New morphotypes of condensed DNA microparticles formed in PCR with <Emphasis Type="Italic">KlenTaq</Emphasis> and <Emphasis Type="Italic">Taq</Emphasis> polymerases and plasmid DNA as a template

The specimens of DNA microparticles formed during PCR amplification of IS-elements ISAfe1 and IST2 by KlenTaq or Taq polymerases and plasmid DNA as a template under varying conditions were investigated by electron microscopy. Microparticle yield and morphology were found to depend on the level of synthesis of single-stranded DNA fragments during PCR. The conditions were studied for formation of discs (ellipsoids) several micrometers in diameter and several dozens of nanometers thick, as well as of microparticles of other morphologies, in the course of PCR with Taq polymerase. The structure of the microparticles produced during an asymmetric PCR, i.e., under conditions of low concentration of one of the two primers, was investigated. Morphology of the DNA micro- and nanoparticles was found to depend mainly on the DNA polymerase used in asymmetric PCR. In particular, in the presence of the KlenTaq polymerase, discs or ellipsoids a few dozen nanometers thick were formed, while in the presence of the Taq polymerase, micro- and nanospheres, heterogeneous in size with rugged surfaces, were produced. The effect of Mn²⁺ cations on DNA microparticle morphology was studied. In the presence of Mn²⁺, microparticle morphology changed dramatically; in PCR mixtures containing KlenTaq polymerase supplemented with Mn²⁺, DNA microspheres with fringed surfaces were formed; in the presence of Taq polymerase, microparticles in the form of short, rounded rods were produced. In light of these data, the molecular mechanism of micro- and nanoparticle formation in the course of PCR is discussed.     

Micro- and nanoparticles of condensed DNA formed in a PCR with yeast genomic DNA as a template. Electron microscopy data

It has been previously found that in a PCR with yeast genomic DNA as a template, microparticles of condensed DNA are formed in the presence of KlenTaq polymerase. In the present work, the study of these microparticles was continued using electron microscopy. It was shown that along with standard electrondense microspheres, microspheres of a low electron density with numerous thorns or without any thorns are formed. Various types of nanoparticles were detected in the samples: nanowires, dot-like electron-absorbing particles (nanodots), and compact nanoparticles (nanoscales) of different shape and size. It was found that increasing the number of PCR cycles above the optimum leads to an abrupt rise in the amount of nanoparticles in the PCR mixture. Suspensions of microparticles after quick (5 min) heating at 94°C were examined. The partial melting of the microspheres in the heated samples was established: they lost part of the DNA and decreased in size; simultaneously, abundant clusters of nanowires appeared. The effect of nuclease S1 on the DNA of microspheres was studied. The molecular mechanisms of the formation of micro- and nanoparticles are discussed.     

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.     

Structural variability of DNA-containing Mg-pyrophosphate microparticles: optimized conditions to produce particles with desired size and morphology

Our previous studies demonstrated the formation of structurally diverse DNA-containing microparticles (DNA MPs) in PCR with Mg-pyrophosphate (MgPPi) as the structure-forming component. These DNA MPs were referred to major structural types: microdisks (2D MPs) with nanometer thickness and 3D MPs with sophisticated morphology and constructed from intersecting disks and their segments. Little is known about factors that influence both the morphology and size of DNA MPs, and the present study was aimed at fulfilling this gap. We showed that the addition of Mn²⁺ cations to PCR mixtures caused the profound changes in MPs morphology, depending on DNA polymerase used (KlenTaq or Taq). Asymmetric PCR with 20-fold decrease in the concentration of one of two primers facilitated the predominant formation of microdisks with unusual structure. The addition of 1 mM Na-pyrophosphate to PCR mixtures with synthesized DNA and subsequent thermal cycling (10–15 cycles) were optimal to produce microdisks or nanometer 3D particles. Using electron microscopy, we studied also the structure of inorganic micro- and nanoparticles from MgPPi, formed during multiple heating and cooling cycles of a mixture of Mg²⁺ and Na-pyrophosphate in various regimes. Also, we found the conditions to yield planar (Mg·Mn)PPi nanocrystals (diameter ~100 nm and thickness ~10 nm) which efficiently adsorbed exogenous DNA. These inorganic nanoparticles are promising for DNA delivery in transfection studies. Mechanisms to be involved in structural modifications of MPs and perspectives of their practical application are discussed.     

Optimization of PCR in application of hot start <Emphasis Type="Italic">Taq</Emphasis> DNA polymerase for detection of <Emphasis Type="Italic">Erwinia amylovora</Emphasis> with primers FER1-F and FER1-R1

There are two approaches in detection of bacterium Erwinia amylovora by PCR. One is based on detection of plasmid pEA29 and the other is based on detection of a chromosomal DNA sequence, specific for E. amylovora, in a sample. Since pathogenic strains without pEA29 have been isolated from the environment, methods based on this plasmid have been compromised and PCR methods based on chromosomal DNA species specific sequences became only reliable methods. PCR method with chromosomal primers FER1-F and FER1-R is currently the most reliable method due to its high sensitivity and specificity. The goal of this research is to make a significant improvement of the method by optimization of PCR in application of hot start DNA Taq polymerase, instead of wax, to obtain a hot start reaction. This enzyme, which is currently widely applied, can provide simpler achievement of hot start, saving labor and time and decreasing possibility of cross contamination of samples. Experiments showed that simple replacement of a regular recombinant Taq DNA polymerase by a hot start Taq DNA polymerase leads to complete failure of the reaction. Many optimization experiments had to be carried out to obtain an operational and reliable PCR which simultaneously has high sensitivity and specificity. Content of the reaction mixture, as well as temperature and time parameters of PCR, were significantly changed to achieve proper optimization.     

New insight into formation of DNA-containing microparticles during PCR: the scaffolding role of magnesium pyrophosphate crystals

This work aims to study molecular mechanisms involved in the formation of DNA-containing microparticles and nanoparticles during PCR. Both pyrophosphate and Mg²⁺ ions proved to play an important role in the generation of DNA microparticles (MPs) with a unique and sophisticated structure in PCR with Taq polymerase. Thus, the addition of Tli thermostable pyrophosphatase to a PCR mixture inhibited this process and caused the destruction of synthesized DNA MPs. Thermal cycling of Na-pyrophosphate (Na-PPi)- and Mg²⁺-containing mixtures (without DNA polymerase and dNTPs) under the standard PCR regime yielded crystalline oval or lenticular microdisks and 3D MPs composed from magnesium pyrophosphate (Mg-PPi). As shown by scanning electron microscopy (SEM), the produced Mg-PPi microparticles consisted of intersecting disks or their segments. They were morphologically similar but simpler than DNA-containing MPs generated in PCR. The incorporation of dNTPs, primers, or dsDNA into Mg-pyrophosphate particles resulted in the structural diversification of 3D microparticles. Thus, the unusual and complex structure of DNA MPs generated in PCR is governed by the unique feature of Mg-pyrophosphate to form supramolecular particles during thermal cycling. We hypothesize the Mg-pyrophosphate particles that are produced during thermal cycling serve as scaffolds for amplicon DNA condensation.     

Changes of 5＇ Terminal Nucleotides of PCR Primers Causing Variable T-A Cloning Efficiency

T-A cloning takes advantage of the unpaired adenosyl residue added to the 3＇ terminus of amplified DNAs by Taq and other thermostable DNA polymerase and uses a Ilnearlzed plasmld vector with a protruding 3＇ thymldylate residue at each of Its 3＇ termini to clone polymerase chain reaction （PCR）-derived DNA fragments. It Is a simple, reliable, and efficient Ilgatlon-dependent cloning method for PCR products, but the drawback of variable cloning efficiency occurs during application. In the present work, the relationship between variable T-A cloning efficiency and the different 5＇ end nucleotlde base of primers used In PCR amplification was studied. The results showed that different cloning efficiency was obtained with different primer pairs containing A, T, C and G at the 5＇ terminus respectively. The data shows that when the 5＇ end base of primer pair was adenosyl, more white colonies could be obtained In cloning the corresponding PCR product In comparison with other bases. And the least white colonies were formed when using the primer pair with 5＇ cytldylate end. The gluanylate end primers resulted In almost the same cloning efficiency In the white colonies amount as the thymldylate end primer did, and this efficiency was much lower than that of adenosyl end primers. This presumably is a consequence of variability In 3＇dA addition to PCR products mediated by Taq polymerase. Our results offer instructions for primer design for researchers who choose T-A cloning to clone PCR products.     

Cloning,expression, and PCR application of DNA polymerase from the hyperthermophilic archaeon, <Emphasis Type="Italic">Thermococcus celer</Emphasis>

The family B DNA polymerase gene was amplified from Thermococcus celer genomic DNA by using the degenerate primers and DNA walking PCR. The Tce DNA polymerase gene was cloned and sequenced. The gene contains an ORF of 2,325 bp encoding 774 amino acid residues with a calculated molecular weight of 89,788.9 kDa. The Tce DNA polymerase was purified by heat treatment and heparin column chromatography. The optimal conditions for PCR were determined. Long-range PCR and time-saving PCR were performed using various specific ratios of Taq and Tce DNA polymerases (Tce plus DNA polymerase). Tce plus DNA polymerase surpassed the PCR performance of Tce, Taq and Pfu DNA polymerases in terms of yield and efficiency.     

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.     

Characterization and application of aptamers for Taq DNA polymerase selected using an evolution-mimicking algorithm

Using an evolution-mimicking algorithm (EMA), we have recently identified DNA aptamers that inhibit Taq DNA polymerase. In the present study, we have attempted to improve further the inhibitory activities of aptamers, as well as to characterize those aptamers with the most potent inhibitory activities. To characterize the most potent aptamer and demonstrate its applicability, the abilities to inhibit Tth DNA polymerase and to modulate specific amplification in PCR were investigated. This aptamer inhibited both Tth DNA polymerase and Taq DNA polymerase and improved the specificity of detection of a low-copy-number target gene in PCR using these DNA polymerases.     

Optimal conditions to use Pfu exo– DNA polymerase for highly efficient ligation-mediated polymerase chain reaction protocols

Ligation-Mediated Polymerase Chain Reaction (LMPCR) is the most sensitive sequencing technique available to map single-stranded DNA breaks at the nucleotide level of resolution using genomic DNA. LMPCR has been adapted to map DNA damage and reveal DNA–protein interactions inside living cells. However, the sequence context (GC content), the global break frequency and the current combination of DNA polymerases used in LMPCR affect the quality of the results. In this study, we developed and optimized an LMPCR protocol adapted for Pyrococcus furiosus exo^– DNA polymerase (Pfu exo^–). The relative efficiency of Pfu exo^– was compared to T7-modified DNA polymerase (Sequenase 2.0) at the primer extension step and to Thermus aquaticus DNA polymerase (Taq) at the PCR amplification step of LMPCR. At all break frequencies tested, Pfu exo^– proved to be more efficient than Sequenase 2.0. During both primer extension and PCR amplification steps, the ratio of DNA molecules per unit of DNA polymerase was the main determinant of the efficiency of Pfu exo^–, while the efficiency of Taq was less affected by this ratio. Substitution of NaCl for KCl in the PCR reaction buffer of Taq strikingly improved the efficiency of the DNA polymerase. Pfu exo^– was clearly more efficient than Taq to specifically amplify extremely GC-rich genomic DNA sequences. Our results show that a combination of Pfu exo^– at the primer extension step and Taq at the PCR amplification step is ideal for in vivo DNA analysis and DNA damage mapping using LMPCR.     

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.     

Molecular diversity and catalytic activity of Thermus DNA polymerases

Thermus aquaticus DNA polymerase (Taq polymerase) made the polymerase chain reaction feasible and led to a paradigm shift in genomic analysis. Other Thermus polymerases were reported to have comparable performance in PCR and there was an analysis of their properties in the 1990s. We re-evaluated our earlier phylogeny of Thermus species on the basis of 16S rDNA sequences and concluded that the genus could be divided into eight clades. We examined 22 representative isolates and isolated their DNA polymerase I genes. The eight most diverse polymerase genes were selected to represent the eight clades and cloned into an expression vector coding for a His-tag. Six of the eight polymerases were expressed so that there was sufficient protein for purification. The proteins were purified to homogeneity and examination of the biochemical characteristics showed that although they were competent to perform PCR, none was as thermostable as commercially available Taq polymerase; all had similar error-frequencies to Taq polymerase and all showed the expected 5′–3′ exonuclease activity. We conclude that the initial selection of T. aquaticus for DNA polymerase purification was a far-reaching and fortuitous choice but simple mutagenesis procedures on other Thermus-derived polymerases should provide comparable thermostability for the PCR reaction.     

The structural peculiarities of condensed DNA micro- and nanoparticles formed in PCR

Studies of DNA condensation have opened new perspectives in biotechnology and medicine. DNA condensation induced by polyamines or trivalent metal ions in vitro at room temperature has been investigated in detail. Our recent studies have demonstrated Mg²⁺-mediated formation of DNA condensates during the PCR. In this study, we report the unique morphology and fine structure of PCR-generated condensed DNA particles using electron and atomic force microscopy. The principal morphologies of studied DNA condensates are 3D particles of micrometer dimensions, oval microdisks of nanometer thickness, filaments, and compact nano-sized particles. SEM examinations have revealed a new structural type of spherical and elliptical 3D microparticles formed by numerous definitely oriented microdisks and their segments. AFM revealed a granular structure of the microdisk surface and the smallest nano-sized disks and thinnest nanofibrils – that appear to be the primary products of DNA condensation during the PCR. We suggest that the formation of DNA nanofibrils and nanodisks in PCR occurs due to Mg²⁺ – mediated intermolecular (lateral) and intramolecular condensation of ssDNA. Aggregation of elementary nanodisks in the course of thermal PCR cycles, occurring both by magnesium cations and via complementary interactions, give a rise to large nano-sized aggregates and more complex microparticles.     

Insertion of the T3 DNA polymerase thioredoxin binding domain enhances the processivity and fidelity of Taq DNA polymerase

Insertion of the T3 DNA polymerase thioredoxin binding domain (TBD) into the distantly related thermostable Taq DNA polymerase at an analogous position in the thumb domain, converts the Taq DNA polymerase from a low processive to a highly processive enzyme. Processivity is dependent on the presence of thioredoxin. The enhancement in processivity is 20–50-fold when compared with the wild-type Taq DNA polymerase or to the recombinant polymerase in the absence of thioredoxin. The recombinant Taq DNA pol/TBD is thermostable, PCR competent and able to copy repetitive deoxynucleotide sequences six to seven times more faithfully than Taq DNA polymerase and makes 2–3-fold fewer AT→GC transition mutations.     

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.     

Constructing DNA by polymerase recombination.

Polymerase-mediated recombination based on DNA polymerase chain reactions (PCRs) has been used to carry out directed joining at a present point of two DNA fragments initially contained in a plasmid and a single-stranded synthetic DNA. The process includes copying of these fragments by PCR with generation of an overlapping homologous region. Such overlap of 12 base pairs in length was found to be sufficient to provide further DNA joining also by use of PCR.     

A Simple and Efficient Method for High Fidelity PCR Cloning Using Antibody-neutralizing Technology

We introduce the TA cloning antibody method for the high-fidelity PCR product amplified by family B DNA polymerase without purification. This method uses antibodies and Thermus aquaticus (Taq) DNA polymerase. The antibodies can inhibit only the activity of family B DNA polymerase, and Taq can co-work for A-tailing. This method has nearly cloning efficiency to that of the PCR product of Taq.     

Influence of DNA aptamer structure on the specificity of binding to Taq DNA polymerase

The secondary structure of DNA aptamer to Taq DNA polymerase was established as a hairpin. Both stem and loop structures of DNA ligand were shown to be involved in the interaction with Taq DNA polymerase. Moreover, the structure and sequence of DNA aptamer that was the most effective inhibitor of DNA polymerase activity were established. This crucial structure was evaluated as a GC-rich stem longer than 17 bp, and a loop consisting of 12 bases with strictly determined nucleotide sequence. It was demonstrated that nucleotide in position 23 counting from the 5"-end of DNA ligand was involved in direct contact with Taq DNA polymerase. The ability of optimized DNA aptamer TQ21-11 to form a complex with the enzyme was increased 5-fold in comparison to the initial aptamer.     

Ligation of highly modified bacteriophage DNA

After digestion by TaqI or nicking by DNAase I, five highly modified bacteriophage DNAs were tested as substrates for T4 DNA ligase. The DNAs used were from phages T4, XP12, PBS1, SP82, and SP15, which contain as a major base either glucosylated 5-hydroxymethylcytosine, 5-methylcytosine, uracil, 5-hydroxymethyluracil, or phosphoglucuronated, glucosylated 5-(4′,5′-dihydroxypentyl)uracil, respectively. The relative ability of cohesive-ended TaqI fragments of these DNAs and of normal, λ DNA to be ligated was as follows: $\text{λ}\text{DNA}\text{=}\text{XP}\text{12}\text{DNA}\text{>}\text{SP}\text{82}\text{DNA}\text{?}\text{nonglucosylated}\text{T}\text{4}\text{DNA}\text{>}\text{T}\text{4}\text{DNA}\text{=}\text{PBS}\text{1}\text{DNA}\text{?}\text{SP}\text{15}\text{DNA}$. TaqI-T4 DNA fragments were also inefficiently ligated by Escherichia coli DNA ligase. However, annealing-independent ligation of DNAase I-nicked T4, PBS1, and λ DNAs was equally efficient. We conclude that the poor ligation of TaqI fragments of T4 and PBS1 DNAs was due to the hydroxymethylation (and glucosylation) of cytosine residues at T4's cohesive ends and the substitution of uracil residues for thymine residues adjacent to PBS1's cohesive ends destabilizing the annealing of the restriction fragments. Only SP15 DNA with its negatively charged, modified base was unable to serve as a substrate for T4 DNA ligase in an annealing-independent reaction; therefore, its modification directly interfered with enzyme binding or catalysis.