Target DNA bending is an important specificity determinant in target site selection in Tn10 transposition

The bacterial transposon Tn10 inserts preferentially into specific DNA sequences. DNA footprinting and interference studies have revealed that the Tn10-encoded transposase protein contacts a large stretch of target DNA ( approximately 24 bp) and that the target DNA structure is deformed upon incorporation into the transpososome. Target DNA deformation might contribute significantly to target site selection and thus it is of interest to further define the nature of this deformation. Circular permutation analysis was used to demonstrate that the target DNA is bent upon its incorporation into the transpososome. Two lines of evidence are presented that target DNA bending is an important event in target site selection. First, we demonstrate a correlation between increased target site usage and an increased level of target DNA bending. Second, transposase mutants with relaxed target specificity are shown to cause increased target DNA bending relative to wild-type transposase. This latter observation provides new insight into how relaxed specificity may be achieved. We also show that Ca(2+) facilitates target capture by stabilizing transposase interactions with sequences immediately flanking the insertion site. Ca(2+) could, in theory, exert this effect by stabilizing bends in the target DNA.     

Factors responsible for target site selection in Tn10 transposition: a role for the DDE motif in target DNA capture.

Tn10, like several other transposons, exhibits a marked preference for integration into particular target sequences. Such sequences are referred to as integration hotspots and have been used to define a consensus target site in Tn10 transposition. We demonstrate that a Tn10 hotspot called HisG1, which was identified originally in vivo, also functions as an integration hotspot in vitro in a reaction where the HisG1 sequence is present on a short DNA oligomer. We use this in vitro system to define factors which are important for the capture of the HisG1 target site. We demonstrate that although divalent metal ions are not essential for HisG1 target capture, they greatly facilitate capture of a mutated HisG1 site. Analysis of catalytic transposase mutants further demonstrates that the DDE motif plays a critical role in ''divalent metal ion-dependent'' target capture. Analysis of two other classes of transposase mutants, Exc+ Int- (which carry out transposon excision but not integration) and ATS (altered target specificity), demonstrates that while a particular ATS transposase binds HisG1 mutants better than wild-type transposase, Exc+ Int- mutants are defective in HisG1 capture, further defining the properties of these classes of mutants. Possible mechanisms for the above observations are considered.     

Target Capture during Mos1 Transposition

DNA transposition contributes to genomic plasticity. Target capture is a key step in the transposition process, because it contributes to the selection of new insertion sites. Nothing or little is known about how eukaryotic mariner DNA transposons trigger this step. In the case of Mos1, biochemistry and crystallography have deciphered several inverted terminal repeat-transposase complexes that are intermediates during transposition. However, the target capture complex is still unknown. Here, we show that the preintegration complex (i.e., the excised transposon) is the only complex able to capture a target DNA. Mos1 transposase does not support target commitment, which has been proposed to explain Mos1 random genomic integrations within host genomes. We demonstrate that the TA dinucleotide used as the target is crucial both to target recognition and in the chemistry of the strand transfer reaction. Bent DNA molecules are better targets for the capture when the target DNA is nicked two nucleotides apart from the TA. They improve strand transfer when the target DNA contains a mismatch near the TA dinucleotide.     

Intramolecular transposition by Tn10

Transposon Tn10 promotes the formation of a circular product containing only transposon sequences. We show that these circles result from an intramolecular transposition reaction in which all of the strand cleavage and ligation events have occurred but newly created transposon/target junctions have not undergone repair. The unligated strand termini at these junctions are those expected according to a simple model in which the target DNA is cleaved by a pair of staggered nicks 9 bp apart, transposon sequences are separated from flanking donor DNA by cleavage at the terminal nucleotides on both strands (at both ends) of the element, and 3' transposon strand ends are ligated to 5' target strand ends. The stability of the unligated junctions suggests that they are protected from cellular processing by transposase and/or host proteins. We propose that the nonreplicative nature of Tn10 transposition is determined by the efficiency with which the nontransferred transposon strand is separated from flanking donor DNA and by the nature of the protein-DNA complexes present at the strand transfer junctions.     

Alternative interactions between the Tn7 transposase and the Tn7 target DNA binding protein regulate target immunity and transposition

The Tn7 transposon avoids inserting into a target DNA that contains a pre-existing copy of Tn7. This phenomenon, known as 'target immunity', is established when TnsB, a Tn7 transposase subunit, binds to Tn7 sequences in the target DNA and mediates displacement of TnsC, a critical transposase activator, from the DNA. Paradoxically, TnsB-TnsC interactions are also required to promote transposon insertion. We have probed Tn7 target immunity by isolating TnsB mutants that mediate more frequent insertions into a potentially immune target DNA because they fail to provoke dissociation of TnsC from the DNA. We show that a single region of TnsB mediates the TnsB-TnsC interaction that underlies both target immunity and transposition, but that TnsA, the other transposase subunit, channels the TnsB-TnsC interaction toward transposition.     

Tn5 as a model for understanding DNA transposition

Tn5 is an excellent model system for understanding the molecular basis of DNA-mediated transposition. Mechanistic information has come from genetic and biochemical investigations of the transposase and its interactions with the recognition DNA sequences at the ends of the transposon. More recently, molecular structure analyses of catalytically active transposase; transposon DNA complexes have provided us with unprecedented insights into this transposition system. Transposase initiates transposition by forming a dimeric transposase, transposon DNA complex. In the context of this complex, the transposase then catalyses four phosphoryl transfer reactions (DNA nicking, DNA hairpin formation, hairpin resolution and strand transfer into target DNA) resulting in the integration of the transposon into its new DNA site. The studies that elucidated these steps also provided important insights into the integration of retroviral genomes into host DNA and the immune system V(D)J joining process. This review will describe the structures and steps involved in Tn5 transposition and point out a biologically important although surprising characteristic of the wild-type Tn5 transposase. Transposase is a very inactive protein. An inactive transposase protein ensures the survival of the host and thus the survival of Tn5.     

Formation of a nucleoprotein complex containing Tn7 and its target DNA regulates transposition initiation

Tn7 insertion into its specific target site, attTn7, is mediated by the proteins TnsA, TnsB, TnsC and TnsD. The double-strand breaks that separate Tn7 from the donor DNA require the Tns proteins, the transposon and an attTn7 target DNA, suggesting that a prerequisite for transposition is the formation of a nucleoprotein complex containing TnsABC+D, and these DNAs. Here, we identify a TnsABC+D transposon-attTn7 complex, and demonstrate that it is a transposition intermediate. We demonstrate that an interaction between TnsB, the transposase subunit that binds to the transposon ends, and TnsC, the target DNA-binding protein that controls the activity of the transposase, is essential for assembly of the TnsABC+D transposon-attTn7 complex. We also show that certain TnsB residues are required for recombination because they mediate a TnsB-TnsC interaction critical to formation of the TnsABC+D transposon-attTn7 complex. We demonstrate that TnsA, the other transposase subunit, which also interacts with TnsC, greatly stabilizes the TnsABC+D transposon-attTn7 complex. Thus multiple interactions between the transposase subunits, TnsA and TnsB, and the target-binding transposase activator, TnsC, control Tn7 transposition.     

Substrate recognition and induced DNA deformation by transposase at the target-capture stage of Tn10 transposition

The bacterial transposon Tn10 inserts preferentially into sites that conform to a 9 bp consensus sequence: 5' NGCTNAGCN 3'. However, this sequence is not on its own sufficient to confer target specificity as the base-pairs flanking this sequence also contribute significantly to target-site selection. We have performed a series of "contact-probing experiments" to define directly the protein-DNA interactions that govern target-site selection in the Tn10 system. The HisG1 hotspot for Tn10 insertion was the main focus here. We infer that there is a rather broad zone ( approximately 24 bp) of contact between transposase and target DNA in the target-capture complex. This includes base-specific contacts at all of the purine residues in the consensus positions of the target core and primarily backbone contacts out to 7-8 bp in the two flanking regions immediately adjacent to the core. Also, highly localized sites of chemical hypersensitivity are identified that reveal symmetrically disposed deformations in DNA structure in the target-capture complex. Furthermore, the level of strand transfer is shown to be reduced by phosphorothioate substitution of phosphate groups at or close to the sites of target DNA deformation. Interestingly, for one particular target DNA, a mutant form of HisG1 called MutF, the above phosphorothioate inhibition of strand transfer is suppressed by replacing Mg(2+) with Mn(2+). Based on these results a model for sequence-specific target capture is proposed which attempts to define possible relationships between transposase interactions with the target core and flanking sequences, transposase-induced DNA deformation of the target site and divalent metal ion binding to the target-capture complex.     

Single active site catalysis of the successive phosphoryl transfer steps by DNA transposases: insights from phosphorothioate stereoselectivity

The transposase family of proteins mediate DNA transposition or retroviral DNA integration via multistep phosphoryl transfer reactions. For Tn10 and phage Mu, a single active site of one transposase protomer catalyzes the successive transposition reaction steps. We examined phosphorothioate stereoselectivity at the scissile position for all four reaction steps catalyzed by the Tn10 transposase. The results suggest that the first three steps required for double-strand cutting at the transposon end proceed as a succession of pseudo-reverse reaction steps while the 3' end of the transposon remains bound to the same side of the active site. However, the mode of substrate binding to the active site changes for the cut transposon 3' end to target DNA strand joining. The phosphorothioate stereoselectivity of the corresponding steps of phage Mu transposition and HIV DNA integration matches that of Tn10 reaction, indicating a common mode of substrate-active site interactions for this class of DNA transposition reactions.     

The positive and negative regulation of Tn10 transposition by IHF is mediated by structurally asymmetric transposon arms

The Tn10 transpososome has symmetrical components on either side: there are two transposon ends each of which has binding sites for a monomer of transposase and an IHF heterodimer. The DNA bending activity of IHF stimulates assembly of an intermediate with tightly folded transposon ends in which transposase has additional ‘subterminal’ DNA contacts, located distal to the IHF site. These subterminal contacts are required to activate later steps in the reaction. Quantitative hydroxyl radical footprinting and gel retardation unfolding experiments show that the transpososome is fundamentally asymmetric, despite having identical components on either side. Major differences between the transposon ends define α and β sides of the complex. IHF can dissociate from the transposon arm on the β side of the complex in the absence of metal ion. However, IHF is locked onto the α side of the complex, probably by the subterminal transposase contacts, until released by a metal ion-dependent conformational change. Later in the reaction, IHF inhibits target interactions. Using a very short transposon arm, target interactions are demonstrated at a saturating IHF concentration. This suggests that inhibition of target interactions is due to steric hindrance of the target binding site by a single IHF-folded transposon arm.     

Solution conformations of early intermediates in Mos1 transposition

DNA transposases facilitate genome rearrangements by moving DNA transposons around and between genomes by a cut-and-paste mechanism. DNA transposition proceeds in an ordered series of nucleoprotein complexes that coordinate pairing and cleavage of the transposon ends and integration of the cleaved ends at a new genomic site. Transposition is initiated by transposase recognition of the inverted repeat sequences marking each transposon end. Using a combination of solution scattering and biochemical techniques, we have determined the solution conformations and stoichiometries of DNA-free Mos1 transposase and of the transposase bound to a single transposon end. We show that Mos1 transposase is an elongated homodimer in the absence of DNA and that the N-terminal 55 residues, containing the first helix-turn-helix motif, are required for dimerization. This arrangement is remarkably different from the compact, crossed architecture of the dimer in the Mos1 paired-end complex (PEC). The transposase remains elongated when bound to a single-transposon end in a pre-cleavage complex, and the DNA is bound predominantly to one transposase monomer. We propose that a conformational change in the single-end complex, involving rotation of one half of the transposase along with binding of a second transposon end, could facilitate PEC assembly.     

Tn5 transposase loops DNA in the absence of Tn5 transposon end sequences

Transposases mediate transposition first by binding specific DNA end sequences that define a transposable element and then by organizing protein and DNA into a highly structured and stable nucleoprotein 'synaptic' complex. Synaptic complex assembly is a central checkpoint in many transposition mechanisms. The Tn5 synaptic complex contains two Tn5 transposase subunits and two Tn5 transposon end sequences, exhibits extensive protein-end sequence DNA contacts and is the node of a DNA loop. Using single-molecule and bulk biochemical approaches, we found that Tn5 transposase assembles a stable nucleoprotein complex in the absence of Tn5 transposon end sequences. Surprisingly, this end sequence-independent complex has structural similarities to the synaptic complex. This complex is the node of a DNA loop; transposase dimerization and DNA specificity mutants affect its assembly; and it likely has the same number of proteins and DNA molecules as the synaptic complex. Furthermore, our results indicate that Tn5 transposase preferentially binds and loops a subset of non-Tn5 end sequences. Assembly of end sequence-independent nucleoprotein complexes likely plays a role in the in vivo downregulation of transposition and the cis-transposition bias of many bacterial transposases.     

Structural role of the flanking DNA in mariner transposon excision

During cut-and-paste mariner/Tc1 transposition, transposon DNA is cut precisely at its junction with flanking DNA, ensuring the transposon is neither shortened nor lengthened with each transposition event. Each transposon end is flanked by a TpA dinucleotide: the signature target site duplication of mariner/Tc1 transposition. To establish the role of this sequence in accurate DNA cleavage, we have determined the crystal structure of a pre-second strand cleavage mariner Mos1 transpososome. The structure reveals the route of an intact DNA strand through the transposase active site before second strand cleavage. The crossed architecture of this pre-second strand cleavage paired-end complex supports our proposal that second strand cleavage occurs in trans. The conserved mariner transposase WVPHEL and YSPDL motifs position the strand for accurate DNA cleavage. Base-specific recognition of the flanking DNA by conserved amino acids is revealed, defining a new role for the WVPHEL motif in mariner transposition and providing a molecular explanation for in vitro mutagenesis data. Comparison of the pre-TS cleavage and post-cleavage Mos1 transpososomes with structures of Prototype Foamy Virus intasomes suggests a binding mode for target DNA prior to Mos1 transposon integration.     

Promiscuous target interactions in the mariner transposon Himar1

We have previously characterized the early intermediates of mariner transposition. Here we characterize the target interactions that occur later in the reaction. We find that, in contrast to the early transposition intermediates, the strand transfer complex is extremely stable and difficult to disassemble. Transposase is tightly bound to the transposon ends constraining rotation of the DNA at the single strand gaps in the target site flanking the element on either side. We also find that although the cleavage step requires Mg2+ or Mn2+ as cofactor, the strand transfer step is also supported by Ca2+, suggesting that the structure of the active site changes between cleavage and insertion. Finally, we show that, in contrast to the bacterial cut and paste transposons, mariner target interactions are promiscuous and can take place either before or after cleavage of the flanking DNA. This is similar to the behavior of the V(D)J system, which is believed to be derived from an ancestral eukaryotic transposon. We discuss the implications of promiscuous target interactions for promoting local transposition and whether this is an adaptation to facilitate the invasion of a genome following horizontal transfer to a new host species.     

DNA looping and catalysis; the IHF-folded arm of Tn10 promotes conformational changes and hairpin resolution

DNA loops and bends are common features of DNA processing machines. The bacterial transposon Tn10 has recruited integration host factor (IHF), a site-specific DNA-bending protein, as an architectural component for assembly of the higher-order nucleoprotein complex within which the transposition reaction takes place. Here, we demonstrate additional roles for the IHF loop during the catalytic steps of the reaction. We show that metal ion-dependent unfolding of the IHF-bent transposon arm is communicated to the catalytic center, inducing a substantial conformational change in the DNA. Partial disruption of the IHF loop shows that this step promotes resolution of the hairpin intermediate on one transposon end and initiation of catalysis at the other. Further evidence suggests that the molecular mechanism responsible may be mechanical stress in the IHF loop, related to a change in the relative position of the transposase contacts that anchor the loop on either side.     

Structural Basis for the Inverted Repeat Preferences of mariner Transposases

The inverted repeat (IR) sequences delimiting the left and right ends of many naturally active mariner DNA transposons are non-identical and have different affinities for their transposase. We have compared the preferences of two active mariner transposases, Mos1 and Mboumar-9, for their imperfect transposon IRs in each step of transposition: DNA binding, DNA cleavage, and DNA strand transfer. A 3.1 Å resolution crystal structure of the Mos1 paired-end complex containing the pre-cleaved left IR sequences reveals the molecular basis for the reduced affinity of the Mos1 transposase DNA-binding domain for the left IR as compared with the right IR. For both Mos1 and Mboumar-9, in vitro DNA transposition is most efficient when the preferred IR sequence is present at both transposon ends. We find that this is due to the higher efficiency of cleavage and strand transfer of the preferred transposon end. We show that the efficiency of Mboumar-9 transposition is improved almost 4-fold by changing the 3′ base of the preferred Mboumar-9 IR from guanine to adenine. This preference for adenine at the reactive 3′ end for both Mos1 and Mboumar-9 may be a general feature of mariner transposition.     

Transposase promotes double strand breaks and single strand joints at Tn10 termini in vivo

We present evidence that Tn10 transposase promotes double strand breaks and single strand joints at Tn10 termini in vivo. Plasmids containing a shortened Tn10 element and a transposase overproducer fusion give rise, upon transposase induction, to new DNA species. The most prominent class is a circularized transposon molecule whose structure suggests that it arises from double strand breakage at the two transposon ends followed by covalent joining between the 3' and 5' ends of one of the two strands. We have used formation of the circularized transposon as a physical assay for the interaction between transposase and different mutant and wild-type termini. These experiments show that transposase protein interacts preferentially with the genetically most active termini in a way that suppresses productive interaction with weaker termini present on the same substrate molecule.     

Hairpin formation in Tn5 transposition

The initial chemical steps in Tn5 transposition result in blunt end cleavage of the transposon from the donor DNA. We demonstrate that this cleavage occurs via a hairpin intermediate. The first step is a 3' hydrolytic nick by transposase. The free 3'OH then attacks the phosphodiester bond on the opposite strand, forming a hairpin at the transposon end. In addition to forming precise hairpins, Tn5 transposase can form imprecise hairpins. This is the first example of imprecise hairpin formation on transposon end DNA. To undergo strand transfer, the hairpin must to be resolved by a transposase-catalyzed hydrolytic cleavage. We show that both precise and imprecise hairpins are opened by transposase. A transposition mechanism utilizing a hairpin intermediate allows a single transposase active site to cleave both 3' and 5' strands without massive protein/DNA rearrangements.     

Mapping the transition state for DNA bending by IHF

How DNA-bending proteins recognize their specific sites on DNA remains elusive, particularly for proteins that use indirect readout, which relies on sequence-dependent variations in DNA flexibility/bendability. The question remains as to whether the protein bends the DNA (protein-induced bending) or, alternatively, "prebent" DNA conformations are thermally accessible, which the protein captures to form the specific complex (conformational capture). To distinguish between these mechanisms requires characterization of reaction intermediates and, in particular, snapshots of the transition state along the recognition pathway. We present such a snapshot, from measurements of DNA bending dynamics in complex with Escherichia coli integration host factor (IHF), an architectural protein that bends specific sites on λ-DNA in a U-turn by creating two sharp kinks in DNA. Fluorescence resonance energy transfer measurements in response to laser temperature-jump perturbation monitor DNA bending. We find that nicks or mismatches that enhance DNA flexibility at the site of the kinks show 3- to 4-fold increase in DNA bending rates that reflect a 4- to 11-fold increase in binding affinities, while sequence modifications away from the kink sites, as well as mutations in IHF designed to destabilize the complex, have negligible effect on DNA bending rates despite >250-fold decrease in binding affinities. These results support the scenario that the bottleneck in the recognition step for IHF is spontaneous kinking of cognate DNA to adopt a partially prebent conformation and point to conformational capture as the underlying mechanism of initial recognition, with additional protein-induced bending occurring after the transition state.     

Reorganization of the Mu transpososome active sites during a cooperative transition between DNA cleavage and joining

Transposition of mobile genetic elements proceeds through a series of DNA phosphoryl transfer reactions, with multiple reaction steps catalyzed by the same set of active site residues. Mu transposase repeatedly utilizes the same active site DDE residues to cleave and join a single DNA strand at each transposon end to a new, distant DNA location (the target DNA). To better understand how DNA is manipulated within the Mu transposase-DNA complex during recombination, the impact of the DNA immediately adjacent to the Mu DNA ends (the flanking DNA) on the progress of transposition was investigated. We show that, in the absence of the MuB activator, the 3 '-flanking strand can slow one or more steps between DNA cleavage and joining. The presence of this flanking DNA strand in just one active site slows the joining step in both active sites. Further evidence suggests that this slow step is not due to a change in the affinity of the transpososome for the target DNA. Finally, we demonstrate that MuB activates transposition by stimulating the reaction step between cleavage and joining that is otherwise slowed by this flanking DNA strand. Based on these results, we propose that the 3 '-flanking DNA strand must be removed from, or shifted within, both active sites after the cleavage step; this movement is coupled to a conformational change within the transpososome that properly positions the target DNA simultaneously within both active sites and thereby permits joining.