Mapping of insertion element IS30 in the Escherichia coli K12 chromosome

The dynamic network of IS30 transposition pathways

The E. coli element IS30 has adopted the copy-out-paste-in transposition mechanism that is prevalent in a number of IS-families. As an initial step, IS30 forms free circular transposition intermediates like IS minicircles or tandem IS-dimers by joining the inverted repeats of a single element or two, sometimes distantly positioned IS copies, respectively. Then, the active IR-IR junction of these intermediates reacts with the target DNA, which generates insertions, deletions, inversions or cointegrates. The element shows dual target specificity as it can insert into hot spot sequences or next to its inverted repeats. In this study the pathways of rearrangements of transposition-derived cointegrate-like structures were examined. The results showed that the probability of further rearrangements in these structures depends on whether the IS elements are flanked by hot spot sequences or take part in an IR-IR junction. The variability of the deriving products increases with the number of simultaneously available IRs and IR-IR joints in the cointegrates or the chromosome. Under certain conditions, the parental structures whose transposition formed the cointegrates are restored and persist among the rearranged products. Based on these findings, a novel dynamic model has been proposed for IS30, which possibly fits to other elements that have adopted the same transposition mechanism. The model integrates the known transposition pathways and the downstream rearrangements occurring after the formation of different cointegrate-like structures into a complex network. Important feature of this network is the presence of “feedback loops” and reversible transposition rearrangements that can explain how IS30 generates variability and preserves the original genetic constitution in the bacterial population, which contributes to the adaptability and evolution of host bacteria.

Sequencing and comparative analysis of flagellin genes fliC, fljB, and flpA from Salmonella

Salmonella isolates have traditionally been classified by serotyping, the serologic identification of two surface antigens, O-polysaccharide and flagellin protein. Serotyping has been of great value in understanding the epidemiology of Salmonella and investigating disease outbreaks; however, production and quality control of the hundreds of antisera required for serotyping is difficult and time-consuming. To circumvent the problems associated with antiserum production, we began the development of a system for determination of serotype in Salmonella based on DNA markers. To identify flagellar antigen-specific sequences, we sequenced 280 alleles of the three genes that are known to encode flagellin in Salmonella, fliC, fljB, and flpA, representing 67 flagellar antigen types. Analysis of the data indicated that the sequences from fliC, fljB, and flpA clustered by the antigen(s) they encode not by locus. The sequences grouped into four clusters based on their conserved regions. Three of the four clusters included multiple flagellar antigen types and were designated the G complex, the Z4 complex, and the alpha cluster. The fourth cluster contained a single antigen type, H:z(29). The amino acid sequences of the conserved regions within each cluster have greater than 95% amino acid identity, whereas the conserved regions differ substantially between clusters (75 to 85% identity). Substantial sequence heterogeneity existed between alleles encoding different flagellar antigens while alleles encoding the same flagellar antigen were homologous, suggesting that flagellin genes may be useful targets for the molecular determination of flagellar antigen type.

Site-specific recombination by the DDE family member mobile element IS30 transposase

DNA rearrangements carried out by site-specific recombinases and transposases (Tpases) show striking similarities despite the wide spectrum of the catalytic mechanisms involved in the reactions. Here, we show that the bacterial insertion sequence (IS)30 element can act similarly to site-specific systems. We have developed an inversion system using IS30 Tpase and a viable lambda phage, where the integration/excision system is replaced with IS30. Both models have been proved to operate analogously to their natural counterpart, confirming that a DDE family Tpase is able to fulfill the functions of site-specific recombinases. This work demonstrates that distinction between transposition and site-specific recombination becomes blurred, because both functions can be fulfilled by the same enzyme, and both types of rearrangements can be achieved by the same catalytic mechanisms.

Gene conversion in transposition of Escherichia coli element IS30

The mobile element IS30 has dual target specificity, since it can integrate adjacent to the inverted repeat (IR) of another IS30 copy or into hot-spot sequences characterized by a well-defined consensus showing no similarity to the ends of the element. The result of such integrations into these targets is different, as gene conversion events take place frequently during insertion next to an IR end, while this phenomenon has never been observed in targeting hot-spot sequences. Conversion events in IR-targeting cannot be explained exclusively by the activity of the transposase, but suggest the involvement of the homologous recombination and repair machinery of the host cell. Here, we show that the homology between the donor and target sequences is required for conversion and the starting point of the process is the site of integration. The frequency of conversion depends on the distance of mutations from the end of the targeted element. Remarkable bias is found in the role of donor and target DNA, since generally the donor sequence is converted depending on the target. Conversion was shown to occur also without formation of transposition products. All these data are consistent with the idea of the establishment, migration and resolution of a Holliday-like cruciform structure, which can be responsible for conversion events. To explain the variety of conversion products in IR-targeting, a molecular model has been proposed and discussed.

Formation and transposition of the covalently closed IS30 circle: the relation between tandem dimers and monomeric circles

In the present study, we demonstrate that a circular IS30 element acts as an intermediate for simple insertion. Covalently closed IS and Tn circles constructed in vitro are suitable for integration into the host genome. Minicircle integration displays all the characteristics of transpositional fusion mediated by the (IS30 )2 dimer regarding target selection and target duplication. Evidence is provided for in vivo circularization of the element located either on plasmids or on the genome. It is shown that circle formation can occur through alternative pathways. One of them is excision of IS30 from a hot spot via joining the IRs. This reaction resembles the site-specific dimerization that leads to (IS30 )2 establishment. The other process is the dissolution of (IS30 )2 dimer, when the element is excised from an IR-IR joint. These pathways differ basically in the fate of the donor replicon: only dimer dissolution gives rise to resealed donor backbone. Analysis of minicircles and the rearranged donor replicons led us to propose a molecular model that can account for differences between the circle-generating processes. Our focus was to the dissolution of IR-IR joints located on the host genome, because these events promoted extensive genomic rearrangements and accompanied minicircle formation. The results present the possibility of host genome reorganization by IS30-like transposition.

Lack of hotspot targets: a constraint for IS30 transposition in Salmonella

IS30 is an insertion element common in E. coli strains but rare or absent in Salmonella. Transfer of the IS30-flanked transposon Tn2700 to Salmonella typhimurium was assayed using standard delivery procedures of bacterial genetics (conjugation and transduction). Tn2700 'hops' were rare and required transposase overproduction, suggesting the existence of host constraints for IS30 activity. Sequencing of three Tn2700 insertions in the genome of S. typhimurium revealed that the transposon had been inserted into sites with a low homology to the IS30 consensus target, suggesting that inefficient Tn2700 transposition to the Salmonella genome might be caused by a lack of hotspot targets. This view was confirmed by the introduction of an IS30 'hot target sequence', whose sole presence permitted Tn2700 transposition without transposase overproduction. Detection of IS30-induced DNA rearrangements in S. typhimurium provided further evidence that the element undergoes similar activities in E. coli and S. typhimurium. Thus, hotspot absence may be the main (if not the only) limitation for IS30 activity in the latter species. If these observations faithfully reproduce the scenario of natural populations, establishment of IS30 in the Salmonella genome may have been prevented by a lack of DNA sequences closely related to the unusually long (24 bp) IS30 consensus target.

Oxygen-insensitive nitroreductases: analysis of the roles of nfsA and nfsB in development of resistance to 5-nitrofuran derivatives in Escherichia coli

Nitroheterocyclic and nitroaromatic compounds constitute an enormous range of chemicals whose potent biological activity has significant human health and environmental implications. The biological activity of nitro-substituted compounds is derived from reductive metabolism of the nitro moiety, a process catalyzed by a variety of nitroreductase activities. Resistance of bacteria to nitro-substituted compounds is believed to result primarily from mutations in genes encoding oxygen-insensitive nitroreductases. We have characterized the nfsA and nfsB genes of a large number of nitrofuran-resistant mutants of Escherichia coli and have correlated mutation with cell extract nitroreductase activity. Our studies demonstrate that first-step resistance to furazolidone or nitrofurazone results from an nfsA mutation, while the increased resistance associated with second-step mutants is a consequence of an nfsB mutation. Inferences made from mutation about the structure-function relationships of NfsA and NfsB are discussed, especially with regard to the identification of flavin mononucleotide binding sites. We show that expression of plasmid-carried nfsA and nfsB genes in resistant mutants restores sensitivity to nitrofurans. Among the 20 first-step and 53 second-step mutants isolated in this study, 65 and 49%, respectively, contained insertion sequence elements in nfsA and nfsB. IS1 integrated in both genes, while IS30 and IS186 were found only in nfsA and IS2 and IS5 were observed only in nfsB. Insertion hot spots for IS30 and IS186 are indicated in nfsA, and a hot spot for IS5 insertion is evident in nfsB. We discuss potential regional and sequence-specific determinants for insertion sequence element integration in nfsA and nfsB.

Target specificity of insertion element IS30

The Escherichia coli resident mobile element IS30 has pronounced target specificity. Upon transposition, the element frequently inserts exactly into the same position of a preferred target sequence. Insertion sites in phages, plasmids and in the genome of E. coli are characterized by an exceptionally long palindromic consensus sequence that provides strong specificity for IS30 insertions, despite a relatively high level of degeneracy. This 24-bp-long region alone determines the attractiveness of the target DNA and the exact position of IS30 insertion. The divergence of a target site from the consensus and the occurrence of 'non-permitted' bases in certain positions influence the target activity. Differences in attractiveness are emphasized if two targets are present in the same replicon, as was demonstrated by quantitative analysis. In a system of competitive targets, the oligonucleotide sequence representing the consensus of genomic IS30 insertion sites proved to be the most efficient target. Having compared the known insertion sites, we suppose that IS30-like target specificity, which may represent an alternative strategy in target selection among mobile elements, is characteristic of the insertion sequences IS3, IS6 and IS21, too.

The delta (argF-lacZ)205(U169) deletion greatly enhances resistance to hydrogen peroxide in stationary-phase Escherichia coli

In this study, we demonstrate that a strain bearing the delta (argF-lacZ)205(U169) deletion exhibits a high level of resistance to hydrogen peroxide compared with its undeleted parent. Our initial investigation of the mechanism behind the observed differences in peroxide resistance when parent and mutant strains are compared indicates that the parent strain carries a region near argF that is responsible for the H2O2-sensitive phenotype, which we have named katC. The H2O2 resistance phenotype of the delta katC [delta (argF-lacZ)205(U169)] mutant strain can be duplicated by Tn9 insertion in a specific locus (katC5::Tn9) which maps near argF. The increased H2O2 resistance of the delta katC and katC5::Tn9 mutant strains can be seen only when cells are grown to stationary phase; exponential-phase cells are unaffected by the presence or absence of katC. This H2O2 resistance mechanism requires functional katE and katF genes, which suggests that the mechanism of H2O2 resistance may involve the activity of the stationary-phase-specific catalase HPII. Cloning, DNA sequencing, and analysis of the katC5::Tn9 insertion allele in comparison with its parent allele implicate two insertion elements, IS1B and IS30B, and suggest that their presence sensitizes parent cells to H2O2.

Formation of the tandem repeat (IS30)2 and its role in IS30-mediated transpositional DNA rearrangements

Plasmids carrying two IS30 elements in the same orientation, as in the composite transposon Tn2706, are structurally unstable in Escherichia coli. A primary segregation product is formed by site-specific deletion of the sequences carried between the two IS30 elements. The resulting covalently closed replicon carries the two IS30 elements as tandem repeats separated by only 2 bp. This (IS30)2 structure is extremely unstable, but it can nevertheless be isolated on its vector plasmid and, after purification, can be reintroduced into host cells by transformation. Among the descendants of transformants of recA- bacteria, replicated copies of the introduced (IS30)2 structure are still present, together with various kinds of segregation products which provide evidence for the efficient generation of DNA rearrangements. Most abundant is the product of another site-specific recombination between two identical ends of the IS30 elements involved, which results in the presence of just one intact IS30 on the plasmid. Apart from this, and depending on the presence of appropriate targets for IS30 transposition, various transposition products of (IS30)2 are also seen. Intramolecular reactions lead to DNA inversions and deletions with breakpoints other than IS30 ends. In intermolecular reactions inverse transposition occurs at high frequency and one also obtains simple transposition and cointegration. A mutational study revealed the requirement in cis of one intact IS30 transposase gene and of both proximal ends of the two IS30 elements concerned not only for the formation of (IS30)2, but also for its further rearrangement reactions, including the efficient formation of site-specific deletions. A model is proposed, which postulates that (IS30)2 intermediates play a key role in IS30 transposition pathways in which the formation of (IS30)2 may be rate-limiting. Once this structure is formed, it gives rise to a burst of transpositional rearrangements in the subclone carrying (IS30)2. Evolutionary implications of these findings are discussed.

Proteins encoded by the Escherichia coli replication terminus region

The replication terminus region (31 to 35 min) of the Escherichia coli chromosome contains very few mapped genes (two per min) compared with the remainder of the chromosome, and much of the DNA appears dispensable. In order to determine whether, despite this, the terminus region consists of protein-coding sequences, we cloned 44 kb (1 min) of terminus region DNA (that surrounding trg at 31.4 min) and examined its ability to catalyze protein synthesis in vitro or in minicells. We were able to account for more than half the coding capacity of the cloned DNA with proteins synthesized in these systems, indicating that the sparsity of mapped genes in the terminus region does not result from a lack of identifiable coding sequences. We can therefore conclude that the terminus region is composed mainly of expressable, albeit inessential, protein-encoding genes.

Four types of IS1 with differences in nucleotide sequence reside in the Escherichia coli K-12 chromosome

The Escherichia coli K-12 chromosome contains six copies of insertion element IS1 at loci is1A-is1F. We determined their nucleotide (nt) sequences and found that they were classified into four types. Two copies of IS1 which flank a chromosomal segment containing the argF gene (IS1B and IS1C) have identical nt sequences. Another identical pair are IS1A and IS1E. Comparison of their nt sequences with the IS1 in plasmid R100 revealed seven nt mismatches for IS1A (or IS1E), two for IS1B (or IS1C), four for IS1D, and 75 for IS1F. The fact that the IS1s flanking the argF segment are identical supports the idea that the segment, together with the particular pair of IS1s, has constituted a composite transposon and transposed after genetic transfer from another bacterial species into E. coli K-12. Duplicated sequences were not observed in the regions flanking each of four copies of IS1, indicating that rearrangements have occurred in these chromosomal regions after IS1 elements had been inserted into several target sites. The four types of IS1 present in the E. coli K-12 chromosome were essentially similar to IS1s in plasmid R100 and in the chromosomes of Shigella strains. This and the above results suggest that they have been transferred horizontally from other Enterobacteriaceae, including Shigella, into E. coli K-12.

A novel repeated DNA sequence located in the intergenic regions of bacterial chromosomes

We report the discovery of a novel group of highly conserved DNA sequences located within the intergenic regions of the chromosomes of Escherichia coli, Salmonella typhimurium and other bacteria. These intergenic repeat units (IRUs) are 124-127 nucleotides long and have the potential to form stable stem-loop structures. The location of these sequences within the intergenic regions is variable with respect to known or putative signals for transcription and translation of the flanking genes. Some of the IRU sequences are transcribed, others are probably not. The structure and possible functions of these sequences are discussed in relation to palindromic units and other repeated DNA sequences in bacteria.