The terminal inverted repeats of IS911: requirements for synaptic complex assembly and activity

The bacterial insertion sequence IS911 transposes via a covalently closed circular intermediate. Circle formation involves transposase-mediated pairing of both insertion sequence ends. While full-length transposase, OrfAB, binds poorly in vitro to IS911 DNA fragments carrying a copy of the IS911 end, truncated protein derivatives carrying the first 135 (OrfAB[1-135]) or 149 (OrfAB[1-149]) amino acid residues bind efficiently. They generate a paired-end complex containing two such fragments which resembles that expected for the first synaptic complex. Shorter protein derivatives lacking a region involved in multimerisation do not form these complexes but modify the binding of OrfAB[1-135] and OrfAB[1-149]. DNaseI footprinting demonstrated that OrfAB[1-149] protects a sub-terminal (internal) region of the inverted repeats which includes two blocks of sequence (beta and gamma) conserved between the left (IRL) and right (IRR) ends. DNA binding assays in vitro and measurement of recombination activity in vivo of sequential deletion derivatives of the two inverted repeats suggested a model in which the N-terminal region of OrfAB binds the conserved boxes beta and gamma in a sequence-specific manner and anchors the two insertion sequence ends into a paired-end complex. The external region of the inverted repeat is proposed to contact the C-terminal transposase domain carrying the catalytic site.     

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.     

IS911 transposition is regulated by protein-protein interactions via a leucine zipper motif

Efficient intermolecular transposition of bacterial insertion sequence IS911 involves the activities of two element-encoded proteins: the transposase, OrfAB, and a regulatory factor, OrfA. OrfA shares the majority of its amino acid sequence with the N-terminal part of OrfAB. This includes a putative helix-turn-helix and three of four heptads of a leucine zipper motif. OrfA strongly stimulates OrfAB-mediated intermolecular transposition both in vivo and in vitro. The present results support the notion that this is accomplished by direct interaction between these two proteins via the leucine zipper. We used both a genetic approach, based on gene fusions with phage lambda repressor, and a physical approach, involving co-immunoprecipitation, to show that OrfA not only undergoes oligomerisation but is capable of engaging with OrfAB to form heteromultimers, and that the leucine zipper is necessary for both types of interaction. Furthermore, mutation of the leucine zipper in OrfA inactivated its regulatory function. Previous observations demonstrated that the integrity of the leucine zipper motif was also important for OrfAB binding to the IS911 terminal inverted repeats. Here, we show, in gel shift experiments, using a derivative of OrfAB deleted for the C-terminal catalytic domain, OrfAB[1-149], that the protein is capable of pairing two inverted repeats to generate a species resembling a "synaptic complex". Preincubation of OrfAB[1-149] with OrfA dramatically reduced formation of this complex and favored formation of an alternative complex devoid of OrfA. Together these results suggest that OrfA exerts its regulatory effect by interacting transiently with OrfAB via the leucine zipper and modifying OrfAB binding to the inverted repeats.     

A target specificity switch in IS911 transposition: the role of the OrfA protein

The role played by insertion sequence IS911 proteins, OrfA and OrfAB, in the choice of a target for insertion was studied. IS911 transposition occurs in several steps: synapsis of the two transposon ends (IRR and IRL); formation of a figure-of-eight intermediate where both ends are joined by a single-strand bridge; resolution into a circular form carrying an IRR-IRL junction; and insertion into a DNA target. In vivo, with OrfAB alone, an IS911-based transposon integrated with high probability next to an IS911 end located on the target plasmid. OrfA greatly reduced the proportion of these events. This was confirmed in vitro using a transposon with a preformed IRR-IRL junction to examine the final insertion step. Addition of OrfA resulted in a large increase in insertion frequency and greatly increased the proportion of non-targeted insertions. The intermolecular reaction leading to targeted insertion may resemble the intramolecular reaction involving figure-of-eight molecules, which leads to the formation of circles. OrfA could, therefore, be considered as a molecular switch modulating the site-specific recombination activity of OrfAB and facilitating dispersion of the insertion sequence (IS) to 'non-homologous' target sites.     

Two abundant intramolecular transposition products, resulting from reactions initiated at a single end, suggest that IS2 transposes by an unconventional pathway

The Escherichia coli insertion sequence, IS 2 , is a member of the IS 3 family of bacterial transposable elements. Its transposase is a fusion protein, OrfAB, made by a programmed −1 translational frameshift near to the end of orfA and just after the start of orfB . We have characterized two major products of IS 2 intramolecular transposition, which accumulate in cells that express the IS 2 OrfAB fusion protein at elevated levels. The more abundant product is a minicircle composed of the complete IS 2 with just a single basepair (occasionally 2 bp) separating the two IS ends. In all cases, this basepair is derived from the vector sequence immediately adjacent to the left IS 2 end (IRL). The second product is a figure-eight molecule that contains all the IS 2 and vector sequences present in the parental plasmid. One DNA strand contains the parental sequences unrearranged. The other contains a single-stranded version of the minicircle junction — the precise 3' end of IRR has been cleaved and joined to a target just outside the 5' end of IRL; the remaining vector sequences have a free 5' end, derived from cleavage at the 3' end of IRR, and a free 3' end, released upon cleavage of the target site adjacent to IRL. We propose that figure-eight molecules are the precursor to IS 2 minicircles and that the formation of these two products is the initial step in IS 2 intermolecular transposition. This proposed transposition pathway provides a means for a transposase that can cleave only one strand at each IS end to produce simple insertions and avoid forming co-integrates.     

Isolation of a new insertion sequence, IS13655, and its application to Corynebacterium glutamicum genome mutagenesis

A new functional Corynebacterium glutamicum insertion sequence (IS) element, IS13655, was isolated using a suicide vector. The IS element was 1,293 bp in size and contained 26-bp imperfect inverted repeats (IRs) and 3-bp target site duplication as direct repeats (DRs). IS13655 harbored two ORFs with high similarity to the transposase of IS1206, an IS3 family element. IS13655 revealed relatively high transposition efficiency, with low target site selectivity along the Corynebacterium glutamicum R genome, making it a potentially useful genetic engineering tool.     

Control of IS911 target selection: how OrfA may ensure IS dispersion

IS911 transposition involves a closed circular insertion sequence intermediate (IS-circle) and two IS-encoded proteins: the transposase OrfAB and OrfA which regulates IS911 insertion. OrfAB alone promotes insertion preferentially next to DNA sequences resembling IS911 ends while the addition of OrfA strongly stimulates insertion principally into DNA targets devoid of the IS911 end sequences. OrfAB shares its N-terminal region with OrfA. This includes a helix-turn-helix (HTH) motif and the first three of four heptads of a leucine zipper (LZ). OrfAB binds specifically to IS911 ends via its HTH whereas OrfA does not. We show here: that OrfA binds DNA non-specifically and that this requires the HTH; that OrfA LZ is required for its multimerization; and that both motifs are essential for OrfA activity. We propose that these OrfA properties are required to assemble a nucleoprotein complex committed to random IS911 insertion. This control of IS911 insertion activity by OrfA in this way would assure its dispersion.     

The Sinorhizobium meliloti Insertion Sequence (IS) Element ISRm14 Is Related to a Previously Unrecognized IS Element Located Adjacent to the Escherichia coli Locus of Enterocyte Effacement (LEE) Pathogenicity Island

ISRm14 is 2695 basepairs (bp) in size and bordered by 22 bp imperfect inverted repeats (IRs). A 9-bp target sequence is duplicated upon ISRm14 transposition. The DNA strand that putatively encodes the transposase enzyme carries three open reading frames (ORFs) designated ORFs1 to 3, which specify putative proteins of 15.9 kDa, 13.1 kDa, and 61.1 kDa, respectively. According to its structural characteristics, ISRm14 belongs to the recently proposed IS66 family of IS elements. The ORFs1 to 3 encoded putative proteins displayed significant similarities to ORFs of the previously unrecognized IS element ISEc8, which is inserted adjacent to the locus of enterocyte effacement (LEE) pathogenicity island of Escherichia coli EDL933. Analyses of the distribution of ISRm14 in a natural S. meliloti population showed its widespread occurrence in 66% of the strains tested with a copy number ranging from 1 to 6. Received: 13 May 1999 / Accepted: 14 June 1999     

Truncated forms of IS911 transposase downregulate transposition

IS911 naturally produces transposase (OrfAB) derivatives truncated at the C-terminal end (OrfAB-CTF) and devoid of the catalytic domain. A majority species, OrfAB*, was produced at higher levels at 42 degrees C than at 30 degrees C suggesting that it is at least partly responsible for the innate reduction in IS911 transposition activity at higher temperatures. An engineered equivalent of similar length, OrfAB[1-149], inhibited transposition activity in vivo or in vitro when produced along with full-length transposase. We isolated several point mutants showing higher activity than the wild-type IS911 at 42 degrees C. These fall into two regions of the transposase. One, located in the N-terminal segment of OrfAB, lies between or within two regions involved in protein multimerization. The other is located within the C-terminal catalytic domain. The N-terminal mutations resulted in reduced levels of OrfAB* while the C-terminal mutation alone appeared not to affect OrfAB* levels. Combination of N- and C-terminal mutations greatly reduced OrfAB* levels and transposition was concomitantly high even at 42 degrees C. The mechanism by which truncated transposase species are generated and how they intervene to reduce transposition activity is discussed. While transposition activity of these multiply mutated derivatives in vivo was resistant to temperature, the purified OrfAB derivatives retained an inherent temperature-sensitive phenotype in vitro. This clearly demonstrates that temperature sensitivity of IS911 transposition is a complex phenomenon with several mechanistic components. These results have important implications for the several other transposons and insertion sequences whose transposition has also been shown to be temperature-sensitive.     

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.     

IS1-encoded proteins,InsA and the InsA-B′-InsB transframe protein (transposase): Functions deduced from their DNA-binding ability

Insertion sequence IS1 encodes a transframe protein, InsA-B′-InsB, which is produced from two out-of-phase reading frames, insA and B′-insB, by translational frameshifting at a run of adenines. Unless the frameshifting event occurs, the InsA protein is produced from IS1. We found that cells harboring a plasmid carrying an IS1 mutant with a single adenine insertion in the run of adenines contained miniplasmids. Cloning and DNA sequencing analyses of the miniplasmids revealed that they had a deletion extending from an inverted repeat (IR) at the left end of IS1. This indicates that they were generated by IS1-mediated deletion due to efficient production of the InsA-B′-InsB transframe protein that is IS1 transposase. Both the InsA protein and transposase were partially purified as a fusion protein with collagen-LacZ by LacZ-specific affinity column chromatography. The InsA¹ and the collagenolyzed InsA¹ were found to bind specifically to a 24-bp region within each of the IRs at the ends of IS1. The transposase Tnp¹ and the collagenolyzed Tnp¹ were found to bind to the sequence with or without IR, but preferentially to that with IR. The nonspecific DNA-binding ability of transposase may be involved in recognition of the target DNA, an important process of transposition of IS1. Both InsA and transposase have the IR-specific DNA binding ability and a common polypeptide segment containing the α-helix-turn-α-helix motif, supporting the previous indication that InsA competes with transposase to bind to IRs and thus becomes a transposition inhibitor. Based on the observations described in this article, we speculate that transposase of IS1 consists of at least two domains, the N-terminal half, which almost entirely overlaps InsA, and the C-terminal half, which almost entirely overlaps B′-InsB. The frameshifting event adds the latter domain to the former to give the transposase activity recognizing IRs and the target sequence to initiate the transposition reaction.     

IS911-mediated intramolecular transposition is naturally temperature sensitive

It is shown here that the bacterial insertion sequence IS 911 exhibits a temperature-sensitive transposition phenotype. Previous results have demonstrated that elevated levels of the IS 911 transposase OrfAB generate significant quantities of a figure-eight form, created by cleavage and circularization of one of the transposon strands, and of an excised circular form, in which both transposon strands have been circularized. We show here that the level of both types of molecule observed in vivo was greatly reduced at 42°C compared with 37°C. On the other hand, reducing the temperature to 30°C resulted in a significant increase in production. Transposition activity at this temperature was sufficiently high to permit detection in vivo of an excised circular form of a defective single IS 911 chromosomal copy when OrfAB is supplied in trans . A similar temperature–activity profile is observed for a cell-free reaction that uses partially purified OrfAB and generates the figure-eight form uniquely. Moreover, two point mutants of OrfAB were obtained, which render the reactions partially temperature resistant both in vivo and in vitro . These results suggest that some property of transposase itself is sensitive to elevated temperatures.     

Characterization of IS1474, an insertion sequence of the IS21 family isolated from Pseudomonas alcaligenes NCIB 9867

A new insertion sequence (IS) designated IS1474 was isolated from Pseudomonas alcaligenes NCIB 9867 (P25X). IS1474 is a 2632 bp element which showed a characteristic IS structure with 12 bp inverted repeats (IRs) flanking a 2608 bp central region. IS1474 contained four open reading frames (ORF1–ORF4), two in each orientation. Similarities were detected between ORF1 and ORF2 and the putative transposases of the IS21 family. Sequences upstream from IS1474 were found to display up to 89% homology with IS53 from Pseudomonas syringae suggesting that IS1474 had inserted into another related IS element designated IS1475. An open reading frame, ORF5, located at the junction of IS1474 and IS1475, showed similarities with the IstB protein of IS21 and could possibly be the transposase subunit of IS1475. Transposition assays showed that IS1474 transposed at a relatively low frequency leading to cointegration with target plasmids. Hybridization studies showed that IS1474 is present in at least 13 copies in the chromosome of P25X and one copy on its endogenous plasmid.     

Efficient transposition of IS204-derived plasmids in Streptomyces coelicolor

In order to study functional gene expression in Streptomyces coelicolor, a mini-transposon encoding the apramycin resistance gene aac(3)IV within its inverted repeat (IR) boundaries was constructed based on IS204, which was previously identified in the genome of Nocardia asteroides YP21. The mini-transposon and IS204 transposase gene were then put on a kanamycin-resistant conjugative plasmid pDZY101 that can only replicate in Escherichia coli. After mating with S. coelicolor A3(2) M145, resistant colonies arose efficiently on both apramycin and kanamycin plates. Plasmid rescue indicated that entire plasmids were inserted into the M145 genome with cleavage at an inverted repeat junction formed by the right inverted repeat (IRR) and the last 18 bp of the transposase gene, while the left inverted repeat (IRL) was untouched. Southern blot analysis of the mutants using an aac(3)IV gene probe showed that transposition of plasmid pDZY101 was genetically stable, with a single-copy insertion within the S. coelicolor M145 genome. Several mutagenesis libraries of S. coelicolor M145 were constructed using plasmid pDZY101 derivatives and the transposon insertion site was determined. The correlation between novel mutant phenotypes and previously uncharacterized genes was established and these transposon locations were widely scattered around the genome.     

One-ended insertion of IS911.

An apparently nonreplicative integration reaction mediated by the insertion sequence IS911 has been analyzed. It is shown to involve the right-end inverted repeat (IRR) of the element and sequences in the flanking vector DNA. The flanking sequences appear to behave as a surrogate IS911 end, since integration is greatly reduced when limited similarities with IRR are eliminated by site-directed mutagenesis. Data are presented which suggest that the activity of the IRR junction results from the proximity of the transposase gene and may therefore reflect preferential transposase recognition of IRR in cis.     

Isolation and Characterization of IS1416fromPseudomonas glumae,a New Member of the IS3Family

Isolation and characterization of four different insertion sequence (IS) elements fromPseudomonas glumaeMAFF 302744 through transposition into the entrapment vector pSHI1063 are described. One of the elements, IS1416,was further characterized. IS1416is 1322 bp long and carries 29-bp terminal inverted repeats flanked by a 3-bp direct duplication. IS1416contains three open reading frames (ORFs), which are designated ORFA1, ORFA2, and ORFB, on one strand. Both DNA sequence of IS1416and the deduced amino acid sequences of its ORFs strongly suggest that IS1416is a member of the IS3family, and is closely related to IS401fromPseudomonas cepaciaand IS51fromPseudomonas syringae.To our knowledge, IS1416is the first IS element isolated fromP. glumae.The gene organization and possible regulation of transposition functions of IS1416are also discussed.     

Functional analysis of unique class II insertion sequence IS1071

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

The basis of asymmetry in IS2 transposition

In the first step of IS2 transposition, the formation of an IS2 minicircle, the roles of the two IS ends differ. Terminal cleavage initiates exclusively at the right inverted repeat (IRR) - the donor end - whereas IRL is always the target. At the resulting minicircle junction, the two abutted ends are separated by a spacer of 1 or 2 basepairs. In this study, we have identified the determinants of donor and target function. The inability of IRL to act as a donor results largely from two sequence differences between IRL and IRR - an extra basepair between the conserved transposase binding sequences and the end of the element, and a change of the terminal dinucleotide from CA-3' to TA-3'. These two changes also impose a characteristic size on the minicircle junction spacer. The only sequences required for the efficient target function of IRL appear to be contained within the segment from position 11-42. Although IRR can function as a target, its shorter length and additional contacts with transposase (positions 1-7) result in minicircles with longer, and inappropriate, spacers. We propose a model for the synaptic complex in which the terminus of IRL makes different contacts with the transposase for the initial and final strand transfer steps. The sequence differences between IRR and IRL, and the behavioural characteristics of IRL that result from them, have probably been selected because they optimize expression of transposase from the minicircle junction promoter, Pjunc.