The genes of N. pharaonis SRII and the carboxy terminal truncated transducer (1-114) were cloned into a pET27bmod expression vector 24 with a C-terminal £ 7 His tag, respectively. Proteins were expressed in Escherichia coli strain BL21 (DE3), and purified as described 25,26. After removal of imidazol by diethyl-aminoethyl chromatography, SRII-His and HtrII 114-His were mixed in a 1:1 ratio, followed by reconstitution into purple membrane (the bacteriorhodopsin containing membrane patches of H. salinarum) lipids 7 (protein to lipid ratio 1:35). After filtration, the reconstituted proteins were pelleted by centrifugation at 100,000g. For resolubilization, the samples were resuspended in a buffer containing 2% n-octyl-b-D-glucopyranoside and shaken for 16 h at 4 8C in the dark. The resolubilized complex was isolated by centrifugation at 100,000g. Crystallization, structure determination and refinement We added the solubilized complex in crystallization buffer (150 mM NaCl, 25 mM Na/KPi, pH 5.1, 0.8% n-octyl-b-D-glucopyranoside) to the lipidic phase, formed from monovaccenin (Nu-Chek Prep). Precipitant was 1 M salt Na/KPi, pH 5.6. Crystals were grown at 22 8C. X-ray diffraction data were collected at beamline ID14-1 of the European Synchrotron Radiation Facility (ESRF), Grenoble, France, using a Quantum ADSC Q4R CCD (charge-coupled device) detector. Data were integrated using MOSFILM 27 and SCALA 28. Molecular replacement using MOLREP 28 to phase a polyalanine model (from Protein Data Bank accession number 1JGJ (ref. 12)) gave a unique solution (R ¼ 0.568, correlation coefficient C ¼ 0.357) at 2.9 A ˚. After inserting side chains for SRII, the helices of HtrII were found (R ¼ 0.329, C ¼ 0.711). Simulated annealing, positional refinement and temperature factor refinement were performed in CNS 29 ; model rebuilding was carried out in O 30 (Table 1).
The transport of protons across membranes is an important process in cellular bioenergetics. The light-driven proton pump bacteriorhodopsin is the best-characterized protein providing this function. Photon energy is absorbed by the chromophore retinal, covalently bound to Lys 216 via a protonated Schiff base. The light-induced all-trans to 13-cis isomerization of the retinal results in deprotonation of the Schiff base followed by alterations in protonatable groups within bacteriorhodopsin. The changed force field induces changes, even in the tertiary structure, which are necessary for proton pumping. The recent report of a high-resolution X-ray crystal structure for the late M intermediate of a mutant bacteriorhopsin (with Asp 96-->Asn) displays the structure of a proton pathway highly disturbed by the mutation. To observe an unperturbed proton pathway, we determined the structure of the late M intermediate of wild-type bacteriorhodopsin (2.25 A resolution). The cytoplasmic side of our M2 structure shows a water net that allows proton transfer from the proton donor group Asp 96 towards the Schiff base. An enlarged cavity system above Asp 96 is observed, which facilitates the de- and reprotonation of this group by fluctuating water molecules in the last part of the cycle.
Recently, the first known light-driven sodium pumps, from the microbial rhodopsin family, were discovered. We have solved the structure of one of them, Krokinobacter eikastus rhodopsin 2 (KR2), in the monomeric blue state and in two pentameric red states, at resolutions of 1.45 Å and 2.2 and 2.8 Å, respectively. The structures reveal the ion-translocation pathway and show that the sodium ion is bound outside the protein at the oligomerization interface, that the ion-release cavity is capped by a unique N-terminal α-helix and that the ion-uptake cavity is unexpectedly large and open to the surface. Obstruction of the cavity with the mutation G263F imparts KR2 with the ability to pump potassium. These results pave the way for the understanding and rational design of cation pumps with new specific properties valuable for optogenetics.
The light-gated ion channel channelrhodopsin 2 (ChR2) from is a major optogenetic tool. Photon absorption starts a well-characterized photocycle, but the structural basis for the regulation of channel opening remains unclear. We present high-resolution structures of ChR2 and the C128T mutant, which has a markedly increased open-state lifetime. The structure reveals two cavities on the intracellular side and two cavities on the extracellular side. They are connected by extended hydrogen-bonding networks involving water molecules and side-chain residues. Central is the retinal Schiff base that controls and synchronizes three gates that separate the cavities. Separate from this network is the DC gate that comprises a water-mediated bond between C128 and D156 and interacts directly with the retinal Schiff base. Comparison with the C128T structure reveals a direct connection of the DC gate to the central gate and suggests how the gating mechanism is affected by subtle tuning of the Schiff base's interactions.
Purple membranes adsorbed to mica were imaged in buffer solution using the atomic force microscope. The hexagonal diffraction patterns of topographs from the cytoplasmic and the extracellular surface showed a resolution of 0.7 and 1.2 nm, respectively. On the cytoplasmic surface, individual bacteriorhodopsin molecules consistently exhibited a distinct substructure. Depending on the pH value of the buffer solution, the height of the purple membranes decreased from 5.6 nm (pH 10.5) to 5.1 nm (pH 4). The results are discussed with respect to the structure determined by cryo-electron microscopy.
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