Theoretical study of the absorption spectra and fluorescence of tryptophan and analogues.

Semi-empirical and ab-initio calculations were performed on 5-hydroxytryptophan (5-OH-trp), 7-aza-tryptophan (7-aza-trp) and tryptophan (trp). The potential energy surface (PES) of the ground state (GS) and the lowest exited state (1ES) was determined as a function X IND. 1 e X IND. 2 angles corresponding to the dihedrals N-C IND.alfa-C IND.beta-C IND.gama e C IND.alfa-C IND.beta-C IND.gama- C IND.delta2, respectively. The compounds were studied in the zwitterionic, neutral and anionic states. The PES of the GS was obtained using the AM1 semi-empirical method and was used as a reference for the ab-initio calculations. The configuration interaction method with single excitations (CIS) was used for the calculations of the 1ES with frozen internal orbitals. After geometry optimization of GS, the transition energies to 1ES were obtained by INDO/S-CIS, giving the theoretical optical absorption spectrum. Similarly, following the geometry optimization of 1ES, the transition energies to GS were determined, giving the fluorescence emission spectrum. Experimental results were obtained for optical absorption and fluorescence spectra of 5-OH-trp and 7-aza-trp in phosphate buffer solution, pH 7.4. The fluorescence decay of the compounds was also examined. Decay profiles fitted to multiexponential function were analyzed in terms of Boltzmann relative populations in the GS and 1ES. The non-radioactive electron transfer rates in the excited state were obtained by computational implementation of the Marcus Theory with renormalized perturbation expansion method (RPE). In this study, optimizations of the transition states in the PES of the ground and lower excited states were performed by the Synchronous Transit-Guided Quasi-Newton method and the Berny algorithm modified. For further comparison with experimental conditions, molecular dynamic simulations for the zwitterionic 5-OH-trp were performed using the hybrid QM/MM method with explicit representation of the aqueous solvent. To start the simulations the results from ab-initio calculations were used. The conformations for the GS, the theoretical absorption spectrum and the solvation layers were compared to the experimental results (AU)