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

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.

How Do Transposable Elements Activate Expression of Transcriptionally Silent Antibiotic Resistance Genes?

The rapidly emerging phenomenon of antibiotic resistance threatens to substantially reduce the efficacy of available antibacterial therapies. Dissemination of resistance, even between phylogenetically distant bacterial species, is mediated mainly by mobile genetic elements, considered to be natural vectors of horizontal gene transfer. Transposable elements (TEs) play a major role in this process-due to their highly recombinogenic nature they can mobilize adjacent genes and can introduce them into the pool of mobile DNA. Studies investigating this phenomenon usually focus on the genetic load of transposons and the molecular basis of their mobility. However, genes introduced into evolutionarily distant hosts are not necessarily expressed. As a result, bacterial genomes contain a reservoir of transcriptionally silent genetic information that can be activated by various transposon-related recombination events. The TEs themselves along with processes associated with their transposition can introduce promoters into random genomic locations. Thus, similarly to integrons, they have the potential to convert dormant genes into fully functional antibiotic resistance determinants. In this review, we describe the genetic basis of such events and by extension the mechanisms promoting the emergence of new drug-resistant bacterial strains.

The complete genome of 2,6-dichlorobenzamide (BAM) degrader Aminobacter sp. MSH1 suggests a polyploid chromosome, phylogenetic reassignment, and functions of plasmids

Aminobacter sp. MSH1 (CIP 110285) can use the pesticide dichlobenil and its recalcitrant transformation product, 2,6-dichlorobenzamide (BAM), as sole source of carbon, nitrogen, and energy. The concentration of BAM in groundwater often exceeds the threshold limit for drinking water, requiring additional treatment in drinking water treatment plants or closure of the affected abstraction wells. Biological treatment with MSH1 is considered a potential sustainable alternative to remediate BAM-contamination in drinking water production. We present the complete genome of MSH1, which was determined independently in two institutes at Aarhus University and KU Leuven. Divergences were observed between the two genomes, i.e. one of them lacked four plasmids compared to the other. Besides the circular chromosome and the two previously described plasmids involved in BAM catabolism, pBAM1 and pBAM2, the genome of MSH1 contained two megaplasmids and three smaller plasmids. The MSH1 substrain from KU Leuven showed a reduced genome lacking a megaplasmid and three smaller plasmids and was designated substrain MK1, whereas the Aarhus variant with all plasmids was designated substrain DK1. A plasmid stability experiment indicate that substrain DK1 may have a polyploid chromosome when growing in R2B medium with more chromosomes than plasmids per cell. Finally, strain MSH1 is reassigned as Aminobacter niigataensis MSH1.

The IS6 family, a clinically important group of insertion sequences including IS26

The IS6 family of bacterial and archaeal insertion sequences, first identified in the early 1980s, has proved to be instrumental in the rearrangement and spread of multiple antibiotic resistance. Two IS, IS26 (found in many enterobacterial clinical isolates as components of both chromosome and plasmids) and IS257 (identified in the plasmids and chromosomes of gram-positive bacteria), have received particular attention for their clinical impact. Although few biochemical data are available concerning the transposition mechanism of these elements, genetic studies have provided some interesting observations suggesting that members of the family might transpose using an unexpected mechanism. In this review, we present an overview of the family, the distribution and phylogenetic relationships of its members, their impact on their host genomes and analyse available data concerning the particular transposition pathways they may use. We also provide a mechanistic model that explains the recent observations on one of the IS6 family transposition pathways: targeted cointegrate formation between replicons.

Challenges and advances in genetic manipulation of filamentous actinomycetes - the remarkable producers of specialized metabolites

Covering: up to February 2019Actinomycetes are Gram positive bacteria of the phylum Actinobacteria. These organisms are one of the most important sources of structurally diverse, clinically used antibiotics and other valuable bioactive products, as well as biotechnologically relevant enzymes. Most strains were discovered by their ability to produce a given molecule and were often poorly characterized, physiologically and genetically. The development of genetic methods for Streptomyces and related filamentous actinomycetes has led to the successful manipulation of antibiotic biosynthesis to attain structural modification of microbial metabolites that would have been inaccessible by chemical means and improved production yields. Moreover, genome mining reveals that actinomycete genomes contain multiple biosynthetic gene clusters (BGCs), however only a few of them are expressed under standard laboratory conditions, leading to the production of the respective compound(s). Thus, to access and activate the so-called "silent" BGCs, to improve their biosynthetic potential and to discover novel natural products methodologies for genetic manipulation are required. Although different methods have been applied for many actinomycete strains, genetic engineering is still remaining very challenging for some "underexplored" and poorly characterized actinomycetes. This review summarizes the strategies developed to overcome the obstacles to genetic manipulation of actinomycetes and allowing thereby rational genetic engineering of this industrially relevant group of microorganisms. At the end of this review we give some tips to researchers with limited or no previous experience in genetic manipulation of actinomycetes. The article covers the most relevant literature published until February 2019.

The ISApl1 2 Dimer Circular Intermediate Participates in mcr-1 Transposition

Objectives: The mobile colistin resistance gene mcr-1 is a serious threat to global human and animal health. The composite transposon Tn6330 and its circular intermediate were proposed to be involved in the spread of mcr-1 but their roles remain poorly understood.

Methods: To further explore the intermediates during the transposition of Tn6330, we engineered Escherichia coli strains that carry an intact Tn6330 transposon or its deletion derivatives. PCR assays were performed to detect IR-IR junctions and possible circular intermediates. We carried out transposition experiments to calculate transposition frequency. The transposition sites were characterized by whole genome sequence and ISMapper-based analyses.

Results: The presence of an intact Tn6330 was demonstrated to be essential for the successful transposition of mcr-1, although both Tn6330 and Tn6330-ΔIR could form circular intermediates. The insertion sequence junction structure was observed in all constructed plasmids but the ISApl1 dimer was only formed in one construct containing an intact Tn6330. The average frequency of mcr-1 transposition in an E. coli strain possessing an intact Tn6330 was ∼10^-6 per transformed cell. We identified 27 integration sites for the Tn6330 transposition event. All the transposition sites were flanked by 2 bp target duplications and preferentially occurred in AT-rich regions.

Conclusion: These results indicate that mcr-1 transposition relies on the presence of an intact Tn6330. In addition, formation of the tandem repeat ISApl1₂ could represent a crucial intermediate. Taken together, the current investigations provide mechanistic insights in the transposition of mcr-1.

Insertion Sequence IS26 Reorganizes Plasmids in Clinically Isolated Multidrug-Resistant Bacteria by Replicative Transposition

Carbapenemase-producing Enterobacteriaceae (CPE), which are resistant to most or all known antibiotics, constitute a global threat to public health. Transposable elements are often associated with antibiotic resistance determinants, suggesting a role in the emergence of resistance. One insertion sequence, IS26, is frequently associated with resistance determinants, but its role remains unclear. We have analyzed the genomic contexts of 70 IS26 copies in several clinical and surveillance CPE isolates from the National Institutes of Health Clinical Center. We used target site duplications and their patterns as guides and found that a large fraction of plasmid reorganizations result from IS26 replicative transpositions, including replicon fusions, DNA inversions, and deletions. Replicative transposition could also be inferred for transposon Tn4401, which harbors the carbapenemase bla_KPC gene. Thus, replicative transposition is important in the ongoing reorganization of plasmids carrying multidrug-resistant determinants, an observation that carries substantial clinical and epidemiological implications for understanding how such extreme drug resistance phenotypes evolve.

Although IS26 is frequently reported to reside in resistance plasmids of clinical isolates, the characteristic hallmark of transposition, target site duplication (TSD), is generally not observed, raising questions about the mode of transposition for IS26. The previous observation of cointegrate formation during transposition implies that IS26 transposes via a replicative mechanism. The other possible outcome of replicative transposition is DNA inversion or deletion, when transposition occurs intramolecularly, and this would also generate a specific TSD pattern that might also serve as supporting evidence for the transposition mechanism. The numerous examples we present here demonstrate that replicative transposition, used by many mobile elements (including IS26 and Tn4401), is prevalent in the plasmids of clinical isolates and results in significant plasmid reorganization. This study also provides a method to trace the evolution of resistance plasmids based on TSD patterns.

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.

Site-directed (IS30-FljA) transposon mutagenesis system to produce nonflagellated mutants of Salmonella Enteritidis

Site-directed integration/mutagenesis systems are used to carry out targeted transpositions on DNA. The well-characterized IS30-element and its transposase have numerous advantages that predestine it to be a good candidate for such applications. In order to generate nonflagellated mutants of Salmonella Enteritidis, a new site-directed mutagenesis system has been developed and applied. The system was constructed based on the assumption that the DNA-binding FljA component of the fusion transposase would bind to its target (the operator of fliC), and as a consequence, insertions could be concentrated in the flagellin operon. The system consists of two components: one expresses the fusion transposase and the other is an integration donor plasmid harbouring the (IS30)(2) reactive structure. The application of this site-directed mutagenesis system on a strain of S. Enteritidis 11 (SE11) resulted in several nonmotile mutants with fliD insertion that could serve as negatively markered vaccine candidates. Analysis of less motile mutants generated by the fusion transposase revealed further hot spot sequences preferred by the fusion construct.

Functional organization of the inverted repeats of IS30

The mobile element IS30 has 26-bp imperfect terminal inverted repeats (IRs) that are indispensable for transposition. We have analyzed the effects of IR mutations on both major transposition steps, the circle formation and integration of the abutted ends, characteristic for IS30. Several mutants show strikingly different phenotypes if the mutations are present at one or both ends and differentially influence the transposition steps. The two IRs are equivalent in the recombination reactions and contain several functional regions. We have determined that positions 20 to 26 are responsible for binding of the N-terminal domain of the transposase and the formation of a correct 2-bp spacer between the abutted ends. However, integration is efficient without this region, suggesting that a second binding site for the transposase may exist, possibly within the region from 4 to 11 bp. Several mutations at this part of the IRs, which are highly conserved in the IS30 family, considerably affected both major transposition steps. In addition, positions 16 and 17 seem to be responsible for distinguishing the IRs of related insertion sequences by providing specificity for the transposase to recognize its cognate ends. Finally, we show both in vivo and in vitro that position 3 has a determining role in the donor function of the ends, especially in DNA cleavage adjacent to the IRs. Taken together, the present work provides evidence for a more complex organization of the IS30 IRs than was previously suggested.

Formation of an inverted repeat junction in the transposition of insertion sequence ISLC3 isolated from Lactobacillus casei

An insertion sequence, ISLC3, of 1351 bp has been isolated from Lactobacillus casei. Formation of IS circles containing a 3 bp spacer (complete junction) or deletion of 25 bp at the left inverted repeat (IRL) between the abutted IS ends of the ISLC3 junction region (deleted junction) was also discovered in the lactobacilli and Escherichia coli system studied. We found that the promoter formed by the complete junction P(jun) was more active than that formed by the 25 bp deleted junction P(djun) or the indigenous promoter P(IRL). The corresponding transcription start sites for both promoter P(jun) and P(IRL) as well as P(djun) were subsequently determined using a primer extension assay. The activity of transposase OrfAB of ISLC3 was also assayed using an in vitro system. It was found that this transposase preferred to cleave a single DNA strand at the IRR over the IRL end in the transposition process, suggesting that attack of one end by the other was oriented from IRR to IRL.

Sub-terminal sequences modulating IS30 transposition in vivo and in vitro

Inverted repeats of insertion sequences (ISs) are indispensable for transposition. We demonstrate that sub-terminal sequences adjacent to the inverted repeats of IS30 are also required for optimal transposition activity. We have developed a cell-free recombination system and showed that the transposase catalyses formation of a figure-of-eight transposition intermediate, where a 2 bp long single strand bridge holds the inverted repeat sequences (IRs) together. This is the first demonstration of the figure-of-eight structure in a non-IS3 family element, suggesting that this mechanism is likely more widely adopted among IS families. We show that the absence of sub-terminal IS30 sequences negatively influences figure-of-eight production both in vivo and in vitro. These regions enhance IR-IR junction formation and IR-targeting events in vivo. Enhancer elements have been identified within 51 bp internal to IRL and 17 bp internal to IRR. In the right end, a decanucleotide, 5'-GAGATAATTG-3', is responsible for wild-type activity, while in the left end, a complex assembly of repetitive elements is required. Functioning of the 10 bp element in the right end is position-dependent and the repetitive elements in the left end act cooperatively and may influence bendability of the end. In vitro kinetic experiments suggest that the sub-terminal enhancers may, at least partly, be transposase-dependent. Such enhancers may reflect a subtle regulatory mechanism for IS30 transposition.

Transposition and target specificity of the typical IS30 family element IS1655 from Neisseria meningitidis

We have analysed the transposition and target selection strategy of IS1655, a typical IS30 family member resident in Neisseria meningitidis. We have redefined IS1655 as a 1080 bp long element with 25 bp imperfect inverted repeats (IRs), which generates a 3 bp target duplication and have shown that it transposes using an intermediate with abutted IRs separated by 2 bp. IS1655 exhibits bipartite target specificity inserting preferentially either next to sequences similar to its IRs or into an unrelated but well defined sequence. IR-targeting leads to the formation of a new junction in which the targeted IR and one of the donor IRs are separated by 2 bp. The non-IR targets were characterized as an imperfect 19 bp palindrome in which the central five positions show slight GC excess and the distal region is AT-rich. Artificial targets designed according to the consensus were recognized by the element as hot spots for insertion. The organization of IS1655 is similar to that of other IS30 family members. Moreover, it shows striking similarity to IS30 in transposition strategy even though their transposases differ in their N-terminal regions, which, for IS30, appears to determine target specificity. Comparative analysis of the transposases and the evolutionary aspects of sequence variants are also briefly discussed.

A novel transposon-based method for elimination of large bacterial plasmids

Elimination or modification of large plasmids of bacteria is often an essential step in functional analysis of these replicons. However, the conventional plasmid-curing procedures such as ethidium bromide and heat treatment are insufficient in many cases. For instance, curing of the large virulence plasmid of Salmonella Enteritidis 2,102 has failed when these treatments were applied. To overcome the difficulties, a two-step transposon-based curing method has been developed. First, a Tn10-based transposable unit carrying a Km(R) marker gene and the joined IS30 ends transposes from a replication deficient conjugative plasmid into the target replicon. Then, the inducible IS30 transposase, using the highly reactive joined IS30 ends, mediates deletions or gives rise to the loss of the target plasmid. The efficiency of the method has been monitored by the frequency of Km(S) colonies after induction of IS30 transposase, and it was shown that the Km(S) phenotype often accompanied the complete loss of the virulence plasmid or the formation of deletion derivatives. The procedure has been successfully applied also in removing the large virulence plasmid from enterotoxigenic Escherichia coli (ETEC O147), suggesting that the transposon-based method can be a useful tool for eliminating native plasmids in several bacteria.

Analysis of the N-terminal DNA binding domain of the IS30 transposase

IS30 is the founding member of a large family of widely spread bacterial insertion sequences with closely related transposases. The N-terminal end of the IS30 transposase had been shown to retain sequence-specific DNA binding activity and to protect the IS30 terminal inverted repeats. Structural predictions revealed the presence of a helix-helix-turn-helix motif (H-HTH2) which, in the case of IS30, is preceded by an additional helix-turn-helix motif (HTH1). Analysis of deletion and point mutants in this region revealed that both motifs are important for IS30 transposition. IS30 exhibits two types of insertion specificity preferring either a 24 bp palindromic hot-spot (GOHS) or sequences resembling its ends [left and right terminal inverted repeat (IRL and IRR)]. Results are presented suggesting that the HTH1 region is required for GOHS targeting and interferes with the inverted repeat (IR) targeting. On the other hand, H-HTH2 appears to be required for both. The binding activities of the mutant proteins to the terminal IS30 IRs as measured by gel retardation correlated well with these results. Furthermore, close inspection of the H-HTH2 region revealed significant amino acid identity with a similar predicted secondary structure carried by the transcriptional regulator FixJ of Sinorhizobium meliloti and involved in FixJ binding to its target sequence. This suggests that FixJ and IS30 transposase share similar sequence-specific DNA binding mechanisms.

Regulation of transposition in bacteria

Mobile genetic elements (MGEs) play a central role in the evolution of bacterial genomes. Transposable elements (TE: transposons and insertion sequences) represent an important group of these elements. Comprehension of the dynamics of genome evolution requires an understanding of how the activity of TEs is regulated and how their activity responds to the physiology of the host cell. This article presents an overview of the large range of, often astute, regulatory mechanisms, which have been adopted by TEs. These include mechanisms intrinsic to the element at the level of gene expression, the presence of key checkpoints in the recombination pathway and the intervention of host proteins which provide a TE/host interface. The multiplicity and interaction of these mechanisms clearly illustrates the importance of limiting transposition activity and underlines the compromise that has been reached between TE activity and the host genome. Finally, we consider how TE activity can shape the host genome.

The left end of IS2: a compromise between transpositional activity and an essential promoter function that regulates the transposition pathway

Cut-and-paste (simple insertion) and replicative transposition pathways are the two classical paradigms by which transposable elements are mobilized. A novel variation of cut and paste, a two-step transposition cycle, has recently been proposed for insertion sequences of the IS3 family. In IS2 this variation involves the formation of a circular, putative transposition intermediate (the minicircle) in the first step. Two aspects of the minicircle may involve its proposed role in the second step (integration into the target). The first is the presence of a highly reactive junction formed by the two abutted ends of the element. The second is the assembly at the minicircle junction of a strong hybrid promoter which generates higher levels of transposase. In this report we show that IS2 possesses a highly reactive minicircle junction at which a strong promoter is assembled and that the promoter is needed for the efficient completion of the pathway. We show that the sequence diversions which characterize the imperfect inverted repeats or ends of this element have evolved specifically to permit the formation and optimal function of this promoter. While these sequence diversions eliminate catalytic activity of the left end (IRL) in the linear element, sufficient sequence information essential for catalysis is retained by the IRL in the context of the minicircle junction. These data confirm that the minicircle is an essential intermediate in the two-step transposition pathway of IS2.

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.

Elements for a theory of molecular evolution

Biological evolution is known to be driven by the availability of genetic variants. Spontaneous genetic variation can be the result of a number of specific molecular mechanisms. These can be grouped into three qualitatively different natural strategies of generating genetic variations, namely local sequence changes, DNA rearrangement within the genome and horizontal gene transfer, which is referred to here as DNA acquisition. All of these strategies bring about alterations in the DNA sequences of the genome, thus corresponding to the molecular genetic definition of the term mutation. A detailed inspection of specific mechanisms of mutagenesis reveals on the one hand the impact of non-genetic internal and environmental factors, and on the other hand the specific involvement of gene products. The underlying so-called evolution genes can be classified into generators of genetic variations and into modulators of the frequency of genetic variation. These evolution genes are postulated to have themselves undergone biological evolution under the pressure of second-order selection. On the basis of a few selected examples of mutagenesis, elements for a theory of molecular evolution are collected without a claim for completeness. Philosophical dimensions as well as practical aspects of the advanced knowledge on specific molecular mechanisms involved in molecular evolution are also briefly discussed.

Transposition and targeting of the prokaryotic mobile element IS30 in zebrafish

We provide evidence that a prokaryotic insertion sequence (IS) element is active in a vertebrate system. The transposase of Escherichia coli element IS30 catalyzes both excision and integration in extrachromosomal DNA in zebrafish embryos. The transposase has a pronounced target preference, which is shown to be modified by fusing the enzyme to unrelated DNA binding proteins. Joining the transposase to the cI repressor of phage lambda causes transposition primarily into the vicinity of the lambda operator in E. coli, and linking to the DNA binding domain of Gli1 also directs the recombination activity of transposase near to the Gli1 binding site in zebrafish. Our results demonstrate the possibility of fusion transposases to acquire novel target specificity in both prokaryotes and eukaryotes.

Detection and analysis of transpositionally active head-to-tail dimers in three additional Escherichia coli IS elements

This study demonstrates that Escherichia coli insertion elements IS3, IS150 and IS186 are able to form transpositionally active head-to-tail dimers which show similar structure and transpositional activity to the dimers of IS2, IS21 and IS30. These structures arise by joining of the left and right inverted repeats (IRs) of two elements. The resulting junction includes a spacer region (SR) of a few base pairs derived from the flanking sequence of one of the reacting IRs. Head-to-tail dimers of IS3, IS150 and IS186 are unstable due to their transpositional activity. They can be resolved in two ways that seem to form a general rule for those elements reported to form dimers. One way is a site-specific process (dimer dissolution) which is accompanied by the loss of one IS copy along with the SR. The other is 'classical' transposition where the joined ends integrate into the target DNA. In intramolecular transposition this often gives rise to deletion formation, whereas in intermolecular transposition it gives rise to replicon fusion. The results presented for IS3, IS150 and IS186 are in accordance with the IS dimer model, which is in turn consistent with models based on covalently closed minicircles.

Transposase-dependent formation of circular IS256 derivatives in Staphylococcus epidermidis and Staphylococcus aureus

IS256 is a highly active insertion sequence (IS) element of multiresistant staphylococci and enterococci. Here we show that, in a Staphylococcus epidermidis clinical isolate, as well as in recombinant Staphylococcus aureus and Escherichia coli carrying a single IS256 insertion on a plasmid, IS256 excises as an extrachromosomal circular DNA molecule. First, circles were identified that contained a complete copy of IS256. In this case, the sequence connecting the left and right ends of IS256 was derived from flanking DNA sequences of the parental genetic locus. Second, circle junctions were detected in which one end of IS256 was truncated. Nucleotide sequencing of circle junctions revealed that (i) either end of IS256 can attack the opposite terminus and (ii) the circle junctions vary significantly in size. Upon deletion of the IS256 open reading frame at the 3' end and site-directed mutageneses of the putative DDE motif, circular IS256 molecules were no longer detectable, which implicates the IS256-encoded transposase protein with the circularization of the element.

Diversity of Tn4001 transposition products: the flanking IS256 elements can form tandem dimers and IS circles

We show that both flanking IS256 elements carried by transposon Tn4001 are capable of generating head-to-tail tandem copies and free circular forms, implying that both are active. Our results suggest that the tandem structures arise from dimeric copies of the donor or vector plasmid present in the population by a mechanism in which an IS256 belonging to one Tn4001 copy attacks an IS256 end carried by the second Tn4001 copy. The resulting structures carry abutted left (inverted left repeat [IRL]) and right (inverted right repeat [IRR]) IS256 ends. Examination of the junction sequence suggested that it may form a relatively good promoter capable of driving transposase synthesis in Escherichia coli. This behavior resembles that of an increasing number of bacterial insertion sequences which generate integrative junctions as part of the transposition cycle. Sequence analysis of the IRL-IRR junctions demonstrated that attack of one end by the other is largely oriented (IRL attacks IRR). Our experiments also defined the functional tips of IS256 as the tips predicted from sequence alignments, confirming that the terminal 4 bp at each end are indeed different. The appearance of these multiple plasmid and transposon forms indicates that care should be exercised when Tn4001 is used in transposition mutagenesis. This is especially true when it is used with naturally transformable hosts, such as Streptococcus pneumoniae, in which reconstitution of the donor plasmid may select for higher-order multimers.

Transient promoter formation: a new feedback mechanism for regulation of IS911 transposition

IS911 transposition involves a free circular transposon intermediate where the terminal inverted repeat sequences are connected. Transposase synthesis is usually driven by a weak promoter, p(IRL), in the left end (IRL). Circle junction formation creates a strong promoter, p(junc), with a -35 sequence located in the right end and the -10 sequence in the left. p(junc) assembly would permit an increase in synthesis of transposase from the transposon circle, which would be expected to stimulate integration. Insertion results in p(junc) disassembly and a return to the low p(IRL)- driven transposase levels. We demonstrate that p(junc) plays an important role in regulating IS911 transposition. Inactivation of p(junc) strongly decreased IS911 transposition when transposase was produced in its natural configuration. This novel feedback mechanism permits transient and controlled activation of integration only in the presence of the correct (circular) intermediate. We have also investigated other members of the IS3 and other IS families. Several, but not all, IS3 family members possess p(junc) equivalents, underlining that the regulatory mechanisms adopted to fine-tune transposition may be different.

Isolation and characterization of IS1409, an insertion element of 4-chlorobenzoate-degrading Arthrobacter sp. strain TM1, and development of a system for transposon mutagenesis

A new insertion element of 1,449 bp with 25-bp perfect terminal repeats, designated IS1409, was identified in the chromosome of 4-chlorobenzoate-degrading Arthrobacter sp. strain TM1 NCIB12013. Upon insertion, IS1409 causes a target duplication of 8 bp. IS1409 carries only a single open reading frame of 435 codons encoding the transposase TnpA. Both TnpA and the overall organization of IS1409 are highly similar to those of some related insertion elements of the ISL3 group (J. Mahillon and M. Chandler, Microbiol. Mol. Biol. Rev. 62:725--774, 1998). IS1409 was also found in other 4-chlorobenzoate-degrading Arthrobacter strains and Micrococcus luteus. Based on IS1409, a series of transposons carrying resistance genes for chloramphenicol and gentamicin were constructed. These transposons were used to demonstrate transposition events in vivo and to mutagenize Arthrobacter sp. strains.

Common elements of spiroplasma plectroviruses revealed by nucleotide sequence of SVTS2

DNA of SpV1-like spiroplasma plectroviruses (rods with single-stranded circular DNA) is scattered in the genome of the phytopathogen Spiroplasma citri and has significant consequences for evolution of the S. citri genome. We determined the complete nucleotide sequence of SVTS2, a SpV1-like virus of S. melliferum, a honeybee pathogen, to ascertain, by comparison with S. citri SpV1 viruses (GenBank U28974 and X51344), the defining features of this important group. The 6,824 nt DNA contains nine ORFs homologous to ORFs of S. citri SpV1 viruses and five ORFs unique to SVTS2. The predicted amino acid sequences of the homologous ORFs were 17-38% identical to those of their S. citri counterparts. The SVTS2 predicted ORF 1 product (Mr 47,031) was considerably smaller than those of known S. citri SpV1 viruses. Also, in contrast to those viruses, SVTS2 lacked an ORF with recognizable similarity to a transposase. ORF 2 of all three viruses had a homologue among the products of genes of MVL-1, a virus of Acholeplasma laidlawii, another plectrovirus. The results suggest that, at most, only slightly more than half of SpV1 genomes consists of genes shared by all spiroplasma viruses of the group.

The role of tandem IS dimers in IS911 transposition

Using a combined in vivo and in vitro approach, we demonstrated that the transposition products generated by IS911 from a dimeric donor plasmid are different from those generated from a plasmid monomer. When carried by a monomeric plasmid donor, free IS911 transposon circles are generated by intra-IS recombination in which one IS end undergoes attack by the other. These represent transposition intermediates that undergo integration using the abutted left (IRL) and right (IRR) ends of the element, the active IRR-IRL junction, to generate simple insertions. In contrast, the two IS911 copies carried by a dimeric donor plasmid not only underwent intra-IS recombination to generate transposon circles but additionally participated in inter-IS recombination. This also creates an active IRR-IRL junction by generating a head-to-tail IS tandem dimer ([IS]2) in which one of the original plasmid backbone copies is eliminated in the formation of the junction. Both transposon circles and IS tandem dimers are generated from an intermediate in which two transposon ends are retained by a single strand joint to generate a figure 8 molecule. Inter-IS figure 8 molecules generated in vitro could be resolved into the [IS]2 form following introduction into a host strain by transformation. Resolution did not require IS911 transposase. The [IS]2 structure was stable in the absence of transposase but was highly unstable in its presence both in vivo and in vitro. Previous studies had demonstrated that the IRR-IRL junction promotes efficient intermolecular integration and intramolecular deletions both in vivo and in vitro. Integration of the [IS]2 derivative would result in a product that resembles a co-integrate structure. It is also shown here that the IRR-IRL junction of the [IS]2 form and derivative structures can specifically target one of the other ends in an intramolecular transposition reaction to generate transposon circles in vitro. These results not only demonstrate that IS911 (and presumably other members of the IS3 family) is capable of generating a range of transposition products, it also provides a mechanistic framework which explains the formation and activity of such structures previously observed for several other unrelated IS elements. This behaviour is probably characteristic of a large number of IS elements.

Integrating DNA: transposases and retroviral integrases

Transposable elements appear quite disparate in their organization and in the types of genetic rearrangements they promote. In spite of this diversity, retroviruses and many transposons of both prokaryotes and eukaryotes show clear similarities in the chemical reactions involved in their transposition. This is reflected in the enzymes, integrases and transposases, that catalyze these reactions and that are essential for the mobility of the elements. In this chapter, we examine the structure-function relationships between these enzymes and the different ways in which the individual steps are assembled to produce a complete transposition cycle.

Importance of illegitimate recombination and transposition in IS30-associated excision events

In the present study we report on the excision of IS30 elements and IS30-derived composite transposons. Frequent loss of IS30 was observed during dissolution of dimeric IS30 structures, containing IR-IR junctions, leading to resealed donor molecules. In contrast, unambiguous transpositional excision resulting in resealed remainder products could not be identified in the case of a monomeric element. The bias in the excision of monomeric and dimeric IS30 structures indicates a difference in the molecular mechanism of transposition of IS30 monomers and dimers. Sequence data on the rarely detected plasmids missing full IS or Tn copies rather suggest that all products were derived from illegitimate recombination. The reaction occurred between short homologies and was independent of the transposase activity. Similar IS30 excision events accompanied by multiple plasmid or genome rearrangements were detected in Pseudomonas putida and Rhizobium meliloti, yielding stable replicons that retained the selective marker gene of the transposon. We provide evidence that both transposition and illegitimate recombination can contribute to the stabilization of replicons through the elimination of IS elements, which emphasizes the evolutionary significance of these events.

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.

Mechanisms of spiroplasma genome variation associated with SpV1-like viral DNA inferred from sequence comparisons

Genomes of Spiroplasma citri strains have rearranged frequently during their evolution, partly due to multiple integrated sequences of spiroplasma viruses. To understand better the role of viral sequences in genome evolution, we examined available nucleotide sequences of viruslike elements in the S. citri chromosome. Comparison of integrated and nonintegrated sequences of spiroplasma virus SpV1-C74 DNA suggested that it is an encapsidated form of the circular transposition intermediate belonging to an insertion sequence (IS3) family member. One SpV1-C74 viral DNA fragment was identified as interrupting the remains of a DNA adenine modification methylase gene. A viral DNA insertion of SpV1-R8A2 B DNA had hallmarks of having suffered an internal deletion by a site-specific recombination system. Homologous recombination likely was responsible for several deletions within viral DNA. A homologous recombination event was inferred between part of a viral DNA insertion and a similar chromosomal sequence. Dispersed sequences from SpV1-like C4 open reading frames (ORFs) were identified as involved in a complex deletion-inversion event. Thus, SpV1-like sequences likely have altered spiroplasma genomes by inserting within active genes, destroying their function, by providing targets for site-specific recombination, by mediating deletions of sequences adjacent to their integration sites, and by providing targets for homologous recombination, leading to inversions.

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.

Interaction of Azospirillum lipoferum with wheat germ agglutinin stimulates nitrogen fixation

In vitro, the nitrogen fixation capability of A. lipoferum is efficiently increased in the presence of wheat germ agglutinin (WGA). A putative WGA-binding receptor, a 32-kDa protein, was detected in the cell capsule. The stimulatory effect required N-acetyl-D-glucosamine dimer (GlcNAcdi) terminated sugar side chains of the receptor and was dependent on the number of GlcNAcdi links involved in receptor-WGA interface. Binding to the primary sugar binding sites on WGA had a larger stimulatory effect than binding to the secondary sites. The WGA-receptor complex generated stimulus led to elevated transcription of the nifH and nifA genes and of the glnBA gene cluster but not of the glnA gene from its own promoter. There may well be a signalling cascade contributing to the regulation of nitrogen fixation.

Involvement of gene products in bacterial evolution

Three strategies of different quality contribute in parallel to the natural formation of genetic variants in bacteria: (1) small local alterations of DNA sequences; (2) recombinational reshuffling of segments of the genome; and (3) acquisition of DNA sequences by horizontal gene transfer. Key enzymes involved in these processes often act as variation generators by making use of structural flexibilities of biological macromolecules and of the effect of random encounter. In the theory of molecular evolution, genetic determinants of variation generators as well as of modulators of the frequency of genetic variation are defined as evolutionary genes. This postulate is consistent with the notion that spontaneous mutagenesis is in general not adaptive and that the direction of evolution depends on natural selection exerted on populations of genetic variants.

Evidence that Tn5565, which includes the enterotoxin gene in Clostridium perfringens, can have a circular form which may be a transposition intermediate

The Clostridium perfringens enterotoxin gene is on a transposon-like element, Tn5565, integrated in the chromosome in human food poisoning strains. The flanking IS elements, IS1470 A and B, are related to IS30. The IS element found in the transposon, IS1469, is related to IS200 and has been found upstream of cpe in all Type A strains. PCR and sequencing studies from cell extracts and plasmid isolations of C. perfringens indicate that Tn5565 can form a circular form with the tandem repeat (IS1470)2, similar to the transposition intermediates described for a number of IS elements.

Cointegrase, a naturally occurring, truncated form of IS21 transposase, catalyzes replicon fusion rather than simple insertion of IS21

The bacterial insertion sequence IS21 contains two genes, istA and istB, which are organized as an operon. IS21 spontaneously forms tandem repeats designated (IS21)2. Plasmids carrying (IS21)2 react efficiently with other replicons, producing cointegrates via a cut-and-paste mechanism. Here we show that transposition of a single IS21 element (simple insertion) and cointegrate formation involving (IS21)2 result from two distinct non-replicative pathways, which are essentially due to two differentiated IstA proteins, transposase and cointegrase. In Escherichia coli, transposase was characterized as the full-length, 46 kDa product of the istA gene, whereas the 45 kDa cointegrase was expressed, in-frame, from a natural internal translation start of istA. The istB gene, which could be experimentally disconnected from istA, provided a helper protein that strongly stimulated the transposase and cointegrase-driven reactions. Site-directed mutagenesis was used to express either cointegrase or transposase from the istA gene. Cointegrase promoted replicon fusion at high frequencies by acting on IS21 ends which were linked by 2, 3, or 4 bp junction sequences in (IS21)2. By contrast, cointegrase poorly catalyzed simple insertion of IS21 elements. Transposase had intermediate, uniform activity in both pathways. The ability of transposase to synapse two widely spaced IS21 ends may reside in the eight N-terminal amino acid residues which are absent from cointegrase. Given the 2 or 3 bp spacing in naturally occurring IS21 tandems and the specialization of cointegrase, the fulminant spread of IS21 via cointegration can now be understood.

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.

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.

New Bradyrhizobium japonicum strains that possess high copy numbers of the repeated sequence RS alpha

In a survey of DNA fingerprints of indigenous Bradyrhizobium japonicum with the species-specific repeated sequences RS alpha and RS beta, 21 isolates from three field sites showed numerous RS-specific hybridization bands. The isolates were designated highly reiterated sequence-possessing (HRS) isolates, and their DNA hybridization profiles were easily distinguished from the normal patterns. Some HRS isolates from two field sites possessed extremely high numbers of RS alpha copies, ranging from 86 to 175 (average, 128), and showed shifts and duplications of nif- and hup-specific hybridization bands. The HRS isolates exhibited slower growth than normal isolates, although no difference in symbiotic properties was detected between the HRS and normal isolates. Nucleotide sequence analysis of 16S rRNA genes showed that HRS isolates were strains of B. japonicum. There was no difference in the spectra of serological and hydrogenase groupings of normal and HRS isolates. Some HRS isolates possessed a tandem repeat RS alpha dimer that is similar to the structure of (IS30)2, which was shown to cause a burst of transpositional rearrangements in Escherichia coli. The results suggest that HRS isolates are derived from normal isolates in individual fields by genome rearrangements that may be mediated by insertion sequences such as RS alpha.

Efficient transposition of IS911 circles in vitro

An in vitro system has been developed which supports efficient integration of transposon circles derived from the bacterial insertion sequence IS911. Using relatively pure preparations of IS911-encoded proteins it has been demonstrated that integration into a suitable target required both the transposase, OrfAB, a fusion protein produced by translational frameshifting between two consecutive open reading frames, orfA and orfB, and OrfA, a protein synthesized independently from the upstream orfA. Intermolecular reaction products were identified in which one or both transposon ends were used. The reaction also generated various intramolecular transposition products including adjacent deletions and inversions. The circle junction, composed of abutted left and right IS ends, retained efficient integration activity when carried on a linear donor molecule, demonstrating that supercoiling in the donor molecule is not necessary for the reaction. Both two-ended integration and a lower level of single-ended insertions were observed under these conditions. The frequency of these events depended on the spacing between the transposon ends. Two-ended insertion was most efficient with a natural spacing of 3 bp. These results demonstrate that transposon circles can act as intermediates in IS911 transposition and provide evidence for collaboration between the two major IS911-encoded proteins, OrfA and OrfAB.

Efficient transposition of IS911 circles in vitro

An in vitro system has been developed which supports efficient integration of transposon circles derived from the bacterial insertion sequence IS911. Using relatively pure preparations of IS911-encoded proteins it has been demonstrated that integration into a suitable target required both the transposase, OrfAB, a fusion protein produced by translational frameshifting between two consecutive open reading frames, orfA and orfB, and OrfA, a protein synthesized independently from the upstream orfA. Intermolecular reaction products were identified in which one or both transposon ends were used. The reaction also generated various intramolecular transposition products including adjacent deletions and inversions. The circle junction, composed of abutted left and right IS ends, retained efficient integration activity when carried on a linear donor molecule, demonstrating that supercoiling in the donor molecule is not necessary for the reaction. Both two-ended integration and a lower level of single-ended insertions were observed under these conditions. The frequency of these events depended on the spacing between the transposon ends. Two-ended insertion was most efficient with a natural spacing of 3 bp. These results demonstrate that transposon circles can act as intermediates in IS911 transposition and provide evidence for collaboration between the two major IS911-encoded proteins, OrfA and OrfAB.

An antisense RNA in IS30 regulates the translational expression of the transposase

Two functional promoters had previously been identified in the mobile genetic element IS30 of Escherichia coli. One, P30A, controls the transcription of ORF-A, whose product is the transposase; the other, located within the ORF-A sequence but on the opposite strand, is called P30C, but the nature and function of its product had remained unknown. We identified this product as an RNA about 150 nucleotides long (called RNA-C) that functions as an untranslated antisense transcript. Indeed, biochemical evidence indicates that ORF-C, which is completely contained on RNA-C, is not translated at detectable levels. Mutational analysis of P30C revealed that overproduction of RNA-C resulted in a decrease of IS30 transposition, while a reduction in the promoter strength resulted in an increase of transposition, as measured by the rate of cointegrate formation. We showed that the translation of ORF-A, but not transcription, is negatively affected by the presence of antisense RNA-C. In contrast to other antisense RNAs acting inhibitorily on translation, RNA-C does not seem to affect translation initiation. Most likely its hybridization to the transposase mRNA in the complementary region located in the central part of ORF-A inhibits the ribosomes in their progression, thus reducing the number of completely translated transposase molecules.

Terminal inverted repeats of insertion sequence IS30 serve as targets for transposition

In the present study, we demonstrate that the terminal inverted repeats of the Escherichia coli insertion sequence IS30 are functional target sites for the transposition of the (IS30)2 dimer, which represents an intermediate structure in the transposition of IS30. Comparative analysis of various target regions revealed that the left and right ends differ in their "attractivity." In our experiments, the joined left and right ends, i.e., the (IS30)2 intermediate structure, was found to be the most preferred target. It was also shown that flanking sequences can influence the target activity of the terminal repeats. The functional part of the target region was localized in the inverted repeats by means of mutational analysis, and it corresponds to the binding site of IS30 transposase. Insertion of 1 bp into the right inverted repeat resulted in unusual target duplication accompanied by gene conversion. The choice of the terminal inverted repeats as targets in transposition leads to the reconstruction of the (IS30)2 structure, which may induce a cascade of further rearrangements. Therefore, this process can play a role in the evolution of the genome.

Mutations in the carboxy-terminal part of IS30 transposase affect the formation and dissolution of (IS30)2 dimer

The transposase of IS30 catalyses different transpositional rearrangements via the dimer (IS30)2 intermediate structure. Mutation analysis provides evidence that the C-terminal part of IS30 transposase is required for the formation and dissolution of (IS30)2 dimer. C-terminal mutants are also defective in transpositional fusion; however, this deficiency can be 'suppressed' by addition of the final product of site-specific dimerisation, the core (IS30)2 intermediate structure. The transposase part studied shows significant homologies in three highly conserved regions to proteins of IS30-related mobile elements.

The Clostridium perfringens enterotoxin gene is on a transposable element in type A human food poisoning strains

The Clostridium perfringens enterotoxin gene (cpe) is rarely found in naturally isolated strains. In human food poisoning strains, cpe is found on the chromosome, and is located episomally in animal isolates. Observations that the gene was somewhat unstable and could be gained or lost suggested that the gene was on a mobile element. An IS200-like element, IS1469, is almost always upstream of cpe. A new insertion element was identified, IS1470, a member of the IS30 family, which is found both up-an downstream of cpe in the type A strain NCTC 8239. PCR results confirmed that this configuration was conserved in type A human food poisoning strains. The enterotoxin gene was on a 6.3 kb transposon which, in addition to the two flanking copies of IS1470, included IS1469 and two 1 kb stretches, one on each side of cpe, with no open reading frames. Results indicated that 14 bp was copied from the genome during insertion. Details of the configuration of DNA in this transposon are presented, and the possible connection of this transposon with the movement of the enterotoxin gene is discussed.