Synthesis and enzymatic incorporation of photolabile dUTP analogues into DNA and their applications for DNA labeling

Two novel photolabile nucleotide triphosphate (NTP) analogues were synthesized through Sonogashira coupling and their enzymatic incorporation into DNA was evaluated with three different DNA polymerases (Taq, Vent exo- and T4) by polymerase chain reaction. Both nucleotide triphosphate analogues were recognized by these DNA polymerases as substrates for primer extension. Light irradiation of PCR products removed the photolabile group and released the amino and carboxyl moieties. Further site-specific dual-labeling for oligodeoxynucleotides (ODNs) and random labeling for a long DNA construct with fluorophores were successfully achieved with incorporation of the photolabile amine modified deoxyuridine triphosphate (dUnTP).     

Systematic analysis of enzymatic DNA polymerization using oligo-DNA templates and triphosphate analogs involving 2',4'-bridged nucleosides

In order to systematically analyze the effects of nucleoside modification of sugar moieties in DNA polymerase reactions, we synthesized 16 modified templates containing 2',4'-bridged nucleotides and three types of 2',4'-bridged nucleoside-5'-triphospates with different bridging structures. Among the five types of thermostable DNA polymerases used, Taq, Phusion HF, Vent(exo-), KOD Dash and KOD(exo-), the KOD Dash and KOD(exo-) DNA polymerases could smoothly read through the modified templates containing 2'-O,4'-C-methylene-linked nucleotides at intervals of a few nucleotides, even at standard enzyme concentrations for 5 min. Although the Vent(exo-) DNA polymerase also read through these modified templates, kinetic study indicates that the KOD(exo-) DNA polymerase was found to be far superior to the Vent(exo-) DNA polymerase in accurate incorporation of nucleotides. When either of the DNA polymerase was used, the presence of 2',4'-bridged nucleotides on a template strand substantially decreased the reaction rates of nucleotide incorporations. The modified templates containing sequences of seven successive 2',4'-bridged nucleotides could not be completely transcribed by any of the DNA polymerases used; yields of longer elongated products decreased in the order of steric bulkiness of the modified sugars. Successive incorporation of 2',4'-bridged nucleotides into extending strands using 2',4'-bridged nucleoside-5'-triphospates was much more difficult. These data indicate that the sugar modification would have a greater effect on the polymerase reaction when it is adjacent to the elongation terminus than when it is on the template as well, as in base modification.     

Comparative kinetics of nucleotide analog incorporation by vent DNA polymerase

Comparative kinetic and structural analyses of a variety of polymerases have revealed both common and divergent elements of nucleotide discrimination. Although the parameters for dNTP incorporation by the hyperthermophilic archaeal Family B Vent DNA polymerase are similar to those previously derived for Family A and B DNA polymerases, parameters for analog incorporation reveal alternative strategies for discrimination by this enzyme. Discrimination against ribonucleotides was characterized by a decrease in the affinity of NTP binding and a lower rate of phosphoryl transfer, whereas discrimination against ddNTPs was almost exclusively due to a slower rate of phosphodiester bond formation. Unlike Family A DNA polymerases, incorporation of 9-[(2-hydroxyethoxy)methyl]X triphosphates (where X is adenine, cytosine, guanine, or thymine; acyNTPs) by Vent DNA polymerase was enhanced over ddNTPs via a 50-fold increase in phosphoryl transfer rate. Furthermore, a mutant with increased propensity for nucleotide analog incorporation (Vent(A488L) DNA polymerase) had unaltered dNTP incorporation while displaying enhanced nucleotide analog binding affinity and rates of phosphoryl transfer. Based on kinetic data and available structural information from other DNA polymerases, we propose active site models for dNTP, ddNTP, and acyNTP selection by hyperthermophilic archaeal DNA polymerases to rationalize structural and functional differences between polymerases.     

In vitro replication slippage by DNA polymerases from thermophilic organisms

Replication slippage of DNA polymerases is a potential source of spontaneous genetic rearrangements in prokaryotic and eukaryotic cells. Here we show that different thermostable DNA polymerases undergo replication slippage in vitro, during single-round replication of a single-stranded DNA template carrying a hairpin structure. Low-fidelity polymerases, such as Thermus aquaticus (Taq), high-fidelity polymerases, such as Pyrococcus furiosus (Pfu) and a highly thermostable polymerase from Pyrococcus abyssi (Pyra exo(-)) undergo slippage. Thermococcus litoralis DNA polymerase (Vent) is also able to slip; however, slippage can be inhibited when its strand-displacement activity is induced. Moreover, DNA polymerases that have a constitutive strand-displacement activity, such as Bacillus stearothermophilus DNA polymerase (Bst), do not slip. Polymerases that slip during single-round replication generate hairpin deletions during PCR amplification, with the exception of Vent polymerase because its strand-displacement activity is induced under these conditions. We show that these hairpin deletions occurring during PCR are due to replication slippage, and not to a previously proposed process involving polymerization across the hairpin base.     

Systematic characterization of 2'-deoxynucleoside- 5'-triphosphate analogs as substrates for DNA polymerases by polymerase chain reaction and kinetic studies on enzymatic production of modified DNA

We synthesized C5-modified analogs of 2′-deoxyuridine triphosphate and 2′-deoxycytidine triphosphate and investigated them as substrates for PCRs using Taq, Tth, Vent(exo-), KOD Dash and KOD(exo-) polymerases and pUC 18 plasmid DNA as a template. These assays were performed on two different amplifying regions of pUC18 with different T/C contents that are expected to have relatively high barriers for incorporation of either modified dU or dC. On the basis of 260 different assays (26 modified triphosphates × 5 DNA polymerases × 2 amplifying regions), it appears that generation of the full-length PCR product depends not only on the chemical structures of the substitution and the nature of the polymerase but also on whether the substitution is on dU or dC. Furthermore, the template sequence greatly affected generation of the PCR product, depending on the combination of the DNA polymerase and modified triphosphate. By examining primer extension reactions using primers and templates containing C5-modified dUs, we found that a modified dU at the 3′ end of the elongation strand greatly affects the catalytic efficiency of DNA polymerases, whereas a modified dU opposite the elongation site on the template strand has less of an influence on the catalytic efficiency.     

Challenging artificial genetic systems: thymidine analogs with 5-position sulfur functionality

Eight different polymerases, chosen from evolutionary families A (Taq, Tfl, HotTub and Tth) and B (Pfu, Pwo, Vent and Deep Vent), were examined for their ability to incorporate 5-position modified 2′-deoxyuridine derivatives that carry a protected thiol group appended via different linkers containing either three or four carbon atoms. This represents the first attempt to incorporate the thiol functionality into DNA via enzymatic synthesis. Each polymerase–substrate combination was evaluated using a hierarchy of increasingly more difficult challenges, starting with incorporation of a single derivative, proceeding to incorporation of two derivatives at adjacent sites and non-adjacent sites, then examining the ability of the polymerase to accept the derivative within the template, and concluding with a challenge involving PCR. The evaluation of thiol-bearing 2′-deoxyuridine derivatives was then extended to consider their chemical stabilities. Stability was found to be less than satisfactory when the thiol functionality has a ‘propargylic’ relationship to the unsaturation in the linker. The best polymerase–appendage combination used the polymerase from Pyrococcus woesei (Pwo) and the 5′-tBu-SS-CH₂-CH₂-CC- linker. This pair supported PCR amplification and therefore should have value in artificial in vitro selection experiments. Indeed, we discovered that Pwo and Pfu preferred the derivative triphosphate over TTP, the natural substrate, in competition studies. These studies confirm an earlier suggestion that membership of an evolutionary family of polymerases is a partial predictor of the ability of the polymerase to accept 5-modified 2′-deoxyuridines. Considerable differences are displayed by different members within a polymerase family, however. This remains curious, as the ability of the polymerase to replicate natural DNA with high fidelity and its propensity to exclude unnatural analogs are presumed to be correlated.     

Polymerase-dependent DNA synthesis from phosphoramidate-activated nucleotides

Nucleoside triphosphate mimetics, which are substrates for polymerases, can be used in the enzymatic synthesis of nucleic acids. Alternatively, they might also become reversible or irreversible enzyme inhibitors. In order to analyze the effects of 5'-phosphoramidate modification of deoxynucleotide in DNA synthesis, 3-phosphono-L-Ala-dNMP (N = A, T, or G) were evaluated as substrates of HIV-1 RT, Vent (exo(-)), and Therminator polymerase, respectively. The DNA-dependent DNA polymerase activity is significantly higher for Vent exo(-) polymerase than for HIV-1 RT, which is reflected by the capacity of Vent exo(-) polymerase to efficiently synthesize DNA without stalling effects. In addition, Vent (exo(-)) polymerase proved to be more accurate than Therminator polymerase, based on Watson-Crick base-pairing. The optimal yield (88%-97%) of full-length elongation can be obtained in 60 minutes by Vent (exo(-)) polymerase at 0.025 U/μL, with the phosphoramidate analogues as substrates. These data led us to conclude that the optimal pyrophosphate mimetic for the enzyme-catalyzed synthesis of DNA is polymerase dependent.     

PCR fidelity of pfu DNA polymerase and other thermostable DNA polymerases.

The replication fidelities of Pfu, Taq, Vent, Deep Vent and UlTma DNA polymerases were compared using a PCR-based forward mutation assay. Average error rates (mutation frequency/bp/duplication) increased as follows: Pfu (1.3 x 10(-6)) < Deep Vent (2.7 x 10(-6)) < Vent (2.8 x 10(-6)) < Taq (8.0 x 10(-6)) < < exo- Pfu and UlTma (approximately 5 x 10(-5)). Buffer optimization experiments indicated that Pfu fidelity was highest in the presence of 2-3 mM MgSO4 and 100-300 microM each dNTP and at pH 8.5-9.1. Under these conditions, the error rate of exo- Pfu was approximately 40-fold higher (5 x 10(-5)) than the error rate of Pfu. As the reaction pH was raised from pH 8 to 9, the error rate of Pfu decreased approximately 2-fold, while the error rate of exo- Pfu increased approximately 9-fold. An increase in error rate with pH has also been noted for the exonuclease-deficient DNA polymerases Taq and exo- Klenow, suggesting that the parameters which influence replication error rates may be similar in pol l- and alpha-like polymerases. Finally, the fidelity of 'long PCR' DNA polymerase mixtures was examined. The error rates of a Taq/Pfu DNA polymerase mixture and a Klentaq/Pfu DNA polymerase mixture were found to be less than the error rate of Taq DNA polymerase, but approximately 3-4-fold higher than the error rate of Pfu DNA polymerase.     

A new thermostable DNA polymerase mixture for efficient amplification of long DNA fragments

The thermostable DNA polymerases have been used for amplification of DNA fragments since the invention of PCR. The constraint on the maximum size of the amplified fragments can be solved to certain level by the use of unbalanced mixtures of non-proofreading and proofreading thermostable DNA polymerases. In this study, we tested the use of a mixtures of N-terminal deletional variant of Taq polymerase—Klentaq278 and Tne polymerase from Thermotoga neapolitana. Klentaq278 and Tne polymerase genes were cloned and expressed in different expression vectors under tac promoter. The most efficient ratio of Klentaq278/Tne polymerase for amplification was 10: 1. The polymerase mixture of Klentaq278 and Tne polymerase is very effective in amplification of DNA fragments for up to 8 kb and is useful addition to a DNA polymerases used in long-range PCR.     

Unique Substrate Spectrum and PCR Application of Nanoarchaeum equitans Family B DNA Polymerase

The known archaeal family B DNA polymerases are unable to participate in the PCR in the presence of uracil. Here, we report on a novel archaeal family B DNA polymerase from Nanoarchaeum equitans that can successfully utilize deaminated bases such as uracil and hypoxanthine and on its application to PCR. N. equitans family B DNA polymerase (Neq DNA polymerase) produced λ DNA fragments up to 10 kb with an approximately 2.2-fold-lower error rate (5.53 × 10⁻⁶) than Taq DNA polymerase (11.98 × 10⁻⁶). Uniquely, Neq DNA polymerase also amplified λ DNA fragments using dUTP (in place of dTTP) or dITP (partially replaced with dGTP). To increase PCR efficiency, Taq and Neq DNA polymerases were mixed in different ratios; a ratio of 10:1 efficiently facilitated long PCR (20 kb). In the presence of dUTP, the PCR efficiency of the enzyme mixture was two- to threefold higher than that of either Taq and Neq DNA polymerase alone. These results suggest that Neq DNA polymerase and Neq plus DNA polymerase (a mixture of Taq and Neq DNA polymerases) are useful in DNA amplification and PCR-based applications, particularly in clinical diagnoses using uracil-DNA glycosylase.     

Comparison of DIG-11-dUTP utilization by Geobacillus caldoxylosilyticus TK4, Mycobacterium tuberculosis and Escherichia coli DNA polymerases

DNA polymerases are used for many applications and we comparatively investigated DNA synthesis activity of DNA polymerase I enzymes of Geobacillus caldoxylosilyticus TK4, Escherichia coli and Mycobacterium tuberculosis with DIG-11-dUTP using synthetic DNA substrates. We showed that Gca polymerase I and Klenow Fragment (KF) used DIG-11-dUTP instead of dTTP almost at the same ratio, but more efficiently than Mtb polymerase I. We considered that Gca polymerase I could be efficiently used to label a DNA oligonucleotide either internally or at the 3′-terminus by DIG-11-dUTP for the generation of non-radioactive labeled DNA substrates at higher temperature than KF. All three polymerases could not elongate the primer terminus after adding ddNTPs into DNA that is characteristic for all known DNA polymerase I enzymes.     

A Nuclear Family A DNA Polymerase from Entamoeba histolytica Bypasses Thymine Glycol

Background

Eukaryotic family A DNA polymerases are involved in mitochondrial DNA replication or translesion DNA synthesis. Here, we present evidence that the sole family A DNA polymerase from the parasite protozoan E. histolytica (EhDNApolA) localizes to the nucleus and that its biochemical properties indicate that this DNA polymerase may be involved in translesion DNA synthesis.

Methodology and Results

EhDNApolA is the sole family A DNA polymerase in E. histolytica. An in silico analysis places family A DNA polymerases from the genus Entamoeba in a separate branch of a family A DNA polymerases phylogenetic tree. Biochemical studies of a purified recombinant EhDNApolA demonstrated that this polymerase is active in primer elongation, is poorly processive, displays moderate strand displacement, and does not contain 3′–5′ exonuclease or editing activity. Importantly, EhDNApolA bypasses thymine glycol lesions with high fidelity, and confocal microscopy demonstrates that this polymerase is translocated into the nucleus. These data suggest a putative role of EhDNApolA in translesion DNA synthesis in E. histolytica.

Conclusion

This is the first report of the biochemical characterization of a DNA polymerase from E. histolytica. EhDNApolA is a family A DNA polymerase that is grouped into a new subfamily of DNA polymerases with translesion DNA synthesis capabilities similar to DNA polymerases from subfamily ν.     

Characterization and PCR application of a new high-fidelity DNA polymerase from Thermococcus waiotapuensis

The family B DNA polymerase gene from the euryarchaeon Thermococcus waiotapuensis (Twa) contains an open reading frame of 4404 bases that encodes 1467 amino acid residues. The gene is split by two intein-coding sequences that forms a continuous open reading frame with the three polymerase exteins. Twa DNA polymerase genes with (whole gene) and without (genetically intein-spliced) inteins were expressed in Escherichia coli Rosetta(DE3)pLysS. The inteins of the expressed whole gene were easily spliced during purification. The molecular mass of the purified Twa DNA polymerase was about 90 kDa, as estimated by SDS-PAGE. The optimal pH for Twa DNA polymerase activity was 6.0 and the optimal temperature was 75 °C. The enzyme was activated by magnesium ions. The half-life of the enzyme at 99 °C was about 4 h. The optimal buffer for PCR with Twa DNA polymerase was 50 mM Tris–HCl (pH 8.2), 2.0 mM MgCl₂, 30 mM KCl, 2.0 mM (NH₄)₂SO₄, 0.01% Triton X-100, and 0.005% BSA. The PCR fidelity of Twa DNA polymerase was higher than Pfu, KOD and Vent DNA polymerases. A ratio of 15:1 Taq:Twa DNA polymerase efficiently facilitated long-range PCR.     

Factors affecting PCR-mediated recombination

In the past decade, polymerase chain reaction (PCR) has become an important tool for the identification of previously unknown microorganisms and the analysis of environmental microbial diversity. Several studies published during recent years, however, have demonstrated that products obtained after PCR using Taq or Vent DNA polymerases will contain hybrid molecules when several homologous target sequences such as multigene families, alleles, or RNA viruses are co-amplified. In this report, we examined the recombination frequency and the extent of template switching during PCR using Taq, Pfu and RTth/Vent DNA polymerases. As a test system we constructed a series of plasmids carrying between one and three frame shift mutations in the gene coding for the protease subtilisin or deletions of approximately 100 bp in the lacZ alpha. Highest recombination frequencies were observed when these mutants were co-amplified with Taq followed by RTth/Vent DNA polymerases. Pfu DNA polymerase displayed no discernable recombination activity under normal PCR conditions. Data also suggest that in vivo repair of heteroduplex DNA molecules in Escherichia coli by a RecA-independent mechanism, perhaps the mismatch repair, results in the formation of chimeric molecules. Using Bacillus subtilis as the host, however, can significantly diminish non-PCR RecA-independent in vivo recombination, owing to the fact that transforming DNA molecules enter B. subtilis as single strands. Combined, these results suggest that using Pfu DNA polymerase for amplification and B. subtilis as the host for transformation may significantly reduce chimera formation.     

Improved thermostability and PCR efficiency of Thermococcus celericrescens DNA polymerase via site-directed mutagenesis

The Thermococcus celericrescens (Tcel) DNA polymerase gene, which contains a 2328-bp open reading frame that encodes 775 amino acid residues, was expressed in the Escherichia coli strain Rosetta(DE3)pLysS. The expressed enzyme was purified through heat treatment, HisTrap™ HP column chromatography and then HiTrap™ SP HP column chromatography. Tcel DNA polymerase has poor thermostability and PCR efficiency compared to those of other family B DNA polymerases. To improve thermostability and PCR efficiency, mutant Tcel DNA polymerases were created via site-directed mutagenesis. Specifically, we targeted the A752 residue for enhanced thermostability and the N213 residue for improved PCR efficiency. The mutant Tcel DNA polymerases all showed enhanced PCR efficiency and thermostability compared to those of the wild-type Tcel DNA polymerase. Specifically, the double mutant TcelA752K/N213D DNA polymerase had an approximately three-fold increase in thermostability over that of the wild-type enzyme and amplified a long 10-kb PCR product in an extension time of 2 min. However, there was a small change in the 3′ → 5′ exonuclease activity compared with that of the wild-type Tcel DNA polymerase, even though the mutation is in the ExoII motif. The double mutant TcelA752K/N213D DNA polymerase had a 2.6-fold lower error rate compared to that of Taq DNA polymerase. It seems that the double mutant TcelA752K/N213D DNA polymerase can be used in LA (long and accurate) PCR.     

Strong positional preference in the interaction of LNA oligonucleotides with DNA polymerase and proofreading exonuclease activities: implications for genotyping assays

The effect of locked nucleic acid (LNA) modification position upon representative DNA polymerase and exonuclease activities has been examined for potential use in primer extension genotyping applications. For the 3′→5′ exonuclease activities of four proofreading DNA polymerases (Vent, Pfu, Klenow fragment and T7 DNA polymerase) as well as exonuclease III, an LNA at the terminal (L-1) position of a primer is found to provide partial protection against the exonucleases of the two family B polymerases only. In contrast, an LNA residue at the penultimate (L-2) position generates essentially complete nuclease resistance. The polymerase active sites of these enzymes also display a distinct preference. An L-1 LNA modification has modest effects upon poly merization, but an L-2 LNA group slows dTTP incorporation somewhat while virtually abolishing extension with ddTTP or acyTTP terminators, even with A488L Vent DNA polymerase engineered for terminator incorporation. These observations on active site preference have been utilized to demonstrate two novel assays: exonuclease-mediated single base extension (E-SBE) and proofreading allele-specific extension (PRASE). We show that a model PRASE genotyping reaction with L-2 LNA primers offers greater specificity than existing non-proofreading assays, whether or not the non-proofreading reaction employs LNA-modified primers.     

Interplay of DNA repair,homologous recombination,and DNA polymerases in resistance to the DNA damaging agent 4-nitroquinoline-1-oxide in Escherichia coli

Escherichia coli has three DNA damage-inducible DNA polymerases: DNA polymerase II (Pol II), DNA polymerase IV (Pol IV), and DNA polymerase V (Pol V). While the in vivo function of Pol V is well understood, the precise roles of Pol IV and Pol II in DNA replication and repair are not as clear. Study of these polymerases has largely focused on their participation in the recovery of failed replication forks, translesion DNA synthesis, and origin-independent DNA replication. However, their roles in other repair and recombination pathways in E. coli have not been extensively examined. This study investigated how E. coli's inducible DNA polymerases and various DNA repair and recombination pathways function together to convey resistance to 4-nitroquinoline-1-oxide (NQO), a DNA damaging agent that produces replication blocking DNA base adducts. The data suggest that full resistance to this compound depends upon an intricate interplay among the activities of the inducible DNA polymerases and recombination. The data also suggest new relationships between the different pathways that process recombination intermediates.