The introduction of two microbial opsin-based tools, channelrhodopsin-2 (ChR2) and halorhodopsin (NpHR), to neuroscience has generated interest in fast, multimodal, cell type-specific neural circuit control. Here we describe a cation-conducting channelrhodopsin (VChR1) from Volvox carteri that can drive spiking at 589 nm, with excitation maximum red-shifted ~70 nm compared with ChR2. These results demonstrate fast photostimulation with yellow light, thereby defining a functionally distinct third category of microbial rhodopsin proteins.Microbial proteins that can be rapidly activated by light have been adapted for research in neuroscience, including ChR2 and NpHR, which permit millisecond-precision optical control of genetically defined cell types in intact neural tissue 1-6 . Because ChR2 is a blue light-gated cation channel and NpHR is a yellow light-driven chloride pump, the combination of these two proteins allows independent neural excitation and inhibition in the same preparation. However, there has been enormous interest in developing a hypothetical third major optogenetic tool, namely a second cation channel with an action spectrum that is substantially red-shifted relative to ChR2, to allow tests of the interaction of cell types in circuit computation or behavior.Although efforts to develop a distinct light-activated excitatory protein have been focused on molecular engineering of ChR2, another approach would be to identify previously unknown microbial channelrhodopsins using genomic tools. One ChR2-related sequence from the spheroidal alga Volvox carteri (Fig. 1a) has been described, but the absorption spectrum of the protein and the photocycle dynamics are virtually identical to those of ChR2 (refs. 7 ,8 ). Therefore, we searched the genome database from the US Department of Energy Joint Genome Institute, discovered a second Volvox ChR (VChR1) that is more related to ChR1 (ref. 9) from Chlamydomonas reinhardtii, explored its properties in heterologous expression systems and functionally tested the codon-optimized opsin gene in mammalian neurons.We expressed VChR1 in Xenopus oocytes and HEK293 cells and observed evoked photocurrents similar to those of ChR1 from Chlamydomonas 9,10 . The photocurrents were graded with light intensity and showed inactivation from a fast peak toward a reduced stationary plateau (Fig. 1b) (Fig. 1b) 9 , and currents showed an inwardly rectifying current-voltage relationship (Fig. 1c).Certain primary structural differences between VChR1 and the Chlamydomonas ChRs suggested that the properties of VChR1 would be distinct from those of the other ChRs (Fig. 1d). On the basis of electrostatic potential and quantum mechanical-molecular mechanical calculations for bacteriorhodopsin and relatives, the counterion complex of the all-trans retinal Schiff base (RSB; Fig. 1d) should be critical for color tuning 11,12 , but these residues are conserved in both ChR1 and VChR1 (blue sequence, Fig. 1d). On the other hand, calculations and mutational experiments 11,12 predict that fo...
G-protein-coupled receptors (GPCRs) transmit extracellular signals to activate intracellular heterotrimeric G proteins (Gαβγ) and arrestins. For G protein signalling, the Gα C-terminus (GαCT) binds to a cytoplasmic crevice of the receptor that opens upon activation. A consensus motif is shared among GαCT from the Gi/Gt family and the ‘finger loop’ region (ArrFL1–4) of all four arrestins. Here we present a 2.75 Å crystal structure of ArrFL-1, a peptide analogue of the finger loop of rod photoreceptor arrestin, in complex with the prototypical GPCR rhodopsin. Functional binding of ArrFL to the receptor was confirmed by ultraviolet-visible absorption spectroscopy, competitive binding assays and Fourier transform infrared spectroscopy. For both GαCT and ArrFL, binding to the receptor crevice induces a similar reverse turn structure, although significant structural differences are seen at the rim of the binding crevice. Our results reflect both the common receptor-binding interface and the divergent biological functions of G proteins and arrestins.
Background:Arrestins regulate the signaling of rhodopsin-like G protein-coupled receptors. Results: We isolated the infrared spectra of rhodopsin⅐arrestin-1 complex formation. Conclusion: Complex formation stabilizes the active receptor and is accompanied by -sheet loss. During decay, arrestin stabilizes only half of the receptor population in the active form. Significance: Our new approach extends knowledge from x-ray structures and other recent spectroscopic studies.
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