K. B. Ignatov

Bio: K. B. Ignatov is an academic researcher from Russian Academy of Sciences. The author has contributed to research in topics: Hot start PCR & DNA polymerase. The author has an hindex of 3, co-authored 5 publications receiving 34 citations.

A New Approach to Enhanced PCR Specificity

Abstract: A new approach to enhanced specificity and product yield of polymerase chain reaction is proposed. It is based on control of DNA polymerase activity during PCR by changing the magnesium ion concentration, which depends on the temperature of the reaction mixture. A slightly soluble magnesium salt, magnesium oxalate, whose solubility depends on temperature, was used as a source of magnesium ions. During PCR, magnesium oxalate was maintained at saturating concentration by the presence of an insoluble excess of this salt, and the concentration of magnesium ions depended on the salt solubility: binding of magnesium ions at lower temperatures and their release at higher temperatures was shown to affect the DNA polymerase activity and to favor the specific PCR amplification of the target DNA fragment.

[DNA polymerase mediated amplification of DNA fragments using primers with mismatches in the 3'-region].

Abstract: The ability of three thermostable enzymes, Tth, Taq, and Klentaq DNA polymerases, to amplify DNA with primers containing mismatches in the 3'-terminal region was studied. It is shown that Tth polymerase, in contrast to the Taq and Klentaq enzymes, synthesizes equally well DNA with primers perfectly complementary to the template and with those containing mismatches next the 3'-end. The use of Tth DNA polymerase in the polymerase chain reaction was shown to result, in some cases, in a great number of additional, nonspecific DNA fragments as compared with Taq DNA polymerase. This may be due to the ability of Tth polymerase for DNA primer extension even if the 3'-terminal region of the primer contains nucleotides non-complementary to the template. Tth DNA polymerase and a Klentaq/Tth mixture (100:1) can be efficiently used in the amplification of DNA with degenerated primers and primers forming nonperfect duplexes with the template.

A new approach to enhance PCR specificity

Abstract: A new approach to enhanced specificity and product yield of polymerase chain reaction is proposed. It is based on control of DNA polymerase activity during PCR by changing the magnesium ion concentration, which depends on the temperature of the reaction mixture. A slightly soluble magnesium salt, magnesium oxalate, whose solubility depends on temperature, was used as a source of magnesium ions. During PCR, magnesium oxalate was maintained at saturating concentration by the presence of an insoluble excess of this salt, and the concentration of magnesium ions depended on the salt solubility: binding of magnesium ions at lower temperatures and their release at higher temperatures was shown to affect the DNA polymerase activity and to favor the specific PCR amplification of the target DNA fragment.

Predicting Stability of DNA Duplexes in Solutions Containing Magnesium and Monovalent Cations

Abstract: Accurate predictions of DNA stability in physiological and enzyme buffers are important for the design of many biological and biochemical assays. We therefore investigated the effects of magnesium, potassium, sodium, Tris ions, and deoxynucleoside triphosphates on melting profiles of duplex DNA oligomers and collected large melting data sets. An empirical correction function was developed that predicts melting temperatures, transition enthalpies, entropies, and free energies in buffers containing magnesium and monovalent cations. The new correction function significantly improves the accuracy of predictions and accounts for ion concentration, G-C base pair content, and length of the oligonucleotides. The competitive effects of potassium and magnesium ions were characterized. If the concentration ratio of [Mg2+]0.5/[Mon+] is less than 0.22 M−1/2, monovalent ions (K+, Na+) are dominant. Effects of magnesium ions dominate and determine duplex stability at higher ratios. Typical reaction conditions for PCR an...

Biotechnologically relevant enzymes from Thermus thermophilus.

Abstract: Enzymes produced by Thermus thermophilus are of considerable biotechnological interest. This review covers industrial applications of several protein products of this thermophilic bacterium that are functional under extreme conditions. The purification of proteins from T. thermophilus using either conventional methods or in the light of the cloning of their genes and expression in mesophilic microorganisms is discussed. Enzymes that biodegrade proteins, polysaccharides or key enzymes that are involved in amino acid metabolism, protein folding or in other fundamental biological processes such as DNA replication, DNA repair, and RNA maturation, with potential use in different biotechnological processes are reviewed as well.

Compatible solute influence on nucleic acids: Many questions but few answers

Abstract: Compatible solutes are small organic osmolytes including but not limited to sugars, polyols, amino acids, and their derivatives. They are compatible with cell metabolism even at molar concentrations. A variety of organisms synthesize or take up compatible solutes for adaptation to extreme environments. In addition to their protective action on whole cells, compatible solutes display significant effects on biomolecules in vitro. These include stabilization of native protein and nucleic acid structures. They are used as additives in polymerase chain reactions to increase product yield and specificity, but also in other nucleic acid and protein applications. Interactions of compatible solutes with nucleic acids and protein-nucleic acid complexes are much less understood than the corresponding interactions of compatible solutes with proteins. Although we may begin to understand solute/nucleic acid interactions there are only few answers to the many questions we have. I summarize here the current state of knowledge and discuss possible molecular mechanisms and thermodynamics.

Cloning, expression, and characterization of DNA polymerase I from the hyperthermophilic archaea Thermococcus fumicolans.

Abstract: The DNA polymerase I gene of a newly described deep-sea hydrothermal vent Archaea species, Thermococcus fumicolans, from IFREMERS's collection of hyperthermophiles has been cloned in Escherichia coli. As in Thermococcus litoralis, the gene is split by two intervening sequences (IVS) encoding inteins inserted in sites A and C of family B DNA polymerases. The entire DNA polymerase gene, containing both inteins, was expressed at 30 degrees C in E. coli strain BL21(DE3)pLysS using the pARHS2 expression vector. The native polypeptide precursor of 170kDa was obtained, and intein splicing as well as ligation of the three exteins was observed in vitro after heat exposure. The recombinant enzyme was purified and some of its activities were characterized: polymerization, thermostability, exonuclease activities, and fidelity.