Capacity of Nine Thermostable DNA Polymerases To Mediate DNA Amplification in the Presence of PCR-Inhibiting Samples

The PCR is an extremely powerful method for detecting microorganisms. However, its full potential as a rapid detection method is limited by the inhibition of the thermostable DNA polymerase from Thermus aquaticus by many components found in complex biological samples. In this study, we have compared the effects of known PCR-inhibiting samples on nine thermostable DNA polymerases. Samples of blood, cheese, feces, and meat, as well as various ions, were added to PCR mixtures containing various thermostable DNA polymerases. The nucleic acid amplification capacity of the nine polymerases, under buffer conditions recommended by the manufacturers, was evaluated by using a PCR-based detection method for Listeria monocytogenes in the presence of purified template DNA and different concentrations of PCR inhibitors. The AmpliTaq Gold and the Taq DNA polymerases from Thermus aquaticus were totally inhibited in the presence of 0.004% (vol/vol) blood in the PCR mixture, while the HotTub, Pwo, rTth, and Tfl DNA polymerases were able to amplify DNA in the presence of 20% (vol/vol) blood without reduced amplification sensitivity. The DNA polymerase from Thermotoga maritima (Ultma) was found to be the most susceptible to PCR inhibitors present in cheese, feces, and meat samples. When the inhibitory effect of K and Na ions was tested on the nine polymerases, HotTub from Thermus flavus and rTth from Thermus thermophilus were the most resistant. Thus, the PCR-inhibiting effect of various components in biological samples can, to some extent, be eliminated by the use of the appropriate thermostable DNA polymerase.     

Thermodynamics of the DNA Structural Selectivity of the Pol I DNA Polymerases from Escherichia coli and Thermus aquaticus

Understanding the thermodynamics of substrate selection by DNA polymerase I is important for characterizing the balance between replication and repair for this enzyme in vivo. Due to their sequence and structural similarities, Klenow and Klentaq, the large fragments of the Pol I DNA polymerases from Escherichia coli and Thermus aquaticus, are considered functional homologs. Klentaq, however, does not have a functional proofreading site. Examination of the DNA binding thermodynamics of Klenow and Klentaq to different DNA structures: single-stranded DNA (ss-DNA), primer-template DNA (pt-DNA), and blunt-end double-stranded DNA (ds-DNA) show that the binding selectivity pattern is similar when examined across a wide range of salt concentration, but can significantly differ at any individual salt concentration. For both proteins, binding of single-stranded DNA shifts from weakest to tightest binding of the three structures as the salt concentration increases. Both Klenow and Klentaq release two to three more ions when binding to pt-DNA and ds-DNA than when binding to ss-DNA. Klenow exhibits significant differences in the ΔC_p of binding to pt-DNA versus ds-DNA, and a difference in pI for these two complexes, whereas Klentaq does not, suggesting that Klenow and Klentaq discriminate between these two structures differently. Taken together, the data suggest that the two polymerases bind ds-DNA very differently, but that both bind pt-DNA and ss-DNA similarly, despite the absence of a proofreading site in Klentaq.     

Quantification of mitochondrial DNA (mtDNA) damage and error rates by real-time QPCR

Mitochondrial dysfunction has reported in several diseases including diabetes, cancer, skeletal muscle disorders and neurodegenerative diseases such as Wolfram syndrome. Several different methods have evolved to study mtDNA damage including Southern blotting, 8-oxoG damage, or a comprehensive scanning of the mitochondrial genome by RFLP or TTGE analyses. However these approaches require large amounts of DNA or are labor intensive. The use of polymerase amplification of long DNA products (LRPCR) has been described by several groups and more recently summarized by Van Houten’s group. The underlying basis use of DNA polymerases capable of generating long DNA products and the rationale is that any lesion (strand breaks, base modifications, apurinic sites) will stop a thermostable DNA polymerase. In this method, band density of the PCR product is quantified either by Southern blotting or binding of a fluorescent dye. Although the latter approach still has some limited use in the study gene expression, it is semi-quantitative and realtime PCR analysis has largely supplanted it. Direct application of real-time PCR to LRPCR has been made difficult because of low processivity and polymerization rates of the DNA polymerases used and SYBR green inhibition of DNA amplification. We have modified the LRPCR protocol to use the commercially available PfuUltra^? II Fusion HS DNA Polymerase for real-time determination of mitochondrial DNA amplification as a means to simplify and improve of the accuracy for quantification of mtDNA damage.     

Characteristics of microspheres formed in PCR with bacterial genomic DNA or plasmid DNA as templates

Earlier, we discovered that, along with linear DNA fragments, nano- and microparticles of DNA and their aggregates are formed in the PCR with yeast genomic DNA used as a template and gene-specific or partially complementary primers. The size of the microparticles (microspheres) varied in the range of 0.5 to 3–4 μm. Only thermostable KlenTaq polymerase but not Taq polymerase could effectively generate microspheres. In this work, we demonstrate that KlenTaq polymerase can produce microspheres of variable size (1 to 7 μm in diameter) if genomic DNA of the bacterium Acidithiobacillus ferrooxidans and partially complementary primers are present in the PCR mixture. Conditions for generation of DNA microparticles in PCR with Taq-polymerase and bacterial genomic DNA as template were also elaborated. It was also found that mainly large microspheres of up to 7 μm accumulated in PCR with plasmid DNAs used as templates and gene-specific primers in the presence of KlenTaq polymerase or mixtures of KlenTaq and Pfu polymerases. Besides, small aggregates, as well as linear branched structures and three-dimensional conglomerates of fused microspheres, were also revealed in the PCR mixtures. UV absorption spectra of native DNA microspheres and microspheres that had undergone heating at 93°C were registered. The key role of Mg²⁺ cations in the formation and stabilization of the microsphere structure was established.     

ExCyto PCR Amplification

Background

ExCyto PCR cells provide a novel and cost effective means to amplify DNA transformed into competent bacterial cells. ExCyto PCR uses host E. coli with a chromosomally integrated gene encoding a thermostable DNA polymerase to accomplish robust, hot-start PCR amplification of cloned sequences without addition of exogenous enzyme.

Results

Because the thermostable DNA polymerase is stably integrated into the bacterial chromosome, ExCyto cells can be transformed with a single plasmid or complex library, and then the expressed thermostable DNA polymerase can be used for PCR amplification. We demonstrate that ExCyto cells can be used to amplify DNA from different templates, plasmids with different copy numbers, and master mixes left on ice for up to two hours. Further, PCR amplification with ExCyto cells is comparable to amplification using commercial DNA polymerases. The ability to transform a bacterial strain and use the endogenously expressed protein for PCR has not previously been demonstrated.

Conclusions

ExCyto PCR reduces pipetting and greatly increases throughput for screening EST, genomic, BAC, cDNA, or SNP libraries. This technique is also more economical than traditional PCR and thus broadly useful to scientists who utilize analysis of cloned DNAs in their research.     

Mutant Thermotoga neapolitana DNA polymerase I: altered catalytic properties for non-templated nucleotide addition and incorporation of correct nucleotides

Thermotoga neapolitana (Tne) DNA polymerase belongs to the DNA polymerase I (Pol I) family. The O-helix region of these polymerases is involved in dNTP binding and also plays a role in binding primer–template during DNA synthesis. Here we report that mutations in the O-helix region of Tne DNA polymerase (Arg722 to His, Tyr or Lys) almost completely abolished the enzyme’s ability to catalyze the template-independent addition of a single base at the 3′-end of newly synthesized DNA in vitro. The mutations did not significantly affect the DNA polymerase catalytic activity and reduced base misinsertions 5- to 50-fold. The same Arg722 mutations dramatically increased the ability of the enzyme’s 3′→5′ exonuclease to remove mispaired 3′ bases in a primer extension assay. These mutant DNA polymerases can be used to accurately amplify target DNA in vitro for gene cloning and genotyping analysis.     

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.     

Interactions of replication versus repair DNA substrates with the Pol I DNA polymerases from Escherichia coli and Thermus aquaticus

Different DNA polymerases partition differently between replication and repair pathways. In this study we examine if two Pol I family polymerases from evolutionarily distant organisms also differ in their preferences for replication versus repair substrates. The DNA binding preferences of Klenow and Klentaq DNA polymerases, from Escherichia coli and Thermus aquaticus respectively, have been studied using a fluorescence competition binding assay. Klenow polymerase binds primed-template DNA (the replication substrate) with up to 50× higher affinity than it binds to nicked DNA, DNA with a 2 base single-stranded gap, blunt-ended DNA, or to a DNA end with a 3′ overhang. In contrast, Klentaq binds all of these DNAs almost identically, indicating that Klenow has a stronger ability to discriminate between replication and repair substrates than Klentaq. In contrast, both polymerases bind mismatched primed-template and blunt-ended DNA tighter than they bind matched primed-template DNA, suggesting that these two proteins may share a similar mechanism to identify mismatched DNA, despite the fact that Klentaq has no proofreading ability. In addition, the presence or absence of 5′- or 3′-phosphates has slightly different effects on DNA binding by the two polymerases, but again reinforce Klenow's more effective substrate discrimination capability.     

Novel thermostable Y-family polymerases: applications for the PCR amplification of damaged or ancient DNAs

For many years, Taq polymerase has served as the stalwart enzyme in the PCR amplification of DNA. However, a major limitation of Taq is its inability to amplify damaged DNA, thereby restricting its usefulness in forensic applications. In contrast, Y-family DNA polymerases, such as Dpo4 from Sulfolobus solfataricus, can traverse a wide variety of DNA lesions. Here, we report the identification and characterization of five novel thermostable Dpo4-like enzymes from Acidianus infernus, Sulfolobus shibatae, Sulfolobus tengchongensis, Stygiolobus azoricus and Sulfurisphaera ohwakuensis, as well as two recombinant chimeras that have enhanced enzymatic properties compared with the naturally occurring polymerases. The Dpo4-like polymerases are moderately processive, can substitute for Taq in PCR and can bypass DNA lesions that normally block Taq. Such properties make the Dpo4-like enzymes ideally suited for the PCR amplification of damaged DNA samples. Indeed, by using a blend of Taq and Dpo4-like enzymes, we obtained a PCR amplicon from ultraviolet-irradiated DNA that was largely unamplifyable with Taq alone. The inclusion of thermostable Dpo4-like polymerases in PCRs, therefore, augments the recovery and analysis of lesion-containing DNA samples, such as those commonly found in forensic or ancient DNA molecular applications.     

Overview of thermostable DNA polymerases for classical PCR applications: from molecular and biochemical fundamentals to commercial systems

During the genomics era, the use of thermostable DNA polymerases increased greatly. Many were identified and described—mainly of the genera Thermus, Thermococcus and Pyrococcus. Each polymerase has different features, resulting from origin and genetic modification. However, the rational choice of the adequate polymerase depends on the application itself. This review gives an overview of the most commonly used DNA polymerases used for PCR application: KOD, Pab (Isis?), Pfu, Pst (Deep Vent?), Pwo, Taq, Tbr, Tca, Tfi, Tfl, Tfu, Tgo, Tli (Vent?), Tma (UITma?), Tne, Tth and others.     

Thermostable DNA Ligase-Mediated PCR Production of Circular Plasmid (PPCP) and Its Application in Directed Evolution via In situ Error-Prone PCR

Polymerase chain reaction (PCR) is a powerful method to produce linear DNA fragments. Here we describe the Tma thermostable DNA ligase-mediated PCR production of circular plasmid (PPCP) and its application in directed evolution via in situ error-prone PCR. In this thermostable DNA ligase-mediated whole-plasmid amplification method, the resultant DNA nick between the 5′ end of the PCR primer and the extended newly synthesized DNA 3′ end of each PCR cycle is ligated by Tma DNA ligase, resulting in circular plasmid DNA product that can be directly transformed. The template plasmid DNA is eliminated by ‘selection marker swapping’ upon transformation. When performed under an error-prone condition with Taq DNA polymerase, PPCP allows one-step construction of mutagenesis libraries based on in situ error-prone PCR so that random mutations are introduced into the target gene without altering the expression vector plasmid. A significant difference between PPCP and previously published methods is that PPCP allows exponential amplification of circular DNA. We used this method to create random mutagenesis libraries of a xylanase gene and two cellulase genes. Screening of these libraries resulted in mutant proteins with desired properties, demonstrating the usefulness of in situ error-prone PPCP for creating random mutagenesis libraries for directed evolution.     

Conformational Dynamics of Thermus aquaticus DNA Polymerase I during Catalysis

Despite the fact that DNA polymerases have been investigated for many years and are commonly used as tools in a number of molecular biology assays, many details of the kinetic mechanism they use to catalyze DNA synthesis remain unclear. Structural and kinetic studies have characterized a rapid, pre-catalytic open-to-close conformational change of the Finger domain during nucleotide binding for many DNA polymerases including Thermus aquaticus DNA polymerase I (Taq Pol), a thermostable enzyme commonly used for DNA amplification in PCR. However, little has been performed to characterize the motions of other structural domains of Taq Pol or any other DNA polymerase during catalysis. Here, we used stopped-flow Förster resonance energy transfer to investigate the conformational dynamics of all five structural domains of the full-length Taq Pol relative to the DNA substrate during nucleotide binding and incorporation. Our study provides evidence for a rapid conformational change step induced by dNTP binding and a subsequent global conformational transition involving all domains of Taq Pol during catalysis. Additionally, our study shows that the rate of the global transition was greatly increased with the truncated form of Taq Pol lacking the N-terminal domain. Finally, we utilized a mutant of Taq Pol containing a de novo disulfide bond to demonstrate that limiting protein conformational flexibility greatly reduced the polymerization activity of Taq Pol.     

The Glutamate Effect on DNA Binding by Pol I DNA Polymerases: Osmotic Stress and the Effective Reversal of Salt Linkage

The significant enhancing effect of glutamate on DNA binding by Escherichia coli nucleic acid binding proteins has been extensively documented. Glutamate has also often been observed to reduce the apparent linked ion release (Δn_ions) upon DNA binding. In this study, it is shown that the Klenow and Klentaq large fragments of the Type I DNA polymerases from E. coli and Thermus aquaticus both display enhanced DNA binding affinity in the presence of glutamate versus chloride. Across the relatively narrow salt concentration ranges often used to obtain salt linkage data, Klenow displays an apparently decreased Δn_ions in the presence of Kglutamate, while Klentaq appears not to display an anion-specific effect on Δn_ions.Osmotic stress experiments reveal that DNA binding by Klenow and Klentaq is associated with the release of ∼ 500 to 600 waters in the presence of KCl. For both proteins, replacing chloride with glutamate results in a 70% reduction in the osmotic-stress-measured hydration change associated with DNA binding (to ∼ 150-200 waters released), suggesting that glutamate plays a significant osmotic role.Measurements of the salt-DNA binding linkages were extended up to 2.5 M Kglutamate to further examine this osmotic effect of glutamate, and it is observed that a reversal of the salt linkage occurs above 800 mM for both Klenow and Klentaq. Salt-addition titrations confirm that an increase of [Kglutamate] beyond 1 M results in rebinding of salt-displaced polymerase to DNA. These data represent a rare documentation of a reversed ion linkage for a protein-DNA interaction (i.e., enhanced binding as salt concentration increases). Nonlinear linkage analysis indicates that this unusual behavior can be quantitatively accounted for by a shifting balance of ionic and osmotic effects as [Kglutamate] is increased. These results are predicted to be general for protein-DNA interactions in glutamate salts.     

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.     

Building better polymerases: Engineering the replication of expanded genetic alphabets

DNA polymerases are today used throughout scientific research, biotechnology, and medicine, in part for their ability to interact with unnatural forms of DNA created by synthetic biologists. Here especially, natural DNA polymerases often do not have the “performance specifications” needed for transformative technologies. This creates a need for science-guided rational (or semi-rational) engineering to identify variants that replicate unnatural base pairs (UBPs), unnatural backbones, tags, or other evolutionarily novel features of unnatural DNA. In this review, we provide a brief overview of the chemistry and properties of replicative DNA polymerases and their evolved variants, focusing on the Klenow fragment of Taq DNA polymerase (Klentaq). We describe comparative structural, enzymatic, and molecular dynamics studies of WT and Klentaq variants, complexed with natural or noncanonical substrates. Combining these methods provides insight into how specific amino acid substitutions distant from the active site in a Klentaq DNA polymerase variant (ZP Klentaq) contribute to its ability to replicate UBPs with improved efficiency compared with Klentaq. This approach can therefore serve to guide any future rational engineering of replicative DNA polymerases.     

The PCR plateau phase - towards an understanding of its limitations

The DNA polymerases from Thermus aquaticus and Thermus flavus were recently found to bind to short double-stranded DNA fragments without sequence specificity [Kainz et al. (2000) Biotechniques 28, 278-82]. In the present study, it is shown that the accumulation of amplification products during later PCR cycles also exerts an inhibitory effect on several enzymes tested. To simulate later cycle conditions, a 1.7 kb sequence from phage lambda DNA was amplified in the presence of various amounts of a 1 kb double-stranded DNA fragment. A 30-fold molar excess of fragments to polymerase molecules was found to be required for a complete inhibition of Taq, Tfl and Pwo DNA polymerase. This stoichiometric relation remained constant when PCR amplifications were performed using polymerase concentrations of 0.5, 1 or 1.5 U/50 microl reaction volume. The amount of 1 kb DNA fragments required for a complete inhibition was similar to the product yield of the controls (no fragment added), that were run to plateau phase levels. Additionally, PCR mixtures, that were subjected to different numbers of cycles, were compared in their ability to extend 3'-recessed ends by using a hairpin extension assay. The presence of endogenous amplicon DNA accumulated in later PCR cycles was found to inhibit completely the activity of DNA polymerase. PCR mixtures still in quasi-linear phase partially extended the hairpins. In both cases, a further addition of polymerase significantly improved their function. These results indicate that the main factor contributing to the plateau phase in PCR consists of binding of DNA polymerase to its amplification products.     

Escherichia coli exonuclease III enhances long PCR amplification of damaged DNA templates

Recent development of the long PCR technology has provided an invaluable tool in many areas of molecular biology. However, long PCR amplification fails whenever the DNA template is imperfectly preserved. We report that Escherichia coli exonuclease III, a major repair enzyme in bacteria, strikingly improves the long PCR amplification of damaged DNA templates. Escherichia coli exonuclease III permitted or improved long PCR amplification with DNA samples submitted to different in vitro treatments known to induce DNA strand breaks and/or apurinic/apyrimidinic (AP) sites, including high temperature (99°C), depurination at low pH and near-UV radiation. Exonuclease III also permitted or improved amplification with DNA samples that had been isolated several years ago by the phenol/chloroform method. Amelioration of long PCR amplification was achieved for PCR products ranging in size from 5 to 15.4 kb and with DNA target sequences located either within mitochondrial DNA or the nuclear genome. Exonuclease III increased the amplification of damaged templates using either rTth DNA polymerase alone or rTth plus Vent DNA polymerases or Taq plus Pwo DNA polymerases. However, exonuclease III could not improve PCR amplification from extensively damaged DNA samples. In conclusion, supplementation of long PCR mixes with E.coli exonuclease III may represent a major technical advance whenever DNA samples have been partly damaged during isolation or subsequent storage.     

Enthalpic switch-points and temperature dependencies of DNA binding and nucleotide incorporation by Pol I DNA polymerases

This study examines the relationship between the DNA binding thermodynamics and the enzymatic activity of the Klenow and Klentaq Pol I DNA polymerases from Escherichia coli and Thermus aquaticus. Both polymerases bind DNA with nanomolar affinity at temperatures down to at least 5 °C, but have lower than 1% enzymatic activity at these lower temperatures. For both polymerases it is found that the temperature of onset of significant enzymatic activity corresponds with the temperature where the enthalpy of binding (ΔH_binding) crosses zero (T_H) and becomes favorable (negative). This T_H/activity upshift temperature is 15 °C for Klenow and 30 °C for Klentaq. The results indicate that a negative free energy of DNA binding alone is not sufficient to proceed to catalysis, but that the enthalpic versus entropic balance of binding may be a modulator of the temperature dependence of enzymatic function. Analysis of the temperature dependence of the catalytic activity of Klentaq polymerase using expanded Eyring theory yields thermodynamic patterns for ΔG^‡, ΔH^‡, and TΔS^‡ that are highly analogous to those commonly observed for direct DNA binding. Eyring analysis also finds a significant ΔCp^‡ of formation of the activated complex, which in turn indicates that the temperature of maximal activity, after which incorporation rate slows with increasing temperature, will correspond with the temperature where the activation enthalpy (ΔH^‡) switches from positive to negative.     

Polymerase chain reaction optimization for amplification of Guanine-Cytosine rich templates using buccal cell DNA

CONTEXT:

Amplification of Guanine-Cytosine (GC) -rich sequences becomes important in screening and diagnosis of certain genetic diseases such as diseases arising due to expansion of GC-rich trinucleotide repeat regions. However, GC-rich sequences in the genome are refractory to standard polymerase chain reaction (PCR) amplification and require a special reaction conditions and/or modified PCR cycle parameters.

AIM:

Optimize a cost effective PCR assay to amplify the GC-rich DNA templates.

SETTINGS AND DESIGN:

Fragile X mental retardation gene (FMR 1) is an ideal candidate for PCR optimization as its GC content is more than 80%. Primers designed to amplify the GC rich 5’ untranslated region of the FMR 1 gene, was selected for the optimization of amplification using DNA extracted from buccal mucosal cells.

MATERIALS AND METHODS:

A simple and rapid protocol was used to extract DNA from buccal cells. PCR optimization was carried out using three methods, (a) substituting a substrate analog 7-deaza-dGTP to dGTP (b) in the presence of a single PCR additive and (c) using a combination of PCR additives. All PCR amplifications were carried out using a low-cost thermostable polymerase.

RESULTS:

Optimum PCR conditions were achieved when a combination of 1M betaine and 5% dimethyl sulfoxide (DMSO) was used.

CONCLUSIONS:

It was possible to amplify the GC rich region of FMR 1 gene with reproducibility in the presence of betaine and DMSO as additives without the use of commercially available kits for DNA extraction and the expensive thermostable polymerases.     

Stopped-flow DNA polymerase assay by continuous monitoring of dNTP incorporation by fluorescence

DNA polymerase activity was measured by a stopped-flow assay that monitors polymerase extension using an intercalating dye. Double-stranded DNA formation during extension of a hairpin substrate was monitored at 75 °C for 2 min. Rates were determined in nucleotides per second per molecule of polymerase (nt/s) and were linear with time and polymerase concentration from 1 to 50 nM. The concentrations of 15 available polymerases were quantified and their extension rates determined in 50 mM Tris, pH 8.3, 0.5 mg/ml BSA, 2 mM MgCl₂, and 200 μM each dNTP as well as their commercially recommended buffers. Native Taq polymerases had similar extension rates of 10–45 nt/s. Three alternative polymerases showed faster speeds, including KOD (76 nt/s), Klentaq I (101 nt/s), and KAPA2G (155 nt/s). Fusion polymerases including Herculase II and Phusion were relatively slow (3–13 nt/s). The pH optimum for Klentaq extension was between 8.5 and 8.7 with no effect of Tris concentration. Activity was directly correlated to the MgCl₂ concentration and inversely correlated to the KCl concentration. This continuous assay is relevant to PCR and provides accurate measurement of polymerase activity using a defined template without the need of radiolabeled substrates.