Studies on the Biochemical Basis of Spontaneous Mutation

Mechanisms of DNA methylation and histone modifications

The field of genetics has expanded a lot in the past few decades due to the accessibility of human genome sequences, but still, the regulation of transcription cannot be explicated exclusively by the sequence of DNA of an individual. The coordination and crosstalk between chromatin factors which are conserved is indispensable for all living creatures. The regulation of gene expression has been dependent on the methylation of DNA, post-translational modifications of histones, effector proteins, chromatin remodeler enzymes that affect the chromatin structure and function, and other cellular activities such as DNA replication, DNA repair, proliferation and growth. The mutation and deletion of these factors can lead to human diseases. Various studies are being performed to identify and understand the gene regulatory mechanisms in the diseased state. The information from these high throughput screening studies is able to aid the treatment developments based on the epigenetics regulatory mechanisms. This book chapter will discourse on various modifications and their mechanisms that take place on histones and DNA that regulate the transcription of genes.

Enhanced polymerase activity permits efficient synthesis by cancer-associated DNA polymerase ϵ variants at low dNTP levels

Amino acid substitutions in the exonuclease domain of DNA polymerase ϵ (Polϵ) cause ultramutated tumors. Studies in model organisms suggested pathogenic mechanisms distinct from a simple loss of exonuclease. These mechanisms remain unclear for most recurrent Polϵ mutations. Particularly, the highly prevalent V411L variant remained a long-standing puzzle with no detectable mutator effect in yeast despite the unequivocal association with ultramutation in cancers. Using purified four-subunit yeast Polϵ, we assessed the consequences of substitutions mimicking human V411L, S459F, F367S, L424V and D275V. While the effects on exonuclease activity vary widely, all common cancer-associated variants have increased DNA polymerase activity. Notably, the analog of Polϵ-V411L is among the strongest polymerases, and structural analysis suggests defective polymerase-to-exonuclease site switching. We further show that the V411L analog produces a robust mutator phenotype in strains that lack mismatch repair, indicating a high rate of replication errors. Lastly, unlike wild-type and exonuclease-dead Polϵ, hyperactive variants efficiently synthesize DNA at low dNTP concentrations. We propose that this characteristic could promote cancer cell survival and preferential participation of mutator polymerases in replication during metabolic stress. Our results support the notion that polymerase fitness, rather than low fidelity alone, is an important determinant of variant pathogenicity.

John W. (Jan) Drake: A Biochemical View of a Geneticist Par Excellence

John W. Drake died 02-02-2020, a mathematical palindrome, which he would have enjoyed, given his love of "word play and logic," as stated in his obituary and echoed by his family, friends, students, and colleagues. Many aspects of Jan's career have been reviewed previously, including his early years as a Caltech graduate student, and when he was editor-in-chief, with the devoted assistance of his wife Pam, of this journal for 15 impactful years. During his editorship, he raised the profile of GENETICS as the flagship journal of the Genetics Society of America and inspired and contributed to the creation of the Perspectives column, coedited by Jim Crow and William Dove. At the same time, Jan was building from scratch the Laboratory of Molecular Genetics on the newly established Research Triangle Park campus of the National Institute of Environmental Health Science, which he headed for 30 years. This commentary offers a unique perspective on Jan's legacy; we showcase Jan's 1969 benchmark discovery of antimutagenic T4 DNA polymerases and the research by three generations (and counting) of scientists whose research stems from that groundbreaking discovery. This is followed by a brief discussion of Jan's passion: his overriding interest in analyzing mutation rates across species. Several anecdotal stories are included to bring alive one of Jan's favorite phrases, "to think like a geneticist." We feature Jan's genetical approach to mutation studies, along with the biochemistry of DNA polymerase function, our area of expertise. But in the end, we acknowledge, as Jan did, that genetics, also known as in vivo biochemistry, prevails.

Regulation and Modulation of Human DNA Polymerase δ Activity and Function

This review focuses on the regulation and modulation of human DNA polymerase δ (Pol δ). The emphasis is on the mechanisms that regulate the activity and properties of Pol δ in DNA repair and replication. The areas covered are the degradation of the p12 subunit of Pol δ, which converts it from a heterotetramer (Pol δ4) to a heterotrimer (Pol δ3), in response to DNA damage and also during the cell cycle. The biochemical mechanisms that lead to degradation of p12 are reviewed, as well as the properties of Pol δ4 and Pol δ3 that provide insights into their functions in DNA replication and repair. The second focus of the review involves the functions of two Pol δ binding proteins, polymerase delta interaction protein 46 (PDIP46) and polymerase delta interaction protein 38 (PDIP38), both of which are multi-functional proteins. PDIP46 is a novel activator of Pol δ4, and the impact of this function is discussed in relation to its potential roles in DNA replication. Several new models for the roles of Pol δ3 and Pol δ4 in leading and lagging strand DNA synthesis that integrate a role for PDIP46 are presented. PDIP38 has multiple cellular localizations including the mitochondria, the spliceosomes and the nucleus. It has been implicated in a number of cellular functions, including the regulation of specialized DNA polymerases, mitosis, the DNA damage response, mouse double minute 2 homolog (Mdm2) alternative splicing and the regulation of the NADPH oxidase 4 (Nox4).

Better living with hyper-mutation

The simplest forms of mutations, base substitutions, typically have negative consequences, aside from their existential role in evolution and fitness. Hypermutations, mutations on steroids, occurring at frequencies of 10(-2) -10(-4) per base pair, straddle a domain between fitness and death, depending on the presence or absence of regulatory constraints. Two facets of hypermutation, one in Escherichia coli involving DNA polymerase V (pol V), the other in humans, involving activation-induced deoxycytidine deaminase (AID) are portrayed. Pol V is induced as part of the DNA-damage-induced SOS regulon, and is responsible for generating the lion's share of mutations when catalyzing translesion DNA synthesis (TLS). Four regulatory mechanisms, temporal, internal, conformational, and spatial, activate pol V to copy damaged DNA and then deactivate it. On the flip side of the coin, SOS-induced pols V, IV, and II mutate undamaged DNA, thus providing genetic diversity heightening long-term survival and evolutionary fitness. Fitness in humans is principally the domain of a remarkably versatile immune system marked by somatic hypermutations (SHM) in immunoglobulin variable (IgV) regions that ensure antibody (Ab) diversity. AID initiates SHM by deaminating C → U, favoring hot WRC (W = A/T, R = A/G) motifs. Since there are large numbers of trinucleotide motif targets throughout IgV, AID must exercise considerable catalytic restraint to avoid attacking such sites repeatedly, which would otherwise compromise diversity. Processive, random, and inefficient AID-catalyzed dC deamination simulates salient features of SHM, yet generates B-cell lymphomas when working at the wrong time in the wrong place. Environ. Mol. Mutagen. 57:421-434, 2016. © 2016 Wiley Periodicals, Inc.

Fidelity Variants and RNA Quasispecies

By now, it is well established that the error rate of the RNA-dependent RNA polymerase (RdRp) that replicates RNA virus genomes is a primary driver of the mutation frequencies observed in RNA virus populations-the basis for the RNA quasispecies. Over the last 10 years, a considerable amount of work has uncovered the molecular determinants of replication fidelity in this enzyme. The isolation of high- and low-fidelity variants for several RNA viruses, in an expanding number of viral families, provides evidence that nature has optimized the fidelity to facilitate genetic diversity and adaptation, while maintaining genetic integrity and infectivity. This chapter will provide an overview of what fidelity variants tell us about RNA virus biology and how they may be used in antiviral approaches.

DNA polymerase 3'→5' exonuclease activity: Different roles of the beta hairpin structure in family-B DNA polymerases

Proofreading by the bacteriophage T4 and RB69 DNA polymerases requires a β hairpin structure that resides in the exonuclease domain. Genetic, biochemical and structural studies demonstrate that the phage β hairpin acts as a wedge to separate the primer-end from the template strand in exonuclease complexes. Single amino acid substitutions in the tip of the hairpin or deletion of the hairpin prevent proofreading and create "mutator" DNA polymerases. There is little known, however, about the function of similar hairpin structures in other family B DNA polymerases. We present mutational analysis of the yeast (Saccharomyces cerevisiae) DNA polymerase δ hairpin. Deletion of the DNA polymerase δ hairpin (hpΔ) did not significantly reduce DNA replication fidelity; thus, the β hairpin structure in yeast DNA polymerase δ is not essential for proofreading. However, replication efficiency was reduced as indicated by a slow growth phenotype. In contrast, the G447D amino acid substitution in the tip of the hairpin increased frameshift mutations and sensitivity to hydroxyurea (HU). A chimeric yeast DNA polymerase δ was constructed in which the T4 DNA polymerase hairpin (T4hp) replaced the yeast DNA polymerase δ hairpin; a strong increase in frameshift mutations was observed and the mutant strain was sensitive to HU and to the pyrophosphate analog, phosphonoacetic acid (PAA). But all phenotypes - slow growth, HU-sensitivity, PAA-sensitivity, and reduced fidelity, were observed only in the absence of mismatch repair (MMR), which implicates a role for MMR in mediating DNA polymerase δ replication problems. In comparison, another family B DNA polymerase, DNA polymerase ɛ, has only an atrophied hairpin with no apparent function. Thus, while family B DNA polymerases share conserved motifs and general structural features, the β hairpin has evolved to meet specific needs.

Thinking Outside the Triangle: Replication Fidelity of the Largest RNA Viruses

When judged by ubiquity, adaptation, and emergence of new diseases, RNA viruses are arguably the most successful biological organisms. This success has been attributed to a defect of sorts: high mutation rates (low fidelity) resulting in mutant swarms that allow rapid selection for fitness in new environments. Studies of viruses with small RNA genomes have identified fidelity determinants in viral RNA-dependent RNA polymerases and have shown that RNA viruses likely replicate within a limited fidelity range to maintain fitness. In this review we compare the fidelity of small RNA viruses with that of the largest RNA viruses, the coronaviruses. Coronaviruses encode the first known viral RNA proofreading exoribonuclease, a function that likely allowed expansion of the coronavirus genome and that dramatically increases replication fidelity and the range of tolerated variation. We propose models for regulation of coronavirus fidelity and discuss the implications of altered fidelity for RNA virus replication, pathogenesis, and evolution.

Engineering processive DNA polymerases with maximum benefit at minimum cost

DNA polymerases need to be engineered to achieve optimal performance for biotechnological applications, which often require high fidelity replication when using modified nucleotides and when replicating difficult DNA sequences. These tasks are achieved for the bacteriophage T4 DNA polymerase by replacing leucine with methionine in the highly conserved Motif A sequence (L412M). The costs are minimal. Although base substitution errors increase moderately, accuracy is maintained for templates with mono- and dinucleotide repeats while replication efficiency is enhanced. The L412M substitution increases intrinsic processivity and addition of phage T4 clamp and single-stranded DNA binding proteins further enhance the ability of the phage T4 L412M-DNA polymerase to replicate all types of difficult DNA sequences. Increased pyrophosphorolysis is a drawback of increased processivity, but pyrophosphorolysis is curbed by adding an inorganic pyrophosphatase or divalent metal cations, Mn²⁺ or Ca²⁺. In the absence of pyrophosphorolysis inhibitors, the T4 L412M-DNA polymerase catalyzed sequence-dependent pyrophosphorolysis under DNA sequencing conditions. The sequence specificity of the pyrophosphorolysis reaction provides insights into how the T4 DNA polymerase switches between nucleotide incorporation, pyrophosphorolysis and proofreading pathways. The L-to-M substitution was also tested in the yeast DNA polymerases delta and alpha. Because the mutant DNA polymerases displayed similar characteristics, we propose that amino acid substitutions in Motif A have the potential to increase processivity and to enhance performance in biotechnological applications. An underlying theme in this chapter is the use of genetic methods to identify mutant DNA polymerases with potential for use in current and future biotechnological applications.

Reduction of dNTP levels enhances DNA replication fidelity in vivo

ATP is the most important energy source for the maintenance and growth of living cells. Here we report that the impairment of the aerobic respiratory chain by inactivation of the ndh gene, or the inhibition of glycolysis with arsenate, both of which reduce intracellular ATP, result in a significant decrease in spontaneous mutagenesis in Escherichia coli. The genetic analyses and mutation spectra in the ndh strain revealed that the decrease in spontaneous mutagenesis resulted from an enhanced accuracy of the replicative DNA polymerase. Quantification of the dNTP content in the ndh mutant cells and in the arsenate-treated cells showed reduction of the dNTP pool, which could explain the observed broad antimutator effects. In conclusion, our work indicates that the cellular energy supply could affect spontaneous mutation rates and that a reduction of the dNTP levels can be antimutagenic.

DNA polymerase delta in DNA replication and genome maintenance

The eukaryotic genome is in a constant state of modification and repair. Faithful transmission of the genomic information from parent to daughter cells depends upon an extensive system of surveillance, signaling, and DNA repair, as well as accurate synthesis of DNA during replication. Often, replicative synthesis occurs over regions of DNA that have not yet been repaired, presenting further challenges to genomic stability. DNA polymerase δ (pol δ) occupies a central role in all of these processes: catalyzing the accurate replication of a majority of the genome, participating in several DNA repair synthetic pathways, and contributing structurally to the accurate bypass of problematic lesions during translesion synthesis. The concerted actions of pol δ on the lagging strand, pol ϵ on the leading strand, associated replicative factors, and the mismatch repair (MMR) proteins results in a mutation rate of less than one misincorporation per genome per replication cycle. This low mutation rate provides a high level of protection against genetic defects during development and may prevent the initiation of malignancies in somatic cells. This review explores the role of pol δ in replication fidelity and genome maintenance.

Using a fluorescent cytosine analogue tC(o) to probe the effect of the Y567 to Ala substitution on the preinsertion steps of dNMP incorporation by RB69 DNA polymerase

Residues in the nascent base pair binding pocket (NBP) of bacteriophage RB69 DNA polymerase (RB69pol) are responsible for base discrimination. Replacing Tyr567 with Ala leads to greater flexibility in the NBP, increasing the probability of misincorporation. We used the fluorescent cytosine analogue, 1,3-diaza-2-oxophenoxazine (tC(o)), to identify preinsertion step(s) altered by NBP flexibility. When tC(o) is the templating base in a wild-type (wt) RB69pol ternary complex, its fluorescence is quenched only in the presence of dGTP. However, with the RB69pol Y567A mutant, the fluorescence of tC(o) is also quenched in the presence of dATP. We determined the crystal structure of the dATP/tC(o)-containing ternary complex of the RB69pol Y567A mutant at 1.9 Å resolution and found that the incoming dATP formed two hydrogen bonds with an imino-tautomerized form of tC(o). Stabilization of the dATP/tC(o) base pair involved movement of the tC(o) backbone sugar into the DNA minor groove and required tilting of the tC(o) tricyclic ring to prevent a steric clash with L561. This structure, together with the pre-steady-state kinetic parameters and dNTP binding affinity, estimated from equilibrium fluorescence titrations, suggested that the flexibility of the NBP, provided by the Y567 to Ala substitution, led to a more favorable forward isomerization step resulting in an increase in dNTP binding affinity.

Nontemplate polymerization of free nucleotides into genetic elements by thermophilic DNA polymerase in vitro

DNA synthesis is the cornerstone of all life forms and is required to replicate and restore the genetic information. Usually, DNA synthesis is carried out only by DNA polymerases semiconservatively to copy preexisting DNA templates. We report here that DNA strands were synthesized ab initio in the absence of any DNA or RNA template by thermophilic DNA polymerases at (a) a constant high temperature (74°C), (b) alternating temperatures (94°C/60°C/74°C), or (c) physiological temperatures (37°C). The majority of the ab initio synthesized DNA represented short sequence blocks, repeated sequences, intergenic spacers, and other unknown genetic elements. These results suggest that novel DNA elements could be synthesized in the absence of a nucleic acid template by thermophilic DNA polymerases in vitro. Biogenesis of genetic information by thermophilic DNA polymerase-mediated nontemplate DNA synthesis may explain the origin of genetic information and could serve as a new way of biosynthesis of genetic information that may have facilitated the evolution of life.

Antimutator variants of DNA polymerases

Evolution balances DNA replication speed and accuracy to optimize replicative fitness and genetic stability. There is no selective pressure to improve DNA replication fidelity beyond the background mutation rate from other sources, such as DNA damage. However, DNA polymerases remain amenable to amino acid substitutions that lower intrinsic error rates. Here, we review these 'antimutagenic' changes in DNA polymerases and discuss what they reveal about mechanisms of replication fidelity. Pioneering studies with bacteriophage T4 DNA polymerase (T4 Pol) established the paradigm that antimutator amino acid substitutions reduce replication errors by increasing proofreading efficiency at the expense of polymerase processivity. The discoveries of antimutator substitutions in proofreading-deficient 'mutator' derivatives of bacterial Pols I and III and yeast Pol δ suggest there must be additional antimutagenic mechanisms. Remarkably, many of the affected amino acid positions from Pol I, Pol III, and Pol δ are similar to the original T4 Pol substitutions. The locations of antimutator substitutions within DNA polymerase structures suggest that they may increase nucleotide selectivity and/or promote dissociation of primer termini from polymerases poised for misincorporation, leading to expulsion of incorrect nucleotides. If misincorporation occurs, enhanced primer dissociation from polymerase domains may improve proofreading in cis by an intrinsic exonuclease or in trans by alternate cellular proofreading activities. Together, these studies reveal that natural selection can readily restore replication error rates to sustainable levels following an adaptive mutator phenotype.

The dgt gene of Escherichia coli facilitates thymine utilization in thymine-requiring strains

The Escherichia coli dGTP triphosphohydrolase (dGTPase) encoded by the dgt gene catalyses the hydrolysis of dGTP to deoxyguanosine and triphosphate. The recent discovery of a mutator effect associated with deletion of dgt indicated participation of the triphosphohydrolase in preventing mutagenesis. Here, we have investigated the possible involvement of dgt in facilitating thymine utilization through its ability to provide intracellular deoxyguanosine, which is readily converted by the DeoD phosphorylase to deoxyribose-1-phosphate, the critical intermediate that enables uptake and utilization of thymine. Indeed, we observed that the minimal amount of thymine required for growth of thymine-requiring (thyA) strains decreased with increased expression level of the dgt gene. As expected, this dgt-mediated effect was dependent on the DeoD purine nucleoside phosphorylase. We also observed that thyA strains experience growth difficulties upon nutritional shift-up and that the dgt gene facilitates adaptation to the new growth conditions. Blockage of the alternative yjjG (dUMP phosphatase) pathway for deoxyribose-1-phosphate generation greatly exacerbated the severity of thymine starvation in enriched media, and under these conditions the dgt pathway becomes crucial in protecting the cells against thymineless death. Overall, our results suggest that the dgt-dependent pathway for deoxyribose-1-phosphate generation may operate under various cell conditions to provide deoxyribosyl donors.

Kinetic approaches to understanding the mechanisms of fidelity of the herpes simplex virus type 1 DNA polymerase

We discuss how the results of presteady-state and steady-state kinetic analysis of the polymerizing and excision activities of herpes simplex virus type 1 (HSV-1) DNA polymerase have led to a better understanding of the mechanisms controlling fidelity of this important model replication polymerase. Despite a poorer misincorporation frequency compared to other replicative polymerases with intrinsic 3′ to 5′ exonuclease (exo) activity, HSV-1 DNA replication fidelity is enhanced by a high kinetic barrier to extending a primer/template containing a mismatch or abasic lesion and by the dynamic ability of the polymerase to switch the primer terminus between the exo and polymerizing active sites. The HSV-1 polymerase with a catalytically inactivated exo activity possesses reduced rates of primer switching and fails to support productive replication, suggesting a novel means to target polymerase for replication inhibition.

Reversal of a mutator activity by a nearby fidelity-neutral substitution in the RB69 DNA polymerase binding pocket

Phage RB69 B-family DNA polymerase is responsible for the overall high fidelity of RB69 DNA synthesis. Fidelity is compromised when conserved Tyr567, one of the residues that form the nascent polymerase base-pair binding pocket, is replaced by alanine. The Y567A mutator mutant has an enlarged binding pocket and can incorporate and extend mispairs efficiently. Ser565 is a nearby conserved residue that also contributes to the binding pocket, but a S565G replacement has only a small impact on DNA replication fidelity. When Y567A and S565G replacements were combined, mutator activity was strongly decreased compared to that with Y567A replacement alone. Analyses conducted both in vivo and in vitro revealed that, compared to Y567A replacement alone, the double mutant mainly reduced base substitution mutations and, to a lesser extent, frameshift mutations. The decrease in mutation rates was not due to increased exonuclease activity. Based on measurements of DNA binding affinity, mismatch insertion, and mismatch extension, we propose that the recovered fidelity of the double mutant may result, in part, from an increased dissociation of the enzyme from DNA, followed by the binding of the same or another polymerase molecule in either exonuclease mode or polymerase mode. An additional antimutagenic factor may be a structural alteration in the polymerase binding pocket described in this article.

Rapid and sensitive detection of DNA polymerase fidelity by singly labeled smart fluorescent probes

We report here a novel approach to monitor the DNA polymerase fidelity in detailed steps, including mispair extension, mispair formation and 3'→5' proofreading. The method is based on the photo-induced electron transfer between the natural base guanine and the labeled fluorophore. The G:T mispair extension catalyzed by the exonuclease-deficient Klenow fragment DNA polymerase (KF exo(-)) was easily detected and the effect of the nearest neighbor base pair on the mispair extension rate was clearly observed. More importantly, kinetics of the G:T, G:A and G:G mispair formation and extension under single turnover conditions were measured by continuous fluorescence-based assay for the first time. The probes also showed their applicability to discriminate the 3'→5' proofreading activity of different exonuclease-proficient DNA polymerases. The presented method may greatly simplify the screening and characterization procedures of the increasing number of polymerases that are thought to be potential targets for drug design and cancer treatment. It will also provide important information for deep understanding of the polymerase fidelity mechanism.

The p12 subunit of human polymerase delta modulates the rate and fidelity of DNA synthesis

This study examines the role of the p12 subunit in the function of the human DNA polymerase delta (Pol delta) holoenzyme by comparing the kinetics of DNA synthesis and degradation catalyzed by the four-subunit complex, the three-subunit complex lacking p12, and site-directed mutants of each lacking proofreading exonuclease activity. Results show that p12 modulates the rate and fidelity of DNA synthesis by Pol delta. All four complexes synthesize DNA in a rapid burst phase and a slower, more linear phase. In the presence of p12, the burst rates of DNA synthesis are approximately 5 times faster, while the affinity of the enzyme for its DNA and dNTP substrates appears unchanged. The p12 subunit alters Pol delta fidelity by modulating the proofreading 3' to 5' exonuclease activity. In the absence of p12, Pol delta is more likely to proofread DNA synthesis because it cleaves single-stranded DNA twice as fast and transfers mismatched DNA from the polymerase to the exonuclease sites 9 times faster. Pol delta also extends mismatched primers 3 times more slowly in the absence of p12. Taken together, the changes that p12 exerts on Pol delta are ones that can modulate its fidelity of DNA synthesis. The loss of p12, which occurs in cells upon exposure to DNA-damaging agents, converts Pol delta to a form that has an increased capacity for proofreading.

DNA polymerase fidelity: comparing direct competition of right and wrong dNTP substrates with steady state and pre-steady state kinetics

DNA polymerase fidelity is defined as the ratio of right (R) to wrong (W) nucleotide incorporations when dRTP and dWTP substrates compete at equal concentrations for primer extension at the same site in the polymerase-primer-template DNA complex. Typically, R incorporation is favored over W by 10(3)-10(5)-fold, even in the absence of 3'-exonuclease proofreading. Straightforward in principle, a direct competition fidelity measurement is difficult to perform in practice because detection of a small amount of W is masked by a large amount of R. As an alternative, enzyme kinetics measurements to evaluate k(cat)/K(m) for R and W in separate reactions are widely used to measure polymerase fidelity indirectly, based on a steady state derivation by Fersht. A systematic comparison between direct competition and kinetics has not been made until now. By separating R and W products using electrophoresis, we have successfully taken accurate fidelity measurements for directly competing R and W dNTP substrates for 9 of the 12 natural base mispairs. We compare our direct competition results with steady state and pre-steady state kinetic measurements of fidelity at the same template site, using the proofreading-deficient mutant of Klenow fragment (KF(-)) DNA polymerase. All the data are in quantitative agreement.

Effect of A and B metal ion site occupancy on conformational changes in an RB69 DNA polymerase ternary complex

Rapid chemical quench assays, as well as equilibrium and stopped-flow fluorescence experiments, were performed with an RB69 DNA polymerase (RB69 pol)-primer-template (P/T) complex containing 2-aminopurine (dAP) and a metal exchange-inert Rh(III) derivative of a deoxynucleoside triphosphate (Rh.dTTP). The objective was to determine the effect of catalytic metal ion (A site) occupancy on the affinity of an incoming Rh.dTTP for the RB69 pol-P/T binary complex and on the rate of the conformational change induced by Rh.dTTP binding. With Ca(2+) in the A site, the affinity of the incoming Rh.dTTP for the RB69 pol-P/T binary complex and the conformational change rate can be determined in the absence of chemistry. When Mg(2+) was added to a ternary complex containing Rh.dTTP opposite dAP, the templating base, nucleotidyl transfer occurred, but the rate of product formation was only one-tenth of that found with Mg.dTTP, as determined by rapid chemical quench assays. Rates of conformational change subsequent to formation of a ternary complex, in the absence of chemistry, were estimated from the rate of change in dAP fluorescence with an increase in the Rh.dTTP concentration. We have shown that there is an initial rapid quenching of dAP fluorescence followed by a second phase of dAP quenching, which has nearly the same rate as that of dTMP incorporation, as estimated from rapid chemical quench experiments. We have also demonstrated that the affinity of Rh.dTTP for occupancy of the B metal ion site is dependent on the presence of Ca(2+). However, a saturating Rh.dTTP concentration in the absence of Ca(2+) results in full quenching of dAP fluorescence, whereas a saturating Ca(2+) concentration in the absence of Rh.dTTP gives only partial quenching of dAP fluorescence. The implications of these results for the mechanism of Fingers closing, metal ion binding, and base selectivity are discussed.

The reopening rate of the fingers domain is a determinant of base selectivity for RB69 DNA polymerase

Two divalent metal ions are required for nucleotide incorporation by DNA polymerases. Here we use the bacteriophage RB69 DNA polymerase (RB69 pol) and the metal ion exchange-inert nucleotide analogue rhodium(III) deoxythymidine triphosphate (Rh.dTTP) to investigate the requirements of metal binding to the "A" site and to the "B" site, independently. We show that while binding of a metal ion to the A site is required for the nucleotidyl transfer reaction to occur, this metal binding is insufficient to initiate the prechemistry enzyme isomerization that has been observed with this polymerase. Moreover, we show that binding of a deoxynucleoside triphosphate (dNTP), in the absence of a catalytic metal ion, is sufficient to induce this conformational change. In this report, we also present several lines of evidence (from pulse-chase, rapid chemical quench-flow, and stopped-flow fluorescence experiments) for the reverse rate of the enzyme isomerization, closed to open, of a DNA polymerase complex. The implications of these data for the fidelity of DNA polymerization by RB69 pol are discussed.

DNA damage alters DNA polymerase delta to a form that exhibits increased discrimination against modified template bases and mismatched primers

Human DNA polymerase δ (Pol δ4), a key enzyme in chromosomal replication, is a heterotetramer composed of the p125, p50, p68 and p12 subunits. Genotoxic agents such as UV and alkylating chemicals trigger a DNA damage response in which Pol δ4 is converted to a trimer (Pol δ3) by degradation of p12. We show that Pol δ3 has altered enzymatic properties: it is less able to perform translesion synthesis on templates containing base lesions (O⁶-MeG, 8-oxoG, an abasic site or a thymine-thymine dimer); a greater proofreading activity; an increased exonuclease/polymerase activity ratio; a decreased tendency for the insertion of wrong nucleotides, and for the extension of mismatched primers. Overall, our findings indicate that Pol δ3 exhibits an enhanced ability for the detection of errors in both primers and templates over its parent enzyme. These alterations in Pol δ3 show that p12 plays a major role in Pol δ4 catalytic functions, and provides significant insights into the rationale for the conversion of Pol δ4 to Pol δ3 in the cellular response to DNA damage.

Highly Tolerated Amino Acid Substitutions Increase the Fidelity of Escherichia coli DNA Polymerase I

Fidelity of DNA synthesis, catalyzed by DNA polymerases, is critical for the maintenance of the integrity of the genome. Mutant polymerases with elevated accuracy (antimutators) have been observed, but these mainly involve increased exonuclease proofreading or large decreases in polymerase activity. We have determined the tolerance of DNA polymerase for amino acid substitutions in the active site and in different segments of E. coli DNA polymerase I and have determined the effects of these substitutions on the fidelity of DNA synthesis. We established a DNA polymerase I mutant library, with random substitutions throughout the polymerase domain. This random library was first selected for activity. The essentiality of DNA polymerases and their sequence and structural conservation suggests that few amino acid substitutions would be tolerated. However, we report that two-thirds of single base substitutions were tolerated without loss of activity, and plasticity often occurs at evolutionarily conserved regions. We screened 408 members of the active library for alterations in fidelity of DNA synthesis in Escherichia coli expressing the mutant polymerases and carrying a second plasmid containing a beta-lactamase reporter. Mutation frequencies varied from 1/1000- to 1000-fold greater compared with wild type. Mutations that produced an antimutator phenotype were distributed throughout the polymerase domain, with 12% clustered in the M-helix. We confirmed that a single mutation in this segment results in increased base discrimination. Thus, this work identifies the M-helix as a determinant of fidelity and suggests that polymerases can tolerate many substitutions that alter fidelity without incurring major changes in activity.

A method to select for mutator DNA polymerase deltas in Saccharomyces cerevisiae

Proofreading DNA polymerases share common short peptide motifs that bind Mg(2+) in the exonuclease active center; however, hydrolysis rates are not the same for all of the enzymes, which indicates that there are functional and likely structural differences outside of the conserved residues. Since structural information is available for only a few proofreading DNA polymerases, we developed a genetic selection method to identify mutant alleles of the POL3 gene in Saccharomyces cerevisiae, which encode DNA polymerase delta mutants that replicate DNA with reduced fidelity. The selection procedure is based on genetic methods used to identify "mutator" DNA polymerases in bacteriophage T4. New yeast DNA polymerase delta mutants were identified, but some mutants expected from studies of the phage T4 DNA polymerase were not detected. This would indicate that there may be important differences in the proofreading pathways catalyzed by the two DNA polymerases.

Kinetics of error generation in homologous B-family DNA polymerases

The kinetics of forming a proper Watson-Crick base pair as well incorporating bases opposite furan, an abasic site analog, have been well characterized for the B Family replicative DNA polymerase from bacteriophage T4. Structural studies of these reactions, however, have only been performed with the homologous enzyme from bacteriophage RB69. In this work, the homologous enzymes from RB69 and T4 were compared in parallel reactions to determine the relative abilities of the two polymerases to incorporate correct nucleotides as well as to form improper pairings. The kinetic rates for three different exonuclease mutants for each enzyme were measured for incorporation of an A opposite T and an A opposite furan as well as for the formation of A:C and T:T mismatches. The T4 exonuclease mutants were all approximately 2- to 7-fold more efficient than the corresponding RB69 exonuclease mutants depending on whether a T or furan was in the templating position and which exonuclease mutant was used. The rates for mismatch formation by T4 were significantly reduced compared with incorporation opposite furan, much more so than the corresponding RB69 mutant. These results show that there are kinetic differences between the two enzymes but they are not large enough to preclude structural assumptions for T4 DNA polymerase based on the known structure of the RB69 DNA polymerase.

Dynamics of nucleotide incorporation: snapshots revealed by 2-aminopurine fluorescence studies

Formation of a noncanonical base pair between dFTP, a dTTP analogue that cannot form H bonds, and the fluorescent base analogue 2-aminopurine (2AP) was studied in order to discover how the bacteriophage T4 DNA polymerase selects nucleotides with high accuracy. Changes in 2AP fluorescence intensity provided a spectroscopic reporter of the nucleotide binding reactions, which were combined with rapid-quench, pre-steady-state reactions to measure product formation. These studies supported and extended previous findings that the T4 DNA polymerase binds nucleotides in multiple steps with increasing selectivity. With 2AP in the template position, initial dTTP binding was rapid but selective: K(d(dTTP)) (first step) = 31 microM; K(d(dCTP)) (first step) approximately 3 mM. In studies with dFTP, this step was revealed to have two components: formation of an initial preinsertion complex in which H bonds between bases in the newly forming base pair were not essential, which was followed by formation of a final preinsertion complex in which H bonds assisted. The second nucleotide binding step was characterized by increased discrimination against dTTP binding opposite template 2AP, K(d) (second step) = 367 microM, and additional conformational changes were detected in ternary enzyme-DNA-dTTP complexes, as expected for forming closed complexes. We demonstrate here that the second binding step occurs before formation of the phosphodiester bond. Thus, the high fidelity of nucleotide insertion by T4 DNA polymerase is accomplished by the sequential application of selectivity in first forming accurate preinsertion complexes, and then additional conformational changes are applied that further increase discrimination against incorrect nucleotides.

Idling by DNA polymerase delta maintains a ligatable nick during lagging-strand DNA replication

During each yeast cell cycle, approximately 100,000 nicks are generated during lagging-strand DNA replication. Efficient nick processing during Okazaki fragment maturation requires the coordinated action of DNA polymerase delta (Pol delta) and the FLAP endonuclease FEN1. Misregulation of this process leads to the accumulation of double-stranded breaks and cell lethality. Our studies highlight a remarkably efficient mechanism for Okazaki fragment maturation in which Pol delta by default displaces 2-3 nt of any downstream RNA or DNA it encounters. In the presence of FEN1, efficient nick translation ensues, whereby a mixture of mono- and small oligonucleotides are released. If FEN1 is absent or not optimally functional, the ability of Pol delta to back up via its 3'-5'-exonuclease activity, a process called idling, maintains the polymerase at a position that is ideal either for ligation (in case of a DNA-DNA nick) or for subsequent engagement by FEN1 (in case of a DNA-RNA nick). Consistent with the hypothesis that DNA polymerase epsilon is the leading-strand enzyme, we observed no idling by this enzyme and no cooperation with FEN1 for creating a ligatable nick.

A single mutation in poliovirus RNA-dependent RNA polymerase confers resistance to mutagenic nucleotide analogs via increased fidelity

Ribavirin is a nucleotide analog that can be incorporated by viral polymerases, causing mutations by allowing base mismatches. It is currently used therapeutically as an antiviral drug during hepatitis C virus infections. During the amplification of poliovirus genomic RNA or hepatitis C replicons, error frequency is known to increase upon ribavirin treatment. This observation has led to the hypothesis that ribavirin's antiviral activity results from error catastrophe caused by increased mutagenesis of viral genomes. Here, we describe the generation of ribavirin-resistant poliovirus by serial viral passage in the presence of increasing concentrations of the drug. Ribavirin resistance can be caused by a single amino acid change, G64S, in the viral polymerase in an unresolved portion of the fingers domain. Compared with wild-type virus, ribavirin-resistant poliovirus displays increased fidelity of RNA synthesis in the absence of ribavirin and increased survival both in the presence of ribavirin and another mutagen, 5-azacytidine. Ribavirin-resistant poliovirus represents an unusual class of viral drug resistance: resistance to a mutagen through increased fidelity.

Using 2-aminopurine fluorescence to measure incorporation of incorrect nucleotides by wild type and mutant bacteriophage T4 DNA polymerases

The ability of wild type and mutant T4 DNA polymerases to discriminate in the utilization of the base analog 2-aminopurine (2AP) and the fluorescence of 2AP were used to determine how DNA polymerases distinguish between correct and incorrect nucleotides. Because T4 DNA polymerase incorporates dTMP opposite 2AP under single-turnover conditions, it was possible to compare directly the kinetic parameters for incorporation of dTMP opposite template 2AP to the parameters for incorporation of dTMP opposite template A without the complication of enzyme dissociation. The most significant difference detected was in the K(d) for dTTP, which was 10-fold higher for incorporation of dTMP opposite template 2AP (approximately 367 microm) than for incorporation of dTMP opposite template A (approximately 31 microm). In contrast, the dTMP incorporation rate was reduced only about 2-fold from about 318 s(-1) with template A to about 165 s(-1) for template 2AP. Discrimination is due to the high selectivity in the initial nucleotide-binding step. T4 DNA polymerase binding to DNA with 2AP in the template position induces formation of a nucleotide binding pocket that is preshaped to bind dTTP and to exclude other nucleotides. If nucleotide binding is hindered, initiation of the proofreading pathway acts as an error avoidance mechanism to prevent incorporation of incorrect nucleotides.

Resolving a fidelity paradox: why Escherichia coli DNA polymerase II makes more base substitution errors in AT- compared with GC-rich DNA

The activity of DNA polymerase-associated proofreading 3'-exonucleases is generally enhanced in less stable DNA regions leading to a reduction in base substitution error frequencies in AT- versus GC-rich sequences. Unexpectedly, however, the opposite result was found for Escherichia coli DNA polymerase II (pol II). Nucleotide misincorporation frequencies for pol II were found to be 3-5-fold higher in AT- compared with GC-rich DNA, both in the presence and absence of polymerase processivity subunits, beta dimer and gamma complex. In contrast, E. coli pol III holoenzyme, behaving "as expected," exhibited 3-5-fold lower misincorporation frequencies in AT-rich DNA. A reduction in fidelity in AT-rich regions occurred for pol II despite having an associated 3'-exonuclease proofreading activity that preferentially degrades AT-rich compared with GC-rich DNA primer-template in the absence of DNA synthesis. Concomitant with a reduction in fidelity, pol II polymerization efficiencies were 2-6-fold higher in AT-rich DNA, depending on sequence context. Pol II paradoxical fidelity behavior can be accounted for by the enzyme's preference for forward polymerization in AT-rich sequences. The more efficient polymerization suppresses proofreading thereby causing a significant increase in base substitution error rates in AT-rich regions.

In vivo mutagenesis by Escherichia coli DNA polymerase I. Ile(709) in motif A functions in base selection

The fidelity of DNA replication by Escherichia coli DNA polymerase I (pol I) was assessed in vivo using a reporter plasmid bearing a ColE1-type origin and an ochre codon in the beta-lactamase gene. We screened 53 single mutants within the region Val(700)-Arg(712) in the polymerase active-site motif A. Only replacement of Ile(709) yielded mutator polymerases, with substitution of Met, Asn, Phe, or Ala increasing the beta-lactamase reversion frequency 5-23-fold. Steady-state kinetic analysis of the I709F polymerase revealed reductions in apparent K(m) values for both insertion of non-complementary nucleotides and extension of mispaired primer termini. Abolishment of the 3'-5' exonuclease activity of wild-type pol I increased mutation frequency 4-fold, whereas the combination of I709F and lack of the 3'-5' exonuclease yielded a 400-fold increase. We conclude that accurate discrimination of the incoming nucleotide at the polymerase domain is more critical than exonucleolytic proofreading for the fidelity of pol I in vivo. Surprisingly, the I709F polymerase enhanced mutagenesis in chromosomal DNA, although the increase was 10-fold less than in plasmid DNA. Our findings indicate the feasibility of obtaining desired mutations by replicating a target gene at a specific locus in a plasmid under continuous selection pressure.

A Mutation in the gene-encoding bacteriophage T7 DNA polymerase that renders the phage temperature-sensitive

Gene 5 of bacteriophage T7 encodes a DNA polymerase essential for phage replication. A single point mutation in gene 5 confers temperature sensitivity for phage growth. The mutation results in an alanine to valine substitution at residue 73 in the exonuclease domain. Upon infection of Escherichia coli by the temperature-sensitive phage at 42 degrees C, there is no detectable T7 DNA synthesis in vivo. DNA polymerase activity in these phage-infected cell extracts is undetectable at assay temperatures of 30 degrees C or 42 degrees C. Upon infection at 30 degrees C, both DNA synthesis in vivo and DNA polymerase activity in cell extracts assayed at 30 degrees C or 42 degrees C approach levels observed using wild-type T7 phage. The amount of soluble gene 5 protein produced at 42 degrees C is comparable to that produced at 30 degrees C, indicating that the temperature-sensitive phenotype is not due to reduced expression, stability, or solubility. Thus the polymerase induced at elevated temperatures by the temperature-sensitive phage is functionally inactive. Consistent with this observation, biochemical properties and heat inactivation profiles of the genetically altered enzyme over-produced at 30 degrees C closely resemble that of wild-type T7 DNA polymerase. It is likely that the polymerase produced at elevated temperatures is a misfolded intermediate in its folding pathway.

Role of the C-terminal residue of the DNA polymerase of bacteriophage T7

The crystal structure of the DNA polymerase encoded by gene 5 of bacteriophage T7, in a complex with its processivity factor, Escherichia coli thioredoxin, a primer-template, and an incoming deoxynucleoside triphosphate reveals a putative hydrogen bond between the C-terminal residue, histidine 704 of gene 5 protein, and an oxygen atom on the penultimate phosphate diester of the primer strand. Elimination of this electrostatic interaction by replacing His(704) with alanine renders the phage nonviable, and no DNA synthesis is observed in vivo. Polymerase activity of the genetically altered enzyme on primed M13 DNA is only 12% of the wild-type enzyme, and its processivity is drastically reduced. Kinetic parameters for binding a primer-template (K(D)(app)), nucleotide binding (K(m)), and k(off) for dissociation of the altered polymerase from a primer-template are not significantly different from that of wild-type T7 DNA polymerase. However, the decrease in polymerase activity is concomitant with increased hydrolytic activity, judging from the turnover of nucleoside triphosphate into the corresponding nucleoside monophosphate (percentage of turnover, 65%) during DNA synthesis. Biochemical data along with structural observations imply that the terminal amino acid residue of T7 DNA polymerase plays a critical role in partitioning DNA between the polymerase and exonuclease sites.

Mutational and pH studies of the 3' --> 5' exonuclease activity of bacteriophage T4 DNA polymerase

The 3' --> 5' exonuclease activity of proofreading DNA polymerases requires two divalent metal ions, metal ions A and B. Mutational studies of the 3' --> 5' exonuclease active center of the bacteriophage T4 DNA polymerase indicate that residue Asp-324, which binds metal ion A, is the single most important residue for the hydrolysis reaction. In the absence of a nonenzymatic source of hydroxide ions, an alanine substitution for residue Asp-324 reduced exonuclease activity 10-100-fold more than alanine substitutions for the other metal-binding residues, Asp-112 and Asp-219. Thus, exonuclease activity is reduced 10(5)-fold for the D324A-DNA polymerase compared with the wild-type enzyme, while decreases of 10(3)- to 10(4)-fold are detected for the D219A- and D112A/E114A-DNA polymerases, respectively. Our results are consistent with the proposal that a water molecule, coordinated by metal ion A, forms a metal-hydroxide ion that is oriented to attack the phosphodiester bond at the site of cleavage. Residues Glu-114 and Lys-299 may assist the reaction by lowering the pK(a) of the metal ion-A coordinated water molecule, whereas residue Tyr-320 may help to reorient the DNA from the binding conformation to the catalytically active conformation.

Kinetic characterization of a bacteriophage T4 antimutator DNA polymerase

Fidelity of DNA replication by bacteriophage T4 DNA polymerase is achieved in a multiplicative process: base selection by its polymerase activity and removal of misincorporated nucleotides by its exonuclease activity. The wild-type polymerase is capable of maintaining a balance between the two activities so that DNA replication fidelity is maximized without excessive waste of nucleotides. Antimutator enzymes exhibit a higher DNA replication fidelity than the wild-type enzyme, at the cost of increased nucleotide turnover. The antimutator A737V polymerase has been characterized kinetically using pre-steady-state and steady-state methods to provide a kinetic sequence which defines the effect of the mutation on the discrete steps controlling DNA replication fidelity. Comparison of this sequence to that of the wild type [Capson, L. T., Peliska, J. A., Kaboord, B. F., Frey, M. W., Lively, C., Dahlberg, M., and Benkovic, S. J. (1992) Biochemistry 31, 10984-10994] revealed that A737V polymerase differs in two ways. The rates at which DNA is transferred between the exonuclease and polymerase sites are reduced approximately 7-fold for a duplex DNA containing a mismatched 3'-terminus, and the partitioning of the mismatched duplex between the polymerase and exonuclease sites is 1:2 versus 4:1 for the wild-type enzyme. The exonuclease activity of A737V relative to the wild-type enzyme is unchanged on single-stranded DNA. However, the difference in partitioning the duplex DNA between the exonuclease and polymerase active sites results in an enhanced exonuclease activity for the antimutator enzyme.

Impaired mismatch extension by a herpes simplex DNA polymerase mutant with an editing nuclease defect

The D368A mutation within the 3'-5'-exonuclease domain of the herpes simplex type 1 DNA polymerase inactivates this nuclease and severely interferes with virus viability. Compared with the wild type enzyme, the D368A mutant exhibits substantially elevated rates of incorrect nucleotide incorporation, as measured in a LacZ reversion assay. This high rate occurs in the presence of high levels of dNTPs, a condition that forces the enzyme to extend mismatched primers. Hence, the mutant fails to correct many misincorporations that are removed in the wild type. In addition, the mutant shows a much reduced ability to replicate DNA templates primed with a 3'-mismatch as compared with wild type. This extension defect also appears more severe than observed for replicases which naturally lack editing nucleases. Based on these findings, we suggest that the inability of the D368A herpes simplex mutant polymerase to replicate beyond a mismatched base pair severely inhibits viral replication.

The proofreading pathway of bacteriophage T4 DNA polymerase

The base analog, 2-aminopurine (2AP), was used as a fluorescent reporter of the biochemical steps in the proofreading pathway catalyzed by bacteriophage T4 DNA polymerase. "Mutator" DNA polymerases that are defective in different steps in the exonucleolytic proofreading pathway were studied so that transient changes in fluorescence intensity could be equated with specific reaction steps. The G255S- and D131N-DNA polymerases can hydrolyze DNA, the final step in the proofreading pathway, but the mutator phenotype indicates a defect in one or more steps that prepare the primer-terminus for the cleavage reaction. The hydrolysis-defective D112A/E114A-DNA polymerase was also examined. Fluorescent enzyme-DNA complexes were preformed in the absence of Mg2+, and then rapid mixing, stopped-flow techniques were used to determine the fate of the fluorescent complexes upon the addition of Mg2+. Comparisons of fluorescence intensity changes between the wild type and mutant DNA polymerases were used to model the exonucleolytic proofreading pathway. These studies are consistent with a proofreading pathway in which the protein loop structure that contains residue Gly255 functions in strand separation and transfer of the primer strand from the polymerase active center to form a preexonuclease complex. Residue Asp131 acts at a later step in formation of the preexonuclease complex.

A new look at old mutants of T4 DNA polymerase

The DNA polymerase and nuclease activities of bacteriophage T4 DNA polymerase mutants are discussed in the context of the crystal structure of the closely related bacteriophage RB69 DNA polymerase.

Antimutator mutants in bacteriophage T4 and Escherichia coli

Antimutators are mutant strains that have reduced mutation rates compared to the corresponding wild-type strain. Their existence, along with mutator mutants that have higher mutation rates compared to the wild-type strain, are powerful evidence that mutation rates are genetically controlled. Compared to mutator mutants, antimutators have a very distinguishing property. Because they prevent normally occurring mutations, they, uniquely, are capable of providing insight into the mechanisms of spontaneous mutations. In this review, antimutator mutants are discussed in bacteriophage T4 and the bacterium Escherichia coli, with regard to their properties, possible mechanisms, and implications for the sources of spontaneous mutations in these two organisms.

Fidelity of Escherichia coli DNA polymerase III holoenzyme. The effects of beta, gamma complex processivity proteins and epsilon proofreading exonuclease on nucleotide misincorporation efficiencies

The fidelity of Escherichia coli DNA polymerase III (pol III) is measured and the effects of beta, gamma processivity and epsilon proofreading subunits are evaluated using a gel kinetic assay. Pol III holoenzyme synthesizes DNA with extremely high fidelity, misincorporating dTMP, dAMP, and dGMP opposite a template G target with efficiencies finc = 5.6 x 10(-6), 4.2 x 10(-7), and 7 x 10(-7), respectively. Elevated dGMP.G and dTMP.G misincorporation efficiencies of 3.2 x 10(-5) and 5.8 x 10(-4), attributed to a "dNTP-stabilized" DNA misalignment mechanism, occur when C and A, respectively, are located one base downstream from the template target G. At least 92% of misinserted nucleotides are excised by pol III holoenzyme in the absence of a next correct "rescue" nucleotide. As rescue dNTP concentrations are increased, pol III holoenzyme suffers a maximum 8-fold reduction in fidelity as proofreading of mispaired primer termini are reduced in competition with incorporation of a next correct nucleotide. Compared with pol III holoenzyme, the alpha holoenzyme, which cannot proofread, has 47-, 32-, and 13-fold higher misincorporation rates for dGMP.G, dTMP.G, and dAMP.G mispairs. Both the beta, gamma complex and the downstream nucleotide have little effect on the fidelity of catalytic alpha subunit. An analysis of the gel kinetic fidelity assay when multiple polymerase-DNA encounters occur is presented in the "Appendix" (see Fygenson, D. K., and Goodman, M. F. (1997) J. Biol. Chem. 272, 27931-27935 (accompanying paper)).

Escherichia coli DNA polymerase II catalyzes chromosomal and episomal DNA synthesis in vivo

We have investigated a role for Escherichia coli DNA polymerase II (Pol II) in copying chromosomal and episomal DNA in dividing cells in vivo. Forward mutation frequencies and rates were measured at two chromosomal loci, rpoB and gyrA, and base substitution and frameshift mutation frequencies were measured on an F'(lacZ) episome. To amplify any differences in polymerase error rates, methyl-directed mismatch repair was inactivated. When wild-type Pol II (polB+) was replaced on the chromosome by a proofreading-defective Pol II exo- (polBex1), there was a significant increase in mutation frequencies to rifampicin resistance (RifR) (rpoB) and nalidixic acid resistance (NalR) (gyrA). This increased mutagenesis occurred in the presence of an antimutator allele of E. coli DNA polymerase III (Pol III) (dnaE915), but not in the presence of wild-type Pol III (dnaE+), suggesting that Pol II can compete effectively with DnaE915 but not with DnaE+. Sequencing the RifR mutants revealed a G --> A hot spot highly specific to Pol II exo-. Pol II exo- caused a significant increase in the frequency of base substitution and frameshift mutations on F' episomes, even in dnaE+ cells, suggesting that Pol II is able to compete with Pol III for DNA synthesis on F episomes.

Using 2-aminopurine fluorescence and mutational analysis to demonstrate an active role of bacteriophage T4 DNA polymerase in strand separation required for 3' --> 5'-exonuclease activity

The fluorescence of 2-aminopurine deoxynucleotide positioned in a 3'-terminal mismatch was used to evaluate the pre-steady state kinetics of the 3' --> 5' exonuclease activity of bacteriophage T4 DNA polymerase on defined DNA substrates. DNA substrates with one, two, or three preformed terminal mispairs simulated increasing degrees of strand separation at a primer terminus. The effects of base pair stability and local DNA sequence on excision rates were investigated by using DNA substrates that were either relatively G + C- or A + T-rich. The importance of strand separation as a prerequisite to the hydrolysis of a terminal nucleotide was demonstrated by using a unique mutant DNA polymerase that could degrade single-stranded but not double-stranded DNA, unless two or more 3'-terminal nucleotides were unpaired. Our results led us to conclude that the reduced exonuclease activity of this mutant DNA polymerase on duplex DNA substrates is due to a defect in melting the primer terminus in preparation for the excision reaction. The mutated amino acid (serine substitution for glycine at codon 255) resides in a critical loop structure determined from a crystallographic study of an amino-terminal fragment of T4 DNA polymerase. These results suggest an active role for amino acid residues in the exonuclease domain of the T4 DNA polymerase in the strand separation step.