Light is a key stimulus for plant biological functions, several of which are controlled by lightactivated kinases known as phototropins, a group of kinases that contain two light-sensing domains (LOV, Light-Oxygen-Voltage domains) and a C-terminal serine/threonine kinase domain. The second sensory domain, LOV2, plays a key role in regulating kinase enzymatic activity via the photochemical formation of a covalent adduct between a LOV2 cysteine residue and an internallybound flavin mononucleotide (FMN) chromophore. Subsequent conformational changes in LOV2 lead to the unfolding of a peripheral Jα helix, and ultimately, phototropin kinase activation. To date, the mechanism coupling bond formation and helix dissociation has remained unclear. Previous studies found that a conserved glutamine residue (Q513 in the Avena sativa phototropin 1 LOV2 (AsLOV2) domain) switches its hydrogen-bonding pattern with FMN upon light stimulation. Located in the immediate vicinity of the FMN binding site, this Gln residue is provided by the Iβ strand that interacts with the Jα helix, suggesting a route for signal propagation from the core of the LOV domain to its peripheral Jα helix. To test whether Q513 plays a key role in tuning the photochemical and transduction properties of AsLOV2, we designed two point mutations, Q513L and Q513N, and monitored the effects on the chromophore and protein using a combination of UV-visible absorbance and circular dichroism spectroscopy, limited proteolysis, and solution NMR. The results show that these mutations significantly dampen the changes between the dark and lit state AsLOV2 structures, leaving the protein in a pseudo-dark state (Q513L) or a pseudo-lit state (Q513N) conformation. Further, both mutations changed the photochemical properties of this receptor, particularly the lifetime of the photoexcited signaling states. Together, these data establish that this residue plays a central role in both spectral tuning and signal propagation from the core of the LOV domain through the Iβ strand to the peripheral Jα helix.Protein signaling cascades are central to organismal growth, adaptation, and communication; therefore, the regulation of these cascades is key to survival. PAS (Per-ARNT-Sim) domaincontaining proteins are well characterized as vital members of many such regulatory paths, including adaptation to hypoxia (1), circadian rhythm-dependent gene transcription (2), and phototropism and chloroplast organization in plants (3). A specific subset of PAS proteins, the LOV (light-oxygen-voltage) domains (4), is capable of sensing blue light as an environmental signal and converting it into a biochemical signal in a wide variety of proteins.LOV domains contain a series of highly conserved residues surrounding an internally bound flavin mononucleotide (FMN) or flavin adenine dinucleotide (FAD) chromophore (Fig. 1a, 1b) The sensory role played by LOV domains is characterized in a variety of proteins, including transcription factors, ubiquitin ligases and kinases. Previous studies on photo...
