Single Amino Acid Mutation Decouples Photochemistry of the BLUF Domain from the Enzymatic Function of OaPAC and Drives the Enzyme to a Switched-on State

Enhancing Proton-Coupled Electron Transfer in Blue Light Using FAD Photoreceptor AppABLUF

The Blue Light Using FAD (BLUF) photoreceptor utilizes a noncovalently bound FAD to absorb light and trigger the initial ultrafast events in receptor activation. FAD undergoes 1 and 2 electron reduction as an enzyme redox cofactor, and studies on the BLUF photoreceptor PixD revealed the formation of flavin radicals (FAD•- and FADH•) during the photocycle, supporting a general mechanism for BLUF operation that involves PCET from a conserved Tyr to the oxidized FAD. However, no radical intermediates are observed in the closely related BLUF proteins AppABLUF and BlsA, and replacing the conserved Tyr with fluoro-Tyr analogs that increase the acidity of the phenol OH has a minor effect on AppABLUF photoactivation in contrast to PixD where the photocycle is halted at FAD•-. The hydrogen bonding network in BLUF proteins contains several strictly conserved residues but differs in the identity of amino acids that interact with the flavin C2═O. In PixD there are two hydrogen bonds to the C2═O, whereas there is only one in AppABLUF. Using TRIR we show that the introduction of a second hydrogen bond to the C2═O in AppABLUF results in the formation of flavin radicals (FAD•- and FADH•) during the photocycle. Subsequent replacement of the conserved Tyr (Y21) in the double mutant with 2,3,5-trifluoroTyr prevents radical formation and generation of the light state, indicating that the AppABLUF photocycle is now similar to that of PixD. The ability to trigger PCET provides fundamental insight into the role of electron transfer in the mechanism of BLUF photoactivation.

Unveiling the Photoactivation Mechanism of BLUF Photoreceptor Protein through Hybrid Quantum Mechanics/Molecular Mechanics Free-Energy Calculation

OaPAC is a photoactivated enzyme that forms a homodimer. The two blue-light using flavin (BLUF) photoreceptor domains are connected to the catalytic domains with long coiled-coil C-terminal helices. Upon photoreception, reorganization of the hydrogen bonding network between Tyr6, Gln48, and the chromophore in the BLUF domain and keto-enol tautomerization of Gln48 are thought to occur. However, the quantitative energetics of the photoisomerization reaction and how the BLUF domain's structural change propagates toward the catalytic domain are still unknown. We evaluate the free-energy differences among the dark-state and two different light-state structures by the free-energy perturbation calculations combined with QM/MM free-energy optimizations. Furthermore, we performed long-time MD simulations for the free-energetically optimized dark- and light-state structures to clarify the differences in protein dynamics upon photoisomerization. The free-energy difference between the two optimized light-state structures was estimated at ∼4.7 kcal/mol. The free-energetically optimized light-state structure indicates that the chemically unstable enol tautomer of Gln48 in the light state is stabilized by forming a strong hydrogen bonding network with the chromophore and Tyr6. In addition, the components of free-energy difference between the dark- and light-state structures show that the energy upon photoreception is stored in the environment rather than the internal photoreceived region, suggesting a mechanism to keep the photoactivated signaling state with the chemically unstable enol tautomer of Gln48. In the light state, a fluctuation of Trp90 near the C-terminal helix becomes large, which causes subsequent structural changes in the BLUF core and the C-terminal helix. We also identified residue pairs with significant differences concerning residue-wise contact maps between the dark and light states.

Crystal structure of a bacterial photoactivated adenylate cyclase determined by serial femtosecond and serial synchrotron crystallography

OaPAC is a recently discovered blue-light-using flavin adenosine dinucleotide (BLUF) photoactivated adenylate cyclase from the cyanobacterium Oscillatoria acuminata that uses adenosine triphosphate and translates the light signal into the production of cyclic adenosine monophosphate. Here, we report crystal structures of the enzyme in the absence of its natural substrate determined from room-temperature serial crystallography data collected at both an X-ray free-electron laser and a synchrotron, and we compare these structures with cryo-macromolecular crystallography structures obtained at a synchrotron by us and others. These results reveal slight differences in the structure of the enzyme due to data collection at different temperatures and X-ray sources. We further investigate the effect of the Y6W mutation in the BLUF domain, a mutation which results in a rearrangement of the hydrogen-bond network around the flavin and a notable rotation of the side chain of the critical Gln48 residue. These studies pave the way for picosecond-millisecond time-resolved serial crystallography experiments at X-ray free-electron lasers and synchrotrons in order to determine the early structural intermediates and correlate them with the well studied picosecond-millisecond spectroscopic intermediates.