Assignment of electronic transition moment directions of adenine from linear dichroism measurements
Artikel i vetenskaplig tidskrift, 1997
The electronic spectra of a series of adenine derivatives have been investigated with respect to the number of electronic transitions, their intensities, and transition moments. The experimental work includes linear dichroism (LD) measurements on samples partially oriented in stretched polymer poly(vinyl alcohol) films, fluorescence anisotropy (FA), and: magnetic circular dichroism (MCD). The UV spectra of both 7-methyladenine (7MA) and 9-methyladenine (9MA) are resolved into contributions from five pi --> pi* transitions (I-V). Their polarizations relative to the C-4-C-5 axis are for 7MA +45 degrees (I, 36 600 cm(-1)), -16 degrees (II, 39 500 cm(-1)), -28 degrees (III, 42 600 cm(-1)), +76 degrees (IV 45 800 cm(-1)) and similar to-29 degrees (V, similar to 47 700 cm(-1)); and for 9MA +66 degrees (I, 36 700 cm(-1)), +19 degrees (II, 38 820 cm(-1)), -15 degrees (III, 43 400 cm(-1)), -21 degrees (IV, 46 800 cm(-1)), and similar to-64 degrees (V, similar to 48 320 cm(-1)). The experimental results are correlated with results from semiempirical INDO/S and ab initio CIS/6-31G(d) and CASPT2 molecular orbital calculations. The transition moments are found to be conserved when the adenine amino group has been substituted with either one or two methyl groups. In addition, LD and MCD spectra for 6-(dimethylamino)-9-ethylpurine, which is soluble in nonpolar solvents, have been measured in stretched polyethylene film and cyclohexane, respectively. The results indicate that the electronic transition moments of the 9-substituted adenine chromophore are essentially the same in a polar and a nonpolar solvent. On the basis of the. results,for 7MA and 9MA, the reduced LD and absorption spectra of adenine are analyzed in terms of contributions from the 7-H and 9-H tautomers of adenine. By comparison with theoretical and experimental results for purine and 2-aminopurine regarding the position of the lowest n --> pi* transition, we are able to confidently position the lowest n --> pi* transition in 9MA very close to the lowest pi --> pi* transition. The proximity of the first (1)n pi* and (1) pi pi* states in adenine might be related to the efficient nonradiative deactivation of the lowest excited (1) pi pi* state.