Tetsuji Okada

Functional role of internal water molecules in rhodopsin revealed by X-ray crystallography.

Activation of G protein-coupled receptors (GPCRs) is triggered and regulated by structural rearrangement of the transmembrane heptahelical bundle containing a number of highly conserved residues. In rhodopsin, a prototypical GPCR, the helical bundle accommodates an intrinsic inverse-agonist 11-cis-retinal, which undergoes photo-isomerization to the all-trans form upon light absorption. Such a trigger by the chromophore corresponds to binding of a diffusible ligand to other GPCRs. Here we have explored the functional role of water molecules in the transmembrane region of bovine rhodopsin by using x-ray diffraction to 2.6 Å. The structural model suggests that water molecules, which were observed in the vicinity of highly conserved residues and in the retinal pocket, regulate the activity of rhodopsin-like GPCRs and spectral tuning in visual pigments, respectively. To confirm the physiological relevance of the structural findings, we conducted single-crystal microspectrophotometry on rhodopsin packed in our three-dimensional crystals and show that its spectroscopic properties are similar to those previously found by using bovine rhodopsin in suspension or membrane environment.

Local peptide movement in the photoreaction intermediate of rhodopsin

Photoactivation of the visual rhodopsin, a prototypical G protein-coupled receptor (GPCR), involves efficient conversion of the intrinsic inverse-agonist 11-cis-retinal to the all-trans agonist. This event leads to the rearrangement of the heptahelical transmembrane bundle, which is thought to be shared by hundreds of GPCRs. To examine this activation mechanism, we determined the x-ray crystallographic model of the photoreaction intermediate of rhodopsin, lumirhodopsin, which represents the conformational state having the nearly complete all-trans agonist form of the retinal. A difference electron density map clearly indicated that the distorted all-trans-retinal in the precedent intermediate bathorhodopsin relaxes by dislocation of the β-ionone ring in lumirhodopsin, along with significant peptide displacement in the middle of helix III, including approximately two helical turns. This local movement results in the breaking of the electrostatic interhelical restraints mediated by many of the conserved residues among rhodopsin-like GPCRs, with consequent acquisition of full activity.

X-ray crystallographic studies for ligand-protein interaction changes in rhodopsin

G-protein-coupled receptors constitute the largest transmembrane receptor family in human. They are generally activated on binding their specific ligands at the extracellular side of membranes. The signal carried by an agonist is then transmitted to the intracellular side through a conformational change of the receptor, which becomes competent to catalyse GDP/GTP exchange in the alpha-subunit of heterotrimeric G-protein. Since most of the G-protein-coupled receptors (rhodopsin-like subfamily) share a set of conserved amino acid residues in the transmembrane domain, it is probable that the ligand-triggered activation process involves a common mechanism of rearrangement of the hepta-helical transmembrane bundle. For understanding the nature of this event that is not yet characterized sufficiently, X-ray crystallographic studies of rhodopsin with or without light stimulation can provide valuable information. In rhodopsin, the initial cis-trans photoisomerization of retinal chromophore triggers the structural changes of transmembrane helices. This activation process has been characterized with some spectroscopically distinct photoreaction intermediates (batho, lumi, Meta I and Meta II). With recent advances in the conditions for crystallographic experiments, the diffraction limit of the rhodopsin crystals has been substantially extended. As a result, it becomes possible to detect small structural changes evoked after photoactivation under cryogenic conditions.

X-ray crystallographic analysis of 9-cis-rhodopsin, a model analogue visual pigment.

Recent progress in high‐resolution structural study of rhodopsin has been enabled by a novel selective extraction procedure with rod photoreceptor cells. In this study, we applied the method for rapid and efficient preparation of a purified analogue pigment using bovine rod outer segment membranes with 9‐cis‐retinal. After complete bleaching of the membranes and subsequent regeneration with the exogenous retinal, 9‐cis‐rhodopsin is selectively extracted from the membranes using combination of zinc and heptylthioglucoside. The solubilized sample, even with a small amount of contaminating retinal oximes, is shown to be pure enough for three‐dimensional crystallization. The X‐ray diffraction from 9‐cis‐rhodopsin crystals was examined and the electron density map at 2.9 Å resolution in the chromophore region can be fitted well with the model of 9‐cis‐retinal Schiff base.

X-ray crystallography of rhodopsin

Structural studies on retinal proteins have advanced significantly in recent years. Among the proteins whose structure has been solved by X-ray crystallography, rhodopsin is the only one from eukaryotic organisms having visual function. The structural model of rhodopsin also represents the first atomic template for a much larger superfamily of G protein-coupled receptors. Its natural abundance in vertebrate retinal rod cells and a novel single-step purification method made it possible to obtain three-dimensional crystals for X-ray diffraction study. The ground state structure has been refined so far to 2.6 Å resolution, by which the details of the hepta-helical transmembrane region are resolved including functional internal water molecules. Possible structural change upon photo-excitation is likely to involve interaction changes between retinal chromophore and the surrounding residues. Further studies with microspectroscopy and X-ray diffraction with improved crystals that diffract to 2 Å resolution will reveal a series of conformational changes represented by distinct intermediate states.