Engineered split in Pfu DNA polymerase fingers domain improves incorporation of nucleotide gamma-phosphate derivative.

Using compartmentalized self-replication (CSR), we evolved a version of Pyrococcus furiosus (Pfu) DNA polymerase that tolerates modification of the γ-phosphate of an incoming nucleotide. A Q484R mutation in α-helix P of the fingers domain, coupled with an unintended translational termination-reinitiation (split) near the finger tip, dramatically improve incorporation of a bulky γ-phosphate-O-linker-dabcyl substituent. Whether synthesized by coupled translation from a bicistronic (-1 frameshift) clone, or reconstituted from separately expressed and purified fragments, split Pfu mutant behaves identically to wild-type DNA polymerase with respect to chromatographic behavior, steady-state kinetic parameters (for dCTP), and PCR performance.

Long-range PCR with a DNA polymerase fusion.

Proofreading DNA polymerase fusions offer several advantages for long-range PCR, including faster run times and higher fidelity compared with Taq-based enzymes. However, their use so far has been limited to amplification of small to mid-range targets. In this article, we present a modified protocol for using a DNA polymerase fusion to amplify genomic targets exceeding 20 kb in length.

Easy two-step method for randomizing and cloning gene fragments.

Random mutagenesis is widely used in protein engineering to improve or alter protein function. Creating random mutant libraries typically requires cloning of randomly mutagenized fragments into an expression vector, which is laborious and often hampered by lack of unique and convenient restriction sites. Here, we report an easy two-step method that produces a more balanced mutational spectrum and simplifies the cloning of randomly mutagenized genes or gene fragments for constructing high titer random mutant libraries.

Fine-tuning enzyme activity through saturation mutagenesis.

Codon saturation is a powerful tool for analyzing protein structure-function relationships and fine-tuning enzyme activity. In this technique, one or more key amino acids are randomized by incorporating degenerate codon(s) into a gene of interest in a polymerase-mediated primer extension reaction. Traditional methods for codon saturation mutagenesis are labor-intensive and typically require multiple rounds of PCR and restriction/ligation-based cloning.

Rapid quantification of DNA libraries for next-generation sequencing.

The next-generation DNA sequencing workflows require an accurate quantification of the DNA molecules to be sequenced which assures optimal performance of the instrument. Here, we demonstrate the use of qPCR for quantification of DNA libraries used in next-generation sequencing. In addition, we find that qPCR quantification may allow improvements to current NGS workflows, including reducing the amount of library DNA required, increasing the accuracy in quantifying amplifiable DNA, and avoiding amplification bias by reducing or eliminating the need to amplify DNA before sequencing.

Escherichia coli DNA polymerase III epsilon subunit increases Moloney murine leukemia virus reverse transcriptase fidelity and accuracy of RT-PCR procedures.

In an effort to improve reverse transcriptase (RT) fidelity, we measured the error rate of Moloney murine leukemia virus (MMLV) RT in the presence of several autonomous and DNA polymerase-associated 3'-5' exonucleases using a lacZ forward mutation assay. A number of 3'-5' exonucleases were found to lower the error rate of MMLV RT, including p53, Escherichia coli DNA polymerase III epsilon subunit, and the proofreading activities associated with T4, varphi29, and E. coli pol I DNA polymerases.

Amplification efficiency of thermostable DNA polymerases.

The amplification efficiencies of several polymerase chain reaction (PCR) enzymes were compared using real-time quantitative PCR with SYBR Green I detection. Amplification data collected during the exponential phase of PCR are highly reproducible, and PCR enzyme performance comparisons based upon efficiency measurements are considerably more accurate than those based on endpoint analysis. DNA polymerase efficiencies were determined under identical conditions using five different amplicon templates that varied in length or percentage GC content.

Creating randomized amino acid libraries with the QuikChange Multi Site-Directed Mutagenesis Kit.

The QuikChange Multi Site-Directed Mutagenesis Kit is a simple and efficient method for introducing point mutations at up to five sites simultaneously in plasmid DNA templates. Here we used the QuikChange Multi kit with degenerate (one codon) primers to introduce all possible amino acids at selected sites in the lacZ gene. In reactions employing two or three degenerate primers, diverse libraries (10(4)-10(5) mutants/reaction) are created consisting of random combinations of mutations at two or three different sites.

Efficient and high fidelity incorporation of dye-terminators by a novel archaeal DNA polymerase mutant.

We examined the molecular basis of ddNTP selectivity in archaeal family B DNA polymerases by randomly mutagenizing the gene encoding Thermococcus sp. JDF-3 DNA polymerase and screening mutant libraries for improved ddNTP incorporation. We identified two mutations, P410L and A485T, that improved ddNTP uptake, suggesting the contribution of P410 and A485 to ddNTP/dNTP selectivity in archaeal DNA polymerases.

Archaeal dUTPase enhances PCR amplifications with archaeal DNA polymerases by preventing dUTP incorporation.

We discovered a thermostable enzyme from the archaeon Pyrococcus furiosus (Pfu), which increases yields of PCR product amplified with Pfu DNA polymerase. A high molecular mass (>250 kDa) complex with PCR-enhancing activity was purified from Pfu extracts. The complex is a multimer of two discrete proteins, P45 and P50, with significant similarity to bacterial dCTP deaminase/dUTPase and DNA flavoprotein, respectively.