A simple and efficient method for extraction of Taq DNA polymerase

Background Thermostable DNA polymerase (Taq Pol ?) from Thermus aquaticus has been widely used in PCR, which was usually extracted with Pluthero's method. The method used ammonium sulfate to precipitate the enzyme, and it saved effort and money but not time. Moreover, we found that 30-40% activity of Taq Pol I was lost at the ammonium sulfate precipitation step, and the product contained a small amount of DNA. Results We provided a novel, simplified and low-cost method to purify the Taq Pol ? after overproduction of the enzyme in Escherichia coli, which used ethanol instead of ammonium sulfate to precipitate the enzyme. The precipitate can be directly dissolved in the storage buffer without dialysis. In addition, DNA and RNA contamination was removed with DNase I and RNase A before precipitation, and the extraction procedure was optimized. Our improvements increase recovery rate and specific activity of the enzyme, and save labor, time, and cost. Conclusions Our method uses ethanol, DNase I, and RNase A to purify the Taq Pol ?, and simplifies the operation, and increases the enzyme recovery rate and quality.

[Purification of Taq DNA polymerase expressed in Escherichia coli].

Taq DNA polymerase is one of the most commonly thermostable DNA polymerases in molecular biological researches, which shares its basic characters with others of the family, thereby its purifying strategy could be used not only in itself production but also in the extraction of the others as a reference. At present, the protocols reported for large scale preparation of Taq DNA are high cost, so a cheaper method was described here. In this protocol, by heat denaturation, ammonium sulfate precipitation and cation exchange chromatography of 724 resin, about 18 g powder of Na form resin could recover about 27.07 mg of Taq enzyme. The total activity and specific activity were approximately 2.2 × 105 U and 8131.98 U/mg. The total yield was about 48.92% with 59.35 of purification folds. Analysis of quality of purified enzyme indicated that only one protein 94 kDa was identified against SDS-PAGE and the remnant of DNA nuclease was not detected. For PCR reaction, The amplification ability of purified Taq polymerase was not different from that of the commercially avail-able ones. This method reported in the present study is effective and low cost, making it suitable for general purification in laboratories or business production.

A novel eukaryote-made thermostable DNA polymerase which is free from bacterial DNA contamination.

To achieve the production of a thermostable DNA polymerase free from bacterial DNA contamination, we developed eukaryote-made thermostable DNA (Taq) polymerase. The novel eukaryote-made thermostable DNA polymerase resolves the problem of contaminating bacterial DNA in conventional bacterially made thermostable DNA polymerase as a result of its manufacture and incomplete purification. Using eukaryote-made thermostable DNA polymerase, the sensitive and reliable detection of bacteria becomes feasible for large fields, thereby making the development of a wide range of powerful applications possible.

High-cell density shake-flask expression and rapid purification of the large fragment of Thermus aquaticus DNA polymerase I using a new chemically and temperature inducible expression plasmid in Escherichia coli.

We have developed a new expression vector, pcI(ts) ind(+), based upon the powerful rightward promoter of bacteriophage lambda, which is controlled by a temperature-sensitive and chemically-inducible version of the lambda repressor on the same plasmid. Locating the repressor gene on the plasmid makes this vector "portable" in that it can be used to transform any strain of Escherichia coli. Hence, control over strains, induction conditions, and harvest times can be used to optimize yields of heterologous proteins. To provide a proof of concept, we show that E. coli recA(+) and recA(-) host cells transformed with pcI(ts) ind(+) modKlenTaq1 (a modified version of the large fragment of Thermus aquaticus DNA polymerase I) could be grown to high cell densities in multiple shake-flasks. A mutant version of modKlenTaq1 (V649C) could be induced by simply raising the thermostat setting from 30 to 37 degrees C and (in the case of recA(+) cells) adding nalidixic acid to achieve full induction (12-13% of the total cellular protein). Using a rapid, two-step purification process, it was possible to purify nearly 300 mg of modKlenTaq1 V649C from six 2.8-L baffle-bottomed shake-flasks each holding 1.5L of culture for a final yield of approximately 33 mg per liter or 3mg of purified enzyme per gram of cells wet weight.

Rapid purification of truncated Taq DNA polymerase Stoffel fragment by boiling lysis of bacterial expression cultures.

A simplified and low-cost method, boiling lysis, was developed and used to purify the truncated DNA polymerase Stoffel fragment after overproduction of the enzyme in Escherichia coli. The method is based on the thermostable properties of the Stoffel fragment. Conditions such as the boiling time and number of cycles employed were identified as determinants with which to achieve a high yield and activity of this truncated Taq enzyme. Under established conditions, a period of 8 min consisting of two cycles of boiling and centrifuging was ideal for the purification of the Taq protein, followed by dibasic phosphate and ethanol extraction in a single type of storage buffer to remove contaminating nucleic acid. The whole purification process could be achieved within 1 or 2 h. A total yield of 80 mg of truncated Taq enzyme with an activity of 1.6x10(7) units was purified from l litre of bacterial culture. The purified Taq enzyme had a molecular mass of 61 kDa, a value consistent with the truncated DNA polymerase Stoffel fragment reported previously.

One-step purification of Taq DNA polymerase using nucleotide-mimetic affinity chromatography.

The thermostable Thermus aquaticus DNA polymerase (Taq Pol) has been the key factor in transforming the initial PCR method into one with huge impact in molecular biology and biotechnology. Therefore, the development of effective affinity adsorbents for the purification of Taq Pol, as well as other DNA polymerases, attracts the attention of the enzyme manufacturers and the research laboratories. In this report we describe a simple protocol for the purification of Taq Pol from E. coli lysates, leading to enzymes of high specific activity and purity. The protocol is based on a single affinity chromatography step, featuring an immobilized ligand selected from a structure-biased combinatorial library of dNTP-mimetic synthetic ligands. The ligand library was screened for its ability to bind and purify Taq Pol from E. coli lysates. One immobilized ligand (mABSGu) of the general formula X-Trz-Y, bearing 9-aminoethylguanine (AEGu) and aniline-2-sulfonic acid (mABS) linked on the triazine scaffold (Trz), displayed the highest purifying ability. Adsorption equilibrium studies with this affinity ligand and Taq Pol determined a dissociation constant (KD) of 0.12 mM for the respective complex, whereas ATP prevented the formation of the mABSGu-Taq Pol complex. The mABSGu affinity adsorbent was exploited in the development of a facile Taq Pol purification protocol, affording homogeneous enzyme (>99% purity, approximately 61 500 U/mg) in a single chromatography step. Quality control tests showed that Taq Pol purified on the mABSGu affinity adsorbent is free of nucleic acids and contaminating nuclease activities.

Removal of contaminating TEM-la beta-lactamase gene from commercial Taq DNA polymerase.

This study confirms that Taq DNA polymerase could be contaminated with the blaTEM-1(a) gene. It also proposes two different methods that could be used to overcome DNA contamination: (i) DNase I treatment prior to PCR amplification; and (ii) the use of a highly purified Taq DNA polymerase which was devoid of detectable contamination.

Overcoming bacterial DNA contamination in real-time PCR and RT-PCR reactions for LacZ detection in cell therapy monitoring.

Since the introduction of the polymerase chain reaction the presence of contaminating bacterial DNA in the Taq polymerase preparations has hampered the use of this technique in microbiology. Lately, this inconvenience has equally impeded gene quantification in the field of cell or gene therapy, where bacterial genes such as LacZ are often used as tags to detect vectors or cells after their injection in the recipient organism. Several means to overcome the DNA contamination of Taq Polymerase have been reported with variable degrees of decontamination efficiency and alteration of the PCR reaction. Here we propose two protocols to efficiently quantify DNA or RNA from the LacZ gene by real-time PCR using either decontamination by low concentrations of DNAse I prior to PCR amplification or a highly purified Taq Polymerase which is devoid of detectable contamination.

Ligands selected from combinatorial libraries of protein A for use in affinity capture of apolipoprotein A-1M and taq DNA polymerase.

Here we show that robust and small protein ligands can be used for affinity capture of recombinant proteins from crude cell lysates. Two ligands selectively binding to bacterial Taq DNA polymerase and human apolipoprotein A-1(M), respectively, were used in the study. The ligands were selected from libraries of a randomized alpha-helical bacterial receptor domain derived from staphylococcal protein A and have dissociation constants in the micromolar range, which is typical after primary selection from these libraries consisting of approximately 40 million different members each. Using these ligands in affinity chromatography, both target proteins were efficiently recovered from crude cell lysates with high selectivities. No loss of column capacity or selectivity was observed for repeated cycles of sample loading, washing and low pH elution. Interestingly, column sanitation could be performed using 0. 5 M sodium hydroxide without significant loss of ligand performance. The results suggest that combinatorial approaches using robust protein domains as scaffolds can be a general tool in the process of designing purification strategies for biomolecules.

Recombinant His-tagged DNA polymerase. II. Cloning and purification of Thermus aquaticus recombinant DNA polymerase (Stoffel fragment).

The Stoffel DNA fragment, shortened by 12 bp from 5' end, coding for Stoffel DNA polymerase (missing 4 amino acids at N-terminus of Stoffel amino-acids sequence) from the thermophilic Thermus aquaticus (strain YT-1) was amplified, cloned and expressed in Escherichia coli. The recombinant Stoffel fragment contained a polyhistidine tag at the N-terminus (21 additional amino acids) that allowed its single-step isolation by Ni2+ affinity chromatography. The enzyme was characterized and displayed high DNA polymerase activity and thermostability evidently higher than the native Taq DNA polymerase.

Production and evaluation of Taq DNA polymerase.

Taq DNA polymerase is an enzyme essential in performing Polymerase Chain Reaction (PCR) which has recently become a basic technology in research and diagnostic laboratories. In order to reduce the cost of research work in Thailand, recombinant Taq DNA polymerase was locally produced from pTaq cloned in E. coli. The enzyme was characterized and evaluated in comparison with the commercial Taq DNA polymerase produced by Perkin Elmer Cetus, U.S.A. The yield of enzyme was 6.72 mg/ml and the activity of 9,524 units/mg protein with the total of 448,000 units/litre of the bacterial culture. The preparation was free of DNase based upon its ability to degrade Lambda DNA evaluated by gel electrophoresis. Although the enzyme produced gave a high DNA polymerase activity, the preparation was not as pure as the enzyme produced by Perkin Elmer Cetus. Immunoblot analysis indicated that the enzyme preparation contained the products of enzyme degradation obtained during preparation and bacterial protein contaminations. In spite of the existence of bacterial proteins in the preparation, the Taq enzyme produced was proved to be applicable in performing PCR such as the PCR-SSP (Sequence Specific Primers) typing for HLA-DR. The cost of enzyme preparation was about 256 times less than that of the commercial enzyme. Economically, the locally produced Taq DNA polymerase can be used efficiently in the research laboratories performing PCR based typing of the HLA genes.

Mutagenesis of the positively charged conserved residues in the 5' exonuclease domain of Taq DNA polymerase.

Taq DNA polymerase from Thermus aquaticus has been shown to be very useful in the polymerase chain reaction method. Taq DNA polymerase has a domain at the amino terminus (residue 1 to 290) that has a 5' exonuclease activity and a domain at the C-terminus that catalyzes polymerase reaction. Taq DNA polymerase is classified into the pol I family which is represented by E. coli DNA polymerase I. The alignment of amino acid sequences for the 5' exonuclease domains of the pol I family DNA polymerases shows six highly conserved sequences called motifs A to F. Motif C contains three positively charged residues such as 74Arg, 82Lys and 85Arg which might be involved in catalysis. In order to understand the function of those residues, they are mutagenized to alanine. The 5' exonucleolytic activities of those mutated 5' exonucleases decreased by 80 to 90%, thereby implying that three positively charged residues play certain roles in the 5' exonuclease catalysis.