Specificity of insertion of IS91, an insertion sequence present in alpha-haemolysin plasmids of Escherichia coli

Intracellular Transposition and Capture of Mobile Genetic Elements following Intercellular Conjugation of Multidrug Resistance Conjugative Plasmids from Clinical Enterobacteriaceae Isolates

Mobile genetic elements (MGEs) are often associated with antimicrobial resistance genes (ARGs). They are responsible for intracellular transposition between different replicons and intercellular conjugation and are therefore important agents of ARG dissemination. Detection and characterization of functional MGEs, especially in clinical isolates, would increase our understanding of the underlying pathways of transposition and recombination and allow us to determine interventional strategies to interrupt this process. Entrapment vectors can be used to capture active MGEs, as they contain a positive selection genetic system conferring a selectable phenotype upon the insertion of an MGE within certain regions of that system. Previously, we developed the pBACpAK entrapment vector that results in a tetracycline-resistant phenotype when MGEs translocate and disrupt the cI repressor gene. We have previously used pBACpAK to capture MGEs in clinical Escherichia coli isolates following transformation with pBACpAK. In this study, we aimed to extend the utilization of pBACpAK to other bacterial taxa. We utilized an MGE-free recipient E. coli strain containing pBACpAK to capture MGEs on conjugative, ARG-containing plasmids following conjugation from clinical Enterobacteriaceae donors. Following the conjugative transfer of multiple conjugative plasmids and screening for tetracycline resistance in these transconjugants, we captured several insertion sequence (IS) elements and novel transposons (Tn7350 and Tn7351) and detected the de novo formation of novel putative composite transposons where the pBACpAK-located tet(A) is flanked by ISKpn25 from the transferred conjugative plasmid, as well as the ISKpn14-mediated integration of an entire 119-kb, bla_NDM-1-containing conjugative plasmid from Klebsiella pneumoniae.

IMPORTANCE By analyzing transposition activity within our MGE-free recipient, we can gain insights into the interaction and evolution of multidrug resistance-conferring MGEs following conjugation, including the movement of multiple ISs, the formation of composite transposons, and cointegration and/or recombination between different replicons in the same cell. This combination of recipient and entrapment vector will allow fine-scale experimental studies of factors affecting intracellular transposition and MGE formation in and from ARG-encoding MGEs from multiple species of clinically relevant Enterobacteriaceae.

Emergence of transferable ceftazidime-avibactam resistance in KPC-producing Klebsiella pneumoniae due to a novel CMY AmpC β-lactamase in China

OBJECTIVES

To evaluate the molecular mechanisms of ceftazidime/avibactam (CAZ/AVI) resistance in six Klebsiella pneumoniae strains that co-produce K. pneumoniae carbapenemase (KPC)-2 and a novel variant of CMY cephalosporinase in a Chinese hospital.

METHODS

Antimicrobial susceptibility was determined by broth microdilution. Whole-genome sequencing (WGS) was performed to investigate potential resistance determinants. Plasmid conjugation, electroporation, S1 nuclease pulsed-field gel electrophoresis (S1-PFGE) hybridization and cloning experiment were carried out to investigate the resistance plasmids and genes.

RESULTS

A high level of CAZ/AVI resistance was observed in six KPC-Kp strains (MIC 128 mg/L). Five strains were isolated in 2015 and one in 2016, before the approval of CAZ/AVI in China. Sequence analysis indicated that all the strains belonged to sequence type (ST) 11 and uniformly carried a novel CMY AmpC β-lactamase gene, designated bla_CMY-172. When compared with CMY-2, CMY-172 has a deletion of three consecutive amino acids (K290, V291 and A292) in the R2-loop region and a non-synonymous amino acid substitution at position 346 (N³⁴⁶I). The bla_CMY-172-bearing plasmid, pKPCZA02_4, was 93.3 Kb, IncI1-I type, and conjugative; bla_CMY-172 was located in an IS1294-mediated transposon. Plasmid conjugation and DNA fragment cloning proved that bla_CMY-172 was responsible for CAZ/AVI resistance.

CONCLUSIONS

Our study identified conjugative plasmid-mediated bla_CMY-172 as a new mechanism for CAZ/AVI resistance in clinical KPC-Kp strains. Careful monitoring of CAZ/AVI susceptibility is imperative for preventing the spread of the resistance gene.

Helraiser intermediates provide insight into the mechanism of eukaryotic replicative transposition

Helitrons are eukaryotic DNA transposons that have profoundly affected genome variability via capture and mobilization of host genomic sequences. Defining their mode of action is therefore important for understanding how genome landscapes evolve. Sequence similarities with certain prokaryotic mobile elements suggest a “rolling circle” mode of transposition, involving only a single transposon strand. Using the reconstituted Helraiser transposon to study Helitron transposition in cells and in vitro, we show that the donor site must be double-stranded and that single-stranded donors will not suffice. Nevertheless, replication and integration assays demonstrate the use of only one of the transposon donor strands. Furthermore, repeated reuse of Helraiser donor sites occurs following DNA synthesis. In cells, circular double-stranded intermediates that serve as transposon donors are generated and replicated by Helraiser transposase. Cell-free experiments demonstrate strand-specific cleavage and strand transfer, supporting observations made in cells.

Helitrons are eukaryotic DNA transposons that have profoundly affected genome variation due to their ability to capture and mobilize host genomic fragments. Here the authors provide insight into the mechanism of action of these transposons both in cells and in vitro.

Everyman's Guide to Bacterial Insertion Sequences

The number and diversity of known prokaryotic insertion sequences (IS) have increased enormously since their discovery in the late 1960s. At present the sequences of more than 4000 different IS have been deposited in the specialized ISfinder database. Over time it has become increasingly apparent that they are important actors in the evolution of their host genomes and are involved in sequestering, transmitting, mutating and activating genes, and in the rearrangement of both plasmids and chromosomes. This review presents an overview of our current understanding of these transposable elements (TE), their organization and their transposition mechanism as well as their distribution and genomic impact. In spite of their diversity, they share only a very limited number of transposition mechanisms which we outline here. Prokaryotic IS are but one example of a variety of diverse TE which are being revealed due to the advent of extensive genome sequencing projects. A major conclusion from sequence comparisons of various TE is that frontiers between the different types are becoming less clear. We detail these receding frontiers between different IS-related TE. Several, more specialized chapters in this volume include additional detailed information concerning a number of these.

In a second section of the review, we provide a detailed description of the expanding variety of IS, which we have divided into families for convenience. Our perception of these families continues to evolve and families emerge regularly as more IS are identified. This section is designed as an aid and a source of information for consultation by interested specialist readers.

Distribution of IS91 family insertion sequences in bacterial genomes: evolutionary implications

IS91 is the prototype element of a family of bacterial insertion sequences that transpose by a rolling-circle mechanism. Although previously considered a rarity among IS elements, many new examples have been identified by sequence analysis of bacterial genomes. In this work we provide a summary of occurrences of IS91-like sequences in the GenBank database, characterise the genetic organisation of adjacent sequences, and analyse IS91 ecological significance under the light of current transposition mechanisms. Interestingly, IS91 family elements were usually found adjacent to pathogenicity- and virulence-related genes. Thus, this might constitute the niche for IS91 and IS91 family elements to play an important role in the dissemination and evolution of virulence and pathogenicity types of genes.

Analysis of antibiotic resistance regions in Gram-negative bacteria

Antibiotic resistance in Gram-negative bacteria is often due to the acquisition of resistance genes from a shared pool. In multiresistant isolates these genes, together with associated mobile elements, may be found in complex conglomerations on plasmids or on the chromosome. Analysis of available sequences reveals that these multiresistance regions (MRR) are modular, mosaic structures composed of different combinations of components from a limited set arranged in a limited number of ways. Components common to different MRR provide targets for homologous recombination, allowing these regions to evolve by combinatorial evolution, but our understanding of this process is far from complete. Advances in technology are leading to increasing amounts of sequence data, but currently available automated annotation methods usually focus on identifying ORFs and predicting protein function by homology. In MRR, where the genes are often well characterized, the challenge is to identify precisely which genes are present and to define the boundaries of complete and fragmented mobile elements. This review aims to summarize the types of mobile elements involved in multiresistance in Gram-negative bacteria and their associations with particular resistance genes, to describe common components of MRR and to illustrate methods for detailed analysis of these regions.

Structural characterization of ISCR8, ISCR22, and ISCR23, subgroups of IS91-like insertion elements

Analysis of ISCR8 (ISPps1) revealed that this group of insertion elements has to be subdivided into three subgroups: ISCR8, ISCR22, and ISCR23. The distinction of three subgroups is supported by phylogenetic analysis of the transposase open reading frames (ORFs). Comparison of over 20 complete and partial ISCR8/22/23 elements identified oriIS candidate sequences for all groups and a terIS candidate sequence for ISCR8. The oriIS sequences, their distance to the transposase ORFs, and the sequence of this intervening region are group specific, further supporting the definition of two new ISCR elements. ISCR8/22/23 have a very broad host range, including Gram-positive and Gram-negative bacteria, among which are several (opportunistic) pathogens. The IS often resides on plasmids or in the vicinity of other mobile elements and is mostly associated with genes for the degradation of halo- or nitro-aromatics. However, in one case ISCR8 was found in the neighborhood of an antibiotic resistance determinant in Klebsiella pneumoniae. ISCR8 resembles other IS91 family elements in mediating genetic rearrangements by homologous recombination between two copies. In Delftia acidovorans this led to the loss of the genes encoding dichlorprop cleavage. In conclusion, this study shows that ISCR8 could be a fully functional and active member of the IS91 family of insertion elements.

Revised nomenclature for transposable genetic elements

Transposable DNA elements occur naturally in the genomes of nearly all species of prokaryotes. A proposal for a uniform transposable element nomenclature was published prominently in the 1970s but is not, at present, available online even in abstract form, and many of the newly discovered elements have been named without reference to it. We propose here an updated version of the original nomenclature system for all of the various types of prokaryotic, autonomous, transposable elements excluding insertion sequences, for which a nomenclature system already exists. The use of this inclusive and sequential Tn numbering system for transposable elements, as described here, recognizes the ease of interspecies spread of individual elements, and allows for the naming of mosaic elements containing segments from two or more previously described types of transposons or plasmids. It will guard against any future need to rename elements following changes in bacterial nomenclature which occurs constantly with our increased understanding of bacterial phylogenies and taxonomic groupings. It also takes into account the increasing importance of metagenomic sequencing projects and the continued identification of new mobile elements from unknown hosts.

ISCR elements: novel gene-capturing systems of the 21st century?

"Common regions" (CRs), such as Orf513, are being increasingly linked to mega-antibiotic-resistant regions. While their overall nucleotide sequences show little identity to other mobile elements, amino acid alignments indicate that they possess the key motifs of IS91-like elements, which have been linked to the mobility ent plasmids in pathogenic Escherichia coli. Further inspection reveals that they possess an IS91-like origin of replication and termination sites (terIS), and therefore CRs probably transpose via a rolling-circle replication mechanism. Accordingly, in this review we have renamed CRs as ISCRs to give a more accurate reflection of their functional properties. The genetic context surrounding ISCRs indicates that they can procure 5' sequences via misreading of the cognate terIS, i.e., "unchecked transposition." Clinically, the most worrying aspect of ISCRs is that they are increasingly being linked with more potent examples of resistance, i.e., metallo-beta-lactamases in Pseudomonas aeruginosa and co-trimoxazole resistance in Stenotrophomonas maltophilia. Furthermore, if ISCR elements do move via "unchecked RC transposition," as has been speculated for ISCR1, then this mechanism provides antibiotic resistance genes with a highly mobile genetic vehicle that could greatly exceed the effects of previously reported mobile genetic mechanisms. It has been hypothesized that bacteria will surprise us by extending their "genetic construction kit" to procure and evince additional DNA and, therefore, antibiotic resistance genes. It appears that ISCR elements have now firmly established themselves within that regimen.

Active site sharing and subterminal hairpin recognition in a new class of DNA transposases

Many bacteria harbor simple transposable elements termed insertion sequences (IS). In Helicobacter pylori, the chimeric IS605 family elements are particularly interesting due to their proximity to genes encoding gastric epithelial invasion factors. Protein sequences of IS605 transposases do not bear the hallmarks of other well-characterized transposases. We have solved the crystal structure of full-length transposase (TnpA) of a representative member, ISHp608. Structurally, TnpA does not resemble any characterized transposase; rather, it is related to rolling circle replication (RCR) proteins. Consistent with RCR, Mg2+ and a conserved tyrosine, Tyr127, are essential for DNA nicking and the formation of a covalent intermediate between TnpA and DNA. TnpA is dimeric, contains two shared active sites, and binds two DNA stem loops representing the conserved inverted repeats near each end of ISHp608. The cocrystal structure with stem-loop DNA illustrates how this family of transposases specifically recognizes and pairs ends, necessary steps during transposition.

Recombination in the genome of Chlamydia trachomatis involving the polymorphic membrane protein C gene relative to ompA and evidence for horizontal gene transfer

Genome sequencing of Chlamydia trachomatis serovar D has identified polymorphic membrane proteins (Pmp) that are a newly recognized protein family unique to the Chlamydiaceae family. Cumulative data suggest that these diverse proteins are expressed on the cell surface and might be immunologically important. We performed phylogenetic analyses and statistical modeling with 18 reference serovars and 1 genovariant of C. trachomatis to examine the evolutionary characteristics and comparative genetics of PmpC and pmpC, the gene that encodes this protein. We also examined 12 recently isolated ocular and urogenital clinical samples, since reference serovars are laboratory adapted and may not represent strains that are presently responsible for human disease. Phylogenetic reconstructions revealed a clear distinction for disease groups, corresponding to levels of tissue specificity and virulence of the organism. Further, the most prevalent serovars, E, F, and Da, formed a distinct clade. According to the results of comparative genetic analyses, these three genital serovars contained two putative insertion sequence (IS)-like elements with 10- and 15-bp direct repeats, respectively, while all other genital serovars contained one IS-like element. Ocular trachoma serovars also contained both insertions. Previously, no IS-like elements have been identified for Chlamydiaceae. Surprisingly, 7 (58%) of 12 clinical isolates revealed pmpC sequences that were identical to the sequences of other serovars, providing clear evidence for a high rate of whole-gene recombination. Recombination and the differential presence of IS-like elements among distinct disease and prevalence groups may contribute to genome plasticity, which may lead to adaptive changes in tissue tropism and pathogenesis over the course of the organism's evolution.

Peripheral sequences of the Serratia entomophila pADAP virulence-associated region

Some strains of the Enterobacteriaceae Serratia entomophila and Serratia proteamaculans cause amber disease in the grass grub, Costelytra zealandica (Coleoptera: Scarabaeidae), an important pasture pest in New Zealand. The genes responsible for this disease reside on a large, 155-kb plasmid designated amber disease-associated plasmid (pADAP). Herein, we report the DNA sequencing of approximately 50 kb upstream and 10 kb downstream of the virulence-encoding region. Based on similarity with proteins in the current databases, and potential ribosome-binding sites, 63 potential ORFs were determined. Eleven of these ORFs belong to a type IV pilus cluster (pilL-V) and a further eight have similarities to the translated products of the plasmid transfer traH-N genes of the plasmid R64. In addition, a degenerate 785-nt direct repeat flanks a 44.7-kb region with the potential to encode three Bacillus subtilis Yee-type proteins, a fimbrial gene cluster, the sep virulence-associated genes and several remnant IS elements.

Nested deletions of the SRL pathogenicity island of Shigella flexneri 2a

In this study, we determined the boundaries of a 99-kb deletable element of Shigella flexneri 2a strain YSH6000. The element, designated the multiple-antibiotic resistance deletable element (MRDE), had recently been found to contain a 66-kb pathogenicity island (PAI)-like element (designated the SRL PAI) which carries the Shigella resistance locus (SRL), encoding resistance determinants to streptomycin, ampicillin, chloramphenicol, and tetracycline. The YSH6000 MRDE was found to be flanked by two identical IS91 elements present at the S. flexneri homologs of the Escherichia coli genes putA and mdoA on NotI fragment D. Sequence data from two YSH6000-derived MRDE deletants, YSH6000T and S2430, revealed that deletion of the MRDE occurred between the two flanking IS91 elements, resulting in a single IS91 element spanning the two original IS91 loci. Selection for the loss of tetracycline resistance confirmed that the MRDE deletion occurred reproducibly from the same chromosomal site and also showed that the SRL PAI and the SRL itself were capable of independent deletion from the chromosome, thus revealing a unique set of nested deletions. The excision frequency of the SRL PAI was estimated to be 10(-5) per cell in the wild type, and mutation of a P4-like integrase gene (int) at the left end of the SRL PAI revealed that int mediates precise deletion of the PAI.

Single-stranded DNA intermediates in IS91 rolling-circle transposition

IS91 displays a number of characteristics unique among insertion sequence (IS) elements, suggesting that it transposes by a novel mechanism called rolling-circle (RC) transposition. We reported previously that IS91 transposase (TnpA) amino acid sequence shares a series of five conserved signatures with A proteins of RC replicating phages, including a pair of invariant tyrosines that catalyse two successive transesterification reactions during replication initiation and termination. To analyse their role in IS91 transposition, we constructed a series of TnpA derivatives in which the invariant Tyr-249 and/or Tyr-253 were mutated to either phenylalanine or serine. Mutation of either tyrosine resulted in complete loss of transposition activity in vivo. This result was taken as a first new line of evidence that TnpA is a functional analogue of phiX174 phage A protein. Secondly, RC replication plasmids and phages accumulate single-stranded DNA (ssDNA) intermediates as a result of uncoupled leading and lagging DNA strand synthesis. Using a plasmid carrying an IS91-derived IRLkan-IRR transposable cassette, in which the left (IRL)- and right (IRR)-terminal sequences of IS91 flank a kanamycin resistance gene (kan), we demonstrated the in vivo formation of two new DNA species after induction of transposase expression. The first was a circular ssDNA that contained the transposable cassette covalently joined at its exact termini, whereas the second was a double-stranded circle of the same element. When this experiment was repeated using the mutant transposases described above, the ssDNA and dsDNA intermediates could not be observed, indicating that the integrity of both Y249 and Y253 was essential for their appearance. The presence of ssDNA intermediate products is the first biochemical evidence for a RC mechanism of IS91 transposition.

pUB2380: characterization of a ColD-like resistance plasmid

A detailed analysis of the mobilizable, ColE1-like resistance plasmid, pUB2380, is reported. The 8.5-kb genome encodes six (possibly seven) major functions: (1) a ColD-like origin of replication, oriV, with associated replication functions, RNAI and RNAII; (2) a set of active mobilization functions highly homologous to that of ColE1, including the origin of transfer, oriT; (3) a ColE1-like multimer resolution site (cer); (4) a kanamycin-resistance determinant, aph, encoding an aminoglycoside-3'-phosphotransferase type 1; (5) an insertion sequence, IS1294; and (6) two genes, probably cotranscribed, of unknown function(s). The GC content of the various parts of the genome indicates that the plasmid is a hybrid structure assembled from DNA from at least three different sources, of which the replication region, the mobilization functions, and the resistance gene are likely to have originated in the enterobacteriaceae.

IS1294, a DNA element that transposes by RC transposition

IS1294, found on the ColD-like resistance plasmid pUB2380, is IS91-like. It is an active 1.7-kb insertion sequence that lacks terminal inverted repeats, displays insertion-site specificity, and does not generate direct repeats of the target site. The element has one large open reading frame, tnp(1294), encoding a transposase of 351 amino acids, related to members of the REP family of replication proteins used by RC-plasmids of gram-positive bacteria. IS1294 transposes using rolling-circle replication, initiated at one end of the element, oriIS, and terminated at the other, terIS. oriIS and terIS are highly conserved among like IS elements. oriIS resembles the leading strand replication origins of RC-plasmids; terIS resembles a rho-independent transcription terminator. IS1294 mediates not only its own transposition, but also sequences adjacent to terIS. A transposition model for IS1294 and related elements, involving rolling-circle replication and single-strand DNA intermediates, is presented.

IS elements as constituents of bacterial genomes

We provide here an overview of our present understanding of the distribution of different insertion sequences (ISs) within bacterial genomes (both chromosomes and plasmids). This is at present fragmentary and a significant effort is needed in the analysis of the increasing number of genomes whose sequence has been determined. We also consider some of the properties of ISs which are important in their role of assembling, reassorting, and transmitting groups of genes.

Intramolecular transposition of insertion sequence IS91 results in second-site simple insertions

A series of plasmids carrying an IRL-kan-IRR transposable cassette, in which IRL and IRR are the left- and right-terminal sequences of IS91, have been constructed. These cassettes could be complemented for transposition with similar efficiency when IS91 transposase was provided either in cis or in trans. A total of 87% of IS91 transposition products were simple insertions of the element, while the remaining 13% were plasmid fusions and co-integrates. When transposase expression was induced from an upstream lac promoter, transposition frequency increased approximately 100-fold. An open reading frame (ORF) present upstream of the transposase gene, ORF121, could be involved in target selection, as mutations affecting this ORF were altered in their insertion specificity. Intramolecular rearrangements were analysed by looking at transposition events disrupting a chloramphenicol resistance gene (cat ) located outside the transposable cassette. Plasmid instability resulting from insertion of an extra copy of IRL-kan-IRR within the cat gene was observed; transposition products contained a second copy of the cassette inserted either as a direct or as an inverted repeat. No deletion or inversion of the intervening DNA was observed. These results could be explained as a consequence of intramolecular transposition of IS91 according to a model of rolling-circle transposition.

Insertion sequences

Insertion sequences (ISs) constitute an important component of most bacterial genomes. Over 500 individual ISs have been described in the literature to date, and many more are being discovered in the ongoing prokaryotic and eukaryotic genome-sequencing projects. The last 10 years have also seen some striking advances in our understanding of the transposition process itself. Not least of these has been the development of various in vitro transposition systems for both prokaryotic and eukaryotic elements and, for several of these, a detailed understanding of the transposition process at the chemical level. This review presents a general overview of the organization and function of insertion sequences of eubacterial, archaebacterial, and eukaryotic origins with particular emphasis on bacterial elements and on different aspects of the transposition mechanism. It also attempts to provide a framework for classification of these elements by assigning them to various families or groups. A total of 443 members of the collection have been grouped in 17 families based on combinations of the following criteria: (i) similarities in genetic organization (arrangement of open reading frames); (ii) marked identities or similarities in the enzymes which mediate the transposition reactions, the recombinases/transposases (Tpases); (iii) similar features of their ends (terminal IRs); and (iv) fate of the nucleotide sequence of their target sites (generation of a direct target duplication of determined length). A brief description of the mechanism(s) involved in the mobility of individual ISs in each family and of the structure-function relationships of the individual Tpases is included where available.

A ColE1-type plasmid from Salmonella enteritidis encodes a DNA cytosine methyltransferase

The multicopy plasmid pFM366 was isolated from a virulent Salmonella enteritidis strain and was found to code for DNA methylase activity (Ibáñez and Rotger, 1993). The present work was aimed at characterizing the genetic organization and functional features of this 5.6 kb plasmid. We found pFM366 almost identical to the plasmid P4 isolated from Shigella sonnei, that encodes the SsoII restriction-modification system (Karyagina et al., 1993), and related to other ColE1-type plasmids. Examination of these plasmids revealed a common organization which suggests they were the result of similar recombinational events. The cytosine methylase of pFM366 is nearly identical to M. SsoII, whereas the gene encoding the restrictase homologous to R. SsoII is truncated and its product is inactive. The expression of the cytosine methylase encoded by pFM366 is strongly affected by deletion of regions located upstream and downstream of its ORF, and is negatively controlled by the rpoS gene in Escherichia coli. The methylase activity encoded by pFM366 induces the SOS response, which could be responsible for the observed delay in the growth of E. coli.

Gene integration in the Escherichia coli chromosome mediated by Tn21 integrase (Int21)

A replication-thermosensitive, pSC101-derived plasmid containing the int gene and RHS-2 from the integron in Tn21 and a kanamycin resistance marker has been constructed and used to obtain Tn21 integrase (Int21)-mediated plasmid integration in the Escherichia coli chromosome. Colonies carrying an integrated plasmid were obtained after growth at 42 degrees C. Southern hybridization and PCR experiments indicated that they contained the plasmid specifically integrated through the RHS into different positions in the E. coli chromosome. Nucleotide sequence determination of the plasmid-chromosome junctions showed that integration sites in the chromosome were pentanucleotides with the sequence described for Int21 secondary sites.

Clonal relationships among bloodstream isolates of Escherichia coli

The clonal relationships among 187 bloodstream isolates of Escherichia coli from 179 patients at Boston, Mass., Long Beach, Calif., and Nairobi, Kenya, were determined by multilocus enzyme electrophoresis (MLEE), analysis of polymorphisms associated with the ribosomal operon (ribotyping), and serotyping. MLEE based on 20 enzymes resolved 101 electrophoretic types (ETs), forming five clusters; ribotyping resolved 56 distinct patterns concordant with the analysis by MLEE. The isolates at each study site formed a genetically diverse group and demonstrated similar clonal structures, with the same small subset of lineages accounting for the majority of isolates at each site. Moreover, two ribotypes accounted for approximately 30% of the isolates at each study site. One cluster contained the majority (65%) of isolates and, by direct comparison of the ETs and ribotypes of individual isolates, was genetically indistinguishable from the largest cluster for each of two other collections of E. coli causing pyelonephritis and neonatal meningitis (R. K. Selander, T. K. Korhonen, V. Väisänen-Rhen, P. H. Williams, P. E. Pattison, and D. A. Caugent, Infect. Immun. 52:213-222, 1986; M. Arthur, C. E. Johnson, R. H. Rubin, R. D. Arbeit, C. Campanelli, C. Kim, S. Steinbach, M. Agarwal, R. Wilkinson, and R. Goldstein, Infect. Immun. 57:303-313, 1989), thus defining a virulent set of lineages. The isolates within these virulent lineages typically carried DNA homologous to the adhesin operon pap or sfa and the hemolysin operon hly and expressed O1, O2, O4, O6, O18, O25, or O75 antigens. DNA homologous to pap was distributed among isolates of each major cluster, whereas hly was restricted to isolates of two clusters, typically detected in pap-positive strains, and sfa was restricted to isolates of one cluster, typically detected in pap- and hly-positive strains. The occurrence of pap-positive isolates in the same geographically and genetically divergent lineages suggests that this operon was acquired early in the radiation of E. coli, while hly and sfa were acquired subsequently, most likely by pap-positive and pap- and hly-positive precursors, respectively.

Differential roles of the transposon termini in IS91 transposition

Insertion sequence 91 (IS91) inserts specifically at GTTC or CTTG target sequences without duplication of the target. After insertion, the right inverted repeat (IRR) lies adjacent to the 3' end of the target sequences (or 5' to the complementary sequence CAAG or GAAC). We have analyzed the effects of alteration of each terminus of IS91 on transposition activity in Escherichia coli. IRR is absolutely required for transposition. Deletion analysis indicates that a 14-bp segment is not sufficient, but an 81-bp sequence within the IRR region is sufficient. Furthermore, the GTTC/CTTG target site is also required. The left inverted repeat (IRL) of IS91 is dispensable. Plasmid fusions originated by one-ended transposition of IS91 derivatives lacking IRL occur at about the same frequency as cointegrate formation observed for the wild-type element. In the one-ended-type fusions, the inserted fragment of donor DNA is flanked at one end (constant end) by IRR and at the other end by a GTTC or CTTG sequence present in the donor (variable end) in a way that usually results in multiple tandem insertions of the donor plasmid in the target site. These results are easily accommodated by a rolling-circle replicative transposition mechanism. This model also draws support from the finding that the IS91 transposase is related in sequence to the superfamily of rolling-circle replication proteins and the observation that IRR shows some conservation in sequence and secondary structure with the origins of replication of some rolling-circle replication plasmids.

Characterization of a small cryptic plasmid from Salmonella enteritidis that affects the growth of Escherichia coli

We examined the plasmid content of 25 clinical isolates of Salmonella enteritidis, and detected the presence of small plasmids (3-5.3 kb) in 9 of them, alone, or in addition to the large, so-called virulence plasmid. A 5.3-kb plasmid isolated as unique extrachromosomal DNA from a strain responsible for a high-mortality outbreak was characterized by restriction mapping and cloning. The plasmid replicon was localized in a 1.7-kb fragment, that hybridized with three of the small plasmids detected in S. enteritidis, and with another small plasmid from Salmonella typhimurium. A strain of Escherichia coli carrying this plasmid, or a cloned 3.7-kb PvuII restriction fragment, showed a slower growth rate, especially in minimal medium, as well as a noticeable increase in DNA methyltransferase activity.

DNA sequence of IS91 and identification of the transposase gene

IS91 is a 1,830-bp insertion sequence that inserts specifically at the sequence CAAG or GAAC of the target and does not duplicate any sequence upon insertion (23). By transposon mutagenesis, we have identified open reading frame 426 (ORF426; bp 454 to 1731) as the putative ORF for the transposase. It displays a cysteine-rich, potential metal-binding domain in its N-terminal region. Adjacent to ORF426, there is an ORF (ORF121) which precedes and terminally overlaps ORF426 by one amino acid. Tn1732 insertions in ORF121 do not affect the transposition frequency. IS91 has sequence similarities to IS801 from Pseudomonas syringae. Their putative transposases are 36% identical, including conservation of the cysteine-rich cluster. The information concerning IS801 insertion specificity and target duplication has been reevaluated in the light of our results.