IS10/Tn10 transposition efficiently accommodates diverse transposon end configurations.

Transposon Tn10 and its component insertion sequence IS10 move by non-replicative transposition. We have studied the array of reaction intermediates and products in a high efficiency in vitro IS10/Tn10 transposition reaction. Synapsis of two transposon ends, followed by cleavage and strand transfer, can occur very efficiently irrespective of the relative locations and orientations of the two ends. The two participating ends can occur in inverted or direct orientation on the same molecule or, most importantly, on two different molecules. This behavior contrasts sharply with that of Mu, in which transposition is strongly biased in favor of inverted repeat synapsis. Mechanistically, the absence of discrimination amongst various end configurations implies that the architecture within the IS10/Tn10 synaptic complex is relatively simple, i.e. lacking any significant intertwining of component DNA strands. Biologically these observations are important because they suggest that the IS10 insertion sequence module has considerable flexibility in the types of DNA rearrangements that it can promote. Most importantly, it now seems highly probable that a single non-replicative IS10 element can promote DNA rearrangements usually attributed to replicative transposition, i.e. adjacent deletions and cointegrates, by utilizing transposon ends on two sister chromosomes. Other events which probably also contribute to the diversity of IS10/Tn10-promoted rearrangements are discussed.     

Multiple IS10 rearrangements in Escherichia coli

We have investigated the occurrence of multiple transposon-promoted chromosomal rearrangements in Escherichia coli K12 strains containing transposon Tn10. We show that a single Tn10 element, with its two closely spaced insertion sequence (IS10) elements, frequently gives rise to complex rearrangements that can be accounted for as the sum of two "classical" IS10 events. Using a strain containing differentially marked Tn10 elements at widely separated locations, we have investigated the possibility that IS10-promoted rearrangements occur in cell-wide "bursts", as expected if cells could occasionally undergo brief periods when all IS10 transposition events were activated, interspersed with longer periods of relative quiescence. We find no evidence for strong (greater than 60-fold), periodic cell-wide activation under our experimental conditions. The sensitivity of this experiment has been evaluated using an expression for the accumulation of double mutations in populations with heterogeneous, fluctuating mutation rates (see Appendix). We discuss several mechanisms by which two closely linked IS10 elements could undergo coupled double events without cell-wide activation: local activation of small chromosomal regions, periodic bursts of synthesis of cis-acting transposase protein, and/or a propensity for elements that have actually engaged in one rearrangement event to initiate a second successive event immediately thereafter. We favor the last possibility.     

A comparison of intramolecular rearrangements promoted by transposons Tn5 and Tn10.

The bacterial transposon Tn10 has previously been shown to move to other genomic sites by a conservative mechanism, whereby the transposon is excised by double-strand breaks and inserted between a pair of staggered nicks at the target. Other transposons, like Tn3, have been shown to transpose by a replicative mechanism that involves symmetrical nicking of the element and formation of the 'Shapiro intermediate', which can mature into either a cointegrate or a simple insert. The situation with respect to Tn5 is unclear; it was originally reported to use a conservative mechanism, but other evidence suggests that the mechanism might be replicative. In this paper, rearrangements of adjacent DNA promoted by Tn10 and Tn5 have been compared using positive selection for galactose-resistance to detect such rearrangements. Tn10 promoted the formation of adjacent deletions (that started from an inside end of Tn10), deletion/inversions and simple IS10 insertions, but no cointegrates. This behaviour is fully consistent with a conservative mechanism. In contrast, Tn5 was found to promote formation of adjacent deletions (that started mainly from an outside end of Tn5), IS50 insertions (that were frequently accompanied by inversions of adjacent DNA) and cointegrates. These characteristics seem compatible with a replicative, rather than a conservative, mode of transposition. Clearly, Tn5 and Tn10 exhibit some significant differences in their transposition. These results, and results of some previous experiments, have been interpreted to mean that Tn5 could use a replicative mechanism for its transposition.     

Transposon Tn10: genetic organization, regulation, and insertion specificity

Transposon Tn10 is a composite element in which two individual insertion sequence (IS)-like sequences cooperate to mediate transposition of the intervening material. The two flanking IS10 elements are not identical; IS10-right is responsible for functions required to promote transposition, and IS10-left is defective in transposition functions. We suggest that the two IS10 elements were originally identical in sequence and have subsequently diverged. IS10-right is compactly organized with structural gene(s), promoters, and sites important for transposition and (presumably) its regulation all closely linked and, in some cases, overlapping. IS10 has a single major coding region that almost certainly encodes an essential transposition function. A pair of opposing promoters flank the start of this coding region. One of these promoters is responsible for expression in vivo of transposon-encoded transposition functions. We propose that the second promoter is involved in modulation of Tn10 transposition. Genetic analysis suggests that transposon-encoded function(s) may be preferentially cis-acting. Insertion of Tn10 into particular preferred target sites is due primarily to the occurrence of a particular six-base pair target DNA sequence. The properties of this sequence suggest that symmetrically disposed subunits of a single protein may be responsible for both recognition and cleavage of target DNA during insertion.     

Inversions and deletions of the Salmonella chromosome generated by the translocatable tetracycline resistance element Tn10

Spontaneous tetraoyoline-sensitive derivatives of a Tn10 insertion in the hisG gene of Salmonella typhimurium were isolated and subjected to genetic analysis. All 123 of the drug-sensitive derivatives characterized have undergone stable alterations in the Tn10 element itself; over half of the derivatives have also undergone major alterations of neighboring regions of the Salmonella chromosome. These chromosomal rearrangements are of two types: inversions and deletions. Any single inversion or deletion affects a contiguous stretch of chromosomal material extending from the site of the original Tn10 element either leftward or rightward.The genetic properties of deletion and inversion derivatives suggest that these chromosomal alterations are promoted by the Tn10 element itself. The role of translocatable elements in promoting chromosomal deletions is well documented; the ability of an element to promote inversions of chromosomal material has not previously been reported. Possible analogies between the 1400-base-pair inverted repetition at the end of Tn10 and the small insertion sequence IS1 predict particular structures for Tn10-promoted deletions. A structural explanation or model for Tn10-promoted inversions is presented. The observation that Tn10 promotes the formation of inversions suggests that such elements could play a previously unanticipated role in promoting chromosomal inversions during evolution of prokaryotic organisms. Generally applicable genetic methods for the identification and characterization of chromosomal inversions are described.     

IS10 transposition is regulated by DNA adenine methylation

We show that dam- mutants are a major class of E. coli mutants with increased IS10 activity. IS10 has two dam methylation sites, one within the transposase promoter and one within the inner terminus where transposase presumably binds. Absence of methylation results in increased activity of both promoter and terminus, and completely accounts for increased transposition in dam- strains. Transposition of Tn903 and Tn5 are also increased in dam- strains, probably for analogous reasons. Transposition is also increased when IS10 is hemimethylated. One hemimethylated species is much more active than the other and is estimated to be at least 1000 times more active than a fully methylated element. Evidence is presented that the promoter and inner terminus of IS10 are coordinately activated in a dam-dependent fashion, presumably because they are hemimethylated at the same time. Thus, in dam+ strains, IS10 will transpose preferentially when DNA is hemimethylated. We suggest specifically that IS10 transposition may preferentially occur immediately after passage of a chromosomal replication fork.     

Genetic organization of transposon Tn10

Transposon Tn10 is 9300 bp in length, with 1400 bp inverted repeats at its ends. The inverted repeats are structurally intact IS-like sequences (Ross et al., 1979). Analysis of deletion mutants and structural variants of Tn10, reported below, shows that the two IS10 segments contain all of the Tn10-encoded genetic determinants, both sites and functions, that are required for transposition. Furthermore, the two repeats (IS10-Right and IS10-Left) are not functionally equivalent: IS10-Right is fully functional and is capable by itself of promoting normal levels of Tn10 transposition; IS10-Left functions only poorly by itself, promoting transposition at a very low level when IS10-Right is inactivated. Complementation analysis shows that IS10-Right encodes at least one function, required for Tn10 transposition, which can act in trans and which works at the ends of the element. Also, all of the sites specifically required for normal Tn10 transposition have been localized to the outermost 70 bp at each end of the element; there is no evidence that specific sites internal to the element play an essential role. Finally, Tn10 modulates its own transposition in such a way that transposition-defective point mutants, unlike deletion mutants, are not complemented by functions provided in trans; and wild-type Tn10, unlike deletion mutants, is not affected by functions provided in trans from a "high hopper" Tn10 element.     

Specificity of Tn9 insertion into the genome of bacteriophage lambda att80 depending on its preceding location

It was shown that the site of previous integration (the donor site) of Tn9 affects the specificity of its next integration into the target molecule--phage lambda att80 DNA. The transposon integration sites were mapped by restriction and heteroduplex analysis following Tn9 transposition from chromosomal sites of Escherichia coli K-12 differing in location and Tn9 stability. When transposed from chromosomal galT::IS1 gene, Tn9 inserted into the site with coordinates 44,5 +/- 2 kb of lambda att80; when transposed from chromosomal attTn9A site, the transposon inserted into the sites with coordinates 31 +/- 0,7 kb or 33,3 +/- 0,5 kb. In the course of transposition of Tn9 from chromosomal attTn9N site the transposon inserted into the lambda att80 site with coordinates 26,5 +/- 5 kb. In the latter case, the increase of Tn9 single-stranded loop and the appearance of two new HindIII cleavage sites were observed in heteroduplex experiments. The data were interpreted as indicating structural rearrangements of Tn9 or linked sequences in the course of transposition.     

Multiple copies of IS10 in the Enterobacter cloacae MD36 chromosome.

Repetitive sequences were isolated and characterized as double-stranded DNA fragments by treatment with S1 nuclease after denaturation and renaturation of the total DNA of Enterobacter cloacae MD36. One repetitive sequence was identical to the nucleotide sequence of IS10-right (IS10R), which is the active element in the plasmid-associated transposon Tn10. Unexpectedly, 15 copies of IS10R were found in the chromosomal DNA of E. cloacae MD36. One copy of the central region of Tn10 was found in the total DNA of E. cloacae MD36. IS10Rs in restriction fragments isolated from the E. cloacae MD36 total DNA showed 9-bp duplications adjacent to the terminal sequences that are characteristic of Tn10 transposition. This result suggests that many copies of IS10R in E. cloacae MD36 are due to transposition of IS10R alone, not due to transposition of Tn10 or to DNA rearrangement. I also found nine copies of IS10 in Shigella sonnei HH109, two and four copies in two different natural isolates of Escherichia coli, and two copies in E. coli K-12 strain JM109 from the 60 bacterial strains that were examined. All dam sites in the IS10s in E. cloacae MD36 and S. sonnei HH109 were methylated. Tn10 and IS10 transpose by a mechanism in which the element is excised from the donor site and inserted into the new target site without significant replication of the transposing segment; thus, the copy numbers of the elements in the cell are thought to be unchanged in most circumstances. Accumulation of IS10 copies in E. cloacae MD36 has interesting evolutionary implications.     

Tn10 transposition and circle formation in vitro

We describe a cell-free system that promotes Tn10 transposition and transposon circle formation, a related intramolecular event. Tn10 circle formation in vitro has been characterized in detail, and is shown to require a supercoiled substrate and to proceed in the absence of ATP. The reaction requires Tn10 transposase protein, and either of two E. coli proteins, integration host factor (IHF) and HU, which are small DNA binding proteins that change the conformation of DNA. Tn10 is composed of inverted repeats of insertion sequence IS10. Pair-wise combinations of the IS10 "outside" and "inside" ends mediate distinct classes of rearrangements in vivo, and they exhibit different reaction requirements in vitro. In contrast to the Tn10 reaction, which involves two outside ends, circle formation with two inside ends proceeds with a transposase fraction alone, in the absence of added host factors, and is inhibited by methylation of the dam site within each terminus.     

IS50-mediated inverse transposition: specificity and precision

The IS50 elements, which are present as inverted repeats in the kanamycin-resistance transposon, Tn5, can move in unison carrying with them any interstitial DNA segment. In consequence, DNA molecules such as a lambda::Tn5 phage genome are composed of two overlapping transposons - the kan segment bracketed by IS50 elements (Tn5), and lambda bracketed by IS50 elements. During direct transposition, mediated by IS50 "O" (outside) ends, the kan gene is moved and the lambda vector is left behind. During inverse transposition, mediated by the "I" (inside) ends of the IS50 elements, the lambda vector segment is moved and the kan gene is left behind. Direct transposition is several orders of magnitude more frequent than inverse transposition (Isberg and Syvanen, 1981; Sasakawa and Berg, 1982). We assessed the specificity and precision of the rare events mediated by pairs of I ends by mapping and sequencing independent inverse transpositions from a lambda::Tn5 phage into the amp and tet genes of plasmid pBR322. Using restriction analyses, 32 and 40 distinct sites of insertion were found among 46 and 72 independent inverse transpositions into the amp and tet genes, respectively. Eleven sites were used in two or more insertion events, and the two sites in tet used most frequently corresponded to major hotspots for the insertion of the Tn5 (by direct transposition). The sequences of 22 sites of inverse transposition (including each of the sites used more than once) were determined, in eleven cases by analyzing both pBR322-IS50 junctions, and in eleven others by sequencing one junction. The sequence of the "I" end of IS50 was preserved and 9-bp target sequence duplications were present in every case analyzed. GC pairs were found at each end of the target sequence duplication in ten of the eleven sites used more than once, and also in seven of the other eleven sites. Our data indicate that transposition mediated by pairs of "I" ends is similar in its specificity and precision to the more frequent transposition mediated by IS50 "O" ends.     

Three Tn10-associated excision events: relationship to transposition and role of direct and inverted repeats

We describe three related DNA alterations associated with transposon Tn10: precise excision of Tn10, nearly precise excision of Tn10 and precise excision of the nearly precise excision remnant. DNA sequence analysis shows that each of these alterations results in excision of all or part of the Tn10 element, and each involves specific repeat sequences at or near the ends of the element. Furthermore, all three events are structurally analogous: in each case, excision occurs between two short direct-repeat sequences, with resulting deletion of all intervening material plus one copy of the direct repeat; and in all three cases, the direct repeats involved occur at either end of an inverted repeat. Analysis of mutant Tn10 elements and characterization of bacterial host mutations suggest that all three types of excision events occur by pathways that are fundamentally distinct from the pathway(s) for Tn10-promoted transposition and other DNA rearrangements (deletions and inversions) actively promoted by the element. In addition, precise excision and nearly precise excision appear to occur by very closely related or identical pathways; and several lines of evidence suggest that the 1400 bp inverted repeats at the ends of Tn10 may play a structural role in both of these events. The third excision event appears to occur by yet another pathway.     

Mechanisms of metal ion action in Tn10 transposition

Tn10/IS10 transposition involves assembly of a synaptic complex (or transpososome) in which two transposon ends are paired, followed by four distinct chemical steps at each transposon end. The chemical steps are dependent on the presence of a suitable divalent metal cation (Me(2+)). Transpososome assembly and structure are also affected by Me(2+). To gain further insight into the mechanisms of Me(2+) action in Tn10/IS10 transposition we have investigated the effects of substituting Mn(2+) for Mg(2+), the physiologic Me(2+), in transposition. We have also investigated the significance of an Me(2+)-assisted conformational change in transpososome structure. We show that Mn(2+) has two previously unrecognized effects on the Tn10 donor cleavage reaction. It accelerates the rates of hairpin formation and hairpin resolution without significantly affecting the rate of the first chemical step, first strand nicking. Mn(2+) also relaxes the specificity of first strand nicking. We also show that Me(2+)-assisted transpososome unfolding coincides with a structural transition in the transposon-donor junction that may be necessary for hairpin formation. Possible mechanisms for these observations are considered.     

The effect of host-encoded nucleoid proteins on transposition: H-NS influences targeting of both IS903 and Tn10

Nucleoid proteins are small, abundant, DNA-binding proteins that profoundly affect the local and global structure of the chromosome, and play a major role in gene regulation. Although several of these proteins have been shown to enhance assembly of transpososomes before initiating transposition, no systematic survey has been carried out examining the in vivo role(s) of these proteins in transposition. We have examined the requirement of the six most abundant nucleoid proteins in transposition for three different transposons, IS903, Tn10 and Tn552. Most notably, H-NS was required for efficient transposition of all three elements in a papillation assay, suggesting a general role for H-NS in bacterial transposition. Further studies indicated that H-NS was exerting its effect on target capture. Targeting preferences for IS903 into the Escherichia coli chromosome were dramatically altered in the absence of H-NS. In addition, the alterations observed in the IS903 target profile emphasized the important role that H-NS plays in chromosome organization. A defect in target capture was also inferred for Tn10, as an excised transposon fragment, a precursor to target capture, accumulated in in vivo induction assays. Furthermore, a transposase mutant that is known to increase target DNA bending and to relax target specificity eliminated this block to target capture. Together, these results imply a role for H-NS in target capture, either by providing regions of DNA more accessible to transposition or by stabilizing transpososome binding to captured targets immediately before strand transfer.     

Lack of hotspot targets: a constraint for IS30 transposition in Salmonella

IS30 is an insertion element common in E. coli strains but rare or absent in Salmonella. Transfer of the IS30-flanked transposon Tn2700 to Salmonella typhimurium was assayed using standard delivery procedures of bacterial genetics (conjugation and transduction). Tn2700 'hops' were rare and required transposase overproduction, suggesting the existence of host constraints for IS30 activity. Sequencing of three Tn2700 insertions in the genome of S. typhimurium revealed that the transposon had been inserted into sites with a low homology to the IS30 consensus target, suggesting that inefficient Tn2700 transposition to the Salmonella genome might be caused by a lack of hotspot targets. This view was confirmed by the introduction of an IS30 'hot target sequence', whose sole presence permitted Tn2700 transposition without transposase overproduction. Detection of IS30-induced DNA rearrangements in S. typhimurium provided further evidence that the element undergoes similar activities in E. coli and S. typhimurium. Thus, hotspot absence may be the main (if not the only) limitation for IS30 activity in the latter species. If these observations faithfully reproduce the scenario of natural populations, establishment of IS30 in the Salmonella genome may have been prevented by a lack of DNA sequences closely related to the unusually long (24 bp) IS30 consensus target.     

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.     

Independence of the processes of transposition and genome rearrangements induced by transposons

The data on the influence of the tnm mutations affecting transposition process on the deletion formation promoted by Tn and IS elements are presented. It was shown that the tnm mutations did not affect the frequency of deletion formation. The results of genetic analysis of the tnm mutant deficient in both transposition and genomic rearrangements induced by Tn9 inserted into lambda prophage, indicated that the mutant phenotype was caused by two different but linked mutations. A mutation affecting the process of genomic rearrangements was designated gerA2. The gerA2 mutation decreased sharply the frequency of rearrangements promoted by Tn9, Tn10 or Tn601 inserted into lambda prophage. However, this mutation had no influence upon transposition of the same Tn elements. The data obtained could be interpreted as indicating the independence of the processes of transposition and genomic rearrangements or as indication of the existence of specific steps of these processes.