On the midpoint potential of the FAD chromophore in a BLUF-domain containing photoreceptor protein.

The redox-midpoint potential of the FAD chromophore in the BLUF domain of anti-transcriptional regulator AppA from Rhodobacter sphaeroides equals ∼-260mV relative to the calomel electrode. Altering the structure of its chromophore-binding pocket through site-directed mutagenesis brings this midpoint potential closer to that of free flavin in aqueous solution. The redox-midpoint potential of this BLUF domain is intermediate between those of LOV domains and Cryptochromes, which may rationalize the primary photochemistry observed in these three flavin-containing photoreceptor families. These results also imply that LOV domains, among the flavin-containing photosensory receptors, are least sensitive to intracellular chemical reduction in the dark.

On the signaling mechanism and the absence of photoreversibility in the AppA BLUF domain.

The flavoprotein AppA from Rhodobacter sphaeroides contains an N-terminal, FAD-binding BLUF photoreceptor domain. Upon illumination, the AppA BLUF domain forms a signaling state that is characterized by red-shifted absorbance by 10 nm, a state known as AppA(RED). We have applied ultrafast spectroscopy on the photoaccumulated AppA(RED) state to investigate the photoreversible properties of the AppA BLUF domain. On light absorption by AppA(RED), the FAD singlet excited state FAD(RED)* decays monoexponentially in 7 ps to form the neutral semiquinone radical FADH(*), which subsequently decays to the original AppA(RED) molecular ground state in 60 ps. Thus, FAD(RED)* is deactivated rapidly via electron and proton transfer, probably from the conserved tyrosine Tyr-21 to FAD, followed by radical-pair recombination. We conclude that, in contrast to many other photoreceptors, the AppA BLUF domain is not photoreversible and does not enter alternative reaction pathways upon absorption of a second photon. To explain these properties, we propose that a molecular configuration is formed upon excitation of AppA(RED) that corresponds to a forward reaction intermediate previously identified for the dark-state BLUF photoreaction. Upon excitation of AppA(RED), the BLUF domain therefore enters its forward reaction coordinate, readily re-forming the AppA(RED) ground state and suppressing reverse or side reactions. The monoexponential decay of FAD* indicates that the FAD-binding pocket in AppA(RED) is significantly more rigid than in dark-state AppA. Steady-state fluorescence experiments on wild-type, W104F, and W64F mutant BLUF domains show tryptophan fluorescence maxima that correspond with a buried conformation of Trp-104 in dark and light states. We conclude that Trp-104 does not become exposed to solvent during the BLUF photocycle.