Abstract
Semiempirical CISD calculations were carried out on models of differently protonated forms of the isolated chromophore active in the green fluorescent protein (GFP). Electronic excitation (S 0→S 1) is found to considerably alter the equilibrium conformation of the chromophore. Low activation barriers to rotation about the exocyclic bond C γ–C β adjacent to the phenol ring are calculated for the cationic form in both states, S 0 and S 1, for the neutral chromophore in the S 0, and for the zwitterion in the S 1 state. It is of interest that only in the protonated state the energy gap between the two potential energy surfaces is small enough to allow internal conversion of the isolated chromophore. We propose that the fast internal conversion observed in GFP mutants is also associated with an avoided crossing of the S 0 and S 1 surfaces of the cation during the rotation around the bond C β–C α.
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