Effect of temperature and ionic strength on the dissociation kinetics and lifetime of PNA-DNA triplexes.

Dissociation kinetics of triplexes formed by molecules of peptide nucleic acid (PNA) and DNA have been studied. The complexes consisted of oligomeric PNA containing 10 thymine bases and the dA(10) target incorporated in single-stranded (ssDNA) or double-stranded DNA (dsDNA). Their dissociation was followed by means of the gel mobility shift assay at various temperatures and sodium ion concentrations. In all experiments, the dissociation kinetics of triplexes were exponential; the effective lifetime of a triplex, tau, depended on temperature in accordance with the Arrhenius law. The tau values for T(10) PNA complexes with ss- and dsDNA were equal within the accuracy of experiments. The activation energy, U, value for T(10) PNA-DNA complexes did not change when the NaCl concentration was increased from 50 to 200 or 600 mM. Conversely, the tau values decreased with the increase in NaCl concentration. The equal lifetimes of the T(10) PNA-DNA triplexes containing ss- and dsDNA suggest that the loop formed in dsDNA does not noticeably affect the triplex structure. The decrease in the triplex lifetime tau with an increase in ionic strength was accounted for by the fact that the PNA backbone is neutral. The lack of relationship between the activation energy of dissociation and salt concentration suggests that the dissociation enthalpy does not depend on the ionic strength. Thus, the effect of ionic strength on the lifetime is entropic by its nature. Contrary to this, for complexes of ssDNA with bis-PNA 1743, which also consists of 10 thymine bases but contains 2 additional positive charges inside the sequence in 1 of the PNA arms, an increase of the dissociation enthalpy at low salt concentration was observed. We suggest that this effect is a result of a direct electrostatic interaction of the positive charges of the PNA with the DNA backbone. Finally, our results allow an estimate of the lifetime of a 10-mer triplex invasion complex in dsDNA at 37 degrees C in excess of several hundred days.

Mechanisms of triplex-caused polymerization arrest.

Pyrimidine/purine/purine triplexes are known to inhibit DNA polymerization. Here we have studied the mechanisms of this inhibition by comparing the efficiency of Vent DNA polymerase on triplex- and duplex-containing templates at different temperatures, Mg2+concentrations and time intervals with the thermal stability of the corresponding structures. Our results show that triplexes can only be by-passed at temperatures where thermal denaturation initiates, while duplexes, in contrast, are overcome at temperatures where they are quite stable. These results show that DNA polymerase cannot untangle triplex regions within DNA templates and seems to entirely depend on their thermal fluctuations. The high stability of triplexes at physiological temperatures and ambient conditions make them a barrier to polymerization.

Specific fragmentation of T7 phage DNA at low-melting sites.

A method has been developed for selective fragmentation of T7 DNA at AT-rich regions. The molecules have been subjected to complete digestion with single-strand-specific SI endonuclease after fixation of DNA AT-rich regions in the denatured state by glyoxal. The treatment resulted in three fragments having molecular weights of 13.6 +/- 0.4, 8.2 +/- 0.4 and 3.5 +/- 0.16 megadaltons as determined by electron microscopy. The position of these fragments along the T7 DNA molecule has been determined by means of analysis of the intermediates during SI-cleavage.

Investigation of the binding of Escherichia coli RNA polymerase to DNA from bacteriophages T2 and T7 by kinetic formaldehyde method and electron microscopy.

The complexes of T2 DNA with RNA polymerase of Escherichia coli were studied by two methods: kinetic formaldehyde method with preliminary fixation of complexes with low formaldehyde concentrations, and electron microscopy. For electron-microscopic investigations the effect of different conditions of formaldehyde fixation for DNA-RNA-polymerase complexes was studied and optimal fixation conditions were found. The suggested fixation method for DNA-RNA-polymerase complexes allows investigation of RNA polymerase molecule distribution on DNA in a wide range of conditions (ionic strength of the solution, weight ration of enzyme to DNA etc.). The comparison of the concentration of RNA polymerase molecules bound to DNA, determined by electron microscopy, and the concentration of defects in DNA as determined by the kinetic formaldehyde method, showed their coincidence. The electron-microscopic procedure was used to make maps of RNA polymerase distribution on T7 DNA. A correlation between the binding regions of the enzyme and the genetic map of early DNA T7 region was found.

The study of DNA-RNA-polymerase complexes by kinetic formaldehyde method.

A modification of the kinetic formaldehyde method has been proposed providing a possibility for locally denatured regions (defects) formed in DNA preincubated with RNA polymerase (in the absence of nucleoside triphosphates) to be detected. This modification consists in a previous fixation of DNA-enzyme complex with small concentrations of formaldehyde, which do not induce formation of defects in DNA alone. The method has been calibrated under the conditions favourable to RNA synthesis. Studies of the effect of the fixation conditions on the number of defects in DNA interacting with RNA polymerase have shown that the number of defects is constant with formaldehyde fixation concentration between 0.05% and 0.3-0.5% and with fixation time between 2 min and 100 min. The dependence of the number of defects in DNA on RNA polymerase concentration at low ionic strength (0.05 M KCl) is presented by a curve with a plateau. From the initial linear part of the curve it has been found that the enzyme bound to DNA as a monomer. At the excess of the enzyme the mean number of nucleotide pairs between defects is 400-500. Increase of ionic strength results in decrease of the number of defects in DNA. The number of defects depends on temperature of preincubation of the complex. There were no defects in DNA at temperatures below 20 degrees C. At temperatures above 30 degrees C the number of defects reaches saturation. A sharp transition occurs in the range of temperatures between 20 degrees C and 30 degrees C. Analysis of the experimental and literature data, concerning the interaction of formaldehyde and amino acid methylol derivatives with DNA bases, leads to the conclusion that the mechanism of the formation of defects in helical DNA most likely consists in its unwinding or sharp weakening upon binding of RNA polymerase, prior to addition of formaldehyde.