Multiple copies of IS10 in the Enterobacter cloacae MD36 chromosome.

Repetitive sequences were isolated and characterized as double-stranded DNA fragments by treatment with S1 nuclease after denaturation and renaturation of the total DNA of Enterobacter cloacae MD36. One repetitive sequence was identical to the nucleotide sequence of IS10-right (IS10R), which is the active element in the plasmid-associated transposon Tn10. Unexpectedly, 15 copies of IS10R were found in the chromosomal DNA of E. cloacae MD36. One copy of the central region of Tn10 was found in the total DNA of E. cloacae MD36. IS10Rs in restriction fragments isolated from the E. cloacae MD36 total DNA showed 9-bp duplications adjacent to the terminal sequences that are characteristic of Tn10 transposition. This result suggests that many copies of IS10R in E. cloacae MD36 are due to transposition of IS10R alone, not due to transposition of Tn10 or to DNA rearrangement. I also found nine copies of IS10 in Shigella sonnei HH109, two and four copies in two different natural isolates of Escherichia coli, and two copies in E. coli K-12 strain JM109 from the 60 bacterial strains that were examined. All dam sites in the IS10s in E. cloacae MD36 and S. sonnei HH109 were methylated. Tn10 and IS10 transpose by a mechanism in which the element is excised from the donor site and inserted into the new target site without significant replication of the transposing segment; thus, the copy numbers of the elements in the cell are thought to be unchanged in most circumstances. Accumulation of IS10 copies in E. cloacae MD36 has interesting evolutionary implications.     

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.     

Tn951: A new transposon carrying a lactose operon

Summary A new transposon, Tn951, is described, which derives from plasmid pGC1, originally isolated from Yersinia enterocolitica. Tn951 is 16.6 kb long and presumably flanked by small inverted repeats. It carries the lac genes i, z and y. This lac system is homologous to the E. coli lac operon. However, homology is restricted to 5.6 kb. The DNA sequences surrounding the lac operons on Tn951 and E. coli are nonhomologous. This leads to speculations about the origin of the E. coli lac operon itself.     

Transposition of the oxacillin-hydrolyzing penicillinase gene.

We have found that the oxacillin-hydrolyzing penicillinase gene (oxa) encoded by plasmid RGN238 transposes to various plasmids in a recA background. We call this transposable element Tn2603. Tn2603 encodes the genes for streptomycin, sulfonamide, and mercury resistance in addition to the oxa gene. Tn2603 has a molecular size of 19.6 kilobase pairs and appears to be flanked by small inverted repeat sequences of about 200 base pairs long.     

Location and analysis of nucleotide sequences at one end of a putative lac transposon in the Escherichia coli chromosome.

A segment of Escherichia coli DNA that contained a discontinuity of homology with Salmonella typhimurium DNA was isolated. The segment, 1,430 base pairs long, was derived from one end of the lac "loop," a region of about 12 kilobase pairs of E. coli DNA, including the lac operon which has no detectable homology with S. typhimurium DNA (K. Lampel and M. Riley, Mol. Gen. Genet. 186:82-86, 1982). The nucleotide sequence of the 1,430-base-pair segment of DNA was determined. The location of the junction of discontinuity of homology within the segment was established by hybridization experiments. Nucleotide sequences at or near the junction were determined to be similar to sequences that are involved in site-specific inversion in S. typhimurium, E. coli, phage P1, and phage Mu. Similar sequences are also present within the terminal inverted repeat sequences of transposon Tn5 and at the V-D-J joining sequences of eucaryotic immunoglobulin genes. Therefore, the lac operon, together with flanking DNA, may have been inserted into the E. coli chromosome at one time via a site-specific recombination event. Rearrangement events of this kind undoubtedly have played a significant role in the evolutionary divergence of chromosomal DNAs.     

Evolutionary changes in the structural and regulatory regions of aminoglycoside-3'-phosphotransferase type I gene of E. coli

To investigate the evolutionary relationships between the aph(3') genes from different plasmids, the nucleotide sequence of the aph(3') gene from the E. coli R plasmid was determined and compared with the known aph(3') genes of Tn903 and Tn4352. Three point mutations in the structural part of the cloned aph(3') gene caused amino acid changes in the enzyme molecule at positions 19, 27 and 48 beginning from the start codon. The structural part of the gene was followed by two stop codons and a long DNA region containing no nucleotide sequences homologous to the sequences of Tn903 or Tn4352. Both the cloned aph(3') gene and Tn4352 were limited on the left by the spacer sequence and the insertion sequence IS176. Twenty one base pairs deletion abolished the -35 sequence of the promoter suggested for the aph(3') gene of Tn4352 and resulted in formation of a fusion promoter utilizing the -35 box of IS176 and the -10 box of the aph(3') gene. The distance between the -35 and -10 sequences changed from 18 to 17 bp. Changes in the cloned aph(3') gene and the flanking DNA regions resulted in formation of a new promoter and loss of the right IS176 element.     

Polymorphisms in the umuDC region of Escherichia species.

The umuDC operon of Escherichia coli encodes mutagenic DNA repair. The umuDC regions of multiple isolates of E. coli, E. alkalescens, and E. dispar and a single stock of E. aurescens were mapped by nucleotide hybridization. umuDC is located at one end of a conserved tract of restriction endonuclease sites either 12.5 or 14 kilobase pairs long. Rearrangements, including possible deletions, were seen in the polymorphic DNA flanking the conserved tract. Restriction site polymorphisms were not found around the DNA repair gene recA or polA. The junctions of the conserved region contain direct repeats of nucleotide sequences resembling the termini of the Tn3 group of transposons. Possible mechanisms for the generation of these variants are discussed.     

Completion of the nucleotide sequence of the central region of Tn5 confirms the presence of three resistance genes.

The DNA sequence of the region located downstream from the kanamycin resistance gene of Tn5 up to the right inverted repeat IS50R has been determined. This completes the determination of the sequence of Tn5 which is 5818 bp long. The 2.7 Kb central region contains three resistance genes: the kanamycin-neomycin resistance gene, a gene coding for resistance to CL990 an antimitotic-antibiotic compound of the bleomycin family and a third gene that confers streptomycin resistance in some bacterial species but is cryptic in E. coli. A Tn5* mutant able to express streptomycin resistance in E. coli was isolated. With this mutant, it was demonstrated that in E. coli the expression of the three resistance genes is coordinated in a single operon.     

Conduction of pEC22, a plasmid coding for MR.EcoT22I, mediated by a resident Tn3-like transposon, Tn5396.

pEC22 is a small plasmid that encodes the restriction-modification system MR.EcoT22I. Restriction and functional analysis of the plasmid identified the positions of genes encoding that system. The plasmid is able to be conducted by conjugal plasmids, a process mediated by a transposon contained within pEC22. This cryptic transposon, called Tn5396, was isolated from pEC22 and partially sequenced. The sequence of Tn5396 is for the most part typical of transposons of the Tn3 family and is most similar to that of Tn1000. The transposon differs from closely related transposons in that it lacks well-conserved sequences in the inverted-repeat region and has an unusually long terminal inverted repeat. Consideration of regions of internal sequence similarity in this and other transposons in the Tn3 family supports a theory of the mechanism by which the ends of Tn3-like transposons may maintain substantial identity between their inverted repeats over the course of evolutionary time.     

DNA sequences of the integration sites and inverted repeated structure of transposon Tn3.

The nucleotide sequence of the "inverted repeat" structure of the transposon Tn3 was determined by the DNA sequencing procedure developed by Maxam and Gilbert(1). The sequence, 38 base pairs long, is as follows: 5'-GGGGTCTGACGCTCAGTGGAACGAAAACTCACGTTAAG..(Tn3) 3'-CCCCAGACTGCGAGTCACCTTGCTTTTGAGTGCAATTC.. The integration of Tn3 is associated with a directly repeated sequence of 5 nucleotides appearing at each end of Tn3. The two directly repeated sequences so far determined are not the same. Furthermore, there is no homologous structure around the integration point of Tn3.     

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.     

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.     

Tn5-mediated transposition of plasmid DNA after transduction to Myxococcus xanthus.

After coliphage P1-mediated transfer of Tn5-containing plasmid DNA from Escherichia coli to Myxococcus xanthus, transductants were identified which contained plasmid sequences integrated at many sites on the bacterial chromosome. The unaltered plasmid DNA sequences in these transductants were apparently flanked by intact Tn5 or IS50 sequences. These results suggest that Tn5-mediated transposition has occurred and provide a method for integrating plasmid DNA into the M. xanthus chromosome without the requirement for homologous recombination.     

Sequence requirements of Escherichia coli attTn7, a specific site of transposon Tn7 insertion.

Transposon Tn7 transposes at high frequency to a specific site, attTn7, in the Escherichia coli chromosome. We devised a quantitative assay for Tn7 transposition in which Tn7-end derivatives containing the cis-acting transposition sequences of Tn7 transpose from a bacteriophage lambda vector upon infection into cells containing the Tn7-encoded transposition proteins. We used this assay to identify a 68-base-pair DNA segment containing the sequences essential for attTn7 target activity. This segment is positioned asymmetrically with respect to the specific point of Tn7 insertion in attTn7 and lacks obvious homology to the sequences at the ends of Tn7 which participate directly in transposition. We also show that some sequences essential for attTn7 target activity are contained within the protein-coding sequence of a bacterial gene.     

Specificity of DNA recognition in the nucleoprotein complex for site-specific recombination by Tn21 resolvase.

Resolvases from Tn3-like transposons catalyse site-specific recombination at res sites. Each res site has 3 binding sites for resolvase, I, II, and III. The res sites in Tn3 and Tn21 have similar structures at I and II but they differ at III. Mutagenesis of the Tn21 res site showed that sub-site III is essential for recombination though the sequences in III that are recognized by Tn21 resolvase are positioned differently from the equivalent sequences in the Tn3 site. The deletion of III caused a 1,000-fold drop in the rate of recombination. But other mutations at III, changing 3 or 4 consecutive base pairs, caused only 1.5- to 4-fold decreases in rate, even when the mutations were in target sequences for this helix-turn-helix protein. The reason why Tn21 resolvase has similar activities at a number of different DNA sequences may be due to the multiplicity of protein-protein and protein-DNA interactions in its recombinogenic complex. This lack of precision may be a general feature of nucleoprotein complexes.     

Transposition of the kanamycin-resistance transposon Tn903

Summary The insertion of the kanamycin-resistance transposon, Tn903, into the Escherichia coli chromosome was studied. Tn903 is similar in structure to the well known transposons Tn5 and Tn10 in that it has a unique central sequence flanked by inverted repeat sequences extending more than a thousand base pairs. However, the central region of Tn903 has enough single-frame coding capacity only for the drug modifying enzyme, whereas Tn5 and Tn10 carry multigenic unique sequences. In this paper we demonstrate that two different classes of insertion event occur: (1) the first class is a complex event in which all or part of the genome of the bacteriophage lambda vector is co-inserted near the purE locus on the E. coli chromosome (11.7 min); (2) the second class appears to be a simple transposition event in which the transposon alone is inserted at relatively nonspecific sites in the chromosome, as has been described for Tn5 and Tn10. Furthermore both classes show dependency on homology-requiring recombination systems. We suggest that Tn903 transposes infrequently because it must utilize a recA-controlled host function, whereas Tn5 and Tn10 are recA-independent and encode similar but more active functions on the transposon DNA.     

Tn5 mutagenesis of Anabaena sp. strain PCC 7120: isolation of a new mutant unable to grow without combined nitrogen.

Methylation by Ava methylases in Escherichia coli increases the efficiency to transfer of Tn5 in pBR322bla:: Tn5 from E. coli to Anabaena sp. strain PCC 7120 by conjugation. Following conjugation, Tn5 but not pBR322 sequences were found at many different positions in the Anabaena chromosome. This procedure was used to mutagenize, tag, and clone a previously unrecognized gene required for nitrogen fixation in this Anabaena sp.