Complex of the herpes simplex virus initiator protein UL9 with DNA as a platform for the design of a new type of antiviral drugs

The protein binding to the origin of replication of the herpes simplex virus type 1 is DNA helicase encoded by the UL9 gene of the herpes virus. The protein specifically binds to two binding sites in the viral DNA replication origins OriS or OriL. In order to determine the role of the UL9 protein in the initiation of replication and find efficient inhibitors of the UL9 activity, we have synthesized a recombinant UL9 protein expressed in E. coli cells. It was found that the recombinant UL9 protein binds to Boxes I and II in OriS and possesses DNA helicase and ATPase activities. In the complex with a fluorescent analog of ATP, two molecules of the ATP analog bind to one protein dimer molecule. It was also found that the UL9 protein in the dimer form can bind simultaneously to two DNA fragments, each containing specific binding sites for the protein. The interaction of the recombinant UL9 protein with the 63-mer double- and single-stranded oligonucleotides OriS and OriS*, which correspond to the origin of replication of herpes simplex virus, has been investigated. From the titrations of OriS and OriS* with ethidium bromide in the presence and absence of the UL9 protein, the equilibrium affinity constants of the protein binding to OriS and OriS* have been determined. A DNase I footprinting study showed that bis-netropsins exhibit preference for binding to the AT cluster in the origin of replication OriS and inhibit the fluctuation opening of AT base pairs in the AT cluster. The drugs also prevent formation of an intermediate conformation of OriS* that involves a disordered tail at the 3′ end and stable Box I-Box III hairpin to which the UL9 helicase selectively binds. The stabilization by bis-netropsins of the AT-rich hairpin at its 3′ end can inhibit the helicase activity. It was concluded that the antiviral activity of bis-netropsins may be associated with the inhibitory effects of bis-netropsins on these two stages of the reaction catalyzed by helicase UL9.     

Identification of the SSB Binding Site on E. coli RecQ Reveals a Conserved Surface for Binding SSB's C Terminus

RecQ DNA helicases act in conjunction with heterologous partner proteins to catalyze DNA metabolic activities, including recombination initiation and stalled replication fork processing. For the prototypical Escherichia coli RecQ protein, direct interaction with single-stranded DNA-binding protein (SSB) stimulates its DNA unwinding activity. Complex formation between RecQ and SSB is mediated by the RecQ winged-helix domain, which binds the nine C-terminal-most residues of SSB, a highly conserved sequence known as the SSB-Ct element. Using nuclear magnetic resonance and mutational analyses, we identify the SSB-Ct binding pocket on E. coli RecQ. The binding site shares a striking electrostatic similarity with the previously identified SSB-Ct binding site on E. coli exonuclease I, although the SSB binding domains in the two proteins are not otherwise related structurally. Substitutions that alter RecQ residues implicated in SSB-Ct binding impair RecQ binding to SSB and SSB/DNA nucleoprotein complexes. These substitutions also diminish SSB-stimulated DNA helicase activity in the variants, although additional biochemical changes in the RecQ variants indicate a role for the winged-helix domain in helicase activity beyond SSB protein binding. Sequence changes in the SSB-Ct element are sufficient to abolish interaction with RecQ in the absence of DNA and to diminish RecQ binding and helicase activity on SSB/DNA substrates. These results support a model in which RecQ has evolved an SSB-Ct binding site on its winged-helix domain as an adaptation that aids its cellular functions on SSB/DNA nucleoprotein substrates.     

Binding properties of replication protein A from human and yeast cells.

Replication protein A (RP-A; also known as replication factor A and human SSB), is a single-stranded DNA-binding protein that is required for simian virus 40 DNA replication in vitro. RP-A isolated from both human and yeast cells is a very stable complex composed of 3 subunits (70, 32, and 14 kDa). We have analyzed the DNA-binding properties of both human and yeast RP-A in order to gain a better understanding of their role(s) in DNA replication. Human RP-A has high affinity for single-stranded DNA and low affinity for RNA and double-stranded DNA. The apparent affinity constant of RP-A for single-stranded DNA is in the range of 10(9) M-1. RP-A has a binding site size of approximately 30 nucleotides and does not bind cooperatively. The binding of RP-A to single-stranded DNA is partially sequence dependent. The affinity of human RP-A for pyrimidines is approximately 50-fold higher than its affinity for purines. The binding properties of yeast RP-A are similar to those of the human protein. Both yeast and human RP-A bind preferentially to the pyrimidine-rich strand of a homologous origin of replication: the ARS307 or the simian virus 40 origin of replication, respectively. This asymmetric binding suggests that RP-A could play a direct role in the process of initiation of DNA replication.     

Partial purification and properties of a DNA-binding protein from nuclei of cells infected with polyoma virus.

A DNA-binding protein has been purified from nuclei of 3T3 cells infected with polyoma virus. The assay used to detect this activity measures the amount of double-stranded DNA retained on a nitrocellulose membrane filter in the presence of binding protein. The interaction between DNA and protein is salt dependent and occurs optimally at 0.8 M NaCl. The isolated protein can bind to both circular and linear duplex DNA. Incubation of the binding protein with PM2 or polyoma DNA results in the formation of a fast sedimenting DNA structure in neutral sucrose gradients. The isolated binding protein is also capable of producing a considerable stimulation of both Escherichia coli (Pol I) and T4 DNA polymerase activities when either single-stranded or intact, native T7 DNA is used as the template. The binding protein itself is free of detectable DNA polymerase or nuclease activity.     

Molecular genetic and biochemical characterization of the vaccinia virus I3 protein, the replicative single-stranded DNA binding protein

Vaccinia virus, the prototypic poxvirus, efficiently and faithfully replicates its ～200-kb DNA genome within the cytoplasm of infected cells. This intracellular localization dictates that vaccinia virus encodes most, if not all, of its own DNA replication machinery. Included in the repertoire of viral replication proteins is the I3 protein, which binds to single-stranded DNA (ssDNA) with great specificity and stability and has been presumed to be the replicative ssDNA binding protein (SSB). We substantiate here that I3 colocalizes with bromodeoxyuridine (BrdU)-labeled nascent viral genomes and that these genomes accumulate in cytoplasmic factories that are delimited by membranes derived from the endoplasmic reticulum. Moreover, we report on a structure/function analysis of I3 involving the isolation and characterization of 10 clustered charge-to-alanine mutants. These mutants were analyzed for their biochemical properties (self-interaction and DNA binding) and biological competence. Three of the mutant proteins, encoded by the I3 alleles I3-4, -5, and -7, were deficient in self-interaction and unable to support virus viability, strongly suggesting that the multimerization of I3 is biologically significant. Mutant I3-5 was also deficient in DNA binding. Additionally, we demonstrate that small interfering RNA (siRNA)-mediated depletion of I3 causes a significant decrease in the accumulation of progeny genomes and that this reduction diminishes the yield of infectious virus.     

Structural and enzymatic studies of the T4 DNA replication system. II. ATPase properties of the polymerase accessory protein complex

In this paper we report a detailed enzymatic characterization of the interaction of the polymerase accessory protein complex of the T4 DNA replication system with the various nucleic acid cofactors that activate the ATPase of the complex. We show that the ATPase activity of the T4 coded gene 44/62 protein complex is stimulated synergistically by binding of DNA and T4 gene 45 protein and that the level of ATPase activation appears to be directly correlated with the binding of nucleic acid cofactor. Binding of any partially or completely single-stranded DNA to the complete accessory protein complex increases the catalytic activity (as measured by Vmax) while decreasing the binding affinity for the ATP substrate. While single-stranded DNA is a moderately effective cofactor, we find that the optimal nucleic acid-binding site for the complex is the primer-template junction, rather than single-stranded DNA ends as previously reported in the literature. Gene 45 protein plays an essential role in directing the specificity of binding to primer-template sites, lowering the Km for primer-template sites almost 1000-fold, and increasing Vmax 100-fold, compared with the analogous values for gene 44/62 protein alone. The most effective primer-template site for binding and enzymatic activation has the physiologically relevant recessed 3'-OH configuration and an optimal size in excess of 18 base pairs of duplex DNA. We find that the chemical nature of the primer terminus (i.e. 3'-OH or 3'-H) does not affect the extent of ATPase activation and that binding of the polymerase accessory protein complex to DNA cofactors is salt concentration dependent but appreciably less so when the activating DNA is a primer-template junction. Finally, we show that the gene 32 protein (T4 coded single-stranded DNA-binding protein) can compete with the polymerase accessory protein complex for single-stranded DNA but not for the primer-template junction activation sites. The implications of these results for the structure and function of the polymerase accessory protein complex within the T4 DNA replication system are discussed.     

Nucleic acid binding properties of Escherichia coli ribosomal protein S1. I. Structure and interactions of binding site I.

Escherichia coli ribosomal protein S1 plays a central role in initiation of protein synthesis, perhaps via participation in the binding of messenger RNA to the ribosome. S1 protein has two nucleic acid binding sites with very different properties: site I binds either single-stranded DNA or RNA, while site II binds single-stranded RNA only (Draper et al., 1977). The nucleic acid binding properties of these sites have been explored using the quenching of intrinsic protein fluorescence which results from binding of oligo- and polynucleotides, and are reported in this and the accompanying paper (Draper &; von Hippel, 1978).Site I has been studied primarily using DNA oligomers and polymers, and has been found to have the following properties. (1) The intrinsic binding constant (K) of site I for poly(dA) and poly(dC) is ~3 × 10⁶m^?1 at 0.12 m-Na⁺, and the site size (n, the number of nucleotide residues covered per S1 bound) is 5.1 ± 1.0 residues. (2) Binding of site I to polynucleotides is non-co-operative. (3) The K value for binding of S1 to single-stranded polynucleotides is ~10³ larger than K for binding to double-stranded polynucleotides, meaning that S1 (via site I) is a potential “melting” or “double-helix destabilizing” protein. (4) The dependence of log K on log [Na⁺] is linear, and analysis of the data according to Record et al. (1976) shows that two basic residues in site I form charge-charge interactions with two DNA phosphates. In addition, a major part of the binding free energy of site I with the nucleic acid chain appears to involve non-electrostatic interactions. (5) Oligonucleotides bound in site II somewhat weaken the binding affinity of site I. (6) Binding affin is virtually independent of base and sugar composition of the nucleic acid ligand; in fact, the total absence of the base appears to have little effect on the binding, since the association constant for 2′-deoxyribose 5′-phosphate is approximately the same as that for dAMP or dCMP. (7) Two molecules of d(ApA) can bind to site I, suggesting the presence of two “subsites” within site I. (8) Iodide quenching experiments with S1-oligonucleotide complexes show differential exposure of tryptophans in and near the subsites of site I, depending upon whether neither, one, or both subsites are complexed with an oligonucleotide.     

Residues within the B' motif are critical for DNA binding by the superfamily 3 helicase Rep40 of adeno-associated virus type 2

We have recently published the crystal structure of the adeno-associated virus type 2 superfamily 3 (SF3) helicase Rep40. Although based on its biochemical properties it is unlikely that Rep40 plays a central role as a replicative helicase the involvement of this motor protein in DNA packaging has recently been demonstrated. Here we focused our attention on residues that fall within and adjacent to the B' motif of SF3 helicases that directly interact with single-stranded DNA during translocation of the motor protein. In vitro, alanine substitution at positions Lys-404 or Lys-406 abrogated the ability of the protein to interact with single-stranded DNA as demonstrated by electrophoretic mobility shift assay and fluorescence anisotropy, and accordingly these mutants could not unwind a partially duplex DNA substrate. Despite this loss of helicase activity, basal ATPase activity in these mutants remained intact. However, unlike the wild-type protein, K404A and K406A ATPase activity was not stimulated by DNA. As predicted, disruption of motor activity through interference with DNA binding resulted in an inability of Rep40 to package adeno-associated virus DNA in a tissue culture-based assay. Taken together, we characterized, for the first time in an SF3 helicase family member, residues that are directly involved in single-stranded DNA binding and that are critical for the Rep motor activity. Based on our findings we propose B' as the signature motif of SF3 helicases that is responsible for the complex interactions required for the coupling of DNA binding and ATP hydrolysis.     

Focus: 50 Years of DNA Repair: The Yale Symposium Reports: BRCA2: One Small Step for DNA Repair,One Giant Protein Purified

DNA damage, malfunctions in DNA repair, and genomic instability are processes that intersect at the crossroads of carcinogenesis. Underscoring the importance of DNA repair in breast and ovarian tumorigenesis is the familial inherited cancer predisposition gene BRCA2. The role of BRCA2 in DNA double-strand break repair was first revealed based on its interaction with RAD51, a central player in homologous recombination. The RAD51 protein forms a nucleoprotein filament on single-stranded DNA, invades a DNA duplex, and initiates a search for homology. Once a homologous DNA sequence is found, the DNA is used as a template for the high-fidelity repair of the DNA break. Many of the biochemical features that allow BRCA2 to choreograph the activities of RAD51 have been elucidated and include: targeting RAD51 to single-stranded DNA while inhibiting binding to dsDNA, reducing the ATPase activity of RAD51, and facilitating the displacement of the single-strand DNA binding protein, Replication Protein A. These reinforcing activities of BRCA2 culminate in the correct positioning of RAD51 onto a processed DNA double-strand break and initiate its faithful repair by homologous recombination. In this review, I will address current biochemical data concerning the BRCA2 protein and highlight unanswered questions regarding BRCA2 function in homologous recombination and cancer.     

ssDNA-dependent colocalization of adeno-associated virus Rep and herpes simplex virus ICP8 in nuclear replication domains

The subnuclear distribution of replication complex proteins is being recognized as an important factor for the control of DNA replication. Herpes simplex virus (HSV) single-strand (ss)DNA-binding protein, ICP8 (infected cell protein 8) accumulates in nuclear replication domains. ICP8 also serves as helper function for the replication of adeno-associated virus (AAV). Using quantitative 3D colocalization analysis we show that upon coinfection of AAV and HSV the AAV replication protein Rep and ICP8 co-reside in HSV replication domains. In contrast, Rep expressed by a recombinant HSV, in the absence of AAV DNA, displayed a nuclear distribution pattern distinct from that of ICP8. Colocal ization of Rep and ICP8 was restored by the reintroduction of single-stranded AAV vector genomes. In vitro, ICP8 displayed direct binding to Rep78. Single-stranded recombinant AAV DNA strongly stimulated this interaction, whereas double-stranded DNA was ineffective. Our findings suggest that ICP8 by its strong ssDNA-binding activity exploits the unique single-strandedness of the AAV genome to form a tripartite complex with Rep78 and AAV ssDNA. This novel mechanism for recruiting components of a functional replication complex directs AAV to subnuclear HSV replication compartments where the HSV replication complex can replicate the AAV genome.     

DNA binding and aggregation properties of the vaccinia virus I3L gene product.

The vaccinia virus I3L gene encodes a single-stranded DNA-binding protein which may play a role in viral replication and genetic recombination. We have purified native and recombinant forms of gpI3L and characterized both the DNA-binding reaction and the structural properties of DNA-protein complexes. The purified proteins displayed anomalous electrophoretic properties in the presence of sodium dodecyl sulfate, behaving as if they were 4-kDa larger than the true mass. Agarose gel shift analysis was used to monitor the formation of complexes composed of single-stranded DNA plus gpI3L protein. These experiments detected two different DNA binding modes whose formation was dependent upon the protein density. The transition between the two binding modes occurred at a nucleotide to protein ratio of about 31 nucleotides per gpI3L monomer. S1 nuclease protection assay revealed that at saturating protein densities, each gpI3L monomer occludes 9.5 +/- 2.5 nucleotides. In the presence of magnesium, gpI3L promoted the formation of large DNA aggregates from which double-stranded DNA was excluded. Electron microscopy showed that, in the absence of magnesium and at low protein densities, gpI3L forms beaded structures on DNA. At high protein density the complexes display a smoother and less compacted morphology. In the presence of magnesium the complexes contained long fibrous and tangled arrays. These results suggest that gpI3L can form octameric complexes on DNA much like those formed by Escherichia coli single-stranded DNA protein. Moreover, the capacity to aggregate DNA may provide an environment in which hybrid DNA formation could occur during DNA replication.     

Low-molecular- weight Rauscher leukemia virus protein with preferential binding for single-stranded RNA and DNA.

A sensitive nitrocellulose filter assay that measures the retention of 125I single-stranded calf thymus DNA has been used to detect and purify DNA-binding proteins that retain a biological function from Rauscher murine leukemia virus. By consecutive purification on oligo (dT)- cellulose and DEAE-Bio-Gel columns and centrifugation in 10 to 30% glycerol gradients, RNA-dependent DNA polymerase has been separated from a second virion DNA-binding protein. The binding of this protein to DNA was strongly affected by NaCl concentration but showed little change in activity over a wide range of temperature or pH. After glycerol gradient purification, polyacrylamide gel electrophoresis of this protein showed one major band with a molecular weight of approximately 9,800. This protein binds about as well as to single-stranded Escherichia coli or calf thymus DNA or 70S type C viral RNA. The binding to 125I single-stranded calf thymus DNA is very efficiently inhibited by unlabeled single-stranded DNA from either E. coli or calf thymus and by 70S murine or feline viral RNA. Much larger amounts of double-stranded DNA are required to produce an equivalent percentage of inhibition. This protein, therefore, shows preferential binding to single-stranded DNA or viral RNA.     

Mismatch Repair proteins are recruited to replicating DNA through interaction with Proliferating Cell Nuclear Antigen (PCNA)

Mismatch Repair (MMR) is closely linked to DNA replication; however, other than the role of the replicative sliding clamp (PCNA) in various MMR functions, the linkage between DNA replication and MMR has been difficult to investigate. Here we use an in vitro DNA replication system based on simian virus 40, to investigate MMR recruitment to replicating DNA. Both DNA replication and MMR proteins are recruited to replicating DNA in an origin-dependent fashion. Primer synthesis is required for recruitment of both PCNA and MMR proteins, but not for recruitment of the single-stranded DNA-binding protein (RPA). Blocking PCNA recruitment to replicating DNA with a p21-based polypeptide blocks PCNA and MMR, but not RPA recruitment. Once PCNA and subsequent proteins required for replication are loaded onto DNA, addition of p21 leaves PCNA on the replicating DNA, but actively displaces MMR proteins. These findings indicate that the MMR machinery is recruited to replicating DNA through its interaction with PCNA, and suggests that this occurs via binding of the MMR proteins to the multi-protein interaction sites on PCNA. These studies demonstrate the utility of this system for further investigation of the role of DNA replication in MMR.     

Identification and properties of the crenarchaeal single-stranded DNA binding protein from Sulfolobus solfataricus

Single-stranded DNA binding proteins (SSBs) play central roles in cellular and viral processes involving the generation of single-stranded DNA. These include DNA replication, homologous recombination and DNA repair pathways. SSBs bind DNA using four ‘OB-fold’ (oligonucleotide/oligosaccharide binding fold) domains that can be organised in a variety of overall quaternary structures. Thus eubacterial SSBs are homotetrameric whilst the eucaryal RPA protein is a heterotrimer and euryarchaeal proteins vary significantly in their subunit compositions. We demonstrate that the crenarchaeal SSB protein is an abundant protein with a unique structural organisation, existing as a monomer in solution and multimerising on DNA binding. The protein binds single-stranded DNA distributively with a binding site size of ~5 nt per monomer. Sulfolobus SSB lacks the zinc finger motif found in the eucaryal and euryarchaeal proteins, possessing instead a flexible C-terminal tail, sensitive to trypsin digestion, that is not required for DNA binding. In comparison with Escherichia coli SSB, the tail may play a role in protein–protein interactions during DNA replication and repair.     

N-ethylmaleimide inhibition of the DNA-binding activity of the herpes simplex virus type 1 major DNA-binding protein.

The major herpes simplex virus DNA-binding protein, designated ICP8, binds tightly to single-stranded DNA and is required for replication of viral DNA. The sensitivity of the DNA-binding activity of ICP8 to the action of the sulfhydryl reagent N-ethylmaleimide has been examined by using nitrocellulose filter-binding and agarose gel electrophoresis assays. Incubation of ICP8 with N-ethylmaleimide results in a rapid loss of DNA-binding activity. Preincubation of ICP8 with single-stranded DNA markedly inhibits this loss of binding activity. These results imply that a free sulfhydryl group is involved in the interaction of ICP8 with single-stranded DNA and that this sulfhydryl group becomes less accessible to the environment upon binding. Agarose gel electrophoretic analysis of the binding interaction in the presence and absence of N-ethylmaleimide indicates that the cooperative binding exhibited by ICP8 is lost upon treatment with this reagent but that some residual noncooperative binding may remain. This last result was confirmed by equilibrium dialysis experiments with the 32P-labeled oligonucleotide dT10 and native and N-ethylmaleimide-treated ICP8.     

PriC-mediated DNA Replication Restart Requires PriC Complex Formation with the Single-stranded DNA-binding Protein

Frequent collisions between cellular DNA replication complexes (replisomes) and obstacles such as damaged DNA or frozen protein complexes make DNA replication fork progression surprisingly sporadic. These collisions can lead to the ejection of replisomes prior to completion of replication, which, if left unrepaired, results in bacterial cell death. As such, bacteria have evolved DNA replication restart mechanisms that function to reload replisomes onto abandoned DNA replication forks. Here, we define a direct interaction between PriC, a key Escherichia coli DNA replication restart protein, and the single-stranded DNA-binding protein (SSB), a protein that is ubiquitously associated with DNA replication forks. PriC/SSB complex formation requires evolutionarily conserved residues from both proteins, including a pair of Arg residues from PriC and the C terminus of SSB. In vitro, disruption of the PriC/SSB interface by sequence changes in either protein blocks the first step of DNA replication restart, reloading of the replicative DnaB helicase onto an abandoned replication fork. Consistent with the critical role of PriC/SSB complex formation in DNA replication restart, PriC variants that cannot bind SSB are non-functional in vivo. Single-molecule experiments demonstrate that PriC binding to SSB alters SSB/DNA complexes, exposing single-stranded DNA and creating a platform for other proteins to bind. These data lead to a model in which PriC interaction with SSB remodels SSB/DNA structures at abandoned DNA replication forks to create a DNA structure that is competent for DnaB loading.     

The N-terminus of porcine circovirus type 2 replication protein is required for nuclear localization and ori binding activities

Porcine circovirus type 2 possesses a circular, single-stranded DNA genome that requires the replication protein (Rep) for virus replication. To characterize the DNA binding potential and the significant region that confers the nuclear localization of the Rep protein, the defined coding regions of rep gene were cloned and expressed. All of the recombinant proteins except for the N-terminal 110 residues deletion mutant could bind to the double-stranded minimal binding site of replication origin (ori). In addition, the N-terminal deletion mutant lacking 110 residues exhibited mainly cytoplasmic staining in the transfected cells in contrast to the others, which localized dominantly in the nucleus, suggesting that this N-terminal domain is essential for nuclear localization. Furthermore, a series of green fluorescence proteins (GFP) containing potential nuclear localization signal (NLS) sequences were tested for their cellular distribution. The ability of the utmost 20 residues of the N-terminal region to target the GFP to the nucleus confirmed its role as a functional NLS.     

TcaR–ssDNA complex crystal structure reveals new DNA binding mechanism of the MarR family proteins

The teicoplanin-associated locus regulator (TcaR) regulates gene expression of proteins on the intercellular adhesion (ica) locus involved in staphylococci poly-N-acetylglucosamine biosynthesis. The absence of TcaR increases poly-N-acetylglucosamine production and promotes biofilm formation. Until recently, the mechanism of multiple antibiotic resistance regulator family protein members, such as TcaR, was restricted to binding double-stranded DNA. However, we recently found that TcaR strongly interacts with single-stranded DNA, which is a new role for this family of proteins. In this study, we report Staphylococcus epidermidis TcaR–single-stranded DNA complex structures. Our model suggests that TcaR and single-stranded DNA form a 6₁-symmetry polymer composed of TcaR dimers with single-stranded DNA that wraps outside the polymer and 12 nt per TcaR dimer. Single-stranded DNA binding to TcaR involves a large conformational change at the DNA binding lobe. Several point mutations involving the single-stranded DNA binding surface validate interactions between single-stranded DNA and TcaR. Our results extend the novel role of multiple antibiotic resistance regulator family proteins in staphylococci.     

The Single-Stranded DNA Binding Protein of Sulfolobus solfataricus Acts in the Presynaptic Step of Homologous Recombination

Homologous recombination is an important pathway in the repair of DNA double-strand breaks in all organisms. In mesophiles, single-stranded DNA binding proteins (SSBs) are believed to be involved in the removal of single-stranded DNA (ssDNA) secondary structure during the presynaptic step of homologous recombination, facilitating the formation of a contiguous Rad51/RecA nucleoprotein filament. Here we report a role for the thermophilic archaeal Sulfolobus solfataricus SSB (SsoSSB) in the presynaptic step of homologous recombination. We have identified multiple quaternary structural forms of this protein in vivo and examined the activity of SsoSSB with the strand-exchange protein S. solfataricus RadA (SsoRadA). Using gel-shift analysis, we found that the two major forms of SsoSSB have different DNA binding affinities and site sizes. Biochemical examination of the monomeric form of SsoSSB suggests that it has a minor role in presynapsis and may slightly inhibit the ssDNA-dependent ATPase activity of SsoRadA. The tetrameric form of SsoSSB, however, significantly inhibits SsoRadA ssDNA-dependent ATPase activity under both saturating and subsaturating conditions. Order-of-addition experiments indicate that preincubation of tetrameric SsoSSB and SsoRadA prior to reaction initiation with ssDNA relieves the inhibition observed when SsoSSB is added either before or after SsoRadA. In addition, we demonstrate a direct interaction between SsoRadA and SsoSSB using coimmunoprecipitation. Taken together, these results suggest that a direct interaction between SsoSSB and SsoRadA may occur in vivo prior to the formation of the SsoRadA nucleoprotein filament.