ALBERT

Notes: Seventeen DNA dumbbells were constructed that have duplex sequences ranging in length from 14 to 18 base pairs linked on the ends by T4 single-strand loops. Fifteen of the molecules have the core duplexes with the sequences 5′G-T-A-T-C-C-(W-X-Y-Z)-G-G-A-T-A-C3′, where (W-X-Y-Z) represents a unique combination of A · T, T · A, G · C, and C · G base pairs. The remaining two molecules have the central sequences (W-X-Y-Z) = A-C and A-C-A-C-A-C. These duplex sequences were designed such that the central sequences include different combinations of the 10 possible nearest-neighbor (n-n) stacks in DNA. In this sense the set of molecules is complete and serves as a model system for evaluating sequence-dependent local stability of DNA. Optical melting curves of the samples were collected in 25, 55, 85, and 115 mM [Na +], and showed, regardless of solvent ionic strength, that the transition temperatures of the dumbbells vary by as much as 14° for different molecules of the set.Results of melting experiments analyzed in terms of a n-n sequence-dependent model allowed evaluation of nine independent linear combinations of the n-n stacking interactions in DNA as a function of solvent ionic strength. Although there are in principle 10 possible different n-n interactions in DNA, these 10 are not linearly independent and therefore can not be uniquely determined. For molecules with ends, there are 9 linearly independent combinations, as opposed to circular or semiinfinite repeating copolymers where only 8 linear combinations of the 10 possible n-n interactions are linearly independent. The n-n interactions are presented as combinations of the deviations from average stacking for the 5′-3′ base-pair doublets, δGi, and reveal several interesting features: (1) Titratable changes in the values of δGi, with changing salt environment are observed. In all salts the most stable unique combination is δG4 = (δGGpC + δGCpG,)/2, and the least stable is the GpG/CpC stack, δG2 = δGGpG/CpC. (2) The χ2 values of the fits of the evaluated δGi's to experimental data increased with decreasing [Na +], suggesting that significant interactions beyond nearest neighbors become more pronounced, particularly at 25 mM Na +. (3) In 85 and 115 mM Na +, where the n-n approximation seems to be most valid, the absolute value of δGi for any n-n stack or average of two n-n stacks is not more than ∼ 220 cal/mole, indicating that deviations from average stacking due to n-n interactions represent about 15% of the total stability of a base pair. The overall thermodynamic stability of DNA is predominantly determined by the sequence content (%G · C). Even though the contribution of n-n interactions to overall stability are intrinsically small, reliable predictions of DNA transition temperatures de novo from sequence can be significantly compromised by cumulative errors in the δGi's. (4) Comparisons of our set of n-n linear combinations evaluated in 115 mM Na+ with various published sets evaluated from melting experiments of long restriction fragments, synthetic polymers, and short oligomers, and those obtained from a reanalysis of published melting data of synthetic polymers, are presented. The analysis reveals a major consensus agreement between n-n free energies evaluated from melting data of restriction fragments and long synthetic repeating copolymers. In contrast, only a minor consensus agreement is obtained between our n-n set and these values or those obtained from melting analysis of a combination of short oligomers and long polymers or those theoretically calculated. Results of these comparisons suggest the values of n-n interactions evaluated from DNA melting curves depend on the length of the melted duplex regions of the DNA molecules that comprise the sample set.

Notes: CD spectra and melting curves were collected for a 28 base-pair DNA fragment in the form of a DNA dumbbell (linked on both ends by T4 single-strand loops) and the same DNA sequence in the linear form (without end loops). The central 16 base pairs (bp) of the 28-bp duplex region is the poly(pu) sequence: 5′-AGGAAGGAGGAAAGAG-3′. Mixtures of the dumbbell and linear DNAs with the 16-base single-strand sequence 5′-TCCTTCCTCCTTTCTC-3′ were also prepared and studied. At 22°C, CD measurements of the mixtures in 950 mM NaCl, 10 mM sodium acetate, 1 mM EDTA, pH 5.5, at a duplex concentration of 1.8 μM, provided evidence for triplex formation. Spectroscopic features of the triplexes formed with either a dumbbell or linear substrate were quite similar. Melting curves of the duplex molecules alone and in mixtures with the third strand were collected as a function of duplex concentration from 0.16 to 2.15 μM. Melting curves of the dumbbell alone and mixtures with the third strand were entirely independent of DNA concentration. In contrast, melting curves of the linear duplex alone or mixed with the third strand were concentration dependent. At identical duplex concentrations, the dumbbell alone melts ∼20°C higher than the linear duplex. The curve of the linear duplex displayed a significant pretransition probably due to end fraying.On melting curves of mixtures of the dumbbell or linear duplex with the third strand, a low temperature transition with much lower relative hyperchromicity change (∼ 5%) was observed. This transition was attributed to the melting of a new molecular species, e.g., the triplex formed between the duplex and single-strand DNA molecules. In the case of the dumbbell/single-strand mixture, these melting transitions of the triplex and the dumbbell were entirely resolvable. In contrast, the melting transitions of the linear duplex and the triplex overlapped, thereby preventing their clear distinction. To analyze the data, a three-state equilibrium model is presented. The analysis utilizes differences in relative absorbance vs temperature curves of dumbbells (or linear molecules) alone and in mixtures with the third strand. From the model analysis a straightforward derivation of fT(T), the fraction of triplex as a function of temperature, was obtained. Analysis of fT vs temperature curves, in effect melting curves of the triplexes, provided evaluation of thermodynamic parameters of the melting transition. For the triplex formed with the dumbbell substrate, the total transition enthalpy is ΔHT = 118.4 ± 12.8 kcal/mol (7.4 ± 0.8 kcal/mol per triplet unit) and the total transition entropy is ΔST = 344 ± 36.8 cal/K · mol (eu) (21.5 ± 2.3 eu per triple unit). The transition curves of the triplex formed with the linear duplex substrate displayed two distinct regions. A broad pretransition region from fT = 0 to 0.55 and a higher, sharper transition above fT = 0.55. The transition parameters derived from the lower temperature region of the curve are ΔH′T = 44.8 ± 9.6 kcal/mol and ΔS′T = 112 ± 33.6 eu (or ΔH′ = 2.8 ± 0.6 kcal/mol and ΔS′ = 7.0 ± 2.1 eu per triplet). These values are probably too small to correspond to actual melting of the triplex but instead likely reveal effects of end fraying of the duplex substrate on triplex stability. Transition parameters of the upper transition are ΔH′T = 128.0 ± 2.3 kcal/mol and ΔS′T = 379.2 ± 6.4 eu (ΔH′ = 8.0 ± 0.2 kcal/mol and ΔS′ = 23.7 ± 0.4 eu per triplet) in good agreement (within experimental error) with the transition parameters of the triplex formed with the dumbbell substrate. Supposing this upper transition reflects actual dissociation of the third strand from the linear duplex substrate this triplex is comparable in thermodynamic stability to the triplex formed with a dumbbell substrate. Even so, the biphasic melting character of the linear triplex obscures the whole analysis, casting doubt on its absolute reliability. Apparently triplexes formed with a dumbbell substrate offer technical advantages over triplexes formed from linear or hairpin duplex substrates for studies of DNA triplex stability. © 1993 John Wiley & Sons, Inc.

Notes: Many important applications of DNA sequence-dependent hybridization reactions have recently emerged. This has sparked a renewed interest in analytical calculations of sequence-dependent melting stability of duplex DNA. In particular, for many applications it is often desirable to accurately predict the transition temperature, or tm, of short duplex DNA oligomers (∼ 20 base pairs or less) from their sequence and concentration. The thermodynamic analytical method underlying these predictive calculations is based on the nearest-neighbor model. At least 11 sets of nearest-neighbor sequence-dependent thermodynamic parameters for DNA have been published. These sets are compared. Use of the nearest-neighbor sets in predicting tm from the DNA sequence is demonstrated, and the ability of the nearest-neighbor parameters to provide accurate predictions of experimental tm's of short duplex DNA oligomers is assessed. © 1998 John Wiley & Sons, Inc. Biopoly 44: 217-239, 1997