Electronic absorption and emission spectra of nucleic acids and their components: Some questions of theory and experiment

Abstract: The results of calculations of the transition energies and polarization in nucleotide bases performed by the CNDO/S CI method are compared with experimental data for long-wavelength and vacuumabsorption bands. The calculations and the analysis of experimental data testify to the existence of n -T* transitions in the first absorption bands of the bases. The study of double-stranded polynucleotides and DNA hypochromism based on the theoretical electronic characteristics of the bases and perturbation theory is pe… Show more

“…The lowest electronic state of guanine is unambiguously characterized to be a * state, and the lowest n * state appears to be much higher in energy by about 0.5 eV to 0.9 eV. 13,14,16 Therefore, it is expected that the vibronic mixing between the n * and * states occurs in a much higher frequency region, perhaps well outside the range of the spectrum experimentally observed ͑Fig. 1 of Ref.…”

“…of the -* transition. 9,10 As for the relative locations of these states, Lipiński 13 and Hug and Tinoco 14 suggested that the n * state is located between the two lowest * states, whereas Stewart and Davidson, 10 Danilov et al, 16 and Takahata 17 proposed that the n * state is the lowest singlet excited state of adenine. Broo also concluded that the geometrically relaxed lowest excited state of adenine has an n * character, while a related compound, 2-aminopurine, has a strong * character that gives the molecule totally different photophysical properties.…”

“…15 Most of these studies agree, however, that the energy difference between the n * and * states is too small ͑and perhaps within the accuracy of the calculations͒ to allow unequivocal determination of the relative locations of the two states. 16 In contrast to the case of adenine, the electronic structure of guanine is quite well known. The lowest electronic state of guanine is unambiguously characterized to be a * state, and the lowest n * state appears to be much higher in energy by about 0.5 eV to 0.9 eV.…”

“…11 The locations and transition moments of the n * and * excited states were estimated by theoretical calculations. [12][13][14][15][16][17][18] Although most conventional studies in the condensed phase have found broad, structureless spectra, some recent investigations revealed better-resolved spectral features. For example, infrared spectra were obtained in a low-temperature inert gas matrix, 19 in a static gas cell, 20 and in a supersonic jet.…”

“…In contrast to the broad, structureless spectra of thymine and uracil even in a jet-cooled condition, 24 a well-resolved vibronic structure was observed in the electronic spectrum of adenine, as in the case of guanine. 25 It has been suggested by theory that the n * and * states lie close to each other in adenine, [13][14][15][16][17] while the identity of the lowest electronically excited state has been the subject of a long-standing debate. 13,17 Our findings strongly suggest that this state is of n * character, and that there exists extensive vibronic mixing between the n * and * states.…”

Resonant two-photon ionization and laser induced fluorescence spectroscopy of jet-cooled adenine

“…The lowest electronic state of guanine is unambiguously characterized to be a * state, and the lowest n * state appears to be much higher in energy by about 0.5 eV to 0.9 eV. 13,14,16 Therefore, it is expected that the vibronic mixing between the n * and * states occurs in a much higher frequency region, perhaps well outside the range of the spectrum experimentally observed ͑Fig. 1 of Ref.…”

“…of the -* transition. 9,10 As for the relative locations of these states, Lipiński 13 and Hug and Tinoco 14 suggested that the n * state is located between the two lowest * states, whereas Stewart and Davidson, 10 Danilov et al, 16 and Takahata 17 proposed that the n * state is the lowest singlet excited state of adenine. Broo also concluded that the geometrically relaxed lowest excited state of adenine has an n * character, while a related compound, 2-aminopurine, has a strong * character that gives the molecule totally different photophysical properties.…”

“…15 Most of these studies agree, however, that the energy difference between the n * and * states is too small ͑and perhaps within the accuracy of the calculations͒ to allow unequivocal determination of the relative locations of the two states. 16 In contrast to the case of adenine, the electronic structure of guanine is quite well known. The lowest electronic state of guanine is unambiguously characterized to be a * state, and the lowest n * state appears to be much higher in energy by about 0.5 eV to 0.9 eV.…”

“…11 The locations and transition moments of the n * and * excited states were estimated by theoretical calculations. [12][13][14][15][16][17][18] Although most conventional studies in the condensed phase have found broad, structureless spectra, some recent investigations revealed better-resolved spectral features. For example, infrared spectra were obtained in a low-temperature inert gas matrix, 19 in a static gas cell, 20 and in a supersonic jet.…”

“…In contrast to the broad, structureless spectra of thymine and uracil even in a jet-cooled condition, 24 a well-resolved vibronic structure was observed in the electronic spectrum of adenine, as in the case of guanine. 25 It has been suggested by theory that the n * and * states lie close to each other in adenine, [13][14][15][16][17] while the identity of the lowest electronically excited state has been the subject of a long-standing debate. 13,17 Our findings strongly suggest that this state is of n * character, and that there exists extensive vibronic mixing between the n * and * states.…”

Resonant two-photon ionization and laser induced fluorescence spectroscopy of jet-cooled adenine

Protein: Nucleic acid interactions. I. Electronic structures of cytosine, indole, and guanine complexes

Potential energy curves in complementary base pairs and in model hydrogen bonded systems