Steady-state kinetics of mouse DNA polymerase beta

A duplexed high-throughput mass spectrometry assay for bifunctional POLB polymerase and lyase activity

Polymerase β (POLB), with dual functionality as a lyase and polymerase, plays a critical role in the base excision repair (BER) pathway to maintain genomic stability. POLB knockout and rescue studies in BRCA1/2-mutant cancer cell lines revealed that inhibition of lyase and polymerase activity is required for the synthetic lethal interaction observed with PARP inhibitors, highlighting POLB as a valuable therapeutic target. Traditional biochemical assays to screen for enzyme inhibitors focus on a single substrate to product relationship and limit the comprehensive analysis of enzymes such as POLB that utilize multiple substrates or catalyze a multi-step reaction. This report describes the first high-throughput mass spectrometry-based screen to measure the two distinct biochemical activities of POLB in a single assay using a duplexed self-assembled monolayer desorption ionization (SAMDI) mass spectrometry methodology. A multiplexed assay for POLB dual enzymatic activities was developed optimizing for kinetically balanced conditions and a collection of 200,000 diverse small molecules was screened in the duplexed format. Small molecule modulators identified in the screen were confirmed in a traditional fluorescence-based polymerase strand-displacement assay and an orthogonal label-free binding assay using SAMDI affinity selection mass spectrometry (ASMS). This work demonstrates the flexibility of high-throughput mass spectrometry approaches in drug discovery and highlights a novel application of SAMDI technology that opens new avenues for multiplexed high-throughput screening.

Mouse models to explore the biological and organismic role of DNA polymerase beta

Gene knock-out (KO) mouse models for DNA polymerase beta (Polβ) revealed that loss of Polβ leads to neonatal lethality, highlighting the critical organismic role for this DNA polymerase. While biochemical analysis and gene KO cell lines have confirmed its biochemical role in base excision repair and in TET-mediated demethylation, more long-lived mouse models continue to be developed to further define its organismic role. The Polb-KO mouse was the first of the Cre-mediated tissue-specific KO mouse models. This technology was exploited to investigate roles for Polβ in V(D)J recombination (variable-diversity-joining rearrangement), DNA demethylation, gene complementation, SPO11-induced DNA double-strand break repair, germ cell genome stability, as well as neuronal differentiation, susceptibility to genotoxin-induced DNA damage, and cancer onset. The revolution in knock-in (KI) mouse models was made possible by CRISPR/cas9-mediated gene editing directly in C57BL/6 zygotes. This technology has helped identify phenotypes associated with germline or somatic mutants of Polβ. Such KI mouse models have helped uncover the importance of key Polβ active site residues or specific Polβ enzyme activities, such as the PolbY265C mouse that develops lupus symptoms. More recently, we have used this KI technology to mutate the Polb gene with two codon changes, yielding the PolbL301R/V303R mouse. In this KI mouse model, the expressed Polβ protein cannot bind to its obligate heterodimer partner, Xrcc1. Although the expressed mutant Polβ protein is proteolytically unstable and defective in recruitment to sites of DNA damage, the homozygous PolbL301R/V303R mouse is viable and fertile, yet small in stature. We expect that this and additional targeted mouse models under development are poised to reveal new biological and organismic roles for Polβ.

The Pol β variant containing exon α is deficient in DNA polymerase but has full dRP lyase activity

DNA polymerase (Pol) β is a key enzyme in base excision repair (BER), an important repair system for maintaining genomic integrity. We previously reported the presence of a Pol β transcript containing exon α (105-nucleotide) in normal and colon cancer cell lines. The transcript carried an insertion between exons VI and VII and was predicted to encode a ~42 kDa variant of the wild-type 39 kDa enzyme. However, little is known about the biochemical properties of the exon α-containing Pol β (exon α Pol β) variant. Here, we first obtained evidence indicating expression of the 42 kDa exon α Pol β variant in mouse embryonic fibroblasts. The exon α Pol β variant was then overexpressed in E. coli, purified, and characterized for its biochemical properties. Kinetic studies of exon α Pol β revealed that it is deficient in DNA binding to gapped DNA, has strongly reduced polymerase activity and higher Km for dNTP during gap-filling. On the other hand, the 5'-dRP lyase activity of the exon α Pol β variant is similar to that of wild-type Pol β. These results indicate the exon α Pol β variant is base excision repair deficient, but does conduct 5'-trimming of a dRP group at the gap margin. Understanding the biological implications of this Pol β variant warrants further investigation.

Translesion and Repair DNA Polymerases: Diverse Structure and Mechanism

The number of DNA polymerases identified in each organism has mushroomed in the past two decades. Most newly found DNA polymerases specialize in translesion synthesis and DNA repair instead of replication. Although intrinsic error rates are higher for translesion and repair polymerases than for replicative polymerases, the specialized polymerases increase genome stability and reduce tumorigenesis. Reflecting the numerous types of DNA lesions and variations of broken DNA ends, translesion and repair polymerases differ in structure, mechanism, and function. Here, we review the unique and general features of polymerases specialized in lesion bypass, as well as in gap-filling and end-joining synthesis.

Defective Nucleotide Release by DNA Polymerase β Mutator Variant E288K Is the Basis of Its Low Fidelity

DNA polymerases synthesize new DNA during DNA replication and repair, and their ability to do so faithfully is essential to maintaining genomic integrity. DNA polymerase β (Pol β) functions in base excision repair to fill in single-nucleotide gaps, and variants of Pol β have been associated with cancer. Specifically, the E288K Pol β variant has been found in colon tumors and has been shown to display sequence-specific mutator activity. To probe the mechanism that may underlie E288K's loss of fidelity, a fluorescence resonance energy transfer system that utilizes a fluorophore on the fingers domain of Pol β and a quencher on the DNA substrate was employed. Our results show that E288K utilizes an overall mechanism similar to that of wild type (WT) Pol β when incorporating correct dNTP. However, when inserting the correct dNTP, E288K exhibits a faster rate of closing of the fingers domain combined with a slower rate of nucleotide release compared to those of WT Pol β. We also detect enzyme closure upon mixing with the incorrect dNTP for E288K but not WT Pol β. Taken together, our results suggest that E288K Pol β incorporates all dNTPs more readily than WT because of an inherent defect that results in rapid isomerization of dNTPs within its active site. Structural modeling implies that this inherent defect is due to interaction of E288K with DNA, resulting in a stable closed enzyme structure.

Insertion of oxidized nucleotide triggers rapid DNA polymerase opening

A novel mechanism is unveiled to explain why a pro-mutagenic nucleotide lesion (oxidized guanine, 8-oxoG) causes the mammalian DNA repair polymerase-β (pol-β) to rapidly transition to an inactive open conformation. The mechanism involves unexpected features revealed recently in time-lapse crystallography. Specifically, a delicate water network associated with a lesion-stabilizing auxilliary product ion Mg(p) triggers a cascade of events that leads to poor active site geometry and the rupture of crucial molecular interactions between key residues in both the anti(8-oxoG:C) and syn(8-oxoG:A) systems. Once the base pairs in these lesioned systems are broken, dislocation of both Asp192 (a metal coordinating ligand) and the oxoG phosphate group (PO₄) interfere with the hydrogen bonding between Asp192 and Arg258, whose rotation toward Asp192 is crucial to the closed-to-open enzyme transition. Energetically, the lesioned open states are similar in energy to those of the corresponding closed complexes after chemistry, in marked contrast to the unlesioned pol-β anti(G:C) system, whose open state is energetically higher than the closed state. The delicate surveillance system offers a fundamental protective mechanism in the cell that triggers DNA repair events which help deter insertion of oxidized lesions.

Structural Mechanism for the Fidelity Modulation of DNA Polymerase λ

The mechanism of DNA polymerase (pol) fidelity is of fundamental importance in chemistry and biology. While high-fidelity pols have been well studied, much less is known about how some pols achieve medium or low fidelity with functional importance. Here we examine how human DNA polymerase λ (Pol λ) achieves medium fidelity by determining 12 crystal structures and performing pre-steady-state kinetic analyses. We showed that apo-Pol λ exists in the closed conformation, unprecedentedly with a preformed MgdNTP binding pocket, and binds MgdNTP readily in the active conformation in the absence of DNA. Since prebinding of MgdNTP could lead to very low fidelity as shown previously, it is attenuated in Pol λ by a hydrophobic core including Leu431, Ile492, and the Tyr505/Phe506 motif. We then predicted and demonstrated that L431A mutation enhances MgdNTP prebinding and lowers the fidelity. We also hypothesized that the MgdNTP-prebinding ability could stabilize a mismatched ternary complex and destabilize a matched ternary complex, and provided evidence with structures in both forms. Our results demonstrate that, while high-fidelity pols follow a common paradigm, Pol λ has developed specific conformations and mechanisms for its medium fidelity. Structural comparison with other pols also suggests that different pols likely utilize different conformational changes and microscopic mechanisms to achieve their catalytic functions with varying fidelities.

Structure and mechanism of DNA polymerase β

DNA polymerase (pol) β is a small eukaryotic DNA polymerase composed of two domains. Each domain contributes an enzymatic activity (DNA synthesis and deoxyribose phosphate lyase) during the repair of simple base lesions. These domains are termed the polymerase and lyase domains, respectively. Pol β has been an excellent model enzyme for studying the nucleotidyl transferase reaction and substrate discrimination at a molecular level. In this review, recent crystallographic studies of pol β in various liganded and conformational states during the insertion of right and wrong nucleotides as well as during the bypass of damaged DNA (apurinic sites and 8-oxoguanine) are described. Structures of these catalytic intermediates provide unexpected insights into mechanisms by which DNA polymerases enhance genome stability. These structures also provide an improved framework that permits computational studies to facilitate the interpretation of detailed kinetic analyses of this model enzyme.

Optimal and variant metal-ion routes in DNA polymerase β's conformational pathways

To interpret recent structures of the R283K mutant of human DNA repair enzyme DNA polymerase β (pol β) differing in the number of Mg(2+) ions, we apply transition path sampling (TPS) to assess the effect of differing ion placement on the transition from the open one-metal to the closed two-metal state. We find that the closing pathway depends on the initial ion position, both in terms of the individual transition states and associated energies. The energy barrier of the conformational pathway varies from 25 to 58 kJ/mol, compared to the conformational energy barrier of 42 kJ/mol for the wild-type pol β reported previously. Moreover, we find a preferred ion route located in the center of the enzyme, parallel to the DNA. Within this route, the conformational pathway is similar to that of the overall open to closed transition of pol β, but outside it, especially when the ion starts near active site residues Arg258 and Asp190, the conformational pathway diverges significantly. Our findings should apply generally to pol β, since R283K is relatively far from the active site; further experimental and computational work are required to confirm this. Our studies also underscore the common feature that less active mutants have less stable closed states than their open states, in marked contrast to the wild-type enzyme, where the closed state is significantly more stable than the open form.

Understanding the loss-of-function in a triple missense mutant of DNA polymerase β found in prostate cancer

Human DNA polymerase (pol) β is essential for base excision repair. We previously reported a triple somatic mutant of pol β (p.P261L/T292A/I298T) found in an early onset prostate tumor. This mutation abolishes polymerase activity, and the wild-type allele was not present in the tumor, indicating a complete deficiency in pol β function. The effect on polymerase activity is unexpected because the point mutations that comprise the triple mutant are not part of the active site. Herein, we demonstrate the mechanism of this loss-of-function. In order to understand the effect of the individual point mutations we biochemically analyzed all single and double mutants that comprise the triple mutant. We found that the p.I298T mutation is responsible for a marked instability of the triple mutant protein at 37°C. At room temperature the triple mutant’s low efficiency is also due to a decrease in the apparent binding affinity for the dNTP substrate, which is due to the p.T292A mutation. Furthermore, the triple mutant displays lower fidelity for transversions in vitro, due to the p.T292A mutation. We conclude that distinct mutations of the triple pol β mutant are responsible for the loss of activity, lower fidelity, and instability observed in vitro.

Coordinated processing of 3' slipped (CAG)n/(CTG)n hairpins by DNA polymerases β and δ preferentially induces repeat expansions

Expansion of CAG/CTG trinucleotide repeats causes certain familial neurological disorders. Hairpin formation in the nascent strand during DNA synthesis is considered a major path for CAG/CTG repeat expansion. However, the underlying mechanism is unclear. We show here that removal or retention of a nascent strand hairpin during DNA synthesis depends on hairpin structures and types of DNA polymerases. Polymerase (pol) δ alone removes the 3'-slipped hairpin using its 3'-5' proofreading activity when the hairpin contains no immediate 3' complementary sequences. However, in the presence of pol β, pol δ preferentially facilitates hairpin retention regardless of hairpin structures. In this reaction, pol β incorporates several nucleotides to the hairpin 3'-end, which serves as an effective primer for the continuous DNA synthesis by pol δ, thereby leading to hairpin retention and repeat expansion. These findings strongly suggest that coordinated processing of 3'-slipped (CAG)n/(CTG)n hairpins by polymerases δ and β on during DNA synthesis induces CAG/CTG repeat expansions.

Structures of dNTP intermediate states during DNA polymerase active site assembly

DNA polymerase and substrate conformational changes are essential for high-fidelity DNA synthesis. Structures of DNA polymerase (pol) β in complex with DNA show the enzyme in an "open" conformation. Subsequent to binding the nucleotide, the polymerase "closes" around the nascent base pair with two metals positioned for chemistry. However, structures of substrate/active site intermediates prior to closure are lacking. By destabilizing the closed complex, we determined unique ternary complex structures of pol β with correct and incorrect incoming nucleotides bound to the open conformation. These structures reveal that Watson-Crick hydrogen bonding is assessed upon initial complex formation. Importantly, nucleotide-bound states representing intermediate metal coordination states occur with active site assembly. The correct, but not incorrect, nucleotide maintains Watson-Crick hydrogen bonds during interconversion of these states. These structures indicate that the triphosphate of the incoming nucleotide undergoes rearrangement prior to closure, providing an opportunity to deter misinsertion and increase fidelity.

The structural basis of the kinetic mechanism of a gap-filling X-family DNA polymerase that binds Mg(2+)-dNTP before binding to DNA

DNA with single-nucleotide (1-nt) gaps can arise during various DNA processing events. These lesions are repaired by X-family DNA polymerases (PolXs) with high gap-filling activity. Some PolXs can bind productively to dNTPs in the absence of DNA and fill these 1-nt gaps. Although PolXs have a crucial role in efficient gap filling, currently, little is known of the kinetic and structural details of their productive dNTP binding. Here, we show that Thermus thermophilus HB8 PolX (ttPolX) had strong binding affinity for Mg(2+)-dNTPs in the absence of DNA and that it follows a Theorell-Chance (hit-and-run) mechanism with nucleotide binding first. Comparison of the intermediate crystal structures of ttPolX in a binary complex with dGTP and in a ternary complex with 1-nt gapped DNA and Mg(2+)-ddGTP revealed that the conformation of the incoming nucleotide depended on whether or not DNA was present. Furthermore, the Lys263 residue located between two guanosine conformations was essential to the strong binding affinity of the enzyme. The ability to bind to either syn-dNTP or anti-dNTP and the involvement of a Theorell-Chance mechanism are key aspects of the strong nucleotide-binding and efficient gap-filling activities of ttPolX.

An abridged transition state model to derive structure, dynamics, and energy components of DNA polymerase β fidelity

We show how a restricted reaction surface can be used to facilitate the calculation of biologically important contributions of active site geometries and dynamics to DNA polymerase fidelity. Our analysis, using human DNA polymerase beta (pol β), is performed within the framework of an electrostatic linear free energy response (EFER) model. The structure, dynamics, and energetics of pol β-DNA-dNTP interactions are computed between two points on the multidimensional reaction free energy surface. "Point 1" represents a ground state activation intermediate (GSA), which is obtained by deprotonating the terminal 3'OH group of the primer DNA strand. "Point 2" is the transition state (PTS) for the attack of the 3'O(-) (O(nuc)) on the P(α) atom of dNTP substrate, having the electron density of a dianionic phosphorane intermediate. Classical molecular dynamics simulations are used to compute the geometric and dynamic contributions to the formation of right and wrong O(nuc)-P chemical bonds. Matched dCTP·G and mismatched dATP·G base pairs are used to illustrate the analysis. Compared to the dCTP·G base pair, the dATP·G mismatch has fewer GSA configurations with short distances between O(nuc) and P(α) atoms and between the oxygen in the scissile P-O bond (O(lg)) and the nearest structural water. The thumb subdomain conformation of the GSA complex is more open for the mismatch, and the H-bonds in the mispair become more extended during the nucleophilic attack than in the correct pair. The electrostatic contributions of pol β and DNA residues to catalysis of the right and wrong P-O(nuc) bond formation are 5.3 and 3.1 kcal/mol, respectively, resulting in an 80-fold contribution to fidelity. The EFER calculations illustrate the considerable importance of Arg183 and an O(lg)-proximal water molecule to pol β fidelity.

DNA polymerase beta is critical for genomic stability of sperm cells

Maintaining genome integrity in germ cells is important, given that the germ cells produce the next generation of offspring. Base excision repair is a DNA repair pathway that is responsible for the repair of most endogenous DNA damage. A key enzyme that functions in this repair pathway is DNA polymerase beta (Pol β). We previously used conditional gene targeting to engineer mice with sperm deleted of the Pol B gene, which encodes Pol β. We characterized mutagenesis in the sperm of these mice and compared it to wild-type and mice heterozygous for the Pol B gene. We found that sperm obtained that were heterozygously or homozygously deleted of the Pol B gene exhibited increased mutation frequencies compared to wild-type sperm. We identified an increase in transition mutations in both heterozygously and homozygously deleted sperm, and the types of mutations induced suggest that a polymerase other than Pol β functions in its absence. Interestingly, most of the transversions we observed were induced only in heterozygous, compared with wild-type sperm. Our results suggest that haploinsufficiency of Pol β leads to increased frequencies and varieties of mutations. Our study also shows that Pol β is critical for genome stability in the germline.

Altered order of substrate binding by DNA polymerase X from African Swine Fever virus

A sequential ordered substrate binding established previously for several DNA polymerases is generally extended to all DNA polymerases, and the characterization of novel polymerases is often based on the assumption that the enzymes should productively bind DNA substrate first, followed by template-directed dNTP binding. The comprehensive kinetic study of DNA polymerase X (Pol X) from African swine fever virus reported here is the first analysis of the substrate binding order performed for a low-fidelity DNA polymerase. A classical steady-state kinetic approach using substrate analogue inhibition assays demonstrates that Pol X does not follow the bi-bi ordered mechanism established for other DNA polymerases. Further, using isotope-trapping experiments and stopped-flow fluorescence assays, we show that Pol X can bind Mg²⁺·dNTPs in a productive manner in the absence of DNA substrate. We also show that DNA binding to Pol X, although rapid, may not always be productive. Furthermore, we show that binding of Mg²⁺·dNTP to Pol X facilitates subsequent formation of the catalytically competent Pol X·DNA·dNTP ternary complex, whereas DNA binding prior to dNTP binding brings the enzyme into a nonproductive conformation where subsequent nucleotide substrate binding is hindered. Together, our results suggest that Pol X prefers an ordered sequential mechanism with Mg²⁺·dNTP as the first substrate.

Decreased mutant frequency in embryonic brain of DNA polymerase beta null mice

DNA polymerase beta (Polbeta) knockout mouse embryos exhibit extensive apoptosis in postmitotic neuronal cells and die immediately after birth. In contrast, no apoptosis has been observed in other tissues as well as liver in the mutant embryos. To study the relationship of Polbeta deficiency and mutagenesis during development and neurogenesis, we examined spontaneous mutations in Polbeta null (Polbeta-/-) and wild-type (Polbeta+/+) mouse embryos, by using the transgenic mutation detection system consisting of a pSSW shuttle vector with the Escherichia coli rpsL reporter gene. Unexpectedly, we found a significant decrease in the mutant frequency of Polbeta-/- brain (1.63+/-0.67x10(-5)) compared with wild-type controls (3.12+/-0.83x10(-5)) (P<0.001). In contrast, no such difference was found between livers from Polbeta-/- (0.92+/-0.38x10(-5)) and wild-type (0.71+/-0.31x10(-5)) embryos. Analysis of mutation spectra revealed that mutations in brains from the two genotypes were almost exclusively single-base deletions and that these sites fell within runs of 2-6 identical bases and a two base repeat in the rpsL sequence, while mutations in the corresponding livers contained base substitutions as well as single-base deletions. Taken together with the extensive neuronal apoptosis associated with Polbeta deficiency, we suggest that the lower mutant frequency observed in Polbeta-/- embryonic brain may be caused by the elimination of neuronal cells with unrepaired DNA damage through apoptosis.

Activities and mechanism of DNA polymerase beta

DNA polymerase beta plays an essential role in the base excision repair pathway necessary to cleanse the genome of simple base lesions and abasic sites. Abasic sites arise in DNA from spontaneous base loss (depurination) and DNA-damage specific glycosylases that hydrolyze the N-glycosidic bond between the deoxyribose and the damaged base. DNA polymerase beta contributes two enzymatic activities: DNA synthesis and deoxyribose-phosphate removal through nucleotidyl transferase and lyase mechanisms, respectively. The active site for each of these activities resides on a distinct domain of the protein: 31-kDa polymerase domain and amino-terminal 8-kDa lyase domain. The simple organization of each domain and the ability to assay each activity have hastened our understanding of the faithful replication of DNA during repair synthesis and the flux of intermediates through single nucleotide base excision repair and its alternate pathways.

Determinants in nuclease specificity of Ape1 and Ape2, human homologues of Escherichia coli exonuclease III

Abasic sites and non-conventional 3'-ends, e.g. 3'-oxidized fragments (including 3'-phosphate groups) and 3'-mismatched nucleotides, arise at significant frequency in the genome due to spontaneous decay, oxidation or replication errors. To avert the potentially mutagenic or cytotoxic effects of these chromosome modifications/intermediates, organisms are equipped with apurinic/apyrimidinic (AP) endonucleases and 3'-nucleases that initiate repair. Ape1, which shares homology with Escherichia coli exonuclease III (ExoIII), is the major abasic endonuclease in mammals and an important, yet selective, contributor to 3'-end processing. Mammals also possess a second protein (Ape2) with sequence homology to ExoIII, but this protein exhibits comparatively weak AP site-specific and 3'-nuclease activities. Prompted by homology modeling studies, we found that substitutions in the hydrophobic pocket of Ape1 (comprised of F266, W280 and L282) reduce abasic incision potency about fourfold to 450,000-fold, while introduction of an ExoIII-like pocket into Ape2 enhances its AP endonuclease function. We demonstrate that mutations at F266 and W280 of Ape1 increase 3' to 5' DNA exonuclease activity. These results, coupled with prior comparative sequence analysis, indicate that this active-site hydrophobic pocket influences the substrate specificity of a diverse set of sequence-related proteins possessing the conserved four-layered alpha/beta-fold. Lastly, we report that wild-type Ape1 excises 3'-mismatched nucleotides at a rate up to 374-fold higher than correctly base-paired nucleotides, depending greatly on the structure and sequence of the DNA substrate, suggesting a novel, selective role for the human protein in 3'-mismatch repair.

Kinetic study of various binding modes between human DNA polymerase beta and different DNA substrates by surface-plasmon-resonance biosensor

The interaction of a series of DNA substrates with human DNA polymerase beta has been studied in real time by using a surface-plasmon-resonance (SPR) biosensor technique. We have prepared the sensor surfaces comprising different DNA targets, including single-stranded DNA, blunt-end double-stranded DNA, gapped DNA and DNA template-primer duplexes containing various mismatches at different positions. The binding and dissociation of polymerase beta at the DNA-modified surfaces was measured in real time, and the kinetics profiles of polymerase-DNA interaction were analysed using various physical models. The results showed that polymerase beta binding to single-stranded DNA (K(A)=1.25 x 10(8) M(-1); where K(A) is the equilibrium affinity constant) was thermodynamically more favourable than to blunt-end DNA duplex (K(A)=7.56x10(7) M(-1)) or gapped DNA (K(A)=8.53x10(7) M(-1)), with a single binding mode on each DNA substrate. However, polymerase beta bound to DNA template-primer duplexes (15 bp with a 35 nt overhang) at two sites, presumably one at the single-strand overhang and the other at the 3'-end of the primer. When the DNA duplex was fully matched, most of the polymerase beta (83%) bound to the template-primer duplex region. The introduction of different numbers of mismatches near the 3'-end of the primer caused the binding affinity and the fraction of polymerase beta bound at the duplex region to decrease 8-58-fold and 15-40%, respectively. On the other hand, the affinity of polymerase beta for the single-strand overhang remained unchanged while the fraction bound to the single-strand region increased by 15-40%. The destabilizing effect of the mismatches was due to both a decrease in the rate of binding and an increase in the rate of dissociation for polymerase beta.

DNA structure and aspartate 276 influence nucleotide binding to human DNA polymerase beta. Implication for the identity of the rate-limiting conformational change

Structures of DNA polymerase (pol) beta bound to single-nucleotide gapped DNA had revealed that the lyase and pol domains form a "doughnut-shaped" structure altering the dNTP binding pocket in a fashion that is not observed when bound to non-gapped DNA. We have investigated dNTP binding to pol beta-DNA complexes employing steady-state and pre-steady-state kinetics. Although pol beta has a kinetic scheme similar to other DNA polymerases, polymerization by pol beta is limited by at least two partially rate-limiting steps: a conformational change after dNTP ground-state binding and product release. The equilibrium binding constant, K(d)((dNTP)), decreased and the insertion efficiency increased with a one-nucleotide gapped DNA substrate, as compared with non-gapped DNA. Valine substitution for Asp(276), which interacts with the base of the incoming nucleotide, increased the binding affinity for the incoming nucleotide indicating that the negative charge contributed by Asp(276) weakens binding and that an interaction between residue 276 with the incoming nucleotide occurs during ground-state binding. Since the interaction between Asp(276) and the nascent base pair is observed only in the "closed" conformation of pol beta, the increased free energy in ground-state binding for the mutant suggests that the subsequent rate-limiting conformational change is not the "open" to "closed" structural transition, but instead is triggered in the closed pol conformation.

Structural design of a eukaryotic DNA repair polymerase: DNA polymerase beta

DNA polymerase beta, the smallest eukaryotic DNA polymerase, is designed to synthesize DNA in short DNA gaps during DNA repair. It is composed of two specialized domains that contribute essential enzymatic activities to base excision repair (BER). Its amino-terminal domain possesses a lyase activity necessary to remove the 5'-deoxyribose phosphate (dRP) intermediate generated during BER. Removal of the dRP moiety is often the rate-limiting step during BER. Failure to remove this group may initiate alternate BER pathways. The larger polymerase domain has nucleotidyl transferase activity. This domain has a modular organization with sub-domains that bind duplex DNA, catalytic metals, and the correct nucleoside triphosphate in a template-dependent manner. X-ray crystal structures of DNA polymerase beta, with and without bound substrates, has inferred that domain, sub-domain, and substrate conformational changes occur upon ligand binding. Many of these conformational changes are distinct from those observed in structures of other DNA polymerases. This review will examine the structural aspects of DNA polymerase beta that facilitate its role in BER.

The fidelity of DNA polymerase beta during distributive and processive DNA synthesis

During base excision repair, DNA polymerase beta fills 1-6-nucleotide gaps processively, reflecting a contribution of both its 8- and 31-kDa domains to DNA binding. Here we report the fidelity of pol beta during synthesis to fill gaps of 1, 5, 6, or >300 nucleotides. Error rates during distributive synthesis by recombinant rat and human polymerase (pol) beta with a 390-base gap are similar to each other and to previous values with pol beta purified from tissues. The base substitution fidelity of human pol beta when processively filling a 5-nucleotide gap is similar to that with a 361-nucleotide gap, but "closely-spaced" substitutions are produced at a rate at least 60-fold higher than for distributive synthesis. Base substitution fidelity when filling a 1-nucleotide gap is higher than when filling a 5-nucleotide gap, suggesting a contribution of the 8-kDa domain to the dNTP binding pocket and/or a difference in base stacking or DNA structure imposed by pol beta. Nonetheless, 1-nucleotide gap filling is inaccurate, even generating complex substitution-addition errors. Finally, the single-base deletion error rate during processive synthesis to fill a 6-nucleotide gap is indistinguishable from that of distributive synthesis to fill a 390-nucleotide gap. Thus the mechanism of processivity by pol beta does not allow the enzyme to suppress template misalignments.

Transition between different binding modes in rat DNA polymerase beta-ssDNA complexes

Interactions of rat DNA polymerase beta with a single-stranded (ss) DNA have been studied using the quantitative fluorescence titration technique. Examination of the fluorescence changes accompanying the binding, as a function of the thermodynamically rigorous binding density of rat pol beta-ssDNA complexes, reveals the existence of two binding phases. In the first high affinity phase, rat pol beta forms a complex with the ssDNA in which 16 nucleotides are occluded by the enzyme. In the second low affinity phase, a transition to a complex where the polymerase occludes only five nucleotides occurs. Thus, the data show that rat pol beta binds the ssDNA in two binding modes which differ in the number of occluded nucleotides. We designate the first complex as the (pol beta)16 binding mode and the second as the (pol beta)5 binding mode. The formation of the (pol beta)16 and (pol beta)5 modes has been fully confirmed in experiments with short ssDNA oligomers, a 16mer which can form either the (pol beta)16 or the (pol beta)5 mode, and a 10mer which can form only the (pol beta)5 mode. Binding of rat pol beta to the ssDNA has been analyzed using a statistical thermodynamic model which accounts for the existence of the two binding modes, cooperative interactions, and the overlap of potential binding sites. The results indicate that the 8 kDa domain of the enzyme is involved in ssDNA binding in both modes. Binding studies show that an isolated 8 kDa domain has the same intrinsic affinity for the ssDNA as the entire intact enzyme in its (pol beta)5 mode. However, the site size of the 8 kDa domain-ssDNA complex is ten nucleotides, suggesting that the formation of the (pol beta)5 mode is accompanied by a significant conformational transition of the intact protein. A higher intrinsic affinity, a higher net number of ions released, and a lower fluorescence change accompanying the formation of the (pol beta)16 than the (pol beta)5 mode indicate that the 31 kDa catalytic domain of the enzyme interacts with the ssDNA only in the (pol beta)16 mode. The significance of these results for understanding the functioning of rat pol beta in the DNA metabolism is discussed.

Kinetics at a multifunctional RNA active site

Kinetics of a self-capping RNA, Iso6, have been investigated to constrain the catalytic mechanism. The role of phosphates has been examined by varying the number of phosphates on the nucleophilic attacking group or on the RNA. While the number of phosphates in the nucleophile affects capping kinetics, only KM but not kcat is altered. The KM values for GMP, GDP, GTP and ppppG are 200, 11, 13 and 31 microM, respectively. A reaction product, pyrophosphate, is also found to strongly inhibit RNA activities through a competitive exchange mechanism with an apparent Ki of 200 nM. Uniquely strong binding of pyrophosphate supports the idea that capping originated by utilization of the initial pyrophosphate leaving group site for capping nucleophiles. In contrast to the nucleophile phosphate, change of 5' RNA terminus from triphosphate to tetraphosphate enhances the overall rate and kcat by 40%, with little effect on KM. Thus, only the leaving group appears to affect the rate of the chemical transformation. We propose two possible mechanisms that explain this apparent rate-limiting chemical step, either dissociation of pyrophosphate to form a metaphosphate monoester intermediate or formation of a circular phosphoramidate intermediate, using an internal RNA nitrogenous group. A single essential Ca ion is required for all activities.

DNA polymerase beta: effects of gapped DNA substrates on dNTP specificity, fidelity, processivity and conformational changes

Pre-steady-state kinetic analysis was used to compare the catalytic properties of DNA polymerase beta (Pol beta) for single-base gap-filling and regular duplex DNA synthesis. The rate of polymerization (kpol) and the apparent equilibrium dissociation constant of dNTP (Kd) were determined with single-nucleotide gapped DNA substrates for all four possible correct base pairs and twelve possible incorrect base pairs, and the results were compared with those obtained previously with non-gapped primer/template duplex DNA substrates. For correct dNTP incorporation, the use of single-nucleotide gapped DNA led to significant decreases in the Kd of dNTP. Although kpol was little affected, the catalytic efficiency kpol/Kd increased significantly owing to the decreases in Kd. In contrast, for incorrect dNTP incorporation, the use of single-nucleotide gapped DNA substrates did not affect the Kd of dNTP appreciably but caused the kpol (and thus kpol/Kd) for incorrect dNTP incorporation to increase. As a consequence the fidelity of Pol beta was not significantly affected by the use of single-nucleotide gapped DNA substrates. In addition we show that under processive polymerization conditions the processivity of Pol beta increases in the gap-filling synthesis owing to a decreased rate of DNA dissociation. Finally, with a single-nucleotide gapped DNA substrate the rate-limiting conformational change step before chemistry was also observed. However, the preceding fast conformational change observed with duplex DNA substrates was not clearly detected. A possible cause is that in the complex with the gapped DNA, the 8 kDa N-terminal domain of Pol beta already exists in a closed conformation. This interpretation was supported by tryptic digestion experiments.

Replication of template-primers containing propanodeoxyguanosine by DNA polymerase beta. Induction of base pair substitution and frameshift mutations by template slippage and deoxynucleoside triphosphate stabilization

Propanodeoxyguanosine (PdG) is a model for several unstable exocyclic adducts formed by reaction of DNA with bifunctional carbonyl compounds generated by lipid peroxidation. The effect of PdG on DNA synthesis by human DNA polymerase beta was evaluated using template-primers containing PdG at defined sites. DNA synthesis was conducted in vitro and the products were analyzed by polyacrylamide gel electrophoresis and DNA sequencing. The extent of PdG bypass was low and the products comprised a mixture of base pair substitutions and deletions. Sequence analysis of all of the products indicated that the deoxynucleoside monophosphate incorporated "opposite" PdG was complementary to the base 5' to PdG in the template strand. These findings are very similar to recent results of Efrati et al. (Efrati, E., Tocco, G., Eritja, R., Wilson, S. H., and Goodman, M. F. (1997) J. Biol. Chem. 272, 2559-2569) obtained in DNA replication of template-primers containing abasic sites and suggest that PdG is a non-informational lesion when acted upon by polymerase (pol) beta. In addition to base pair substitutions and one- or two-base deletions, a four-base deletion was observed and the mechanism of its formation was probed by site-specific mutagenesis. The results indicated that this deletion occurred by one-base insertion followed by slippage to form a four-base loop followed by extension. All of the observations on pol beta replication of PdG-containing template-primers are consistent with a mechanism of lesion bypass that involves template slippage and dNTP stabilization followed by deoxynucleoside monophosphate incorporation and extension. This mechanism of PdG bypass is completely different than that previously determined for the Klenow fragment of DNA polymerase I and is consistent with recent structural models for DNA synthesis by pol beta.

Incorporation of the guanosine triphosphate analogs 8-oxo-dGTP and 8-NH2-dGTP by reverse transcriptases and mammalian DNA polymerases

We have measured the efficiencies of utilization of 8-oxo-dGTP and 8-NH2-dGTP by human immunodeficiency virus type 1 and murine leukemia virus reverse transcriptases and compared them to those of DNA polymerases alpha and beta. Initially, we carried out primer extension reactions in the presence of dGTP or a dGTP analog and the remaining three dNTPs using synthetic DNA and RNA templates. These assays revealed that, in general, 8-NH2-dGTP is incorporated and extended more efficiently than 8-oxo-dGTP by all enzymes tested. Second, we determined rate constants for the incorporation of each analog opposite a template cytidine residue using steady state single nucleotide extension kinetics. Our results demonstrated the following. 1) Both reverse transcriptases incorporate the nucleotide analogs; discrimination against their incorporation is a function primarily of Km or Vmax depending on the analog and the enzyme. 2) Discrimination against the analogs is more stringent with the DNA template than with a homologous RNA template. 3) Polymerase alpha exhibits a mixed kinetic phenotype, with a large discrimination against 8-oxo-dGTP but a comparatively higher preference for 8-NH2-dGTP. 4) Polymerase beta incorporates both analogs efficiently; there is no discrimination with respect to Km and a significantly lower discrimination with respect to Vmax when compared with the other polymerases.

A genetic system to identify DNA polymerase beta mutator mutants

DNA polymerase beta (pol beta) is a 39-kDa protein that functions in DNA repair processes in mammalian cells. As a first step toward understanding mechanisms of polymerase fidelity, we developed a genetic method to identify mammalian pol beta mutator mutants. This screen takes advantage of a microbial genetics assay and the ability of rat pol beta to substitute for Escherichia coli DNA polymerase I in DNA replication in vivo. Using this screen, we identified 13 candidate pol beta mutator mutants. Three of the candidate mutator mutants were further characterized in vivo and shown to confer an increased spontaneous mutation frequency over that of wild-type pol beta to our bacterial strain. Purification and subsequent analysis of one of our putative mutator proteins, the pol beta-14 protein, showed that it possesses intrinsic mutator activity in four different assays that measure the fidelity of DNA synthesis. Therefore, residue 265, which is altered in pol beta-14 and another of our mutant proteins, pol beta-166, is probably critical for accurate DNA synthesis by pol beta. Thus, our genetic method of screening for pol beta mutator mutants is useful in identifying active mammalian DNA polymerase mutants that encode enzymes that catalyze DNA synthesis with altered fidelity compared with the wild-type pol beta enzyme.

dNTP binding to HIV-1 reverse transcriptase and mammalian DNA polymerase beta as revealed by affinity labeling with a photoreactive dNTP analog

The dNTP binding pocket of human immunodeficiency virus type 1 reverse transcriptase (RT) and DNA polymerase beta (beta-pol) were labeled using a photoreactive analog of dCTP, exo-N-[beta-(p-azidotetrafluorobenzamido)-ethyl]-deoxycytidine-5'- triphosphate (FABdCTP). Two approaches of photolabeling were utilized. In one approach, photoreactive FABdCTP and radiolabeled primer-template were UV-irradiated in the presence of each enzyme and resulted in polymerase radiolabeling. In an alternate approach, FABdCTP was first UV-cross-linked to enzyme; subsequently, radiolabeled primer-template was added, and the enzyme-linked dCTP analog was incorporated onto the 3'-end of the radiolabeled primer. The results showed strong labeling of the p66 subunit of RT, with only minor labeling of p51. No difference in the intensity of cross-linking was observed with either approach. FABdCTP cross-linking was increased in the presence of a dideoxyterminated primer-template with RT, but not with beta-pol, suggesting a significant influence of prior primer-template binding on dNTP binding for RT. Mutagenesis of beta-pol residues observed to interact with the incoming dNTP in the crystal structure of the ternary complex resulted in labeling consistent with kinetic characterization of these mutants and indicated specific labeling of the dNTP binding pocket.

Recognition by viral and cellular DNA polymerases of nucleosides bearing bases with nonstandard hydrogen bonding patterns

The ability of DNA polymerases (pols) to catalyze the template-directed synthesis of duplex oligonucleotides containing a nonstandard Watson-Crick base pair between a nucleotide bearing a 5-(2,4-diaminopyrimidine) heterocycle (d kappa) and a nucleotide bearing either deoxyxanthosine (dX) or N1-methyloxoformycin B (pi) has been investigated. The kappa-X and kappa-pi base pairs are jointed by a hydrogen bonding pattern different from and exclusive of those joining the AT and GC base pairs. Reverse transcriptase from human immunodeficiency virus type 1 (HIV-1) incorporates dXTP into an oligonucleotide opposite d kappa in a template with good fidelity. With lower efficiency and fidelity, HIV-1 reverse transcriptase also incorporates d kappa TP opposite dX in the template. With d pi in the template, no incorporation of d kappa TP was observed with HIV reverse transcriptase. The Klenow fragment of DNA pol I from Escherichia coli does not incorporate d kappa TP opposite dX in a template but does incorporate dXTP opposite d kappa. Bovine DNA pols alpha, beta, and epsilon accept neither dXTP opposite d kappa nor d kappa TP opposite d pi. DNA pols alpha and epsilon (but not beta) incorporate d kappa TP opposite dX in a template but discontinue elongation after incorporating a single additional base. These results are discussed in light of the crystal structure for pol beta and general considerations of how polymerases must interact with an incoming base pair to faithfully copy genetic information.

Specific inhibition of DNA polymerase beta by its 14 kDa domain: role of single- and double-stranded DNA binding and 5'-phosphate recognition

DNA polymerase beta (beta-polymerase) has been implicated in short-patch DNA synthesis in the DNA repair pathway known as base excision repair. The native 39 kDa enzyme is organized into four structurally and functionally distinct domains. In an effort to examine this enzyme as a potential therapeutic target, we analyzed the effect of various beta-polymerase domains on the activity of the enzyme in vitro. We show that the 14 kDa N-terminal segment of beta-polymerase, which binds to both single- and double-stranded DNA, but lacks DNA polymerase activity, inhibits beta-polymerase activity in vitro. Most importantly, the 8, 27 and 31 kDa domains of beta-polymerase do not inhibit beta-polymerase activity, demonstrating that the inhibition by the 14 kDa domain is specific. The inhibition of beta-polymerase activity in vitro is abolished by increasing the concentrations of both of the substrates (template-primer and deoxynucleoside triphosphate). In contrast, an in vitro base excision repair assay is inhibited in a domain specific manner by the 14 kDa domain even in the presence of saturating substrates. The inhibition of beta-polymerase activity by the 14 kDa domain appears specific to beta-polymerase as this domain does not inhibit either mammalian DNA polymerase alpha or Escherichia coli polymerase I (Klenow fragment). These data suggest that the 14 kDa domain could be used as a potential inhibitor of intracellular beta-polymerase and that it may provide a means for sensitizing cells to therapeutically relevant DNA damaging agents.

Crystal structure of rat DNA polymerase beta: evidence for a common polymerase mechanism

Structures of the 31-kilodalton catalytic domain of rat DNA polymerase beta (pol beta) and the whole 39-kilodalton enzyme were determined at 2.3 and 3.6 angstrom resolution, respectively. The 31-kilodalton domain is composed of fingers, palm, and thumb subdomains arranged to form a DNA binding channel reminiscent of the polymerase domains of the Klenow fragment of Escherichia coli DNA polymerase I, HIV-1 reverse transcriptase, and bacteriophage T7 RNA polymerase. The amino-terminal 8-kilodalton domain is attached to the fingers subdomain by a flexible hinge. The two invariant aspartates found in all polymerase sequences and implicated in catalytic activity have the same geometric arrangement within structurally similar but topologically distinct palms, indicating that the polymerases have maintained, or possibly re-evolved, a common nucleotidyl transfer mechanism. The location of Mn2+ and deoxyadenosine triphosphate in pol beta confirms the role of the invariant aspartates in metal ion and deoxynucleoside triphosphate binding.

Aphidicolin-resistant Chinese hamster ovary cells possess altered DNA polymerases of the alpha-family

DNA polymerases alpha, delta and epsilon were partially purified and characterized from a wild type Chinese hamster ovary (CHO) cell line and from two aphidicolin-resistant mutant CHO cell lines (BR5 and BR5-20a). The main characteristics of the wild type and mutant DNA polymerases were compared in order to reveal differences in the properties of these enzymes responsible for the aphidicolin resistance of the mutant cell lines. Pol alpha's of the mutant cells show: (1) in vitro aphidicolin-resistance, (2) 1.5-3-fold lower specific activity than that of the wild type, (3) resistance to cytosine and adenosine arabinofuranoside 5'-triphosphate (araCTP and araATP), (4) altered resistance to carbonyldiphosphonate (COMDP) and to alkylphenyl nucleotide analogs (butylphenyl-dGTP and butylanilino-dATP), and (5) lower activity on poly(dA)/oligo(dT) template-primers. These changes in the biochemical properties of this enzyme may result from a mutation in pol alpha gene. Pol epsilon and delta of the mutant cells did not differ from the wild type enzymes with respect to aphidicolin resistance. However, the specific activities of these mutant enzymes were much higher (1.5 to 8-fold for pol epsilon and 4 to 20-fold for pol delta) in comparison to that of the wild type enzymes. Also in comparison to the wild type enzymes, the mutant pol epsilon showed changes in the template-primer preference; whereas the mutant pol delta was found to have altered sensitivity to other inhibitors. These results indicate that pol epsilon and pol delta are also altered as a secondary effect of mutation in the aphidicolin-resistant cells. It is suggested that these altered properties of the DNA pols of the alpha family are responsible for the in vivo aphidicolin resistance of the mutant cells.

2.3 A crystal structure of the catalytic domain of DNA polymerase beta

The crystal structure of the catalytic domain of rat DNA polymerase beta (pol beta) has been determined at 2.3 A resolution and refined to an R factor of 0.22. The mixed alpha/beta protein has three subdomains arranged in an overall U shape reminiscent of other polymerase structures. The folding topology of pol beta, however, is unique. Two divalent metals bind near three aspartic acid residues implicated in the catalytic activity. In the presence of Mn2+ and dTTP, interpretable electron density is seen for two metals and the triphosphate, but not the deoxythymidine moiety. The principal interaction of the triphosphate moiety is with the bound divalent metals.

Requirement for the polymerization and 5'-->3' exonuclease activities of DNA polymerase I in initiation of DNA replication at oriK sites in the absence of RecA in Escherichia coli rnhA mutants

In previous studies, we found that the requirement for RecA protein in constitutive stable DNA replication (cSDR) can be bypassed by derepression of the LexA regulon and that DNA polymerase I (DNA PolI) is essential for this Rip (RecA-independent process) pathway of cSDR (Y. Cao, R. R. Rowland, and T. Kogoma, J. Bacteriol. 175:7247-7253, 1993). In this study, the role of DNA PolI in the Rip pathway was further examined. By using F' plasmids carrying different parts of the polA gene, a series of complementation tests was carried out to investigate the requirement for the three enzymatic activities, polymerization, 3'-->5' exonuclease, and 5'-->3' exonuclease activities, of DNA PolI. The result indicated that both the 5'-->3' exonuclease and polymerization activities of DNA PolI are essential for bypassing the requirement for RecA in cSDR but that the 3'-->5' exonuclease activity can be dispensed with. Complementation experiments with rat DNA Pol beta also supported the hypothesis that a nick translation activity is probably involved in cSDR in the absence of RecA. An analysis of DNA synthesis suggested that DNA PolI is involved in the initiation but not the elongation stage of cSDR. Moreover, the dnaE293(Ts) mutation was shown to render the bypass replication temperature sensitive despite the presence of active DNA PolI, suggesting that DNA PolIII is responsible for the elongation stage of the Rip pathway. A model which describes the possible roles of RecA in cSDR and the possible function of DNA PolI in the Rip pathway is proposed.

DNA replication defect in Salmonella typhimurium mutants lacking the editing (epsilon) subunit of DNA polymerase III

In Salmonella typhimurium, dnaQ null mutants (encoding the epsilon editing subunit of DNA polymerase III [Pol III]) exhibit a severe growth defect when the genetic background is otherwise wild type. Suppression of the growth defect requires both a mutation affecting the alpha (polymerase) subunit of DNA polymerase III and adequate levels of DNA polymerase I. In the present paper, we report on studies that clarify the nature of the physiological defect imposed by the loss of epsilon and the mechanism of its suppression. Unsuppressed dnaQ mutants exhibited chronic SOS induction, indicating exposure of single-stranded DNA in vivo, most likely as gaps in double-stranded DNA. Suppression of the growth defect was associated with suppression of SOS induction. Thus, Pol I and the mutant Pol III combined to reduce the formation of single-stranded DNA or accelerate its maturation to double-stranded DNA. Studies with mutants in major DNA repair pathways supported the view that the defect in DNA metabolism in dnaQ mutants was at the level of DNA replication rather than of repair. The requirement for Pol I was satisfied by alleles of the gene for Pol I encoding polymerase activity or by rat DNA polymerase beta (which exhibits polymerase activity only). Consequently, normal growth is restored to dnaQ mutants when sufficient polymerase activity is provided and this compensatory polymerase activity can function independently of Pol III. The high level of Pol I polymerase activity may be required to satisfy the increased demand for residual DNA synthesis at regions of single-stranded DNA generated by epsilon-minus pol III. The emphasis on adequate polymerase activity in dnaQ mutants is also observed in the purified alpha subunit containing the suppressor mutation, which exhibits a modestly elevated intrinsic polymerase activity relative to that of wild-type alpha.

Site-directed mutagenesis of recombinant rat DNA polymerase beta: involvement of arginine-183 in primer recognition

By site-directed mutagenesis using synthetic oligonucleotides, amino acid residues 181Phe-Arg-Arg183 of recombinant rat DNA polymerase beta were replaced by other amino acids to clarify the roles of these residues in the DNA synthesizing reaction. Replacement of Phe-181 by alanine reduced the enzyme activity only 30%. Replacement of Arg-182 by alanine and glutamine resulted in reduction of the activity by about 67% and 95%, respectively. The Arg-182----Gln replacement increased the binding strength to single-stranded DNA but did not significantly change the Km's for the primer and dTTP, suggesting that Arg-182 is involved in modulation of binding to the template rather than to the primer or deoxyribonucleoside triphosphate. Replacement of Arg-183 by Gln resulted in reduction of the activity by about 95%, and this change, although causing little change in binding strength to single-stranded DNA, resulted in a 3-4-fold increase in the Km's for the primer and deoxyribonucleoside triphosphate. A more dramatic change was observed when Arg-183 was replaced by Ala, which resulted in a 99.98% reduction of enzyme activity. Although the Km for deoxyribonucleoside triphosphate of this mutant enzyme was hardly changed, that for the primer increased 159-fold. Therefore, it is concluded that Arg-183 occupies an important part of the primer recognition site of DNA polymerase beta.

A kinetic study of rat recombinant DNA polymerase beta: detection of a slow (hysteretic) transition in polymerase activity and inhibition by butylphenyl-deoxyguanosine triphosphate

We have identified and characterized a distinct non-linearity in the time course of the reaction of mammalian DNA polymerase beta with synthetic polynucleotides. Nucleotide incorporation is biphasic; an initial burst of activity decays exponentially to a lower steady-state velocity. This slow transition in polymerase activity is not due to substrate depletion, abortive complex formation, or enzyme inactivation. The data are consistent with description of the beta-polymerase as a hysteretic enzyme, a finding which provides a potential explanation for the non-hyperbolic kinetics which have been reported previously for this polymerase. We have also found, in contrast to some previous data, that the nucleotide analogue, N2-(p-n-butylphenyl)-2'-deoxyguanosine-5'-triphosphate (BuPdGTP), is an inhibitor of the beta-polymerase. When poly(dC).oligo(dG) is used as template.primer, inhibition of the initial velocity is competitive with dGTP with a Ki of 1.25 microM. On activated DNA, however, beta-polymerase displays sensitivity to BuPdGTP which overlaps with that previously reported for DNA polymerase delta; 100 microM BuPdGTP is required to inhibit the initial velocity of a dGTP-deficient, truncated assay. Finally, we demonstrate that, in addition to its inhibition of initial velocity, BuPdGTP also modulates both the rate constant of the slow transition in polymerase activity, and the steady-state velocity of the beta-polymerase.