Bacteriophage T4 DNA polymerase mutations that confer sensitivity to the PPi analog phosphonoacetic acid

Excessive excision of correct nucleotides during DNA synthesis explained by replication hurdles

The proofreading exonuclease activity of replicative DNA polymerase excises misincorporated nucleotides during DNA synthesis, but these events are rare. Therefore, we were surprised to find that T7 replisome excised nearly 7% of correctly incorporated nucleotides during leading and lagging strand syntheses. Similar observations with two other DNA polymerases establish its generality. We show that excessive excision of correctly incorporated nucleotides is not due to events such as processive degradation of nascent DNA or spontaneous partitioning of primer‐end to the exonuclease site as a “cost of proofreading”. Instead, we show that replication hurdles, including secondary structures in template, slowed helicase, or uncoupled helicase–polymerase, increase DNA reannealing and polymerase backtracking, and generate frayed primer‐ends that are shuttled to the exonuclease site and excised efficiently. Our studies indicate that active‐site shuttling occurs at a high frequency, and we propose that it serves as a proofreading mechanism to protect primer‐ends from mutagenic extensions.

New Insights into DNA Polymerase Function Revealed by Phosphonoacetic Acid-Sensitive T4 DNA Polymerases

The bacteriophage T4 DNA polymerase (pol) and the closely related RB69 DNA pol have been developed into model enzymes to study family B DNA pols. While all family B DNA pols have similar structures and share conserved protein motifs, the molecular mechanism underlying natural drug resistance of nonherpes family B DNA pols and drug sensitivity of herpes DNA pols remains unknown. In the present study, we constructed T4 phages containing G466S, Y460F, G466S/Y460F, P469S, and V475W mutations in DNA pol. These amino acid substitutions replace the residues in drug-resistant T4 DNA pol with residues found in drug-sensitive herpes family DNA pols. We investigated whether the T4 phages expressing the engineered mutant DNA pols were sensitive to the antiviral drug phosphonoacetic acid (PAA) and characterized the in vivo replication fidelity of the phage DNA pols. We found that G466S substitution marginally increased PAA sensitivity, whereas Y460F substitution conferred resistance. The phage expressing a double mutant G466S/Y460F DNA pol was more PAA-sensitive. V475W T4 DNA pol was highly sensitive to PAA, as was the case with V478W RB69 DNA pol. However, DNA replication was severely compromised, which resulted in the selection of phages expressing more robust DNA pols that have strong ability to replicate DNA and contain additional amino acid substitutions that suppress PAA sensitivity. Reduced replication fidelity was observed in all mutant phages expressing PAA-sensitive DNA pols. These observations indicate that PAA sensitivity and fidelity are balanced in DNA pols that can replicate DNA in different environments.

From Structure-Function Analyses to Protein Engineering for Practical Applications of DNA Ligase

DNA ligases are indispensable in all living cells and ubiquitous in all organs. DNA ligases are broadly utilized in molecular biology research fields, such as genetic engineering and DNA sequencing technologies. Here we review the utilization of DNA ligases in a variety of in vitro gene manipulations, developed over the past several decades. During this period, fewer protein engineering attempts for DNA ligases have been made, as compared to those for DNA polymerases. We summarize the recent progress in the elucidation of the DNA ligation mechanisms obtained from the tertiary structures solved thus far, in each step of the ligation reaction scheme. We also present some examples of engineered DNA ligases, developed from the viewpoint of their three-dimensional structures.

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.

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.

Utility of the bacteriophage RB69 polymerase gp43 as a surrogate enzyme for herpesvirus orthologs

Viral polymerases are important targets in drug discovery and development efforts. Most antiviral compounds that are currently approved for treatment of infection with members of the herpesviridae family were shown to inhibit the viral DNA polymerase. However, biochemical studies that shed light on mechanisms of drug action and resistance are hampered primarily due to technical problems associated with enzyme expression and purification. In contrast, the orthologous bacteriophage RB69 polymerase gp43 has been crystallized in various forms and therefore serves as a model system that provides a better understanding of structure–function relationships of polymerases that belong the type B family. This review aims to discuss strengths, limitations, and opportunities of the phage surrogate with emphasis placed on its utility in the discovery and development of anti-herpetic drugs.

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.

Drug-sensitive DNA polymerase δ reveals a role for mismatch repair in checkpoint activation in yeast

We have used a novel method to activate the DNA damage S-phase checkpoint response in Saccharomyces cerevisiae to slow lagging-strand DNA replication by exposing cells expressing a drug-sensitive DNA polymerase δ (L612M-DNA pol δ) to the inhibitory drug phosphonoacetic acid (PAA). PAA-treated pol3-L612M cells arrest as large-budded cells with a single nucleus in the bud neck. This arrest requires all of the components of the S-phase DNA damage checkpoint: Mec1, Rad9, the DNA damage clamp Ddc1-Rad17-Mec3, and the Rad24-dependent clamp loader, but does not depend on Mrc1, which acts as the signaling adapter for the replication checkpoint. In addition to the above components, a fully functional mismatch repair system, including Exo1, is required to activate the S-phase damage checkpoint and for cells to survive drug exposure. We propose that mismatch repair activity produces persisting single-stranded DNA gaps in PAA-treated pol3-L612M cells that are required to increase DNA damage above the threshold needed for checkpoint activation. Our studies have important implications for understanding how cells avoid inappropriate checkpoint activation because of normal discontinuities in lagging-strand replication and identify a role for mismatch repair in checkpoint activation that is needed to maintain genome integrity.

Phosphonoformic acid inhibits viral replication by trapping the closed form of the DNA polymerase

Phosphonoformic acid (PFA, foscarnet) belongs to a class of antiviral drugs that inhibit the human cytomegalovirus DNA polymerase (UL54) by mimicking the pyrophosphate leaving group of the nucleotide transfer reaction. Difficulties expressing UL54 have hampered investigation of the precise structural requirements rendering inhibition by this drug. However, a previously engineered chimeric DNA polymerase, constructed by mutating the homologous polymerase from bacteriophage RB69 (gp43) to express several variable elements from UL54, can bypass this obstacle because of its favorable expression and acquired sensitivity to PFA (Tchesnokov, E. P., Obikhod, A., Schinazi, R. F., and Götte, M. (2008) J. Biol. Chem. 283, 34218-34228). Here, we compare two crystal structures that depict the chimeric DNA polymerase with and without PFA bound. PFA is visualized for the first time in the active site of a DNA polymerase, where interactions are resolved between the PP(i) mimic and two basic residues absolutely conserved in the fingers domain of family B polymerases. PFA also chelates metal ion B, the cation that contacts the triphosphate tail of the incoming nucleotide. These DNA complexes utilize a primer-template pair enzymatically chain-terminated by incorporation of acyclo-GMP, the phosphorylated form of the anti-herpes drug acyclovir. We postulate that the V478W mutation present in the chimera is critical in that it pushes the fingers domain to more readily adopt the closed conformation whether or not the drug is bound. The closed state of the fingers domain traps the variant polymerase in the untranslocated state and increases affinity for PFA. This finding provides a model for the mechanism of UL54 stalling by PFA.

Identification of a new motif in family B DNA polymerases by mutational analyses of the bacteriophage t4 DNA polymerase

Structure-based protein sequence alignments of family B DNA polymerases revealed a conserved motif that is formed from interacting residues between loops from the N-terminal and palm domains and between the N-terminal loop and a conserved proline residue. The importance of the motif for function of the bacteriophage T4 DNA polymerase was revealed by suppressor analysis. T4 DNA polymerases that form weak replicating complexes cannot replicate DNA when the dGTP pool is reduced. The conditional lethality provides the means to identify amino acid substitutions that restore replication activity under low-dGTP conditions either by correcting the defect produced by the first amino acid substitution or by generally increasing the stability of polymerase complexes; the second type are global suppressors that can effectively counter the reduced stability caused by a variety of amino acid substitutions. Some amino acid substitutions that increase the stability of polymerase complexes produce a new phenotype-sensitivity to the antiviral drug phosphonoacetic acid. Amino acid substitutions that confer decreased ability to replicate DNA under low-dGTP conditions or drug sensitivity were identified in the new motif, which suggests that the motif functions in regulating the stability of polymerase complexes. Additional suppressor analyses revealed an apparent network of interactions that link the new motif to the fingers domain and to two patches of conserved residues that bind DNA. The collection of mutant T4 DNA polymerases provides a foundation for future biochemical studies to determine how DNA polymerases remain stably associated with DNA while waiting for the next available dNTP, how DNA polymerases translocate, and the biochemical basis for sensitivity to antiviral drugs.

The use of 2-aminopurine fluorescence to study DNA polymerase function

The fluorescence of the base analog 2-aminopurine (2AP) is used in highly sensitive assays to determine kinetic parameters for DNA polymerase catalyzed reactions, including exonucleolytic proofreading and nucleotide binding and incorporation. Since 2AP fluorescence can also be used to probe DNA polymerase-induced conformational changes in 2AP-labeled DNA substrates, reaction steps that occur before product formation can be detected. Instruction is provided here in the use of 2AP fluorescence in steady-state and presteady-state assays to study DNA polymerase function and DNA replication.

DNA polymerase proofreading: active site switching catalyzed by the bacteriophage T4 DNA polymerase

DNA polymerases achieve high-fidelity DNA replication in part by checking the accuracy of each nucleotide that is incorporated and, if a mistake is made, the incorrect nucleotide is removed before further primer extension takes place. In order to proofread, the primer-end must be separated from the template strand and transferred from the polymerase to the exonuclease active center where the excision reaction takes place; then the trimmed primer-end is returned to the polymerase active center. Thus, proofreading requires polymerase-to-exonuclease and exonuclease-to-polymerase active site switching. We have used a fluorescence assay that uses differences in the fluorescence intensity of 2-aminopurine (2AP) to measure the rates of active site switching for the bacteriophage T4 DNA polymerase. There are three findings: (i) the rate of return of the trimmed primer-end from the exonuclease to the polymerase active center is rapid, >500 s⁻¹; (ii) T4 DNA polymerase can remove two incorrect nucleotides under single turnover conditions, which includes presumed exonuclease-to-polymerase and polymerase-to-exonuclease active site switching steps and (iii) proofreading reactions that initiate in the polymerase active center are not intrinsically processive.

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.

Role of helix P of the human cytomegalovirus DNA polymerase in resistance and hypersusceptibility to the antiviral drug foscarnet

Mutations in the human cytomegalovirus DNA polymerase (UL54) can not only decrease but also increase susceptibility to the pyrophosphate (PP(i)) analogue foscarnet. The proximity of L802M, which confers resistance, and K805Q, which confers hypersusceptibility, suggests a possible unifying mechanism that affects drug susceptibility in one direction or the other. We found that the polymerase activities of L802M- and K805Q-containing mutant enzymes were literally indistinguishable from that of wild-type UL54; however, susceptibility to foscarnet was decreased or increased, respectively. A comparison with the crystal structure model of the related RB69 polymerase suggests that L802 and K805 are located in the conserved alpha-helix P that is implicated in nucleotide binding. Although L802 and K805 do not appear to make direct contacts with the incoming nucleotide, it is conceivable that changes at these residues could exert their effects through the adjacent, highly conserved amino acids Q807 and/or K811. Our data show that a K811A substitution in UL54 causes reductions in rates of nucleotide incorporation. The activity of the Q807A mutant is only marginally affected, while this enzyme shows relatively high levels of resistance to foscarnet. Based on these data, we suggest that L802M exerts its effects through subtle structural changes in alpha-helix P that affect the precise positioning of Q807 and, in turn, its presumptive involvement in binding of foscarnet. In contrast, the removal of a positive charge associated with the K805Q change may facilitate access or increase affinity to the adjacent Q807.

Roles of DNA Polymerases in Replication, Repair, and Recombination in Eukaryotes

The functioning of the eukaryotic genome depends on efficient and accurate DNA replication and repair. The process of replication is complicated by the ongoing decomposition of DNA and damage of the genome by endogenous and exogenous factors. DNA damage can alter base coding potential resulting in mutations, or block DNA replication, which can lead to double-strand breaks (DSB) and to subsequent chromosome loss. Replication is coordinated with DNA repair systems that operate in cells to remove or tolerate DNA lesions. DNA polymerases can serve as sensors in the cell cycle checkpoint pathways that delay cell division until damaged DNA is repaired and replication is completed. Eukaryotic DNA template-dependent DNA polymerases have different properties adapted to perform an amazingly wide spectrum of DNA transactions. In this review, we discuss the structure, the mechanism, and the evolutionary relationships of DNA polymerases and their possible functions in the replication of intact and damaged chromosomes, DNA damage repair, and recombination.

Multiplexed DNA sequencing-by-synthesis

We report a new DNA sequencing-by-synthesis method in which the sequences of DNA templates, hybridized to a surface-immobilized array of DNA primers, are determined by sensing the number of nucleotides by which the primers in each array spot are extended in sequential DNA polymerase-catalyzed nucleotide incorporation reactions, each with a single fluorescein-labeled deoxyribonucleoside triphosphate (dNTP) species. The fluorescein label is destroyed after each readout by a photostimulated reaction with diphenyliodonium chloride. A DNA polymerase with enhanced ability to incorporate, and to extend beyond, modified nucleotides is used. Self-quenching of adjacent fluorescein labels, which impedes readout of homopolymeric runs, is avoided by diluting the labeled dNTP with unlabeled reagent. Misincorporation effects have been quantified and are small; however, low-level contamination of dNTPs with other nucleotides mimics misincorporation and can produce significant false-positive signals. These impurities are removed by polymerase-catalyzed incorporation into complementary "cleaning duplexes." Here, we demonstrate the accurate sequence readout for a small array of known DNA templates, the ability to quantify homopolymeric runs, and a short sequencing example of sections of the wild-type and mutant BRCA1 gene. For a 20,000-spot array, readout rates in excess of 6000 bases per minute are projected.

Sensitivity to phosphonoacetic acid: a new phenotype to probe DNA polymerase delta in Saccharomyces cerevisiae

A mutant allele (pol3-L612M) of the DNA polymerase delta gene in Saccharomyces cerevisiae that confers sensitivity to the antiviral drug phosphonoacetic acid (PAA) was constructed. We report that PAA-sensitivity tagging DNA polymerases is a useful method for selectively and reversibly inhibiting one type of DNA polymerase. Our initial studies reveal that replication by the L612M-DNA pol delta requires Rad27 flap endonuclease activity since the pol3-L612M strain is not viable in the absence of RAD27 function. The L612M-DNA pol delta also strongly depends on mismatch repair (MMR). Reduced viability is observed in the absence of any of the core MMR proteins-Msh2, Mlh1, or Pms1-and severe sensitivity to PAA is observed in the absence of the core proteins Msh6 or Exo1, but not Msh3. We propose that pol3-L612M cells need the Rad27 flap endonuclease and MMR complexes composed of Msh2/Msh6, Mlh1/Pms1, and Exo1 for correct processing of Okazaki fragments.

Drug resistance patterns of recombinant herpes simplex virus DNA polymerase mutants generated with a set of overlapping cosmids and plasmids

Herpes simplex virus (HSV) DNA polymerase (Pol) mutations can confer resistance to all currently available antiherpetic drugs. However, discrimination between mutations responsible for drug resistance and those that are part of viral polymorphism can be difficult with current methodologies. A new system is reported for rapid generation of recombinant HSV type 1 (HSV-1) DNA Pol mutants based on transfection of a set of overlapping viral cosmids and plasmids. With this approach, twenty HSV-1 recombinants with single or dual mutations within the DNA pol gene were successfully generated and subsequently evaluated for their susceptibilities to acyclovir (ACV), foscarnet (FOS), cidofovir (CDV), and adefovir (ADV). Mutations within DNA Pol conserved regions II (A719T and S724N), VI (L778M, D780N, and L782I), and I (F891C) were shown to induce cross-resistance to ACV, FOS, and ADV, with two of these mutations (S724N and L778M) also conferring significant reduction in CDV susceptibility. Mutant F891C was associated with the highest levels of resistance towards ACV and FOS and was strongly impaired in its replication capacity. One mutation (D907V) lying outside of the conserved regions was also associated with this ACV-, FOS-, and ADV-resistant phenotype. Some mutations (K522E and Y577H) within the delta-region C were lethal, whereas others (P561S and V573M) induced no resistance to any of the drugs tested. Recombinants harboring mutations within conserved regions V (N961K) and VII (Y941H) were resistant to ACV but susceptible to FOS. Finally, mutations within conserved region III were associated with various susceptibility profiles. This new system allows a rapid and accurate evaluation of the functional role of various DNA Pol mutations, which should translate into improved management of drug-resistant HSV infections.

Bacteriophage T4 genome

Phage T4 has provided countless contributions to the paradigms of genetics and biochemistry. Its complete genome sequence of 168,903 bp encodes about 300 gene products. T4 biology and its genomic sequence provide the best-understood model for modern functional genomics and proteomics. Variations on gene expression, including overlapping genes, internal translation initiation, spliced genes, translational bypassing, and RNA processing, alert us to the caveats of purely computational methods. The T4 transcriptional pattern reflects its dependence on the host RNA polymerase and the use of phage-encoded proteins that sequentially modify RNA polymerase; transcriptional activator proteins, a phage sigma factor, anti-sigma, and sigma decoy proteins also act to specify early, middle, and late promoter recognition. Posttranscriptional controls by T4 provide excellent systems for the study of RNA-dependent processes, particularly at the structural level. The redundancy of DNA replication and recombination systems of T4 reveals how phage and other genomes are stably replicated and repaired in different environments, providing insight into genome evolution and adaptations to new hosts and growth environments. Moreover, genomic sequence analysis has provided new insights into tail fiber variation, lysis, gene duplications, and membrane localization of proteins, while high-resolution structural determination of the "cell-puncturing device," combined with the three-dimensional image reconstruction of the baseplate, has revealed the mechanism of penetration during infection. Despite these advances, nearly 130 potential T4 genes remain uncharacterized. Current phage-sequencing initiatives are now revealing the similarities and differences among members of the T4 family, including those that infect bacteria other than Escherichia coli. T4 functional genomics will aid in the interpretation of these newly sequenced T4-related genomes and in broadening our understanding of the complex evolution and ecology of phages-the most abundant and among the most ancient biological entities on Earth.

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.

Dinucleotide repeat expansion catalyzed by bacteriophage T4 DNA polymerase in vitro

DNA replication normally occurs with high fidelity, but certain "slippery" regions of DNA with tracts of mono-, di-, and trinucleotide repeats are frequently mutation hot spots. We have developed an in vitro assay to study the mechanism of dinucleotide repeat expansion. The primer-template resembles a base excision repair substrate with a single nucleotide gap centered opposite a tract of nine CA repeats; nonrepeat sequences flank the dinucleotide repeats. DNA polymerases are expected to repair the gap, but further extension is possible if the DNA polymerase can displace the downstream oligonucleotide. We report here that the wild type bacteriophage T4 DNA polymerase carries out gap and strand displacement replication and also catalyzes a dinucleotide expansion reaction. Repeat expansion was not detected for an exonuclease-deficient T4 DNA polymerase or for Escherichia coli DNA polymerase I. The dinucleotide repeat expansion reaction catalyzed by wild type T4 DNA polymerase required a downstream oligonucleotide to "stall" replication and 3' --> 5' exonuclease activity to remove the 3'-nonrepeat sequence adjacent to the repeat tract in the template strand. These results suggest that dinucleotide repeat expansion may be stimulated in vivo during DNA repair or during processing of Okazaki fragments.

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.

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.

Rates of spontaneous mutation

Rates of spontaneous mutation per genome as measured in the laboratory are remarkably similar within broad groups of organisms but differ strikingly among groups. Mutation rates in RNA viruses, whose genomes contain ca. 10(4) bases, are roughly 1 per genome per replication for lytic viruses and roughly 0.1 per genome per replication for retroviruses and a retrotransposon. Mutation rates in microbes with DNA-based chromosomes are close to 1/300 per genome per replication; in this group, therefore, rates per base pair vary inversely and hugely as genome sizes vary from 6 x 10(3) to 4 x 10(7) bases or base pairs. Mutation rates in higher eukaryotes are roughly 0.1-100 per genome per sexual generation but are currently indistinguishable from 1/300 per cell division per effective genome (which excludes the fraction of the genome in which most mutations are neutral). It is now possible to specify some of the evolutionary forces that shape these diverse mutation rates.

Identification of a transient excision intermediate at the crossroads between DNA polymerase extension and proofreading pathways

DNA polymerases achieve accurate DNA replication through a delicate balance between primer elongation and proofreading. While insufficient proofreading results in DNA replication errors, indiscriminate removal of correct along with incorrect nucleotides is wasteful and may prevent completion of DNA synthesis. The transition between polymerization and proofreading modes is proposed to be governed by a kinetic barrier that prevents proofreading unless the rate of primer elongation is significantly reduced by the presence of an incorrect base pair at the primer-terminus. We have used mutational analysis, coupled with a sensitive, fluorescence-based assay to characterize intermediate steps in the proofreading pathway. A highly fluorescent complex forms between the bacteriophage T4 DNA polymerase and DNA primer-templates labeled at the 3' terminus with the base analog 2-aminopurine. Formation of the fluorescent complex appears to be a rate-determining step in the proofreading pathway and is impaired for several mutator T4 DNA polymerases with amino acid substitutions in the exonuclease domain. Although these mutant DNA polymerases are proficient in hydrolysis, their reduced ability to form the fluorescent complex imposes a higher kinetic barrier. As a consequence, the mutant DNA polymerases proofread less frequently, resulting in more DNA replication errors.

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.

Replication of O6-methylguanine-containing DNA by repair and replicative DNA polymerases

The biological consequences of O6-methylguanine (m6G) in DNA are well recognized. When template m6G is encountered by DNA polymerases, replication is hindered and trans-lesion replication results in the preferential incorporation of dTMP opposite template m6G. Thus, unrepaired m6G in DNA is both cytotoxic and mutagenic. Yet, cell lines tolerant to m6G in DNA have been isolated, which indicates that some cellular DNA polymerases may replicate m6G-containing DNA with reasonable efficiency. Previous reports suggested that mammalian pol beta could not replicate m6G-containing DNA, but we find that pol beta can catalyze trans-lesion replication; however, the lesion must reside in the optimal context for pol beta activity, single- or short nucleotide gapped substrates. Primed single-stranded DNA templates, with or without template m6G, were poor substrates for pol beta as reported in earlier studies. In contrast, trans-lesion replication by bacteriophage T4 DNA polymerase was observed for primed single-stranded DNA templates. Replication of m6G-containing DNA by T4 DNA polymerase required the gp45 accessory protein that clamps the polymerase to the DNA template. The rate-limiting step in replicating m6G-containing DNAs by both DNA polymerases tested was incorporation of dTMP across from the lesion.

Improving the fidelity of Thermus thermophilus DNA ligase

The DNA ligase from Thermus thermophilus (Tth DNA ligase) seals single-strand breaks (nicks) in DNA duplex substrates. The specificity and thermostability of this enzyme are exploited in the ligase chain reaction (LCR) and ligase detection reaction (LDR) to distinguish single base mutations associated with genetic diseases. Herein, we describe a quantitative assay using fluorescently labeled substrates to study the fidelity of Tth DNA ligase. The enzyme exhibits significantly greater discrimination against all single base mismatches on the 3'-side of the nick in comparison with those on the 5'-side of the nick. Among all 12 possible single base pair mismatches on the 3'-side of the nick, only T-G and G-T mismatches generated a quantifiable level of ligation products after 23 h incubation. The high fidelity of Tth DNA ligase can be improved further by introducing a mismatched base or a universal nucleoside analog at the third position of the discriminating oligonucleotide. Finally, two mutant Tth DNA ligases, K294R and K294P, were found to have increased fidelity using this assay.

Selection of bacteriophage T4 antimutator DNA polymerases: a link between proofreading and sensitivity to phosphonoacetic acid

During DNA replication, DNA polymerases alternate between DNA synthesis and proofreading the newly synthesized DNA. In order to understand the molecular details of how DNA polymerases determine the balance between polymerase and proofreading activities, it would be useful to have mutants which switch between the two activities either more or less frequently. Antimutator DNA polymerases switch more frequently and thus have more opportunity for proofreading. We have observed that mutant DNA polymerases which proofread less frequently have a mutator phenotype and are inhibited by the pyrophosphate analogue phosphonoacetic acid. Sensitivity to phosphonoacetic acid can be used to isolate second-site suppressor mutations. These suppressor mutations encode amino acid substitutions which produce antimutator DNA polymerases.

Use of genetic analyses to probe structure, function, and dynamics of bacteriophage T4 DNA polymerase

Functionally distinct mutant DNA polymerases have been isolated by the genetic selection strategies described here. These methods can be supplemented by the use of targeted mutagenesis procedures to enhance mutagenesis of DNA polymerase genes and to direct mutagenesis to specific sites in cloned DNA polymerases (see [22-24, 28], this volume). The power of genetic selection is in the ability to identify amino acid residues that are critical for protein structure and function that may not be obvious from studies of structural data alone. For the study of DNA polymerases, it is essential to identify residues involved in the movement of the DNA polymerase along the DNA template and in shuttling the DNA between the polymerase and exonuclease active centers. Ongoing studies are directed toward these goals.

Pre-steady-state kinetic analysis of sequence-dependent nucleotide excision by the 3'-exonuclease activity of bacteriophage T4 DNA polymerase

The effects of local DNA sequence on the proofreading efficiency of wild-type T4 DNA polymerase were examined by measuring the kinetics of removal of the fluorescent nucleotide analog 2-aminopurine deoxynucleoside monophosphate (dAPMP) from primer/templates of defined sequences. The effects of (1) interactions with the 5'-neighboring bases, (2) base pair stability, and (3) G.C content of the surrounding sequences on the pre-steady-state kinetics of dAPMP excision were measured. Rates of excision dAPMP from a primer 3'-terminus located opposite a template T (AP.T base pair) increased, over a 3-fold range, with the 5'-neighbor to AP in the order C < G < T < A. Rates of removal of dAPMP from AP.X base pairs located in the same surrounding sequence increased as AP.T < AP.A < AP.C < AP.G, which correlates with the decrease in the stabilities of these base pairs predicted by Tm measurements. A key finding was that AP was excised at a slower rate when mispaired opposite C located next to four G.C base pairs than when correctly paired opposite T next to four A.T base pairs, suggesting that exonuclease mismatch removal specificities may be enhanced to a much greater extent by instabilities of local primer termini than by specific recognition of incorrect base pairs. In polymerase-initiated reactions, biphasic reaction kinetics were observed for the excision of AP within most but not all sequence contexts. Rates of the rapid phases (30-40 s-1) were relatively insensitive to sequence context. Rapid-phase rates reflect the rate constants for exonucleolytic excision of dAPMP from melted primer termini for both correct and incorrect base pairs and were roughly comparable to rates of removal of dAPMP from single-stranded DNA (65-80 s-1). Rates of the slow phases (3-13 s-1) were dependent on sequence context; the slow phase may reflect the rate of switching from the polymerase to the exonuclease active site, or perhaps the conversion of a primer/template terminus from an annealed to a melted state in the exonuclease active site. These data, using wild-type T4 DNA polymerase and two exonuclease-deficient T4 polymerases, support a model in which exonuclease excision occurs on melted primer 3'-termini for both mismatched and correctly matched primer termini, and where specificity favoring removal of terminally mismatched base pairs is determined by the much larger fraction of melted-out primer 3'-termini for mispairs compared to that for correct pairs.

Analysis of inhibitors of bacteriophage T4 DNA polymerase

Bacteriophage T4 DNA polymerase was inhibited by butylphenyl nucleotides, aphidicolin and pyrophosphate analogs, but with lower sensitivities than other members of the B family DNA polymerases. The nucleotides N2-(p-n-butylphenyl)dGTP (BuPdGTP) and 2-(p-n-butylanilino)dATP (BuAdATP) inhibited T4 DNA polymerase with competitive Ki values of 0.82 and 0.54 microM with respect to dGTP and dATP, respectively. The same compounds were more potent inhibitors in truncated assays lacking the competitor dNTP, displaying apparent Ki values of 0.001 and 0.0016 microM, respectively. BuPdGTP was a substrate for T4 DNA polymerase, and the resulting 3'-BuPdG-primer:template was bound strongly by the enzyme. Each of the non-substrate derivatives, BuPdGDP and BuPdGMPCH2PP, inhibited T4 DNA polymerase with similar potencies in both the truncated and variable competitor assays. These results indicate that BuPdGTP inhibits T4 DNA polymerase by distinct mechanisms depending upon the assay conditions. Reversible competitive inhibition predominates in the presence of dGTP, and incorporation in the absence of dGTP leads to potent inhibition by the modified primer:template. The implications of these findings for the use of these inhibitors in the study of B family DNA polymerases is discussed.

Genetic characterization of the vaccinia virus DNA polymerase: cytosine arabinoside resistance requires a variable lesion conferring phosphonoacetate resistance in conjunction with an invariant mutation localized to the 3'-5' exonuclease domain

In this report, we describe the isolation, molecular genetic mapping, and phenotypic characterization of vaccinia virus mutants resistant to cytosine arabinoside (araC) and phosphonoacetic acid (PAA). At 37 degrees C, 8 microM araC was found to prevent macroscopic plaque formation by wild-type virus and to cause a 10(4)-fold reduction in viral yield. Mutants resistant to 8 microM araC were selected by serial passage of a chemically mutagenized viral stock in the presence of drug. Because recovery of mutants required that initial passages be performed under less stringent selective conditions, and because plaque-purified isolates were found to be cross-resistant to 200 micrograms of PAA per ml, it seemed likely that resistance to araC required more than one genetic lesion. This hypothesis was confirmed by genetic and physical mapping of the responsible mutations. PAAr was accorded by the acquisition of one of three G-A transitions in the DNA polymerase gene which individually alter cysteine 356 to tyrosine, glycine 372 to aspartic acid, or glycine 380 to serine. AraCr was found to require one of these substitutions plus an additional T-C transition within codon 171 of the DNA polymerase gene, a change which replaces the wild-type phenylalanine with serine. Congenic viral stocks carrying one of the three PAAr lesions, either alone or in conjunction with the upstream araCr lesion, in an otherwise wild-type background were generated. The PAAr mutations conferred nearly complete resistance to PAA, a slight degree of resistance to araC, hypersensitivity to aphidicolin, and decreased spontaneous mutation frequency. Addition of the mutation at codon 171 significantly augmented araC resistance and aphidicolin hypersensitivity but caused no further change in mutation frequency. Several lines of evidence suggest that the PAAr mutations primarily affect the deoxynucleoside triphosphate-binding site, whereas the codon 171 mutation, lying within a conserved motif associated with 3'-5' exonuclease function, is postulated to affect the proofreading exonuclease of the DNA polymerase.