Specific DNA binding of the TraM protein to the oriT region of plasmid R100.

The product of the traM gene of plasmid R100 was purified as the TraM-collagen-beta-galactosidase fusion protein (TraM*) by using a beta-galactosidase-specific affinity column, and the TraM portion of TraM* (TraM') was separated by collagenolysis. Both the TraM* and TraM' proteins were found to bind specifically to a broad region preceding the traM gene. This region (designated sbm) was located within the nonconserved region in oriT among conjugative plasmids related to R100. The region seems to contain four core binding sites (designated sbmA, sbmB, sbmC, and sbmD), each consisting of a similar number of nucleotides and including a homologous 15-bp sequence. This result, together with the observation that the TraM* protein was located in the membrane fraction, indicates the possibility that the TraM protein has a function in anchoring the oriT region of R100 at the sbm sites to the membrane pore, through which the single-stranded DNA is transferred to the recipient. sbmC and sbmD, each of which contained a characteristic inverted repeat sequence, overlapped with the promoter region for the traM gene. This suggests that the expression of the traM gene may be regulated by its own product.     

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.     

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 the oriT region of the IncFV plasmid pED208

DNA sequence analysis of a 2.2kb EcoRI-HindIII fragment from pED208, the derepressed form of the IncFV plasmid Folac, revealed sequences highly homologous to the oriT region, traM, and traJ genes of other IncF plasmids. The TraM protein was purified and immunoblots of fractionated cells containing pED208 or Folac showed that TraM was predominantly in the cytoplasm. Using DNA retardation assays and the DNase I footprinting technique, the TraM protein was found to bind to three large motifs in the oriT region: (I) an inverted repeat, (II) two direct repeats, and (III) the traM promoter region. These three footprint regions contained a Hinfl-like sequence (GANTC) that appeared 16 times, spaced 11-12 bp (or multiples thereof) apart, suggesting that TraM protein binds in a complex manner over this entire region.     

TraY DNA recognition of its two F factor binding sites

F factor TraY, a ribbon-helix-helix DNA-binding protein, performs two roles in bacterial conjugation. TraY binds the F origin of transfer (oriT) to promote nicking of plasmid DNA prior to conjugative transfer. TraY also binds the P(Y) promoter to up-regulate tra gene expression. The two plasmid regions bound by TraY share limited sequence identity, yet TraY binds them with similar affinities. TraY recognition of the two sites was first probed using in vitro footprinting methods. Hydroxyl radical footprinting at both oriT and P(Y) sites indicated that bound TraY protected the DNA backbone bordering three adjacent DNA subsites. Analytical ultracentrifugation results for TraY:oligonucleotide complexes were consistent with two of these subsites being bound cooperatively, and the third being occupied at higher TraY concentrations. Methylation protection and interference footprinting identified several guanine bases contacted by or proximal to bound TraY, most located within these subsites. TraY affinity for variant oriT sequences with base substitutions at or near these guanine bases suggested that two of the three subsites correspond to high-affinity, cooperatively bound imperfect inverted GA(G/T)A repeats. Altering the spacing or orientation of these sites reduced binding. TraY mutant R73A failed to protect two symmetry-related oriT guanine bases in these repeats from methylation, identifying possible direct TraY-DNA contacts. The third subsite appears to be oriented as an imperfect direct repeat with its adjacent subsite, although base substitutions at this subsite did not reduce binding. Although unusual for ribbon-helix-helix proteins, this binding site arrangement occurs at both F TraY sites, consistent with it being functionally relevant.     

The TraM protein of plasmid R1 is a DNA-binding protein

The TraM protein of the resistance plasmid R1 was purified to homogeneity and used for DNA-binding studies. Both gel retardation- and footprint experiments showed that TraM specifically binds to DNA of plasmid R1 comprising the region between the origin of transfer and the traM gene. Several TraM molecules bind and, according to the footprint experiments, two distinct sites of specific binding exist. The two sites are separated from each other by 12 nucleotides and each contains an inverted repeat. DNase I protection assays showed that the initial TraM binding occurs at these palindromic sequences. At higher protein concentrations the lengths of the DNA segments protected by TraM were increased towards the traM gene. In one region this extension leads to binding of TraM protein at its own promoters.     

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 major recognition sequences for a herpes simplex virus type 1 origin-binding protein.

To investigate early initiation events in the replication of herpes simplex virus type 1, we analyzed interactions of proteins from infected cell extracts with the small origin of herpes simplex virus type 1 (oris1). Using the mobility shift assay, we detected two origin-specific binding interactions. We characterized the more prominent interaction on both strands of the DNA duplex with DNase I protection and methylation interference assays. Protein binding protects 17 bases of DNA on each strand from DNase I. These sequences are located at the left end of the central palindrome and are shifted four bases relative to one another. On the basis of the DNase protection pattern, we believe this protein to be related to the origin-binding protein defined by Elias et al. (P. Elias, M.E. O'Donnell, E.S. Mocarski, and I.R. Lehman, Proc. Natl. Acad. Sci. 83:6322-6326, 1986). Our DNase I footprint shows both strong and weak areas of protection. The regions strongly protected from DNase I align with the essential contact residues identified by interference footprinting. Methylation interference defines a small binding domain of 8 base pairs: 5'-GTTCGCAC-3'/3'-CAAGCGTG-5'. This recognition sequence contains two inverted 5'-GT(T/G)CG-3' repeats which share a 2-base overlap; thus, the origin-binding protein probably binds to the inverted repeats as a dimer.     

Structural basis of cooperative DNA recognition by the plasmid conjugation factor, TraM

The conjugative transfer of F-like plasmids such as F, R1, R100 and pED208, between bacterial cells requires TraM, a plasmid-encoded DNA-binding protein. TraM tetramers bridge the origin of transfer (oriT) to a key component of the conjugative pore, the coupling protein TraD. Here we show that TraM recognizes a high-affinity DNA-binding site, sbmA, as a cooperative dimer of tetramers. The crystal structure of the TraM-sbmA complex from the plasmid pED208 shows that binding cooperativity is mediated by DNA kinking and unwinding, without any direct contact between tetramers. Sequence-specific DNA recognition is carried out by TraM's N-terminal ribbon-helix-helix (RHH) domains, which bind DNA in a staggered arrangement. We demonstrate that both DNA-binding specificity, as well as selective interactions between TraM and the C-terminal tail of its cognate TraD mediate conjugation specificity within the F-like family of plasmids. The ability of TraM to cooperatively bind DNA without interaction between tetramers leaves the C-terminal TraM tetramerization domains free to make multiple interactions with TraD, driving recruitment of the plasmid to the conjugative pore.     

The cytoplasmic DNA-binding protein TraM binds to the inner membrane protein TraD in vitro.

The cytoplasmic protein TraM is one of four essential gene products of the F factor which are involved in DNA transfer after mating pair formation. TraM binds to three specific sites within the oriT region. Besides regulation of its own synthesis, the precise function of TraM during conjugation is not yet known. In the present work, the affinity of TraM to TraD was studied in vitro by an overlay assay and by affinity chromatography. Whether the interaction between TraM and TraD causes a transient or permanent anchoring of the F factor to the site of transfer is discussed. A 35-kDa host membrane protein of yet unknown function also shows affinity to TraM and may be involved in this anchoring process as well.     

Mutational analysis of TraM correlates oligomerization and DNA binding with autoregulation and conjugative DNA transfer

F plasmid TraM, an autoregulatory homotetramer, is essential for F plasmid bacterial conjugative transfer, one of the major mechanisms for horizontal gene dissemination. TraM cooperatively binds to three sites (sbmA, -B, and -C) near the origin of transfer in the F plasmid. To examine whether or not tetramerization of TraM is required for autoregulation and F conjugation, we used a two-plasmid system to screen for autoregulation-defective traM mutants generated by random PCR mutagenesis. A total of 72 missense mutations in TraM affecting autoregulation were selected, all of which also resulted in a loss of TraM function during F conjugation. Mutational analysis of TraM defined three regions important for F conjugation, including residues 3-10 (region I), 31-53 (region II), and 80-121 (region III); in addition, residues 3-47 were also important for the immunoreactivity of TraM. Biochemical analysis of mutant proteins indicated that region I defined a DNA binding domain that was not involved in tetramerization, whereas regions II and III were important for both tetramerization and efficient DNA binding. Mutations in region III affected the cooperativity of binding of TraM to sbmA, -B, and -C. Our results suggest that tetramerization is important for specific DNA binding, which, in turn, is essential for traM autoregulation and F conjugation. These findings support the hypothesis that TraM functions as a "signaling" factor that triggers DNA transport during F conjugation.     

Specific binding of MobA, a plasmid-encoded protein involved in the initiation and termination of conjugal DNA transfer, to single-stranded oriT DNA.

MobA protein, encoded by the broad host-range plasmid R1162, is required for conjugal mobilization of this plasmid. The protein is an essential part of the relaxosome, and is also necessary for the termination of strand transfer. In vitro, MobA is a nuclease specific for one of the two DNA strands of the origin of transfer (oriT). The protein can cleave this strand at the same site that is nicked in the relaxosome, and can also ligate the DNA. We show here that purified MobA protein forms a complex that is specific for this single oriT strand. The complex is unusually stable, with a half-life of approximately 95 min, is not disrupted by hybridization with the complementary strand, and reforms rapidly after boiling. Both the inverted repeat within oriT, and the eight bases between this repeat and the site cleaved by MobA, are required for binding by the protein. Mutations reducing base complementarity between the arms of the inverted repeat also decrease binding. This effect is partially suppressed by second-site mutations restoring complementarity. These results parallel the effects of these mutations on termination. Footprinting experiments with P1 nuclease indicate that the DNA between the inverted repeat and the nick site is protected by MobA, but that pairing between the arms of the repeat, which occurs in the absence of protein, is partially disrupted. Our results suggest that termination of strand transfer during conjugation involves tight binding of the MobA protein to the inverted repeat and adjacent oriT DNA. This complex positions the protein for ligation of the ends of the transferred strand, to reform a circular plasmid molecule.     

Footprint Analysis of the RAG Protein Recombination Signal Sequence Complex for V(D)J Type Recombination

We have studied the interaction between recombination signal sequences (RSSs) and protein products of the truncated forms of recombination-activating genes (RAG) by gel mobility shift, DNase I footprinting, and methylation interference assays. Methylation interference with dimethyl sulfate demonstrated that binding was blocked by methylation in the nonamer at the second-position G residue in the bottom strand and at the sixth- and seventh-position A residues in the top strand. DNase I footprinting experiments demonstrated that RAG1 alone, or even a RAG1 homeodomain peptide, gave footprint patterns very similar to those obtained with the RAG1-RAG2 complex. In the heptamer, partial methylation interference was observed at the sixth-position A residue in the bottom strand. In DNase I footprinting, the heptamer region was weakly protected in the bottom strand by RAG1. The effects of RSS mutations on RAG binding were evaluated by DNA footprinting. Comparison of the RAG-RSS footprint data with the published Hin model confirmed the notion that sequence-specific RSS-RAG interaction takes place primarily between the Hin domain of the RAG1 protein and adjacent major and minor grooves of the nonamer DNA.     

High resolution footprinting of a type I methyltransferase reveals a large structural distortion within the DNA recognition site.

The type I DNA methyltransferase M.EcoR124I is a multi-subunit enzyme that binds to the sequence GAAN6RTCG, transferring a methyl group from S-adenosyl methionine to a specific adenine on each DNA strand. We have investigated the protein-DNA interactions in the complex by DNase I and hydroxyl radical footprinting. The DNase I footprint is unusually large: the protein protects the DNA on both strands for at least two complete turns of the helix, indicating that the enzyme completely encloses the DNA in the complex. The higher resolution hydroxyl radical probe shows a smaller, but still extensive, 18 bp footprint encompassing the recognition site. Within this region, however, there is a remarkably hyper-reactive site on each strand. The two sites of enhanced cleavage are co-incident with the two adenines that are the target bases for methylation, showing that the DNA is both accessible and highly distorted at these sites. The hydroxyl radical footprint is unaffected by the presence of the cofactor S-adenosyl methionine, showing that the distorted DNA structure induced by M.EcoR124I is formed during the initial DNA binding reaction and not as a transient intermediate in the reaction pathway.     

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).     

Specific binding of the NikA protein to one arm of 17-base-pair inverted repeat sequences within the oriT region of plasmid R64.

Products of the nikA and nikB genes of plasmid R64 have been shown to form a relaxation complex with R64 oriT DNA and to function together as an oriT-specific nickase. We purified the protein product of the nikA gene. The purified NikA protein bound specifically to the oriT region of R64 DNA. Gel retardation assays and DNase I footprinting analyses indicated that the NikA protein bound only to the right arm of 17-bp inverted repeat sequences; the right arm differed from the left arm by a single nucleotide. The binding site is proximal to the nick site and within the 44-bp oriT core sequence. Binding of the NikA protein induced DNA bending within the R64 oriT sequence.     

The integrase of the conjugative transposon Tn916 directs strand- and sequence-specific cleavage of the origin of conjugal transfer, oriT, by the endonuclease Orf20

Orf20 of the conjugative transposon Tn916 was purified as a chimeric protein fused to maltose binding protein (MBP-Orf20). The chimeric protein possessed endonucleolytic activity, cleaving both strands of the Tn916 origin of conjugal transfer (oriT) at several distinct sites and favoring GT dinucleotides. Incubation of the oriT DNA with purified Tn916 integrase (Int) and MBP-Orf20 resulted in strand- and sequence-specific cleavage of oriT at a TGGT motif in the transferred strand. This motif lies immediately adjacent to a sequence in oriT previously shown to be protected from DNase I cleavage by Int. The endonucleolytic cleavages produced by Orf20 generated a 3' OH group that could be radiolabeled by dideoxy ATP and terminal transferase. The production of a 3' OH group distinguished these Orf20-dependent cleavage events from those catalyzed by Int at the ends of Tn916. Thus, Orf20 functions as the relaxase of Tn916, nicking oriT as the first step in conjugal DNA transfer. Remarkably for a tyrosine recombinase, Tn916 Int acts as a specificity factor in the reaction, conferring both strand and sequence specificities on the endonucleolytic cleavage activity of Orf20.     

Studies on the binding of integration host factor (IHF) and TraM to the origin of transfer of the IncFV plasmid pED208

The origin of transfer (oriT) of the IncFV plasmid pED208 contains a region with three binding sites for both the plasmid-encoded TraM protein and the integration host factor (IHF) of Escherichia coli, a sequence-specific DNA-binding protein. One region, containing overlapping TraM and IHF binding sites, could be interpreted as containing two binding sites for each protein. Using gel retardation assays, an affinity constant for IHF binding to the three main sites was estimated in the presence and absence of 0.1 M potassium glutamate, which increased the avidity of IHF binding to the weaker sites by two orders of magnitude. DNase I protection analyses and electron microscopy were used to determine the affinity of IHF for oriT-containing DNA in the presence and absence of TraM. The binding of IHF and TraM was found to be non-cooperative by the two techniques employed. Electron microscopy also demonstrated that IHF bent the oriT region in a manner consistent with its previously determined mode of action, while TraM had no discernible effect on the appearance of the DNA. This suggested that IHF and TraM interact with a 295 by sequence in the oriT region and organize it into a higher order structure that may have a role in the initiation of DNA transfer and control of traM expression.     

Identification of the replication terminator protein binding sites in the terminus region of the Bacillus subtilis chromosome and stoichiometry of the binding

DNase I footprinting of the interaction between the replication terminator protein (RTP) of Bacillus subtilis and the inverted repeat region (IRR) at the chromosome terminus, to which it binds to block the clockwise replication fork, showed that two major regions of 41 base pairs (bp) were protected from cleavage. These regions corresponded approximately to the imperfect inverted repeats (IRI and IRII) identified previously. Band retardation analyses of the interaction between RTP and portions of the IRR established that each inverted repeat (IRI or IRII) contained two RTP binding sites. By sedimentation equilibrium in the ultracentrifuge, RTP was found to exist as a dimer of 29 kDa at neutral pH and concentrations above 0.2 g/l. Quantitative studies of the RTP-IRR interaction using [3H]RTP and [32P]IRR showed that the fully saturated complex contained eight RTP monomers per IRR. It is concluded that a dimer of RTP binds to each of the four sites in IRR. The apparent dissociation constant for the interaction was estimated (in the presence of 50% glycerol) to be 1.2 x 10(-11) M (dimer of RTP). Glycerol was found to have a marked effect on the affinity of RTP for the IRR and on the relative amounts of the interaction complexes formed; in the absence of glycerol the dissociation constant was approximately 50-fold higher and there was pronounced co-operative binding of RTP dimers to adjacent sites in each inverted repeat. Examination of the DNA sequence in IRI and IRII identified two 8 bp direct repeats in each. The regions protected from DNase I cleavage in each inverted repeat and the protection afforded by a core sequence spanning just one of the 8 bp direct repeats were consistent with each 8 bp repeat representing a recognition sequence for the RTP dimer. A model describing the binding of RTP to the IRR is presented.