Key residues for the light regulation of the blue light-activated adenylyl cyclase from Beggiatoa sp.

Photoactivated adenylyl cyclases are powerful tools for optogenetics and for investigating signal transduction mechanisms in biological photoreceptors. Because of its large increase in enzyme activity in the light, the BLUF (blue light sensor using flavin adenine dinucleotide)-activated adenylyl cyclase (bPAC) from Beggiatoa sp. is a highly attractive model system for studying BLUF domain signaling. In this report, we studied the influence of site-directed mutations within the BLUF domain on the light regulation of the cyclase domain and determined key elements for signal transduction and color tuning. Photoactivation of the cyclase domain is accomplished via strand ß5 of the BLUF domain and involves the formation of helical structures in the cyclase domain as assigned by vibrational spectroscopy. In agreement with earlier studies, we observed severely impaired signaling in mutations directly on strand ß5 as well as in mutations affecting the hydrogen bond network around the flavin. Moreover, we identified a bPAC mutant with red-shifted absorbance and a decreased dark activity that is highly valuable for long-term optogenetic experiments. Additionally, we discovered a mutant that forms a stable neutral flavin semiquinone radical in the BLUF domain and surprisingly exhibits an inversion of light activation.

Photoactivation Mechanism of a Bacterial Light-Regulated Adenylyl Cyclase.

Light-regulated enzymes enable organisms to quickly respond to changing light conditions. We characterize a photoactivatable adenylyl cyclase (AC) from Beggiatoa sp. (bPAC) that translates a blue light signal into the production of the second messenger cyclic AMP. bPAC contains a BLUF photoreceptor domain that senses blue light using a flavin chromophore, linked to an AC domain. We present a dark state crystal structure of bPAC that closely resembles the recently published structure of the homologous OaPAC from Oscillatoria acuminata. To elucidate the structural mechanism of light-dependent AC activation by the BLUF domain, we determined the crystal structures of illuminated bPAC and of a pseudo-lit state variant. We use hydrogen-deuterium exchange measurements of secondary structure dynamics and hypothesis-driven point mutations to trace the activation pathway from the chromophore in the BLUF domain to the active site of the cyclase. The structural changes are relayed from the residues interacting with the excited chromophore through a conserved kink of the BLUF ß-sheet to a tongue-like extrusion of the AC domain that regulates active site opening and repositions catalytic residues. Our findings not only show the specific molecular pathway of photoactivation in BLUF-regulated ACs but also have implications for the general understanding of signaling in BLUF domains and of the activation of ACs.