Maxim D. Frank-Kamenetskii

Conformational and Thermodynamic Properties of Supercoiled DNA

We used Monte Carlo simulations to investigate the conformational and thermodynamic properties of DNA molecules with physiological levels of supercoiling. Three parameters determine the properties of DNA in this model: Kuhn statistical length, torsional rigidity and effective double-helix diameter. The chains in the simulation resemble strongly those observed by electron microscopy and have the conformation of an interwound superhelix whose axis is often branched. We compared the geometry of simulated chains with that determined experimentally by electron microscopy and by topological methods. We found a very close agreement between the Monte Carlo and experimental values for writhe, superhelix axis length and the number of superhelical turns. The computed number of superhelix branches was found to be dependent on superhelix density, DNA chain length and double-helix diameter. We investigated the thermodynamics of supercoiling and found that at low superhelix density the entropic contribution to superhelix free energy is negligible, whereas at high superhelix density, the entropic and enthalpic contributions are nearly equal. We calculated the effect of supercoiling on the spatial distribution of DNA segments. The probability that a pair of DNA sites separated along the chain contour by at least 50 nm are juxtaposed is about two orders of magnitude greater in supercoiled DNA than in relaxed DNA. This increase in the effective local concentration of DNA is not strongly dependent on the contour separation between the sites. We discuss the implications of this enhancement of site juxtaposition by supercoiling in the context of protein-DNA interactions involving multiple DNA-binding sites.

The B̄ to Ā transition of DNA in solution

Abstract The B to Ā transition of DNA in water-ethanol solutions has been studied by circular dichroism. The transition is reversible and co-operative and occurs within a narrow concentration range of alcohol (70 to 80% ethanol). The value of water activity within this interval corresponds to the value of the relative humidity for the B to Ā transition in DNA fibres. An increase in Na+ concentration results in a shift of the transition curve to lower ethanol concentrations. By contrast, Li+, Cs+, guanidine+, Mg2+, and Ca2+ ions stabilize the 5 form. The B α A equilibrium is not influenced by temperature. The B to Ā transition may have only a slight dependence (if any) on G + C content, since the transition width is the same for the heterogeneous calf thymus DNA and the homogeneous bacterial and phage DNA. Hence, in the B to Ā transition DNA behaves as a “single-stranded” (the strands are not separated) homopolymer. This allows one to apply the simplest variant of the Ising model to the description of the B to Ā transition. On the basis of data obtained in the presence of the antibiotic netropsin, which stabilizes the B form, we estimated the co-operativity length, ν0 = 20 base pairs, and the free energy difference of the Ā and B states in water, FA − FB ~ 1 kcal/mol.

Structures of Homopurine-homopyrimidine Tract in Superhelical DNA

For homopurine-homopyrimidine tracts in superhelical DNA, we propose a structure involving Watson-Crick and Hoogsteen paired triple helixes, hairpin loops and unstructured domains. Topologically, the whole structure is equivalent to an open region. The proposed structure is consistent with available S1 cleavage, pH and alkylation data and energetics under superhelical stress; this new structure is a much more probable candidate than the one proposed by us recently (V.I. Lyamichev, S.M. Mirkin & M.D. Frank-Kamenetskii, J. Biomole. Str. Dyns 3, 327-338, 1985).

Computer Simulation of DNA Supercoiling

We treat supercoiled DNA within a wormlike model with excluded volume. A modified Monte Carlo approach has been used, which allowed computer statistical-mechanical simulations of moderately and highly supercoiled DNA molecules. Even highly supercoiled molecules do not have a regular shape, though with an increase in writhing the chains look more and more like branched interwound helixes. The averaged writhing (Wr) approximately 0.7 delta Lk. The superhelical free energy F is calculated as a function of the linking number. Lk. The calculations have shown that the generally accepted quadratic dependence of F on Lk is valid for a variety of conditions, though it is by no means universal. Significant deviations from the quadratic dependence are expected at high superhelical density under ionic conditions where the effective diameter of DNA is small. The results are compared with the available experimental data.

Kinetics and mechanism of the DNA double helix invasion by pseudocomplementary peptide nucleic acids

If adenines and thymines in two mutually complementary mixed-base peptide nucleic acid (PNA) oligomers are substituted with diaminopurines and thiouracils, respectively, so-called pseudocomplementary PNAs (pcPNAs) are created. Pairs of pcPNAs have recently demonstrated an ability to highly selectively target essentially any designated site on double-stranded DNA (dsDNA) by forming very stable PNA–DNA strand-displacement complexes via double duplex invasion (helix invasion). These properties of pcPNAs make them unique and very promising ligands capable of denying the access of DNA-binding proteins to dsDNA. To elucidate the sequence-unrestricted mechanism of sequence-specific dsDNA recognition by pcPNAs, we have studied the kinetics of formation of corresponding PNA–DNA complexes at various temperatures by the gel-shift assay. In parallel, the conditions for possible self-hybridization of pcPNA oligomers have been assayed by mixing curve (Job plot) and thermal melting experiments. The data indicate that, at physiological temperatures (≈37°C), the equilibrium is shifted toward the pairing of corresponding pcPNAs with each other. This finding explains a linear concentration dependence, within the submicromolar range, of the pcPNA invasion rate into dsDNA at 37°C. At elevated temperatures (>50°C), the rather unstable pcPNA duplexes dissociate, yielding the expected quadratic dependence for the rate of pcPNA invasion on the PNA concentration. The polycationic character of pcPNA pairs, carrying the duplicated number of protonated terminal PNA residues commonly used to increase the PNA solubility and binding affinity, also explains the self-inhibition of pcPNA invasion observed at higher PNA concentrations. Melting of pcPNA duplexes occurs with the integral transition enthalpies ranged from −235 to −280 kJ⋅mol−1, contributing to an anomalously high activation energy of ≈150 kJ⋅mol−1 found for the helix invasion of pcPNAs carrying four different nucleobases. A simplified kinetic model for pcPNAs helix invasion is proposed that interprets all unusual features of pcPNAs binding to dsDNA. Our findings have important implications for rational use of pcPNAs.

A pH-dependent structural transition in the homopurine-homopyrimidine tract in superhelical DNA.

Abstract We have inserted the 509-bp-long fragment of sea urchin P. miliaris histone gene spacer region into plasmid pUC19. The fragment contains the 60-bp-long homopurine-homopyrimidine tract that is known to be hypersensitive to the S1 endonuclease. Using two-dimensional gel electrophoresis we have observed a sharp structural transition in the insert with increasing DNA superhelicity. As in the cases of cruciform and Z form formation, the observed transition partly relaxes the superhelical stress. In contrast with the other two well documented transitions, the observed transition strongly depends on pH. At pH7 and above the transition occurs at negative superhelicities exceeding the physiological range (σ>0.08). For pH6 the transition occurs at −σ = 0.055, whereas for pH4.3 it takes place at −σ = 0.001. A comprehensive analysis of the obtained data has made it possible to define the nature of the observed transition. We conclude that under superhelical stress or/and at low pH homopurine- homopyrimidine ...

PNA beacons for duplex DNA.

We report here on the hybridization of peptide nucleic acid (PNA)-based molecular beacons (MB) directly to duplex DNA sites locally exposed by PNA openers. Two stemless PNA beacons were tested, both featuring the same recognition sequence and fluorophore-quencher pair (Fluorescein and DABCYL, respectively) but differing in arrangement of these groups and net electrostatic charge. It was found that one PNA beacon rapidly hybridized, with the aid of openers, to its complementary target within duplex DNA at ambient conditions via formation of a PD-like loop. In contrast, the other PNA beacon bound more slowly to preopened duplex DNA target and only at elevated temperatures, although it readily hybridized to single-stranded (ss) DNA target. Besides a higher selectivity of hybridization provided by site-specific PNA openers, we expect this approach to be very useful in those MB applications when denaturation of the duplex DNA analytes is unfavorable or undesirable. Furthermore, we show that PNA beacons are advantageous over DNA beacons for analyzing unpurified/nondeproteinized DNA samples. This feature of PNA beacons and our innovative hybridization strategy may find applications in emerging fluorescent DNA diagnostics.

Tuning DNA “strings”: Modulating the rate of DNA replication with mechanical tension

Recent experiments have measured the rate of replication of DNA catalyzed by a single enzyme moving along a stretched template strand. The dependence on tension was interpreted as evidence that T7 and related DNA polymerases convert two (n = 2) or more single-stranded template bases to double helix geometry in the polymerization site during each catalytic cycle. However, we find structural data on the T7 enzyme–template complex indicate n = 1. We also present a model for the “tuning” of replication rate by mechanical tension. This model considers only local interactions in the neighborhood of the enzyme, unlike previous models that use stretching curves for the entire polymer chain. Our results, with n = 1, reconcile force-dependent replication rate studies with structural data on DNA polymerase complexes.

Detection of Low-Copy-Number Genomic DNA Sequences in Individual Bacterial Cells by Using Peptide Nucleic Acid-Assisted Rolling-Circle Amplification and Fluorescence In Situ Hybridization†

ABSTRACT An approach is proposed for in situ detection of short signature DNA sequences present in single copies per bacterial genome. The site is locally opened by peptide nucleic acids, and a circular oligonucleotide is assembled. The amplicon generated by rolling circle amplification is detected by hybridization with fluorescently labeled decorator probes.

End invasion of peptide nucleic acids (PNAs) with mixed-base composition into linear DNA duplexes

Peptide nucleic acid (PNA) is a synthetic DNA mimic with valuable properties and a rapidly growing scope of applications. With the exception of recently introduced pseudocomplementary PNAs, binding of common PNA oligomers to target sites located inside linear double-stranded DNAs (dsDNAs) is essentially restricted to homopurine–homopyrimidine sequence motifs, which significantly hampers some of the PNA applications. Here, we suggest an approach to bypass this limitation of common PNAs. We demonstrate that PNA with mixed composition of ordinary nucleobases is capable of sequence-specific targeting of complementary dsDNA sites if they are located at the very termini of DNA duplex. We then show that such targeting makes it possible to perform capturing of designated dsDNA fragments via the DNA-bound biotinylated PNA as well as to signal the presence of a specific dsDNA sequence, in the case a PNA beacon is employed. We also examine the PNA–DNA conjugate and prove that it can initiate the primer-extension reaction starting from the duplex DNA termini when a DNA polymerase with the strand-displacement ability is used. We thus conclude that recognition of duplex DNA by mixed-base PNAs via the end invasion has a promising potential for site-specific and sequence-unrestricted DNA manipulation and detection.