel insights about class 2 integrons from experimental and genomic epidemiology

In order to contribute to the knowledge of the architecture and epidemiology of class 2 integrons, we performed a class 2 integron molecular survey in which we analyzed 726 isolates in two bacterial populations from environmental and nonepidemiologically related clinical samples, respectively, collected from 1982 to 2007. We recovered the intI2 gene from 130 of 726 isolates, most of which were clinical isolates, and only 1 (a psychrophilic Pseudomonas sp.) was from a water sample. Unlike the widespread distribution of class 1 integrons within Gram-negative bacilli, only Acinetobacter baumannii and Enterobacter cloacae harbored class 2 integrons at a high frequency in our collection. Class 2 integrons with six novel cassette arrays were documented. Characterization of the transposition module of Tn7, the genetic platform in which class 2 integrons have always been reported, showed tns modules with a mosaic genetic structure. A bioinformatic analysis performed with the tns genes present in sequence databases, the finding of intI2 not associated with tns genes, and the genetic examination of novel tns-like genes found in three isolates indicated the possibility of the independent evolution of the two components related to horizontal gene transfer, the class 2 integrons and the Tn7 transposons.

DNA damage differentially activates regional chromosomal loci for Tn7 transposition in Escherichia coli

The bacterial transposon Tn7 recognizes replicating DNA as a target with a preference for the region where DNA replication terminates in the Escherichia coli chromosome. It was previously shown that DNA double-strand breaks in the chromosome stimulate Tn7 transposition where transposition events occur broadly around the point of the DNA break. We show that individual DNA breaks actually activate a series of small regional hotspots in the chromosome for Tn7 insertion. These hotspots are fixed and become active only when a DNA break occurs in the same region of the chromosome. We find that the distribution of insertions around the break is not explained by the exonuclease activity of RecBCD moving the position of the DNA break, and stimulation of Tn7 transposition is not dependent on RecBCD. We show that other forms of DNA damage, like exposure to UV light, mitomycin C, or phleomycin, also stimulate Tn7 transposition. However, inducing the SOS response does not stimulate transposition. Tn7 transposition is not dependent on any known specific pathway of replication fork reactivation as a means of recognizing DNA break repair. Our results are consistent with the idea that Tn7 recognizes DNA replication involved in DNA repair and reveals discrete regions of the chromosome that are differentially activated as transposition targets.

Transposon Tn7 is widespread in diverse bacteria and forms genomic islands

We find that relatives of the bacterial transposon Tn7 are widespread in disparate environments and phylogenetically diverse species. These elements form functionally diverse genomic islands at the specific site of Tn7 insertion adjacent to glmS. This work presents the first example of genomic island formation by a DDE type transposon.

Novel rearrangement of a class 2 integron in two non-epidemiologically related isolates of Acinetobacter baumannii

Tn7::In2-8 contains sat2-aadB-catB2(deltaattC)-dfrA1-sat2-aadA1-orfX in the variable region of a class 2 integron embedded in the Tn7-like transposon. This novel transposon was inserted in its preferred site downstream of the glms gene in Acinetobacter baumannii. Acquisition of the pseudocassette catB2 could have arisen by a secondary-site integrase-mediated intermolecular recombination event.

IntI2 integron integrase in Tn7

Integrons can insert and excise antibiotic resistance genes on plasmids in bacteria by site-specific recombination. Class 1 integrons code for an integrase, IntI1 (337 amino acids in length), and are generally borne on elements derived from Tn5090, such as that found in the central part of Tn21. A second class of integron is found on transposon Tn7 and its relatives. We have completed the sequence of the Tn7 integrase gene, intI2, which contains an internal stop codon. This codon was found to be conserved among intI2 genes on three other Tn7-like transposons harboring different cassettes. The predicted peptide sequence (IntI2*) is 325 amino acids long and is 46% identical to IntI1. In order to detect recombination activity, the internal stop codon at position 179 in the parental allele was changed to a triplet coding for glutamic acid. The sequences flanking the cassette arrays in the class 1 and 2 integrons are not closely related, but a common pool of mobile cassettes is used by the different integron classes; two of the three antibiotic resistance cassettes on Tn7 and its close relatives are also found in various class 1 integrons. We also observed a fourth excisable cassette downstream of those described previously in Tn7. The fourth cassette encodes a 165-amino-acid protein of unknown function with 6.5 contiguous repeats of a sequence coding for 7 amino acids. IntI2*179E promoted site-specific excision of each of the cassettes in Tn7 at different frequencies. The integrases from Tn21 and Tn7 showed limited cross-specificity in that IntI1 could excise all cassettes from both Tn21 and Tn7. However, we did not observe a corresponding excision of the aadA1 cassette from Tn21 by IntI2*179E.

Tn7 recognizes transposition target structures associated with DNA replication using the DNA-binding protein TnsE

We report that the bacterial transposon Tn7 selects targets by recognizing features associated with DNA replication using the transposon-encoded DNA-binding protein TnsE. We show that Tn7 transposition directed by TnsE occurs in one orientation with respect to chromosomal DNA replication, indicating that a structure or complex involved in DNA replication is likely to be a critical determinant of TnsE insertion. We find that mutant TnsE proteins that allow higher levels of transposition also bind DNA better than the wild-type protein. The increased binding affinity displayed by the TnsE high-activity mutants indicates that DNA binding is relevant to transposition activity and suggests that TnsE interacts directly with target DNAs. In vitro, TnsE interacts preferentially with certain DNA structures, indicating a mechanism for the TnsE-mediated orientation and insertion preference. The pattern of TnsE-mediated insertion events around the Escherichia coli chromosome provides insight into how DNA replication forks proceed in vivo.

Tn7 transposes proximal to DNA double-strand breaks and into regions where chromosomal DNA replication terminates

We report that the bacterial transposon Tn7 can preferentially transpose into regions where chromosomal DNA replication terminates. DNA double-strand breaks are associated with the termination of chromosomal replication; therefore, we directly tested the effect of DNA breaks on Tn7 transposition. When DNA double-strand breaks are induced at specific sites in the chromosome, Tn7 transposition is stimulated and insertions are directed proximal to the induced break. The targeting preference for the terminus of replication and DNA double-strand breaks is dependent on the Tn7-encoded protein TnsE. The results presented in this study could also explain the previous observation that Tn7 is attracted to events associated with conjugal DNA replication during plasmid DNA transfer.

Class 1 integron-borne multiple-antibiotic resistance carried by IncFI and IncL/M plasmids in Salmonella enterica serotype typhimurium

The presence and genetic content of integrons were investigated for 37 epidemiologically unrelated multiple-drug-resistant strains of Salmonella enterica serotype Typhimurium from humans. All isolates were resistant to ampicillin, chloramphenicol, kanamycin, streptomycin, sulfonamides, and trimethoprim, as well as to tetracycline and/or nalidixic acid; 20% of them were also resistant to gentamicin and amikacin. Three different class 1 integrons (In-t1, In-t2, and In-t3) were identified by Southern blot hybridization, PCR, and DNA sequencing, and these integrons were found to carry the aadB, catB3, oxa1, aadA1a, aacA4, and aacC1 gene cassettes. Integrons In-t1 (aadB and catB3) and In-t2 (oxa1 and aadA1a) were both located on a conjugative IncFI plasmid of 140 kb. In-t3 (aacA4, aacC1, and aadAIa) was located on an IncL/M plasmid of 100 kb which was present, in association with the IncFI plasmid, in gentamicin- and amikacin-resistant isolates. Despite the extensive similarity at the level of the antibiotic resistance phenotype, integrons were not found on the prototypic IncFI plasmids carried by epidemic Salmonella strains isolated during the late 1970s. The recent appearance and the coexistence of multiple integrons on two conjugative plasmids in the same Salmonella isolate are examples of how mobile gene cassettes may contribute to the acquisition and dissemination of antibiotic resistance.

Cyanobacterial transposons Tn5469 and Tn5541 represent a novel noncomposite transposon family

A noncomposite transposon, designated Tn5541, was isolated from strain Fd33 of the filamentous cyanobacterium Fremyella diplosiphon UTEX 481. Sequence analysis showed that Tn5541 is structurally and genetically very similar to Tn5469, which is also endogenous to F. diplosiphon. Both Tn5469 and Tn5541 encode homologous forms of an unusual composite transposase and a protein of unknown function. DNA hybridization analysis showed that like Tn5469, Tn5541 was not widely distributed among cyanobacterial genera. A similar analysis showed that Tn5469 and Tn5541 were equally limited to and present as multiple genomic copies in three of six distinct strains comprising the Tolypothrix 1 cluster of heterocyst-forming filamentous cyanobacteria. These and other distinguishing features suggest that Tn5469 and Tn5541 represent a novel noncomposite transposon family.

Negative regulation of IS2 transposition by the cyclic AMP (cAMP)-cAMP receptor protein complex

Three sequences similar to that of the consensus binding sequence of the cyclic AMP (cAMP)-cAMP receptor protein (CRP) complex were found in the major IS2 promoter region. Experiments were performed to determine whether the cAMP-CRP complex plays a role in the regulation of IS2 transposition. In the gel retardation assay, the cAMP-CRP complex was found to be able to bind the major IS2 promoter. A DNA footprinting assay confirmed that the cAMP-CRP complex binds to the sequences mentioned above. With an IS2 promoter-luciferase gene fusion construct, the cAMP-CRP complex was shown to inhibit transcription from the major IS2 promoter. IS2 was found to transpose at a frequency approximately 200-fold higher in an Escherichia coli host defective for CRP or adenyl cyclase than in a wild-type host. These results suggest that the cAMP-CRP complex is a negative regulator of IS2 transposition.

Avoiding self: two Tn7-encoded proteins mediate target immunity in Tn7 transposition

The bacterial transposon Tn7 exhibits target immunity, a process that prevents Tn7 from transposing into target DNAs that already contain a copy of the transposon. This work investigates the mechanism of target immunity in vitro. We demonstrate that two Tn7-encoded proteins_TnsB, which binds specifically to the ends of Tn7, and TnsC, the ATP-dependent DNA binding protein_act as a molecular switch to impose immunity on target DNAs containing Tn7 (or just Tn7 ends). TnsC binds to target DNA molecules and communicates with the Tn7 transposition machinery; here we show that target DNAs containing Tn7 ends are also bound and subsequently inactivated by TnsB. Protein-protein interactions between TnsB and TnsC appear to be responsible for this inactivation; the target DNA promotes these interactions by tethering TnsB and TnsC in high local concentration. An attractive model that emerges from this work is that TnsB triggers the dissociation of TnsC from the Tn7 end-containing target DNA; that dissociation depends on TnsC's ability to hydrolyze ATP. We propose that these interactions between TnsB and TnsC not only prevent Tn7 from inserting into itself, but also facilitate the selection of preferred target sites that is the hallmark of Tn7 transposition.

Gain-of-function mutations in TnsC, an ATP-dependent transposition protein that activates the bacterial transposon Tn7

The bacterial transposon Tn7 encodes five genes whose protein products are used in different combinations to direct transposition to different types of target sites. TnsABC + D directs transposition to a specific site in the Escherichia coli chromosome called attTn7, whereas TnsABC + E directs transposition to non-attTn7 sites. These transposition reactions can also recognize and avoid "immune" targets that already contain a copy of Tn7. TnsD and TnsE are required to activate TnsABC as well as to select a target site; no transposition occurs with wild-type TnsABC alone. Here, we describe the isolation of TnsC gain-of-function mutants that activate the TnsA+B transposase in the absence of TnsD or TnsE. Some of these TnsC mutants enable the TnsABC machinery to execute transposition without sacrificing its ability to discriminate between different types of targets. Other TnsC mutants appear to constitutively activate the TnsABC machinery so that it bypasses target signals. We also present experiments that suggest that target selection occurs early in the Tn7 transposition pathway in vivo: favorable attTn7 targets appear to promote the excision of Tn7 from the chromosome, whereas immune targets do not allow transposon excision to occur. This work supports the view that TnsC plays a central role in the evaluation and utilization of target DNAs.

The Tn7 transposase is a heteromeric complex in which DNA breakage and joining activities are distributed between different gene products

The bacterial transposon Tn7 translocates by a cut and paste mechanism: excision from the donor site results from double-strand breaks at each end of Tn7 and target insertion results from joining of the exposed 3' Tn7 tips to the target DNA. Through site-directed mutagenesis of the Tn7-encoded transposition proteins TnsA and TnsB, we demonstrate that the Tn7 transposase is a heteromeric complex of these proteins, each protein executing different DNA processing reactions. TnsA mediates DNA cleavage reactions at the 5' ends of Tn7, and TnsB mediates DNA breakage and joining reactions at the 3' ends of Tn7. Thus the double-strand breaks that underlie Tn7 excision result from a collaboration between two active sites, one in TnsA and one in TnsB; the same (or a closely related) active site in TnsB also mediates the subsequent joining of the 3' ends to the target. Both TnsA and TnsB appear to be members of the retroviral integrase superfamily: mutation of their putative DD(35)E motifs blocks catalytic activity. Recombinases of this class require a divalent metal cofactor that is thought to interact with these acidic residues. Through analysis of the metal ion specificity of a TnsA mutant containing a sulfur (cysteine) substitution, we provide evidence that a divalent metal actually interacts with these acidic amino acids.

Characterization of transposon Tn5469 from the cyanobacterium Fremyella diplosiphon

A transposon, designated Tn5469, was isolated from mutant strain FdR1 of the filamentous cyanobacterium Fremyella diplosiphon following its insertion into the rcaC gene. Tn5469 is a 4,904-bp noncomposite transposon with 25-bp near-perfect terminal inverted repeats and has three tandemly arranged, slightly overlapping potential open reading frames (ORFs) encoding proteins of 104.6 kDa (909 residues), 42.5 kDa (375 residues), and 31.9 kDa (272 residues). Insertion of Tn5469 into the rcaC gene in strain FdR1 generated a duplicate 5-bp target sequence. On the basis of amino acid sequence identifies, the largest ORF, designated tnpA, is predicted to encode a composite transposase protein. A 230-residue domain near the amino terminus of the TnpA protein has 15.4% amino acid sequence identity with a corresponding domain for the putative transposase encoded by Lactococcus lactis insertion sequence S1 (ISS1). In addition, the sequence for the carboxyl-terminal 600 residues of the TnpA protein is 20.0% identical to that for the TniA transposase encoded by Tn5090 on Klebsiella aerogenes plasmid R751. The TnpA and TniA proteins contain the D,D(35)E motif characteristic of a recently defined superfamily consisting of bacterial transposases and integrase proteins of eukaryotic retroelements and retrotransposons. The two remaining ORFs on Tn5469 encode proteins of unknown function. Southern blot analysis showed that wild-type F. diplosiphon harbors five genomic copies of Tn5469. In comparison, mutant strain FdR1 harbors an extra genomic copy of Tn5469 which was localized to the inactivated rcaC gene. Among five morphologically distinct cyanobacterial strains examined, none was found to contain genomic sequences homologous to Tn5469.

Genetic analysis of the terminal 8-bp inverted repeats of transposon Tn7

Mutations in the terminal 8-bp (5'-T1G2T3G4G5G6C7G8-3') of the inverted repeats of the bacterial transposon, Tn7, were analysed by measuring Tn7 transposition to the attachment site, attTn7. The mutation, C2, present at either end of Tn7 reduces transposition only threefold, but in the double mutant, with C2 at both ends of Tn7, no transposition is detected. C6 mutations have no effect on transposition frequency. Replacement with 5'-A3C4G5C6G7C8-3' at the right end of Tn7 apparently abolishes transposition; yet in the double mutant, where the inverted repeats are restored by substituting this sequence at both ends of Tn7, transposition is partially rescued. This suggests that the mechanism of Tn7 transposition requires communication between the two ends. Tn7 transposition has always been seen to generate a 5-bp target duplication. This is presumed to result from a staggered cut, plus repair synthesis during transposition. We found that two of our right-end mutants, C2 and C6, sometimes yielded a 6-bp target duplication. This observation implies that cleavage of the target site might also involve interaction with the donor ends which, when mutant, relax the specificity for target-site cleavage.

Recombinant and wild-type Pseudomonas aureofaciens strains introduced into soil microcosms: effect on decomposition of cellulose and straw

The effect of a genetically engineered Pseudomonas aureofaciens (Ps3732RNL11) strain (GEM) and the parental wild-type (Ps3732RN) on decomposition of cellulose paper, straw and calico cloth was assessed after 18 weeks incubation in laboratory soil microcosms. Effect(s) of inoculum density (10(3), 10(5), and 10(8) cells/g dry soil) and single versus multiple bacterial inoculations were also investigated. Cellulose paper was completely decomposed after 18 weeks in all treatments. There were no significant differences (95% level), between treatments, in percentage decomposition of either straw or calico cloth. Recovery of the GEM at 18 weeks, using viable plating, was limited to treatments originally receiving 10(8) cells/g dry soil. Log 1.8 CFU/g dry soil were recovered from the single dose treatment while log 4.2 CFU/g dry soil were recovered from the multiple dose treatment. Biolog metabolic tests were used to determine if the GEM or parental wild-type had any effect on overall carbon utilization in soil. Results suggested they did not. Detection of the recombinant lacZY gene sequence in soil using PCR suggested the possibility of viable but nonculturable cells and/or persistence of chromosomal DNA.

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.

The IS4 family of insertion sequences: evidence for a conserved transposase motif

The eight IS231 variants characterized so far (IS231 A-F, V and W) display similar transposases with an overall 40% identity. Comparison with all the prokaryotic transposable elements sequenced so far revealed that the IS231 transposases share two conserved regions with those of 35 other insertion sequences of wide origins. These insertion sequences, defining the IS4 family, have a common bipartite organization of their ends and are divided into two similarity groups. Interestingly, the transposase domains conserved within this family display similarities with the well known integrase domain shared by transposases of the IS3 and IS15 families, and integrases of retroelements. This domain is also found in IS30-related elements and Tn7 TnsB protein. Amino acid residues conserved throughout all these prokaryotic and eukaryotic mobile genetic elements define a major transposase/integrase motif, likely to play an important role in the transposition process.

Overproduction of four functionally active proteins, TnsA, B, C, and D, required for Tn7 transposition to its attachment site, attTn7

The bacterial transposon Tn7 encodes five trans-acting transposition genes, tnsA, B, C, D, and E. Tn7 requires four of these genes, tnsA, B, C, and D, for a novel transposition pathway: high-efficiency site-specific transposition to a chromosomal attachment site, attTn7. Plasmids that individually allow inducible overexpression of proteins from the first initiation codon of four of these genes were constructed. Escherichia coli strains carrying these plasmids were used to overexpress the TnsA, B, C, and D proteins. The abundance and the apparent relative molecular mass of these proteins were examined and the latter was compared to those predicted from wild-type Tn7. The functionality of these proteins, encoded by an overexpression construct, was demonstrated by the fact that they could efficiently trans-complement a defective mini-Tn7 carrying only the cis-essential Tn7 termini in an in vivo assay for transposition to attTn7.

Purification and characterization of TnsC, a Tn7 transposition protein that binds ATP and DNA

The bacterial transposon Tn7 encodes five transposition genes tnsABCDE. We report a simple and rapid procedure for the purification of TnsC protein. We show that purified TnsC is active in and required for Tn7 transposition in a cell-free recombination system. This finding demonstrates that TnsC participates directly in Tn7 transposition and explains the requirement for tnsC function in Tn7 transposition. We have found that TnsC binds adenine nucleotides and is thus a likely site of action of the essential ATP cofactor in Tn7 transposition. We also report that TnsC binds non-specifically to DNA in the presence of ATP or the generally non-hydrolyzable analogues AMP-PNP and ATP-gamma-S, and that TnsC displays little affinity for DNA in the presence of ADP. We speculate that TnsC plays a central role in the selection of target DNA during Tn7 transposition.

Characterization of In0 of Pseudomonas aeruginosa plasmid pVS1, an ancestor of integrons of multiresistance plasmids and transposons of gram-negative bacteria

Many multiresistance plasmids and transposons of gram-negative bacteria carry related DNA elements that appear to have evolved from a common ancestor by site-specific integration of discrete cassettes containing antibiotic resistance genes or sequences of unknown function. The site of integration is flanked by conserved segments coding for an integraselike protein and for sulfonamide resistance, respectively. These segments, together with the antibiotic resistance genes between them, have been termed integrons (H. W. Stokes and R. M. Hall, Mol. Microbiol. 3:1669-1683, 1989). We report here the characterization of an integron, In0, from Pseudomonas aeruginosa plasmid pVS1, which has an unoccupied integration site and hence may be an ancestor of more complex integrons. Codon usage of the integrase (int) and sulfonamide resistance (sul1) genes carried by this integron suggests a common origin. This contrasts with the codon usage of other antibiotic resistance genes that were presumably integrated later as cassettes during the evolution and spread of these DNA elements. We propose evolutionary schemes for (i) the genesis of the integrons by the site-specific integration of antibiotic resistance genes and (ii) the evolution of the integrons of multiresistance plasmids and transposons, in relation to the evolution of transposons related to Tn21.

Tn7: a target site-specific transposon

The bacterial transposon Tn7 is an unusual mobile DNA segment. Most transposable elements move at low-frequency and display little target site-selectivity. By contrast, Tn7 inserts at high-frequency into a single specific site in the chromosomes of many bacteria. In the absence of this specific site, called attTn7 in Escherichia coli where Tn7 has been most extensively studied, Tn7 transposes at low-frequency and inserts into many different sites. Much has recently been learned about Tn7 transposition from both genetic and biochemical studies. The Tn7 recombination machinery is elaborate and includes a large number of Tn7-encoded proteins, probably host-encoded proteins and also rather large cis-acting transposition sequences at the transposon termini and at the target site. Dissection of the Tn7 transposition mechanism has revealed that the DNA strand breakage and joining reactions that underlie the translocation of Tn7 have several unusual features.

The merR regulatory gene in Thiobacillus ferrooxidans is spaced apart from the mer structural genes

Two distinct merR genes, which regulate expression of the mercuric ion resistance gene (mer), of Thiobacillus ferrooxidans strain E-15 have been cloned, sequenced and termed merR1 and merR2. As a result of gene walking around two merR genes, it was found that these two genes were quite close in distance. The nucleotide sequence of the region (5,001 base pairs; PstI-EcoRI fragment) containing the merR genes was determined. Between the two merR genes, there were five potential open reading frames (ORFs). Two of these were identified as merC genes, and the other three as ORFs 1 to 3. ORFs 1 to 3 show significant homology to merA, tnsA from transposon Tn7, and merA, respectively. Both merR genes consist of a 408 bp ORF coding for 135 amino acids. Their gene products, MerR1 and MerR2, differed at three amino acid positions, and shared 56-57% and 32-38% identity with the MerRs from other Gram-negative and Gram-positive bacteria, respectively. Competitive primer extension analysis revealed that both regulatory genes were expressed in the host cells. These merR genes were located more than 6 kb from either end of the mer structural genes (merC-merA). This is the first example of merR being separated from the mer structural genes. The two merC genes, each of which coded for a 140-amino-acid protein, appeared to be functionally active because Escherichia coli cells carrying these merC genes on plasmid vectors showed hypersensitivity to HgCl2. However, ORFs 1 and 3, which were homologous to merA, seemed to be inactive both structurally and enzymatically. The gene arrangement in this region took on a mirror image, with the truncated tnsA as the symmetrical centre. It is suggested that the Tn7-like factor may have participated in gene duplication events of the mer region, and in its chromosomal integration.

Interaction of the Tn7-encoded transposition protein TnsB with the ends of the transposon

We have used several high resolution methods to examine the interaction of TnsB, a transposition protein encoded by the bacterial transposon Tn7, with its binding sites at the ends of the transposon. These binding sites lie within the DNA segments that are directly involved in transposition. We show that the binding of TnsB to DNA can promote DNA bending, suggesting that the interaction of TnsB with the ends may result in formation of a highly organized protein-DNA complex. We also identify likely positions of close contact between of TnsB and its binding sites. Analysis of the interaction of TnsB with intact Tn7 ends reveals TnsB occupies its binding sites in a particular order, the sites immediately adjacent to the transposon termini being occupied only after other inner sites are bound. Such ordered occupancy suggests that the various binding sites have differing apparent affinities for TnsB.

Analysis of genetic localization of the type I trimethoprim resistance gene from Escherichia coli isolated in Finland

Among a collection of clinical Escherichia coli isolates, the type I dihydrofolate reductase (DHFR) mediating trimethoprim resistance was generally observed to be chromosomally determined. Only a minority of isolates carried the type I DHFR gene simultaneously on a plasmid. The majority of E. coli isolates studied also hybridized with a probe specific for the transposition gene tnsC of transposon Tn7; and in most of these isolates, Tn7 was found to be inserted into a preferred site in the E. coli chromosome. A minority of isolates that harbored the type I DHFR gene in the chromosome lacked a complete Tn7. Some of these harbored the type I DHFR gene inserted in a structure similar to that containing the gene for streptomycin resistance in Tn21. In the other isolates that were negative for a complete Tn7, the sequences upstream of the type I DHFR gene were demonstrated to be homologous to those flanking the type I DHFR gene in Tn7. This could indicate that the antibiotic resistance region of Tn7 may occur independently of this transposon. In two isolates, no sequences resembling Tn7 or Tn21 were found adjacent to the type I DHFR gene.

Identification of transposition proteins encoded by the bacterial transposon Tn7

The bacterial transposon, Tn7, encodes an elaborate array of transposition genes, tnsABCDE. We report here the direct identification of the TnsA, TnsB, TnsC and TnsD polypeptides by immunoblotting. Our results demonstrate that the complexity of the protein information devoted to Tn7 transposition is considerable: the aggregate molecular size of the five Tns polypeptides is about 300 kDa. We also report the sequence of the tnsA gene and of the 5' ends of tnsB and tnsD. This analysis reveals that all five tns genes are oriented in the same direction within Tn7.

Purification and characterisation of the TnsB protein of Tn7: a transposition protein that binds to the ends of Tn7

Tn7, a large bacterial transposon encodes 5 proteins required for its transposition. We report a rapid and easy purification of one of these proteins, TnsB, from an overexpression strain. This protein was shown to bind to the ends of Tn7, in a bandshift assay, in two distinct stages as a function of protein concentration. DNasel footprinting at each end of Tn7 showed that the TnsB recognition sequence, a set of 22 bp repeats, plus Tn7 termini are protected. Binding of TnsB appeared cooperative but was only observed above a threshold concentration of protein. ATP and Mg2+ had no effect on the pattern of protection, nor did addition of other Tn7-encoded proteins. Hydroxyl radical footprinting, performed at the right end, showed that TnsB binds preferentially to one side of the DNA helix.