Localization of Action of the Is50-Encoded Transposase Protein

The movement of the bacterial insertion sequence IS50 and of composite elements containing direct terminal repeats of IS50 involves the two ends of IS50, designated O (outside) and I (inside), which are weakly matched in DNA sequence, and an IS50 encoded protein, transposase, which recognizes the O and I ends and acts preferentially in cis. Previous data had suggested that, initially, transposase interacts preferentially with the O end sequence and then, in a second step, with either an O or an I end. To better understand the cis action of transposase and how IS50 ends are selected, we generated a series of composite transposons which contain direct repeats of IS50 elements. In each transposon, one IS50 element encoded transposase (tnp+), and the other contained a null (tnp-) allele. In each of the five sets of composite transposons studied, the transposon for which the tnp+ IS50 element contained its O end was more active than a complementary transposon for which the tnp- IS50 element contained its O end. This pattern of O end use suggests models in which the cis action of transposase and its choice of ends is determined by protein tracking along DNA molecules.     

Characterization of a novel insertion sequence,IS<Emphasis Type="Italic">Bp1</Emphasis>, in<Emphasis Type="Italic"> Burkholderia pseudomallei</Emphasis>

During screening for antigenic proteins in Burkholderia pseudomallei, a novel insertion sequence, IS Bp1, was found by sequence similarity searches. IS Bp1 contains two overlapping ORFs of 261 bp ( orfA) and 852 bp ( orfB), encoding 87 and 284 amino acid residues, respectively, and an imperfect inverted repeat. The putative protein encoded by orfA (OrfA) is similar to the OrfA in insertion sequences of the IS 3 family in other bacteria, showing 49% and 76% amino acid identity and similarity, respectively, with the transposase encoded by IS D1 of Desulfovibrio vulgaris vulgaris. The putative protein encoded by orfB (OrfB) is similar to the OrfB in insertion sequences of the IS 3 family in other bacteria, showing 43% and 62% amino acid identity and similarity, respectively, with the transposase encoded by IS 1222 of Enterobacter agglomerans. Sequence analysis of OrfA showed the presence of an alpha-helix-turn-alpha-helix motif, as well as the putative leucine zipper at its 3' end, for possible DNA binding to the terminal inverted repeats. Sequence analysis of OrfB showed the presence of a DDE motif of aspartic acid, aspartic acid, and glutamic acid, a highly conserved motif present in OrfB of other members of the IS 3 family. Furthermore, several other conserved amino acid residues, including the arginine residue located seven amino acids downstream from the glutamic acid residue, were observed. PCR amplification of the IS Bp1 gene showed a specific band in 65% of the 26 B. pseudomallei strains tested. Southern blot hybridization after XhoI or SacI digestion showed nine different patterns of hybridization. The number of copies of IS Bp1 in those strains that possessed the insertion sequence ranged from three to 12. Using several insertion sequences and a combination of insertion-sequence-based and non-insertion-sequence-based methods such as ribotyping will probably increase the discriminatory power of molecular typing in B. pseudomallei.     

The IS4 family of insertion sequences: evidence for a conserved transposase motif

The eight IS 231 variants characterized so far (IS 231 A-F, V and W) display similar transposases with an overall 40% identity. Comparison with all the proka-ryotic transposable elements sequenced so far revealed that the IS231 transposases share two conserved regions with those of 35 other insertion sequences of wide origins. These insertion sequences, defining the IS4 family, have a common bipartite organization of their ends and are divided into two similarity groups. Interestingly, the transposase domains conserved within this family display similarities with the well known integrase domain shared by transposases of the IS3 and IS15 families, and integrases of retroelements. This domain is also found in IS30- related elements and Tn7 TnsB protein. Amino acid residues conserved throughout all these prokaryotic and eukaryotic mobile genetic elements define a major transposase/integrase motif, likely to play an important role in the transposition process.     

Combining protein sequence,structure, and dynamics: A novel approach for functional evolution analysis of PAS domain superfamily

PAS domains are widespread in archaea, bacteria, and eukaryota, and play important roles in various functions. In this study, we aim to explore functional evolutionary relationship among proteins in the PAS domain superfamily in view of the sequence‐structure‐dynamics‐function relationship. We collected protein sequences and crystal structure data from RCSB Protein Data Bank of the PAS domain superfamily belonging to three biological functions (nucleotide binding, photoreceptor activity, and transferase activity). Protein sequences were aligned and then used to select sequence‐conserved residues and build phylogenetic tree. Three‐dimensional structure alignment was also applied to obtain structure‐conserved residues. The protein dynamics were analyzed using elastic network model (ENM) and validated by molecular dynamics (MD) simulation. The result showed that the proteins with same function could be grouped by sequence similarity, and proteins in different functional groups displayed statistically significant difference in their vibrational patterns. Interestingly, in all three functional groups, conserved amino acid residues identified by sequence and structure conservation analysis generally have a lower fluctuation than other residues. In addition, the fluctuation of conserved residues in each biological function group was strongly correlated with the corresponding biological function. This research suggested a direct connection in which the protein sequences were related to various functions through structural dynamics. This is a new attempt to delineate functional evolution of proteins using the integrated information of sequence, structure, and dynamics.     

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.     

ISWpi1 from Wolbachia pipientis defines a novel group of insertion sequences within the IS5 family

Insertion sequences are transposable elements that can represent substantial proportions of prokaryotic genomes and play a substantial role in shaping host genome evolution. As such, evaluating and understanding insertion sequence diversity is an important task to fulfill, because it is expected to yield new insight into the evolution of bacterial transposable elements and contribute to improve genome annotations. Here, I characterized an insertion sequence, termed ISWpi1, for which the taxonomic distribution appears to be restricted to the obligate intracellular alpha-Proteobacterium Wolbachia pipientis. ISWpi1 exhibits approximately 46% identity at the amino acid level with members of the IS1031 group of insertion sequences from the IS5 family. However, the IS1031 group is characterized by a transposase gene encoded by a single open reading frame, whereas the ISWpi1 transposase gene consists of two overlapping open reading frames presumably translated as a single protein via programmed translational frameshifting. Such structure suggests that ISWpi1 may instead be related to the IS427 group of insertion sequences from the IS5 family. Altogether, these data indicate that ISWpi1 extends the known spectrum of diversity of the IS5 family, and I propose to define a novel group of insertion sequences within the IS5 family typified by ISWpi1. Probable transpositional activity, relevant insertion site preferences and taxonomic specificity make ISWpi1 a promising tool for experimentally manipulating W. pipientis bacteria, especially in light of the increasing interest in developing these bacteria as tools for controlling insect disease vectors and agricultural pests.     

Palindromic unit-independent transposition of IS1397 in Yersinia pestis

Palindromic units (PUs) are intergenic repeated sequences scattered over the chromosomes of Escherichia coli and several other enterobacteria. In the latter, IS1397, an E. coli insertion sequence specific to PUs, transposes into PUs with sequences close to the E. coli consensus. Reasons for this insertion specificity can relate to either a direct recognition of the target (by its sequence or its structure) by the transposase or an interaction between a specific host protein and the PU target DNA sequence. In this study, we show that for Yersinia pestis, a species deprived of PUs, IS1397 can transpose onto its chromosome, with transpositional hot spots. Our results are in favor of a direct recognition of target DNA by IS1397 transposase.     

The organization of the outside end of transposon Tn5.

The end sequences of the IS50 insertion sequence are known as the outside end (OE) and inside end. These complex ends are related but nonidentical 19-bp sequences that serve as substrates for the activity of the Tn5 transposase. Besides providing the binding site of the transposase, the end sequences of a transposon contain additional types of information necessary for transposition. These additional properties include but are not limited to host protein interaction sites and sites that program synapsis and cleavage events. In order to delineate the properties of the IS50 ends,the base pairs involved in the transposase binding site have been defined. This has been approached through performing a variety of in vitro analyses: a ++hydroxyl radical missing-nucleoside interference experiment, a dimethyl sulfate interference experiment, and an examination of the relative binding affinities of single-site end substitutions. These approaches have led to the conclusion that the transposase binds to two nonsymmetrical regions of the OE, including positions 6 to 9 and 13 to 19. Proper binding occurs along one face of the helix, over two major and minor grooves, and appears to result in a significant bending of the DNA centered approximately 3 bp from the donor DNA-OE junction.     

IS10 transposase mutations that specifically alter target site recognition.

IS10 inserts preferentially into particular hotspots. We describe here mutations of IS10 transposase, called 'ATS' that confer Altered Target Specificity. These mutations yield a general relaxation in target specificity but do not affect other aspects of transposition. Thus, the preference for specific nucleotide sequences at the target site can be cleanly separated from other steps of the transposition reaction. Eleven ATS mutations identified in a genetic screen occur at only two codons in transposase, one in each of two regions of the protein previously implicated in target site interactions (Patch I and Patch II). Genetic analysis suggests that mutations at the two ATS codons affect the same specific function of transposase, thus raising the possibility that Patch I and Patch II interact. For wild-type IS10, insertion specificity is determined in part by a specific 6 bp consensus sequence and in part by the immediately adjacent sequence context of the target DNA. The ATS mutations do not qualitatively alter the hierarchy with which base pairs are recognized in the consensus sequence; instead, sites selected by ATS transposase exhibit a reduction in the degree to which certain base pairs are preferred over others. Models for the basis of this phenotype are discussed.     

IS50L as a non-self transposable vector used to integrate the Bacillus thuringiensis delta-endotoxin gene into the chromosome of root-colonizing pseudomonads

Insertion sequence IS50L of transposon Tn5 was used as a non-self transposable vector to integrate the delta-endotoxin gene (tox) from Bacillus thuringiensis subsp. kurstaki HD-1 into the chromosome of two corn-root colonizing strains of Pseudomonas fluorescens (112-12 and Ps3732-3-7). A DNA fragment containing the KmR gene from Tn5 and tox was inserted into an IS50L element (IS50L-tox) contained on a suicide plasmid. Transposition of IS50L-tox into the chromosome of P. fluorescens 112-12 and Ps3732-3-7 occurred by selecting for KmR transconjugants and supplying transposase in cis from a linked IS50R element. A frameshift mutation in the transposase gene of the IS50L-tox element was also constructed to decrease the likelihood that suppression or a spontaneous reversion at the UAA (ochre) termination codon of IS50L would create an active transposase. The inability of IS50L-tox to transpose further minimizes the potential for horizontal gene transfer of the tox gene to other bacterial species. Expression of the Tox protein in strains 112-12 and Ps3732-3-7 was demonstrated by an immunological assay (Western blot) and toxicity against larvae of the tobacco hornworm (Manduca sexta).     

Sequences essential for IS50 transposition. The first base-pair

Sequences near the ends of the insertion element IS50 are essential for its transposition, probably because they serve as sites upon which the IS50-encoded transposase protein acts. To determine if these essential sequences include the first base-pair at each end of IS50 we generated 5'C to 5'G transversions at these positions. Each mutation reduced the transposition frequency to 1% to 2% of wild-type. DNA sequence analyses showed that the mutant 5'G is preserved during transposition.     

Linearization and transposition of circular molecules of insertion sequence IS3.

IS3 transposase has been shown to promote production of characteristic circular and linear IS3 molecules from the IS3-carrying plasmid; IS3 circles have the entire IS3 sequence with terminal inverted repeats, IRL and IRR, which are separated by a three base-pair sequence originally flanking either end in the parental plasmid, whereas linear IS3 molecules have three nucleotide overhangs at their 5' ends. Here, we showed that a plasmid carrying an IS3 derivative, which is flanked by different sequences at both ends, generated IS3 circles and linear IS3 molecules owing to the action of transposase. Cloning and sequencing analyses of the linear molecules showed that each had the same 5'-protruding three nucleotide overhanging sequences at both ends, suggesting that the linear molecules were not generated from the parental plasmid by the two double-strand breaks at both end regions of IS3. The plasmid carrying IS3 with a two base-pair mutation in the terminal dinucleotide, which would be required for transposase to cleave the 3' end of IS3, could still generate linear molecules as well as circles. Plasmids bearing an IS3 circle were cleaved by transposase and gave linear molecules with the same 5'-protruding three nucleotide overhanging sequences. These show that the linear molecules are generated from IS3 circles via a double-strand break at the three base-pair intervening sequence. Plasmids carrying an IS3 circle with the two base-pair end mutation still were cleaved by transposase, though with reduced efficiencies, suggesting that IS3 transposase has the ability to cleave not only the 3' end of IS3, but a site three nucleotides from the 5' end of IS3. IS3 circles also were shown to transpose to the target plasmids. The end mutation almost completely inhibited this transposition, showing that the terminal dinucleotides are important for the transfer of the 3' end of IS3 to the target as well as for the end cleavage.     

Tn5-mediated integration of the delta-endotoxin gene from Bacillus thuringiensis into the chromosome of root-colonizing pseudomonads

Gene replacement mediated by Tn5 sequences was used to integrate the Bacillus thuringiensis subsp. kurstaki HD-1 delta-endotoxin gene (tox) into the chromosome of two corn root-colonizing strains of Pseudomonas fluorescens. A Tn5 transposase deletion element containing the tox gene (delta Tn5-tox) was substituted for a Tn5 element previously present in the P. fluorescens chromosome. Two classes of delta Tn5-tox elements were made. The first class encodes kanamycin resistance in addition to the Tox protein, whereas the second class encodes only the Tox protein. Both classes of delta Tn5-tox elements can no longer transpose, owing to a 324-base-pair deletion in the transposase gene of IS50R, minimizing the potential for horizontal gene transfer of the tox gene to other bacterial species. A frameshift mutation in the transposase gene of IS50L was also constructed to eliminate the possibility of suppression or of a spontaneous reversion at the ochre termination codon that would create an active transposase. Expression of the Tox protein in P. fluorescens strains 112-12 and Ps3732-3-7 was demonstrated by an immunological assay (Western blot) and toxicity against larvae of the tobacco hornworm (Manduca sexta).     

A novel IS element,IS621, of the IS110/IS492 family transposes to a specific site in repetitive extragenic palindromic sequences in Escherichia coli

An Escherichia coli strain, ECOR28, was found to have insertions of an identical sequence (1,279 bp in length) at 10 loci in its genome. This insertion sequence (named IS621) has one large open reading frame encoding a putative protein that is 326 amino acids in length. A computer-aided homology search using the DNA sequence as the query revealed that IS621 was homologous to the piv genes, encoding pilin gene invertase (PIV). A homology search using the amino acid sequence of the putative protein encoded by IS621 as the query revealed that the protein also has partial homology to transposases encoded by the IS110/IS492 family elements, which were known to have partial homology to PIV. This indicates that IS621 belongs to the IS110/IS492 family but is most closely related to the piv genes. In fact, a phylogenetic tree constructed on the basis of amino acid sequences of PIV proteins and transposases revealed that IS621 belongs to the piv gene group, which is distinct from the IS110/IS492 family elements, which form several groups. PIV proteins and transposases encoded by the IS110/IS492 family elements, including IS621, have four acidic amino acid residues, which are conserved at positions in their N-terminal regions. These residues may constitute a tetrad D-E(or D)-D-D motif as the catalytic center. Interestingly, IS621 was inserted at specific sites within repetitive extragenic palindromic (REP) sequences at 10 loci in the ECOR28 genome. IS621 may not recognize the entire REP sequence in transposition, but it recognizes a 15-bp sequence conserved in the REP sequences around the target site. There are several elements belonging to the IS110/IS492 family that also transpose to specific sites in the repeated sequences, as does IS621. IS621 does not have terminal inverted repeats like most of the IS110/IS492 family elements. The terminal sequences of IS621 have homology with the 26-bp inverted repeat sequences of pilin gene inversion sites that are recognized and used for inversion of pilin genes by PIV. This suggests that IS621 initiates transposition through recognition of their terminal regions and cleavage at the ends by a mechanism similar to that used for PIV to promote inversion at the pilin gene inversion sites.     

Identification of an insertion sequence, IS1081, in Mycobacterium bovis

Abstract: An insertion sequence, IS1081, in the genome of Mycobacterium bovis has been identified and sequenced. It is 1324 bp long with 15 bp inverted repeat ends and contains a large ORF. There are six copies of IS1081 in the genome of M. bovis and the element is also present in Mycobacterium tuberculosis . IS1081 is not closely related to other DNA elements described in actinomycetes but its putative transposase bears some resemblance to that of IS256 from Staphylococcus aureus . IS1081 may be useful for genetic manipulations and for developing a diagnostic test for bovine tuberculosis based on the polymerase chain reaction.