Target sequences for the C. elegans transposable element Tc1.

The target sequences for two independent insertions of the transposable element Tc1 from Caenorhabditis elegans show homology. Because both insertions are at palindromic TA/AT sequences, the exact boundaries of Tc1 cannot be distinguished; Tc1 could be 1610 bp and flanked by a 2-bp duplication of the target site or it could be 1612 bp and without target site duplication. The latter possibility implies a novel manner for insertion of a transposable element.     

Identification and characterization of IS 1138, a transposable element from Mycoplasma pulmonis that belongs to the IS3 family

Insertion sequence (IS) elements are mobile genetic elements found in prokaryotes. We have identified a repetitive element from Mycoplasma pulmonis, a murine pathogen, that is similar to eubacterial IS elements. By subcloning a single strain of M. pulmonis, we isolated a variant clone in which the IS element had undergone an apparent transposition event. The nucleotide sequences of the element, designated IS 1138, and the target site into which it inserted were determined. IS1138 consists of 1288bp with 18bp perfect terminal inverted repeats. Sequence analysis of the target site before and after insertion of IS1138 identified a 3bp duplication of target DNA flanking the element. The predicted amino acids encoded by the major open reading frame of IS 1138 share significant similarity with the transposases of the IS3 family. Southern hybridization analysis indicates that repetitive sequences similar to IS 1138 are present in most, if not all, strains of M. pulmonis, but Is1138–like sequences were not detected in other mycoplasmal species.     

IS186 Insertion at a Hot Spot in the lon Promoter as a Basis for Lon Protease Deficiency of Escherichia coli B: Identification of a Consensus Target Sequence for IS186 Transposition

The radiation sensitivity of Escherichia coli B was first described more than 50 years ago, and the genetic locus responsible for the trait was subsequently identified as lon (encoding Lon protease). We now show that both E. coli B and the first reported E. coli K-12 lon mutant, AB1899, carry IS186 insertions in opposite orientations at a single site in the lon promoter region and that this site represents a natural hot spot for transposition of the insertion sequence (IS) element. Our analysis of deposited sequence data for a number of other IS186 insertion sites permitted the deductions that (i) the consensus target site sequence for IS186 transposition is 5'-(G)(> or =4)(N)(3-6)(C)(> or =4)-3', (ii) the associated host sequence duplication varies within the range of 6 to 12 bp and encompasses the N(3-6) sequence, and (iii) in a majority of instances, at least one end of the duplication is at the G-N (or N-C) junction. IS186-related sequences were absent in closely related bacterium Salmonella enterica serovar Typhimurium, indicating that this IS element is a recent acquisition in the evolutionary history of E. coli.     

Target specificity of insertion element IS30

The Escherichia coli resident mobile element IS 30 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 IS 30 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 IS 30 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 IS 30 insertion sites proved to be the most efficient target. Having compared the known insertion sites, we suppose that IS 30 -like target specificity, which may represent an alternative strategy in target selection among mobile elements, is characteristic of the insertion sequences IS 3 , IS 6 and IS 21 , too.     

The nucleotide sequence and protein-coding capability of the transposable element IS5

The nucleotide sequence of IS5, a bacterial insertion sequence, has been determined. It is 1195 bp long and contains an inverted terminal repetition of 16 bp with one mismatch. One open reading frame, spanning nearly the entire length of the element, could encode a polypeptide of 338 amino acids. Upon insertion into a DNA segment, IS5 causes a duplication of 4 bp. Based on seven examples, this site of insertion appears to be nonrandom, and the consensus target site sequence is C . T/A . A . G/A (or C/T . T . A/T . G on the opposite strand). The nucleotide sequences of IS5 insertions into the B and cim genes of bacteriophage Mu have allowed tentative identification of the protein-coding frames of B and cim.     

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.     

The IS1111 family members IS4321 and IS5075 have subterminal inverted repeats and target the terminal inverted repeats of Tn21 family transposons

IS5075 and IS4321 are closely related (93.1% identical) members of the IS1111 family that target a specific position in the 38-bp terminal inverted repeats of Tn21 family transposons and that are inserted in only one orientation. They are 1,327 bp long and have identical ends consisting of short inverted repeats of 12 bp with an additional 7 bp (TAATGAG) or 6 bp (AATGAG) to the left of the left inverted repeats and 3 bp (AGA) or 4 bp (AGAT) to the right of the right inverted repeat. Circular forms of IS5075 and IS4321 in which the inverted repeats are separated by abutting terminal sequences (AGATAATGAG) were detected. A similar circular product was found for the related ISPa11. Transposition of IS4321 into the 38-bp target site was detected, but a flanking duplication was not generated. The precisely reconstituted target site was also identified. Over 50 members of the IS1111 family were identified. They encode related transposases, have related inverted repeats, and include related bases that lie outside these inverted repeats. In some, the flanking bases number 5 or 6 on the left and 4 or 3 on the right. Specific target sites were found for several of these insertion sequence (IS) elements. IS1111 family members therefore differ from the majority of IS elements, which are characterized by terminal inverted repeats and a target site duplication, and from members of the related IS110 family, which do not have obvious inverted repeats near their termini.     

Target Choice and Orientation Preference of the Insertion Sequence IS903

We have examined the targeting preference of the bacterial insertion element IS903 by determining the sites of insertion of a large number of transposition events into the 55-kb conjugative plasmid pOX38. Despite the large target size, all the insertions were clustered in four small distinct regions associated with conjugal DNA transfer. Within these regions, many different sites were used for insertion; however, there were a few sites that IS903 inserted into more than once. Alignment of the insertion sites showed that there was no consensus sequence within the 9-bp target duplication but that there were preferred sequences located symmetrically on either side of the target. This is consistent with target recognition by a dimer or multimer of transposase, with either sequence-specific or structure-specific interactions on both sides of the target. We show further that when one of these preferred regions was cloned into a second conjugative plasmid, pUB307, it was still a preferred target, implying that all the sequences necessary for target selection are contained within this DNA segment. Also, we observed a very strong preference for insertion in a single orientation in pUB307. We examined the possibility that either DNA replication from the origin of vegetative replication, oriV, or the origin of transfer, oriT, might determine this orientation effect. We find that reversing the direction of vegetative replication had no effect on the orientation of transposon insertions; however, reversing the direction of DNA transfer abolished the orientation effect. This supports the idea that conjugal DNA transfer imparts a polarity on the target that is sensed by the transposon.     

Testing the palindromic target site model for DNA transposon insertion using the Drosophila melanogaster P-element

Understanding the molecular mechanisms that influence transposable element target site preferences is a fundamental challenge in functional and evolutionary genomics. Large-scale transposon insertion projects provide excellent material to study target site preferences in the absence of confounding effects of post-insertion evolutionary change. Growing evidence from a wide variety of prokaryotes and eukaryotes indicates that DNA transposons recognize staggered-cut palindromic target site motifs (TSMs). Here, we use over 10 000 accurately mapped P-element insertions in the Drosophila melanogaster genome to test predictions of the staggered-cut palindromic target site model for DNA transposon insertion. We provide evidence that the P-element targets a 14-bp palindromic motif that can be identified at the primary sequence level, which predicts the local spacing, hotspots and strand orientation of P-element insertions. Intriguingly, we find that the although P-element destroys the complete 14-bp target site upon insertion, the terminal three nucleotides of the P-element inverted repeats complement and restore the original TSM, suggesting a mechanistic link between transposon target sites and their terminal inverted repeats. Finally, we discuss how the staggered-cut palindromic target site model can be used to assess the accuracy of genome mappings for annotated P-element insertions.     

Structural and genetic organization of IS232, a new insertion sequence of Bacillus thuringiensis.

In the Bacillus thuringiensis strains toxic for the lepidopteran larvae, the delta-endotoxin genes cryIA are frequently found within a composite transposonlike structure flanked by two inverted repeat sequences. We report that these elements are true insertion sequences and designate them IS232. IS232 is a 2,184-bp element and is delimited by two imperfect inverted repeats (28 of 37 bp are identical). Two adjacent open reading frames, overlapping for three codons, span almost the entire sequence of IS232. The potential encoded polypeptides of 50 and 30-kDa are homologous to the IstA and IstB proteins of the gram-negative insertion sequence IS21. The N-terminal part of the 50-kDa polypeptide contains a helix-turn-helix DNA-binding motif. The junctions at the insertion sites of three IS232 elements were analyzed. Each case was different, with 0, 4, or 6 bp of the target DNA being duplicated. Transposition of IS232 in Escherichia coli was demonstrated by using a genetic marker inserted upstream of the two open reading frames.     

IS30, a new insertion sequence of Escherichia coli K12

Summary Three independent spontaneous mutations of prophage P1 affecting the ability of the phage to reproduce vegetatively are due to the insertion of a mobile genetic element, called IS 30. The same sequence is also carried in the R plasmid NR 1-Basel, but not in the parental plasmid NR 1. Southern hybridisation study indicates that the Escherichia coli K 12 chromosome carries several copies of IS 30 as a normal resident. IS 30 is 1.2 kb long and contains unique restriction cleavage sites for Bg/II, ClaI, HindIII, NciI and HincII, and it is cleaved twice by the enzymes HpaII and TaqI. The ends of IS 30 are formed by 26 bp long inverted repeats with 3 bases mismatched. Upon transposition IS 30 generates a duplication of only 2 bp of the target. The following observations suggest a pronounced specificity in target selection by IS 30. In transposition to the phage P 1 genome a single integration site was used three times independently, and in both orientations. A short region of sequence homology has been identified between the P 1 and NR 1-Basel insertion sites. IS 30 has mediated cointegration as well as deletion. The entire IS 30 sequences were duplicated in the cointegrates between a pBR 322 derivative containing IS 30 and the genome of phage P 1–15, and several loci on the P1–15 genome served as fusion sites, some of which were used more than once.     

Nucleotide sequence of Rhizobium meliloti insertion sequence ISRm1: homology to IS2 from Escherichia coli and IS426 from Agrobacterium tumefaciens.

Nucleotide sequencing of Rhizobium meliloti insertion sequence ISRm1 showed that it is 1319 nucleotides long and includes 32/31 nucleotide terminal inverted repeats. Analysis of five different insertion sites using sequencing primers complementary to sequences within the left and right ends demonstrated that ISRm1 generates five bp direct repeats at the sites of insertion. Although ISRm1 has shown a target preference for certain short regions (hot spots), there was no apparent similarity in the DNA sequences near the insertion sites. On one strand ISRm1 contains two contiguous open reading frames (ORFs) spanning most of its length. ISRm1 was found to have over 50% sequence homology to insertion sequences IS2 from Escherichia coli and IS426 from Agrobacterium tumefaciens. Their sizes, the sequences of their inverted repeats, and the characteristics of their insertion sites are also comparable, indicating that ISRm1, IS2 and IS426 belong to a class of related insertion sequences. Comparison of the proteins potentially encoded by these insertion sequences showed that the two ORFs found in ISRm1 are also present in IS2 and IS426, suggesting that they may be functional genes.     

A 10- rather than 9-bp duplication associated with insertion of Tn5 in Escherichia coli K-12

The composite transposable element Tn5, which is made up of two inverted IS50 elements surrounding genes encoding drug resistance, generally generates 9-bp duplications at the site of insertion. In our studies of three Tn5 insertion mutants at one location in the Escherichia coli chromosome, we have observed that one contains a duplication of 10 bp, while the other two have the usual 9-bp duplication. Three other insertion elements, IS1, IS4, and IS186, give variable-sized target site sequence duplications. We observed a similarity of amino acid sequence in a small region of the putative transposases among IS4, IS186, and Tn5 suggesting a conservation of function in this group of transposases.     

Identification of IS 1206, a Corynebacterium glutamicum IS3-related insertion sequence and phylogenetic analysis

Integration of plasmid pCGL320 into a Corynebacterium glutamicum ATCC21086 derivative led to tandem amplification of the inserted plasmid (Labarre et a/., 1993). One amplification event was associated with integration of an insertion sequence that we have named IS 1206. Hybridizing sequences were only found in C. glutamicum strains and at various copy numbers. IS1206 is 1290bp long, carries 32 bp imperfect inverted repeats and generates a 3bp duplication of the target DNA upon insertion. IS1206 presents the features characteristic of the IS3 family and part of the DNA sequence centering on the putative transposase region (orfB) is similar to those of IS3 and some other related elements. Phylogenetic analysis of orfB deduced protein sequences from IS 1206 and IS3-related elements contradicts the phylogeny of the species, suggesting that evolution of these elements might be complex. Horizontal transfer could be invoked but other alternatives like ancestral polymorphism or/and different rates of evolution could also be involved.     

Characterization of insertion sequence IS892 and related elements from the cyanobacterium Anabaena sp. strain PCC 7120.

IS892, one of the several insertion sequence (IS) elements discovered in Anabaena sp. strain PCC 7120 (Y. Cai and C. P. Wolk, J. Bacteriol. 172:3138-3145, 1990), is 1,675 bp with 24-bp near-perfect inverted terminal repeats and has two open reading frames (ORFs) that could code for proteins of 233 and 137 amino acids. Upon insertion into target sites, this IS generates an 8-bp directly repeated target duplication. A 32-bp sequence in the region between ORF1 and ORF2 is similar to the sequence of the inverted termini. Similar inverted repeats are found within each of those three segments, and the sequences of these repeats bear some similarity to the 11-bp direct repeats flanking the 11-kb insertion interrupting the nifD gene of this strain (J. W. Golden, S. J. Robinson, and R. Haselkorn, Nature [London] 314:419-423, 1985). A sequence similar to that of a binding site for the Escherichia coli integration host factor is found about 120 bp from the left end of IS892. Partial nucleotide sequences of active IS elements IS892N and IS892T, members of the IS892 family from the same Anabaena strain, were shown to be very similar to the sequence of IS892.     

DNA sequence analysis of Tn10 insertions: origin and role of 9 bp flanking repetitions during Tn10 translocation.

The sequences of insertions of the translocatable tetracycline-resistance element Tn10 into the repressor (cl) gene of bacteriophage lambda have been analyzed. Each insertion contains the same discrete set of Tn10 sequences flanked by a direct repetition of a 9 bp cl-gene sequence. The flanking repititions are generated by duplication of information present only in the target DNA molecule rather than by a Campbell-type recombination event between one 9 bp sequence on the target DNA and a second one provided on the incoming element. The repetitions do not contain genetic or structural information important for translocation. A genetically constructed Tn10 insertion which lacks flanking repetitions is fully functional in translocation to a new position. Tn10 insertions cluster at preferred positions along a target DNA (Kleckner et al., 1979). Sequence analysis shows that four independently isolated cl::Tn10 insertions occur at identical positions in the cl gene. We speculate that homology between Tn10 and its target, at some distance from the site of the actual recombination event, could be relevant to the preference of Tn10 for particular insertion sites.     

Characterization of an insertion sequence, IS12528, from Gluconobacter suboxydans.

A novel insertion sequence element, IS12528, was found to be associated with inactivation of the alcohol dehydrogenase by insertion in the adhA gene, which encodes the primary dehydrogenase subunit of the three-component membrane-bound alcohol dehydrogenase complex in Gluconobacter suboxydans. Cloning and sequencing analyses revealed that IS12528 was 905 bp in length and had a terminal inverted repeat of 18 bp. In addition, IS12528 was found to generate a 3-bp duplication (TMA, where M represents C or A) at the inserted site upon transposition. IS12528 encoded one long product of 274 amino acids that was rich in basic amino acids. This protein showed significant homology with putative transposases of the IS1031 family isolated from Acetobacter xylinum, which belongs to another genus of acetic acid bacteria. IS12528-like sequences were distributed in a wide variety of acetic acid bacteria, as determined by Southern hybridization and PCR. These observations suggest that IS12528 is one of the insertion sequences that are responsible for genetic instability leading to deficiencies in various physiological properties in a variety of acetic acid bacteria.     

Insertion element IS102 resides in plasmid pSC101.

In vivo recombination was found to occur between plasmid pHS1, a temperature-sensitive replication mutant of pSC101 carrying tetracycline resistance, and plasmid ColE1 after selection for tetracycline resistance at the restrictive temperature, 42 degrees C. Extensive analysis of the physical structures of three of these recombinant plasmids, using restriction endonucleases and the electron microscope heteroduplex method, revealed that the plasmid pHS1 was integrated into different sites on ColE1. The recombinant plasmids contained a duplication of a unique 1-kilobase (kb) sequence of pHS1 in a direct orientation at the junctions between the two parental plasmid sequences. This was confirmed by comparing the nucleotide sequence of the recombinants and their parental plasmids. Nucleotide sequence analysis further revealed that nine nucleotides at the site of recombination of ColE1 were duplicated at the junction of each of the 1-kb sequences. The formation of recombinants was independent of RecA function. Based on our previous finding that a plasmid containing a deoxyribonucleic acid insertion (IS) element can recombine with a second plasmid to generate a duplication of the IS element, we conclude that the 1-kb sequence is an insertion sequence, which we named IS102. For convenience, we have also denoted the IS102 sequence as eta theta to assign the orientation of the sequence. Eighteen nucleotides at one end (eta end) were found to be repeated in an inverted orientation at the other end (theta end) of IS102. The nucleotide sequence of the eta end of the sequence was found to be identical to the sequence at the ends of the transposon Tn903, which is responsible for transposition of the kanamycin resistance gene.     

IS231A from Bacillus thuringiensis is functional in Escherichia coli: transposition and insertion specificity.

A kanamycin resistance gene was introduced within the insertion sequence IS231A from Bacillus thuringiensis, and transposition of the element was demonstrated in Escherichia coli. DNA sequencing at the target sites showed that IS231A transposition results in direct repeats of variable lengths (10, 11, and 12 bp). These target sequences resemble the terminal inverted repeats of the transposon Tn4430, which are the preferred natural insertion sites of IS231 in B. thuringiensis.