Determinants for hairpin formation in Tn10 transposition

The telomere resolvase, TelA, utilizes an underwound pre-cleavage intermediate to promote hairpin telomere formation

The telomere resolvase, TelA, forms the hairpin telomeres of the linear chromosome of Agrobacterium tumefaciens in a process referred to as telomere resolution. Telomere resolution is a unique DNA cleavage and rejoining reaction that resolves replicated telomere junctions into a pair of hairpin telomeres. Telomere resolvases utilize a reaction mechanism with similarities to that of topoisomerase-IB enzymes and tyrosine recombinases. The reaction proceeds without the need for high-energy cofactors due to the use of a covalent, enzyme-cleaved DNA intermediate that stores the bond energy of the cleaved bonds in 3'-phosphotyrosyl linkages. The cleaved DNA strands are then refolded into a hairpin conformation and the 5'-OH ends of the refolded strands attack the 3'-phosphotyrosine linkages in order to rejoin the DNA strands into hairpin telomeres. Because this kind of reaction mechanism is, in principle, reversible it is unclear how TelA controls the direction of the reaction and propels the reaction to completion. We present evidence that TelA forms and/or stabilizes a pre-cleavage intermediate that features breakage of the four central basepairs between the scissile phosphates prior to DNA cleavage to help propel the reaction forwards, thus preventing abortive cleavage and rejoining cycles that regenerate the substrate DNA. We identify eight TelA sidechains, located in the hairpin-binding module and catalytic domains of TelA, implicated in this process. These mutants were deficient for telomere resolution on parental replicated telomere junctions but were rescued by introduction of substrate modifications that mimic unwinding of the DNA between the scissile phosphates.

Biochemical Characterization of Kat1: a Domesticated hAT-Transposase that Induces DNA Hairpin Formation and MAT-Switching

Kluyveromyces lactis hAT-transposase 1 (Kat1) generates hairpin-capped DNA double strand breaks leading to MAT-switching (MATa to MATα). Using purified Kat1, we demonstrate the importance of terminal inverted repeats and subterminal repeats for its endonuclease activity. Kat1 promoted joining of the transposon end into a target DNA molecule in vitro, a biochemical feature that ties Kat1 to transposases. Gas-phase Electrophoretic Mobility Macromolecule analysis revealed that Kat1 can form hexamers when complexed with DNA. Kat1 point mutants were generated in conserved positions to explore structure-function relationships. Mutants of predicted catalytic residues abolished both DNA cleavage and strand-transfer. Interestingly, W576A predicted to be impaired for hairpin formation, was active for DNA cleavage and supported wild type levels of mating-type switching. In contrast, the conserved CXXH motif was critical for hairpin formation because Kat1 C402A/H405A completely blocked hairpinning and switching, but still generated nicks in the DNA. Mutations in the BED zinc-finger domain (C130A/C133A) resulted in an unspecific nuclease activity, presumably due to nonspecific DNA interaction. Kat1 mutants that were defective for cleavage in vitro were also defective for mating-type switching. Collectively, this study reveals Kat1 sharing extensive biochemical similarities with cut and paste transposons despite being domesticated and evolutionary diverged from active transposons.

Hairpin Telomere Resolvases

Covalently closed hairpin ends, also known as hairpin telomeres, provide an unusual solution to the end replication problem. The hairpin telomeres are generated from replication intermediates by a process known as telomere resolution. This is a DNA breakage and reunion reaction promoted by hairpin telomere resolvases (also referred to as protelomerases) found in a limited number of phage and bacteria. The reaction promoted by these enzymes is a chemically isoenergetic two-step transesterification without a requirement for divalent metal ions or high-energy cofactors and uses an active site and mechanism similar to that for type IB topoisomerases and tyrosine recombinases. The small number of unrelated telomere resolvases characterized to date all contain a central, catalytic core domain with the active site, but in addition carry variable C- and N-terminal domains with different functions. Similarities and differences in the structure and function of the telomere resolvases are discussed. Of particular interest are the properties of the Borrelia telomere resolvases, which have been studied most extensively at the biochemical level and appear to play a role in shaping the unusual segmented genomes in these organisms and, perhaps, to play a role in recombinational events.

Transposons Tn 10 and Tn 5

The study of the bacterial transposons Tn 10 and Tn 5 has provided a wealth of information regarding steps in nonreplicative DNA transposition, transpososome dynamics and structure, as well as mechanisms employed to regulate transposition. The focus of ongoing research on these transposons is mainly on host regulation and the use of the Tn 10 antisense system as a platform to develop riboregulators for applications in synthetic biology. Over the past decade two new regulators of both Tn 10 and Tn 5 transposition have been identified, namely H-NS and Hfq proteins. These are both global regulators of gene expression in enteric bacteria with functions linked to stress-response pathways and virulence and potentially could link the Tn 10 and Tn 5 systems (and thus the transfer of antibiotic resistance genes) to environmental cues. Work summarized here is consistent with the H-NS protein working directly on transposition complexes to upregulate both Tn 10 and Tn 5 transposition. In contrast, evidence is discussed that is consistent with Hfq working at the level of transposase expression to downregulate both systems. With regard to Tn 10 and synthetic biology, some recent work that incorporates the Tn 10 antisense RNA into both transcriptional and translational riboswitches is summarized.

The processing of repetitive extragenic palindromes: the structure of a repetitive extragenic palindrome bound to its associated nuclease

Extragenic sequences in genomes, such as microRNA and CRISPR, are vital players in the cell. Repetitive extragenic palindromic sequences (REPs) are a class of extragenic sequences, which form nucleotide stem-loop structures. REPs are found in many bacterial species at a high copy number and are important in regulation of certain bacterial functions, such as Integration Host Factor recruitment and mRNA turnover. Although a new clade of putative transposases (RAYTs or TnpA_REP) is often associated with an increase in these repeats, it is not clear how these proteins might have directed amplification of REPs. We report here the structure to 2.6 Å of TnpA_REP from Escherichia coli MG1655 bound to a REP. Sequence analysis showed that TnpA_REP is highly related to the IS200/IS605 family, but in contrast to IS200/IS605 transposases, TnpA_REP is a monomer, is auto-inhibited and is active only in manganese. These features suggest that, relative to IS200/IS605 transposases, it has evolved a different mechanism for the movement of discrete segments of DNA and has been severely down-regulated, perhaps to prevent REPs from sweeping through genomes.

H-NS mediates the dissociation of a refractory protein-DNA complex during Tn10/IS10 transposition

Tn10/IS10 transposition takes place in the context of a protein–DNA complex called a transpososome. During the reaction, the transpososome undergoes several conformational changes. The host proteins IHF and H-NS, which also are global regulators of gene expression, play important roles in directing these architectural changes. IHF binds tightly to only one of two transposon ends within the transpososome, folding this end into a DNA loop structure. Unfolding this DNA loop is necessary for excising the transposon from flanking donor DNA and preventing integration of the transposon into itself. We show here that efficient DNA loop unfolding relies on the continuity of the flanking donor DNA on the side of the transpososome opposite to the folded transposon end. We also show this same donor DNA is a preferred binding site for H-NS, which promotes opening of the IHF-loop, which is required for productive target interactions. This is counter to the usual mode of H-NS action, which is repressive due to its propensity to coat DNA. The interplay between IHF and H-NS likely serves to couple the rate of transposition to the host cell physiology as both of these proteins are integrated into cellular stress response pathways.

Preventing broken Borrelia telomeres: ResT couples dual hairpin telomere formation with product release

Spirochetes of the genus Borrelia include the tick-transmitted causative agents of Lyme disease and relapsing fever. They possess unusual genomes composed mainly of linear replicons terminated by closed DNA hairpins. Hairpin telomeres are formed from inverted repeat replicated telomere junctions (rTels) by the telomere resolvase ResT. ResT uses a reaction mechanism similar to that of the type IB topoisomerases and tyrosine recombinases. ResT can catalyze three distinct reactions: telomere resolution, telomere fusion, and Holliday junction (HJ) formation. HJ formation is known to occur only in the context of a synapsed pair of rTels. To test whether telomere resolution was synapsis-dependent, we performed experiments with rTel substrates immobilized on streptavidin-coated beads. We report that telomere resolution by ResT is synapsis-independent, indicating that alternative complexes are formed for telomere resolution and HJ formation. We also present evidence that dual hairpin telomere formation precedes product release. This mechanism of telomere resolution prevents the appearance of broken telomeres. We compare and contrast this mechanism with that proposed for TelK, the telomere resolvase of ϕKO2.

Integrating prokaryotes and eukaryotes: DNA transposases in light of structure

DNA rearrangements are important in genome function and evolution. Genetic material can be rearranged inadvertently during processes such as DNA repair, or can be moved in a controlled manner by enzymes specifically dedicated to the task. DNA transposases comprise one class of such enzymes. These move DNA segments known as transposons to new locations, without the need for sequence homology between transposon and target site. Several biochemically distinct pathways have evolved for DNA transposition, and genetic and biochemical studies have provided valuable insights into many of these. However, structural information on transposases - particularly with DNA substrates - has proven elusive in most cases. On the other hand, large-scale genome sequencing projects have led to an explosion in the number of annotated prokaryotic and eukaryotic mobile elements. Here, we briefly review biochemical and mechanistic aspects of DNA transposition, and propose that integrating sequence information with structural information using bioinformatics tools such as secondary structure prediction and protein threading can lead not only to an additional level of understanding but possibly also to testable hypotheses regarding transposition mechanisms. Detailed understanding of transposition pathways is a prerequisite for the long-term goal of exploiting DNA transposons as genetic tools and as a basis for genetic medical applications.

Phosphate coordination and movement of DNA in the Tn5 synaptic complex: role of the (R)YREK motif

Bacterial DNA transposition is an important model system for studying DNA recombination events such as HIV-1 DNA integration and RAG-1-mediated V(D)J recombination. This communication focuses on the role of protein-phosphate contacts in manipulating DNA structure as a requirement for transposition catalysis. In particular, the participation of the nontransferred strand (NTS) 5' phosphate in Tn5 transposition strand transfer is analyzed. The 5' phosphate plays no direct catalytic role, nonetheless its presence stimulates strand transfer approximately 30-fold. X-ray crystallography indicates that transposase-DNA complexes formed with NTS 5' phosphorylated DNA have two properties that contrast with structures formed with complexes lacking the 5' phosphate or complexes generated from in-crystal hairpin cleavage. Transposase residues R210, Y319 and R322 of the (R)YREK motif coordinate the 5' phosphate rather than the subterminal NTS phosphate, and the 5' NTS end is moved away from the 3' transferred strand end. Mutation R210A impairs the 5' phosphate stimulation. It is posited that DNA phosphate coordination by R210, Y319 and R322 results in movement of the 5' NTS DNA away from the 3'-end thus allowing efficient target DNA binding. It is likely that this role for the newly identified RYR triad is utilized by other transposase-related proteins.

The global regulator H-NS binds to two distinct classes of sites within the Tn10 transpososome to promote transposition

The histone-like nucleoid structuring protein (H-NS) is a global transcriptional regulator that influences stress response and virulence pathways in Gram-negative bacteria. H-NS also promotes Tn10 transposition by binding directly to the transpososome and inducing a conformational change in the transpososome that favours intermolecular transposition events. H-NS binds preferentially to curved DNA and can bend non-curved DNA, it self-oligomerizes and can interact with other proteins. To determine what functions of H-NS are important in promoting Tn10 transposition, we have examined the ability of two mutant forms of H-NS, P116S and 1-64, to act in Tn10 transposition. We provide evidence that the initial interaction of H-NS with the transpososome is dependent on H-NS binding to a specific structure in DNA flanking the transposon end. Additional molecules of H-NS then bind within the transposon end. This latter event appears to be directed by H-NS binding to the Tn10 transposase protein, and is important in maintaining the transpososome in a conformation that promotes intermolecular transposition. The binding of H-NS to a transposase protein is a novel function for this important regulatory molecule.

Base-flipping dynamics in a DNA hairpin processing reaction

Many enzymes that repair or modify bases in double-stranded DNA gain access to their substrates by base flipping. Although crystal structures provide stunning snap shots, biochemical approaches addressing the dynamics have proven difficult, particularly in complicated multi-step reactions. Here, we use protein-DNA crosslinking and potassium permanganate reactivity to explore the base-flipping step in Tn5 transposition. We present a model to suggest that base flipping is driven by a combination of factors including DNA bending and the intrusion of a probe residue. The forces are postulated to act early in the reaction to create a state of tension, relieved by base flipping after cleavage of the first strand of DNA at the transposon end. Elimination of the probe residue retards the kinetics of nicking and reduces base flipping by 50%. Unexpectedly, the probe residue is even more important during the hairpin resolution step. Overall, base flipping is pivotal to the hairpin processing reaction because it performs two opposite but closely related functions. On one hand it disrupts the double helix, providing the necessary strand separation and steric freedom. While on the other, transposase appears to position the second DNA strand in the active site for cleavage using the flipped base as a handle.

Requirements for DNA hairpin formation by RAG1/2

The rearrangement of antigen receptor genes is initiated by double-strand breaks catalyzed by the RAG1/2 complex at the junctions of recombination signal sequences and coding segments. As with some "cut-and-paste" transposases, such as Tn5 and Hermes, a DNA hairpin is formed at one end of the break via a nicked intermediate. By using abasic DNA substrates, we show that different base positions are important for the two steps of cleavage. Removal of one base in the coding flank enhances hairpin formation, bypassing a requirement for a paired complex of two signal sequences. Rescue by abasic substrates is consistent with a base-flip mechanism seen in the crystal structure of the Tn5 postcleavage complex and may mimic the DNA changes on paired complex formation. We have searched for a tryptophan residue in RAG1 that would be the functional equivalent of W298 in Tn5, which stabilizes the DNA interaction by stacking the flipped base on the indole ring. A W956A mutation in RAG1 had an inhibitory effect on both nicking and hairpin stages that could be rescued by abasic substrates. W956 is therefore a likely candidate for interacting with this base during hairpin formation.

Transpososome dynamics and regulation in Tn10 transposition

Tn10 is a bacterial transposon that transposes through a non-replicative mechanism. This mode of DNA transposition is widely used in bacteria and is also used by "DNA-based" transposons in eukaryotes. Tn10 has served as a paradigm for this mode of transposition and continues to provide novel insights into how steps in transposition reactions occur and how these steps are regulated. A common feature of transposition reactions is that they require the formation of a higher order protein-DNA complex called a transpososome. A major objective in the last few years has been to better understand the dynamics of transpososome assembly and progression through the course of transposition reactions. This problem is particularly interesting in the Tn10 system because two important host proteins, IHF and H-NS, have been implicated in regulating transpososome assembly and/or function. Interestingly, H-NS is an integral part of stress response pathways in bacteria, and its function is known to be sensitive to changes in environmental conditions. Consequently, H-NS may provide a means of allowing Tn10 to responed to changing environmental conditions. The current review focuses on the roles of both IHF and H-NS on Tn10 transposition.

Amino acid residues in Rag1 crucial for DNA hairpin formation

The Rag proteins carry out V(D)J recombination through a process mechanistically similar to cut-and-paste transposition. Specifically, Rag complexes form DNA hairpins through direct transesterification, using a catalytic Asp-Asp-Glu (DDE) triad in Rag1. How is sufficient DNA distortion introduced to allow hairpin formation? We hypothesized that, like certain transposases, the Rag proteins might use aromatic amino acid residues to stabilize a flipped-out base. Through in vivo and in vitro experiments and structural predictions, we identified residues in Rag1 crucial for hairpin formation. One of these, a conserved tryptophan (Trp893), probably participates in base-stacking interactions near the cleavage site, as do Trp298, Trp265 and Trp319 in the Tn5, Tn10 and Hermes transposases, respectively. Other residues surrounding the catalytic glutamate (YKEFRK) may share functional similarities with the YREK motif in IS4 family transposases.

Characteristics of MuA transposase-catalyzed processing of model transposon end DNA hairpin substrates

Bacteriophage Mu uses non-replicative transposition for integration into the host's chromosome and replicative transposition for phage propagation. Biochemical and structural comparisons together with evolutionary considerations suggest that the Mu transposition machinery might share functional similarities with machineries of the systems that are known to employ a hairpin intermediate during the catalytic steps of transposition. Model transposon end DNA hairpin substrates were used in a minimal-component in vitro system to study their proficiency to promote Mu transpososome assembly and subsequent MuA-catalyzed chemical reactions leading to the strand transfer product. MuA indeed was able to assemble hairpin substrates into a catalytically competent transpososome, open the hairpin ends and accurately join the opened ends to the target DNA. The hairpin opening and transposon end cleavage reactions had identical metal ion preferences, indicating similar conformations within the catalytic center for these reactions. Hairpin length influenced transpososome assembly as well as catalysis: longer loops were more efficient in these respects. In general, MuA's proficiency to utilize different types of hairpin substrates indicates a certain degree of flexibility within the transposition machinery core. Overall, the results suggest that non-replicative and replicative transposition systems may structurally and evolutionarily be more closely linked than anticipated previously.

The global regulator H-NS acts directly on the transpososome to promote Tn10 transposition

The histone-like nucleoid structuring (H-NS) protein is a global transcriptional regulator that is known to regulate stress response pathways and virulence genes in bacteria. It has also been implicated in the regulation of bacterial transposition systems, including Tn10. We demonstrate here that H-NS promotes Tn10 transposition by binding directly to the transposition complex (or transpososome). We present evidence that, upon binding, H-NS induces the unfolding of the Tn10 transpososome and helps to maintain the transpososome in an unfolded state. This ensures that intermolecular (as opposed to self-destructive intramolecular) transposition events are favored. We present evidence that H-NS binding to the flanking donor DNA of the transpososome is the initiating event in the unfolding process. We propose that by recruiting H-NS as a modulator of transposition, Tn10 has evolved a means of sensing changes in host physiology, as the amount of H-NS in the cell, as well its activity, are responsive to changes in environmental conditions. Sensing of environmental changes through H-NS would allow transposition to occur when it is most opportune for both the transposon and the host.

The transpososome: control of transposition at the level of catalysis

Studies of several transposable genetic elements have pinpointed the importance of the transpososome, a nucleoprotein complex involving the transposon ends and a transposon-encoded enzyme--the transposase--as a key in regulating transposition. Transpososomes provide a precise architecture within which the chemical reactions involved in transposon displacement occur. Data are accumulating that suggest they are dynamic and undergo staged conformational changes to accommodate different steps in the transposition pathway. This has been underpinned by recent results obtained particularly with Tn5, Tn10 and bacteriophage Mu.

Uncoupling the chemical steps of telomere resolution by ResT

ResT is the telomere resolvase of the spirochete Borrelia burgdorferi, the causative agent of Lyme disease. ResT is an essential cellular function that processes replication intermediates to produce linear replicons terminated by covalently closed hairpin telomeres. ResT generates these hairpin telomeres in a reaction with mechanistic similarities to those catalyzed by type IB topoisomerases and tyrosine recombinases. We report here, that like most of the tyrosine recombinases, ResT requires interprotomer communication, likely in an in-line synapse, to activate reaction chemistry. Unlike the tyrosine recombinases, however, we infer that the cleavage and strand transfer reactions on the two sides of the replicated telomere occur nearly simultaneously. Nonetheless, the chemical steps of the forward and reverse reactions performed by ResT can occur in a non-concerted fashion (i.e. events on the two sides of the replicated telomere can occur independently). We propose that uncoupling of reaction completion on the two sides of the substrate is facilitated by an early commitment to hairpin formation that is imposed by the precleavage action of the hairpin binding module of the ResT active site.

Tn10 Transposase Mutants with Altered Transpososome Unfolding Properties are Defective in Hairpin Formation

Transposition reactions take place in the context of higher-order protein-DNA complexes called transpososomes. In the Tn10 transpososome, IHF binding to an "outside end" creates a bend in the DNA that allows the transposase protein to contact the end at two different sites, the terminal and subterminal binding sites. Presumably this helps to stabilize the transposase-end interaction. However, the DNA loop that is formed must be unfolded at a later stage in order for the transposon to integrate into other DNA molecules. It has been proposed that transpososome unfolding also plays a role in transposon excision. To investigate this possibility further, we have isolated and characterized transposase mutants with altered transpososome unfolding properties. Two such mutants were identified, R182A and R184A. Both mutants fail to carry out hairpin formation, an intermediate step in transposon excision, specifically with outside end-containing substrates. These results support the idea that transpososome unfolding and excision are linked. Also, based on the importance of residues R182 and R184 in transpososome unfolding, we propose a new model for the Tn10 transpososome, wherein both DNA ends of the transpososome make subterminal contacts with transposase.

The bounty of RAGs: recombination signal complexes and reaction outcomes

V(D)J recombination is a form of site-specific DNA rearrangement through which antigen receptor genes are assembled. This process involves the breakage and reunion of DNA mediated by two lymphoid cell-specific proteins, recombination activating genes RAG-1 and RAG-2, and ubiquitously expressed architectural DNA-binding proteins and DNA-repair factors. Here I review the progress toward understanding the composition, assembly, organization, and activity of the protein-DNA complexes that support the initiation of V(D)J recombination, as well as the molecular basis for the sequence-specific recognition of recombination signal sequences (RSSs) that are the targets of the RAG proteins. Parallels are drawn between V(D)J recombination and Tn5/Tn10 transposition with respect to the reactions, the proteins, and the protein-DNA complexes involved in these processes. I also consider the relative roles of the different sequence elements within the RSS in recognition, cleavage, and post-cleavage events. Finally, I discuss alternative DNA transactions mediated by the V(D)J recombinase, the protein-DNA complexes that support them, and factors and forces that control them.

Enhancement and rescue of target capture in Tn10 transposition by site-specific modifications in target DNA

The bacterial transposon Tn10 inserts preferentially into specific target sequences. This insertion specificity appears to be linked to the ability of target sites to adopt symmetrically positioned DNA bends after binding the transposition machinery. Target DNA bending is thought to permit the transposase protein to make additional contacts with the target DNA, thereby stabilizing the target complex so that the joining of transposon and target DNA sequences can occur efficiently. In the current work, we have asked whether the introduction of a discontinuity in a target DNA strand, a modification that is expected to make it easier for a DNA molecule to bend, can enhance or rescue target capture under otherwise suboptimal reaction conditions. We show that either a nick or a missing phosphate specifically at the site of reaction chemistry increases the ability of various target DNAs to form the target capture complex. The result suggests that the bends in the target DNA are highly localized and include the scissile phosphates. This raises the possibility that strand transfer is mechanistically linked to target capture. We have also identified specific residues in the target DNA and in transposase that appear to play an important role in target DNA bending.

Mixing active-site components: a recipe for the unique enzymatic activity of a telomere resolvase

The ResT protein, a telomere resolvase from Borrelia burgdorferi, processes replication intermediates into linear replicons with hairpin ends by using a catalytic mechanism similar to that for tyrosine recombinases and type IB topoisomerases. We have identified in ResT a hairpin binding region typically found in cut-and-paste transposases. We show that substitution of residues within this region results in a decreased ability of these mutants to catalyze telomere resolution. However, the mutants are capable of resolving heteroduplex DNA substrates designed to allow spontaneous destabilization and prehairpin formation. These findings support the existence of a hairpin binding region in ResT, the only known occurrence outside a transposase. The combination of transposase-like and tyrosine-recombinase-like domains found in ResT indicates the use of a composite active site and helps explain the unique breakage-and-reunion reaction observed with this protein. Comparison of the ResT sequence with other known telomere resolvases suggests that a hairpin binding motif is a common feature in this class of enzyme; the sequence motif also appears in the RAG recombinases. Finally, our data support a mechanism of action whereby ResT induces prehairpin formation before the DNA cleavage step.

Excision of Sleeping Beauty transposons: parameters and applications to gene therapy

A major problem in gene therapy is the determination of the rates at which gene transfer has occurred. Our work has focused on applications of the Sleeping Beauty (SB) transposon system as a non-viral vector for gene therapy. Excision of a transposon from a donor molecule and its integration into a cellular chromosome are catalyzed by SB transposase. In this study, we used a plasmid-based excision assay to study the excision step of transposition. We used the excision assay to evaluate the importance of various sequences that border the sites of excision inside and outside the transposon in order to determine the most active sequences for transposition from a donor plasmid. These findings together with our previous results in transposase binding to the terminal repeats suggest that the sequences in the transposon-junction of SB are involved in steps subsequent to DNA binding but before excision, and that they may have a role in transposase-transposon interaction. We found that SB transposons leave characteristically different footprints at excision sites in different cell types, suggesting that alternative repair machineries operate in concert with transposition. Most importantly, we found that the rates of excision correlate with the rates of transposition. We used this finding to assess transposition in livers of mice that were injected with the SB transposon and transposase. The excision assay appears to be a relatively quick and easy method to optimize protocols for delivery of genes in SB transposons to mammalian chromosomes in living animals.

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.

DNA sequence bias during Tn5 transposition

Transposition is one of the primary mechanisms causing genome instability. This phenomenon is mechanistically related to other DNA rearrangements such as V(D)J recombination and retroviral DNA integration. In the Tn5 system, only one protein, the transposase (Tnp), is required for all of the catalytic steps involved in transposon movement. The complexity involved in moving multiple DNA strands within one active site suggests that, in addition to the specific contacts maintained between Tnp and its recognition sequence, Tnp also interacts with the flanking DNA sequence. Here, we demonstrate that Tnp interacts with the donor DNA region. Tnp protects the donor DNA from DNase I digestion, suggesting that Tnp is in contact with, or otherwise distorts, the donor DNA during synapsis. In addition, changes in the donor DNA sequence within this region alter the affinity of Tnp for DNA by eightfold during synapsis. In vitro selection for more stable synaptic complexes reveals an A/T sequence bias for this region. We further show that certain donor DNA sequences, which favor synapsis, also appear to serve as hot spots for strand transfer. The TTATA donor sequence represents the best site. Most surprising is the fact that this sequence is found within the Tnp recognition sequence. Preference for insertion into a site within the Tnp recognition sequence would effectively inactivate one copy of the element and form clusters of the Tn5 transposon. In addition, the fact that several donor DNA sequences, which favor synapsis, appear to serve as hot spots for transposon insertion suggest that similar criteria may exist for Tnp-donor DNA and Tnp-target DNA interactions.

Patterns of sequence conservation at termini of long terminal repeat (LTR) retrotransposons and DNA transposons in the human genome: lessons from phage Mu

Long terminal repeat (LTR) retrotransposons and DNA transposons are transposable elements (TEs) that perform cleavage and transfer at precise DNA positions. Here, we present statistical analyses of sequences found at the termini of precise TEs in the human genome. The results show that the terminal di- and trinucleotides of these TEs are highly conserved. 5'TG...CA3' occurs most frequently at the termini of LTR retrotransposons, while 5'CAG...CTG3' occurs most frequently in DNA transposons. Interestingly, these sequences are the most flexible base pair steps in DNA. Both the sequence preference and the degree of conservation of each position within the human LTR dinucleotide termini are remarkably similar to those experimentally demonstrated in transposable phage Mu. We discuss the significance of these observations and their implication for the function of terminal residues in the transposition of precise TEs.

The conserved CA/TG motif at Mu termini: T specifies stable transpososome assembly

The dinucleotide CA/TG found at the termini of transposable phage Mu occurs also at the termini of a large class of transposable elements, including HIV, all retroviruses and many retrotransposons. It was shown recently that mutations of this sequence block transpososome assembly, that A/T is more critical for activity than C/G, and that the hierarchy of reactivity of mutant termini follows closely the reported hierarchy of flexibility of their dinucleotide steps. In order to test the hypothesis that the terminal dinucleotide plays an essential structural role during "open termini" formation accompanying assembly, we have examined the activity of substrates carrying 100 different pairs of mismatched termini. Consistent with the flexibility hypothesis, we find that mismatched substrates are extremely efficient at assembly. A wild-type T residue on the bottom strand is essential for stable assembly, but the identity of the dinucleotide on the top strand is irrelevant for transposition chemistry. In addition, we have found a new rule for suppression of terminal defects by MuB protein, as well as a role for metal ions in DNA opening at the termini.

Excision of the Drosophila mariner transposon Mos1. Comparison with bacterial transposition and V(D)J recombination

It has been proposed that the modern immune system has evolved from a transposon in an ancient vertebrate. While much is known about the mechanism by which bacterial transposable elements catalyze double-strand breaks at their ends, less is known about how eukaryotic transposable elements carry out these reactions. We have examined the mechanism by which mariner, a eukaryotic transposable element, performs DNA cleavage. We show that the nontransferred strand is cleaved initially, unlike prokaryotic transposons which cleave the transferred strand first. First strand cleavage is not tightly coupled to second strand cleavage and can occur independently of synapsis, as happens in V(D)J recombination but not in transposition of prokaryotic transposons. Unlike V(D)J recombination, however, second strand cleavage of mariner does not occur via a hairpin intermediate.

IHF-independent assembly of the Tn10 strand transfer transpososome: implications for inhibition of disintegration

The frequency of DNA transposition in transposition systems that employ a strand transfer step may be significantly affected by the occurrence of a disintegration reaction, a reaction that reverses the strand transfer event. We have asked whether disintegration occurs in the Tn10 transposition system. We show that disintegration substrates (substrates constituting one half of the strand transfer product) are assembled into a transpososome that mimics the strand transfer intermediate. This strand transfer transpososome (STT) does appear to support an intermolecular disintegration reaction, but only at a very low level. Strikingly, assembly of the STT is not dependent on IHF, a host protein that is required for de novo assembly of all previously characterized Tn10 transpososomes. We suggest that disintegration substrates are able to form both transposon end and target type contacts with transposase because of their enhanced conformational flexibility. This probably allows the conformation of DNA within the complex that prevents the destructive disintegration reaction, and is responsible for relaxing the DNA sequence requirements for STT formation relative to other Tn10 transpososomes.

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.

Tn5 transposase active site mutants

Tn5 transposase (Tnp) is a 53.3-kDa protein that is encoded by and facilitates movement of transposon Tn5. Tnp monomers contain a single active site that is responsible for catalyzing a series of four DNA breaking/joining reactions at one transposon end. Based on primary sequence homology and protein structural information, we designed and constructed a series of plasmids that encode for Tnps containing active site mutations. Following Tnp expression and purification, the active site mutants were tested for their ability to form protein-DNA complexes and perform each of the four catalytic steps in the transposition pathway in vitro. The results demonstrate that Asp-97, Asp-188, and Glu-326, visible in the active site of Tn5 crystal structures, are absolutely required for all catalytic steps. Mutations within a series of amino acid residues that are conserved in the IS4 family of transposases and retroviral integrases also impair Tnp catalytic activity. Mutations at either Tyr-319 or Arg-322 reduce both hairpin resolution and strand transfer activity within protein-DNA complexes. Mutations at Lys-333 reduce the ability of Tnps to form protein-DNA complexes, whereas mutations at the less strongly conserved Lys-330 have less of an effect on both synaptic complex formation and catalytic activity.

Mutational analysis of the base flipping event found in Tn5 transposition

This work identifies novel structure-function relationships between Tn5 transposase (Tnp) and its DNA recognition sequence. The Tn5 Tnp-DNA co-crystal structure revealed the protein-DNA contacts of the post-cleavage complex (Davies, D. R., Goryshin, I. Y., Reznikoff, W. S., and Rayment, I. (2000) Science 289, 77-85). One of the most striking features of this complex is the rotation of thymine 2 (T2) away from the DNA helix and into a pocket within the Tnp. This interaction appears similar to the "base flipping" phenomenon found in many DNA repair enzymes such as T4 endonuclease V and uracil DNA glycosylase (Roberts, R. J., and Cheng, X. (1998) Annu. Rev. Biochem. 67, 181-198). To study the biochemical significance of this phenomenon, we mutated the Tnp residues proposed to be involved in stabilizing this interaction and removed the T2 nucleotide to examine which steps in the transposition reaction require T2-Tnp interactions. From this work, we have determined that stacking interactions between T2 and Tnp are critical for efficient transposition in vitro. In addition, our results suggested that T2-Tnp interactions facilitate hairpin formation and hairpin resolution primarily through base stacking and that T2 plays a role in the alignment of the transposon DNA for strand transfer.

Importance of the conserved CA dinucleotide at Mu termini

The dinucleotide CA found at the termini of transposable phage Mu also occurs at the termini of a large class of transposable elements, including HIV, all retroviruses and many retrotransposons. In order to understand the importance of this sequence conservation, the activity of all 16 dinucleotide permutations of the termini was first examined using a sensitive plasmid-based in vivo transposition assay. The reactivity of these substrates varied over several orders of magnitude in vivo, with substitutions at the A position being more severely impaired than those at the C position. The same general hierarchy of reactivity was observed in vitro using mutant oligonucleotide substrates. These experiments revealed that CA was not important for the chemistry of strand transfer, and that the block in the activity of the mutant substrates was at the stage of assembly of a stable transpososome. Given that DNA at the Mu-host junctions is melted/distorted concomitantly with transpososome assembly, we consider the hypothesis that the CA dinucleotide has been selected at transposon termini primarily for its significant conformational mobility.