Recognition of template-primer and gapped DNA substrates by the human DNA polymerase beta

Signal and binding. II. Converting physico-chemical responses to macromolecule-ligand interactions into thermodynamic binding isotherms

Physico-chemical titration techniques are the most commonly used methods in characterizing molecular interactions. These methods are mainly based on spectroscopic, calorimetric, hydrodynamic, etc., measurements. However, truly quantitative physico-chemical methods are absolutely based on the determination of the relationship between the measured signal and the total average degree of binding in order to obtain meaningful interaction parameters. The relationship between the observed physico-chemical signal of whatever nature and the degree of binding must be determined and not assumed, based on some ad hoc intuitive relationship/model, leading to determination of the true binding isotherm. The quantitative methods reviewed and discussed here allow an experimenter to rigorously determine the degree of binding and the free ligand concentration, i.e., they lead to the construction of the thermodynamic binding isotherm in a model-independent fashion from physico-chemical titration curves.

Quantitative Thermodynamic Analyses of Spectroscopic Titration Curves

Elucidation of ligand - macromolecule interactions requires detailed knowledge of energetics of the formed complexes. Spectroscopic methods are most commonly used in characterizing molecular interactions in solution. The methods do not require large quantities of material and most importantly, do not perturb the studied reactions. However, spectroscopic methods absolutely require the determination of the relationship between the observed signal and the degree of binding in order to obtain meaningful interaction parameters. In other words, the meaningful, thermodynamic interaction parameters can be only determined if the relationship between the observed signal and the degree of binding is determined and not assumed, based on an ad hoc model of the relationship. The approaches discussed here allow an experimenter to quantitatively determine the degree of binding and the free ligand concentration, i.e., they enable to construct thermodynamic binding isotherms in a model-independent fashion.

Interactions of replication versus repair DNA substrates with the Pol I DNA polymerases from Escherichia coli and Thermus aquaticus

Different DNA polymerases partition differently between replication and repair pathways. In this study we examine if two Pol I family polymerases from evolutionarily distant organisms also differ in their preferences for replication versus repair substrates. The DNA binding preferences of Klenow and Klentaq DNA polymerases, from Escherichia coli and Thermus aquaticus respectively, have been studied using a fluorescence competition binding assay. Klenow polymerase binds primed-template DNA (the replication substrate) with up to 50× higher affinity than it binds to nicked DNA, DNA with a 2 base single-stranded gap, blunt-ended DNA, or to a DNA end with a 3' overhang. In contrast, Klentaq binds all of these DNAs almost identically, indicating that Klenow has a stronger ability to discriminate between replication and repair substrates than Klentaq. In contrast, both polymerases bind mismatched primed-template and blunt-ended DNA tighter than they bind matched primed-template DNA, suggesting that these two proteins may share a similar mechanism to identify mismatched DNA, despite the fact that Klentaq has no proofreading ability. In addition, the presence or absence of 5'- or 3'-phosphates has slightly different effects on DNA binding by the two polymerases, but again reinforce Klenow's more effective substrate discrimination capability.

Macromolecular competition titration method accessing thermodynamics of the unmodified macromolecule-ligand interactions through spectroscopic titrations of fluorescent analogs

Analysis of thermodynamically rigorous binding isotherms provides fundamental information about the energetics of the ligand-macromolecule interactions and often an invaluable insight about the structure of the formed complexes. The Macromolecular Competition Titration (MCT) method enables one to quantitatively obtain interaction parameters of protein-nucleic acid interactions, which may not be available by other methods, particularly for the unmodified long polymer lattices and specific nucleic acid substrates, if the binding is not accompanied by adequate spectroscopic signal changes. The method can be applied using different fluorescent nucleic acids or fluorophores, although the etheno-derivatives of nucleic acid are especially suitable as they are relatively easy to prepare, have significant blue fluorescence, their excitation band lies far from the protein absorption spectrum, and the modification eliminates the possibility of base pairing with other nucleic acids. The MCT method is not limited to the specific size of the reference nucleic acid. Particularly, a simple analysis of the competition titration experiments is described in which the fluorescent, short fragment of nucleic acid, spanning the exact site-size of the protein-nucleic acid complex, and binding with only a 1:1 stoichiometry to the protein, is used as a reference macromolecule. Although the MCT method is predominantly discussed as applied to studying protein-nucleic acid interactions, it can generally be applied to any ligand-macromolecule system by monitoring the association reaction using the spectroscopic signal originating from the reference macromolecule in the presence of the competing macromolecule, whose interaction parameters with the ligand are to be determined.

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.

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.

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.

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.

Structure and function of 2:1 DNA polymerase.DNA complexes

DNA polymerases are required for DNA replication and DNA repair in all of the living organisms. Different DNA polymerases are responsible different stages of DNA metabolism, and many of them are multifunctional enzymes. It was generally assumed that the different reactions are catalyzed by the same enzyme molecule. In addition to 1:1 DNA polymerase.DNA complex reported by crystallization studies, 2:1 and higher order DNA polymerase.DNA complexes have been identified in solution studies by various biochemical and biophysical approaches. Further, abundant evidences for the DNA polymerase-DNA interactions in several DNA polymerases suggested that the 2:1 complex represents the more active form. This review describes the current status of this emerging subject and explores their potential in vitro and in vivo functional significance, particularly for the 2:1 complexes of mammalian DNA polymerase beta (Pol beta), the Klenow fragment of E. coli DNA polymerase I (KF), and T4 DNA polymerase.

Solution structures of 2 : 1 and 1 : 1 DNA polymerase-DNA complexes probed by ultracentrifugation and small-angle X-ray scattering

We report small-angle X-ray scattering (SAXS) and sedimentation velocity (SV) studies on the enzyme-DNA complexes of rat DNA polymerase beta (Pol beta) and African swine fever virus DNA polymerase X (ASFV Pol X) with one-nucleotide gapped DNA. The results indicated formation of a 2 : 1 Pol beta-DNA complex, whereas only 1 : 1 Pol X-DNA complex was observed. Three-dimensional structural models for the 2 : 1 Pol beta-DNA and 1 : 1 Pol X-DNA complexes were generated from the SAXS experimental data to correlate with the functions of the DNA polymerases. The former indicates interactions of the 8 kDa 5'-dRP lyase domain of the second Pol beta molecule with the active site of the 1 : 1 Pol beta-DNA complex, while the latter demonstrates how ASFV Pol X binds DNA in the absence of DNA-binding motif(s). As ASFV Pol X has no 5'-dRP lyase domain, it is reasonable not to form a 2 : 1 complex. Based on the enhanced activities of the 2 : 1 complex and the observation that the 8 kDa domain is not in an optimal configuration for the 5'-dRP lyase reaction in the crystal structures of the closed ternary enzyme-DNA-dNTP complexes, we propose that the asymmetric 2 : 1 Pol beta-DNA complex enhances the function of Pol beta.

Interactions of the DNA polymerase X from African swine fever virus with gapped DNA substrates. Quantitative analysis of functional structures of the formed complexes

Energetics and specificity of interactions between the African swine fever virus polymerase X and gapped DNA substrates have been studied, using the quantitative fluorescence titration technique. Stoichiometries of pol X complexes, with the DNA substrates, are higher than suggested by NMR studies. This can be understood in the context of the functionally heterogeneous organization of the total DNA-binding site of pol X, which is composed of two DNA-binding subsites. The enzyme forms two different complexes with the gapped DNAs, differing dramatically in affinities. In the high-affinity complex, pol X engages the total DNA-binding site, forming the gap complex, while in the low-affinity the enzyme binds to the dsDNA parts of the gapped DNA, using only one of the DNA-binding subsites. As a result, the net number of ions released in the gap complex formation is significantly larger than in the binding of the dsDNA part. In the presence of Mg+2, pol X shows a strong preference for the ssDNA gaps having one and two nucleotides. Recognition of the short gaps already occurs in the ground state of the enzyme-DNA complex. Surprisingly, the specific structure necessary to recognize the short gaps is induced by magnesium binding to the enzyme. In the absence of Mg+2, pol X looses its selectivity for short ssDNA gaps. Pol X binds gapped DNAs with considerable cooperative interactions, which increase with the decreasing gap size. The functional implications of these findings for ASFV pol X activities are discussed.

Kinetic model for the ATP-dependent translocation of Saccharomyces cerevisiae RSC along double-stranded DNA

The chromatin remodeling complex RSC from Saccharomyces cerevisiae is a DNA translocase that moves with directionality along double-stranded DNA in a reaction that is coupled to ATP hydrolysis. To better understand how this basic molecular motor functions, a novel method of analysis has been developed to study the kinetics of RSC translocation along double-stranded DNA. The data provided are consistent with RSC translocation occurring through a series of repeating uniform steps with an overall processivity of P = 0.949 +/- 0.003; this processivity corresponds to an average translocation distance of 20 +/- 1 base pairs (bp) before dissociation. Interestingly, a slow initiation process, following DNA binding, is required to make RSC competent for DNA translocation. These results are further discussed in the context of previously published studies of RSC and other DNA translocases.

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.

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.

Kinetic mechanism of rat polymerase beta-dsDNA interactions. Fluorescence stopped-flow analysis of the cooperative ligand binding to a two-site one-dimensional lattice

Kinetics of cooperative binding of rat polymerase beta to a double-stranded DNA has been studied using the fluorescence stopped-flow techniques. The data have been analyzed by an approach developed to examine complete kinetics of cooperative large ligand binding to a one-dimensional lattice. The method is based on using the smallest possible system that preserves key ingredients of cooperative binding; i.e., at saturation, the lattice can accept only two ligand molecules. It allows the identification of collective amplitudes as well as amplitudes describing particular normal modes of the reaction. The mechanism of the intrinsic binding of pol beta to the dsDNA is different from the analogous mechanism for the ssDNA. The difference originates from different enzyme orientations in the corresponding complexes. Intrinsic binding to the dsDNA includes only two sequential steps: a very fast bimolecular association followed by an energetically favorable conformational transition of the complex. The transition following the bimolecular step does not facilitate the engagement of the enzyme in cooperative interactions. Its role seems to be reinforcing the affinity of the bimolecular step. Salt and magnesium cations affect both the bimolecular step and the conformational transition. As a result, the bimolecular step is less sensitive to the increased salt concentration, allowing the enzyme to preserve its initial dsDNA affinity. The changing character of cooperative interactions between bound enzyme molecules as a function of NaCl concentration and MgCl(2) concentration does not affect the binding mechanism. The engagement in cooperative interactions is approximately 3-4 orders of magnitude slower than the conformational transition of the DNA-bound polymerase. The importance of the obtained results for the pol beta activities is discussed.

Structure and mechanism of DNA polymerases

DNA polymerases are molecular motors directing the synthesis of DNA from nucleotides. All polymerases have a common architectural framework consisting of three canonical subdomains termed the fingers, palm, and thumb subdomains. Kinetically, they cycle through various states corresponding to conformational transitions, which may or may not generate force. In this review, we present and discuss the kinetic, structural, and single-molecule works that have contributed to our understanding of DNA polymerase function.

Gene structure, purification and characterization of DNA polymerase beta from Xiphophorus maculatus

Cloning of the Xiphophorus maculatus Polbeta gene and overexpression of the recombinant Polbeta protein has been performed. The organization of the XiphPolbeta introns and exons, including intron-exon boundaries, have been assigned and were found to be similar to that for human Polbeta with identical exon sizes except for exon XII coding for an additional two amino acid residues in Xiphophorus. The cDNA sequence encoding the 337-amino acid X. maculatus DNA polymerase beta (Polbeta) protein was subcloned into the Escherichia coli expression plasmid pET. Induction of transformed E. coli cells resulted in the high-level expression of soluble recombinant Polbeta, which catalyzed DNA synthesis on template-primer substrates. The steady-state Michaelis constants (Km) and catalytic efficiencies (kcat/Km) of the recombinant XiphPolbeta for nucleotide insertion opposite single-nucleotide gap DNA substrates were measured and compared with previously published values for recombinant human Polbeta. Steady-state in vitro Km and kcat/Km values for correct nucleotide insertion by XiphPolbeta and human Polbeta were similar, although the recombinant Xiphophorus protein exhibited 2.5-7-fold higher catalytic efficiencies for dGTP and dCTP insertion versus human Polbeta. In contrast, the recombinant XiphPolbeta displayed significantly lower fidelities than human Polbeta for dNTP insertion opposite a single-nucleotide gap at 37 degrees C.

Tertiary conformation of the template-primer and gapped DNA substrates in complexes with rat polymerase beta. Fluorescence energy transfer studies using the multiple donor-acceptor approach

The tertiary structure of template-primer and gapped DNA substrates in the complex with rat polymerase beta (pol beta) has been examined using the fluorescence energy transfer method based on the multiple donor-acceptor approach. In these studies, we used DNA substrates labeled at the 5' end of the template strand and the 5' end of the primer with the fluorescent donor and/or acceptor. Measurements of the enzyme complex with the template-primer DNA substrate having a ten nucleotide long ssDNA extension indicate that the distance between the 5' end of the template strand and the 5' end of the primer decreases by approximately 9.8 A as compared to the free nucleic acid. Analogous experiments with the template-primer substrate, having the ssDNA extension with five nucleotide residues, show approximately 6.6 A distance decrease. Such large distance decreases indicate that the DNA is significantly bent in the binding site. Analysis of the data indicates that the bending occurs between the third and the fourth nucleotide of the ssDNA extension. The entire template strand is at the bend angle Theta(TP) = 85 +/- 7 degrees with respect to the dsDNA part of the DNA molecule. In the polymerase complex with the gapped DNA, the distance between the 5' ends of the DNA and the bend angle are 66 +/- 2.2 A and 65 +/- 6 degrees, respectively. These values are very similar to the same distance and bend angle of the gap complex in the crystal structure of the co-complex. The presence of the 5'-terminal PO(4)(-) group downstream from the primer does not affect the tertiary conformation of the gapped DNA, indicating that the effect of the phosphate group is localized at the ssDNA gap.

Translesion synthesis past platinum DNA adducts by human DNA polymerase mu

DNA polymerase mu (pol mu) is a member of the pol X family of DNA polymerases, and it shares a number of characteristics of both DNA polymerase beta (pol beta) and terminal deoxynucleotidyl transferase (TdT). Because pol beta has been shown to perform translesion DNA synthesis past cisplatin (CP)- and oxaliplatin (OX)-GG adducts, we determined the ability of pol mu to bypass these lesions. Pol mu bypassed CP and OX adducts with an efficiency of 14-35% compared to chain elongation on undamaged DNA, which is second only to pol eta in terms of bypass efficiency. The relative ability of pol mu to bypass CP and OX adducts was dependent on both template structure and sequence context. Since pol mu has been shown to be more efficient on gapped DNA templates than on primed single-stranded DNA templates, we determined the ability of pol mu to bypass Pt-DNA adducts on both primed single-stranded and gapped templates. The bypass of Pt-DNA adducts by pol mu was highly error-prone on all templates, resulting in 2, 3, and 4 nt deletions. We postulate that bypass of Pt-DNA adducts by pol mu may involve looping out the Pt-GG adduct to allow chain elongation downstream of the adduct. This reaction appears to be facilitated by the presence of a downstream "acceptor" and a gap large enough to provide undamaged template DNA for elongation past the adduct, although gapped DNA is clearly not required for bypass.

Dynamics of gapped DNA recognition by human polymerase beta

Kinetics of human polymerase beta binding to gapped DNA substrates having single stranded (ss) DNA gaps with five or two nucleotide residues in the ssDNA gap has been examined, using the fluorescence stopped-flow technique. The mechanism of the recognition does not depend on the length of the ssDNA gap. Formation of the enzyme complex with both DNA substrates occurs by a minimum three-step reaction, with the bimolecular step followed by two isomerization steps. The results indicate that the polymerase initiates the association with gapped DNA substrates through the DNA-binding subsite located on the 8-kDa domain of the enzyme. This first association step is independent of the length of the ssDNA gap and is characterized by similar rate constants for both examined DNA substrates. The subsequent, first-order transition occurs at the rate of approximately 600-1200 s(-1). This is the major docking step accompanied by favorable free energy changes in which the 31-kDa domain engages in interactions with the DNA. The 5'-terminal PO(4)(-) group downstream from the primer is not a specific recognition element of the gap. However, the phosphate group affects the enzyme orientation in the complex with the DNA, particularly, for the substrate with a longer gap.

The p58 subunit of human DNA primase is important for primer initiation, elongation, and counting

The p58 subunit of human DNA primase contains a region, M288-K344, that is homologous to part of the 8 kDa domain of DNA polymerase beta. Since regions of a protein that are highly conserved evolutionarily often play important catalytic functions, we examined the effects of mutating this region of the p58 subunit on primase activity. Deleting M288-L313 of the p58 subunit results in a protein that binds to the primase p49 subunit but cannot support primer synthesis on any template when assays only contain Mg(2+) as the divalent metal. Including Mn(2+), a metal that stimulates initiation of primer synthesis, in the assays now allows the enzyme to synthesize primers at a rate only moderately lower than that of the wild-type enzyme on templates consisting solely of deoxycytidylates. While the enzyme is active under these conditions, it has lost the ability to synthesize primers of defined length (i.e., count). Alanine scanning mutagenesis of charged residues in this region revealed three amino acids, R302, R306, and K314, that play important roles in both primer initiation and translocation. Conversion of these residues to alanine interfered with initiation and significantly decreased the processivity of primase. Together, these studies indicate that this "pol beta-like" region of p58 is important for three distinct aspects of primer synthesis:; initiation, translocation, and counting. The implications of these results with respect to the biological role of the p58 subunit and the mechanism of primer synthesis are discussed.

Kinetic mechanisms of rat polymerase beta-ssDNA interactions. Quantitative fluorescence stopped-flow analysis of the formation of the (Pol beta)(16) and (Pol beta)(5) ssDNA binding mode

Kinetics of rat polymerase beta (pol beta) binding to the single-stranded DNA (ssDNA) in the (pol beta)(16) and (pol beta)(5) binding modes has been examined, using the fluorescence stopped-flow technique. Binding of the enzyme to the ssDNA containing fluorescein is characterized by a strong increase of the DNA fluorescence, which provides an excellent signal to quantitatively study the complex mechanism of the ssDNA recognition process. The experiments were performed with a 20-mer ssDNA, which can engage the enzyme in the (pol beta)(16) binding mode, i.e. it encompasses the entire, total DNA-binding site of rat pol beta, and with a 10-mer which binds the enzyme exclusively in the (pol beta)(5) binding mode where only the 8 kDa domain of the enzyme is engaged in interactions with the DNA. The data indicate that the formation of the (pol beta)(16) binding mode occurs by a minimum three-step mechanism with the bimolecular binding step followed by two isomerizations: [formula-see text] A similar mechanism is observed in the formation of the (pol beta)(5) binding mode, although at low salt concentrations there is an additional, slow step in the reaction. The data analysis was performed using the matrix projection operator technique, a powerful method to address stopped-flow kinetics, particularly, amplitudes. The binding modes differ in the free energy changes of the partial reactions and ion effects on transitions between intermediates that reflect different participation of the two structural domains. The formation of both binding modes is initiated by the fast association with the ssDNA through the 8 kDa domain, followed by transitions induced by interactions at the interface of the 8 kDa domain and the DNA. In the (pol beta)(16) binding mode, the subsequent intermediates are stabilized by the DNA binding to the DNA-binding subsite on the 31 kDa domain. The data indicate that interactions of the ssDNA-binding subsite of the 8 kDa domain with the ssDNA, controlled by the ion binding, induce conformational transitions of the formed complexes in both binding modes. The sequential nature of the determined mechanisms indicates a lack of kinetically significant conformational equilibrium of rat pol beta, prior to ssDNA binding.

Multiple-step kinetic mechanisms of the ssDNA recognition process by human polymerase beta in its different ssDNA binding modes

The kinetics of human polymerase beta (pol beta) binding to the single-stranded DNA, in the (pol beta)(16) and (pol beta)(5) binding modes, that differ in the number of occluded nucleotide residues in the protein-DNA complexes, have been examined, using the fluorescence stopped-flow technique. This is the first determination of the mechanism of ssDNA recognition by human pol beta. Binding of the enzyme to the ssDNA containing fluorescein in the place of one of the nucleotides is characterized by a strong DNA fluorescence increase, providing the required signal to quantitatively examine the complex mechanism of ssDNA recognition. The experiments were performed with the ssDNA 20-mer, which engages the polymerase in the (pol beta)(16) binding mode and encompasses the total DNA-binding site of the enzyme, and with the 10-mer, which exclusively forms the (pol beta)(5) binding mode engaging only the 8-kDa domain of the enzyme. The obtained data and analyses indicate that the (pol beta)(16) formation occurs by a minimum four-step, sequential mechanism: (reaction: see text). Formation of the (pol beta)(5) binding mode proceeds with the same mechanism; however, both binding modes differ in the energetics of the partial reactions and the structure of the intermediates. Quantitative amplitude analysis, using the matrix projection operator approach, allowed us to determine molar fluorescence intensities of all intermediates relative to the fluorescence of the free DNA. The results indicate that (pol beta)(16) binding mode formation, which is initiated by the association of the 8-kDa domain with the DNA, is followed by subsequent intermediates stabilized by DNA binding to the 31-kDa domain. Comparison with the (pol beta)(5) binding mode formation indicates that transitions of the enzyme-DNA complex in both modes are induced at the interface of the 8-kDa domain and the DNA. The sequential nature of the mechanism indicates the lack of a conformational preequilibrium of the enzyme prior to ssDNA binding.