Volume changes accompanying the complex formation of polyadenylic and polyuridylic acids

Energetics, Ion, and Water Binding of the Unfolding of AA/UU Base Pair Stacks and UAU/UAU Base Triplet Stacks in RNA

Triplex formation occurs via interaction of a third strand with the major groove of double-stranded nucleic acid, through Hoogsteen hydrogen bonding. In this work, we use a combination of temperature-dependent UV spectroscopy and differential scanning calorimetry to determine complete thermodynamic profiles for the unfolding of polyadenylic acid (poly(rA))·polyuridylic acid (poly(rU)) (duplex) and poly(rA)·2poly(rU) (triplex). Our thermodynamic results are in good agreement with the much earlier work of Krakauer and Sturtevant using only UV melting techniques. The folding of these two helices yielded an uptake of ions, Δ n_Na⁺ = 0.15 mol Na⁺/mol base pair (duplex) and 0.30 mol Na⁺/mole base triplet (triplex), which are consistent with their polymer behavior and the higher charge density parameter of triple helices. The osmotic stress technique yielded a release of structural water, Δ n_W = 2 mol H₂O/mol base pair (duplex unfolding into single strands) and an uptake of structural water, Δ n_W = 2 mol H₂O/mole base pair (triplex unfolding into duplex and a single strand). However, an overall release of electrostricted waters is obtained for the unfolding of both complexes from pressure perturbation calorimetric experiments. In total, the Δ V values obtained for the unfolding of triplex into duplex and a single strand correspond to an immobilization of two structural waters and a release of three electrostricted waters. The Δ V values obtained for the unfolding of duplex into two single strands correspond to the release of two structural waters and the immobilization of four electrostricted water molecules.

Effect of 5-methylcytosine on the structure and stability of DNA. Formation of triple-stranded concatenamers by overlapping oligonucleotides

A triple helix can be formed upon binding of a pyrimidine oligonucleotide to the major groove of a homopurine-homopyrimidine (R.Y) double-stranded DNA target site. Here, we report that this reaction can be influenced by base methylation. The pyrimidine strand 5'-TmCTmCTmCTmCTTmCT (mY12), whose cytosine residues are methylated at C5, does not bind the duplex 5'-AGAGAGAGAAGA.3'-TCTCTCTCTTCT (R12.Y12) to yield a 12-triad triplex, as would be expected from these DNA sequences. Rather, a complex of overlapping oligonucleotides, which we define concatenamer, is formed. The concatenamer is clearly evidenced by polyacrylamide gel electrophoresis (PAGE) since it migrates with a smeared band of very low mobility. The stoichiometry of the concatenamer, determined by both UV mixing curves and electrophoresis, is surprisingly found to be (R12.2mY12)n, thus showing that the unmethylated Y12 strand is excluded from the complex. Denaturation experiments performed by ultraviolet absorbance (UV) and differential scanning calorimetry (DSC) show that the concatenamers melt with a single and highly cooperative transition whose Tm strongly depends on pH. Overall, the data point to the conclusion that the concatenamers are in triple helix, where the methylated mY12 strand is engaged in both Watson-Crick and Hoogsteen base pairings, thus displacing the Y12 strand from the R12.Y12 duplex. A possible mechanism of concatenamer formation is proposed. The results presented in this paper show that 5-methylcytosine brings about a strong stabilizing effect on both double and triple DNA helices, and that pyrimidine oligonucleotides containing 5-methylcytosine can displace from R.Y duplexes the analogous non-methylated strand. The advantage of using methylated oligonucleotides in antisense technology is discussed.

Volume changes correlate with entropies and enthalpies in the formation of nucleic acid homoduplexes: differential hydration of A and B conformations

We have used a combination of densimetric, calorimetric, and uv absorption techniques to obtain a complete thermodynamic characterization for the formation of nucleic acid homoduplexes of known sequence and conformation. The volume change delta V accompanying the formation of four duplexes was interpreted to reflect changes in hydration based on the electrostriction phenomenon. In 10 mM sodium phosphate buffer at pH 7, the magnitude of the measured delta V's ranged from -2.0 to +7.2 ml/mol base pair and followed the order of poly(rA).poly(dT) approximately poly(dA).poly(dT) < poly(rA).poly(dU) approximately poly(rA).poly(rU). Inclusion of 100 mM NaCl in the same buffer gave the range of -17.4 to -2.3 mL/mol base pair and the following order: poly(dA).poly(dT) < poly(rA).poly(dT) < poly(rA).poly(rU) approximately poly(rA).polyr(dU). Standard thermodynamic profiles of forming these duplexes from their corresponding complementary single strands indicated similar free energies that resulted from the compensation of favorable enthalpies with unfavorable entropies along with a similar counterion uptake at both ionic strengths. The differences in these compensating effects of entropy and enthalpy correlated very well with the volume change measurements in a manner suggesting that the homoduplexes in the B conformation are more hydrated than are those in the A conformation. Moreover, the increased thermal stability of these homoduplexes resulted from an increase in the salt concentration corresponding to larger hydration levels as reflected by the delta V results.

Thermodynamic characterization of deoxyribooligonucleotide duplexes containing bulges

Ultraviolet absorption techniques were used to study the thermodynamics of duplex formation for a DNA decamer, d(GCGAAAAGCG).d(CGCTTTTCGC), and a series of related duplexes, each of which contains a bulged base centered in the A.T tract. Thermodynamic parameters were obtained from nonlinear least-squares fits of the melting curves and the concentration dependences of the melting temperatures. Duplexes containing a localized single-base bulge were found to be 3.5-4.6 kcal/mol less stable than the decamer at 37 degrees C. These results indicate that both the identity of the bulged base and the strand in which it is located may influence the amount by which the duplex is destabilized. Bulged bases located in the T-strand, d(CGCTTYTTCGC), in position Y, were observed to be slightly more destabilizing than those located in the A-strand, d(GCGAAXAAGCG), in position X. Bulged purines may be more destabilizing than bulged pyrimidines.

Probing the hydration of the minor groove of A.T synthetic DNA polymers by volume and heat changes

The minor-groove ligand netropsin provides a sensitive probe of the hydration difference between poly(dA).poly(dT) and poly[d(AT)].poly[d(AT)]. We have measured the volume change delta V accompanying binding of netropsin to these polymers, using an improved magnetic suspension densimeter. For poly(dA).poly(dT) we find delta V = +97 mL/mol of bound netropsin at pH 7.0 and 10 mM sodium phosphate buffer. For poly[d(AT)].poly[d(AT)] we find delta V = -16 mL/mol of bound netropsin. This striking differential effect suggests that the poly(dA).poly(dT) duplex compresses more water (or is more extensively hydrated). From our enthalpy and entropy results we estimate the approximately 10 water molecules, immobilized in the minor groove of this system, are displaced by each netropsin bound. The volume increase, however, is substantially larger than can be explained by a simple melting of these immobilized water molecules in the minor groove. A decompression of at least 40 water molecules must attend the complexation to the poly(dA).poly(dT) duplex. This suggests that the conformation change attending the binding of the drug to this polymer duplex causes a further dehydration, whereas no such change in dehydration and configuration for the heteropolymer system is indicated.

High-pressure scattering study of Artemia salina ribosomes and polysomes

The intensity has been measured of the light scattered by solutions of brine shrimp (Artemia salina) ribosomes and polysomes under hydrostatic pressures up to 2000 atm. This has given information about pressure-induced decreases in the means weight of the particles in solutions containing different concentrations of K+ and Mg2+ ions. The dissociation-association equilibrium reaction ribosome formed from large subunit + small subunit is accompanied by a volume change, --200 less than delta V less than --300 ml/mol; this delta V is discussed with relation to different models for the interaction between the ribosome subunits. The application of high pressures on polysome solutions caused also decreases of the light scattering; these were slower than in the case of ribosomes, and nonexponential. Only small decreases were found for ribosomes attached to messenger-RNA, which were obtained by incubation of polysomes with pancreatic RNAase. After fixation of the ribsomes and polysomes with formaldehyde, the light scattering remained constant with increasing pressures.