Characterizing the DNA contacts and cooperative binding of F plasmid TraM to its cognate sites at oriT

TraM is a DNA binding protein required for conjugative transfer of the self-transmissible IncF group of plasmids, including F, R1, and R100. F TraM binds to three sites in F oriT: two high affinity binding sites, sbmA and sbmB, which are direct repeats of nearly identical sequence involved in the autoregulation of the traM gene; and a lower affinity site, sbmC, an inverted repeat important for transfer, which is situated nearest to the nic site where transfer originates. TraM bound cooperatively to its binding sites at oriT; the presence of sbmA and sbmB increased the affinity for sbmC 10-fold. Bending of oriT DNA by TraM was minimal, suggesting that TraM, a tetramer, was able to loop the DNA when bound to sbmA and sbmB simultaneously. Hydroxyl radical footprinting of DNA of sbmA and sbmC revealed that TraM contacted the DNA within a region previously delineated by DNase I footprinting. TraM protected the CT bases within the sequence CTAG, which occurred at 12-base intervals on the top and bottom strand of sbmA, most consistently with other protected bases. The footprint on sbmC revealed that the predicted inverted repeats were protected by TraM with a pattern that began at the center of the repeats and radiated outward at 11-12 base intervals toward the 5'-ends of either strand. At high protein concentrations, this pattern extended beyond the footprint defined by DNase I, suggesting that the DNA was wrapped around the protein forming a nucleosome-like structure, which could aid in preparing the DNA for transfer.     

TraY and integration host factor oriT binding sites and F conjugal transfer: sequence variations, but not altered spacing, are tolerated

Bacterial conjugation is the process by which a single strand of a conjugative plasmid is transferred from donor to recipient. For F plasmid, TraI, a relaxase or nickase, binds a single plasmid DNA strand at its specific origin of transfer (oriT) binding site, sbi, and cleaves at a site called nic. In vitro studies suggest TraI is recruited to sbi by its accessory proteins, TraY and integration host factor (IHF). TraY and IHF bind conserved oriT sites sbyA and ihfA, respectively, and bend DNA. The resulting conformational changes may propagate to nic, generating the single-stranded region that TraI can bind. Previous deletion studies performed by others showed transfer efficiency of a plasmid containing F oriT decreased progressively as increasingly longer segments, ultimately containing both sbyA and ihfA, were deleted. Here we describe our efforts to more precisely define the role of sbyA and ihfA by examining the effects of multiple base substitutions at sbyA and ihfA on binding and plasmid mobilization. While we observed significant decreases in in vitro DNA-binding affinities, we saw little effect on plasmid mobilization even when sbyA and ihfA variants were combined. In contrast, when half or full helical turns were inserted between the relaxosome protein-binding sites, mobilization was dramatically reduced, in some cases below the detectable limit of the assay. These results are consistent with TraY and IHF recognizing sbyA and ihfA with limited sequence specificity and with relaxosome proteins requiring proper spacing and orientation with respect to each other.     

Mobilization of chimeric oriT plasmids by F and R100-1: role of relaxosome formation in defining plasmid specificity

Cleavage at the F plasmid nic site within the origin of transfer (oriT) requires the F-encoded proteins TraY and TraI and the host-encoded protein integration host factor in vitro. We confirm that F TraY, but not F TraM, is required for cleavage at nic in vivo. Chimeric plasmids were constructed which contained either the entire F or R100-1 oriT regions or various combinations of nic, TraY, and TraM binding sites, in addition to the traM gene. The efficiency of cleavage at nic and the frequency of mobilization were assayed in the presence of F or R100-1 plasmids. The ability of these chimeric plasmids to complement an F traM mutant or affect F transfer via negative dominance was also measured using transfer efficiency assays. In cases where cleavage at nic was detected, R100-1 TraI was not sensitive to the two-base difference in sequence immediately downstream of nic, while F TraI was specific for the F sequence. Plasmid transfer was detected only when TraM was able to bind to its cognate sites within oriT. High-affinity binding of TraY in cis to oriT allowed detection of cleavage at nic but was not required for efficient mobilization. Taken together, our results suggest that stable relaxosomes, consisting of TraI, -M, and -Y bound to oriT are preferentially targeted to the transfer apparatus (transferosome).     

Intrinsic bends and integration host factor binding at F plasmid oriT.

F plasmid oriT DNA extending from the F kilobase coordinate 66.7 (base pair [bp] 1 on the oriT sequence map) rightward to bp 527 was analyzed for intrinsic bends (by permutation assays) and for binding of integration host factor (IHF) (by gel retardation and DNase footprinting). Intrinsic bending of the 527-bp fragment (bend center approximately at bp 240) was represented as a composite of at least two components located near bp 170 and near bp 260. IHF bound primarily to a site extending from bp 165 to 195 and with lower affinity to a site extending from bp 287 to 319. The intrinsic curvature and sequences to which IHF binds (IHF is known to bend DNA) may play a structural role in oriT function.     

The F plasmid-encoded TraM protein stimulates relaxosome-mediated cleavage at oriT through an interaction with TraI

Conjugative DNA transfer is a highly conserved process for the direct transfer of DNA from a donor to a recipient. The conjugative initiator proteins are key players in the DNA processing reactions that initiate DNA transfer - they introduce a site- and strand-specific break in the DNA backbone via a transesterification that leaves the initiator protein covalently bound on the 5'-end of the cleaved DNA strand. The action of the initiator protein at the origin of transfer (oriT) is governed by auxiliary proteins that alter the architecture of the DNA molecule, allowing binding of the initiator protein. In the F plasmid system, two auxiliary proteins have roles in establishing the relaxosome: the host-encoded IHF and the plasmid-encoded TraY. Together, these proteins direct the loading of TraI which contains the catalytic centre for the transesterification. The F-oriT sequence includes a binding site for another plasmid-encoded protein, TraM, which is required for DNA transfer. Here the impact of TraM protein on the formation and activity of the F plasmid relaxosome has been examined. Purified TraM stimulates the formation of relaxed DNA in a reaction that requires the minimal components of the relaxosome, TraI, TraY and IHF. Unlike TraY and IHF, TraM is not essential for the formation of the relaxosome in vitro and TraM cannot substitute for either TraY or IHF in this process. The TraM binding site sbmC, along with both IHF binding sites, is essential for stimulation of the relaxase reaction. In addition, stimulation of transesterification appears to require the C-terminal domain of TraI suggesting that TraM and TraI may interact through this domain on TraI. Taken together, these results provide additional evidence of a role for TraM as a component of the relaxosome, suggest a previously unknown interaction between TraI and TraM, and allow us to propose a molecular role for the C-terminal domain of TraI.     

Characterization of the functional sites in the oriT region involved in DNA transfer promoted by sex factor plasmid R100.

We have previously identified three sites, named sbi, ihfA, and sbyA, specifically recognized or bound by the TraI, IHF, and TraY proteins, respectively; these sites are involved in nicking at the origin of transfer, oriT, of plasmid R100. In the region next to these sites, there exists the sbm region, which consists of four sites, sbmA, sbmB, sbmC, and sbmD; this region is specifically bound by the TraM protein, which is required for DNA transfer. Between sbmB and sbmC in this region, there exists another IHF-binding site, ihfB. The region containing all of these sites is located in the proximity of the tra region and is referred to as the oriT region. To determine whether these sites are important for DNA transfer in vivo, we constructed plasmids with various mutations in the oriT region and tested their mobilization in the presence of R100-1, a transfer-proficient mutant of R100. Plasmids with either deletions in the sbi-ihfA-sbyA region or substitution mutations introduced into each specific site in this region were mobilized at a greatly reduced frequency, showing that all of these sites are essential for DNA transfer. By binding to ihfA, IHF, which is known to bend DNA, may be involved in the formation of a complex (which may be called oriT-some) consisting of TraI, IHF, and TraY that efficiently introduces a nick at oriT. Plasmids with either deletions in the sbm-ihfB region or substitution mutations introduced into each specific site in this region were mobilized at a reduced frequency, showing that this region is also important for DNA transfer. By binding to ihfB, IHF may also be involved in the formation of another complex (which may be called the TraM-IHF complex) consisting of TraM and IHF that ensures DNA transfer with a high level of efficiency. Several-base-pair insertions into the positions between sbyA and sbmA affected the frequency of transfer in a manner dependent upon the number of base pairs, indicating that the phasing between sbyA and sbmA is important. This in turn suggests that both oriT-some and the TraM-IHF complex should be in an appropriate position spatially to facilitate DNA transfer.     

Specific binding of the TraY protein to oriT and the promoter region for the traY gene of plasmid R100

The traY gene product of plasmid R100 was purified as a hybrid protein, TraY-collagen-beta-galactosidase. The hybrid protein as well as the TraY' protein, which was obtained by collagenolysis of the hybrid protein, specifically binds to an AT-rich 36-base pair sequence (here called sbyA) within the region including the origin of transfer, oriT. The oriT region consists of highly conserved and nonconserved regions among R100-related plasmids, and sbyA was located within the nonconserved region immediately adjacent to the conserved region. This supports the idea that the TraY protein has a role as a component of endonuclease in recognizing its own oriT sequence. Unexpectedly, however, the hybrid protein and the TraY' protein were also found to bind to two different AT-rich sequences (each 24 base pairs in length) in the promoter region preceding the traY gene (here called sbyB and sbyC). This suggests that the TraY protein may have another role in regulating the expression of its own gene. The "TAA(A/T)T" sequence motif observed in these binding sites might constitute a core sequence recognized by the TraY protein. Mg2+ is not required for the specific binding of the TraY protein.     

Centromere pairing by a plasmid-encoded type I ParB protein

The par2 locus of Escherichia coli plasmid pB171 encodes two trans-acting proteins, ParA and ParB, and two cis-acting sites, parC1 and parC2, to which ParB binds cooperatively. ParA is related to MinD and oscillates in helical structures and thereby positions ParB/parC-carrying plasmids regularly over the nucleoid. ParB ribbon-helix-helix dimers bind cooperatively to direct repeats in parC1 and parC2. Using four different assays we obtain solid evidence that ParB can pair parC1- and parC2-encoding DNA fragments in vitro. Convincingly, electron microscopy revealed that ParB mediates binary pairing of parC fragments. In addition to binary complexes, ParB mediated the formation of higher order complexes consisting of several DNA fragments joined by ParB at centromere site parC. N-terminal truncated versions of ParB still possessing specific DNA binding activity were incompetent in pairing, hence identifying the N terminus of ParB as a requirement for ParB-mediated centromere pairing. These observations suggest that centromere pairing is an important intermediate step in plasmid partitioning mediated by the common type I loci.     

Mutational and physical analysis of F plasmid traY protein binding to oriT

F plasmid traY protein binding to wild-type or deleted regions containing the TraY-binding site, sbyA, was studied in vitro. The principal DNA-protein complex was formed with DNA segments including the sbyA site defined by footprinting and (with lesser affinity) with truncated segments that retained the leftward two-thirds of sbyA. This located the major sequence determinants for TraY binding between bp 204 and 227 on the oriT map. For all sequences tested, bound TraY induced bending of approximateiy 50 to 55°, and centred between bp 214 and 221. Thermodynamic and mobility analyses indicated that two TraY protomers bind to sbyA. At higher TraY concentrations, additional TraY bound to the left of the sbyA in a region previously shown to bind IHF (site IHF A). TraY binding to this additional site (sbyC) was inhibited by IHF. Sequence similarities shared by sbyA, sbyB, and SbyC may include the critical base pairs for TraY binding.     

Purified Escherichia coli F-factor TraY protein binds oriT.

The traY gene of the Escherichia coli F plasmid has been shown by genetic studies (R. Everett and N. Willetts, J. Mol. Biol. 136:129-150, 1980) to be involved in the site-specific nicking reaction at oriT required for the initiation of DNA transfer during bacterial conjugation. In order to assign a biochemical function to TraY protein, the traY gene was cloned in a plasmid vector which utilizes the strong T7 phi 10 promoter to overproduce the protein. The plasmid-encoded TraY protein was specifically labeled with [35S]methionine, and purification of the polypeptide was accomplished by monitoring the radioactive label. Purified TraY protein had a relative molecular mass of approximately 17,000, as determined by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The amino terminus of the purified protein was sequenced to confirm that the protein was encoded by the traY gene. The protein sequence revealed that the start codon for the TraY protein was a UUG codon 36 base pairs upstream of the AUG start site originally deduced from the DNA sequence (T. Fowler, L. Taylor, and R. Thompson, Gene 26:79-89, 1983). This start sequence confirmed the premise of Inamoto et al. that the F-plasmid TraY polypeptide-coding sequence would begin with UUG, creating a reading frame which renders a large degree of amino acid sequence identity with the TraY polypeptide from R100 (S. Inamoto, Y. Yoshioka, and E. Ohtsubo, J. Bacteriol. 170:2749-2757, 1988). The purified TraY protein from F bound specifically to the origin of transfer region of the F plasmid. However, no nicking activity was detected at oriT by using TraY protein or TraY protein in conjunction with helicase I.     

Maize Activator transposase has a bipartite DNA binding domain that recognizes subterminal sequences and the terminal inverted repeats

The mobility of maize transposable element Activator (Ac) is dependent on the 11-bp terminal inverted repeats (IRs) and approximately 250 subterminal nucleotides at each end. These sequences flank the coding region for the transposase (TPase) protein, which is required for the transposition reaction. Here we show that Ac TPase has a bipartite DNA binding domain, and recognizes the IRs and subterminal sequences in the Ac ends. TPase binds cooperatively to repetitive ACG and TCG sequences, of which 25 copies are found in the 5′ and 20 copies in the 3′ subterminal regions. TPase affinity is highest when these sites are flanked on the 3′ side by an additional G residue (A/TCGG), which is found at 75% of binding sites. Moreover, TPase binds specifically to the Ac IRs, albeit with much lower affinity. Two mutations within the IRs that immobilize Ac abolish TPase binding completely. The basic DNA binding domain of TPase is split into two subdomains. Binding to the subterminal motifs is accomplished by the C-terminal subdomain alone, whereas recognition of the IRs requires the N-terminal subdomain in addition. Furthermore, TPase is extremely flexible in DNA binding. Two direct or inverted binding sites are bound equally well, and sites that are five to twelve bases apart are similarly well bound. The consequences of these findings for the Ac transposition reaction are discussed.     

Characterization of DNA binding sites of the ComE response regulator from Streptococcus mutans

In Streptococcus mutans, both competence and bacteriocin production are controlled by ComC and the ComED two-component signal transduction system. Recent studies of S. mutans suggested that purified ComE binds to two 11-bp direct repeats in the nlmC-comC promoter region, where ComE activates nlmC and represses comC. In this work, quantitative binding studies and DNase I footprinting analysis were performed to calculate the equilibrium dissociation constant and further characterize the binding site of ComE. We found that ComE protects sequences inclusive of both direct repeats, has an equilibrium dissociation constant in the nanomolar range, and binds to these two direct repeats cooperatively. Furthermore, similar direct repeats were found upstream of cslAB, comED, comX, ftf, vicRKX, gtfD, gtfB, gtfC, and gbpB. Quantitative binding studies were performed on each of these sequences and showed that only cslAB has a similar specificity and high affinity for ComE as that seen with the upstream region of comC. A mutational analysis of the binding sequences showed that ComE does not require both repeats to bind DNA with high affinity, suggesting that single site sequences in the genome may be targets for ComE-mediated regulation. Based on the mutational analysis and DNase I footprinting analysis, we propose a consensus ComE binding site, TCBTAAAYSGT.     

Maize Activator transposase has a bipartite DNA binding domain that recognizes subterminal sequences and the terminal inverted repeats

 The mobility of maize transposable element Activator (Ac) is dependent on the 11-bp terminal inverted repeats (IRs) and approximately 250 subterminal nucleotides at each end. These sequences flank the coding region for the transposase (TPase) protein, which is required for the transposition reaction. Here we show that Ac TPase has a bipartite DNA binding domain, and recognizes the IRs and subterminal sequences in the Ac ends. TPase binds cooperatively to repetitive ACG and TCG sequences, of which 25 copies are found in the 5′ and 20 copies in the 3′ subterminal regions. TPase affinity is highest when these sites are flanked on the 3′ side by an additional G residue (A/TCGG), which is found at 75% of binding sites. Moreover, TPase binds specifically to the Ac IRs, albeit with much lower affinity. Two mutations within the IRs that immobilize Ac abolish TPase binding completely. The basic DNA binding domain of TPase is split into two subdomains. Binding to the subterminal motifs is accomplished by the C-terminal subdomain alone, whereas recognition of the IRs requires the N-terminal subdomain in addition. Furthermore, TPase is extremely flexible in DNA binding. Two direct or inverted binding sites are bound equally well, and sites that are five to twelve bases apart are similarly well bound. The consequences of these findings for the Ac transposition reaction are discussed. Received: 3 June 1996 / Accepted: 29 July 1996     

Evidence that DNA helicase I and oriT site-specific nicking are both functions of the F TraI protein

Site-specific and strand-specific nicking at the origin of transfer (oriT) of the F sex factor is the initial step in conjugal DNA metabolism. Then, DNA helicase I, the product of the traI gene, processively unwinds the plasmid from the nick site to generate the single strand of DNA that is transferred to the recipient. The nick at oriT is produced by the combined action of two Tra proteins, TraY and TraZ. The traZ gene was never precisely mapped, as no available point mutation uniquely affected TraZ-dependent oriT nicking. With several new mutations, we have demonstrated that TraZ activity is dependent upon traI DNA sequences. The simplest interpretation of this finding is that the F TraI protein is bifunctional, with DNA unwinding and site-specific DNA nicking activities.     

The TraM protein of the conjugative plasmid F binds to the origin of transfer of the F and ColE1 plasmids

The gene encoding the TraM protein of the conjugative plasmid F was cloned, overexpressed and the gene product was purified. The TraM protein was found in the cytoplasm of cells carrying the F plasmid with a smaller amount in the inner membrane. DNase I footprinting experiments showed that the purified protein protects three regions in the F oriT locus with different affinity for the upper and lower strands of DNA. A 15-nucleotide motif was identified within the protected regions that represented the DNA-binding site. The TraM protein was also found to bind to a sequence in the oriT region of the non-conjugative plasmid ColE1 that resembles the three binding sites in the F oriT region.     

Characterization of bacteriophage lambda excisionase mutants defective in DNA binding

The bacteriophage lambda excisionase (Xis) is a sequence-specific DNA binding protein required for excisive recombination. Xis binds cooperatively to two DNA sites arranged as direct repeats on the phage DNA. Efficient excision is achieved through a cooperative interaction between Xis and the host-encoded factor for inversion stimulation as well as a cooperative interaction between Xis and integrase. The secondary structure of the Xis protein was predicted to contain a typical amphipathic helix that spans residues 18 to 28. Several mutants, defective in promoting excision in vivo, were isolated with mutations at positions encoding polar amino acids in the putative helix (T. E. Numrych, R. I. Gumport, and J. F. Gardner, EMBO J. 11:3797-3806, 1992). We substituted alanines for the polar amino acids in this region. Mutant proteins with substitutions for polar amino acids in the amino-terminal region of the putative helix exhibited decreased excision in vivo and were defective in DNA binding. In addition, an alanine substitution at glutamic acid 40 also resulted in altered DNA binding. This indicates that the hydrophilic face of the alpha-helix and the region containing glutamic acid 40 may form the DNA binding surfaces of the Xis protein.     

The Arabidopsis TAG1 transposase has an N-terminal zinc finger DNA binding domain that recognizes distinct subterminal motifs

The in vitro DNA binding activity of the Arabidopsis Tag1 transposase (TAG1) was characterized to determine the mechanism of DNA recognition. In addition to terminal inverted repeats, the Tag1 element contains four different subterminal repeats that flank a transcribed region encoding a 729-amino acid protein. A single site-specific DNA binding domain is located near the N terminus of TAG1, between residues 21 and 133. This domain binds specifically to the AAACCC and TGACCC subterminal repeats, found near the 5' and 3' ends of the element, respectively. The ACCC sequence within these repeats is critical for recognition because mutations at positions 3, 5, and 6 abolished binding, yet the first two bases also are important because substitutions at these positions decreased binding by up to 90%. Weak interaction also occurs with the terminal inverted repeats, but no binding was observed to the other two 3' subterminal repeat regions. Sequence analysis of the TAG1 DNA binding domain revealed a C(2)HC zinc finger motif. Tests for metal dependence showed that DNA binding activity was inhibited by divalent metal chelators and greatly enhanced by zinc. Furthermore, mutation of each cysteine residue predicted to be a metal ligand in the C(2)HC motif abolished DNA binding. Together, these data show that the DNA binding domain of TAG1 specifically binds to distinct subterminal repeats and contains a zinc finger.