Mechanisms of photoprotection and nonphotochemical quenching in pea light-harvesting complex at 2.5 Å resolution
The plant light-harvesting complex of photosystem II (LHC-II) collects and transmits solar energy for photosynthesis in chloroplast membranes and has essential roles in regulation of photosynthesis and in photoprotection. The 2.5 Å structure of pea LHC-II determined by X-ray crystallography of stacked two-dimensional crystals shows how membranes interact to form chloroplast grana, and reveals the mutual arrangement of 42 chlorophylls a and b, 12 carotenoids and six lipids in the LHC-II trimer. Spectral assignment of individual chlorophylls indicates the flow of energy in the complex and the mechanism of photoprotection in two close chlorophyll a-lutein pairs. We propose a simple mechanism for the xanthophyllrelated, slow component of nonphotochemical quenching in LHC-II, by which excess energy is transferred to a zeaxanthin replacing violaxanthin in its binding site, and dissipated as heat. Our structure shows the complex in a quenched state, which may be relevant for the rapid, pH-induced component of nonphotochemical quenching. The EMBO Journal (2005) 24, 919-928.
G protein-coupled receptors (GPCRs) signal primarily through G proteins or arrestins. Arrestin binding to GPCRs blocks G protein interaction and redirects signaling to numerous G proteinindependent pathways. Here we report the crystal structure of a constitutively active form of human rhodopsin bound to a pre-activated form of the mouse visual arrestin, determined by serial femtosecond X-ray laser crystallography. Together with extensive biochemical and mutagenesis data, the structure reveals an overall architecture of the rhodopsin-arrestin assembly, in which rhodopsin uses distinct structural elements, including TM7 and Helix 8 to recruit arrestin. Correspondingly, arrestin adopts the pre-activated conformation, with a ~20° rotation between the Users may view, print, copy, and download text and data-mine the content in such documents, for the purposes of academic research, subject always to the full Conditions of use:http://www.nature.com/authors/editorial_policies/license.html#terms § Correspondence to H. Eric Xu: Eric.Xu@vai.org. * These authors contributed equally.Contributions: Y.K. initiated the project, developed the expression and purification methods for rhodopsin-arrestin complex, and bulk-purified expression constructs and proteins used in LCP crystallization for the SFX method; X.E.Z. collected the synchrotron data, helped with the SFX data collection, processed the data, and solved the structures; X.G. expressed and purified rhodopsinarrestin complexes, characterized their binding and thermal stability, discovered the initial crystallization conditions with 9.7 MAG, prepared most crystals for synchrotron data collection, prepared all crystals for the final data collection by SFX, helped with SFX data collection, and established the initial cross-linking method for the rhodopsin-arrestin complex; Y.H. designed and performed Tango assays and disulfide bond cross-linking experiments; C.Z. developed the mammalian expression methods; P.W.dW helped with XFEL data processing and performed computational experiments; J.K., M.H.E.T., K. M. S-P., K. P., J. M., Y.J., X.Y.Z., and Q.C. performed cell culture, mutagenesis, protein purification, rhodopsin-arrestin binding experiments; W.L. and A.I. grew crystals and collected synchrotron data at APS and SFX data at LCLS, G.W.H. and Q.X. determined and validated the structure. Z.Z. and V.K. constructed the full model, the phosphorylated rhodopsin-arrestin model, and help writing the paper; D.W., S.L., D.J., C.K., Sh.B., and N.A. Z. helped with XFEL data collection and initial data analysis; S.B., M.M., and G.J.W. set up the XFEL experiment, performed the data collection, and commented on the paper. A.B., T.W., C.G., O.Y., and H.C. helped with XFEL data collection and data analysis, processed the data and helped with structure validation. G.M. W., B.P., and P.G. performed HDX experiments and helped with manuscript writing. J.L. helped initiate this collaborative project and with writing the paper. M.W. collected the 7.7 Å dataset at Swiss Light Source. A.M.,...
G protein-coupled receptors (GPCRs) comprise the largest family of membrane proteins in the human genome and mediate cellular responses to an extensive array of hormones, neurotransmitters, and sensory stimuli. While some crystal structures have been determined for GPCRs, most are for modified forms, showing little basal activity, and are bound to inverse agonists or antagonists1. Consequently, these structures correspond to receptors in their inactive states. The visual pigment rhodopsin is the only GPCR for which structures exist that are thought to be in the active state2,3. However, these structures are for the apoprotein or opsin form that does not contain the agonist all-trans retinal. We present here a crystal structure for the constitutively active rhodopsin mutant E113Q4-6 in complex with a peptide derived from the C-terminus of the G protein transducin (the GαCT peptide). Importantly, the protein appears to be in an active conformation, and retinal is retained in the binding pocket after photoactivation. Comparison with the structure of ground state rhodopsin7 suggests how translocation of the retinal β-ionone ring leads to a rotational tilt of transmembrane helix 6 (TM6), the critical conformational change upon activation8. A key feature of this conformational change is a reorganization of water mediated hydrogen-bonding networks between the retinal-binding pocket and three of the most conserved GPCR sequence motifs. For the first time we thus show how an agonist ligand can activate its GPCR.
Bacteriorhodopsin (bR) is a light-driven proton pump and a model membrane transport protein. We used time-resolved serial femtosecond crystallography at an x-ray free electron laser to visualize conformational changes in bR from nanoseconds to milliseconds following photoactivation. An initially twisted retinal chromophore displaces a conserved tryptophan residue of transmembrane helix F on the cytoplasmic side of the protein while dislodging a key water molecule on the extracellular side. The resulting cascade of structural changes throughout the protein shows how motions are choreographed as bR transports protons uphill against a transmembrane concentration gradient.
Ultrafast isomerization of retinal is the primary step in photoresponsive biological functions including vision in humans and ion transport across bacterial membranes. We used an x-ray laser to study the subpicosecond structural dynamics of retinal isomerization in the light-driven proton pump bacteriorhodopsin. A series of structural snapshots with near-atomic spatial resolution and temporal resolution in the femtosecond regime show how the excited all-trans retinal samples conformational states within the protein binding pocket before passing through a twisted geometry and emerging in the 13-cis conformation. Our findings suggest ultrafast collective motions of aspartic acid residues and functional water molecules in the proximity of the retinal Schiff base as a key facet of this stereoselective and efficient photochemical reaction.
G protein-coupled receptors (GPCR) are seven transmembrane helix proteins that couple binding of extracellular ligands to conformational changes and activation of intracellular G proteins, GPCR kinases, and arrestins. Constitutively active mutants are ubiquitously found among GPCRs and increase the inherent basal activity of the receptor, which often correlates with a pathological outcome. Here, we have used the M257Y 6.40 constitutively active mutant of the photoreceptor rhodopsin in combination with the specific binding of a C-terminal fragment from the G protein alpha subunit (GαCT) to trap a light activated state for crystallization. The structure of the M257Y/GαCT complex contains the agonist all-trans-retinal covalently bound to the native binding pocket and resembles the G protein binding metarhodopsin-II conformation obtained by the natural activation mechanism; i.e., illumination of the prebound chromophore 11-cis-retinal. The structure further suggests a molecular basis for the constitutive activity of 6.40 substitutions and the strong effect of the introduced tyrosine based on specific interactions with Y223 5.58 in helix 5, Y306 7.53 of the NPxxY motif and R135 3.50 of the E(D)RY motif, highly conserved residues of the G protein binding site.constitutive activity | GPCRs | light-activated | rhodopsin T he more than 800 G protein-coupled receptors (GPCRs) in a typical eukaryotic genome allow signaling between cells and tissues and provide an important link to our environment as the principal receptors for our senses of taste, smell, and vision. Rhodopsin, the dim-light sensor in rod photoreceptor cells, is the prototypical receptor to study the molecular mechanisms of GPCR activation. This is due mainly to a wealth of biophysical and spectroscopic methods that take advantage of the covalently bound chromophore retinal. The possibility to purify rhodopsin directly from its native membrane furthermore facilitated its crystallization and structure determination. Comparison of structures with spectroscopic and biochemical data allowed the accurate attribution to specific states and to track the sequence of events during activation (1). This unique framework includes structures of the ground state from native (2, 3) and thermostabilized recombinant protein (4), several metastable intermediates (5, 6) with bound all-trans-retinal and an activated form of the apoprotein opsin (7). Opsin has also been solved in complex with a peptide resembling the C-terminus of the G protein alpha subunit (GαCT), which provided the first molecular insights into how the G protein binds the active receptor (8). Recently, active state structures that contain the retinal agonist have been solved using two different approaches. In one, the mutation E113Q 3.28 (9) was incorporated into rhodopsin to neutralize the counterion of the retinal Schiff base (10) preventing dissociation of retinal. In the other, opsin crystals were grown and then back-soaked with all-trans-retinal (11). Both structures share many features that are expecte...
Light-driven sodium pumps actively transport small cations across cellular membranes 1 .They are used by microbes to convert light into membrane potential and have become useful optogenetic tools with applications in neuroscience. While resting state structures of the prototypical sodium pump Krokinobacter eikastus rhodopsin 2 (KR2) have been solved 2,3 , it is unclear how structural alterations over time allow sodium translocation against a concentration gradient. Using the Swiss X-ray Free Electron Laser 4 , we have collected serial crystallographic data at ten pump-probe delays from femtoseconds to milliseconds. Highresolution structural snapshots throughout the KR2 photocycle show how retinal isomerization is completed on the femtosecond timescale and changes the local structure of the binding pocket in the early nanoseconds. Subsequent rearrangements and deprotonation of the retinal Schiff base open an electrostatic gate in microseconds. Structural and spectroscopic data in combination with quantum chemical calculations indicate transient binding of a sodium ion close to the retinal within one millisecond. In the last structural intermediate at 20 ms after activation, we identified a potential second sodium binding site close to the extracellular exit. These results provide direct molecular insight into the dynamics of active cation transport across biological membranes.
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