Signal propagation in LOV-based multidomain proteins: time-resolved infrared spectroscopy reveals the complete photocycle of YF1 and PAL

Light-oxygen-voltage (LOV) domain proteins represent a versatile class of photoreceptors capable of regulating a wide range of light-dependent biological functions. While a lot of studies have focused on the photochemistry of LOV domains, the mechanisms of signal generation and propagation in multidomain LOV proteins remain incompletely understood. Here, we investigated two multidomain proteins, using time-resolved infrared spectroscopy. The measurements resolve the entire photocycle dynamics from picoseconds to hours and uncover distinct patterns of local and global structural responses. The two multidomain proteins under study, YF1 and PAL, exhibit nearly identical dynamics during excitation and intersystem crossing on the nanosecond timescale, reflecting conserved local interactions between the chromophore and its highly conserved binding pocket. Multiscale simulations attribute minor spectral differences in this regime to a phenylalanine residue located near the chromophore present only in one of the two LOV domains. The similarities, however, end at the microsecond timescale, where adduct formation already involves global structural adaptations. By experimentally isolating the response of the histidine kinase effector domain in the synthetic photoreceptor YF1, we show that major structural adaptions of the effector domain occur concurrently with cysteine-adduct formation and that the Jα-helix putatively mediates unidirectional communication between domains. In PAL, light-induced opening of the RNA binding site during the adduct formation is additionally followed by a subsequent rearrangement in the distal PAS domain after 3 s. This highlights the pivotal yet distinct roles of the Jα-helix in signal transmission, which depend on the domain topology. Ultimately, our study not only deepens the current understanding of signal transduction in full-length LOV proteins, but also contributes to the fundamental framework for the future application of LOV domains in optogenetic engineering.