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.     

Orientation of IS50 transposase gene and IS50 transposition.

Reversal of transposase gene orientation with respect to the nonidentical ends of IS50 strongly decreased IS50 transposition in both Dam- and Dam+ hosts. In either orientation, IS50 transposase expression was unaffected. These effects were independent of the surrounding DNA context. This shows that the efficiency of IS50 transposition is dependent on transposase gene orientation. The transposition frequencies of transposons utilizing inverted IS50 inside ends (IE), IE-IE transposons, were lower than either outside end (OE)-IE or OE-OE transposons.     

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.     

DNA sequence of IS91 and identification of the transposase gene.

IS91 is a 1,830-bp insertion sequence that inserts specifically at the sequence CAAG or GAAC of the target and does not duplicate any sequence upon insertion (23). By transposon mutagenesis, we have identified open reading frame 426 (ORF426; bp 454 to 1731) as the putative ORF for the transposase. It displays a cysteine-rich, potential metal-binding domain in its N-terminal region. Adjacent to ORF426, there is an ORF (ORF121) which precedes and terminally overlaps ORF426 by one amino acid. Tn1732 insertions in ORF121 do not affect the transposition frequency. IS91 has sequence similarities to IS801 from Pseudomonas syringae. Their putative transposases are 36% identical, including conservation of the cysteine-rich cluster. The information concerning IS801 insertion specificity and target duplication has been reevaluated in the light of our results.     

Crystal structure of a metal ion-bound IS200 transposase

IS200 transposases, present in many bacteria and Archaea, appear to be distinct from other groups of transposases. To provide a structural basis for understanding the action of IS200 transposases, we have determined the crystal structure of the SSO1474 protein from Sulfolobus solfataricus, a member of the IS200 family, in both Mn(2+)-bound and Mn(2+)-free forms. Its monomer fold is distinct from other classes of structurally characterized transposases. Two monomers form a tight dimer by exchanging the C-terminal alpha-helix and by merging the two central beta-sheets into a large beta-sheet. Glu(55), His(62), and four water molecules provide the direct coordination sphere of the catalytically essential metal ion in the Mn(2+)-bound structure. His(16), Asp(59), and His(60) also play important roles in maintaining the metal binding site. The catalytic site is formed at the interface between monomers. The candidate nucleophile in the transposition mechanism, strictly conserved Tyr(121) coming from the other monomer, is turned away from the active site, suggesting that a conformational change is likely to occur during the catalytic cycle.     

Binding of the IS903 transposase to its inverted repeat in vitro.

We have purified the transposase of IS903 in three different ways. We find that transposase expressed as a fusion protein with either glutathione-S-transferase or maltose-binding protein is soluble and can be purified rapidly using affinity chromatography. The third purification requires extracting the native transposase from an insoluble pellet using an alkaline pH buffer. All three proteins bind specifically to the ends of IS903 and give identical patterns of protection when challenged with DNase I. We have used the more stable fusion proteins to examine transposase--DNA interactions in vitro. Methylation interference experiments have identified critical bases for transposase binding; methylated purines that inhibit binding all lie within the inner part of the 18 bp inverted repeat (bp 7-16). Moreover, the positions and identities of these purines suggest that the transposase interacts with base pairs in adjacent major and minor grooves. Binding assays with mutant inverted repeats confirm that transposase binding is sensitive to sequence changes only within this inner region. We propose that the transposase binding site is limited to this domain of the inverted repeat. These data are consistent with our previous analysis of the behaviour of mutant ends in vivo, from which we postulated that the inverted repeat was composed of two functional domains; an inner binding domain (bp 6-18), which included a region of minor groove interactions, and an outer domain that was involved in a step subsequent to transposase binding.     

IS903 transposase mutants that suppress defective inverted repeats

The inverted repeats (IRs) of the insertion element IS903 are composed of two functional regions. An inner region, consisting of basepairs 6-18, is the transposase binding site. The outer region (positions 1-3) is not contacted during initial transposase binding, but is essential for efficient transposition. We have examined the interaction of the IR with the transposase by isolating transposase suppressors of IR mutations. These suppressors define two patches within the N-terminus of the protein. One class of suppressors, which rescued the majority of outer IR mutants tested, contained mutations in close proximity to an aspartate residue (D121) believed to form part of the catalytic DDE motif, suggesting that their suppressive effect is in the positioning of the catalytic site at the terminus of the transposon. The hypertransposition phenotype of mutant VA119 is also consistent with this hypothesis. The second class was more allele specific and preferentially suppressed a mutation at position 3 of the IR. Finally, we showed that mutations at the termini of the IR elevate the frequency of cointegrate formation by IS903. Other outer IR mutations did not have this effect. These data are consistent with the terminal bases of the transposon playing multiple and distinct roles in transposition.     

Comparative sequence analysis of IS50/Tn5 transposase

Comparative sequence analysis of IS50 transposase-related protein sequences in conjunction with known structural, biochemical, and genetic data was used to determine domains and residues that play key roles in IS50 transposase function. BLAST and ClustalW analyses have been used to find and analyze six complete protein sequences that are related to the IS50 transposase. The protein sequence identity of these six homologs ranged from 25 to 55% in comparison to the IS50 transposase. Homologous motifs were found associated with each of the three catalytic residues. Residues that play roles in transposase-DNA binding, protein autoregulation, and DNA hairpin formation were also found to be conserved in addition to other residues of unknown function. On the other hand, some homologous sequences did not appear to be competent to encode the inhibitor regulatory protein. The results were also used to compare the IS50 transposase with the more distantly related transposase encoded by IS10.     

Presence of a characteristic D-D-E motif in IS1 transposase

Transposases encoded by various transposable DNA elements and retroviral integrases belong to a family of proteins with three conserved acidic amino acids, D, D, and E, constituting the D-D-E motif that represents the active center of the proteins. IS1, one of the smallest transposable elements in bacteria, encodes a transposase which has been thought not to belong to the family of proteins with the D-D-E motif. In this study, we found several IS1 family elements that were widely distributed not only in eubacteria but also in archaebacteria. The alignment of the transposase amino acid sequences from these IS1 family elements showed that out of 14 acidic amino acids present in IS1 transposase, three (D, D, and E) were conserved in corresponding positions in the transposases encoded by all the elements. Comparison of the IS1 transposase with other proteins with the D-D-E motif revealed that the polypeptide segments surrounding each of the three acidic amino acids were similar. Furthermore, the deduced secondary structures of the transposases encoded by IS1 family elements were similar to one another and to those of proteins with the D-D-E motif. These results strongly suggest that IS1 transposase has the D-D-E motif and thus belongs to the family of proteins with the D-D-E motif. In fact, mutant IS1 transposases with an amino acid substitution for each of the three acidic amino acids possibly constituting the D-D-E motif were not able to promote transposition of IS1, supporting this hypothesis. The D-D-E motif identified in IS1 transposase differs from those in the other proteins in that the polypeptide segment between the second D and third E in IS1 transposase is the shortest, 24 amino acids in length. Because of this difference, the presence of the D-D-E motif in IS1 transposase has not been discovered for some time.     

Cis preference of the IS 903 transposase is mediated by a combination of transposase instability and inefficient translation

The transposase protein encoded by the insertion element IS 903 belongs to an unusual class of DNA-binding proteins, termed cis-acting proteins, that act preferentially at their site of synthesis. Previous work had led us to propose that instability of the IS 903 transposase was a major determinant of its cis preference. Here we describe the isolation of two classes of mutations within the transposase gene that increased action in trans. One class specifically increased trans action without increasing the level of transposition when the mutant gene was located in cis to the transposon. In particular, a threonine-to-proline substitution at amino acid 25 (T25P) reduced cis preference about 60-fold. The half-life of this mutant transposase was significantly longer than that of the wild-type transposase, confirming the critical role of protein instability. The second, larger, class of mutations increased the level of transposition both in trans and in cis. The behaviour and location of these mutations were consistent with an increase in gene expression by improving translational initiation. Several of these mutations exerted a disproportionate effect on the action of transposase in trans, implying that translation efficiency may affect more than just the amount of transposase made. Our results indicate that cis preference of the IS 903 transposase is mediated by a combination of transposase instability and inefficient translation initiation.     

Mutagenesis of the IS1 transposase: importance of a His-Arg-Tyr triad for activity.

Inspection of the primary sequence of the IS1 transposase suggested that it carries residues which are characteristic of the active site of integrases of the bacteriophage lambda family (Int). In particular, these include a highly conserved triad: His-Arg-Tyr. The properties of mutants made at each of these positions were investigated in vivo. The results of several different assays confirm that each is important for transposase activity. Moreover, as in the case of members of the Int family, different mutations of the His residue exhibited different effects. In a particular, His-to-Leu mutation resulted in complete inactivation whereas the equivalent His-to-Gln mutation retained low but significant levels of activity.     

DNA sequences required for translational frameshifting in production of the transposase encoded by IS1.

Summary The transposase encoded by insertion sequence IS 1 is produced from two out-of-phase reading frames (insA and B-insB) by translational frameshifting, which occurs within a run of six adenines in the –1 direction. To determine the sequence essential for frameshifting, substitution mutations were introduced within the region containing the run of adenines and were examined for their effects on frameshifting. Substitutions at each of three (2nd, 3rd and 4th) adenine residues in the run, which are recognized by tRNA^Lys reading insA, caused serious defects in frameshifting, showing that the three adenine residues are essential for frameshifting. The effects of substitution mutations introduced in the region flanking the run of adenines and in the secondary structures located downstream were, however, small, indicating that such a region and structures are not essential for frameshifting. Deletion of a region containing the termination codon of insA caused a decrease in -galactosidase activity specified by the lacZ fusion plasmid in frame with B-insB. Exchange of the wild-type termination codon of insA for a different one or introduction of an additional termination codon in the region upstream of the native termination codon caused an increase in -galactosidase activity, indicating that the termination codon in insA affects the efficiency of frameshifting.