Flavin-based fluorescent
proteins are a class of fluorescent reporters
derived from light, oxygen, and voltage (LOV) sensing proteins. Through
mutagenesis, natural LOV proteins have been engineered to obtain improved
fluorescence properties. In this study, we combined extended classical
Molecular Dynamics simulations and multiscale Quantum Mechanics/Molecular
Mechanics methods to clarify the relationship between structural and
dynamic changes induced by specific mutations and the spectroscopic
response. To reach this goal we compared two LOV variants, one obtained
by the single mutation needed to photochemically inactivate the natural
system, and the other (iLOV) obtained through additional mutations
and characterized by a significantly improved fluorescence. Our simulations
confirmed the “flipping and crowding” effect induced
in iLOV by the additional mutations and revealed its mechanism of
action. We also showed that these mutations, and the resulting differences
in the composition and flexibility of the binding pockets, are not
reflected in significant shifts of the excitation and emission energies,
in agreement with the similarity of the spectra measured for the two
systems. However, a small but consistent reduction was found in the
Stokes shift of iLOV, suggesting a reduction of the intermolecular
reorganization experienced by the chromophore after excitation, which
could slow down its internal conversion to the ground state and improve
the fluorescence.
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