Interactions of Escherichia coli replicative helicase PriA protein with single-stranded DNA

Single-molecule binding characterization of primosomal protein PriA involved in replication restart

DNA damage leads to stalled or collapsed replication forks. Replication restart primosomes re-initiate DNA synthesis at these stalled or collapsed DNA replication forks, which is important for bacterial survival. Primosomal protein PriA specifically recognizes the DNA fork structure and recruits other primosomal proteins to load the replicative helicase, in order to re-establish the replication fork. PriA binding on DNA is the first step to restart replication forks for proper DNA repair. Using a single-molecule fluorescence colocalization experiment, we measured the thermodynamic and real-time kinetic properties of fluorescence-labeled Gram-positive bacteria Geobacillus stearothermophilus PriA binding on DNA forks. We showed that PriA preferentially binds to a DNA fork structure with a fully duplexed leading strand at sub-nanomolar affinity (Kd = 268 ± 99 pM). PriA binds dynamically, and its association and dissociation rate constants can be determined using the appearance and disappearance of the fluorescence signal. In addition, we showed that PriA binds to DNA forks as a monomer using photobleaching step counting. This information offers a molecular basis essential for understanding the mechanism of replication restart.

Characterization of Streptococcus pneumoniae PriA helicase and its ATPase and unwinding activities in DNA replication restart

DNA replication forks often encounter template DNA lesions that can stall their progression. The PriA-dependent pathway is the major replication restart mechanism in Gram-positive bacteria, and it requires several primosome proteins. Among them, PriA protein - a 3' to 5' superfamily-2 DNA helicase - is the key factor in recognizing DNA lesions and it also recruits other proteins. Here, we investigated the ATPase and helicase activities of Streptococcus pneumoniae PriA (SpPriA) through biochemical and kinetic analyses. By comparing various DNA substrates, we observed that SpPriA is unable to unwind duplex DNA with high GC content. We constructed a deletion mutant protein (SpPriAdeloop) from which the loop area of the DNA-binding domain of PriA had been removed. Functional assays on SpPriAdeloop revealed that the loop area is important in endowing DNA-binding properties on the helicase. We also show that the presence of DnaD loader protein is important for enhancing SpPriA ATPase and DNA unwinding activities.

Molecular Model for the Surface-Catalyzed Protein Self-Assembly

The importance of cell surfaces in the self-assembly of proteins is widely accepted. One biologically significant event is the assembly of amyloidogenic proteins into aggregates, which leads to neurodegenerative disorders like Alzheimer's and Parkinson's diseases. The interaction of amyloidogenic proteins with cellular membranes appears to dramatically facilitate the aggregation process. Recent findings indicate that, in the presence of surfaces, aggregation occurs at physiologically low concentrations, suggesting that interaction with surfaces plays a critical role in the disease-prone aggregation process. However, the molecular mechanisms behind the on-surface aggregation process remain unclear. Here, we provide a theoretical model that offers a molecular explanation. According to this model, monomers transiently immobilized to surfaces increase the local monomer protein concentration and thus work as nuclei to dramatically accelerate the entire aggregation process. This physical-chemical theory was verified by experimental studies, using mica surfaces, to examine the aggregation kinetics of amyloidogenic α-synuclein protein and non-amyloidogenic cytosine deaminase APOBEC3G.

Structure-specific DNA replication-fork recognition directs helicase and replication restart activities of the PriA helicase

DNA replication restart, the essential process that reinitiates prematurely terminated genome replication reactions, relies on exquisitely specific recognition of abandoned DNA replication-fork structures. The PriA DNA helicase mediates this process in bacteria through mechanisms that remain poorly defined. We report the crystal structure of a PriA/replication-fork complex, which resolves leading-strand duplex DNA bound to the protein. Interaction with PriA unpairs one end of the DNA and sequesters the 3'-most nucleotide from the nascent leading strand into a conserved protein pocket. Cross-linking studies reveal a surface on the winged-helix domain of PriA that binds to parental duplex DNA. Deleting the winged-helix domain alters PriA's structure-specific DNA unwinding properties and impairs its activity in vivo. Our observations lead to a model in which coordinated parental-, leading-, and lagging-strand DNA binding provide PriA with the structural specificity needed to act on abandoned DNA replication forks.

Mechanisms of bacterial DNA replication restart

Multi-protein DNA replication complexes called replisomes perform the essential process of copying cellular genetic information prior to cell division. Under ideal conditions, replisomes dissociate only after the entire genome has been duplicated. However, DNA replication rarely occurs without interruptions that can dislodge replisomes from DNA. Such events produce incompletely replicated chromosomes that, if left unrepaired, prevent the segregation of full genomes to daughter cells. To mitigate this threat, cells have evolved 'DNA replication restart' pathways that have been best defined in bacteria. Replication restart requires recognition and remodeling of abandoned replication forks by DNA replication restart proteins followed by reloading of the replicative DNA helicase, which subsequently directs assembly of the remaining replisome subunits. This review summarizes our current understanding of the mechanisms underlying replication restart and the proteins that drive the process in Escherichia coli (PriA, PriB, PriC and DnaT).

Deinococcus radiodurans PriA is a Pseudohelicase

Reactivation of repaired DNA replication forks in bacteria is catalyzed by PriA helicase. This broadly-conserved bacterial enzyme can remodel the structure of DNA at a repaired DNA replication fork by unwinding small portions of duplex DNA to prepare the fork for replisome reloading. While PriA's helicase activity is not strictly required for cell viability in E. coli, the sequence motifs that confer helicase activity upon PriA are well-conserved among sequenced bacterial priA genes, suggesting that PriA's duplex DNA unwinding activity confers a selective advantage upon cells. However, these helicase sequence motifs are not well-conserved among priA genes from the Deinococcus-Thermus phylum. Here, we show that PriA from a highly radiation-resistant member of that phylum, Deinococcus radiodurans, lacks the ability to hydrolyze ATP and unwind duplex DNA, thus qualifying D. radiodurans PriA as a pseudohelicase. Despite the lack of helicase activity, D. radiodurans PriA has retained the DNA binding activity expected of a typical PriA helicase, and we present evidence for a physical interaction between D. radiodurans PriA and its cognate replicative helicase, DnaB. This suggests that PriA has retained a role in replisome reloading onto repaired DNA replication forks in D. radiodurans despite its lack of helicase activity.

The Escherichia coli primosomal DnaT protein exists in solution as a monomer-trimer equilibrium system

The oligomerization reaction of the Escherichia coli DnaT protein has been quantitatively examined using fluorescence anisotropy and analytical ultracentrifugation methods. In solution, DnaT exists as a monomer-trimer equilibrium system. At the estimated concentration in the E. coli cell, DnaT forms a mixture of the monomer and trimer states with a 3:1 molar ratio. In spite of the modest affinity, the trimerization is a highly cooperative process, without the detectable presence of the intervening dimer. The DnaT monomer consists of a large N-terminal core domain and a small C-terminal region. The removal of the C-terminal region dramatically affects the oligomerization process. The isolated N-terminal domain forms a dimer instead of the trimer. These results indicate that the DnaT monomer possesses two structurally different, interacting sites. One site is located on the N-terminal domain, and two monomers, in the trimer, are associated through their binding sites located on that domain. The C-terminal region forms the other interacting site. The third monomer is engaged through the C-terminal regions. Surprisingly, the high affinity of the N-terminal domain dimer indicates that the DnaT monomer undergoes a conformational transition upon oligomerization, involving the C-terminal region. These data and the high specificity of the trimerization reaction, i.e., lack of any oligomers higher than a trimer, indicate that each monomer in the trimer is in contact with the two remaining monomers. A model of the global structure of the DnaT trimer based on the thermodynamic and hydrodynamic data is discussed.

Identification of a small molecule PriA helicase inhibitor

PriA helicase catalyzes the initial steps of replisome reloading onto repaired DNA replication forks in bacterial DNA replication restart pathways. We have used a high-throughput screen to identify a small molecule inhibitor of PriA-catalyzed duplex DNA unwinding. The compound, CGS 15943, targets Neisseria gonorrhoeae PriA helicase with an IC(50) of 114 ± 24 μM. The PriA helicase of Escherichia coli is also inhibited, although to a lesser extent than N. gonorrhoeae PriA. CGS 15943 decreases rates of PriA-catalyzed ATP hydrolysis and reduces the affinity with which PriA binds DNA. Steady-state kinetic data indicate that CGS 15943 inhibits PriA through a mixed mode of inhibition with respect to ATP and with respect to DNA, indicating that it binds to a site on PriA that participates in both substrate binding and catalysis. Inhibitor binding constants derived from steady-state kinetic experiments reveal that CGS 15943 has the highest binding affinity for the PriA·PriB·ATP complex, intermediate binding affinity for the PriA·PriB·DNA complex, and the lowest binding affinity for the PriA·PriB·DNA·ATP complex, suggesting that PriA assumes different conformations in each of these complexes. We propose that CGS 15943 binds to PriA at a site distinct from the DNA and primary ATP binding sites, perhaps at PriA's weak nucleotide binding site, and induces a conformational change in PriA that renders it less catalytically proficient or prevents conformational changes in PriA that are necessary for ATP hydrolysis and duplex DNA unwinding.

The N-terminal domain of the Escherichia coli PriA helicase contains both the DNA- and nucleotide-binding sites. Energetics of domain--DNA interactions and allosteric effect of the nucleotide cofactors

Functional interactions of the Escherichia coli PriA helicase 181N-terminal domain with the DNA and nucleotide cofactors have been quantitatively examined. The isolated 181N-terminal domain forms a stable dimer in solution, most probably reflecting the involvement of the domain in specific cooperative interactions of the intact PriA protein--double-stranded DNA (dsDNA) complex. Only one monomer of the domain dimer binds the DNA; i.e., the dimer has one effective DNA-binding site. Although the total site size of the dimer--single-stranded DNA (ssDNA) complex is ~13 nucleotides, the DNA-binding subsite engages in direct interactions with approximately five nucleotides. A small number of interacting nucleotides indicates that the DNA-binding subsites of the PriA helicase, i.e., the strong subsite on the helicase domain and the weak subsite on the N-terminal domain, are spatially separated in the intact enzyme. Contrary to current views, the subsite has an only slight preference for the 3'-end OH group of the ssDNA and lacks any significant base specificity, although it has a significant dsDNA affinity. Unlike the intact helicase, the DNA-binding subsite of the isolated domain is in an open conformation, indicating the presence of the direct helicase domain--N-terminal domain interactions. The discovery that the 181N-terminal domain possesses a nucleotide-binding site places the allosteric, weak nucleotide-binding site of the intact PriA on the N-terminal domain. The specific effect of ADP on the domain DNA-binding subsite indicates that in the intact helicase, the bound ADP not only opens the DNA-binding subsite but also increases its intrinsic DNA affinity.

A bacterial PriB with weak single-stranded DNA binding activity can stimulate the DNA unwinding activity of its cognate PriA helicase

Background

Bacterial DNA replication restart pathways facilitate reinitiation of DNA replication following disruptive encounters of a replisome with DNA damage, thereby allowing complete and faithful duplication of the genome. In Neisseria gonorrhoeae, the primosome proteins that catalyze DNA replication restart differ from the well-studied primosome proteins of E. coli with respect to the number of proteins involved and the affinities of their physical interactions: the PriA:PriB interaction is weak in E. coli, but strong in N. gonorrhoeae, and the PriB:DNA interaction is strong in E. coli, but weak in N. gonorrhoeae. In this study, we investigated the functional consequences of this affinity reversal.

Results

We report that N. gonorrhoeae PriA's DNA binding and unwinding activities are similar to those of E. coli PriA, and N. gonorrhoeae PriA's helicase activity is stimulated by its cognate PriB, as it is in E. coli. This finding is significant because N. gonorrhoeae PriB's single-stranded DNA binding activity is weak relative to that of E. coli PriB, and in E. coli, PriB's single-stranded DNA binding activity is important for PriB stimulation of PriA helicase. Furthermore, a N. gonorrhoeae PriB variant defective for binding single-stranded DNA can stimulate PriA's helicase activity, suggesting that DNA binding by PriB might not be important for PriB stimulation of PriA helicase in N. gonorrhoeae. We also demonstrate that N. gonorrhoeae PriB stimulates ATP hydrolysis catalyzed by its cognate PriA. This activity of PriB has not been observed in E. coli, and could be important for PriB stimulation of PriA helicase in N. gonorrhoeae.

Conclusions

The results of this study demonstrate that a bacterial PriB homolog with weak single-stranded DNA binding activity can stimulate the DNA unwinding activity of its cognate PriA helicase. While it remains unclear if N. gonorrhoeae PriB's weak DNA binding activity is required for PriB stimulation of PriA helicase, the ability of PriB to stimulate PriA-catalyzed ATP hydrolysis could play an important role. Thus, the weak interaction between N. gonorrhoeae PriB and DNA might be compensated for by the strong interaction between PriB and PriA, which could result in allosteric activation of PriA's ATPase activity.

Binding of two PriA-PriB complexes to the primosome assembly site initiates primosome formation

A direct quantitative analysis of the initial steps in primosome assembly, involving PriA and PriB proteins and the minimal primosome assembly site (PAS) of phage ϕX174, has been performed using fluorescence intensity, fluorescence anisotropy titration, and fluorescence resonance energy transfer techniques. We show that two PriA molecules bind to the PAS at both strong and weak binding sites on the DNA, respectively, without detectable cooperative interactions. Binding of the PriB dimer to the PriA-PAS complex dramatically increases PriA's affinity for the strong site, but only slightly affects its affinity for the weak site. Associations with the strong and weak sites are driven by apparent entropy changes, with binding to the strong site accompanied by a large unfavorable enthalpy change. The PriA-PriB complex, formed independently of the DNA, is able to directly recognize the PAS without the preceding the binding of PriA to the PAS. Thus, the high-affinity state of PriA for PAS is generated through PriA-PriB interactions. The effect of PriB is specific for PriA-PAS association, but not for PriA-double-stranded DNA or PriA-single-stranded DNA interactions. Only complexes containing two PriA molecules can generate a profound change in the PAS structure in the presence of ATP. The obtained results provide a quantitative framework for the elucidation of further steps in primosome assembly and for quantitative analyses of other molecular machines of cellular metabolism.

Kinetic mechanism of the ssDNA recognition by the polymerase X from African Swine Fever Virus. Dynamics and energetics of intermediate formations

Kinetic mechanism of the ssDNA recognition by the polymerase X of African Swine Fever Virus (ASFV) and energetics of intermediate formations have been examined, using the fluorescence stopped-flow method. The association is a minimum three-step process PolX + ssDNA k(1) <-- --> k(-1) (P-ssDNA)(1) k(2) <-- --> k(-2) (P-ssDNA)(2) k(3) <-- --> k(-3) (P-ssDNA)(3). The nucleic acid makes the initial contact through the C-terminal domain, which generates most of the overall ΔG°. In the second step the nucleic acid engages the N-terminal domain, assuming the bent structure. In equilibrium, the complex exists in at least two different states. Apparent enthalpy and entropy changes, characterizing formations of intermediates, reflect association of the DNA with the C-terminal domain and gradual engagement of the catalytic domain by the nucleic acid. The intrinsic DNA-binding steps are entropy-driven processes accompanied by the net release of water molecules. The final conformational transition of the complex does not involve any large changes of the DNA topology, or the net release of the water molecules.

Interactions of the DNA polymerase X from African Swine Fever Virus with the ssDNA. Properties of the total DNA-binding site and the strong DNA-binding subsite

Interactions of the polymerase X from the African Swine Fever Virus with the ssDNA have been studied, using quantitative fluorescence titration and fluorescence resonance energy transfer techniques. The primary DNA-binding subsite of the enzyme, independent of the DNA conformation, is located on the C-terminal domain. Association of the bound DNA with the catalytic N-terminal domain finalizes the engagement of the total DNA-binding site of the enzyme and induces a large topological change in the structure of the bound ssDNA. The free energy of binding includes a conformational transition of the protein. Large positive enthalpy changes accompanying the ASFV pol X-ssDNA association indicate that conformational changes of the complex are induced by the engagement of the N-terminal domain. The enthalpy changes are offset by large entropy changes accompanying the DNA binding to the C-terminal domain and the total DNA-binding site, predominantly resulting from the release of water molecules.

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.

The primary DNA-binding subsite of the rat pol β. Energetics of interactions of the 8-kDa domain of the enzyme with the ssDNA

Interactions of the 8-kDa domain of the rat pol β and the intact enzyme with the ssDNA have been studied, using the quantitative fluorescence titration technique. The 8-kDa domain induces large topological changes in the bound DNA structure and engages much larger fragments of the DNA than when embedded in the intact enzyme. The DNA affinity of the domain is predominantly driven by entropy changes, dominated by the water release from the protein. The thermodynamic characteristics dramatically change when the domain is embedded in the intact polymerase, indicating the presence of significant communication between the 8-kDa domain and the catalytic 31-kDa domain. The diminished water release from the 31-kDa domain strongly contributes to its dramatically lower DNA affinity, as compared to the 8-kDa domain. Unlike the 8-kDa domain, the DNA binding of the intact pol β is driven by entropy changes, originating from the structural changes of the formed complexes.

Size-independent and noncooperative recognition of dsRNA by the Rice stripe virus RNA silencing suppressor NS3

Plant and animal viruses employ diverse suppressor proteins to thwart the host antiviral reaction of RNA silencing. Many suppressors bind dsRNA with different size specificity. Here, we examine the dsRNA recognition mechanism of the Rice stripe virus NS3 suppressor using quantitative biochemical approaches, as well as mutagenesis and suppression activity analyses in plants. We show that dimeric NS3 is a size-independent, rather than small interfering RNA-specific, dsRNA-binding protein that recognizes a minimum of 9 bp and can bind to long dsRNA with two or more copies. Global analysis using a combinatorial approach reveals that NS3 dimer has an occluded site size of ∼ 13 bp on dsRNA, an intrinsic binding constant of 1 × 10(8) M(-1), and virtually no binding cooperativity. This lack of cooperativity suggests that NS3 is not geared to target long dsRNA. The larger site size of NS3, compared with its interacting size, indicates that the NS3 structure has a border region that has no direct contact with dsRNA but occludes a ∼ 4-bp region from binding. We also develop a method to correct the border effect of ligand by extending the lattice length. In addition, we find that NS3 recognizes the helical structure and 2'-hydroxyl group of dsRNA with moderate specificity. Analysis of dsRNA-binding mutants suggests that silencing of the suppression activity of NS3 is mechanistically related to its dsRNA binding ability.

The Escherichia coli PriA helicase-double-stranded DNA complex: location of the strong DNA-binding subsite on the helicase domain of the protein and the affinity control by the two nucleotide-binding sites of the enzyme

The Escherichia coli PriA helicase complex with the double-stranded DNA (dsDNA), the location of the strong DNA-binding subsite, and the effect of the nucleotide cofactors, bound to the strong and weak nucleotide-binding site of the enzyme on the dsDNA affinity, have been analyzed using the fluorescence titration, analytical ultracentrifugation, and photo-cross-linking techniques. The total site size of the PriA-dsDNA complex is only 5±1 bp, that is, dramatically lower than 20±3 nucleotides occluded in the enzyme-single-stranded DNA (ssDNA) complex. The helicase associates with the dsDNA using its strong ssDNA-binding subsite in an orientation very different from the complex with the ssDNA. The strong DNA-binding subsite of the enzyme is located on the helicase domain of the PriA protein. The dsDNA intrinsic affinity is considerably higher than the ssDNA affinity and the binding process is accompanied by a significant positive cooperativity. Association of cofactors with strong and weak nucleotide-binding sites of the protein profoundly affects the intrinsic affinity and the cooperativity, without affecting the stoichiometry. ATP analog binding to either site diminishes the intrinsic affinity but preserves the cooperativity. ADP binding to the strong site leads to a dramatic increase of the cooperativity and only slightly affects the affinity, while saturation of both sites with ADP strongly increases the affinity and eliminates the cooperativity. Thus, the coordinated action of both nucleotide-binding sites on the PriA-dsDNA interactions depends on the structure of the phosphate group. The significance of these results for the enzyme activities in recognizing primosome assembly sites or the ssDNA gaps is discussed.

Binding specificity of Escherichia coli single-stranded DNA binding protein for the chi subunit of DNA pol III holoenzyme and PriA helicase

The Escherichia coli single-stranded DNA binding protein (SSB) plays a central role in DNA metabolism through its high affinity interactions with ssDNA, as well as its interactions with numerous other proteins via its unstructured C-termini. Although SSB interacts with at least 14 other proteins, it is not understood how SSB might recruit one protein over another for a particular metabolic role. To probe the specificity of these interactions, we have used isothermal titration calorimetry to examine the thermodynamics of binding of SSB to two E. coli proteins important for DNA replication, the chi subunit of DNA polymerase III holoenzyme and the PriA helicase. We find that an SSB tetramer can bind up to four molecules of either protein primarily via interactions with the last approximately 9 amino acids in the conserved SSB C-terminal tails (SSB-Ct). We observe intrinsic specificity for the binding of an isolated SSB-Ct peptide to PriA over chi due primarily to a more favorable enthalpic component. PriA and chi also bind with weaker affinity to SSB (in the absence of ssDNA) than to isolated SSB-Ct peptides, indicating an inhibitory effect of the SSB protein core. Although the binding affinity of SSB for both chi and PriA is enhanced if SSB is prebound to ssDNA, this effect is larger with PriA indicating a further enhancement of SSB specificity for PriA. These results also suggest that DNA binding proteins such as PriA, which also interact with SSB, could use this interaction to gain access to ssDNA by first interacting with the SSB C-termini.

Kinetic mechanism of DNA unwinding by the BLM helicase core and molecular basis for its low processivity

Bloom's syndrome (BS) is a rare human autosomal recessive disorder characterized by a strong predisposition to a wide range of cancers commonly affecting the general population. Understanding the functioning mechanism of the BLM protein may provide the opportunity to develop new effective therapy strategies. In this work, we studied the DNA unwinding kinetic mechanism of the helicase core of the BLM protein using various stopped-flow assays. We show that the helicase core of BLM unwinds duplex DNA as monomers even under conditions strongly favoring oligomerization. An unwinding rate of approximately 20 steps per second and a step size of 1 bp have been determined. We have observed that the helicase has a very low processivity. From dissociation and inhibition experiments, we have found that during its ATP hydrolysis cycle in DNA unwinding the helicase tends to dissociate from the DNA substrate in the ADP state. The experimental results imply that the BLM helicase core may unwind duplex DNA in an inchworm manner.

Interactions of the Escherichia coli primosomal PriB protein with the single-stranded DNA. Stoichiometries, intrinsic affinities, cooperativities, and base specificities

Quantitative analysis of the interactions of the Escherichia coli primosomal PriB protein with a single-stranded DNA was done using quantitative fluorescence titration, photocrosslinking, and analytical ultracentrifugation techniques. Stoichiometry studies were done with a series of etheno-derivatives of single-stranded (ss) DNA oligomers. Interactions with the unmodified nucleic acids were studied, using the macromolecular competition titration (MCT) method. The total site-size of the PriB dimer-ssDNA complex, i.e. the maximum number of nucleotides occluded by the PriB dimer in the complex, is 12+/-1 nt. The protein has a single DNA-binding site, which is located centrally within the dimer and has a functionally homogeneous structure. The stoichiometry and photocrosslinking data show that only a single monomer of the PriB dimer engages in interactions with the nucleic acid. The analysis of the PriB binding to long oligomers was done using a statistical thermodynamic model that takes into account the overlap of potential binding sites and cooperative interactions. The PriB dimer binds the ssDNA with strong positive cooperativity. Both the intrinsic affinity and cooperative interactions are accompanied by a net ion release, with anions participating in the ion exchange process. The intrinsic binding process is an entropy-driven reaction, suggesting strongly that the DNA association induces a large conformational change in the protein. The PriB protein shows a dramatically strong preference for the homo-pyrimidine oligomers with an intrinsic affinity higher by about three orders of magnitude, as compared to the homo-purine oligomers. The significance of these results for PriB protein activity is discussed.

The Escherichia coli PriA helicase specifically recognizes gapped DNA substrates: effect of the two nucleotide-binding sites of the enzyme on the recognition process

Energetics and specificity of interactions between the Escherichia coli PriA helicase and the gapped DNAs have been studied, using the quantitative fluorescence titration and analytical ultracentrifugation methods. The gap complex has a surprisingly low minimum total site size, corresponding to approximately 7 nucleotides of the single-stranded DNA (ssDNA), as compared with the site size of approximately 20 nucleotides of the enzyme-ssDNA complex. The dramatic difference in stoichiometries indicates that the enzyme predominantly engages the strong DNA-binding subsite in interactions with the gap and assumes a very different orientation in the gap complex, as compared with the complex with the ssDNA. The helicase binds the ssDNA gaps with 4-5 nucleotides with the highest affinity, which is approximately 3 and approximately 2 orders of magnitude larger than the affinities for the ssDNA and double-stranded DNA, respectively. In the gap complex, the protein does not engage in cooperative interactions with the enzyme predominantly associated with the surrounding dsDNA. Binding of nucleoside triphosphate to the strong and weak nucleotide-binding sites of the helicase eliminates the selectivity of the enzyme for the size of the gap, whereas saturation of both sites with ADP leads to amplified affinity for the ssDNA gap containing 5 nucleotides and engagement of an additional protein area in interactions with the nucleic acid.

Dynamics of the ssDNA recognition by the RepA hexameric helicase of plasmid RSF1010: analyses using fluorescence stopped-flow intensity and anisotropy methods

The kinetic mechanism of the single-stranded DNA (ssDNA) recognition by the RepA hexameric replicative helicase of the plasmid RSF1010 and the nature of formed intermediates, in the presence of the ATP nonhydrolyzable analog, beta,gamma-imidoadenosine-5'-triphosphate (AMP-PNP), have been examined, using the fluorescence intensity and anisotropy stopped-flow and analytical ultracentrifugation methods. Association of the RepA hexamer with the ssDNA oligomers that engage the total DNA-binding site and exclusively the strong DNA-binding subsite is a minimum four-step mechanism [formula: see text]. Extreme stability of the RepA hexamer precludes any disintegration of its structure, and the sequential character of the mechanism indicates that the enzyme exists in a predominantly single conformation prior to the association with the nucleic acid. Moreover, the hexameric helicase possesses a DNA-binding site located outside its cross channel. The reaction steps have dramatically different dynamics, with rate constants differing by 2-3 orders of magnitude. Such behavior indicates a very diverse nature of the observed transitions, which comprises binding steps and large conformational transitions of the helicase, including local opening of the hexameric structure. Steady-state fluorescence anisotropies of intermediates indicate that the entry of the DNA into the cross channel is initiated from the 5' end of the bound nucleic acid. The global structure of the tertiary complex RepA-ssDNA-AMP-PNP is very different from the structure of the binary complex RepA-AMP-PNP, indicating that, in equilibrium, the RepA hexamer-ssDNA-AMP-PNP complex exists as a mixture of partially open states.

Thermodynamic analysis of the structure-function relationship in the total DNA-binding site of enzyme-DNA complexes

Both helicases and polymerases perform their activities when bound to the nucleic acids, that is, the enzymes possess a nucleic acid-binding site. Functional complexity of the helicase or the polymerase action is reflected in the intricate structure of the total nucleic acid-binding site, which allows the enzymes to control and change their nucleic acid affinities during the catalysis. Understanding the fundamental aspects of the functional heterogeneity of the total nucleic acid-binding site of a polymerase or helicase can be achieved through quantitative thermodynamic analysis of the enzyme binding to the nucleic acids oligomers, which differ in their length. Such an analysis allows the experimenter to assess the presence of areas with strong and weak affinity for the nucleic acid, that is, the presence of the strong and the weak nucleic acid-binding subsites, determine the number of the nucleotide occlude by each subsite, and estimate their intrinsic free energies of interactions.

The zinc-binding motif of human RECQ5beta suppresses the intrinsic strand-annealing activity of its DExH helicase domain and is essential for the helicase activity of the enzyme

RecQ family helicases, functioning as caretakers of genomic integrity, contain a zinc-binding motif which is highly conserved among these helicases, but does not have a substantial structural similarity with any other known zinc-finger folds. In the present study, we show that a truncated variant of the human RECQ5beta helicase comprised of the conserved helicase domain only, a splice variant named RECQ5alpha, possesses neither ATPase nor DNA-unwinding activities, but surprisingly displays a strong strand-annealing activity. In contrast, fragments of RECQ5beta including the intact zinc-binding motif, which is located immediately downstream of the helicase domain, exhibit much reduced strand-annealing activity but are proficient in DNA unwinding. Quantitative measurements indicate that the regulatory role of the zinc-binding motif is achieved by enhancing the DNA-binding affinity of the enzyme. The novel intramolecular modulation of RECQ5beta catalytic activity mediated by the zinc-binding motif may represent a universal regulation mode for all RecQ family helicases.

Multiple global conformational states of the hexameric RepA helicase of plasmid RSF1010 with different ssDNA-binding capabilities are induced by different numbers of bound nucleotides. Analytical ultracentrifugation and dynamic light scattering studies

Global conformational transitions of the hexameric RepA helicase of plasmid RSF1010, induced by the nucleoside tri and di-phosphate binding, have been examined using analytical ultracentrifugation and dynamic light scattering techniques. The global structure of the RepA hexamer in solution, modeled as an oblate ellipsoid of revolution, is very different from its crystal structure, with the axial ratio of the ellipsoid being approximately 4.5 as compared to only approximately 2.4 in the crystal structure. The large axial ratio and the experimentally determined partial specific volume strongly suggest that, in solution, the diameter of the cross-channel of the hexamer is larger than approximately 17 A seen in the crystal. The global conformation of the helicase is modulated by a specific number of bound nucleotides. The enzyme exists in at least four conformational states, occurring sequentially as a function of the number of bound cofactors. These conformational states are different for ADP, as compared to beta,gamma-imidoadenosine 5'-triphosphate (AMP-PNP). Modulation of the global structure is separated into two phases, different for complexes with up to three bound nucleotides, from the effect observed at the saturating level of cofactors. This heterogeneity indicates different functional roles of the two modulation processes. Nucleotide control of helicase - single-stranded (ss)DNA interactions occurs through affecting the enzyme structure and the ssDNA affinity prior to DNA binding. Only one conformational state of the helicase, with two AMP-PNP molecules bound, has dramatically higher ssDNA-affinities than the complexes with ADP. Moreover the same state also has an increased site-size of the enzyme - ssDNA complexes. The implications of these findings for functional activities of a hexameric helicase are discussed.

Interactions of the DNA polymerase X of African swine fever virus with double-stranded DNA. Functional structure of the complex

Interactions of the polymerase X of African swine fever virus with the double-stranded DNA (dsDNA) have been studied with fluorescent dsDNA oligomers, using quantitative fluorescence titrations, analytical ultracentrifugation, and fluorescence energy transfer techniques. Studies with unmodified dsDNAs were performed, using competition titration method. ASV pol X binds the dsDNA with a site-size of n=10(+/-2) base-pairs, which is significantly shorter than the total site-size of 16(+/-2) nucleotides of the enzyme-ssDNA complex. The small site size indicates that the enzyme binds the dsDNA exclusively using the proper DNA-binding subsite. Fluorescence energy transfer studies between the tryptophan residue W92 and the acceptor, located at the 5' or 3' end of the dsDNA, suggest strongly that the proper DNA-binding subsite is located on the non-catalytic C-terminal domain. Moreover, intrinsic interactions with the dsDNA 10-mer or 20-mer are accompanied by the same net number of ions released, independent of the length of the DNA, indicating the same length of the DNA engaged in the complex. The dsDNA intrinsic affinity is about two orders of magnitude higher than the ssDNA affinity, indicating that the proper DNA-binding subsite is, in fact, the specific dsDNA-binding site. Surprisingly, ASFV pol X binds the dsDNA with significant positive cooperativity, which results from protein-protein interactions. Cooperative interactions are accompanied by the net ion release, with anions participating in the ion-exchange process. The significance of these results for ASFV pol X activity in the recognition of damaged DNA is discussed.

Biochemical, biophysical, and proteomic approaches to study DNA helicases

Helicases are a family of enzymes that play an essential role in nearly all DNA metabolic processes, catalyzing the transient opening of DNA duplexes. These motor proteins couple the chemical energy of ATP binding and hydrolysis to the separation of the complementary strands of a DNA or RNA duplex substrate. A full understanding of their mechanism of DNA unwinding can be achieved only through careful investigation of the thermodynamic and kinetic parameters that control this ATP-driven process, as well as through analysis of the helicases' tertiary and quaternary structures associated with nucleic acids and/or nucleotide recognition. This review describes the various biochemical, biophysical, and, more recently, proteomic techniques that have been developed to shed light on the still controversial, and in some aspects elusive, helicase-catalyzed mechanism of DNA unwinding.

DNA polymerase X from African swine fever virus: quantitative analysis of the enzyme-ssDNA interactions and the functional structure of the complex

Interactions of polymerase X from African swine fever virus with single-stranded DNA (ssDNA) have been studied, using quantitative fluorescence titration and analytical ultracentrifugation techniques. Experiments were performed with a fluorescent etheno-derivative of ssDNA oligomers. Studies of unmodified ssDNA oligomers were carried out using the competition titration method. The total site-size of the pol X-ssDNA complex is 16(+/-1) nucleotide residues. The large total ssDNA-binding site has a complex heterogeneous structure. It contains the proper ssDNA-binding site that encompasses only 7(+/-1) residues. As the length of the ssDNA increases, the enzyme engages an additional binding area in interactions with the DNA, at a distance of approximately 7-8 nucleotides from the proper site, which is located asymmetrically within the polymerase molecule. As a result, the net ion release accompanying the interactions with the DNA, increases from approximately 1 for the proper DNA-binding site to approximately 6 for the total DNA-binding site. Unlike in the case of the mammalian polymerase beta that belongs to the same polymerase X family, the DNA-binding areas within the total DNA-binding site of pol X are not autonomous. Consequently, the enzyme does not form different binding modes with different numbers of occluded nucleotide residues, although the interacting areas are structurally separated. The statistical thermodynamic model that accounts for the engagement of the proper and the total DNA-binding site in interactions with the DNA provides an excellent description of the binding process. Pol X binds the ssDNA without detectable cooperativity and with very modest base specificity.

Interactions of the RepA helicase hexamer of plasmid RSF1010 with the ssDNA. Quantitative analysis of stoichiometries, intrinsic affinities, cooperativities, and heterogeneity of the total ssDNA-binding site

Interactions between the replicative RepA helicase hexamer of plasmid RSF1010 with the single-stranded DNA (ssDNA) have been studied, using the quantitative fluorescence titration, analytical sedimentation velocity, and sedimentation equilibrium techniques. Experiments were performed with fluorescein-labeled ssDNA oligomers. Studies with unmodified ssDNA oligomers were accomplished using the macromolecular competition titration method. Analyses of RepA helicase interactions with a series of the ssDNA provide direct evidence that the total site-size of the RepA hexamer-ssDNA complex is 19 +/- 1 nucleotide residues. The total ssDNA-binding site of the hexamer has a heterogeneous structure. Part of the total binding site constitutes the proper ssDNA-binding site of the enzyme, an area that possesses strong ssDNA-binding capability and encompasses only 8 +/- 1 residues of the ssDNA. The statistical effect on the macroscopic binding constant for the proper ssDNA-binding site indicates that it is structurally separated from the remaining part of the total ssDNA-binding site. Engagement in interactions with the ssDNA is accompanied by net ion release. Moreover, the proper ssDNA-binding site shows little base specificity. On the other hand, with long ssDNA oligomers, the entire total ssDNA-binding site of the RepA hexamer engages in interactions with the ssDNA resulting in a dramatic change in the nature of interactions with the nucleic acid. The association includes an uptake of ions by the protein. Moreover, unlike the proper-ssDNA-binding site, the total binding site shows a significant preference for pyrimidine oligomers. In this aspect, the RepA helicase is different from the Escherichia coli DnaB hexamer that shows large preference for purine homo-oligomers. In similar solution conditions, the ssDNA intrinsic affinity of the RepA hexamer is similar to the intrinsic affinity of the DnaB helicase. The RepA helicase binds to ssDNA oligomers that can accept more than one RepA hexamer with significant positive cooperative interactions.

The DNA binding properties of the Escherichia coli RecQ helicase

The RecQ helicase family is highly conserved from bacteria to men and plays a conserved role in the preservation of genome integrity. Its deficiency in human cells leads to a marked genomic instability that is associated with premature aging and cancer. To determine the thermodynamic parameters for the interaction of Escherichia coli RecQ helicase with DNA, equilibrium binding studies have been performed using the thermodynamic rigorous fluorescence titration technique. Steady-state fluorescence anisotropy measurements of fluorescein-labeled oligonucleotides revealed that RecQ helicase bound to DNA with an apparent binding stoichiometry of 1 protein monomer/10 nucleotides. This stoichiometry was not altered in the presence of AMPPNP (adenosine 5'-(beta,gamma-imido) triphosphate) or ADP. Analyses of RecQ helicase interactions with oligonucleotides of different lengths over a wide range of pH, NaCl, and nucleic acid concentrations indicate that the RecQ helicase has a single strong DNA binding site with an association constant at 25 degrees C of K=6.7 +/- 0.95 x 10(6) M(-1) and a cooperativity parameter of omega=25.5 +/- 1.2. Both single-stranded DNA and double-stranded DNA bind competitively to the same site. The intrinsic affinities are salt-dependent, and the formation of DNA-helicase complex is accompanied by a net release of 3-4 ions. Allosteric effects of nucleotide cofactors on RecQ binding to DNA were observed only for single-stranded DNA in the presence of 1.5 mM AMPPNP, whereas both AMPPNP and ADP had no detectable effect on double-stranded DNA binding over a large range of nucleotide cofactor concentrations.

Analytic binding isotherms describing competitive interactions of a protein ligand with specific and nonspecific sites on the same DNA oligomer

Many studies of specific protein-nucleic acid binding use short oligonucleotides or restriction fragments, in part to minimize the potential for nonspecific binding of the protein. However, when the specificity ratio is low, multiple nonspecifically bound proteins may occupy the region of DNA corresponding to one specific site; this situation was encountered in our recent calorimetric study of binding of integration host factor (IHF) protein to its specific 34-bp H' DNA site. Here, beginning from the analytical McGhee and von Hippel infinite-lattice nonspecific binding isotherm, we derive a novel analytic isotherm for nonspecific binding of a ligand to a finite lattice. This isotherm is an excellent approximation to the exact factorial-based Epstein finite lattice isotherm even for short lattices and therefore is of great practical significance for analysis of experimental data and for analytic theory. Using this isotherm, we develop an analytic treatment of the competition between specific and nonspecific binding of a large ligand to the same finite lattice (i.e., DNA oligomer) containing one specific and multiple overlapping nonspecific binding sites. Analysis of calorimetric data for IHF-H' DNA binding using this treatment yields enthalpies and binding constants for both specific and nonspecific binding and the nonspecific site size. This novel analysis demonstrates the potential contribution of nonspecific binding to the observed thermodynamics of specific binding, even with very short DNA oligomers, and the need for reverse (constant protein) titrations or titrations with nonspecific DNA to resolve specific and nonspecific contributions. The competition treatment is useful in analyzing low-specificity systems, including those where specificity is weakened by mutations or the absence of specificity factors.