Comparative architecture of transposase and integrase complexes.

Transposases and retroviral integrases promote the movement of DNA segments to new locations within and between genomes. These recombinases function as multimeric protein-DNA complexes. Recent success in solving the crystal structure of a Tn5 transposase--DNA complex provides the first detailed structural information about a member of the transposase/integrase superfamily in its active, DNA-bound state. Here, we summarize the reactions catalyzed by transposases and integrases and review the Tn5 transposase-DNA co-crystal structure. The insights gained from the Tn5 structure and other available structures are considered together with biochemical and genetic data to discuss features that are likely to prove common to the catalytic complexes used by members of this important protein family.     

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.     

Tn5 transposase active site mutations suggest position of donor backbone DNA in synaptic complex

Tn5 transposase (Tnp), a 53.3-kDa protein, enables the movement of transposon Tn5 by a conservative mechanism. Within the context of a protein and DNA synaptic complex, a single Tnp molecule catalyzes four sequential DNA breaking and joining reactions at the end of a single transposon. The three amino acids of the DDE motif (Asp-97, Asp-188, and Glu-326), which are conserved among transposases and retroviral integrases, have been shown previously to be absolutely required for all catalytic steps. To probe the effect of active site geometry on the ability to form synaptic complexes and perform catalysis, single mutations at each position of the DDE motif were constructed. The aspartates were changed to glutamates, and the glutamate was changed to an aspartate. These mutants were studied by performing in vitro binding assays using short oligonucleotide substrates simulating the natural substrates for the synaptic complex formation and subsequent transposition steps. The results indicate that the aspartate to glutamate mutations restrict synaptic complex formation with substrates resembling the natural transposon prior to transferred strand nicking. This suggests a structural model in which the donor backbone DNA, prior to nicking, occupies the same space that is invaded by the longer side chains present in the aspartate to glutamate mutants. Additionally, catalytic assays support the previous proposal that the active site coordinates two divalent metal ions.     

Tn552, a novel transposable element from Staphylococcus aureus

Tn552, one of several closely related beta-lactamase-encoding transposons from Staphylococcus aureus, has a novel set of putative transposition functions. Each is homologous with a well-characterized function from a different type of mobile genetic element. Thus, Tn552 encodes: (i) resL-binL, a co-integrate resolution system homologous with those of Tn3 family elements; (ii) p480, a potential transposase significantly homologous with the DNA integrases of eukaryotic retroviruses and retrotransposons; and (iii) p271, a potential ATP-binding protein that shows homology with the B protein of phage Mu. The 3' terminal nucleotides of Tn552 (CA), adjacent to which p480 might cleave, are the same as those of retroviruses, retrotransposons and phage Mu. The presumptive resolvase (BinL) is very closely related to BinR, which was identified as a DNA invertase and is now shown to resolve an artificial co-integrate in vivo. Furthermore, the structure of the derivative of Tn552 found in the staphylococcal plasmid pI258 can be explained by a BinL (or BinR)-mediated site-specific deletion ('resolution') event. Thus, pI258 contains only the right-hand half of Tn552, which encodes the beta-lactamase and two regulatory proteins. The latter are homologous with the beta-lactamase gene repressor and co-inducer of Bacillus licheniformis. Interestingly, the order of the regulatory genes is reversed in S. aureus compared with Bacillus licheniformis.     

Interaction of related Tn916-like transposons: analysis of excision events promoted by Tn916 and Tn5386 integrases

In recent work, we described the excision of a large genomic region from Enterococcus faecium D344R in which the sequence from "joint" regions suggested that excision resulted from the interaction of conjugative transposon Tn916 and the related mobile element Tn5386. In the present study, we examined the ability of integrases and integrase-excisase combinations from Tn916 and Tn5386 to promote the excision of constructs consisting of the termini of Tn916, Tn5386, and the VanB mobile element Tn5382. Integrases alone from either Tn916 or Tn5386 promoted the circularization of constructs from the three different transposons, even when the different termini used in the constructs were discordant in their transposon of origin. The termini of Tn916 and Tn5382 found in all joints were consistent with previously identified Tn916 and Tn5382 termini. Substantial variation was seen in the integrase terminus of Tn5386 used to form joints, regardless of the integrase that was responsible for circularization. Variability was observed in joints formed from Tn5386 constructs, in contrast to joints observed with the termini of Tn916 or Tn5382. The coexpression of excisase yielded some variability in the joint regions observed. These data confirm that integrases from some Tn916-like elements can promote circularization with termini derived from heterologous transposons and, as such, could promote excision of large genomic regions flanked by such elements. These findings also raise interesting questions about the sequence specificities of the C terminals of Tn916-like integrases, which bind to the ends and facilitate strand exchange.     

Dissecting Tn5 transposition using HIV-1 integrase diketoacid inhibitors

Diketoacid (DKA) compounds have been shown to inhibit HIV-1 integrase by a mechanism that involves sequestration of the active site metals. Because HIV-1 integrase and Tn5 transposase have similar active site architectures and catalytic mechanisms, we investigated whether DKA analogues would inhibit Tn5 transposase activity and provide a model system to explore the mechanisms of action of these inhibitors. A screen of several hundred DKA analogues identified several with activity against Tn5 Tnp. Six DKA inhibitors used in this study manifested a variety of effects on different transposition steps suggesting that different analogues may have different binding contacts with transposase. All DKA compounds inhibited paired end complex (PEC) formation in which the nucleoprotein complex required for catalysis is assembled. Dissociation of PECs by some DKA compounds indicates that these inhibitors can decrease PEC stability. Four DKA compounds inhibited the two cleavage steps releasing transposon DNA from flanking DNA, and one of these four compounds preferentially inhibited the second cleavage step. The differential effect of this inhibitor on the second cleavage event indicates that cleavage of the two transposon-donor DNA boundaries is a sequential process requiring a conformational change. The requirement for a conformational change between cleavage events was also demonstrated by the inability of transposase to perform second cleavage at 25 degrees C. Finally, all six compounds inhibit strand transfer, the final step of Tn5 transposition. Two of the compounds that inhibited strand transfer have no effect on DNA cleavage. The strand transfer inhibition properties of various DKA compounds was sensitive to the structure of the 5'-non-transferred strand, suggesting that these compounds bind in or near the transposase active site. Other results that probe compound binding sites include the effects of active site mutations and donor DNA on DKA compound inhibition activities. Thus, DKA inhibitors will provide an important set of tools to investigate the mechanism of action of transposases and integrases.     

Critical contacts between HIV-1 integrase and viral DNA identified by structure-based analysis and photo-crosslinking.

Analysis of the crystal structure of HIV-1 integrase reveals a cluster of lysine residues near the active site. Using site-directed mutagenesis and photo-crosslinking we find that Lys156 and Lys159 are critical for the functional interaction of integrase with viral DNA. Mutation of Lys156 or Lys159 to glutamate led to a loss of both 3' processing and strand transfer activities in vitro while maintaining the ability to interact with nonspecific DNA and support disintegration. However, mutation of both residues to glutamate produced a synergistic effect eliminating nearly all nonspecific DNA interaction and disintegration activity. In addition, virus containing either of these changes was replication-defective at the step of integration. Photo-crosslinking, using 5-iododeoxyuracil-substituted oligonucleotides, suggests that Lys159 interacts at the N7 position of the conserved deoxyadenosine adjacent to the scissile phosphodiester bond of viral DNA. Sequence conservation throughout retroviral integrases and certain bacterial transposases (e.g. Tn10/IS10) supports the premise that within those families of polynucleotidyl transferases, these residues are strategic for DNA interaction.     

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.     

Tn552 transposase purification and in vitro activities.

The Staphylococcus aureus transposon Tn552 encodes a protein (p480) containing the 'D,D(35)E' motif common to retroviral integrases and the transposases of a number of bacterial elements, including phage Mu, the integron-containing element Tn5090, Tn7 and IS3. p480 and a histidine-tagged derivative were overexpressed in Escherichia coli and purified by methods involving denaturation and renaturation. DNase I footprinting and gel binding assays demonstrated that p480 binds to two adjacent, directly repeated 23 bp motifs at each end of Tn552. Although donor strand cleavage by p480 was not detected, in vitro conditions were defined for strand transfer activity with transposon end fragments having pre-cleaved 3' termini. Strand transfer was Mn(2+)-dependent and appeared to join a single left or right end fragment to target DNA. The importance of the terminal dinucleotide CA-3' was demonstrated by mutation. The in vitro activities of p480 are consistent with its proposed function as the Tn552 transposase.     

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.     

Kinetic and structural analysis of a cleaved donor intermediate and a strand transfer intermediate in Tn10 transposition.

Tn10 transposes by a nonreplicative "cut and paste" mechanism. We describe here two protein-DNA complexes that are reaction intermediates in the Tn10 transposition process: a cleaved donor complex whose DNA component consists of transposon sequences cleanly excised from flanking donor DNA, and a strand transfer complex whose DNA component contains transposon termini specifically joined to a target site. The kinetic behavior of the first species suggests that it is an early intermediate in the transposition reaction. These two Tn10 complexes are closely analogous to complexes identified in the pathway for replicative "cointegrate" formation by bacteriophage Mu and thus represent intermediates that may be common to both nonreplicative and replicative transposition. These and other results suggest that the Tn10 and Mu reactions are fundamentally very similar despite their very different biological outcomes. The critical difference between the two reactions is the fate of the DNA strand that is not joined to target DNA.     

Tetrameric structure of a serine integrase catalytic domain

The serine integrases have recently emerged as powerful new chromosome engineering tools in various organisms and show promise for therapeutic use in human cells. The serine integrases are structurally and mechanistically unrelated to the bacteriophage lambda integrase but share a similar catalytic domain with the resolvase/invertase enzymes typified by the resolvase proteins from transposons Tn3 and gammadelta. Here we report the crystal structure and solution properties of the catalytic domain from bacteriophage TP901-1 integrase. The protein is a dimer in solution but crystallizes as a tetramer that is closely related in overall architecture to structures of activated gammadelta-resolvase mutants. The ability of the integrase tetramer to explain biochemical experiments performed in the resolvase and invertase systems suggests that the TP901 integrase tetramer represents a unique intermediate on the recombination pathway that is shared within the serine recombinase superfamily.     

Formation, characterization and partial purification of a Tn5 strand transfer complex

DNA transposition reactions typically involve a strand transfer step wherein the transposon ends are covalently joined by the transposase protein to a short target site. There is very little known about the transposase-DNA interactions that direct this process, and thus our overall understanding of the dynamics of DNA transposition reactions is limited. Tn5 presents an attractive system for defining such interactions because it has been possible to solve the structure of at least one Tn5 transposition intermediate: a transpososome formed with pre-cleaved ends. However, insertion specificity in the Tn5 system is low and this has hampered progress in generating target-containing transpososomes that are homogeneous in structure (i.e. where a single target site is engaged) and therefore suitable for biochemical and structural analysis. We have developed a system where the Tn5 transpososome integrates almost exclusively into a single target site within a short DNA fragment. The key to establishing this high degree of insertion specificity was to use a target DNA with tandem repeats of a previously characterized Tn5 insertion hotspot. The target DNA requirements to form this strand transfer complex are evaluated. In addition, we show that target DNAs missing single phosphate groups at specific positions are better substrates for strand transfer complex formation relative to the corresponding unmodified DNA fragments. Moreover, utilization of missing phosphate substrates can increase the degree of target site selection. A method for concentrating and partially purifying the Tn5 strand transfer complex is described.     

Pulling apart catalytically active Tn5 synaptic complexes using magnetic tweezers

The Tn5 transposase is an example of a class of proteins that move DNA sequences (transposons) via a process called transposition. DNA transposition is a widespread genetic mobility mechanism that has profoundly affected the genomes of nearly all organisms. We have used single-DNA micromanipulation experiments to study the process by which Tn5 DNA transposons are identified and processed by their transposase protein. We have determined that the energy barrier to disassemble catalytically active synaptic complexes is 16 kcal mol(-1). However, we have found that the looping organization of DNA segments by transposase is less sequence-driven than previously thought. Loops anchored at some non-transposon end sequences display a disassembly energy barrier of 14 kcal mol(-1), nearly as stable as the synapses formed at known transposon end sequences. However, these non-transposon end sequence independent complexes do not mediate DNA cleavage. Therefore, the sequence-sensitivity for DNA binding and looping by Tn5 transposase is significantly less than that required for DNA cleavage. These results have implications for the in vivo down regulation of transposition and the cis-transposition bias of transposase.     

Characterization of a Tn5 pre-cleavage synaptic complex

Protein catalyzed DNA rearrangements typically require assembly of complex nucleoprotein structures. In transposition and integration reactions, these structures, termed synaptic complexes, are mandatory for catalysis. We characterize the Tn5 pre-cleavage synaptic complex, the simplest transposition complex described to date. We identified this complex by gel retardation assay using short, linear fragments and have shown that it contains a dimer of transposase, two DNA molecules, and is competent for DNA cleavage in the presence of Mg(2+). We also used hydroxyl radical footprinting and interference techniques to delineate the protein-DNA contacts made in the Tn5 synaptic and monomer complexes. All positions (except position 1) of the end sequence are contacted by transposase in the synaptic complex. We have determined that positions 2-5 of the end sequence are specifically required for synaptic complex formation as they are not required for monomer complex formation. In addition, in the synaptic complex, there is a strong, local distortion centered around position 1 which likely facilitates cleavage.     

The global bacterial regulator H-NS promotes transpososome formation and transposition in the Tn5 system

The histone-like nucleoid structuring protein (H-NS) is an important regulator of stress response and virulence genes in gram-negative bacteria. In addition to binding regulatory regions of genes in a structure-specific manner, H-NS also binds in a structure-specific manner to sites in the Tn10 transpososome, allowing it to act as a positive regulator of Tn10 transposition. This is the only example to date of H-NS regulating a transposition system by interacting directly with the transposition machinery. In general, transposition complexes tend to include segments of deformed DNA and given the capacity of H-NS to bind such structures, and the results from the Tn10 system, we asked if H-NS might regulate another transposition system (Tn5) by directly binding the transposition machinery. We show in the current work that H-NS does bind Tn5 transposition complexes and use hydroxyl radical footprinting to characterize the H-NS interaction with the Tn5 transpososome. We also show that H-NS can promote Tn5 transpososome formation in vitro, which correlates with the Tn5 system showing a dependence on H-NS for transposition in vivo. Taken together the results suggest that H-NS might play an important role in the regulation of many different bacterial transposition systems and thereby contribute directly to lateral gene transfer.     

DNA sequences of the integration sites and inverted repeated structure of transposon Tn3.

The nucleotide sequence of the "inverted repeat" structure of the transposon Tn3 was determined by the DNA sequencing procedure developed by Maxam and Gilbert(1). The sequence, 38 base pairs long, is as follows: 5'-GGGGTCTGACGCTCAGTGGAACGAAAACTCACGTTAAG..(Tn3) 3'-CCCCAGACTGCGAGTCACCTTGCTTTTGAGTGCAATTC.. The integration of Tn3 is associated with a directly repeated sequence of 5 nucleotides appearing at each end of Tn3. The two directly repeated sequences so far determined are not the same. Furthermore, there is no homologous structure around the integration point of Tn3.     

The Bacteroides mobilizable insertion element, NBU1, integrates into the 3' end of a Leu-tRNA gene and has an integrase that is a member of the lambda integrase family.

NBU1 is a 10.3-kbp integrated Bacteroides element that can be induced to excise from the chromosome and can be mobilized to a recipient by trans-acting functions provided by certain Bacteroides conjugative transposons. The NBU1 transfer intermediate is a covalently closed circle, which is presumed to be the form that integrates into the recipient genome. We report here that a 2.4-kbp segment of NBU1 was all that was required for site-specific integration into the chromosome of Bacteroides thetaiotaomicron 5482. This 2.4-kbp region included the joined ends of the NBU1 circular form (attN1) and a single open reading frame, intN1, which encoded the integrase. Previously, we had found that NBU1 integrates preferentially into a single site in B. thetaiotaomicron 5482. We have now shown that the NBU1 target site is located at the 3' end of a Leu-tRNA gene. The NBU1 integrase gene, intN1, was sequenced. The predicted protein had little overall amino acid sequence similarity to any proteins in the databases but had limited carboxy-terminal similarity to the integrases of lambdoid phages and to the integrases of the gram-positive conjugative transposons Tn916 and Tn1545. We also report that the intN1 gene is expressed constitutively.     

Identification and characterization of genes involved in excision of the Lactococcus lactis conjugative transposon Tn5276.

The 70-kb transposon Tn5276, originally detected in Lactococcus lactis NIZO R5 and carrying the genes for nisin production and sucrose fermentation, can be conjugally transferred to other L. lactis strains. Sequence analysis and complementation studies showed that the right end of Tn5276 contains two genes, designated xis and int, which are involved in excision. The 379-amino-acid int gene product shows high (up to 50%) similarity with various integrases, including that of the Tn916-related conjugative transposons. The xis gene product, like almost all known excisionase (Xis) proteins, is a small (68-residue), basic protein. Expression of both the Tn5276 int and xis genes is required for efficient excision of the ends of Tn5276 in Escherichia coli that appeared to be circularized in the excision process. Mutational analysis of the xis and int genes showed that excision efficiency is dependent on the integrity of the int gene but that an intact xis gene is also required for efficient excision.     

The biphenyl- and 4-chlorobiphenyl-catabolic transposon Tn4371, a member of a new family of genomic islands related to IncP and Ti plasmids

The nucleotide sequence of the biphenyl catabolic transposon Tn4371 has been completed and analyzed. It confirmed that the element has a mosaic structure made of several building blocks. In addition to previously identified genes coding for a tyrosine recombinase related to phage integrases and for biphenyl degradation enzymes very similar to those of Achromobacter georgiopolitanum KKS102, Tn4371 carries many plasmid-related genes involved in replication, partition, and other, as-yet-unknown, plasmid functions. One gene cluster contains most of the genes required to express a type IV secretion-mating pair formation apparatus coupled with a TraG ATPase, all of which are related to those found on IncP and Ti plasmids. Orthologues of all Tn4371 plasmid-related genes and of the tyrosine recombinase gene were found, with a very similar organization, in the chromosome of Ralstonia solanacearum and on the yet-to-be-determined genomic sequences of Erwinia chrysanthemi and Azotobacter vinelandii. In each of these chromosomal segments, conserved segments were separated by different groups of genes, which also differed from the Tn4371 bph genes. The conserved blocks of genes were also identified, in at least two copies, in the chromosome of Ralstonia metallidurans CH34. Tn4371 thus appears to represent a new family of potentially mobile genomic islands with a broad host range since they reside in a wide range of soil proteobacteria, including plant pathogens.