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.     

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.     

Isolation and characterization of the Tn3 resolvase synaptic intermediate.

We have isolated in quantitative yield the synaptic intermediate formed during site-specific recombination by Tn3 resolvase and characterized it by restriction endonuclease mapping, electron microscopy and topological methods. The intermediate accumulates at low reaction temperatures and is stabilized by crosslinking of the resolvase protomers with glutaraldehyde. The DNA-resolvase complex that maintains the structure of the intermediate (the synaptosome) is approximately 100 A in diameter, forms specifically at resolution (res) sites, and requires two res sites in a supercoiled DNA molecule. Resolvase bound to individual res sites protects approximately -0.5 supercoil per site from relaxation by a topoisomerase, whereas the formation of the synaptosome protects -3 supercoils and condenses the associated DNA to a supercoil density 2.5 times that of the non-complexed substrate. Although recombination requires two directly repeated res sites, both direct and inverted sites form synaptosomes. We conclude that the specificity of recombination is achieved by a three-stage recognition system: binding of resolvase to separate sites, formation of the synaptosome and determination of site orientation from within the complex.     

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

The bacterial transposon Tn7 encodes five transposition genes tnsABCDE. We report a simple and rapid procedure for the purification of TnsC protein. We show that purified TnsC is active in and required for Tn7 transposition in a cell-free recombination system. This finding demonstrates that TnsC participates directly in Tn7 transposition and explains the requirement for tnsC function in Tn7 transposition. We have found that TnsC binds adenine nucleotides and is thus a likely site of action of the essential ATP cofactor in Tn7 transposition. We also report that TnsC binds non-specifically to DNA in the presence of ATP or the generally non-hydrolyzable analogues AMP-PNP and ATP-gamma-S, and that TnsC displays little affinity for DNA in the presence of ADP. We speculate that TnsC plays a central role in the selection of target DNA during Tn7 transposition.     

Identification of a circular intermediate in the transfer and transposition of Tn4555, a mobilizable transposon from Bacteroides spp.

Transmissible cefoxitin (FX) resistance in Bacteroides vulgatus CLA341 was associated with the 12.5-kb, mobilizable transposon, Tn4555, which encoded the beta-lactamase gene cfxA. Transfer occurred by a conjugation-like mechanism, was stimulated by growth of donor cells with tetracycline (TC), and required the presence of a Bacteroides chromosomal Tcr element. Transconjugants resistant to either FX, TC, or both drugs were obtained, but only Fxr Tcr isolates could act as donors of Fxr in subsequent matings. Transfer of Fxr could be restored in Fxr Tcs strains by the introduction of a conjugal Tcr element from Bacteroides fragilis V479-1. A covalently closed circular DNA form of Tn4555 was observed in donor cells by Southern hybridization, and the levels of this circular transposon increased significantly in cells grown with TC. Both the cfxA gene and the Tn4555 mobilization region hybridized to the circular DNA, suggesting that this was a structurally intact transposon unit. Circular transposon DNA purified by CsCl-ethidium bromide density gradient centrifugation was used to transform Tcs B. fragilis 638, and Fxr transformants were obtained. Both the circular form and the integrated Tn4555 were observed in transformants, but the circular form was present at less than one copy per chromosomal equivalent. Examination of genomic DNA from Fxr transformants and transconjugants revealed that Tn4555 could insert at a wide variety of chromosomal sites. Multiple transposon insertions were present in many of the transconjugants, indicating that there was no specific barrier to the introduction of a second transposon copy.     

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.     

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.     

Tn10 transposition and circle formation in vitro

We describe a cell-free system that promotes Tn10 transposition and transposon circle formation, a related intramolecular event. Tn10 circle formation in vitro has been characterized in detail, and is shown to require a supercoiled substrate and to proceed in the absence of ATP. The reaction requires Tn10 transposase protein, and either of two E. coli proteins, integration host factor (IHF) and HU, which are small DNA binding proteins that change the conformation of DNA. Tn10 is composed of inverted repeats of insertion sequence IS10. Pair-wise combinations of the IS10 "outside" and "inside" ends mediate distinct classes of rearrangements in vivo, and they exhibit different reaction requirements in vitro. In contrast to the Tn10 reaction, which involves two outside ends, circle formation with two inside ends proceeds with a transposase fraction alone, in the absence of added host factors, and is inhibited by methylation of the dam site within each terminus.     

Identification and characterization of an Epstein-Barr virus early antigen that is encoded by the NotI repeats.

The Epstein-Barr virus (EBV) genome is characterized by two regions carrying partially homologous clusters of short tandem repeats (NotI and PstI repeats) flanked by 1,044 and 1,045 base pairs with almost perfect homology (DL and DR, left and right duplications, respectively). Both repetitive regions are transcribed into poly(A)+ mRNA after induction of the productive EBV cycle with the tumor promoter 12-O-tetradecanoylphorbol-13-acetate and contain open reading frames. To identify the potential protein encoded by the NotI repeat open reading frame (BHLF1), two repeat units of EBV strain M-ABA were expressed using the tryptophan-regulated Escherichia coli expression vector pATH11. Rabbit antisera generated against the resulting fusion protein reacted specifically with a protein varying in molecular size between 70,000 and 90,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, found after 12-O-tetradecanoyl-phorbol-13-acetate or n-butyrate induction in various cell lines harboring EBV. In immunofluorescence tests with the BHLF1-specific antiserum, an immunofluorescence with EA-D specificity could be observed. In addition, the BHLF1 protein is exhibiting polyanion-binding activity with a maximum for single-stranded DNA. Furthermore, the fusion protein is recognized by a number of human EBV-positive sera.     

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

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

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.     

Tn7 transposition in vitro proceeds through an excised transposon intermediate generated by staggered breaks in DNA.

We have developed a cell-free system in which the bacterial transposon Tn7 inserts at high frequency into its preferred target site in the Escherichia coli chromosome, attTn7; Tn7 transposition in vitro requires ATP and Tn7-encoded proteins. Tn7 transposes via a cut and paste mechanism in which the element is excised from the donor DNA by staggered double-strand breaks and then inserted into attTn7 by the joining of 3' transposon ends to 5' target ends. Neither recombination intermediates nor products are observed in the absence of any protein component or DNA substrate. Thus, we suggest that Tn7 transposition occurs in a nucleoprotein complex containing several proteins and the substrate DNAs and that recognition of attTn7 within this complex provokes strand cleavages at the Tn7 ends.     

Spectroscopic evidence for a porphobilinogen deaminase-tetrapyrrole complex that is an intermediate in the biosynthesis of uroporphyrinogen III

Incubation of porphobilinogen (PBG) with PBG deaminase from Rhodopseudomonas sphaeroides in carbonate buffer (pH 9.2) to total PBG consumption resulted in low yields of uroporphyrinogen I (uro'gen I). In the reaction mixture a pyrrylmethane accumulated, which at longer incubation periods was transformed into uro'gen I. The accumulated pyrrylmethane gave an Ehrlich reaction which was different from that of a 2-(aminomethyl)dipyrrylmethane or 2-(aminomethyl)tripyrrane. It resembled that of a bilane (tetrapyrrylmethane) but was different from that of a 2-(hydroxymethyl)bilane. The 13C NMR spectra of incubations carried out with [11-13C]PBG indicated that the pyrrylmethane was a tetrapyrrole with methylene resonances at 22.35-22.50 ppm. It was loosely bound to the deaminase, and when separated from the enzyme by gel filtration or gel electrophoresis, it immediately cyclized to uro'gen I. No enzyme-bound methylene could be detected by its chemical shift, suggesting that its line width must be very broad. When uro'gen III-cosynthase was added to the deaminase-tetrapyrrole complex, uro'gen III was formed at the expense of the latter in about 75% yield. The tetrapyrrole could only be partially displaced from the enzyme by ammonium ions, although a small amount of 2-(aminomethyl)bilane was always formed together with the tetrapyrrole intermediate. A protonated uro'gen I structure for this intermediate was ruled out by incubations using [2,11-13C]PBG. Uro'gen III formation from 2-(hydroxymethyl)bilane (HMB) and from the deaminase-tetrapyrrole intermediate was compared by using deaminase-cosynthase and cosynthase from several sources. It was found that while the HMB inhibited uro'gen III formation at higher concentrations and longer incubation times, uro'gen III formation from the complex did not decrease with time.     

Transposon Tn7. cis-Acting sequences in transposition and transposition immunity

We have identified and characterized the cis-acting sequences at the termini of the bacterial transposon Tn7 that are necessary for its transposition. Tn7 participates in two kinds of transposition event: high-frequency transposition to a specific target site (attTn7) and low-frequency transposition to apparently random target sites. Our analyses suggest that the same sequences at the Tn7 ends are required for both transposition events. These sequences differ in length and nucleotide structure: about 150 base-pairs at the left end (Tn7L) and about 70 base-pairs at the right end (Tn7R) are necessary for efficient transposition. We also show that the ends of Tn7 are functionally distinct: a miniTn7 element containing two Tn7R ends is active in transposition but an element containing two Tn7L ends is not. We also report that the presence of Tn7's cis-acting transposition sequences anywhere in a target replicon inhibits subsequent insertion of another copy of Tn7 into either an attTn7 target site or into random target sites. The inhibition to an attTn7 target site is most pronounced when the Tn7 ends are immediately adjacent to attTn7. We also show that the presence of Tn7R's cis-acting transposition sequences in a target replicon is necessary and sufficient to inhibit subsequent Tn7 insertion into the target replicon.     

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.     

Identification of transposition proteins encoded by the bacterial transposon Tn7.

The bacterial transposon, Tn7, encodes an elaborate array of transposition genes, tnsABCDE. We report here the direct identification of the TnsA, TnsB, TnsC and TnsD polypeptides by immunoblotting. Our results demonstrate that the complexity of the protein information devoted to Tn7 transposition is considerable: the aggregate molecular size of the five Tns polypeptides is about 300 kDa. We also report the sequence of the tnsA gene and of the 5' ends of tnsB and tnsD. This analysis reveals that all five tns genes are oriented in the same direction within Tn7.     

Tn10 transpososome assembly involves a folded intermediate that must be unfolded for target capture and strand transfer

Tn10 transposition, like all transposition reactions examined thus far, involves assembly of a stable protein-DNA transpososome, containing a pair of transposon ends, within which all chemical events occur. We report here that stable Tn10 pre-cleavage transpososomes occur in two conformations: a folded form which contains the DNA-bending factor IHF and an unfolded form which lacks IHF. Functional analysis shows that both forms undergo double strand cleavage at the transposon ends but that only the unfolded form is competent for target capture (and thus for strand transfer to target DNA). Additional studies reveal that formation of any type of stable transpososome, folded or unfolded, requires not only IHF but also non-specific transposase-DNA contacts immediately internal to the IHF-binding site, implying the occurrence of a topo- logically closed loop at the transposon end. Overall, transpososome assembly must proceed via a folded intermediate which, however, must be unfolded in order for intermolecular transposition to occur. These and other results support key features of a recently proposed model for transpososome assembly and morphogenesis.