Single-Stranded DNA Binding by F TraI Relaxase and Helicase Domains Is Coordinately Regulated

Transfer of conjugative plasmids requires relaxases, proteins that cleave one plasmid strand sequence specifically. The F plasmid relaxase TraI (1,756 amino acids) is also a highly processive DNA helicase. The TraI relaxase activity is located within the N-terminal ∼300 amino acids, while helicase motifs are located in the region comprising positions 990 to 1450. For efficient F transfer, the two activities must be physically linked. The two TraI activities are likely used in different stages of transfer; how the protein regulates the transition between activities is unknown. We examined TraI helicase single-stranded DNA (ssDNA) recognition to complement previous explorations of relaxase ssDNA binding. Here, we show that TraI helicase-associated ssDNA binding is independent of and located N-terminal to all helicase motifs. The helicase-associated site binds ssDNA oligonucleotides with nM-range equilibrium dissociation constants and some sequence specificity. Significantly, we observe an apparent strong negative cooperativity in ssDNA binding between relaxase and helicase-associated sites. We examined three TraI variants having 31-amino-acid insertions in or near the helicase-associated ssDNA binding site. B. A. Traxler and colleagues (J. Bacteriol. 188:6346-6353) showed that under certain conditions, these variants are released from a form of negative regulation, allowing them to facilitate transfer more efficiently than wild-type TraI. We find that these variants display both moderately reduced affinity for ssDNA by their helicase-associated binding sites and a significant reduction in the apparent negative cooperativity of binding, relative to wild-type TraI. These results suggest that the apparent negative cooperativity of binding to the two ssDNA binding sites of TraI serves a major regulatory function in F transfer.Transfer of conjugative plasmids between bacteria contributes to genome diversification and acquisition of new traits. Conjugative plasmids encode most proteins required for transfer of one plasmid strand from the donor to the recipient cell (reviewed in references 11, 24, and 43). In preparation for transfer, a complex of proteins assembles at the plasmid origin of transfer (oriT). Within this complex, called the relaxosome, a plasmid-encoded relaxase or nickase binds and cleaves one plasmid strand at a specific oriT site (nic). As part of the cleavage reaction, the relaxase forms a covalent linkage between an active-site tyrosyl hydroxyl oxygen and a single-stranded DNA (ssDNA) phosphate, yielding a 3′ ssDNA hydroxyl (19, 30). Upon initiation of transfer, the plasmid strands are separated, and the cut strand is transported into the recipient. The relaxase is likely transferred into the recipient (12, 31) while still physically attached to plasmid DNA. The transferred relaxase may then join the ends of the ssDNA plasmid copy in the final step of plasmid transfer. Complementary strand synthesis in the donor and the recipient generates a double-stranded plasmid that is competent for further transfer. Successful conjugation requires effective temporal regulation, yet the mechanisms governing this regulation are poorly understood.The F plasmid oriT is ∼500 bp long and includes multiple binding sites for integration host factor (IHF), TraY, and TraM and a single site for TraI, the F relaxase (11). IHF, TraY, and TraM, participants in the relaxosome, bind double-stranded DNA to facilitate the action of TraI, perhaps by creating or stabilizing the ssDNA conformation around nic required for TraI recognition. The F TraI minimal high-affinity binding site includes ∼15 nucleotides around nic (39), and throughout the text, we refer to oligonucleotides that contain the TraI wild-type (wt) or variant binding site as oriT oligonucleotides. F TraI is 192 kDa (42), and in addition to its relaxase activity, TraI has a 5′-to-3′ helicase activity (4). These activities must be physically joined to allow efficient plasmid transfer (29), yet how the two activities are coordinated is a mystery. The relaxase region of F TraI has been defined as the N-terminal ∼300 amino acids (aa) (6, 40). Conserved helicase motifs, including those associated with an ATPase, lie between amino acids 990 and 1450. The C-terminal region (positions 1450 to 1756) plays an important role in bacterial conjugation, possibly involving protein-protein interactions with TraM (32) and/or inner membrane protein TraD (28).The 70-kDa central region of TraI that lies between the relaxase and helicase domains has been implicated in two functions. Haft and colleagues described TraI variants with 31-amino-acid insertions in this TraI region that facilitated plasmid transfer with greater efficiency than that afforded by the wild-type protein when these proteins are expressed at high levels (16). On the basis of this observation, the authors proposed that the region participated in a negative regulation of transfer. Matson and Ragonese demonstrated that this central region is required for TraI helicase function, likely due to participation in ssDNA recognition essential for the helicase activity (28). We wondered whether the proposed regulatory and ssDNA binding roles of the central region are linked and whether this region might help modulate TraI helicase and relaxase activities. Our objectives in this study were to confirm the role of the central region in ssDNA recognition, to assess the affinity and specificity of the ssDNA recognition by the central region, and to determine whether the relaxase and central domain ssDNA binding sites demonstrate cooperativity in binding. Our work yielded two significant and surprising results. First, the binding site within the TraI central region binds ssDNA with high affinity and significant sequence specificity, both unusual characteristics for a helicase. Second, the central region and relaxase ssDNA binding sites show an apparent strong negative cooperativity of binding, possibly explaining the role of the central region as a negative regulator and providing clues about how the timing of conjugative transfer might be regulated.     

Essential motifs of relaxase (TraI) and TraG proteins involved in conjugative transfer of plasmid RP4.

Two essential transfer genes of the conjugative plasmid RP4 were altered by site-directed mutagenesis: traG of the primase operon and traI of the relaxase operon. To evaluate effects on the transfer phenotype of the point mutations, we have reconstituted the RP4 transfer system by fusion of the transfer regions Tra1 and Tra2 to the small multicopy replicon ColD. Deletions in traG or traI served to determine the Tra phenotype of mutant plasmids by trans complementation. Two motifs of TraG which are highly conserved among TraG-like proteins in several other conjugative DNA transfer systems were found to be essential for TraG function. One of the motifs resembles that of a nucleotide binding fold of type B. The relaxase (TraI) catalyzes the specific cleaving-joining reaction at the transfer origin needed to initiate and terminate conjugative DNA transfer (W. Pansegrau, W. Schröder, and E. Lanka, Proc. Natl. Acad. Sci. USA 90:2925-2929, 1993). Phenotypes of mutations in three motifs that belong to the active center of the relaxase confirmed previously obtained biochemical evidence for the contributions of the motifs to the catalytic activity of TraI. Expression of the relaxase operon is greatly increased in the absence of an intact TraI protein. This finding suggests that the relaxosome which assembles only in the presence of the TraI in addition to its enzymatic activity plays a role in gene regulation.     

Site-directed mutations in the relaxase operon of RP4.

Mutations were constructed by site-directed mutagenesis in the relaxase operon of the broad-host-range plasmid RP4. The mutations were constructed in smaller plasmids, recombined into the 60-kb RP4 plasmid, and tested for their ability to transfer. The relaxase operon contains the transfer genes traJ, traH, and traI, which are involved in nicking at the transfer origin to generate the single strand destined to be transferred to the recipient cell. In the first mutant, the C terminus of TraI was truncated, leaving TraH intact. This mutant decreased transfer by approximately 500-fold in Escherichia coli, and the traI mutation could be complemented by a wild-type copy of traI in trans in the donor. The traI mutation similarly decreased transfer between a variety of gram-negative bacteria. A site-specific mutation was made by the polymerase chain reaction-based unique-site mutagenesis procedure to alter the start site of traH. This mutation had no effect on intraspecific E. coli transfer but reduced transfer by up to sevenfold for some gram-negative bacteria. The traH mutation had no effect on plasmid stability. Thus, neither TraH nor the C terminus of TraI is required for conjugative transfer, but both increase mating efficiency in some hosts.     

The F-plasmid TraI protein contains three functional domains required for conjugative DNA strand transfer

The F-plasmid-encoded TraI protein, also known as DNA helicase I, is a bifunctional protein required for conjugative DNA transfer. The enzyme catalyzes two distinct but functionally related reactions required for the DNA processing events associated with conjugation: the site- and strand-specific transesterification (relaxase) reaction that provides the nick required to initiate strand transfer and a processive 5'-to-3' helicase reaction that provides the motive force for strand transfer. Previous studies have identified the relaxase domain, which encompasses the first approximately 310 amino acids of the protein. The helicase-associated motifs lie between amino acids 990 and 1450. The function of the region between amino acids 310 and 990 and the region from amino acid 1450 to the C-terminal end is unknown. A protein lacking the C-terminal 252 amino acids (TraIDelta252) was constructed and shown to have essentially wild-type levels of transesterase and helicase activity. In addition, the protein was capable of a functional interaction with other components of the minimal relaxosome. However, TraIDelta252 was not able to support conjugative DNA transfer in genetic complementation experiments. We conclude that TraIDelta252 lacks an essential C-terminal domain that is required for DNA transfer. We speculate this domain may be involved in essential protein-protein interactions with other components of the DNA transfer machinery.     

Molecular recognition determinants for type IV secretion of diverse families of conjugative relaxases

In preparation for transfer conjugative type IV secretion systems (T4SS) produce a nucleoprotein adduct containing a relaxase enzyme covalently linked to the 5' end of single-stranded plasmid DNA. The bound relaxase is expected to present features necessary for selective recognition by the type IV coupling protein (T4CP), which controls substrate entry to the envelope spanning secretion machinery. We prove that the IncF plasmid R1 relaxase TraI is translocated to the recipient cells. Using a Cre recombinase assay (CRAfT) we mapped two internally positioned translocation signals (TS) on F-like TraI proteins that independently mediate efficient recognition and secretion. Tertiary structure predictions for the TS matched best helicase RecD2 from Deinococcus radiodurans. The TS is widely conserved in MOB(F) and MOB(Q) families of relaxases. Structure/function relationships within the TS were identified by mutation. A key residue in specific recognition by T4CP TraD was revealed by a fidelity switch phenotype for an F to plasmid R1 exchange L626H mutation. Finally, we show that physical linkage of the relaxase catalytic domain to a TraI TS is necessary for efficient conjugative transfer.     

Site-Specific Mutations in the TraI Relaxase and Upstream Region of Plasmid RP4

The relaxase of RP4 nicks the double-stranded plasmid at the oriT site and binds covalently to DNA at the 5′ end of the nick. The 80-kDa relaxase (TraI) is encoded on an operon with several overlapping open reading frames (ORFs). The importance in conjugation of a short ORF (traX) with a start site overlapping the 5′ terminus of traI was investigated, as well as the effects of specific mutations in the relaxase. Elimination of TraX reduced the transfer efficiency by approximately 50% in several intergeneric matings, especially when Escherichia coli was the donor. While TraI was essential for transfer to occur, deletion of the C-terminus of TraI decreased, but did not eliminate plasmid transfer. Mutation of the active site tyrosine resulted in residual transfer associated with amino acid misincorporation.     

An intrastrand three-DNA-base interaction is a key specificity determinant of F transfer initiation and of F TraI relaxase DNA recognition and cleavage

Bacterial conjugation, transfer of a single conjugative plasmid strand between bacteria, diversifies prokaryotic genomes and disseminates antibiotic resistance genes. As a prerequisite for transfer, plasmid-encoded relaxases bind to and cleave the transferred plasmid strand with sequence specificity. The crystal structure of the F TraI relaxase domain with bound single-stranded DNA suggests binding specificity is partly determined by an intrastrand three-way base-pairing interaction. We showed previously that single substitutions for the three interacting bases could significantly reduce binding. Here we examine the effect of single and double base substitutions at these positions on plasmid mobilization. Many substitutions reduce transfer, although the detrimental effects of some substitutions can be partially overcome by substitutions at a second site. We measured the affinity of the F TraI relaxase domain for several DNA sequence variants. While reduced transfer generally correlates with reduced binding affinity, some oriT variants transfer with an efficiency different than expected from their binding affinities, indicating ssDNA binding and cleavage do not correlate absolutely. Oligonucleotide cleavage assay results suggest the essential function of the three-base interaction may be to position the scissile phosphate for cleavage, rather than to directly contribute to binding affinity.     

Subdomain organization and catalytic residues of the F factor TraI relaxase domain

TraI from conjugative plasmid F factor is both a "relaxase" that sequence-specifically binds and cleaves single-stranded DNA (ssDNA) and a helicase that unwinds the plasmid during transfer. Using limited proteolysis of a TraI fragment, we generated a 36-kDa fragment (TraI36) retaining TraI ssDNA binding specificity and relaxase activity but lacking the ssDNA-dependent ATPase activity of the helicase. Further proteolytic digestion of TraI36 generates stable N-terminal 26-kDa (TraI26) and C-terminal 7-kDa fragments. Both TraI36 and TraI26 are stably folded and unfold in a highly cooperative manner, but TraI26 lacks affinity for ssDNA. Mutational analysis of TraI36 indicates that N-terminal residues Tyr(16) and Tyr(17) are required for efficient ssDNA cleavage but not for high-affinity ssDNA binding. Although the TraI36 N-terminus provides the relaxase catalytic residues, both N- and C-terminal structural domains participate in binding, suggesting that both domains combine to form the TraI relaxase active site.     

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.     

The Bacillus subtilis conjugative transposon ICEBs1 mobilizes plasmids lacking dedicated mobilization functions

Integrative and conjugative elements (ICEs, also known as conjugative transposons) are mobile elements that are found integrated in a host genome and can excise and transfer to recipient cells via conjugation. ICEs and conjugative plasmids are found in many bacteria and are important agents of horizontal gene transfer and microbial evolution. Conjugative elements are capable of self-transfer and also capable of mobilizing other DNA elements that are not able to self-transfer. Plasmids that can be mobilized by conjugative elements are generally thought to contain an origin of transfer (oriT), from which mobilization initiates, and to encode a mobilization protein (Mob, a relaxase) that nicks a site in oriT and covalently attaches to the DNA to be transferred. Plasmids that do not have both an oriT and a cognate mob are thought to be nonmobilizable. We found that Bacillus subtilis carrying the integrative and conjugative element ICEBs1 can transfer three different plasmids to recipient bacteria at high frequencies. Strikingly, these plasmids do not have dedicated mobilization-oriT functions. Plasmid mobilization required conjugation proteins of ICEBs1, including the putative coupling protein. In contrast, plasmid mobilization did not require the ICEBs1 conjugative relaxase or cotransfer of ICEBs1, indicating that the putative coupling protein likely interacts with the plasmid replicative relaxase and directly targets the plasmid DNA to the ICEBs1 conjugation apparatus. These results blur the current categorization of mobilizable and nonmobilizable plasmids and indicate that conjugative elements play a role in horizontal gene transfer even more significant than previously recognized.     

Tracking F plasmid TraI relaxase processing reactions provides insight into F plasmid transfer

Early in F plasmid conjugative transfer, the F relaxase, TraI, cleaves one plasmid strand at a site within the origin of transfer called nic. The reaction covalently links TraI Tyr16 to the 5'-ssDNA phosphate. Ultimately, TraI reverses the cleavage reaction to circularize the plasmid strand. The joining reaction requires a ssDNA 3'-hydroxyl; a second cleavage reaction at nic, regenerated by extension from the plasmid cleavage site, may generate this hydroxyl. Here we confirm that TraI is transported to the recipient during transfer. We track the secondary cleavage reaction and provide evidence it occurs in the donor and F ssDNA is transferred to the recipient with a free 3'-hydroxyl. Phe substitutions for four Tyr within the TraI active site implicate only Tyr16 in the two cleavage reactions required for transfer. Therefore, two TraI molecules are required for F plasmid transfer. Analysis of TraI translocation on various linear and circular ssDNA substrates supports the assertion that TraI slowly dissociates from the 3'-end of cleaved F plasmid, likely a characteristic essential for plasmid re-circularization.     

A high security double lock and key mechanism in HUH relaxases controls oriT-processing for plasmid conjugation

Relaxases act as DNA selection sieves in conjugative plasmid transfer. Most plasmid relaxases belong to the HUH endonuclease family. TrwC, the relaxase of plasmid R388, is the prototype of the HUH relaxase family, which also includes TraI of plasmid F. In this article we demonstrate that TrwC processes its target nic-site by means of a highly secure double lock and key mechanism. It is controlled both by TrwC–DNA intermolecular interactions and by intramolecular DNA interactions between several nic nucleotides. The sequence specificity map of the interaction between TrwC and DNA was determined by systematic mutagenesis using degenerate oligonucleotide libraries. The specificity map reveals the minimal nic sequence requirements for R388-based conjugation. Some nic-site sequence variants were still able to form the U-turn shape at the nic-site necessary for TrwC processing, as observed by X-ray crystallography. Moreover, purified TrwC relaxase effectively cleaved ssDNA as well as dsDNA substrates containing these mutant sequences. Since TrwC is able to catalyze DNA integration in a nic-site-containing DNA molecule, characterization of nic-site functionally active sequence variants should improve the search quality of potential target sequences for relaxase-mediated integration in any target genome.     

Structure-function analysis of Escherichia coli DNA helicase I reveals non-overlapping transesterase and helicase domains

TraI (DNA helicase I) is an Escherichia coli F plasmid-encoded protein required for bacterial conjugative DNA transfer. The protein is a sequence-specific DNA transesterase that provides the site- and strand-specific nick required to initiate DNA strand transfer and a 5' to 3' DNA helicase that unwinds the F plasmid to provide the single-stranded DNA that is transferred from donor to recipient. Sequence comparisons with other transesterases and helicases suggest that these activities reside in the N- and C-terminal regions of TraI, respectively. Computer-assisted secondary structure probability analysis identified a potential interdomain region spanning residues 304-309. Proteins encoded by segments of traI, whose N or C terminus either flanked or coincided with this region, were purified and assessed for catalytic activity. Amino acids 1-306 contain the transesterase activity, whereas amino acids 309-1504 contain the helicase activity. The C-terminal 252 amino acids of the 1756-amino acid TraI protein are not required for either helicase or transesterase activity. Protein and nucleic acid sequence similarity searches indicate that the occurrence of both transesterase- and helicase-associated motifs in a conjugative DNA transfer initiator protein is rare. Only two examples (other than R100 plasmid TraI) were found: R388 plasmid TrwC and R46 plasmid (pKM101) TraH, belonging to the IncW and IncN groups of broad host range conjugative plasmids, respectively. The most significant structural difference between these proteins and TraI is that TraI contains an additional region of approximately 650 residues between the transesterase domain and the helicase-associated motifs. This region is required for helicase activity.     

Structure of a translocation signal domain mediating conjugative transfer by type IV secretion systems

Relaxases are proteins responsible for the transfer of plasmid and chromosomal DNA from one bacterium to another during conjugation. They covalently react with a specific phosphodiester bond within DNA origin of transfer sequences, forming a nucleo‐protein complex which is subsequently recruited for transport by a plasmid‐encoded type IV secretion system. In previous work we identified the targeting translocation signals presented by the conjugative relaxase TraI of plasmid R1. Here we report the structure of TraI translocation signal TSA. In contrast to known translocation signals we show that TSA is an independent folding unit and thus forms a bona fide structural domain. This domain can be further divided into three subdomains with striking structural homology with helicase subdomains of the SF1B family. We also show that TSA is part of a larger vestigial helicase domain which has lost its helicase activity but not its single‐stranded DNA binding capability. Finally, we further delineate the binding site responsible for translocation activity of TSA by targeting single residues for mutations. Overall, this study provides the first evidence that translocation signals can be part of larger structural scaffolds, overlapping with translocation‐independent activities.     

Examination of an inverted repeat within the F factor origin of transfer: context dependence of F TraI relaxase DNA specificity

Prior to conjugative transfer of plasmids, one plasmid strand is cleaved in a site- and strand-specific manner by an enzyme called a relaxase or nickase. In F and related plasmids, an inverted repeat is located near the plasmid strand cleavage site, and others have proposed that the ability of this sequence to form a hairpin when in single-stranded form is important for transfer. Substitutions were introduced into a cloned F oriT region and their effects on plasmid transfer were assessed. For those substitutions that substantially reduced transfer, the results generally correlated with effects on in vitro binding of oligonucleotides to the F TraI relaxase domain rather than with predicted effects on hairpin formation. One substitution shown previously to dramatically reduce both plasmid transfer and in vitro binding to a 17-base oligonucleotide had little apparent effect on binding to a 30-base oligonucleotide that contained the hairpin region. Results from subsequent experiments strongly suggest that the relaxase domain can bind to hairpin oligonucleotides in two distinct manners with different sequence specificities, and that the protein binds the oligonucleotides at the same or overlapping sites.     

The TraK accessory factor activates substrate transfer through the pKM101 type IV secretion system independently of its role in relaxosome assembly

A large subfamily of the type IV secretion systems (T4SSs), termed the conjugation systems, transmit mobile genetic elements (MGEs) among many bacterial species. In the initiating steps of conjugative transfer, DNA transfer and replication (Dtr) proteins assemble at the origin-of-transfer (oriT) sequence as the relaxosome, which nicks the DNA strand destined for transfer and couples the nicked substrate with the VirD4-like substrate receptor. Here, we defined contributions of the Dtr protein TraK, a predicted member of the Ribbon-Helix-Helix (RHH) family of DNA-binding proteins, to transfer of DNA and protein substrates through the pKM101-encoded T4SS. Using a combination of cross-linking/affinity pull-downs and two-hybrid assays, we determined that TraK self-associates as a probable tetramer and also forms heteromeric contacts with pKM101-encoded TraI relaxase, VirD4-like TraJ receptor, and VirB11-like and VirB4-like ATPases, TraG and TraB, respectively. TraK also promotes stable TraJ–TraB complex formation and stimulates binding of TraI with TraB. Finally, TraK is required for or strongly stimulates the transfer of cognate (pKM101, TraI relaxase) and noncognate (RSF1010, MobA relaxase) substrates. We propose that TraK functions not only to nucleate pKM101 relaxosome assembly, but also to activate the Tra_pKM101 T4SS via interactions with the ATPase energy center positioned at the channel entrance.     

Unique Helicase Determinants in the Essential Conjugative TraI Factor from Salmonella enterica Serovar Typhimurium Plasmid pCU1

The widespread development of multidrug-resistant bacteria is a major health emergency. Conjugative DNA plasmids, which harbor a wide range of antibiotic resistance genes, also encode the protein factors necessary to orchestrate the propagation of plasmid DNA between bacterial cells through conjugative transfer. Successful conjugative DNA transfer depends on key catalytic components to nick one strand of the duplex DNA plasmid and separate the DNA strands while cell-to-cell transfer occurs. The TraI protein from the conjugative Salmonella plasmid pCU1 fulfills these key catalytic roles, as it contains both single-stranded DNA-nicking relaxase and ATP-dependent helicase domains within a single, 1,078-residue polypeptide. In this work, we unraveled the helicase determinants of Salmonella pCU1 TraI through DNA binding, ATPase, and DNA strand separation assays. TraI binds DNA substrates with high affinity in a manner influenced by nucleic acid length and the presence of a DNA hairpin structure adjacent to the nick site. TraI selectively hydrolyzes ATP, and mutations in conserved helicase motifs eliminate ATPase activity. Surprisingly, the absence of a relatively short (144-residue) domain at the extreme C terminus of the protein severely diminishes ATP-dependent strand separation. Collectively, these data define the helicase motifs of the conjugative factor TraI from Salmonella pCU1 and reveal a previously uncharacterized C-terminal functional domain that uncouples ATP hydrolysis from strand separation activity.     

Functional characterization of the multidomain F plasmid TraI relaxase-helicase

TraI, a bifunctional enzyme containing relaxase and helicase activities, initiates and drives the conjugative transfer of the Escherichia coli F plasmid. Here, we examined the structure and function of the TraI helicase. We show that TraI binds to single-stranded DNA (ssDNA) with a site size of ～25 nucleotides, which is significantly longer than the site size of other known superfamily I helicases. Low cooperativity was observed with the binding of TraI to ssDNA, and a double-stranded DNA-binding site was identified within the N-terminal region of TraI 1-858, outside the core helicase motifs of TraI. We have revealed that the affinity of TraI for DNA is negatively correlated with the ionic strength of the solution. The binding of AMPPNP or ADP results in a 3-fold increase in the affinity of TraI for ssDNA. Moreover, TraI prefers to bind ssDNA oligomers containing a single type of base. Finally, we elucidated the solution structure of TraI using small angle x-ray scattering. TraI exhibits an ellipsoidal shape in solution with four domains aligning along one axis. Taken together, these data result in the assembly of a model for the multidomain helicase activity of TraI.