Structure and function of Tn5467, a Tn21-like transposon located on the Thiobacillus ferrooxidans broad-host-range plasmid pTF-FC2.

A 3.5-kb region of plasmid pTF-FC2, which contains a transposon-like element designated Tn5467, has been sequenced, and its biological activity has been investigated. The transposon is bordered by two 38-bp inverted repeat sequences which have sequence identity in 37 of 38 and in 38 of 39 bp to the tnpA distal and tnpA proximal inverted repeats of Tn21, respectively. Within these borders, open reading frames with amino acid similarity to a glutaredoxin-like protein, a MerR regulatory protein, and a multidrug-resistant-membrane transport-like protein were found. The gene for the glutaredoxin-like protein was expressed in Escherichia coli and enabled growth of a glutathione-requiring E. coli trxA gshA mutant on minimal medium and the reduction of methionine sulfoxide to methionine. In addition, there were two regions which, when translated, had homology to 85% of the N-terminal region of the Tn21 resolvase (tnpR) and to 15% of the C terminus of the Tn21 transposase (tnpA). A region containing res-like sites was located immediately upstream of the partial tnpR gene. Neither the partial transposase nor the resolvase genes of Tn5467 were biologically active, but Tn5467 was transposed and resolved when the Tn21 transposase and resolvase were provided in trans. Tn5467 appears to be a defective transposon which belongs to the Tn21 subgroup of the Tn3 family.     

Tn5037-a Tn21-like mercury transposon, detected in Thiobacillus ferrooxidans

The 6645-bp mercury resistance transposon of the chemolithotrophic bacterium Thiobacillus ferrooxidans was cloned and sequenced. This transposon, named Tn5037, belongs to the Tn21 branch of the Tn21 subgroup, many members of which have been isolated from clinical sources. Having the minimum set of the genes (merRTPA), the mercury resistance operon of Tn5037 is organized similarly to most of the Gram-negative bacteria mer operons and is closest to that of Thiobacillus 3.2. The operator-promoter region of the mer operon of Tn5037 also 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. ferrooxidance E-15, and Thiobacillus 3.2, respectively. No inducibility of the Tn5037 mer operon was detected in the in vivo experiments. The transposition system (terminal repeats plus gene tnpA) of Tn5037 was inactive in Escherichia coli K12, in contrast to its resolution system (res site plus gene tnpR). However, transposition of Tn5037 in this host was provided by the tnpA gene of Tn5036, a member of the Tn21 subgroup. Sequence analysis of the Tn5037 res site suggested its recombinant nature.     

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.     

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 genes for benzene catabolism in Pseudomonas putida ML2 are flanked by two copies of the insertion element IS1489, forming a class-I-type catabolic transposon, Tn5542

Two directly repeated sequences of the IS elements IS1489v1 and IS1489v2 flank the benzene dioxygenase (bedC1C2BA) and the cis-benzene dihydrodiol dehydrogenase (bedD) genes on the catabolic plasmid pHMT112 in Pseudomonas putida ML2, forming a Class-I-type composite transposon, Tn5542. Both IS1489v1 and IS1489v2 contain an identical 1371-bp open reading frame, tnpA, that is preceded by a possible ribosome binding site. The tnpA gene of IS1489v1 is bound by a pair of 40-bp imperfect inverted repeats while that of IS1489v2 is flanked only by the left inverted repeat. The tnpA gene codes for a putative 53-kDa polypeptide of 456 amino acids bearing similarity to transposases encoded on IS elements of P. alcaligenes, P. aeruginosa, P. stutzeri, and Serratia marcescens. The basic nature of the putative TnpA protein with a deduced pI of 8.93 is typical of IS-encoded transposases. Similar to other IS elements, an outward facing promoter was detected at the right end of IS1489v1. Experiments involving the suicide vector, pKNG101, failed to show transposition of Tn5542.     

Transposition of Tn1000: in vivo properties.

Transposition mediated by the Tn1000 transposase was investigated by using transposon variants carrying synthetic or wild-type termini but no intact Tn1000 genes. Transposon Tn1001, whose only homologies to Tn1000 are in its 38-base-pair terminal inverted repeats, transposed at the same rate as Tn1005, an artificial construct carrying wild-type Tn1000 termini and approximately 1 kilobase of flanking Tn1000 DNA at each end, when transposase was supplied in trans. The majority of the transpositions into pOX38 gave rise to cointegrates, but approximately 10% of the products expressed phenotypes of direct transpositions. The expression and temperature dependence of the tnpA gene product were examined by studying transposition of Tn1001 to bacteriophage lambda. The temperature optimum for transposition was 37 degrees C, and the transposase was stable for up to 2 h at this temperature.     

Transposition of DEH,a broad-host-range transposon flanked by ISPpu12, in Pseudomonas putida is associated with genomic rearrangements and dehalogenase gene silencing

Pseudomonas putida strain PP3 produces two hydrolytic dehalogenases encoded by dehI and dehII, which are members of different deh gene families. The 9.74-kb DEH transposon containing dehI and its cognate regulatory gene, dehR(I), was isolated from strain PP3 by using the TOL plasmid pWW0. DEH was fully sequenced and shown to have a composite transposon structure, within which dehI and dehR(I) were divergently transcribed and were flanked on either side by 3.73-kb identical direct repeats. The flanking repeat unit, designated ISPpu12, had the structure of an insertion sequence in that it was bordered by 24-bp near-perfect inverted repeats and contained four open reading frames (ORFs), one of which was identified as tnpA, putatively encoding an ISL3 family transposase. A putative lipoprotein signal peptidase was encoded by an adjacent ORF, lspA, and the others, ISPpu12 orf1 and orf2, were tentatively identified as a truncated cation efflux transporter gene and a PbrR family regulator gene, respectively. The orf1-orf2 intergenic region contained an exact match with a previously described active, outward-orientated promoter, Pout. Transposition of DEH-ISPpu12 was investigated by cloning the whole transposon into a suicide plasmid donor, pAWT34, and transferring the construct to various recipients. In this way DEH-ISPpu12 was shown to transpose in a broad range of Proteobacteria. Transposition of ISPpu12 independently from DEH, and inverse transposition, whereby the vector DNA and ISPpu12 inserted into the target genome without the deh genes, were also observed to occur at high frequencies in P. putida PaW340. Transposition of a second DEH-ISPpu12 derivative introduced exogenously into P. putida PP3 via the suicide donor pAWT50 resulted in silencing of resident dehI and dehII genes in about 10% of transposition transconjugants and provided a genetic link between transposition of ISPpu12 and dehalogenase gene silencing. Database searches identified ISPpu12-related sequences in several bacterial species, predominantly associated with plasmids and xenobiotic degradative genes. The potential role of ISPpu12 in gene silencing and activation, as well as the adaptation of bacteria to degrade xenobiotic compounds, is discussed.     

Novel one-step cloning vector with a transposable element: application to the Myxococcus xanthus genome.

A new strategy was developed for rapid cloning of genes with a transposon mutation library. We constructed a transposon designated TnV that was derived from Tn5 and consists of the gene coding for neomycin phosphotransferase II as well as the replication origin of an Escherichia coli plasmid, pSC101, flanked by Tn5 inverted repeats (IS50L and IS50R). TnV can transpose to many different sites of DNA in E. coli and Myxococcus xanthus and confers kanamycin resistance (Kmr) to the cells. From the Kmr cells, one-step cloning of a gene which is mutated as a result of TnV insertion can be achieved as follows. Chromosomal DNA isolated from TnV-mutagenized cells is digested with an appropriate restriction enzyme, ligated, and transformed into E. coli cells with selection for Kmr. The plasmids isolated contain TnV in the target gene. The plasmid DNA can then be used as a probe for characterization of the gene and screening of clones from a genomic library. We used this vector to clone DNA fragments containing genes involved in the development of M. xanthus.     

Complete nucleotide sequence of Tn1721: gene organization and a novel gene product with features of a chemotaxis protein.

The complete 11,139-nucleotide sequence of transposon Tn1721 has been determined. It contains three 38-bp inverted repeats, and (in this order) a new orfI, a resolution site (res), genes encoding resolvase (tnpR), transposase (tnpA), tetracycline-resistance (TcR) repressor (tetR), TcR (tetA) and a truncated transposase gene (tnpA'). The modulator origin of Tn1721 from at least three separate sources is supported by the distinctive codon usages of orfI, tnpR/tnpA and tetR/tetA, and by sequence similarities with Tn501 (tnpR/tnpA) and RP1 (tetR/tetA). The ORFI-encoded 56-kDa polypeptide exhibits features of a methyl-accepting chemotaxis protein (MCP) with a conserved signal domain and a potential transmembrane domain; this polypeptide cross-reacts with anti-MCP antiserum. Like chemotaxis genes, orfI is transcribed from a sigma 28-like promoter. The overexpressed orfI gene product interferes with MCP-dependent chemotaxis suggesting that it completes for soluble transducer protein(s) in the cell. The potential selective advantage of this novel transposon-borne gene is discussed.     

IS231A from Bacillus thuringiensis is functional in Escherichia coli: transposition and insertion specificity.

A kanamycin resistance gene was introduced within the insertion sequence IS231A from Bacillus thuringiensis, and transposition of the element was demonstrated in Escherichia coli. DNA sequencing at the target sites showed that IS231A transposition results in direct repeats of variable lengths (10, 11, and 12 bp). These target sequences resemble the terminal inverted repeats of the transposon Tn4430, which are the preferred natural insertion sites of IS231 in B. thuringiensis.     

Molecular genetic analysis of the Tn5041 transposition system

A study was made of the transposition of the mercury resistance transposon Tn5041 which, together with the closely related toluene degradation transposon Tn4651, forms a separate group in the Tn3 family. Transposition of Tn5041 was host-dependent: the element transposed in its original host Pseudomonas sp. KHP41 but not in P. aeruginosa PAO-R and Escherichia coli K12. Transposition of Tn5041 in these strains proved to be complemented by the transposase gene (tnpA) of Tn4651. The gene region determining the host dependence of Tn5041 transposition was localized with the use of a series of hybrid (Tn5041 x Tn4651) tnpA genes. Its location in the 5'-terminal one-third of the transposase gene is consistent with the data that this region is involved in the formation of the transposition complex in transposons of the Tn3 family. As in other transposons of this family, transposition of Tn5041 occurred via cointegrate formation, suggesting its replicative mechanism. However, neither of the putative resolution proteins encoded by Tn5041 resolved the cointegrates formed during transposition or an artificial cointegrate in E. coli K12. Similar data were obtained with the mercury resistance transposons isolated from environmental Pseudomonas strains and closely related to Tn5041 (Tn5041 subgroup).     

Toluene transposons Tn4651 and Tn4653 are class II transposons

The toluene degradative transposon Tn4651 is included within another transposon, Tn4653, and both of these elements are members of the Tn3 family. The tnpA gene product of each element mediates formation of cointegrates as intermediate products of transposition, and the tnpS and tnpT gene products encoded by Tn4651 take part in resolution of both Tn4651- and Tn4653-mediated cointegrates. Sequence analysis demonstrated that Tn4651 and Tn4653 have 46- and 38-base-pair terminal inverted repeats, respectively, and that both elements generate 5-base-pair duplication of the target sequence upon transposition. Complementation tests of the Tn4651- and Tn4653-encoded transposition functions with those of Tn3, Tn21, and Tn1721 showed that (i) the trans-acting transposition functions encoded by Tn4651 were not interchangeable with those encoded by the four other transposons, (ii) the Tn4653 tnpA function was interchangeable with the Tn1721 function, and (iii) Tn4653 coded for a resolvase (tnpR gene product) that complemented the tnpR mutations of Tn21 and Tn1721. The Tn4653 tnpR gene was located just 5' upstream of the tnpA gene and shared extensive sequence homology with the Tn1721 tnpR gene. The res region was located adjacent to the tnpR gene, and sequence analysis indicated that failure of the Tn4653 tnpR product to resolve the Tn4653-mediated cointegrates is ascribed to an incomplete structure of the res region.     

Functional analysis of unique class II insertion sequence IS1071

Various xenobiotic-degrading genes on many catabolic plasmids are often flanked by two copies of an insertion sequence, IS1071. This 3.2-kb IS element has long (110-bp) terminal inverted repeats (IRs) and a transposase gene that are phylogenetically related to those of the class II transposons. However, the transposition mechanism of IS1071 has remained unclear. Our study revealed that IS1071 was only able to transpose at high frequencies in two environmental beta-proteobacterial strains, Comamonas testosteroni and Delftia acidovorans, and not in any of the bacteria examined which belong to the alpha- and gamma-proteobacteria. IS1071 was found to have the functional features of the class II transposons in that (i) the final product of the IS1071 transposition was a cointegrate of its donor and target DNA molecules connected by two directly repeated copies of IS1071, one at each junction; (ii) a 5-bp duplication of the target sequence was observed at the insertion site; and (iii) a tnpA mutation of IS1071 was efficiently complemented by supplying the wild-type tnpA gene in trans. Deletion analysis of the IS1071 IR sequences indicated that nearly the entire region of the IRs was required for its transposition, suggesting that the interaction between the transposase and IRs of IS1071 might be different from that of the other well-characterized class II transposons.     

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.     

The nucleotide sequence of the tnpA gene completes the sequence of the Pseudomonas transposon Tn501.

The nucleotide sequence of the gene (tnpA) which codes for the transposase of transposon Tn501 has been determined. It contains an open reading frame for a polypeptide of Mr = 111,500, which terminates within the inverted repeat sequence of the transposon. The reading frame would be transcribed in the same direction as the mercury-resistance genes and the tnpR gene. The amino acid sequence predicted from this reading frame shows 32% identity with that of the transposase of the related transposon Tn3. The C-terminal regions of these two polypeptides show slightly greater homology than the N-terminal regions when conservative amino acid substitutions are considered. With this sequence determination, the nucleotide sequence of Tn501 is fully defined. The main features of the sequence are briefly presented.     

Overproduction of the Tn3 transposition protein and its role in DNA transposition

Five single base pair mutations that increase expression of the tnpA (transposase) gene of the Tn3 transposon approximately 30-fold, but which still allow the gene to be regulated, have been isolated by using a generally applicable procedure that involves distally linked lac gene fusions. The mutations, which are all located in a region controlling initiation of translation of the tnpA gene, do not affect normal repression of tnpA by the tnpR gene product, and yield up to a 9000-fold increase in tnpA protein production when combined with a tnpR mutation and placed on a high copy number plasmid. The mutation yielding the highest expression level was separated from the fused lac gene segment by homologous recombination and was found to increase the rate of transposition without altering the nature of the transposition product; in cells defective in both the E. coli recA gene and the tnpR gene of tn3, cointegrate transposition-intermediate structures occur with the overproducing--as well as with the wild-type--tnpA gene. In the presence of a functional Tn3 tnpR gene or the related transposon delta gamma, such cointegrate structures are resolved into the final products of transposition.     

Scooter, a new active transposon in Schizophyllum commune, has disrupted two genes regulating signal transduction

Two copies of scooter, a DNA-mediated transposon in the basidiomycetous fungus Schizophyllum commune, were characterized. Scooter is the first transposon isolated from S. commune. Scooter creates 8-bp target site duplications, comparable to members of the hAT superfamily, and has 32-bp terminal inverted repeats. Both copies of scooter are nonautonomous elements capable of movement. Southern blot hybridizations show that scooter-related sequences are present in all S. commune strains tested. Scooter-1 was identified initially as an insertion in the Bbeta2 pheromone receptor gene, bbr2, leading to a partial defect in mating. Scooter-2 spontaneously disrupted a gene to produce the frequently occurring morphological mutant phenotype known as thin. The scooter-2 insert permitted cloning of the disrupted gene, thn1, which encodes a putative regulator of G protein signaling (RGS) protein. Spontaneous insertion of scooter into genes with identifiable mutant phenotypes constitutes the first evidence of active transposition of a DNA-mediated transposon in a basidiomycete.