Purification and characterization of TnsC, a Tn7 transposition protein that binds ATP and DNA

IS21 family transposase cleaved donor complex traps two right-handed superhelical crossings

Transposases are ubiquitous enzymes that catalyze DNA rearrangement events with broad impacts on gene expression, genome evolution, and the spread of drug-resistance in bacteria. Here, we use biochemical and structural approaches to define the molecular determinants by which IstA, a transposase present in the widespread IS21 family of mobile elements, catalyzes efficient DNA transposition. Solution studies show that IstA engages the transposon terminal sequences to form a high-molecular weight complex and promote DNA integration. A 3.4 Å resolution structure of the transposase bound to transposon ends corroborates our biochemical findings and reveals that IstA self-assembles into a highly intertwined tetramer that synapses two supercoiled terminal inverted repeats. The three-dimensional organization of the IstA•DNA cleaved donor complex reveals remarkable similarities with retroviral integrases and classic transposase systems, such as Tn7 and bacteriophage Mu, and provides insights into IS21 transposition.

Evolutionary and mechanistic diversity of Type I-F CRISPR-associated transposons

Canonical CRISPR-Cas systems utilize RNA-guided nucleases for targeted cleavage of foreign nucleic acids, whereas some nuclease-deficient CRISPR-Cas complexes have been repurposed to direct the insertion of Tn7-like transposons. Here, we established a bioinformatic and experimental pipeline to comprehensively explore the diversity of Type I-F CRISPR-associated transposons. We report DNA integration for 20 systems and identify a highly active subset that exhibits complete orthogonality in transposon DNA mobilization. We reveal the modular nature of CRISPR-associated transposons by exploring the horizontal acquisition of targeting modules and by characterizing a system that encodes both a programmable, RNA-dependent pathway, and a fixed, RNA-independent pathway. Finally, we analyzed transposon-encoded cargo genes and found the striking presence of anti-phage defense systems, suggesting a role in transmitting innate immunity between bacteria. Collectively, this study substantially advances our biological understanding of CRISPR-associated transposon function and expands the suite of RNA-guided transposases for programmable, large-scale genome engineering.

Structural basis for target site selection in RNA-guided DNA transposition systems

CRISPR-associated transposition systems allow guide RNA-directed integration of a single DNA cargo in one orientation at a fixed distance from a programmable target sequence. We used cryo-electron microscopy (cryo-EM) to define the mechanism that underlies this process by characterizing the transposition regulator, TnsC, from a type V-K CRISPR-transposase system. In this scenario, polymerization of adenosine triphosphate-bound TnsC helical filaments could explain how polarity information is passed to the transposase. TniQ caps the TnsC filament, representing a universal mechanism for target information transfer in Tn7/Tn7-like elements. Transposase-driven disassembly establishes delivery of the element only to unused protospacers. Finally, TnsC transitions to define the fixed point of insertion, as revealed by structures with the transition state mimic ADP•AlF₃ These mechanistic findings provide the underpinnings for engineering CRISPR-associated transposition systems for research and therapeutic applications.

Transposons to toxins: the provenance, architecture and diversification of a widespread class of eukaryotic effectors

Enzymatic effectors targeting nucleic acids, proteins and other cellular components are the mainstay of conflicts across life forms. Using comparative genomics we identify a large class of eukaryotic proteins, which include effectors from oomycetes, fungi and other parasites. The majority of these proteins have a characteristic domain architecture with one of several N-terminal 'Header' domains, which are predicted to play a role in trafficking of these effectors, including a novel version of the Ubiquitin fold. The Headers are followed by one or more diverse C-terminal domains, such as restriction endonuclease (REase), protein kinase, HNH endonuclease, LK-nuclease (a RNase) and multiple distinct peptidase domains, which are predicted to carry their toxicity determinants. The most common types of these proteins appear to have originated from prokaryotic transposases (e.g. TN7 and Mu) and combine a CDC6/ORC1-STAND clade NTPase domain with a C-terminal REase domain. Other than the so-called Crinkler effectors of oomycetes and fungi, these effectors are encoded by other eukaryotic parasites such as trypanosomatids (the RHS proteins) and the rhizarian Plasmodiophora, and symbionts like Capsaspora Remarkably, we also find these proteins in free-living eukaryotes, including several viridiplantae, fungi, amoebozoans and animals. These versions might either still be transposons or function in other poorly understood eukaryote-specific inter-organismal and inter-genomic conflicts. These include the Medea1 selfish element of Tribolium that spreads via post-zygotic killing. We present a unified mechanism for the recombination-dependent diversification and action of this widespread class of molecular weaponry deployed across diverse conflicts ranging from parasitic to free-living forms.

An Atypical AAA+ ATPase Assembly Controls Efficient Transposition through DNA Remodeling and Transposase Recruitment

Transposons are ubiquitous genetic elements that drive genome rearrangements, evolution, and the spread of infectious disease and drug-resistance. Many transposons, such as Mu, Tn7, and IS21, require regulatory AAA+ ATPases for function. We use X-ray crystallography and cryo-electron microscopy to show that the ATPase subunit of IS21, IstB, assembles into a clamshell-shaped decamer that sandwiches DNA between two helical pentamers of ATP-associated AAA+ domains, sharply bending the duplex into a 180° U-turn. Biochemical studies corroborate key features of the structure and further show that the IS21 transposase, IstA, recognizes the IstB•DNA complex and promotes its disassembly by stimulating ATP hydrolysis. Collectively, these studies reveal a distinct manner of higher-order assembly and client engagement by a AAA+ ATPase and suggest a mechanistic model where IstB binding and subsequent DNA bending primes a selected insertion site for efficient transposition.

Avoiding the ends: internal epitope tagging of proteins using transposon Tn7

Peptide tags fused to proteins are used in a variety of applications, including as affinity tags for purification, epitope tags for immunodetection, or fluorescent protein tags for visualization. However, the peptide tags can disrupt the target protein function. When function is disrupted by fusing a peptide to either the N or C terminus of the protein of interest, identifying alternative ways to create functional tagged fusion proteins can be difficult. Here, we describe a method to introduce protein tags internal to the coding sequence of a target protein. The method employs in vitro Tn7-transposon mutagenesis of plasmids for random introduction of the tag, followed by subsequent Gateway cloning steps to isolate alleles with mutations in the coding sequence of the target gene. The Tn7-epitope cassette is designed such that essentially all of the transposon is removed through restriction enzyme digestion, leaving only the protein tag at diverse sites internal to the ORF. We describe the use of this system to generate a panel of internally epitope-tagged versions of the Saccharomyces cerevisiae GPI-linked membrane protein Dcw1 and the Candida glabrata transcriptional regulator Sir3. This internal protein tagging system is, in principle, adaptable to tag proteins in any organism for which Gateway-adapted expression vectors exist.

The Tn7 transposition regulator TnsC interacts with the transposase subunit TnsB and target selector TnsD

The excision of transposon Tn7 from a donor site and its insertion into its preferred target site, attachment site attTn7, is mediated by four Tn7-encoded transposition proteins: TnsA, TnsB, TnsC, and TnsD. Transposition requires the assembly of a nucleoprotein complex containing all four Tns proteins and the DNA substrates, the donor site containing Tn7, and the preferred target site attTn7. TnsA and TnsB together form the heteromeric Tn7 transposase, and TnsD is a target-selecting protein that binds specifically to attTn7. TnsC is the key regulator of transposition, interacting with both the TnsAB transposase and TnsD-attTn7. We show here that TnsC interacts directly with TnsB, and identify the specific region of TnsC involved in the TnsB-TnsC interaction during transposition. We also show that a TnsC mutant defective in interaction with TnsB is defective for Tn7 transposition both in vitro and in vivo. Tn7 displays cis-acting target immunity, which blocks Tn7 insertion into a target DNA that already contains Tn7. We provide evidence that the direct TnsB-TnsC interaction that we have identified also mediates cis-acting Tn7 target immunity. We also show that TnsC interacts directly with the target selector protein TnsD.

Direct interaction between the TnsA and TnsB subunits controls the heteromeric Tn7 transposase

The transposon Tn7 transposase that recognizes the transposon ends and mediates breakage and joining is heteromeric. It contains the Tn7-encoded proteins TnsB, which binds specifically to the transposon ends and carries out breakage and joining at the 3' ends, and TnsA, which carries out breakage at the 5' ends of Tn7. TnsA apparently does not bind specifically to DNA, and we have hypothesized that it is recruited to the ends by interaction with TnsB. In this work, we show that TnsA and TnsB interact directly and identify several TnsA and TnsB amino acids involved in this interaction. We also show that TnsA can stimulate two key activities of TnsB, specific binding to the ends and pairing of the Tn7 ends. The ends of Tn7 are structurally asymmetric (i.e., contain different numbers of TnsB-binding sites), and Tn7 also is functionally asymmetric, inserting into its specific target site, attachment site attTn7 (attTn7) in a single orientation. Moreover, Tn7 elements containing two Tn7 right ends can transpose, but elements with two Tn7 left ends cannot. We show here that TnsA + TnsB are unable to pair the ends of a Tn7 element containing two Tn7 left ends. This pairing defect likely contributes to the inability of Tn7 elements with two Tn7 left ends to transpose.

Architecture of the Tn7 posttransposition complex: an elaborate nucleoprotein structure

Four transposition proteins encoded by the bacterial transposon Tn7, TnsA, TnsB, TnsC, and TnsD, mediate its site- and orientation-specific insertion into the chromosomal site attTn7. To establish which Tns proteins are actually present in the transpososome that executes DNA breakage and joining, we have determined the proteins present in the nucleoprotein product of transposition, the posttransposition complex (PTC), using fluorescently labeled Tns proteins. All four required Tns proteins are present in the PTC in which we also find that the Tn7 ends are paired by protein-protein contacts between Tns proteins bound to the ends. Quantification of the relative amounts of the fluorescent Tns proteins in the PTC indicates that oligomers of TnsA, TnsB, and TnsC mediate Tn7 transposition. High-resolution DNA footprinting of the DNA product of transposition attTn7Colon, two colonsTn7 revealed that about 350 bp of DNA on the transposon ends and on attTn7 contact the Tns proteins. All seven binding sites for TnsB, the component of the transposase that specifically binds the ends and mediates 3' end breakage and joining, are occupied in the PTC. However, the protection pattern of the sites closest to the Tn7 ends in the PTC are different from that observed with TnsB alone, likely reflecting the pairing of the ends and their interaction with the target nucleoprotein complex necessary for activation of the breakage and joining steps. We also observe extensive protection of the attTn7 sequences in the PTC and that alternative DNA structures in substrate attTn7 that are imposed by TnsD are maintained in the PTC.

Dissecting the roles of MuB in Mu transposition: ATP regulation of DNA binding is not essential for target delivery

Collaboration between MuA transposase and its activator protein, MuB, is essential for properly regulated transposition. MuB activates MuA catalytic activity, selects target DNA, and stimulates transposition into the selected target site. Selection of appropriate target DNA requires ATP hydrolysis by the MuB ATPase. By fusing MuB to a site-specific DNA-binding protein, the Arc repressor, we generated a MuB variant that could select target DNA independently of ATP. This Arc-MuB fusion protein allowed us to test whether ATP binding and hydrolysis by MuB are necessary for stimulation of transposition into selected DNA, a process termed target delivery. We find that with the fusion proteins, MuB-dependent target delivery occurs efficiently under conditions where ATP hydrolysis is prevented by mutation or use of ADP. In contrast, no delivery was detected in the absence of nucleotide. These data indicate that the ATP- and MuA-regulated DNA-binding activity of MuB is not essential for target delivery but that activation of MuA by MuB strictly requires nucleotide-bound MuB. Furthermore, we find that the fusion protein directs transposition to regions of the DNA within 40-750 bp of its own binding site. Taken together, these results suggest that target delivery by MuB occurs as a consequence of the ability of MuB to stimulate MuA while simultaneously tethering MuA to a selected target DNA. This tethered-activator model provides an attractive explanation for other examples of protein-stimulated control of target site selection.

Genetic evidence that GTP is required for transposition of IS903 and Tn552 in Escherichia coli

Surprisingly little is known about the role of host factors in regulating transposition, despite the potentially deleterious rearrangements caused by the movement of transposons. An extensive mutant screen was therefore conducted to identify Escherichia coli host factors that regulate transposition. An E. coli mutant library was screened using a papillation assay that allows detection of IS903 transposition events by the formation of blue papillae on a colony. Several host mutants were identified that exhibited a unique papillation pattern: a predominant ring of papillae just inside the edge of the colony, implying that transposition was triggered within these cells based on their spatial location within the colony. These mutants were found to be in pur genes, whose products are involved in the purine biosynthetic pathway. The transposition ring phenotype was also observed with Tn552, but not Tn10, establishing that this was not unique to IS903 and that it was not an artifact of the assay. Further genetic analyses of purine biosynthetic mutants indicated that the ring of transposition was consistent with a GTP requirement for IS903 and Tn552 transposition. Together, our observations suggest that transposition occurs during late stages of colony growth and that transposition occurs inside the colony edge in response to both a gradient of exogenous purines across the colony and the developmental stage of the cells.

The carboxy-terminal portion of TnsC activates the Tn7 transposase through a specific interaction with TnsA

Tn7 transposition requires the assembly of a nucleoprotein complex containing four self-encoded proteins, transposon ends, and target DNA. Within this complex, TnsC, the molecular switch that regulates transposition, and TnsA, one part of the transposase, interact directly. Here, we demonstrate that residues 504-555 of TnsC are responsible for TnsA/TnsC interaction. The crystal structure of the TnsA/TnsC(504-555) complex, resolved to 1.85 A, illustrates the burial of a large hydrophobic patch on the surface of TnsA. One consequence of sequestering this patch is a marked increase in the thermal stability of TnsA as shown by differential scanning calorimetry. A model based on the complex structure suggested that TnsA and a slightly longer version of the cocrystallized TnsC fragment (residues 495-555) might cooperate to bind DNA, a prediction confirmed using gel mobility shift assays. Donor DNA binding by the TnsA/TnsC(495-555) complex is correlated with the activation of the TnsAB transposase, as measured by double-stranded DNA cleavage assays, demonstrating the importance of the TnsA/TnsC interaction in affecting Tn7 transposition.

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

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

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

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

Tn7: smarter than we thought

A notable feature of transposable elements--segments of DNA that can move from one position to another in genomes--is that they are highly prevalent, despite the fact that their translocation can result in mutation. The bacterial transposon Tn7 uses an elaborate system of target-site selection pathways that favours the dispersal of Tn7 in diverse hosts as well as minimizing its negative effects.

Selective recognition of pyrimidine motif triplexes by a protein encoded by the bacterial transposon Tn7

The bacterial transposon Tn7 is distinguished among mobile genetic elements by its targeting abilities. Recently, we reported that Tn7 is able to selectively insert adjacent to triple-helical DNA. The binding of TnsC, a Tn7-encoded protein, to the triplex DNA target leads to the specific transposition of Tn7 adjacent to both inter- and intramolecular pyrimidine motif triplexes. Here, we further probe how Tn7 targets triplex DNA. We report that TnsC discriminates between different types of triplexes, showing binding preference for pyrimidine but not for purine motif intermolecular triplex DNA. The binding preferences of TnsC and the Tn7 insertion profiles were obtained using psoralenated, triplex- forming oligonucleotides annealed to plasmid DNAs. Although the presence of psoralen is not required for targeting nor is it alone able to attract TnsC, we show that the location of psoralen within the pyrimidine motif triplex does alter the position of Tn7 insertion relative to the triplex. Comparison between the triplex-targeting pathway and the highly site-specific targeting pathway mediated by the binding of the Tn7-encoded protein, TnsD, to the unique site attTn7, suggests that similar structural features within each target DNA are recognized by TnsC, leading to site-specific transposition. This work demonstrates that a prokaryotic protein involved in the targeting and regulation of Tn7 translocation, TnsC, can selectively recognize pyrimidine motif triplexes.

Arrayed transposase-binding sequences on the ends of transposon Tn5090/Tn402

The transposon Tn5090/Tn402 encodes a 559 amino acid transposase, TniA, with a DDE motif. Gel mobility shifting and cleavage protection analysis with DNase I and hydroxyl radical probes revealed that TniA binds to multiple repeat sequences on either terminus of Tn5090/Tn402. Four of these TniA-binding 19mers occurred on the left-hand (t) end and two on the right-hand (i) end. Hydroxyl radical cleavage protection demonstrated the presence of 3-6 bp contact sequences on one face of the DNA helix. The binding pattern and organisation of repeats suggested parallels between Tn5090/Tn402 and Mu, which controls its transpositional activity in the assembly step of a higher order transpososome complex. The complex terminal structure and genes of transposase and nucleotide-binding proteins in tandem are hallmarks of the handful of Mu-like elements that are known to date.

Target DNA structure plays a critical role in Tn7 transposition

The bacterial transposon Tn7 utilizes four Tn7-encoded proteins, TnsA, TnsB, TnsC and TnsD, to make insertions at a specific site termed attTn7. This target is selected by the binding of TnsD to attTn7 in a sequence-specific manner, followed by the binding of TnsC and activation of the transposase. We show that TnsD binding to attTn7 induces a distortion at the 5' end of the binding site and TnsC contacts the region of attTn7 distorted by TnsD. Previous work has shown that a target site containing triplex DNA, instead of TnsD-attTn7, can recruit TnsABC and effect site- specific insertion of Tn7. We propose that the DNA distortion imposed by TnsD on attTn7, like the altered DNA structure via triplex formation, serves as a signal to recruit TnsC. We also show that TnsD primarily contacts the major groove of DNA, whereas TnsC is a minor groove binding protein. The footprint of the TnsC-TnsD-attTn7 nucleoprotein complex includes and extends beyond the Tn7 insertion site, where TnsC forms a platform to receive and activate the transposase to carry out recombination.

Analysis of gain-of-function mutants of an ATP-dependent regulator of Tn7 transposition

The bacterial transposon Tn7 is distinguished by its unusual discrimination among targets, being particularly attracted to certain target DNA and actively avoiding other DNA. Tn7 transposition is mediated by the interaction of two alternative transposon-encoded target selection proteins, TnsD and TnsE, with a common core transposition machinery composed of the transposase (TnsAB) and an ATP-dependent DNA-binding protein TnsC. No transposition is observed with wild-type TnsABC. Here, we analyze the properties of two gain-of-function TnsC mutants that allow transposition in the absence of TnsD or TnsE. We find that these TnsC mutants have altered interactions with ATP and DNA that can account for their gain-of-function phenotype. We also show that TnsC is an ATPase and that it directly interacts with the TnsAB transposase. This work provides strong support to the view that TnsC and its ATP state are central to the control of Tn7 transposition.

Transposon Tn7 gene insertion into an evolutionarily conserved human homolog of Escherichia coli attTn7

Escherichia coli transposon Tn7 can integrate into its target DNA sequence, attTn7 at the 3' end of glmS, with high specificity and efficiency. Remarkably, the insertional recognition sequence in the E. coli genome displays a high degree of identity with the corresponding region at the 3' end of the corresponding human gene for glutamine-fructose-6-phosphate transaminase (GFPT), located at 2p13. It was therefore of interest to determine whether Tn7 could recognize the corresponding human sequence, and transpose at that site. Strains of E. coli DH5alpha were prepared carrying the tnsA-E genes on one plasmid, and attTn7 or the human equivalent on a second recipient plasmid within the alpha-complementation fragment of the lacZ gene. Each strain was transformed with a donor plasmid carrying a gentamycin resistance gene within the Tn7L and Tn7R cassettes. Restriction mapping and sequence analysis of recipient plasmids isolated from white colonies demonstrated that Tn7 inserted the gentamycin resistance gene both into the E. coli attTn7 sequence, and into its human counterpart. No nonspecific insertion was observed in a control plasmid containing only the lacZ fragment. These results provide a basis to investigate whether TnsA-D proteins can mediate gene insertion into comparably conserved sites in eukaryotic chromosomes.

Isolation and characterization of Tn7 transposase gain-of-function mutants: a model for transposase activation

Tn7 transposition has been hypothesized to require a heteromeric transposase formed by two Tn7-encoded proteins, TnsA and TnsB, and accessory proteins that activate the transposase when they are associated with an appropriate target DNA. This study investigates the mechanism of Tn7 transposase activation by isolation and analysis of transposase gain-of-function mutants that are active in the absence of these accessory proteins. This work shows directly that TnsA and TnsB are essential and sufficient components of the Tn7 transposase and also provides insight into the signals that activate the transposase. We also describe a protein-protein interaction between TnsA and TnsC, a regulatory accessory protein, that is likely to be critical for transposase activation.

A minimal system for Tn7 transposition: the transposon-encoded proteins TnsA and TnsB can execute DNA breakage and joining reactions that generate circularized Tn7 species

In the presence of ATP and Mg(2+), the bacterial transposon Tn7 translocates via a cut and paste mechanism executed by the transposon-encoded proteins TnsA+TnsB+TnsC+TnsD. We report here that in the presence of Mn(2+), TnsA+TnsB alone can execute the DNA breakage and joining reactions of Tn7 recombination. ATP is not essential in this minimal system, revealing that this cofactor is not directly involved in the chemical steps of recombination. In both the TnsAB and TnsABC+D systems, recombination initiates with double-strand breaks at each transposon end that cut Tn7 away from flanking donor DNA. In the minimal system, breakage occurs predominantly at a single transposon end and the subsequent end-joining reactions are intramolecular, with the exposed 3' termini of a broken transposon end joining near the other end of the Tn7 element in the same donor molecule to form circular transposon species. In contrast, in TnsABC+D recombination, breaks occur at both ends of Tn7 and the two ends join to a target site on a different DNA molecule to form an intermolecular simple insertion. This demonstration of the capacity of TnsAB to execute breakage and joining reactions supports the view that these proteins form the Tn7 transposase.

A simple in vitro Tn7-based transposition system with low target site selectivity for genome and gene analysis

A robust Tn7-based in vitro transposition system is described that displays little target site selectivity, allowing the efficient recovery of many different transposon insertions in target DNAs ranging from small plasmids to cosmids to whole genomes. Two miniTn7 derivatives are described that are useful for the analysis of genes: one a derivative for making translational and transcriptional target gene fusions and the other a derivative that can generate 15 bp (5 amino acid) insertions in target DNAs (proteins).

Mobile DNA elements: controlling transposition with ATP-dependent molecular switches

Nucleotide-binding proteins are often used as molecular switches to control the assembly or activity of macromolecular machines. Recent work has revealed that such molecular switches also regulate the spread of some mobile DNA elements. Bacteriophage Mu and the bacterial transposon Tn7 each use an ATP-dependent molecular switch to select a new site for insertion and to coordinate the assembly of the transposition machinery at that site. Strong parallels between these ATP-dependent transposition proteins and other well-characterized molecular switches, such as Ras and EF-Tu, have emerged.

A Tn7-like transposon is present in the glmUS region of the obligately chemoautolithotrophic bacterium Thiobacillus ferrooxidans

The region downstream of the Thiobacillus ferrooxidans ATCC 33020 atp operon was examined, and the genes encoding N-acetylglucosamine-1-uridyltransferase (glmU) and glucosamine synthetase (glmS) were found. This atpEFHAGDC-glmUS gene order is identical to that of Escherichia coli. The T. ferrooxidans glmS gene was shown to complement E. coli glmS mutants for growth on minimal medium lacking glucosamine. A Tn7-like transposon, Tn5468, was found inserted into the region immediately downstream of the glmS gene in a manner similar to the site-specific insertion of transposon Tn7 within the termination region of the E. coli glmS gene. Tn5468 was sequenced, and Tn7-like terminal repeat sequences as well as several open reading frames which are related to the Tn7 transposition genes tnsA, tnsB, tnsC, and tnsD were found. Tn5468 is the closest relative of Tn7 to have been characterized to date. Southern blot hybridization indicated that a similar or identical transposon was present in three T. ferrooxidans strains isolated from different parts of the world but not in two Thiobacillus thiooxidans strains or a Leptospirillum ferrooxidans strain. Since T. ferrooxidans is an obligately acidophilic autotroph and E. coli is a heterotroph, ancestors of the Tn7-like transposons must have been active in a variety of physiologically different bacteria so that their descendants are now found in bacteria that occupy very different ecological niches.

Avoiding self: two Tn7-encoded proteins mediate target immunity in Tn7 transposition

The bacterial transposon Tn7 exhibits target immunity, a process that prevents Tn7 from transposing into target DNAs that already contain a copy of the transposon. This work investigates the mechanism of target immunity in vitro. We demonstrate that two Tn7-encoded proteins_TnsB, which binds specifically to the ends of Tn7, and TnsC, the ATP-dependent DNA binding protein_act as a molecular switch to impose immunity on target DNAs containing Tn7 (or just Tn7 ends). TnsC binds to target DNA molecules and communicates with the Tn7 transposition machinery; here we show that target DNAs containing Tn7 ends are also bound and subsequently inactivated by TnsB. Protein-protein interactions between TnsB and TnsC appear to be responsible for this inactivation; the target DNA promotes these interactions by tethering TnsB and TnsC in high local concentration. An attractive model that emerges from this work is that TnsB triggers the dissociation of TnsC from the Tn7 end-containing target DNA; that dissociation depends on TnsC's ability to hydrolyze ATP. We propose that these interactions between TnsB and TnsC not only prevent Tn7 from inserting into itself, but also facilitate the selection of preferred target sites that is the hallmark of Tn7 transposition.

Gain-of-function mutations in TnsC, an ATP-dependent transposition protein that activates the bacterial transposon Tn7

The bacterial transposon Tn7 encodes five genes whose protein products are used in different combinations to direct transposition to different types of target sites. TnsABC + D directs transposition to a specific site in the Escherichia coli chromosome called attTn7, whereas TnsABC + E directs transposition to non-attTn7 sites. These transposition reactions can also recognize and avoid "immune" targets that already contain a copy of Tn7. TnsD and TnsE are required to activate TnsABC as well as to select a target site; no transposition occurs with wild-type TnsABC alone. Here, we describe the isolation of TnsC gain-of-function mutants that activate the TnsA+B transposase in the absence of TnsD or TnsE. Some of these TnsC mutants enable the TnsABC machinery to execute transposition without sacrificing its ability to discriminate between different types of targets. Other TnsC mutants appear to constitutively activate the TnsABC machinery so that it bypasses target signals. We also present experiments that suggest that target selection occurs early in the Tn7 transposition pathway in vivo: favorable attTn7 targets appear to promote the excision of Tn7 from the chromosome, whereas immune targets do not allow transposon excision to occur. This work supports the view that TnsC plays a central role in the evaluation and utilization of target DNAs.

The Tn7 transposase is a heteromeric complex in which DNA breakage and joining activities are distributed between different gene products

The bacterial transposon Tn7 translocates by a cut and paste mechanism: excision from the donor site results from double-strand breaks at each end of Tn7 and target insertion results from joining of the exposed 3' Tn7 tips to the target DNA. Through site-directed mutagenesis of the Tn7-encoded transposition proteins TnsA and TnsB, we demonstrate that the Tn7 transposase is a heteromeric complex of these proteins, each protein executing different DNA processing reactions. TnsA mediates DNA cleavage reactions at the 5' ends of Tn7, and TnsB mediates DNA breakage and joining reactions at the 3' ends of Tn7. Thus the double-strand breaks that underlie Tn7 excision result from a collaboration between two active sites, one in TnsA and one in TnsB; the same (or a closely related) active site in TnsB also mediates the subsequent joining of the 3' ends to the target. Both TnsA and TnsB appear to be members of the retroviral integrase superfamily: mutation of their putative DD(35)E motifs blocks catalytic activity. Recombinases of this class require a divalent metal cofactor that is thought to interact with these acidic residues. Through analysis of the metal ion specificity of a TnsA mutant containing a sulfur (cysteine) substitution, we provide evidence that a divalent metal actually interacts with these acidic amino acids.

Switching from cut-and-paste to replicative Tn7 transposition

The bacterial transposon Tn7 usually moves through a cut-and-paste mechanism whereby the transposon is excised from a donor site and joined to a target site to form a simple insertion. The transposon was converted to a replicative element that generated plasmid fusions in vitro and cointegrate products in vivo. This switch was a consequence of the separation of 5'- and 3'-end processing reactions of Tn7 transposition as demonstrated by the consequences of a single amino acid alteration in an element-encoded protein essential for normal cut-and-paste transposition. The mutation specifically blocked cleavage of the 5' strand at each transposon end without disturbing the breakage and joining on the 3' strand, producing a fusion (the Shapiro Intermediate) that resulted in replicative transposition. The ability of Tn7 recombination products to serve as substrates for both the limited gap repair required to complete cut-and-paste transposition and the extensive DNA replication involved in cointegrate formation suggests a remarkable plasticity in Tn7's recruitment of host repair and replication functions.

Transposon Tn5090 of plasmid R751, which carries an integron, is related to Tn7, Mu, and the retroelements

Integrons confer on bacterial plasmids a capability of taking up antibiotic resistance genes by integrase-mediated recombination. We show here that integrons are situated on genetic elements flanked by 25-bp inverted repeats. The element carrying the integron of R751 has three segments conserved with similar elements in Tn21 and Tn5086. Several characteristics suggest that this element is a transposon, which we call Tn5090. Tn5090 was shown to contain an operon with three open reading frames, of which two, tniA and tniB, were predicted by amino acid similarity to code for transposition proteins. The product of tniA (559 amino acids) is a probable transposase with 25% amino acid sequence identity to TnsB from Tn7. Both of these polypeptides contain the D,D(35)E motif characteristic of a protein family made up of the retroviral and retrotransposon IN proteins and some bacterial transposases, such as those of Tn552 and of a range of insertion sequences. Like the transposase genes in Tn552, Mu, and Tn7, the tniA gene was followed by a gene, tniB, for a probable ATP-binding protein. The ends of Tn5090, like those of most other elements producing D,D(35)E proteins, begin by 5'-TG and also contains a complex structure with four 19-bp repeats at the left end and three at the right end. Similarly organized repeats have been observed earlier at the termini of both Tn7 and phage Mu, where they bind their respective transposases and have a role in holoenzyme assembly. Another open reading frame observed in Tn5090, tniC, codes for a recombinase of the invertase/resolvase family, suggesting a replicative transposition mechanism. The data presented here suggest that Tn5090, Tn7, Tn552, and Mu form a subfamily of bacterial transposons which in parallel to many insertion sequences are related to the retroelements.

Molecular matchmakers

Molecular matchmakers are a class of proteins that use the energy released from the hydrolysis of adenosine triphosphate to cause a conformational change in one or both components of a DNA binding protein pair to promote formation of a metastable DNA-protein complex. After matchmaking the matchmaker dissociates from the complex, permitting the matched protein to engage in other protein-protein interactions to bring about the effector function. Matchmaking is most commonly used under circumstances that require targeted, high-avidity DNA binding without relying solely on sequence specificity. Molecular matchmaking is an extensively used mechanism in repair, replication, and transcription and most likely in recombination and transposition reactions, too.