B family DNA polymerases asymmetrically recognize pyrimidines and purines

We utilized a series of pyrimidine analogues modified at O(2), N-3, and N(4)/O(4) to determine if two B family DNA polymerases, human DNA polymerase α and herpes simplex virus I DNA polymerase, choose whether to polymerize pyrimidine dNTPs using the same mechanisms they use for purine dNTPs. Removing O(2) of a pyrimidine dNTP vastly decreased the level of incorporation by these enzymes and also compromised fidelity in the case of C analogues, while removing O(2) from the templating base had more modest effects. Removing the Watson-Crick hydrogen bonding groups of N-3 and N(4)/O(4) greatly impaired polymerization, both of the resulting dNTP analogues and of natural dNTPs opposite these pyrimidine analogues when present in the template strand. Thus, the Watson-Crick hydrogen bonding groups of a pyrimidine clearly play an important role in enhancing correct dNTP polymerization but are not essential for preventing misincorporation. These studies also indicate that DNA polymerases recognize bases extremely asymmetrically, both in terms of whether they are a purine or pyrimidine and whether they are in the template or are the incoming dNTP. The mechanistic implications of these results with regard to how polymerases discriminate between right and wrong dNTPs are discussed.     

Relations between synthesis of deoxyribonucleotides and DNA replication in 3T6 fibroblasts

In exponentially growing 3T6 cells, the synthesis of deoxythymidine triphosphate (dTTP) is balanced by its utilization for DNA replication, with a turnover of the dTTP pool of around 5 min. We now investigate the effects of two inhibitors of DNA synthesis (aphidicolin and hydroxyurea) on the synthesis and degradation of pyrimidine deoxynucleoside triphosphates (dNTPs). Complete inhibition of DNA replication with aphidicolin did not decrease the turnover of pyrimidine dNTP pools labeled from the corresponding [3H]deoxynucleosides, only partially inhibited the in situ activity of thymidylate synthetase and resulted in excretion into the medium of thymidine derived from breakdown of dTTP synthesized de novo. These data demonstrate continued synthesis of dTTP in the absence of DNA replication. In contrast, hydroxyurea decreased the turnover of pyrimidine dNTP pools 5-50-fold. Hydroxyurea is an inhibitor of ribonucleotide reductase and stops DNA synthesis by depleting cells of purine dNTPs but not pyrimidine dNTPs. Our results suggest that degradation of dNTPs is turned off by an unknown mechanism when de novo synthesis is blocked.     

Fidelity of replication of bacteriophage phi X174 DNA in vitro and in vivo

Seven different revertants of bacteriophage phi X174am16 (AB5276G leads to T) have been isolated and the nature of the reversions determined by sequencing their DNA. The revertants each differ from am16 by just a single base substitution. These may be distinguished with varying degrees of ease by characteristic temperature sensitivities of growth. This has facilitated the determination of the frequency at which DNA polymerase III catalyses different types of substitution mutations in copying phi X174 DNA in vitro and in vivo. During the replicative form (RF) leads to single-stranded (SS) stage of replication in vitro, four different revertants may be readily produced according to well-defined rate laws on biasing the concentrations of dNTPs. Transversion mutations are found to be formed predominantly by purine x purine mismatching, whilst transitions are formed predominantly by G x T mismatching. The substitutions via G x T and G x A mismatches are estimated to occur at similar frequencies in vivo. The two most common revertants isolated in vivo, however, are not those readily produced during the RF leads to SS stage in vitro but are those produced on purine x purine mismatching in the SS leads to RF stage. The accuracy of the DNA polymerase in vitro appears to be similar to that in this stage in vivo. However, the overall accuracy of the RF leads to SS replication in vivo is more accurate than predicted from the measurements of the accuracy in vitro.     

Genome-wide analysis of the specificity and mechanisms of replication infidelity driven by imbalanced dNTP pools

The absolute and relative concentrations of the four dNTPs are key determinants of DNA replication fidelity, yet the consequences of altered dNTP pools on replication fidelity have not previously been investigated on a genome-wide scale. Here, we use deep sequencing to determine the types, rates and locations of uncorrected replication errors that accumulate in the nuclear genome of a mismatch repair-deficient diploid yeast strain with elevated dCTP and dTTP concentrations. These imbalanced dNTP pools promote replication errors in specific DNA sequence motifs suggesting increased misinsertion and increased mismatch extension at the expense of proofreading. Interestingly, substitution rates are similar for leading and lagging strand replication, but are higher in regions replicated late in S phase. Remarkably, the rate of single base deletions is preferentially increased in coding sequences and in short rather than long mononucleotides runs. Based on DNA sequence motifs, we propose two distinct mechanisms for generating single base deletions in vivo. Collectively, the results indicate that elevated dCTP and dTTP pools increase mismatch formation and decrease error correction across the nuclear genome, and most strongly increases mutation rates in coding and late replicating sequences.     

Nucleotide selection by the Y-family DNA polymerase Dpo4 involves template translocation and misalignment

Y-family DNA polymerases play a crucial role in translesion DNA synthesis. Here, we have characterized the binding kinetics and conformational dynamics of the Y-family polymerase Sulfolobus solfataricus P2 DNA polymerase IV (Dpo4) using single-molecule fluorescence. We find that in the absence of dNTPs, the binary complex shuttles between two different conformations within ∼1 s. These data are consistent with prior crystal structures in which the nucleotide binding site is either occupied by the terminal base pair (preinsertion conformation) or empty following Dpo4 translocation by 1 base pair (insertion conformation). Most interestingly, on dNTP binding, only the insertion conformation is observed and the correct dNTP stabilizes this complex compared with the binary complex, whereas incorrect dNTPs destabilize it. However, if the n+1 template base is complementary to the incoming dNTP, a structure consistent with a misaligned template conformation is observed, in which the template base at the n position loops out. This structure provides evidence for a Dpo4 mutagenesis pathway involving a transient misalignment mechanism.     

Quantitation of cellular deoxynucleoside triphosphates

Eukaryotic cells contain a delicate balance of minute amounts of the four deoxyribonucleoside triphosphates (dNTPs), sufficient only for a few minutes of DNA replication. Both a deficiency and a surplus of a single dNTP may result in increased mutation rates, faulty DNA repair or mitochondrial DNA depletion. dNTPs are usually quantified by an enzymatic assay in which incorporation of radioactive dATP (or radioactive dTTP in the assay for dATP) into specific synthetic oligonucleotides by a DNA polymerase is proportional to the concentration of the unknown dNTP. We find that the commonly used Klenow DNA polymerase may substitute the corresponding ribonucleotide for the unknown dNTP leading in some instances to a large overestimation of dNTPs. We now describe assay conditions for each dNTP that avoid ribonucleotide incorporation. For the dTTP and dATP assays it suffices to minimize the concentrations of the Klenow enzyme and of labeled dATP (or dTTP); for dCTP and dGTP we had to replace the Klenow enzyme with either the Taq DNA polymerase or Thermo Sequenase. We suggest that in some earlier reports ribonucleotide incorporation may have caused too high values for dGTP and dCTP.     

Dynamics of termination during in vitro replication of ultraviolet-irradiated DNA with DNA polymerase III holoenzyme of Escherichia coli

During in vitro replication of UV-irradiated single-stranded DNA with Escherichia coli DNA polymerase III holoenzyme termination frequently occurs at pyrimidine photodimers. The termination stage is dynamic and characterized by at least three different events: repeated dissociation-reinitiation cycles of the polymerase at the blocked termini; extensive hydrolysis of ATP to ADP and inorganic phosphate; turnover of dNTPs into dNMP. The reinitiation events are nonproductive and are not followed by further elongation. The turnover of dNTPs into dNMPs is likely to result from repeated cycles of insertion of dNMP residues opposite the blocking lesions followed by their excision by the 3'----5' exonucleolytic activity of the polymerase. Although all dNTPs are turned over, there is a preference for dATP, indicating that DNA polymerase III holoenzyme has a preference for inserting a dAMP residue opposite blocking pyrimidine photodimers. We suggest that the inability of the polymerase to bypass photodimers during termination is due to the formation of defective initiation-like complexes with reduced stability at the blocked termini.     

Patch size and base composition of ultraviolet light-induced repair synthesis in toluenized Escherichia coli.

Small patch repair in ultraviolet-irradiated Escherichia coli is saturated at deoxyrmcleoside triphosphate concentrations (～ 2 μm of each dNTP) that are severely limiting for DNA replication. The low requirement of the repair process for dNTPs permits direct demonstration of u.v.-induced DNA synthesis by incorporation of labeled dNTP and determination of its extent, base composition and patch size.It is concluded that DNA polymeraso 1 is involved in small patch repair and that an average of 13 to 16 nucleotides are re-inserted per pyrimidine dimer excised. The average base composition of the repaired stretches adjacent to the dimers is similar to that of total E. coli DNA.An assay utilizing endogenous u.v.-specific endonuclease to determine dimer excision is described.     

Differential extension of 3' mispairs is a major contribution to the high fidelity of calf thymus DNA polymerase-alpha

The fidelity of DNA polymerase-alpha-primase from calf thymus has been analyzed by measuring mutagenesis in vitro and by site-specific nucleotide misinsertion and mispair extension. Using the phi X174 am3 DNA reversion assay errors are detected at the amber3 site only when both dATP and dCTP are significantly biased during in vitro copying reactions. Analysis of these products on DNA sequencing gels reveals pause sites due to the slow extension of mispaired 3' termini. Measurements of misinsertion rates opposite template A show that the rates of dAMP or dCMP misinsertion are similar and occur 40-50 times more rapidly than dGMP misinsertion. The rate of extension from an A:C mispair is 100- and 400-fold greater than from an A:A mispair and an A:G mispair, respectively. Nucleotide misinsertions to generate all 12 possible mispairs have been measured kinetically on phi X174 DNA templates that contain either A, C, G, or T at position 587. Misinsertion frequencies range from 1/4000 to 1/10(6) depending on the mispairs generated. Extension from all 12 different mispairs was examined by starting with oligonucleotide primers that contain different 3'-terminal mispairs. Rates of extension from mispairs are 10(3) to 10(6) times slower than from correctly paired bases. Extension frequencies were purine:pyrimidine greater than pyrimidine:pyrimidine greater than purine:purine. Lack of extension of misincorporated bases suggests the involvement of exonucleolytic proofreading to enable continued DNA synthesis and to guarantee the high fidelity of eucaryotic DNA replication.     

Characterization of the DNA- and dNTP-binding activities of the human cytomegalovirus DNA polymerase catalytic subunit UL54

The catalytic subunit of the human cytomegalovirus DNA polymerase is critical for the replication of the virus. In the present study, we report the expression and purification of a recombinant catalytic subunit of the human cytomegalovirus DNA polymerase expressed in bacteria which retains polymerase activity. As a first step towards elucidating the nature of the interaction between the enzyme, DNA and dNTPs, we have utilized endogenous tryptophan fluorescence to evaluate the binding of ligands to the enzyme. Using this technique, we demonstrate that the minimal DNA-binding site of the enzyme is 6 nt. We also report the first detailed study of the binding kinetics and thermodynamic parameters involved in the interaction between the enzyme, DNA and dNTPs. Our thermodynamic analyses indicate that the initial formation of the enzyme-DNA binary complex is driven by a favourable entropy change, but is also clearly associated with an unfavourable enthalpic contribution. In contrast, the interaction of dNTPs to the binary complex was shown to depend on a completely different mode of binding that is dominated by a favourable enthalpy change and associated with an unfavourable entropy change. In order to provide additional insights into the structural modifications that occur during catalysis, we correlated the effect of DNA and dNTP binding on protein structure using CD. Our results indicate that the enzyme undergoes a first conformational change upon the formation of the protein-DNA binary complex, which is followed by a second structural modification upon dNTP binding. The present study provides a better understanding of the molecular basis of DNA and dNTP recognition by the catalytic subunit of the human cytomegalovirus DNA polymerase.     

DNA polymerase insertion fidelity. Gel assay for site-specific kinetics

A quantitative assay based on gel electrophoresis is described to measure nucleotide insertion kinetics at an arbitrary DNA template site. The assay is used to investigate kinetic mechanisms governing the fidelity of DNA synthesis using highly purified Drosophila DNA polymerase alpha holoenzyme complex and M13 primer-template DNA. Km and Vmax values are reported for correct insertion of A and misinsertion of G, C, and T opposite a single template T site. The misinsertion frequencies are 2 X 10(-4) for G-T and 5 X 10(-5) for both C-T and T-T relative to normal A-T base pairs. The dissociation constant of the polymerase-DNA-dNTP complex, as measured by Km, plays a dominant role in determining the rates of forming right and wrong base pairs. Compared with Km for insertion of A opposite T (3.7 +/- 0.7 microM), the Km value is 1100-fold greater for misinsertion of G opposite T (4.2 +/- 0.4 mM), and 2600-fold greater for misinsertion of either C or T opposite T (9.8 +/- 4.2 mM). These Km differences indicate that in the enzyme binding site the stability of A-T base pairs is 4.3 kcal/mol greater than G-T pairs and 4.9 kcal/mol greater than C-T or T-T pairs. In contrast to the large differences in Km, differences in Vmax are relatively small. There is only a 4-fold reduction in Vmax for insertion of G opposite T and an 8-fold reduction for C or T opposite T, compared with the correct insertion of A. For the specific template T site investigated, the nucleotide insertion fidelity for Drosophila polymerase alpha seems to be governed primarily by a Km discrimination mechanism.     

Mitochondrial purine and pyrimidine metabolism and beyond

ABSTRACT

Carefully balanced deoxynucleoside triphosphate (dNTP) pools are essential for both nuclear and mitochondrial genome replication and repair. Two synthetic pathways operate in cells to produce dNTPs, e.g., the de novo and the salvage pathways. The key regulatory enzymes for de novo synthesis are ribonucleotide reductase (RNR) and thymidylate synthase (TS), and this process is considered to be cytosolic. The salvage pathway operates both in the cytosol (TK1 and dCK) and the mitochondria (TK2 and dGK). Mitochondrial dNTP pools are separated from the cytosolic ones owing to the double membrane structure of the mitochondria, and are formed by the salvage enzymes TK2 and dGK together with NMPKs and NDPK in postmitotic tissues, while in proliferating cells the mitochondrial dNTPs are mainly imported from the cytosol produced by the cytosolic pathways. Imbalanced mitochondrial dNTP pools lead to mtDNA depletion and/or deletions resulting in serious mitochondrial diseases. The mtDNA depletion syndrome is caused by deficiencies not only in enzymes in dNTP synthesis (TK2, dGK, p53R2, and TP) and mtDNA replication (mtDNA polymerase and twinkle helicase), but also in enzymes in other metabolic pathways such as SUCLA2 and SUCLG1, ABAT and MPV17. Basic questions are why defects in these enzymes affect dNTP synthesis and how important is mitochondrial nucleotide synthesis in the whole cell/organism perspective? This review will focus on recent studies on purine and pyrimidine metabolism, which have revealed several important links that connect mitochondrial nucleotide metabolism with amino acids, glucose, and fatty acid metabolism.     

Formation of purine-purine mispairs by Sulfolobus solfataricus DNA polymerase IV

DNA damage that stalls replicative polymerases can be bypassed with the Y-family polymerases. These polymerases have more open active sites that can accommodate modified nucleotides. The lack of protein-DNA interactions that select for Watson-Crick base pairs correlate with the lowered fidelity of replication. Interstrand hydrogen bonds appear to play a larger role in dNTP selectivity. The mechanism by which purine-purine mispairs are formed and extended was examined with Solfolobus solfataricus DNA polymerase IV, a member of the RAD30A subfamily of the Y-family polymerases, as is pol eta. The structures of the purine-purine mispairs were examined by comparing the kinetics of mispair formation with adenine versus 1-deaza- and 7-deazaadenine and guanine versus 7-deazaguanine at four positions in the DNA, the incoming dNTP, the template base, and both positions of the terminal base pair. The time course of insertion of a single dNTP was examined with a polymerase concentration of 50 nM and a DNA concentration of 25 nM with various concentrations of dNTP. The time courses were fitted to a first-order equation, and the first-order rate constants were plotted against the dNTP concentration to produce k pol and K d (dNTP) values. A decrease in k pol/ K d (dNTP) associated with the deazapurine substitution would indicate that the position is involved in a crucial hydrogen bond. During correct base pair formation, the adenine to 1-deazaadenine substitution in both the incoming dNTP and template base resulted in a >1000-fold decrease in k pol/ K d (dNTP), indicating that interstrand hydrogen bonds are important in correcting base pair formation. During formation of purine-purine mispairs, the k pol/ K d (dNTP) values for the insertion of dATP and dGTP opposite 7-deazaadenine and 7-deazaguanine were decreased >10-fold with respect to those of the unmodified nucleotides. In addition, the rate of incorporation of 1-deaza-dATP opposite guanine was decreased 5-fold. These results suggest that during mispair formation the newly forming base pair is in a Hoogsteen geometry with the incoming dNTP in the anti conformation and the template base in the syn conformation. These results indicate that Dpo4 holds the incoming dNTP in the normal anti conformation while allowing the template nucleotide to change conformations to allow reaction to occur. This result may be functionally relevant in the replication of damaged DNA in that the polymerase may allow the template to adopt multiple configurations.     

phi 29 DNA polymerase residue Leu384, highly conserved in motif B of eukaryotic type DNA replicases,is involved in nucleotide insertion fidelity

Replicative DNA polymerases achieve insertion fidelity by geometric selection of a complementary nucleotide followed by induced fit: movement of the fingers subdomain toward the active site to enclose the incoming and templating nucleotides generating a binding pocket for the nascent base pair. Several residues of motif B of DNA polymerases from families A and B, localized in the fingers subdomain, have been described to be involved in template/primer binding and dNTP selection. Here we complete the analysis of this motif, which has the consensus "KLX2NSXYG" in DNA polymerases from family B, characterized by mutational analysis of conserved leucine, Leu384 of phi 29 DNA polymerase. Mutation of Leu384 into Arg resulted in a phi 29 DNA polymerase with reduced nucleotide insertion fidelity during DNA-primed polymerization and protein-primed initiation reactions. However, the mutation did not alter the intrinsic affinity for the different dNTPs, as shown in the template-independent terminal protein-deoxynucleotidylation reaction. We conclude that Leu384 of phi 29 DNA polymerase plays an important role in positioning the templating nucleotide at the polymerization active site and in controlling nucleotide insertion fidelity. This agrees with the localization of the corresponding residue in the closed ternary complexes of family A and family B DNA polymerases, contributing to form the binding pocket for the nascent base pair. As an additional effect, mutant polymerase L384R was strongly reduced in DNA binding, resulting in reduced processivity during polymerization.     

Fidelity of DNA synthesis by the Thermococcus litoralis DNA polymerase--an extremely heat stable enzyme with proofreading activity

We demonstrate that the DNA polymerase isolated from Thermococcus litoralis (VentTM DNA polymerase) is the first thermostable DNA polymerase reported having a 3'----5' proofreading exonuclease activity. This facilitates a highly accurate DNA synthesis in vitro by the polymerase. Mutational frequencies observed in the base substitution fidelity assays were in the range of 30 x 10(-6). These values were 5-10 times lower compared to other thermostable DNA polymerases lacking the proofreading activity. All classes of DNA polymerase errors (transitions, transversions, frameshift mutations) were assayed using the forward mutational assay (1). The mutation frequencies of Thermococcus litoralis DNA polymerase varied between 15-35 x 10(-4) being 2-4 times lower than the respective values obtained using enzymes without proofreading activity. We also noticed that the fidelity of the DNA polymerase from Thermococcus litoralis responds to changes in dNTP concentration, units of enzyme used per one reaction and the concentration of MgSO4 relative to the total concentration of dNTPs present in the reaction. The high fidelity DNA synthesis in vitro by Thermococcus litoralis DNA polymerase provides good possibilities for maintaining the genetic information of original target DNA sequences intact in the DNA amplification applications.     

The fidelity of base selection by the polymerase subunit of DNA polymerase III holoenzyme.

In common with other DNA polymerases, DNA polymerase III holoenzyme of E. coli selects the biologically correct base pair with remarkable accuracy. DNA polymerase III is particularly useful for mechanistic studies because the polymerase and editing activities reside on separate subunits. To investigate the biochemical mechanism for base insertion fidelity, we have used a gel electrophoresis assay to measure kinetic parameters for the incorporation of correct and incorrect nucleotides by the polymerase (alpha) subunit of DNA polymerase III. As judged by this assay, base selection contributes a factor of roughly 10(4)-10(5) to the overall fidelity of genome duplication. The accuracy of base selection is determined mainly by the differential KM of the enzyme for correct vs. incorrect deoxynucleoside triphosphate. The misinsertion of G opposite template A is relatively efficient, comparable to that found for G opposite T. Based on a variety of other work, the G:A pair may require a special correction mechanism, possibly because of a syn-anti pairing approximating Watson-Crick geometry. We suggest that precise recognition of the equivalent geometry of the Watson-Crick base pairs may be the most critical feature for base selection.     

Efficiency of correct nucleotide insertion governs DNA polymerase fidelity

DNA polymerase fidelity or specificity expresses the ability of a polymerase to select a correct nucleoside triphosphate (dNTP) from a pool of structurally similar molecules. Fidelity is quantified from the ratio of specificity constants (catalytic efficiencies) for alternate substrates (i.e. correct and incorrect dNTPs). An analysis of the efficiency of dNTP (correct and incorrect) insertion for a low fidelity mutant of DNA polymerase beta (R283A) and exonuclease-deficient DNA polymerases from five families derived from a variety of biological sources reveals that a strong correlation exists between the ability to synthesize DNA and the probability that the polymerase will make a mistake (i.e. base substitution error). Unexpectedly, this analysis indicates that the difference between low and high fidelity DNA polymerases is related to the efficiency of correct, but not incorrect, nucleotide insertion. In contrast to the loss of fidelity observed with the catalytically inefficient R283A mutant, the fidelity of another inefficient mutant of DNA polymerase beta (G274P) is not altered. Thus, although all natural low fidelity DNA polymerases are inefficient, not every inefficient DNA polymerase has low fidelity. Low fidelity polymerases appear to be an evolutionary solution to how to replicate damaged DNA or DNA repair intermediates without burdening the genome with excessive polymerase-initiated errors.