Project description:Potent PCR inhibitors in blood and soil samples can cause false negative results from PCR-based clinical and forensic tests. We show that the effect of these inhibitors is primarily upon Taq DNA polymerase, since mutational alteration of the polymerase can overcome the inhibition to the extent that no DNA purification is now required. An N-terminal deletion (Klentaq1) is some 10-100-fold inhibition resistant to whole blood compared to full-length, wild-type (w.t.) Taq, which is strongly inhibited by 0.1-1% blood. Further mutations at codon 708, both in Klentaq 1 and Taq, confer enhanced resistance to various inhibitors of PCR reactions, including whole blood, plasma, hemoglobin, lactoferrin, serum IgG, soil extracts and humic acid, as well as high concentrations of intercalating dyes. Blood PCR inhibitors can predominantly reduce the DNA extension speed of the w.t. Taq polymerase as compared to the mutant enzymes. Single-copy human genomic targets are readily amplified from whole blood or crude soil extract, without pretreatment to purify the template DNA, and the allowed increase in dye concentration overcomes fluorescence background and quenching in real-time PCR of blood.

Project description:DNA damage blocks DNA polymerase progression and increases miscoding. In this study, we assessed the effects of specific lesions on Taq DNA polymerase fidelity and amplification efficiency. In the presence of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG), Taq DNA polymerase inserted dCMP and to a lesser extent dAMP. 8-Oxo-7,8-dihydro-2'-deoxyadenosine (8-oxodA) instructed the incorporation of dTMP and caused a pronounced n-1 deletion not observed in other systems. The presence of an abasic lesion led to dAMP incorporation and n-1 deletions. In addition, we introduce the mean modified efficiency (MME) as a more precise method for determining PCR amplification efficiency of damaged templates. Using this method, we were able to quantify reductions in amplification efficiency of templates containing 8-oxodG (single or multiple), 8-oxodA, or abasic sites. Because the MME method can detect small reductions in amplification efficiency, it may be useful in comparing the extent of damage in environmentally degraded or archival DNA specimens.

Project description:Allele-specific PCR (AS-PCR) has been used as a simple, cost-effective method for genotyping and gene mapping in research and clinical settings. AS-PCR permits the detection of single nucleotide variants and insertion or deletion variants owing to the selective extension of a perfectly matched primer (to the template DNA) over a mismatched primer. Thus, the mismatch discrimination power of the DNA polymerase is critical. Unfortunately, currently available polymerases often amplify some mismatched primer-template complexes as well as matched ones, obscuring AS detection. To increase mismatch discrimination, mutations were generated in the Thermus aquaticus (Taq) DNA polymerase, the most efficient variant was selected, and its performance evaluated in single nucleotide polymorphism and cancer mutation genotyping. In addition, the primer design and reaction buffer conditions were optimized for AS amplification. Our highly selective AS-PCR, which is based on an allele-discriminating priming system that leverages a Taq DNA polymerase variant with optimized primers and reaction buffer, can detect mutations with a mutant allele frequency as low as 0.01% in genomic DNA and 0.0001% in plasmid DNA. This method serves as a simple, fast, cost-effective, and ultra-sensitive way to detect single nucleotide variants and insertion or deletion mutations with low abundance.

Project description:Taq DNA polymerase functions at elevated temperatures with fast conformational dynamics-regimes previously inaccessible to mechanistic, single-molecule studies. Here, single-walled carbon nanotube transistors recorded the motions of Taq molecules processing matched or mismatched template-deoxynucleotide triphosphate pairs from 22° to 85°C. By using four enzyme orientations, the whole-enzyme closures of nucleotide incorporations were distinguished from more rapid, 20-μs closures of Taq's fingers domain testing complementarity and orientation. On average, one transient closure was observed for every nucleotide binding event; even complementary substrate pairs averaged five transient closures between each catalytic incorporation at 72°C. The rate and duration of the transient closures and the catalytic events had almost no temperature dependence, leaving all of Taq's temperature sensitivity to its rate-determining open state.

Project description:A change of an aspartic acid to asparagine of Taq (Thermus aquaticus) DNA polymerase is a gain of function mutation that supports faster PCR: the extension times for PCR amplification can be 2-3 times shorter. Surprising results from negative controls led to the discovery of strand-displacement ability and reverse transcriptase activity of Taq D732N DNA polymerase. We demonstrate that the mutant enzyme can, by itself, catalyze RT-PCR, and RT-LAMP assays. Residue 732 is on the surface of the enzyme, not near the active site.

Project description:Taq DNA polymerase, one of the first thermostable DNA polymerases to be discovered, has been typecast as a DNA-dependent DNA polymerase commonly employed for PCR. However, Taq polymerase belongs to the same DNA polymerase superfamily as the Molony murine leukemia virus reverse transcriptase and has in the past been shown to possess reverse transcriptase activity. We report optimized buffer and salt compositions that promote the reverse transcriptase activity of Taq DNA polymerase and thereby allow it to be used as the sole enzyme in TaqMan RT-qPCRs. We demonstrate the utility of Taq-alone RT-qPCRs by executing CDC SARS-CoV-2 N1, N2, and N3 TaqMan RT-qPCR assays that could detect as few as 2 copies/μL of input viral genomic RNA.

Project description:BACKGROUND: The detection of a broad range of bacteria by PCR is applied for the screening of blood and blood products with special attention to platelet concentrates. For practical use it is desirable that detection systems include Gram-positive, Gram-negative and non-Gram-stainable bacteria. It is quite challenging to achieve high sensitivity along with a clear negative control with PCR reagents, because especially Taq polymerase is contaminated with traces of bacterial DNA. METHODS: Bacterial DNA decontamination of Taq polymerase was attempted by two different methods using the restriction enzyme Sau 3A1 and microfiltration. Additionally a commercially available Taq polymerase depleted of bacterial DNA was included. A published real-time PCR specific for Gram-negative bacteria was adapted for Gram-positive bacteria, including certain Staphylococcus species and Mycobacteria, and was used to charge the three Taq polymer-ases depleted of bacterial DNA contamination RESULTS: Despite published reports about successful DNA decontamination, all three approaches performed poorly in experiments done in this study. Sensitivity ranged at approximately 50-100 colony forming units (CFU) per PCR reaction for Escherichia coli and Staphylococcus epidermidis, corresponding to 1,250-2,500 CFU/ml sample material. Conclusion: It seems unsatisfying to accept detection limits that high for diagnostic bacterial PCR even if highly multiplexed. Reliable methods for DNA decontamination of Taq polymerase are needed and would present one important step towards bacterial DNA detection with high sensitivity.

Project description:Polymerase chain reaction (PCR) technique is widely used in many experimental conditions, and Taq DNA polymerase is critical in PCR process. In this article, the Taq DNA polymerase expression plasmid is reconstructed and the protein product is obtained by rapid purification, ("Rapid purification of high-activity Taq DNA polymerase" (Pluthero, 1993 [1]), "Single-step purification of a thermostable DNA polymerase expressed in Escherichia coli" (Desai and Pfaffle, 1995 [2])). Here we present the production data from protein expression and provide the analysis results of the production from two different vectors. Meanwhile, the purification data is also provided to show the purity of the protein product.

Project description:The polymerase chain reaction (PCR) is widely used for applications which require a high level of specificity and reliability, such as genetic testing, clinical diagnostics, blood screening, forensics and biodefense. Great improvements to PCR performance have been achieved by the use of Hot Start activation strategies that aim to prevent DNA polymerase extension until more stringent, higher temperatures are reached. Herein we present a novel Hot Start activation approach in PCR where primers contain one or two thermolabile, 4-oxo-1-pentyl (OXP) phosphotriester (PTE) modification groups at 3'-terminal and 3'-penultimate internucleotide linkages. Studies demonstrated that the presence of one or more OXP PTE modifications impaired DNA polymerase primer extension at the lower temperatures that exist prior to PCR amplification. Furthermore, incubation of the OXP-modified primers at elevated temperatures was found to produce the corresponding unmodified phosphodiester (PDE) primer, which was then a suitable DNA polymerase substrate. The OXP-modified primers were tested in conventional PCR with endpoint detection, in one-step reverse transcription (RT)-PCR and in real-time PCR with SYBR Green I dye and Taqman(R) probe detection. When OXP-modified primers were used as substitutes for unmodified PDE primers in PCR, significant improvement was observed in the specificity and efficiency of nucleic acid target amplification.

Project description:Many studies have reported the presence of bacterial DNA contamination in commercial Taq DNA polymerase reagents. This is the first report of the presence of phage-like DNA sequences in certain commercial Taq DNA polymerase reagents. Precautions are needed when using amplification reagents with exogenous DNAs.