Evidence for a role of translational frameshifting in the expression of transposition activity of the bacterial insertion element IS1

The bacterial insertion element IS1 contains two essential open reading frames, insA and insB, arranged in tandem. We have introduced a number of site-specific mutations into the region including the 3'-terminal region of insA, the region between insA and insB, and the ATG codon at the start of insB. Relative transposition activities of mutant and wild-type elements were determined using a modified in vivo cointegration assay. The results support the hypothesis that a translational (-1) frameshift occurring in the 3'-terminal region of insA and linking insB to insA is responsible for the synthesis of the active IS1 transposition enzyme. Further results with IS1 elements containing internal deletions are in agreement with a role of the normally terminated insA product as an inhibitor of transposition.     

A transcriptional terminator sequence in the prokaryotic transposable element IS1

The prokaryotic transposable element IS1 is known to exert a strong polar effect upon integration into an operon. To elucidate this polar effect, we constructed a plasmid which has an IS1 integrated between the 5' half of the tet gene for tetracycline resistance and the cat structural gene for chloramphenicol resistance. The cat gene is expressed by the tet promoter and the presence of IS1 in orientation I, in which the IS1 transposase genes insA and insB are in the same orientation as the cat gene, reduced the cat expression. By introducing deletions or insertions within the IS1 sequence, we were able to map a rho-dependent terminator TIS1A between the insA and insB genes. Translational interruption between these ins genes is important for TIS1A to be an active terminator.     

Insertion element IS1 encodes two structural genes required for its transposition

The nucleotide sequence analysis of insertion element IS1 has shown that IS1 could have as many as six translational reading frames encoding possible proteins. In order to determine which reading frames are actual structural genes responsible for IS1-mediated recombination, we introduced base substitution mutations including nonsense mutations into all of the potential reading frames and examined the ability of these IS1 mutants to mediate cointegration between two plasmids. The results reveal that IS1 has two structural genes (termed insA and insB), which are required for plasmid cointegration mediated by IS1.     

Different Reading Frames Are Responsible for Is1-Dependent Deletions and Recombination

Two classes of plasmids in addition to the parent become apparent when plasmids that contain direct repeats of IS1. One class of plasmids has deleted sequences from the end of IS1 to nonrandom sites within the plasmid. The appearance of these plasmids in the population requires intact insA and insB reading frames, but not insC. The other class of plasmids has undergone an exchange within the direct repeats of IS1 on the plasmid. Their appearance requires InsC but neither InsA nor InsB. The two reactions may represent two distinguishable steps in IS1 transposition. The InsC-catalyzed exchange is independent of RecA and resembles hologous recombination since the frequency of recombinants arising from exchanges in different regions of IS1 appears to be roughly proportional to the size of the region. InsC can also catalyze an exchange between direct repeats of non-IS1 DNA.     

Function of the InsA gene in the IS1 element of the Tn9' transposon: influence of oligonucleotide inserts in the InsA gene on formation of simple insertions and plasmid cointegrates]

To elucidate the role of the insA reading frame in transposition of the IS1 element of the Tn9' transposon, the derivatives of plasmids pUC19::Tn9' and pUC19::IS1 have been obtained using oligonucleotide inserts of the length equal or exceeding 9 bp and equal to 10 bp. The ability of mutant variants of the Tn9' transposon and the IS1 element to form simple insertions and plasmid cointegrates was studied. To this end, experiments were performed on mobilization of the derivatives of pUC19 containing mutant variants of the IS1 element and Tn9' as well as of the plasmids pUC19::Tn9' by the conjugative plasmid pRP3.1. According to the data obtained, mutations (inserts) in the insA gene have no influence on the frequency of transposition of the IS1 element and Tn9' from the plasmid pUC19 to pRP3.1. At the same time, the frequency of transposition events of mutant variants of Tn9' from the plasmid pRP3.1 to pBR322 is more than 10 times lower in comparison with the wild type transposon. The data obtained are in accordance with the assumption that the insA gene is not essential for transposition. A hypothesis is put forward explaining the role of the insA gene product in the process of bringing together short inverted repeats of the IS1, which are the sites for the transposase to be recognized at first stages of transposition.     

Mutational Analysis of the Open Reading Frames in the Transposable Element Is1

IS1 is one of the smallest transposable elements found in bacteria (768 bp). It contains eight overlapping open-reading-frames (ORFs) greater than 50 codons, designated insA to insG and insB'. To determine which of the ORFs actually code for proteins involved in transposition, we have introduced amber codons into each ORF by site-directed mutagenesis which make neutral changes in the overlapping ORFs. Each mutant IS1 was then tested for its ability to mediate cointegrate formation in Su+ and Su- backgrounds. The mutant elements were also tested for trans-complementation in an IS1-free Salmonella background. Our results show that the products of the insA and insB genes are the only ones essential for cointegrate formation. We suggest that other ORFs may, however, encode accessory proteins.     

The regulatory role of the IS 1-encoded InsA protein in transposition

We show here that the protein InsA, which is encoded by IS 1 and binds specifically to the terminal inverted repeats of this insertion sequence, negatively regulates IS 1 transposition activity. We demonstrate that it inhibits both IS 1-mediated cointegrate formation and transposition of a synthetic IS 1-based transposon (‘omegon’Ω-on). These results also indicate that the Ω-on which does not itself encode IS 1 transposition functions can be complemented in trans, presumably by the copies of IS 1 resident in the Escherichia coli chromosome. Using insA-lacZ gene fusions, we show that at least part of this effect can be explained by the ability of InsA to repress expression of IS 1-encoded genes both in cis or in trans. The experiments involving Ω-on transposition raise the possibility that InsA inhibits transposition directly by competition with the transposase for their cognate site within the ends of IS 1.     

Functional organization of the ends of IS 1: specific binding site for an IS1-encoded protein

The IS 1-encoded protein InsA binds specifically to both ends of IS1, and acts as a repressor of IS1 gene expression and may be a direct inhibitor of the transposition process. We show here, using DNasel 'foot-printing' and gel retardation, that the InsA binding sites are located within the 24/25 bp minimal active ends of IS1 and that InsA induces DNA bending upon binding. Conformational modification of the ends of IS1 as a result of binding of the host protein integration host factor (IHF) to its site within the minimal ends has been previously observed. Using a collection of synthetic mutant ends we have mapped some of the nucleotide sequence requirements for InsA binding and for transposition activity. We show that sequences necessary for InsA binding are also essential for transposition activity. We demonstrate that InsA and IHF binding sites overlap since some sequence determinants are shared by both InsA and IHF. The data suggest that these ends contain two functional domains: one for binding of InsA and IHF, and the other for transposition activity. A third region, when present, may enhance transposition activity with an intact right end. This 'architecture' of the ends of IS1 is remarkably similar to that of IS elements IS10, IS50 and IS903.     

Base substitutions in transposable element IS1 cause DNA duplication of variable length at the target site for plasmid co-integration.

We demonstrate that base substitutions in the IS1 sequence affect the length of the nucleotide sequence which is duplicated during IS1-mediated co-integration. IS1K, an IS1 variant present in the Escherichia coli chromosome, has seven base substitutions in its sequence as compared with that of IS1R derived from the plasmid R100. All substitutions are located in the internal region of IS1K. We have constructed plasmids containing IS1R, IS1K and hybrids between them: one contains four base substitutions causing an amino acid substitution in the insA gene and the other has three substitutions producing an amino acid substitution in the insB gene. We have isolated co-integrate plasmids formed by each IS1 and analysed nucleotide sequences of the target sites duplicated at the co-integration junctions. The results show that IS1K generates duplications of 8 or 14 bp as well as 9 bp, while IS1R exclusively generates the 9-bp duplications. Both hybrid IS1s also create 8- or 7-bp target duplications in addition to 9-bp duplications. These results indicate that the base substitutions in either insA or insB are sufficient for the occurrence of unusual target duplications, suggesting that both genes are involved in the target duplication.     

Study of the role of the insA open reading frame in the IS1 insertion element structure during transposition and resolution of the IS1 mediated cointegrates

In order to elucidate the function of the IS1 insA gene derivatives of plasmid pUC19::Tn9' with insertions of synthetic oligonucleotides were obtained. The latter are equal or multiple of 9 b.p. in length and are located in the Pst1 site within each of the two IS1 copies of the Tn9' transposon. The insertions of the nine base oligonucleotides code for the neutral amino acids and do not shift the reading frame. One of the mutant transposon obtained - Tn9'/X was studied on the ability to form simple insertions and plasmid cointegrates. For this purpose the pUC19 derivatives carrying the wild type and mutant transposon were mobilized by conjugative plasmid pRP3.1. It was found that the damage of the insA gene does not influence the ability of transposon to form simple insertions and plasmid cointegrates in both recA - and rec+ cells of E. coli. However, the frequency of the cointegrate formation in the subsequent transposition of the mutant transposon from pRP3.1::Tn9'/X to pBR322 was by 10-20 times lower in comparison to the wild type transposon. Instable (dissociating) Tn9'/X-mediated plasmid cointegrates formed by interaction pUC19::Tn9'/X and pRP3.1 were obtained. It was shown that in the E. coli recA-cells such cointegrates dissociate, as a rule, "correctly", i.e. they segregate mainly plasmids of types pUC19::Tn9'/X and pUC19::IS1/X. The data obtained correspond with the notion that the gene insA product is not essential for transposition, but is, possibly, involved in the formation of the IS1-generated deletions.     

Recombination in recA cells between direct repeats of insertion element IS1.

The IS1 sequences that flank the Tn9 chloramphenicol acetyltransferase gene as direct repeats recombine after transformation into an Escherichia coli recA strain. The recombination requires the lambda pL promoter on the plasmid. A plasmid that contains mutant IS1 elements does not recombine. These results indicate that this recombination requires an IS1-specific gene product. The recombinational activity of IS1 may resolve transient cointegrates formed during the transposition of IS1. I discuss a possible role for the lambda pL promoter.     

Is the IS1 transposase, InsAB', the only IS1-encoded protein required for efficient transposition?

The transposase of the bacterial insertion sequence IS1 is normally expressed by inefficient translational frameshifting between an upstream reading frame which itself specifies a transposition inhibitor, InsA, and a second consecutive reading frame located immediately downstream. A fused-frame mutant which carries an additional base pair inserted at the point of frameshifting was constructed. This mutant exhibits high transposition activity and should express the transposase, InsAB', constitutively without frameshifting. Unexpectedly, a second protein species was observed to be expressed from this mutant. We demonstrate here that this protein, InsA*, results from continued frameshifting on the modified frameshift motif. The protein retains the activities of the repressor InsA. Its elimination, by further modification of the frameshift motif, results in a further increase in various transposition activities of IS1. These results support the hypothesis that a single IS1-encoded protein, InsAB', is necessary for transposition.     

Escherichia coli insertion sequence IS150: transposition via circular and linear intermediates

IS150, a member of the widespread IS3 family, contains two consecutive out-of-phase open reading frames, orfA and orfB, that partially overlap. These open reading frames encode three proteins, InsA, InsB, and the InsAB protein, which is jointly encoded by both open reading frames by means of programmed translational frameshifting. We demonstrate that the InsAB protein represents the IS150 element's transposase. In vivo, the wild-type IS150 element generates circular excision products and linear IS150 molecules. Circular and linear species have previously been detected with mutant derivatives of other members of the IS3 family. Our finding supports the assumption that these products represent true transposition intermediates of members of this family. Analysis of the molecular nature of these two species suggested that the circular forms are precursors of the linear molecules. Elimination of InsA synthesis within the otherwise intact element led to accumulation of large amounts of the linear species, indicating that the primary role of InsA may be to prevent abortive production of the linear species and to couple generation of these species to productive insertion events.     

Direct selection of IS903 transposon insertions by use of a broad-host-range vector: isolation of catalase-deficient mutants of Actinobacillus actinomycetemcomitans

Transposon mutagenesis in bacteria generally requires efficient delivery of a transposon suicide vector to allow the selection of relatively infrequent transposition events. We have developed an IS903-based transposon mutagenesis system for diverse gram-negative bacteria that is not limited by transfer efficiency. The transposon, IS903phikan, carries a cryptic kan gene, which can be expressed only after successful transposition. This allows the stable introduction of the transposon delivery vector into the host. Generation of insertion mutants is then limited only by the frequency of transposition. IS903phikan was placed on an IncQ plasmid vector with the transposase gene located outside the transposon and expressed from isopropyl-beta-D-thiogalactopyranoside (IPTG)-inducible promoters. After transposase induction, IS903phikan insertion mutants were readily selected in Escherichia coli by their resistance to kanamycin. We used IS903phikan to isolate three catalase-deficient mutants of the periodontal pathogen Actinobacillus actinomycetemcomitans from a library of random insertions. The mutants display increased sensitivity to hydrogen peroxide, and all have IS903phikan insertions within an open reading frame whose predicted product is closely related to other bacterial catalases. Nucleotide sequence analysis of the catalase gene (designated katA) and flanking intergenic regions also revealed several occurrences of an 11-bp sequence that is closely related to the core DNA uptake signal sequence for natural transformation of Haemophilus influenzae. Our results demonstrate the utility of the IS903phikan mutagenesis system for the study of A. actinomycetemcomitans. Because IS903phikan is carried on a mobilizable, broad-host-range IncQ plasmid, this system is potentially useful in a variety of bacterial species.