A novel conjugative transposon carrying an autonomously amplified plasmid.

Tetracyclines serve as broad-spectrum antibiotics to treat bacterial infections. The discovery of new tetracycline resistance genes has led to new questions about the underlying mechanisms of resistance, gene transfer, and their relevance to human health. We tracked changes in the abundance of a 55-kbp conjugative transposon (CTn214) carrying tetQ, a tetracycline resistance gene, within a Bacteroides fragilis metagenome-assembled genome derived from shotgun sequencing of microbial DNA extracted from the ileal pouch of a patient with ulcerative colitis. The mapping of metagenomic reads to CTn214 revealed the multi-copy nature of a 17,044-nt region containing tetQ in samples collected during inflammation and uninflamed visits. B. fragilis cultivars isolated from the same patient during periods of inflammation harbored CTn214 integrated into the chromosome or both a circular, multi-copy, extrachromosomal region of the CTn214 containing tetQ and the corresponding integrated form. The tetracycline-dependent mechanism for the transmission of CTn214 is nearly identical to a common conjugative transposon found in the genome of B. fragilis (CTnDOT), but the autonomously amplified nature of a circular 17,044-nt region of CTn214 that codes for tetQ and the integration of the same sequence in the linear chromosome within the same cell is a novel observation. Genome and transcriptome sequencing of B. fragilis cultivars grown under different concentrations of tetracycline and ciprofloxacin indicates that tetQ in strains containing the circular form remains actively expressed regardless of treatment, while the expression of tetQ in strains containing the linear form increases only in the presence of tetracycline.IMPORTANCEThe exchange of antibiotic production and resistance genes between microorganisms can lead to the emergence of new pathogens. In this study, short-read mapping of metagenomic samples taken over time from the illeal pouch of a patient with ulcerative colitis to a Bacteroides fragilis metagenome-assembled genome revealed two distinct genomic arrangements of a novel conjugative transposon, CTn214, that encodes tetracycline resistance. The autonomous amplification of a plasmid-like circular form from CTn214 that includes tetQ potentially provides consistent ribosome protection against tetracycline. This mode of antibiotic resistance offers a novel mechanism for understanding the emergence of pathobionts like B. fragilis and their persistence for extended periods of time in patients with inflammatory bowel disease.

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.

Tn5 synaptic complex formation: role of transposase residue W450.

A series of Tn5 transposases (Tnp's) with mutations at the conserved amino acid position W450, which was structurally predicted to be important for synapsis, have been generated and characterized. This study demonstrates that W450 is involved in hydrophobic (and possibly aromatic) contacts within the Tnp monomer that negatively regulate synaptic complex formation.

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.

Mobile DNA in obligate intracellular bacteria.

The small genomes of obligate intracellular bacteria are often presumed to be impervious to mobile DNA and the fluid genetic processes that drive diversification in free-living bacteria. Categorized by reductive evolution and streamlining, the genomes of some obligate intracellular bacteria manifest striking degrees of stability and gene synteny. However, recent findings from complete genome sequences of obligate intracellular species and their mobile genetic associates favour the abandonment of these wholesale terms for a more complex and tantalizing picture.

Transposon-based strategies for the identification of essential bacterial genes.

We present a conceptual review of transposition-based strategies for determining gene essentiality on a one-by-one basis in bacteria. Many of the techniques are described in greater detail in individual chapters of this volume. The second section of this chapter deals with transposition-deletion-based strategies for determining the essentiality of blocks of genes. This latter approach has the potential to experimentally define the minimal required genome for a given organism.

Defining characteristics of Tn5 Transposase non-specific DNA binding.

While non-specific DNA plays a role in target localization for many recombinases, transcription factors and restriction enzymes, the importance of non-specific DNA interactions for transposases has not been investigated. Here, we discuss non-specific DNA-Tn5 Transposase (Tnp) interactions and suggest how they stabilize the Tnp and modulate Tnp localization of the 19 bp Tnp recognition end sequences (ESes). DNA protection assays indicate that full-length Tnp interacts efficiently with supercoiled DNA that does not contain ESes. These interactions significantly prolong the lifetime of Tnp, in vitro. The balance between non-specific DNA bound and free Tnp is affected by DNA topology, yet, intermolecular transfer of active Tnp occurs with both supercoiled and linear non-specific DNA. Experiments with substrates of varying lengths show that Tn5 Tnp can utilize non-specific DNA to facilitate localization of an intramolecular ES over distances less than 464 bp. Finally, synaptic complex formation is inhibited in the presence of increasing concentrations of supercoiled and linear pUC19. These experiments strongly suggest that Tn5 Tnp has a robust non-specific DNA binding activity, that non-specific DNA modulates ES sequence localization within the global DNA, most likely through a direct transfer mechanism, and that non-specific DNA binding may play a role in the cis bias manifested by Tn5 transposition.

Screening transposon mutant libraries using full-genome oligonucleotide microarrays.

The experimental details for a high-throughput microarray-based screening technique for both detecting and mapping Tn5 insertion mutants in parallel within a library are presented. Following Tn5 mutagenesis, viable mutants are pooled and grown competitively under selective conditions. Chromosomal DNA is then isolated from each mutant pool. Biotin-labeled run-off in vitro RNA transcripts, representing the neighboring chromosomal DNA for each insertion remaining in the population, are generated using T7 promoters located at the ends of the transposon. Custom-designed, whole-genome oligonucleotide microarrays are used to analyze the labeled RNA transcripts and to detect each mutant in the library. Microarray data comparisons for each growth condition allow the identification of mutants that failed to survive the imposed growth selection. In addition, due to the density of the microarrays the genomic locations of the individual transposon insertions within each library can be identified to within 50 base pairs. Details for the in vivo Tn5 mutagenesis procedure, mutant library construction and competitive outgrowth, T7 in vitro transcription/labeling, and microarray data analysis will be provided.

JBP2, a SWI2/SNF2-like protein, regulates de novo telomeric DNA glycosylation in bloodstream form Trypanosoma brucei.

Synthesis of the modified thymine base, beta-d-glucosyl-hydroxymethyluracil or J, within telomeric DNA of Trypanosoma brucei correlates with the bloodstream form specific epigenetic silencing of telomeric variant surface glycoprotein genes involved in antigenic variation. In order to analyze the function of base J in the regulation of antigenic variation, we are characterizing the regulatory mechanism of J biosynthesis. We have recently proposed a model in which chromatin remodeling by a SWI2/SNF2-like protein (JBP2) regulates the developmental and de novo site-specific localization of J synthesis within bloodstream form trypanosome DNA. Consistent with this model, we now show that JBP2 (-/-) bloodstream form trypanosomes contain five-fold less base J and are unable to stimulate de novo J synthesis in newly generated telomeric arrays.

Structure/function insights into Tn5 transposition.

Prokaryotic transposon 5 (Tn5) serves as a model system for studying the molecular mechanism of DNA transposition. Elucidation of the X-ray co-crystal structure of Tn5 transposase complexed with a DNA recognition end sequence provided the first three-dimensional picture of an intermediate in a transposition/retroviral integration pathway. The many Tn5 transposase-DNA co-crystal structures now available complement biochemical and genetic studies, allowing a comprehensive and detailed understanding of transposition mechanisms. Specifically, the structures reveal two different types of protein-DNA contacts: cis contacts, required for initial DNA recognition, and trans contacts, required for catalysis. Protein-protein contacts required for synapsis are also seen. Finally, the two divalent metals in the active site of the transposase support a 'two-metal-ion' mechanism for Tn5 transposition.

Mutation of Tn5 transposase beta-loop residues affects all steps of Tn5 transposition: the role of conformational changes in Tn5 transposition.

X-ray cocrystal structures of Tn5 transposase (Tnp) bound to its 19 base pair (bp) recognition end sequence (ES) reveal contacts between a beta-loop (amino acids 240-260) and positions 3, 4, 5, and 6 of the ES. Here, we show that mutations of residues in this loop affect both in vivo and in vitro transposition. Most mutations are detrimental, whereas some mutations at position 242 cause hyperactivity. More specifically, mutations to the beta-loop affect every individual step of transposition tested. Mutants performing in vivo and in vitro transposition less efficiently also form fewer synaptic complexes, whereas hyperactive Tnps form more synaptic complexes. Surprisingly, two hypoactive mutations, K244R and R253L, also affect the cleavage steps of transposition with a much more dramatic effect on the second double end break (DEB) complex formation step, indicating that the beta-loop likely plays an important roll in positioning the substrate DNA within the catalytic site. Finally, all mutants tested decrease efficiency of the final transposition step, strand transfer. A disparity in cleavage rate constants in vitro for mutants with changes to the proline at position 242 on transposons flanked by ESs differing in the orientation of the A-T base pair at position 4 allows us to postulate that P242 contacts the position 4 nucleotide pair. On the basis of these data, we propose a sequential model for end cleavage in Tn5 transposition in which the uncleaved PEC is not symmetrical, and conformational changes are necessary between the first and second cleavage events and also for the final strand transfer step of transposition.

A high-throughput assay for Tn5 Tnp-induced DNA cleavage.

Transposition causes genomic instability by mobilizing DNA elements. This phenomenon is mechanistically related to other DNA rearrangements, such as V(D)J recombination and retroviral DNA integration. A conserved active site architecture within the transposase/integrase superfamily catalyzes these distinct phenomena. The Tn5 transposase (Tnp) falls within this protein class, and many intermediates of the Tn5 transposition reaction have been characterized. Here, we describe a method for the rapid identification of Tn5 Tnp small molecule effectors. This high-throughput screening strategy will aid in the identification of compounds that perturb Tnp-induced DNA cleavage. This method is advantageous, since it identifies effectors that specifically inhibit catalysis without inhibiting Tnp-DNA binding interactions. Effectors identified using this method will serve as a valuable aid both in the isolation and characterization of metal-bound reaction intermediates and in co-crystallization studies involving the effector, Tnp and DNA, to identify the structural basis of the interaction. Furthermore, since Tn5 Tnp shares a similar active site architecture to other transposase/integrase superfamily members, this strategy and any effectors identified using this method will be readily applicable to these other systems.

Production of combinatorial libraries of fused genes by sequential transposition reactions.

The use of in vivo and in vitro transposition reactions to perform non-combinatorial manipulation of DNAs in molecular biology is widespread. In this work we describe a technique that utilizes two sequential, directed transposition reactions in order to carry out combinatorial DNA manipulations. The methodology relies on the use of two different mutant Tn5 transposase proteins that have different transposon end recognition specificities. We demonstrate that the technique can be used to create large libraries of random fusions between two genes. These transpositional fusions are defined by insertion of a 32 bp linker sequence. We applied the technique to a model system, chloramphenicol acetyl transferase, to create functional fusions from N- and C-terminally truncated, non-functional genes. Comparative structural analysis suggests that both sides of the linker are inserted into disordered regions in functional proteins.

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.

Evidence for "unseen" transposase--DNA contacts.

In this study, evidence of novel, important interactions between a hyperactive Tn5 transposon recognition end sequence and hyperactive Tn5 transposase (Tnp) are presented. A hyperactive Tn5 end sequence, the mosaic end (ME), was isolated previously. The ME and a wild-type end sequence, the outside end (OE), differ at only three positions, yet transposition on the ME is tenfold higher than on the OE in vivo. Also, transposition on the ME is much more efficient than transposition on the OE in vitro. Here, we show that the decreased activity observed for the OE is caused by a defect in paired ends complex (PEC) formation resulting from the orientation of the A-T base-pair at position 4 of this end. Efficient PEC formation requires an interaction between the C5-methyl group (C5-Me) on the non-transferred strand thymine base at position 4 (T4) and Tnp. PEC formation on nicked substrates is much less affected by the orientation of the A-T base-pair at position 4, indicating that the C5-Me group is important only for steps preceding nicking. A recently determined co-crystal structure of Tn5 Tnp with the ME is discussed and a model explaining possible roles for the base-pair at position 4 is explored.

Tn5 as a molecular genetics tool: In vitro transposition and the coupling of in vitro technologies with in vivo transposition.

The development of in vitro transposition technologies have provided many powerful tools for the molecular genetics research laboratory. In this chapter we describe some of these tools with a focus on the Tn5 transposition system. Tn5 technologies are particularly useful because the Tn5 transposition system has simple requirements, is efficient, random in target recognition, and robust. In particular we will describe the use of in vitro Tn5 transposition in transposon tagging and in the generation of nested deletions. We will also describe a unique in vitro/in vivo technology in which Tn5 inserts can be generated in a wide spectrum of bacterial species through the electroporation of preformed tranposase-transposon DNA complexes.

Transposon Tn5.

Tn5 was one of the first transposons to be identified ( 10 ). As a result of Tn5's early discovery and its simple macromolecular requirements for transposition, the Tn5 system has been a very productive tool for studying the molecular mechanism of DNA transposition. These studies are of broad value because they offer insights into DNA transposition in general, because DNA transposition is a useful model with which to understand other types of protein-DNA interactions such as retroviral DNA integration and the DNA cleavage events involved in immunoglobulin gene formation, and because Tn5-derived tools are useful adjuncts in genetic experimentation.

A bifunctional DNA binding region in Tn5 transposase.

Tn5 transposition is a complicated process that requires the formation of a highly ordered protein-DNA structure, a synaptic complex, to catalyse the movement of a sequence of DNA (transposon) into a target DNA. Much is known about the structure of the synaptic complex and the positioning of protein-DNA contacts, although many protein-DNA contacts remain largely unstudied. In particular, there is little evidence for the positioning of donor DNA and target DNA. In this communication, we describe the isolation and analysis of mutant transposases that have, for the first time, provided genetic and biochemical evidence for the stage-specific positioning of both donor and target DNAs within the synaptic complex. Furthermore, we have provided evidence that some of the amino acids that contact donor DNA also contact target DNA, and therefore suggest that these amino acids help define a bifunctional DNA binding region responsible for these two transposase-DNA binding events.

Site-directed mutagenesis studies of tn5 transposase residues involved in synaptic complex formation.

Transposition (the movement of discrete segments of DNA, resulting in rearrangement of genomic DNA) initiates when transposase forms a dimeric DNA-protein synaptic complex with transposon DNA end sequences. The synaptic complex is a prerequisite for catalytic reactions that occur during the transposition process. The transposase-DNA interactions involved in the synaptic complex have been of great interest. Here we undertook a study to verify the protein-DNA interactions that lead to synapsis in the Tn5 system. Specifically, we studied (i) Arg342, Glu344, and Asn348 and (ii) Ser438, Lys439, and Ser445, which, based on the previously published cocrystal structure of Tn5 transposase bound to a precleaved transposon end sequence, make cis and trans contacts with transposon end sequence DNA, respectively. By using genetic and biochemical assays, we showed that in all cases except one, each of these residues plays an important role in synaptic complex formation, as predicted by the cocrystal structure.