ssDNA Recognition Research Articles

Identification of the DNA-Binding Domains of Human Replication Protein A That Recognize G-Quadruplex DNA

Replication protein A (RPA), a key player in DNA metabolism, has 6 single-stranded DNA-(ssDNA-) binding domains (DBDs) A-F. SELEX experiments with the DBDs-C, -D, and -E retrieve a 20-nt G-quadruplex forming sequence. Binding studies show that RPA-DE binds preferentially to the G-quadruplex DNA, a unique preference not observed with other RPA constructs. Circular dichroism experiments show that RPA-CDE-core can unfold the G-quadruplex while RPA-DE stabilizes it. Binding studies show that RPA-C binds pyrimidine- and purine-rich sequences similarly. This difference between RPA-C and RPA-DE binding was also indicated by the inability of RPA-CDE-core to unfold an oligonucleotide containing a TC-region 5′ to the G-quadruplex. Molecular modeling studies of RPA-DE and telomere-binding proteins Pot1 and Stn1 reveal structural similarities between the proteins and illuminate potential DNA-binding sites for RPA-DE and Stn1. These data indicate that DBDs of RPA have different ssDNA recognition properties.

Structure–function analysis and molecular modeling of DNase catalytic antibodies

There is great interest in the antibodies-to-DNA transformation, since this change is characteristic of autoimmune diseases and contributes to its pathology. After immunization and fusions, 14 hybridomas bearing DNA-hydrolysis activity against pUC19 plasmid DNA were obtained. Genes coding for V H and V L regions of the 14 monoclonal antibodies (mAbs) were cloned and sequenced. The sequences were compared with sequences of the Ig-Blast database to determine their germline and to identify potential mutations responsible for DNA binding and DNase activity. V genes of the H chains’ genes expressed four genes of the V H1/J558 family, three of V H5/V H7183, and three of V H8/V H3609. The genetic repertoire of these mAbs was examined by determining the nucleotide sequences of their H chain V regions. This V H and V L domain was most similar to an anti-ssDNA (DNA-1) antibody as well as to catalytic autoimmune mAb (m3D8). Computer-generated models of the three-dimensional structures of V H and V L (VHL4) of the IgG4 combinations were used to define the positions occupied by the important sequence motifs at the binding sites. The modeling structure showed that VHL4 binds to oligo (dT3) primarily by sandwiching thymine bases between Tyr L32, Tyr L49 and Tyr H97 side-chains. Superposing VHL4 with anti-nucleic acid m3D8 catAbs revealed a common ssDNA recognition module consisting of His L93, His H35 residues which are critical for DNA-hydrolyzing antibodies. This study demonstrates the potential usefulness of the protein DNA surrogate in the investigation of the origin of anti-DNA antibodies’ hydrolyzing activities.

Insights into the Dynamics of Specific Telomeric Single-Stranded DNA Recognition by Pot1pN

The N-terminal oligonucleotide/oligosaccharide-binding fold domain of the Schizosaccharomyces pombe protection of telomeres 1 (Pot1) protein, Pot1pN (residues 1-187 of full-length Pot1), specifically recognizes telomeric single-stranded DNA (ssDNA) via a complex series of molecular interactions that are punctuated by unusual internucleotide hydrogen bonds. While the structure of ssDNA-bound Pot1pN provides an initial model for understanding how the Pot1pN-ssDNA complex is assembled and how specific nucleotide recognition occurs, further refinement requires knowledge of the ssDNA-free state of Pot1pN and the dynamic changes that accompany the binding of ssDNA. Using NMR strategies, we found that ssDNA-free Pot1pN adopts a similar overall protein backbone topology as ssDNA-bound Pot1pN does. Although the backbone structure remained relatively unchanged, we observed unexpected differential dynamic changes within the ssDNA-binding pockets of Pot1pN upon binding of cognate ssDNA. These studies support a model in which conformational selection and induced fit play important roles in the recognition of ssDNA by Pot1pN. Furthermore, the studies presented here provide a more comprehensive understanding of how specific nucleotide recognition is achieved by the telomere-end protection family of essential proteins.

Probing the mechanism of recognition of ssDNA by the Cdc13-DBD

The Saccharomyces cerevisiae protein Cdc13 tightly and specifically binds the conserved G-rich single-stranded overhang at telomeres and plays an essential role in telomere end-protection and length regulation. The 200 residue DNA-binding domain of Cdc13 (Cdc13-DBD) binds an 11mer single-stranded representative of the yeast telomeric sequence [Tel11, d(GTGTGGGTGTG)] with a 3 pM affinity and specificity for three bases (underlined) at the 5′ end. The structure of the Cdc13-DBD bound to Tel11 revealed a large, predominantly aromatic protein interface with several unusual features. The DNA adopts an irregular, extended structure, and the binding interface includes a long (∼30 amino acids) structured loop between strands β2-β3 (L2–3) of an OB-fold. To investigate the mechanism of ssDNA binding, we studied the free and bound states of Cdc13-DBD using NMR spectroscopy. Chemical shift changes indicate that the basic topology of the domain, including L2–3, is essentially intact in the free state. Changes in slow and intermediate time scale dynamics, however, occur in L2–3, while conformational changes distant from the DNA interface suggest an induced fit mechanism for binding in the ‘hot spot’ for binding affinity and specificity. These data point to an overall binding mechanism well adapted to the heterogeneous nature of yeast telomeres.

Loading/release behavior of (chitosan/DNA) n layer-by-layer films toward negatively charged anthraquinone and its application in electrochemical detection of natural DNA damage

In the present work, positively charged chitosan (CS) and negatively charged DNA were alternately adsorbed on the surface of pyrolytic graphite (PG) electrodes, forming (CS/DNA) n layer-by-layer films. Cyclic voltammetry (CV) results showed that negatively charged electroactive probe, 9,10-anthraquinone-2,6-disulfonate (AQDS), could be loaded into the (CS/DNA) n films from its solution (1 mM at pH 7.0, containing 0.1 M NaCl), designated as (CS/DNA) n –AQDS, and then released from the films in blank buffers. The loading/release behavior of (CS/DNA) n films toward AQDS was found to be obviously different between double-stranded (dsDNA) and single-stranded DNA (ssDNA). The release rate of AQDS from (CS/dsDNA) n films was much slower than that from the ssDNA counterparts mainly because AQDS could be intercalated into the double helix structure of dsDNA despite the repulsion between likely charged AQDS and DNA. The loading/release behavior of (CS/DNA) n films toward AQDS in recognition of dsDNA and ssDNA was then successfully applied to electrochemically detect the damage of natural DNA caused by Fenton reaction. To further understand the essence of the interactions involved in the AQDS loading/release process for (CS/DNA) n films, comparison experiments were performed, in which either positively charged intercalator brilliant cresyl blue (BCB) was used to replace AQDS as the redox probe, or poly(diallyldimethylammonium) (PDDA) with relatively high positive charge density was used to replace CS as the constituent of layer-by-layer films with DNA. The loading/release behavior of DNA films toward electroactive intercalator may open new possibilities for dsDNA/ssDNA recognition and of DNA damage detection by electrochemistry.

Recognition and detection of ssDNA using 2-mercaptobenzothiazole self-assembled monolayer modified gold electrode

A novel method for sensitive detection of single-stranded DNA (ssDNA) using 2-mercaptobenzothiazole (MBT) self-assembled monolayer (SAM) modified gold electrode (Au-MBT) has been developed. Based on the intercalating effect of MBT into double stranded DNA (dsDNA), Au-MBT electrode possessed the ability to distinguish ssDNA and dsDNA. Cyclic voltammetry (CV) was used to preliminarily characterize the MBT self-assembled monolayer on gold electrode. In the mixture of excessive probe ssDNA and target ssDNA, current signal recorded by differential pulse voltammetry (DPV) after DNA hybridization reflected the extent of the hybridization. Definite relations were observed between the reductive peak currents and the concentration of target ssDNA. The quantitative detection of target ssDNA was achieved with a linear range from 1.59 × 10−8 to 2.4 × 10−6 mol/L. The detection limit was 2.38 × 10−9 mol/L (3σ, n = 11). The Au-MBT electrode possessed high reusability and reproducibility, no significant deterioration of peak currents occurring over 10 detection/regeneration cycles. Combined with the advantages of simplicity and low-cost, the developed electrochemical biosensor shows potential in continuous and quantitative detection of ssDNA in biological samples.

Structural Modeling of Sequence Specificity by an Autoantibody against Single-Stranded DNA

11F8 is a sequence-specific pathogenic anti-single-stranded (ss)DNA autoantibody isolated from a lupus prone mouse. Site-directed mutagenesis of 11F8 has shown that six binding site residues (R31VH, W33VH, L97VH, R98VH, Y100VH, and Y32VL) contribute 80% of the free energy for complex formation. Mutagenesis results along with intermolecular distances obtained from fluorescence resonance energy transfer were implemented here as restraints to model docking between 11F8 and the sequence-specific ssDNA. The model of the complex suggests that aromatic stacking and two sets of bidentate hydrogen bonds between binding site arginine residues (R31VH and R96VH) and loop nucleotides provide the molecular basis for high affinity and specificity. In part, 11F8 utilizes the same ssDNA binding motif of Y32VL, H91VL, and an aromatic residue in the third complementarity-determining region to recognize thymine-rich sequences as do two anti-ssDNA autoantibodies crystallized in complex with thymine. R31SVH is a dominant somatic mutation found in the J558 germline sequence that is implicated in 11F8 sequence specificity. A model of the mutant R31S11F8.ssDNA complex suggests that different interface contacts occur when serine replaces arginine 31 at the binding site. The modeled contacts between the R31S11F8 mutant and thymine are closely related to those observed in other anti-ssDNA binding antibodies, while we find additional contacts between 11F8 and ssDNA that involve amino acids not utilized by the other antibodies. These data-driven 11F8.ssDNA models provide testable hypotheses concerning interactions that mediate sequence specificity in 11F8 and the effects of somatic mutation on ssDNA recognition.

Role of conformational dynamics in sequence‐specific autoantibody•ssDNA recognition

11F8 is a sequence-specific monoclonal anti-ssDNA autoantibody isolated from a lupus prone mouse that forms pathogenic complexes with ssDNA, resulting in kidney damage. Prior studies show that specificity is mediated by a somatic mutation from serine at (31)V(H) to arginine. Reversion back to serine in 11F8 resulted in >30-fold decrease in affinity and altered thermodynamic and kinetic parameters for sequence-specific recognition of its cognate ssDNA ligand. Mutagenesis and structural studies suggest that (R31)V(H) contacts ssDNA via a salt bridge and a bidentate hydrogen bond and may further contribute to specificity by altering binding-site conformation. Fluorescence resonance energy transfer experiments were conducted to assess the kinetics of conformational change during 11F8*ssDNA association. The extent of rearrangement between the six complementary determining regions in the 11F8*ssDNA complex with germline serine or somatically mutated arginine at residue 31 of the heavy chain was examined. Our studies show that greater conformational change occurs in five of six complementarity determining regions after the heavy chain germline J558 sequence undergoes mutation to arginine at (31)V(H).

Effect of somatic mutation on DNA binding properties of anti‐DNA autoantibodies

Autoantibodies that bind DNA are a hallmark of systemic lupus erythematosus. A subset of autoantibody*DNA complexes localize to kidney tissue and lead to damage and even death. 11F8, 9F11, and 15B10 are clonally related anti-DNA autoantibodies isolated from an autoimmune mouse. 11F8 binds ssDNA in a sequence-specific manner and causes tissue damage, while 9F11 and 15B10 bind ssDNA non-specifically and are benign. Among these antibodies, DNA binding properties are mediated by five amino acid differences in primary sequence. Thermodynamic and kinetic parameters associated with recognition of structurally different DNA sequences were determined for each antibody to provide insight toward recognition strategies, and to explore a link between binding properties and disease pathogenesis. A model of 11F8 bound to its high affinity consensus sequence provides a foundation for understanding the differences in thermodynamic and kinetic parameters between the three mAbs. Our data suggest that 11F8 utilizes the proposed ssDNA recognition motif including (Y32)V(L), a hydrogen bonding residue at (91)V(L), and an aromatic residue at the tip of the third heavy chain complementarity determining region. Interestingly, a somatic mutation to arginine at (31)V(H) in 11F8 may afford additional binding site contacts including (R31)V(H), (R96)V(H), and (R98)V(H) that could determine specificity.

Spectroscopic and Electrochemical Studies of the Interaction Between Fuchsin Basic and DNA

Visible spectroscopic and electrochemical methods were used to study the interactions between DNA and fuchsin basic (FB). FB has an irreversible electro-oxidation peak in 5 mmol/L Tris-HCl buffer solution at pH = 7. 4 on a glassy carbon electrode (GCE). After adding certain concentration of dsDNA, the oxidation peak current of FB decreases, but the peak potential hardly changes. The visible absorption spectroscopic study shows that the binding mode of FB to dsDNA is intercalative binding and electrostatic binding when the ratio of the concentration of dsDNA to FB is smaller than 0.2, and a new substance, which produces a new absorption peak, is obtained via a covalent binding between dsDNA and FB apart from intercalative binding and electrostatic binding when the ratio of the concentration of dsDNA to FB is larger than 0. 2. The visible absorption spectra varies no longer when the ratio of the concentration of dsDNA to FB is larger than 1. 5. A mean binding ratio of dsDNA to FB was determined to be 1. 4: 1, suggesting that two complexes FB-dsDNA and FB-2dsDNA be formed. The interaction between FB and ssDNA was only electrostatic binding. The more powerful interaction of FB with dsDNA than with ssDNA may be applied for the recognition of dsDNA and ssDNA, and in DNA biosensor as hybridization indicator.

Physicochemical Basis of RecA Filamentation on Single-Stranded DNA

Quantitative analysis was performed for the first time for the interaction of Escherichia coli RecA, which plays the central role in homologous recombination, and ssDNA varying in length and structure. DNA recognition was shown to depend on weak additive interactions between RecA monomers of the filament and various structural elements of DNA. Orthophosphate and dNMPs acted as minimal inhibitors of RecA filamentation on d(pN)20. A stepwise increase in homooligonucleotide length by one nucleotide (from 2 to 20 nt) monotonically increased the affinity approximately twofold (factor f) due to weak additive contacts of RecA with each internucleoside phosphate (f ≈ 1.56) and specific interactions with T and C (f ≈ 1.32). In the case of d(pA) n , the RecA filament showed virtually no interaction with bases and interacted more efficiently with internucleoside phosphates of the first than of the next helix turn (n 10, f ≈ 1.3). The affinity of RecA for d(pN) n and various modified bases proved to depend on the base, the DNA structure, and the conformation of the sugar-phosphate backbone. The affinity considerably increased with bases containing exocyclic proton-accepting groups. Possible causes of the preferential binding of RecA with DNAs of a particular length and composition are considered. Mechanisms are proposed for ssDNA recognition by RecA and for homologous strand exchange.

Formation of nucleoprotein RecA filament on single‐stranded DNA

RecA protein plays a pivotal role in homologous recombination in Escherichia coli. RecA polymerizes on single-stranded (ss) DNA forming a nucleoprotein filament. Then double-stranded (ds) DNA is bound and searched for segments homologous to the ssDNA. Finally, homologous strands are exchanged, a new DNA duplex is formed, and ssDNA is displaced. We report a quantitative analysis of RecA interactions with ss d(pN)n of various structures and lengths using these oligonucleotides as inhibitors of RecA filamentation on d(pT)20. DNA recognition appears to be mediated by weak interactions between its structural elements and RecA monomers within a filament. Orthophosphate and dNMP are minimal inhibitors of RecA filamentation (I50 = 12-20 mM). An increase in homo-d(pN)2-40 length by one unit improves their affinity for RecA (f factor) approximately twofold through electrostatic contacts of RecA with internucleoside phosphate DNA moieties (f approximately = 1.56) and specific interactions with T or C bases (f approximately = 1.32); interactions with adenine bases are negligible. RecA affinity for d(pN)n containing normal or modified nucleobases depends on the nature of the base, features of the DNA structure. The affinity considerably increases if exocyclic hydrogen bond acceptor moieties are present in the bases. We analyze possible reasons underlying RecA preferences for DNA sequence and length and propose a model for recognition of ssDNA by RecA.

Evidence for Structural Plasticity of Heavy Chain Complementarity-determining Region 3 in Antibody–ssDNA Recognition

Anti-DNA antibodies play important roles in the pathogenesis of autoimmune diseases. They also represent a unique and relatively unexplored class of DNA-binding protein. Here, we present a study of conformational changes induced by DNA binding to an anti-ssDNA Fab known as DNA-1. Three crystal structures are reported: a complex of DNA-1 bound to dT3, and two structures of the ligand-free Fab. One of the ligand-free structures was determined from crystals exhibiting perfect hemihedral twinning, and the details of structure determination are provided. Unexpectedly, five residues (H97-H100A) in the apex of heavy chain complementarity-determining region 3 (HCDR3) are disordered in both ligand-free structures. Ligand binding also caused a 2-4A shift of the backbone of Tyr L92 and ordering of the L92 side-chain. In contrast, these residues are highly ordered in the Fab/dT3 complex, where Tyr H100 and Tyr H100A form intimate stacking interactions with DNA bases, and L92 forms the 5' end of the binding site. The structures suggest that HCDR3 is very flexible and adopts multiple conformations in the ligand-free state. These results are discussed in terms of induced fit and pre-existing equilibrium theories of ligand binding. Our results allow new interpretations of existing thermodynamic and mutagenesis data in terms of conformational entropy and the volume of conformational space accessible to HCDR3 in the ligand-free state. In the context of autoimmune disease, plasticity of the ligand-free antibody could provide a mechanism by which anti-DNA antibodies bind diverse host ligands, and thereby contribute to pathogenicity.

Nucleotide shuffling and ssDNA recognition in Oxytricha nova telomere end-binding protein complexes.

Sequence-specific protein recognition of single-stranded nucleic acids is critical for many fundamental cellular processes, such as DNA replication, DNA repair, transcription, translation, recombination, apoptosis and telomere maintenance. To explore the mechanisms of sequence-specific ssDNA recognition, we determined the crystal structures of 10 different non-cognate ssDNAs complexed with the Oxytricha nova telomere end-binding protein (OnTEBP) and evaluated their corresponding binding affinities (PDB ID codes 1PH1-1PH9 and 1PHJ). The thermodynamic and structural effects of these sequence perturbations could not have been predicted based solely upon the cognate structure. OnTEBP accommodates non-cognate nucleotides by both subtle adjustments and surprisingly large structural rearrangements in the ssDNA. In two complexes containing ssDNA intermediates that occur during telomere extension by telomerase, entire nucleotides are expelled from the complex. Concurrently, the sequence register of the ssDNA shifts to re-establish a more cognate-like pattern. This phenomenon, termed nucleotide shuffling, may be of general importance in protein recognition of single-stranded nucleic acids. This set of structural and thermodynamic data highlights a fundamental difference between protein recognition of ssDNA versus dsDNA.

Insights into ssDNA recognition by the OB fold from a structural and thermodynamic study of Sulfolobus SSB protein.

Information processing pathways such as DNA replication are conserved in eukaryotes and archaea and are significantly different from those found in bacteria. Single-stranded DNA-binding (SSB) proteins (or replication protein A, RPA, in eukaryotes) play a central role in many of these pathways. However, whilst euryarchaea have a eukaryotic-type RPA homologue, crenarchaeal SSB proteins appear much more similar to the bacterial proteins, with a single OB fold for DNA binding and a flexible C-terminal tail that is implicated in protein-protein interactions. We have determined the crystal structure of the SSB protein from the crenarchaeote Sulfolobus solfataricus to 1.26 A. The structure shows a striking and unexpected similarity to the DNA-binding domains of human RPA, providing confirmation of the close relationship between archaea and eukaryotes. The high resolution of the structure, together with thermodynamic and mutational studies of DNA binding, allow us to propose a molecular basis for DNA binding and define the features required for eukaryotic and archaeal OB folds.

Kinetic analysis of sequence-specific recognition of ssDNA by an autoantibody.

11F8 is a pathogenic monoclonal anti-ssDNA autoantibody isolated from a lupus prone mouse. Previous studies established that 11F8 is sequence-specific and identified the thermodynamic and kinetic basis for the specific recognition of ssDNA, and binding site mutations of a single-chain construct reveal that (Y32)LCDR1, (R31)HCDR1, (W33)HCDR1, (R98)HCDR3, (L97)HCDR3, and (Y100)HCDR3 are responsible for approximately 80% of the binding free energy. Here we evaluate the role of these residues along with a group of basic residues (K62, K64, R24, K52) within the context of the binding mechanism. Binding of 11F8 takes place in two steps. In the first step, the overall positive charge of the antigen binding site attracts the negatively charged DNA to form an encounter complex that is stabilized by two salt bridges and a hydrogen bond. The second step is a slow process in which minor conformational changes occur. During this step, aromatic side chains become desolvated, presumably through stacking interactions involving two thymine bases within the DNA recognition epitope. Although the stability of the complex arises primarily from interactions formed in the second step, sequence specificity results from interactions with residues involved in both steps. These studies also show that the way in which 11F8 achieves high affinity sequence-specific binding is more closely related to RNA binding proteins than those that bind DNA and point to strategies for disrupting DNA binding that could prove to be therapeutically useful.

Mutational analysis of a sequence-specific ssDNA binding lupus autoantibody.

11F8 is a murine anti-ssDNA monoclonal autoantibody isolated from a lupus prone autoimmune mouse. This mAb binds sequence specifically, and prior studies have defined the thermodynamic and kinetic basis for sequence-specific recognition of ssDNA (Ackroyd, P. C., et al. (2001) Biochemistry 40, 2911-2922; Beckingham, J. A. and Glick, G. D. (2001) Bioorg. Med. Chem. 9, 2243-2252). Here we present experiments designed to identify the residues on 11F8 that mediate sequence-specific, noncognate, and nonspecific recognition of ssDNA and their contribution to the overall binding thermodynamics. Site-directed mutagenesis of an 11F8 single-chain construct reveals that six residues within the complementarity determining regions of 11F8 account for ca. 80% of the binding free energy and that there is little cooperativity between these residues. Germline-encoded aromatic and hydrophobic side chains provides the basis for nonspecific recognition of single-stranded thymine nucleobases. Sequence-specific recognition is controlled by a tyrosine in the heavy chain along with a somatically mutated arginine residue. Our data show that the manner in which 11F8 achieves sequence-specific recognition more closely resembles RNA-binding proteins such as U1A than other types of nucleic acid binding proteins. In addition, comparing the primary sequence of 11F8 with clonally related antibodies that differ by less than five amino acids suggests that somatic mutations which confer sequence specificity may be a feature that distinguishes glomerulotrophic pathogenic anti-DNA from those that are benign.

Crystal structure of an antigen-binding fragment bound to single-stranded DNA

Antibodies to DNA are characteristic of the autoimmune disease systemic lupus erythematosus (SLE) and they also serve as models for the study of protein-DNA recognition. Anti-DNA antibodies often play an important role in disease pathogenesis by mediating kidney damage via antibody-DNA immune complex formation. The structural underpinnings of anti-DNA antibody pathogenicity and antibody-DNA recognition, however, are not well understood, due in part to the lack of direct, experimental three-dimensional structural information on antibody-DNA complexes. To address these issues for anti-single-stranded DNA antibodies, we have determined the 2.1 Å crystal structure of a recombinant Fab (DNA-1) in complex with dT5. DNA-1 was previously isolated from a bacteriophage Fab display library from the immunoglobulin repertoire of an SLE-prone mouse. The structure shows that DNA-1 binds oligo(dT) primarily by sandwiching thymine bases between Tyr side-chains, which allows the bases to make sequence-specific hydrogen bonds. The critical stacking Tyr residues are L32, L49, H100, and H100A, while His L91 and Asn L50 contribute hydrogen bonds. Comparison of the DNA-1 structure to other anti-nucleic acid Fab structures reveals a common ssDNA recognition module consisting of Tyr L32, a hydrogen bonding residue at position L91, and an aromatic side-chain from the tip of complementarity determining region H3. The structure also provides a framework for interpreting previously determined thermodynamics data, and this analysis suggests that hydrophobic desolvation might underlie the observed negative enthalpy of binding. Finally, Arg side-chains from complementarity determining region H3 appear to play a novel role in DNA-1. Rather than forming ion pairs with dT5, Arg contributes to oligo(dT) recognition by helping to maintain the structural integrity of the combining site. This result is significant because antibody pathogenicity is thought to be correlated to the Arg content of anti-DNA antibody hypervariable loops.

Kinetic mechanisms of rat polymerase β-ssDNA interactions. quantitative fluorescence stopped-flow analysis of the formation of the (pol β)16 and (pol β)5 ssDNA binding mode

Kinetics of rat polymerase β (pol β) binding to the single-stranded DNA (ssDNA) in the (pol β)16 and (pol β)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 β)16 binding mode, i.e. it encompasses the entire, total DNA-binding site of rat pol β, and with a 10-mer which binds the enzyme exclusively in the (pol β)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 β)16 binding mode occurs by a minimum three-step mechanism with the bimolecular binding step followed by two isomerizations:Rat polβ+ssDNA↔k−1k1(P16−ssDNA)1↔k−2k2(P16−ssDNA)2↔k−3k3(P16−ssDNA)3 A similar mechanism is observed in the formation of the (pol β)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 β)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 β, 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.