DISTORTED STRUCTURE OF THE RETINAL CHROMOPHORE IN BACTERIORHODOPSIN RESOLVED BY H-2-NMR

Structural details about the geometry of the retinal chromophore in the binding pocket of bacteriorhodopsin are revealed by measuring the orientations of its individual methyl groups. Solid-state H-2-NMR measurements were performed on macroscopically oriented samples of purple membrane patches, containing retinal specifically deuterium-labeled at one of the three methyl groups along the polyene chain (C-18, C-19, C-20). The deuterium quadrupole splitting of each ''zero-tilt'' spectrum is used to calculate the orientation of the corresponding C-CD3 bond vector with respect to the membrane normal; however, two possible solutions may arise. These ambiguities in angle could be resolved by recording a tilt series of spectra at different sample inclinations to the magnetic field and analyzing the resulting complex line shapes with the aid of computer simulations. The angles for the C-18, C-19, and C-20 group are found to be 37 +/- 1 degrees, 40 +/- 1 degrees, and 32 +/- 1 degrees, respectively. These highly accurate values imply that the polyene chain of the retinal chromophore is not straight but rather has an in-plane curvature and possibly an out-of-plane twist. Together with the angles of the remaining methyl groups on the cyclohexene ring that have been measured previously, an overall picture has thus emerged of the intramolecular conformation and the three-dimensional orientation of retinal within bacteriorhodopsin. The deduced geometry confirms and refines the known structural information on the chromophore, suggesting that this H-2-NMR strategy may serve as a valuable tool for other membrane proteins.