Investigations on purine and pyrimidine bases stacking associations in aqueous solutions by the fluorescence quenching method. I. Autoassociation of 2-aminopurine

Photoinduced electron transfer occurs between 2-aminopurine and the DNA nucleic acid monophosphates: results from cyclic voltammetry and fluorescence quenching

2-Aminopurine (2AP) is a fluorescent adenine analogue that is useful in part because its substantial fluorescence quantum yield is sensitive to base stacking with native bases in ss- and ds-DNA. However, the degree of quenching is sequence dependent and the mechanism of quenching is still a matter of some debate. Here we show that the most likely quenching mechanism in aqueous solution involves photoinduced electron transfer (PET), as revealed by cyclic voltammetry (CV) performed in aprotic organic solvents. These potentials were used with spectroscopic data to obtain excited-state reduction and oxidation potentials. Stern-Volmer (S-V) experiments using the native base monophosphate nucleotides (NMPs) rGMP, rAMP, rCMP, and dTMP were performed in aqueous solution to obtain quenching rate constants kq. The results suggest that 2AP* can act as either an electron donor or an electron acceptor depending on the particular NMP but that PET proceeds for all NMPs tested.

Use of 2-aminopurine as a fluorescent tool for characterizing antibiotic recognition of the bacterial rRNA A-site

Spectroscopic and calorimetric techniques have been employed to characterize the impact of incorporation of the fluorescent base analog 2-aminopurine into the 1492 or 1493 position of an E. coli rRNA A-site model oligonucleotide, as well as the energetics and dynamics associated with recognition of this A-site model oligomer by aminoglycoside antibiotics. The results of these studies indicate that incorporation of 2AP into either the 1492 or 1493 position does not perturb the structure or stability of the host RNA or its aminoglycoside binding affinity. In addition, the results also highlight drug-induced reduction in the mobilities of the bases at both positions 1492 and 1493 as a potentially key determinant of bactericidal potency.

Solution influence on biomolecular equilibria: nucleic acid base associations

This paper consists of two parts. In the first part, the general problem of biomolecular equilibria in solution is considered, stressing that molecular interactions ultimately determine the answer to this problem. It is discussed how computer simulation techniques can reliably treat the problem and several pitfalls of computer simulation to be avoided are pointed out. Other approaches based on modeling and conceptual simplifications such as perturbative methods, long-range interaction approximations, surface thermodynamic approaches, and hydration shell models are discussed. In the second part, the results of Monte Carlo calculations on the associations of nucleic acid bases in water and carbon tetrachloride are presented. Stacked self-associations are found to be preferred in water and hydrogen-bonded complexes are favored in nonpolar solutions, in agreement with experimental data. The influence of the solvent on base associations is explained in terms of solute-solvent and solvent-solvent contributions to the total energy. No enthalpic stabilization of the complexes by the solvent was found. The results are used to examine the validity of various approximations discussed in the first part of the paper.

Fluorescence quenching and spin label electron spin resonance studies of stacking self-association in aqueous solutions of 2-aminopurine riboside and its 5'-mono- and -diphosphate

The autoassociation of 2-aminopurine riboside (rn2Pur) and its 5'-mono- (P-rn2Pur) and 5'-diphosphate (PP-rn2Pur) in neutral aqueous solutions was investigated using fluorescence quenching and ESR spin-label methods within the range 276-358 K. Respective equilibrium constants and thermodynamic functions were derived therefrom assuming two models of infinite autoassociation: (i) an isodesmic one (K2 = K3 = ... Kp), and (ii) one in which K2 no equal to K2 = K4 ... Kp. Comparative analysis of these data and that of the parent 2-aminopurine, obtained previously, allowed us to formulate the following conclusions: (1) the mechanism of autoassociation of rn2Pur varies with temperature in such a way that a T = 318 K the isodesmic model is fulfilled (K2 = Kp); at high temperatures Kp/K2 greater than 1, i.e. the process is cooperative, while at lower temperatures it becomes anticooperative (Kp/K2 greater less than 1); (2) at 298 K the tendency to autoassociation decreases in the order; rn2Pur greater than P-rn2Pur greater than PP-rn2Pur; (3) rn2Pur forms highly packed complexes with the bases stacked and the ribofuranose residues interacting via hydrogen bonds or water bridges; (4) autoassociation of P-rn2Pur and PP-rn2Pur is mainly governed by stacking of the bases, while the ribose phosphate residues attain a trans configuration corresponding to the lowest electrostatic repulsion between charged phosphate groups; even at high ionic strength (I = 0.8), a positive electrostatic contribution to the free enthalpy of autoassociation is observed; (5) the two methods employed gave similar results for P-rn2Pur, but somewhat different ones for rn2Pur because the presence of the spin label (nitroxide stable radical) at the 2'(3')-OH group of the ribose residues prevents its interaction via hydrogen bonding with an unlabeled one of an adjacent nucleoside.

Investigations on purine and pyrimidine bases stacking associations in aqueous solutions by the fluorescence quenching method. II. Heteroassociation between 2-aminopurine and thymidine

Heteroassociation between A and B compounds in liquid solution was considered. Provided that concentration of A molecules is low, a general equation describing fluorescence quantum yield and lifetime of compound A as a function of B molecules concentration was derived. The heteroassociation between 2-aminopurine and thymidine in aqueous solutions was examined within the range of temperatures 0 to 90 degrees C. The equilibrium constants of the first step of association, namely heterodimer formation, were determined and its thermodynamic parameters (deltaH equals - 2.76 kcal/mol, deltaS equals - 5.9 e.u.) were calculated. The observed changes of the stacking rate constants with temperature confirm the two-step mechanism of the reaction. The activation energy (approximately 10.7 angstroms) are only slightly larger than in the case of 2-aminopurine autoassociation, most probably because of a stronger solvation of thymidine molecules.

Investigations on purine and pyrimidine bases stacking associations in aqueous solutions by the fluorescence quenching method. III. Intramolecular association of 9,9'-[1,3-propylene]-bis-2-aminopurine

General equations relating fluorescence quantum yield and lifetime of a compound with its intramolecular stacking equilibrium and kinetics were derived. Intramolecular stacking association of 9,9'-[1,3-propylene]-bis-2-aminopurine in aqueous solution was examined within the range of temperatures from 0 to 90 degrees C. A two-state thermodynamic model of the association was verified. The stacking enthalpy and entropy can be taken, with a good approximation, as temperature-independent (deltaH equals - 2.0 kcal/mol, deltaS=-3.25 e.u.) although the function deltaG=-0.00886T2 + 8.847 T - 2876 describes more precisely the observed changes of stacking free enthalpy with temperature. The association rate constants were detemined. Activation energy of the reaction (2 kcal/mol) is the same as in the case of association between free 2-aminopurine molecules. It confirms a two-step mechanism of the process. The advantages and shortcomings of the fluorescence quenching method are discussed.