Abstract
Channelrhodopsins are microbial type rhodopsins that operate as light-gated ion channels. Largely prolonged lifetimes of the conducting state of channelrhodopsin-2 may be achieved by mutations of crucial single amino acids, i.e. cysteine 128. Such mutants are of great scientific interest in the field of neurophysiology because they allow neurons to be switched on and off on demand (step function rhodopsins). Due to their slow photocycle, structural alterations of these proteins can be studied by vibrational spectroscopy in more detail than possible with wild type. Here, we present spectroscopic evidence that the photocycle of the C128T mutant involves three different dark-adapted states that are populated according to the wavelength and duration of the preceding illumination. Our results suggest an important role of multiphoton reactions and the previously described side reaction for dark state regeneration. Structural changes that cause formation and depletion of the assumed ion conducting state P520 are only small and follow larger changes that occur early and late in the photocycle, respectively. They require only minor structural rearrangements of amino acids near the retinal binding pocket and are triggered by all-trans/13-cis retinal isomerization, although additional isomerizations are also involved in the photocycle. We will discuss an extended photocycle model of this mutant on the basis of spectroscopic and electrophysiological data.
Highlights
Channelrhodopsins are light-gated ion channels of microalgae
Monitoring Dark State Regeneration of C128T by FTIR and UV-visible Difference Spectroscopy—Recombinant channelrhodopsin mutant ChR-C128T used for this study was purified from COS cells and reconstituted in lipid vesicles under dim red light (Ͼ 680 nm)
The Dark States of C128T—By FTIR spectroscopy, we showed that samples of the ChR2-C128T mutant that were never exposed to light exist in a unique initial dark state (IDA) whose recovery was neither possible by illumination nor by thermal decay
Summary
Channelrhodopsins are light-gated ion channels of microalgae. Results: By FTIR spectroscopy, we identified three different dark and two photoswitchable light-adapted states of the ChRC128T mutant. Prolonged lifetimes of the conducting state of channelrhodopsin-2 may be achieved by mutations of crucial single amino acids, i.e. cysteine 128 Such mutants are of great scientific interest in the field of neurophysiology because they allow neurons to be switched on and off on demand (step function rhodopsins). We previously suggested that the probability of photochemical side reactions increases with the lifetime of the corresponding state [8, 10] Despite these complications the slow kinetics of step function rhodopsins offers the opportunity to study the photocycle of Cys-128 in depth because they facilitate the application of FTIR spectroscopy, which allows the observation of the reaction mechanisms of channelrhodopsins at the molecular level. We present a model of the photocycle that links and explains both spectroscopic and electrophysiological findings
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