Single-molecule and ensemble fluorescence assays for a functionally important conformational change in T7 DNA polymerase

We report fluorescence assays for a functionally important conformational change in bacteriophage T7 DNA polymerase (T7 pol) that use the environmental sensitivity of a Cy3 dye attached to a DNA substrate. An increase in fluorescence intensity of Cy3 is observed at the single-molecule level, reflecting a conformational change within the T7 pol ternary complex upon binding of a dNTP substrate. This fluorescence change is believed to reflect the closing of the T7 pol fingers domain, which is crucial for polymerase function. The rate of the conformational change induced by a complementary dNTP substrate was determined by both conventional stopped-flow and high-time-resolution continuous-flow fluorescence measurements at the ensemble-averaged level. The rate of this conformational change is much faster than that of DNA synthesis but is significantly reduced for noncomplementary dNTPs, as revealed by single-molecule measurements. The high level of selectivity of incoming dNTPs pertinent to this conformational change is a major contributor to replicative fidelity.     

Structural basis for the synthesis of nucleobase modified DNA by Thermus aquaticus DNA polymerase

Numerous 2'-deoxynucleoside triphosphates (dNTPs) that are functionalized with spacious modifications such as dyes and affinity tags like biotin are substrates for DNA polymerases. They are widely employed in many cutting-edge technologies like advanced DNA sequencing approaches, microarrays, and single molecule techniques. Modifications attached to the nucleobase are accepted by many DNA polymerases, and thus, dNTPs bearing nucleobase modifications are predominantly employed. When pyrimidines are used the modifications are almost exclusively at the C5 position to avoid disturbing of Watson-Crick base pairing ability. However, the detailed molecular mechanism by which C5 modifications are processed by a DNA polymerase is poorly understood. Here, we present the first crystal structures of a DNA polymerase from Thermus aquaticus processing two C5 modified substrates that are accepted by the enzyme with different efficiencies. The structures were obtained as ternary complex of the enzyme bound to primer/template duplex with the respective modified dNTP in position poised for catalysis leading to incorporation. Thus, the study provides insights into the incorporation mechanism of the modified nucleotides elucidating how bulky modifications are accepted by the enzyme. The structures show a varied degree of perturbation of the enzyme substrate complexes depending on the nature of the modifications suggesting design principles for future developments of modified substrates for DNA polymerases.     

Restriction Primer Extension Method of Labeling Oligonucleotide Probes and Its Application to the Detection of HB E Genes

A new method for labeling oligonucleotides was developed to obtain high specific activity of radioactive probes. In an oligonucleotide molecule, two sequences were designed. One sequence, the 5′, contains 19 nucleotides and serves as a template for probe synthesis. The second sequence, 3′, contains a consensus sequence which forms a Pst I site after forming a complementary strand with the primer. In the presence of E. coli DNA polymerase I (Klenow fragment), α-32P dNTP and other dNTPs, a radioactive labeled oligonucleotide was synthesized by the primer extension method. After Pst I digestion, the probe was different from its template in length by 4 bp and could be separated from each other on urea-polyacrylamide gel electrophoresis (PAGE). A radioactive 01ionucleotide probe with extremely high specific activity up to 10¹⁰ dpm/μg could be obtained by the use of this method. The oligonucleotide probes have been used for the detection of the Hb E mutation in this report.     

Restriction primer extension method of labeling oligonucleotide probes and its application to the detection of Hb E genes

A new method for labeling oligonucleotides was developed to obtain high specific activity of radioactive probes. In an oligonucleotide molecule, two sequences were designed. One sequence, the 5', contains 19 nucleotides and serves as a template for probe synthesis. The second sequence, 3', contains a consensus sequence which forms a Pst I site after forming a complementary strand with the primer. In the presence of E. coli DNA polymerase I (Klenow fragment), alpha-32P dNTP and other dNTPs, a radioactive labeled oligonucleotide was synthesized by the primer extension method. After Pst I digestion, the probe was different from its template in length by 4 bp and could be separated from each other on urea-polyacrylamide gel electrophoresis (PAGE). A radioactive oligonucleotide probe with extremely high specific activity up to 10(10) dpm/micrograms could be obtained by the use of this method. The oligonucleotide probes have been used for the detection of the Hb E mutation in this report.     

Unique active site promotes error-free replication opposite an 8-oxo-guanine lesion by human DNA polymerase iota

The 8-oxo-guanine (8-oxo-G) lesion is the most abundant and mutagenic oxidative DNA damage existing in the genome. Due to its dual coding nature, 8-oxo-G causes most DNA polymerases to misincorporate adenine. Human Y-family DNA polymerase iota (polι) preferentially incorporates the correct cytosine nucleotide opposite 8-oxo-G. This unique specificity may contribute to polι's biological role in cellular protection against oxidative stress. However, the structural basis of this preferential cytosine incorporation is currently unknown. Here we present four crystal structures of polι in complex with DNA containing an 8-oxo-G lesion, paired with correct dCTP or incorrect dATP, dGTP, and dTTP nucleotides. An exceptionally narrow polι active site restricts the purine bases in a syn conformation, which prevents the dual coding properties of 8-oxo-G by inhibiting syn/anti conformational equilibrium. More importantly, the 8-oxo-G base in a syn conformation is not mutagenic in polι because its Hoogsteen edge does not form a stable base pair with dATP in the narrow active site. Instead, the syn 8-oxo-G template base forms the most stable replicating base pair with correct dCTP due to its small pyrimidine base size and enhanced hydrogen bonding with the Hoogsteen edge of 8-oxo-G. In combination with site directed mutagenesis, we show that Gln59 in the finger domain specifically interacts with the additional O(8) atom of the lesion base, which influences nucleotide selection, enzymatic efficiency, and replication stalling at the lesion site. Our work provides the structural mechanism of high-fidelity 8-oxo-G replication by a human DNA polymerase.     

Replication of duplex DNA by bacteriophage T7 DNA polymerase and gene 4 protein is accompanied by hydrolysis of nucleoside 5''-triphosphates.

Homogeneous preparations of phage T7 gene 4 protein catalyze the hydrolysis of dNTPs and rNTPs to NDPs and Pi in the presence of single-stranded DNA. Synthesis on single-stranded DNA by T7 DNA polymerase (DNA nucleotidyltransferase; deoxynucleosidetriphosphate:DNA deoxynucleotidyltransferase, EC 2.7.7.7) does not affect the hydrolysis of NTPs by the gene 4 protein. Gene 4 protein does not catalyze the hydrolysis of NTPs in the presence of duplex DNA, nor can T7 DNA polymerase use duplex DNA as a template. However, the two proteins together can replicate duplex DNA and, under these conditions, synthesis is accompanied by hydrolysis of NTPs. During synthesis on duplex templates in the presence of T7 DNA polymerase, gene 4 protein, dNTPs, and rNTPs, 4.2 NTPs are hydrolyzed for each dNMP polymerized. 2'3'-Dideoxy-TTP, an inhibitor of DNA synthesis, inhibits hydrolysis by the gene 4 protein during synthesis on duplex DNA, and beta, gamma-methylene-dTTP, an inhibitor of hydrolysis by the gene 4 protein, stops DNA synthesis on duplex DNA. The multiple activities of gene 4 protein are shown to reside in a single protein molecule.     

Enzymatic initiation of DNA synthesis by yeast DNA polymerases.

Partially purified yeast RNA polymerases (RNA nucleotidyltransferases) initiate DNA synthesis by yeast DNA polymerase (DNA nucleotidyltransferase) I and to a lesser extent yeast DNA polymerase II in the replication of single-stranded DNA. The enzymatic initiation of DNA synthesis on phage fd DNA template occurs with dNTPs alone and is further stimulated by the presence of rNTPs in DNA polymerase I reactions. The presence of rNTPs has no effect on the RNA polymerase initiation of the DNA polymerase II reaction. RNA polymerases I and III are more efficient in initiation of DNA synthesis than RNA polymerase II. Analyses of the products of fd DNA replication show noncovalent linkage between the newly synthesized DNA and the template DNA, and covalent linkage between the newly synthesized RNA and DNA.     

NMR of enzymatically synthesized uniformly 13C15N-labeled DNA oligonucleotides.

A procedure for the enzymatic synthesis of uniformly 13C15N-labeled DNA oligonucleotides in milligram quantities for NMR studies is described. Deoxynucleotides obtained from microorganisms grown on 13C and 15N nutrient sources are enzymatically phosphorylated to dNTPs, and the dNTPs are incorporated into oligonucleotides using a 3'-5' exonuclease-deficient mutant of Klenow fragment of DNA polymerase I and an oligonucleotide template primer designed for efficient separation of labeled product DNA from unlabeled template. The labeling strategy has been used to uniformly label one or the other oligonucleotide strand in the DNA duplex dGGCAAAACGG.dCCGTTTTGCC in order to facilitate assignment and structure determination by NMR. Application of 15N and 13C heteronuclear NMR experiments to isotopically labeled DNA is presented.     

Binary complex crystal structure of DNA polymerase β reveals multiple conformations of the templating 8-oxoguanine lesion

Oxidation of genomic DNA forms the guanine lesion 7,8-dihydro-8-oxoguanine (8-oxoG). When in the template base position during DNA synthesis the 8-oxoG lesion has dual coding potential by virtue of its anti- and syn-conformations, base pairing with cytosine and adenine, respectively. This impacts mutagenesis, because insertion of adenine opposite template 8-oxoG can result in a G to T transversion. DNA polymerases vary by orders of magnitude in their preferences for mutagenic vs. error-free 8-oxoG lesion bypass. Yet, the structural basis for lesion bypass specificity is not well understood. The DNA base excision repair enzyme DNA polymerase (pol) β is presented with gap-filling synthesis opposite 8-oxoG during repair and has similar insertion efficiencies for dCTP and dATP. We report the structure of pol β in binary complex with template 8-oxoG in a base excision repair substrate. The structure reveals both the syn- and anti-conformations of template 8-oxoG in the confines of the polymerase active site, consistent with the dual coding observed kinetically for this enzyme. A ternary complex structure of pol β with the syn-8-oxoG:anti-A Hoogsteen base pair in the closed fully assembled preinsertion active site is also reported. The syn-conformation of 8-oxoG is stabilized by minor groove hydrogen bonding between the side chain of Arg283 and O8 of 8-oxoG. An adjustment in the position of the phosphodiester backbone 5'-phosphate enables 8-oxoG to adopt the syn-conformation.     

DNA precursor asymmetries in mammalian tissue mitochondria and possible contribution to mutagenesis through reduced replication fidelity

The mutation rate of the mammalian mitochondrial genome is higher than that of the nuclear genome. Because mitochondrial and nuclear deoxyribonucleoside triphosphate (dNTP) pools are physically distinct and because dNTP concentrations influence replication fidelity, we asked whether mitochondrial dNTP pools are asymmetric with respect to each other. We report here that the concentrations of the four dNTPs are not equal in mitochondria isolated from several tissues of both young and old rats. In particular, in most tissues examined, mitochondrial dGTP concentrations are high relative to the other dNTPs. Moreover, in the presence of the biased dNTP concentrations measured in heart and skeletal muscle, the fidelity of DNA synthesis in vitro by normally highly accurate mtDNA polymerase gamma is reduced, with error frequencies increased by as much as 3-fold, due to increased formation of template T.dGTP mismatches that are inefficiently corrected by proofreading. These data, plus some published data on specific mitochondrial mutations seen in human diseases, are consistent with the hypothesis that normal intramitochondrial dNTP pool asymmetries may contribute to spontaneous mutagenesis in the mammalian mitochondrial genome.     

A DNA polymerase alpha pause site is a hot spot for nucleotide misinsertion.

In this study we examined whether the arrest of DNA polymerase alpha (pol alpha)-catalyzed DNA synthesis at template pause sites entails terminal nucleotide misincorporation. An approach was developed to identify the 3'-terminal nucleotide in nascent DNA chains that accumulate at pause sites. A radioactive 5'-end-labeled primer was annealed to a bacteriophage M13mp2 single-stranded DNA template and elongated by pol alpha. Individual DNA chains that were accumulated at pause sites were resolved by sequencing gel electrophoresis, isolated, and purified. These DNA chains were elongated by pol alpha by using four annealed synthetic DNA templates, each of which contained a different nucleotide at the position opposite the 3' terminus of the arrested chain. Owing to the high preference of pol alpha for matched-over-mismatched primer termini, only those templates that contain a nucleotide that is complementary to the 3' terminus of the isolated pause-site chain are copied. Electrophoresis of product DNA showed the extent of copying of each template and thus identified the 3'-terminal nucleotide of the pause-site chains. We found that product DNA chains terminate with a noncomplementary 3'-terminal nucleotide opposite pause sites within the sequence 3'-d(AAAA)-5' at positions 6272-6269 of the M13mp2 genome. pol alpha catalyzed misincorporation of dG or dA into the 3' terminus of nascent chains opposite two of the M13mp2 template dA residues. A similar analysis of a different pause site did not reveal significant misincorporation opposite template dC. These results suggest that some but not all sites at which pol alpha pauses may constitute loci of mutagenesis.     

Cost of rNTP/dNTP pool imbalance at the replication fork

The concentration of ribonucleoside triphosphates (rNTPs) in cells is far greater than the concentration of deoxyribonucleoside triphosphates (dNTPs), and this pool imbalance presents a challenge for DNA polymerases (Pols) to select their proper substrate. This report examines the effect of nucleotide pool imbalance on the rate and fidelity of the Escherichia coli replisome. We find that rNTPs decrease replication fork rate by competing with dNTPs at the active site of the C-family Pol III replicase at a step that does not require correct base-pairing. The effect of rNTPs on Pol rate generalizes to B-family eukaryotic replicases, Pols δ and ε. Imbalance of the dNTP pool also slows the replisome and thus is not specific to rNTPs. We observe a measurable frequency of rNMP incorporation that predicts one rNTP incorporated every 2.3 kb during chromosome replication. Given the frequency of rNMP incorporation, the repair of rNMPs is likely rapid. RNase HII nicks DNA at single rNMP residues to initiate replacement with dNMP. Considering that rNMPs will mark the new strand, RNase HII may direct strand-specificity for mismatch repair (MMR). How the newly synthesized strand is recognized for MMR is uncertain in eukaryotes and most bacteria, which lack a methyl-directed nicking system. Here we demonstrate that Bacillus subtilis incorporates rNMPs in vivo, that RNase HII plays a role in their removal, and the RNase HII gene deletion enhances mutagenesis, suggesting a possible role of incorporated rNMPs in MMR.The structures of ribonucleoside triphosphates (rNTPs) and deoxyribonucleoside triphosphates (dNTPs) differ by a single atom, yet each must be distinguished by DNA and RNA polymerases (Pols). This is more challenging for DNA Pols because the intracellular concentration of rNTPs is 10–100-fold higher than that of dNTPs (1–3). DNA is more stabile than RNA, and rNMP residues in DNA could lead to spontaneous strand breaks. Hence, it is important to genomic integrity that DNA Pols exclude rNMPs from incorporation into the genome (1, 4).Structural studies reveal that DNA Pols distinguish ribo and deoxyribo sugars via a “steric gate,” in which a bulky residue or main chain atom sterically occludes binding of the ribo 2′OH (5, 6). However, the single-atom difference between rNTPs and dNTPs imposes an upper limit to sugar recognition, and thus DNA Pols incorporate rNMPs at a low frequency. For example, studies in yeast demonstrate that rNMPs are incorporated in vivo, and studies in vitro demonstrate a frequency of rNMP incorporation predicting that 10,000 rNMPs or more may be incorporated each replication cycle (2, 7, 8). Given their abundant incorporation, there are probably multiple pathways to remove rNMPs, as their persistence is associated with genomic instability in yeast (7, 9).The current study reconstitutes the Escherichia coli replisome and examines the cost of rNTP/dNTP nucleotide pool imbalance on the frequency of rNMP incorporation and the rate of fork progression. We find that a nucleotide pool imbalance slows the replisome two- to threefold by competing with dNTPs at the active site of the Pol III replicase at a step that does not require correct base-pairing. We determine the rNMP incorporation frequency and estimate that at intracellular concentrations of nucleotides, Pol III incorporates one rNMP every 2.3 kb, for a total of about 2,000 rNMPs per daughter chromosome. We also find that the replisome pauses 4–30-fold at a template rNMP, which could possibly promote genomic instability if rNMPs were not removed before the next round of replication.Despite detrimental aspects of the rNTP/dNTP pool imbalance, there exists a potential benefit of rNMP incorporation: It has been proposed that replicative Pols may incorporate rNMPs for particular tasks, one of which may mark the newly replicated DNA strand for mismatch repair (MMR) (2). Some bacteria (e.g., E. coli) direct MMR using a DNA methylase and MutH endonuclease to recognize and nick the newly replicated strand (1, 10, 11). However, eukaryotes and most bacteria (e.g., Bacillus subtilis) do not use methyl direction for MMR. Because rNMP incorporation is specific to the newly synthesized strand, the nick generated during its repair could be recruited to direct MMR. We investigated this hypothesis in B. subtilis, a Gram-positive bacterium that lacks a methyl-directed MMR system, and report an increase in mutagenesis after deletion of two RNase H genes.     

Crystal structure of a covalent intermediate in DNA cleavage and rejoining by Escherichia coli DNA topoisomerase I

DNA topoisomerases control DNA topology by breaking and rejoining DNA strands via covalent complexes with cleaved DNA substrate as catalytic intermediates. Here we report the structure of Escherichia coli topoisomerase I catalytic domain (residues 2–695) in covalent complex with a cleaved single-stranded oligonucleotide substrate, refined to 2.3-Å resolution. The enzyme-substrate intermediate formed after strand cleavage was captured due to the presence of the D111N mutation. This structure of the covalent topoisomerase-DNA intermediate, previously elusive for type IA topoisomerases, shows distinct conformational changes from the structure of the enzyme without bound DNA and provides detailed understanding of the covalent catalysis required for strand cleavage to take place. The portion of cleaved DNA 5′ to the site of cleavage is anchored tightly with extensive noncovalent protein–DNA interactions as predicted by the “enzyme-bridged” model. Distortion of the scissile strand at the -4 position 5′ to the cleavage site allows specific selectivity of a cytosine base in the binding pocket. Many antibacterial and anticancer drugs initiate cell killing by trapping the covalent complexes formed by topoisomerases. We have demonstrated in previous mutagenesis studies that accumulation of the covalent complex of bacterial topoisomerase I is bactericidal. This structure of the covalent intermediate provides the basis for the design of novel antibiotics that can trap the enzyme after formation of the covalent complex.     

Okazaki fragment processing: Modulation of the strand displacement activity of DNA polymerase δ by the concerted action of replication protein A, proliferating cell nuclear antigen, and flap endonuclease-1

DNA polymerase (pol) delta is essential for both leading and lagging strand DNA synthesis during chromosomal replication in eukaryotes. Pol delta has been implicated in the Okazaki fragment maturation process for the extension of the newly synthesized fragment and for the displacement of the RNA/DNA segment of the preexisting downstream fragment generating an intermediate flap structure that is the target for the Dna2 and flap endonuclease-1 (Fen 1) endonucleases. Using a single-stranded minicircular template with an annealed RNA/DNA primer, we could measure strand displacement by pol delta coupled to DNA synthesis. Our results suggested that pol delta alone can displace up to 72 nucleotides while synthesizing through a double-stranded DNA region in a distributive manner. Proliferating cell nuclear antigen (PCNA) reduced the template dissociation rate of pol delta, thus increasing the processivity of both synthesis and strand displacement, whereas replication protein A (RP-A) limited the size of the displaced fragment down to 20-30 nucleotides, by generating a "locked" flap DNA structure, which was a substrate for processing of the displaced fragment by Fen 1 into a ligatable product. Our data support a model for Okazaki fragment processing where the strand displacement activity of DNA polymerase delta is modulated by the concerted action of PCNA, RP-A and Fen 1.