The Three-dimensional Structure of Bovine Rhodopsin Determined by Electron Cryomicroscopy

Krebs, Angelika; Edwards, Patricia C.; Villa, Claudio; Li, Jade; Schertler, Gebhard F. X.

doi:10.1074/jbc.m307995200

Cited by 42 publications

(30 citation statements)

References 53 publications

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“…Similar dimeric arrangements were found in previous structure determinations from two dimensional and three dimensional rhodopsin crystals [68,114] and rhodopsin models [115]. Based on atomic force microscopic studies [116], a model with TM4 and TM5 as interface of a physiological rhodopsin dimer was proposed [116,117,118].…”

Section: Overall Structure Of Opsinsupporting

confidence: 51%

Crystal structure of the ligand-free G-protein-coupled receptor opsin

Park

Scheerer

Hofmann

et al. 2008

Nature

858

925

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Compared with the known structure of inactive rhodopsin, opsin displays prominent structural changes in the conserved E(D)RY and NPxxY(x) 5,6 F regions and TM5-TM7. At the cytoplasmic side, TM6 is tilted outwards by 6-7 Å, whereas the helix structure of TM5 is more elongated and close to TM6. These structural changes, of which some are attributed to an active GPCR state, reorganize the empty retinal binding pocket to disclose two openings for exit and entry of retinal. The opsin structure thus sheds new light on binding of hydrophobic ligands to GPCRs, GPCR activation and signal transfer to the G protein.

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Section: Overall Structure Of Opsinsupporting

confidence: 51%

Crystal structure of the ligand-free G-protein-coupled receptor opsin

Park

Scheerer

Hofmann

et al. 2008

Nature

858

925

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“…The present study identified TMD III, TMD VI, and TMD VII as part of the ligand binding pocket, which is also the case for bioamine GPCRs (39 -41) and rhodopsin (42)(43)(44). This is further proof of a highly conserved feature among this very large family of receptors.…”

Section: Discussionmentioning

confidence: 50%

Determining the Environment of the Ligand Binding Pocket of the Human Angiotensin II Type I (hAT1) Receptor Using the Methionine Proximity Assay

Clement

Martin

Beaulieu

et al. 2005

Journal of Biological Chemistry

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The peptide hormone angiotensin II (AngII) binds to the AT 1 (angiotensin type 1) receptor within the transmembrane domains in an extended conformation, and its C-terminal residue interacts with transmembrane domain VII at Phe-293/Asn-294. The molecular environment of this binding pocket remains to be elucidated. The preferential binding of benzophenone photolabels to methionine residues in the target structure has enabled us to design an experimental approach called the methionine proximity assay, which is based on systematic mutagenesis and photolabeling to determine the molecular environment of this binding pocket. The octapeptide hormone angiotensin II (AngII) 1 (Fig. 1A) is the active component of the renin-angiotensin system. Virtually all known physiological effects of AngII are produced through the activation of the hAT 1 receptor, which belongs to the class A rhodopsin-like family of the heptahelical G proteincoupled receptor (GPCR) superfamily (1, 2). Elucidating the stereochemistry of the ligand-receptor interaction is vital for understanding the mechanism of ligand binding, GPCR activation, and, eventually, rational drug design.In the past, much effort was devoted to identifying the domains or individual residues of a given receptor that may interact with its ligand. Most experiments to address ligandreceptor interactions were performed with series of receptor mutants to identify specific residues critical to ligand binding (3-5). It is, however, speculative to deduce precise structures of ligand-receptor interactions through mutagenesis studies alone. More direct approaches have therefore been used to study ligand-receptor interactions. Among these is photoaffinity labeling, which allows covalent incorporation of the ligand within its binding site, presumably at the contact area of the photolabel in the receptor. This ligand-receptor contact can be identified by specific enzymatic or chemical digestion of the labeled receptor (6) or by mass spectrometry (7). The binding pockets within the transmembrane domains of several bioamine receptors have been identified using this kind of approach. The adenosine A 1 receptor (8) and the ␤ 2 adrenergic receptor (9, 10) are typical examples. Peptidergic receptors such as hAT 1 and hAT 2 (11, 12), neurokinin receptors (13), and several other receptors from the secretin GPCR family B (14) have been also studied using this approach. We previously identified ligandcontact points within the second extracellular loop (ECL) and the seventh transmembrane domain (TMD) of the hAT 1 receptor (12,15,16). Although photoaffinity labeling has been widely used to study peptidergic GPCR binding pockets, generally only a single contact point between a given ligand and its cognate receptor has been identified. The resulting information does not, however, induce sufficient restrictions to generate credible GPCR structures in the ligand-bound state using homology modeling.Labeling studies using benzophenone residues have identified many ligand-receptor contact points with a surpris...

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“…Molecular model of the residues proposed to be part of the structural basis for the high constitutive activity in the ghrelin receptor. A, molecular model of the ghrelin receptor built over the inactive structure of rhodopsin (60,61). The seven helical bundle is displayed without the loops as viewed from the extra-cellular side.…”

Section: Figmentioning

confidence: 99%

Common Structural Basis for Constitutive Activity of the Ghrelin Receptor Family

Holst

Holliday

Bach

et al. 2004

Journal of Biological Chemistry

311

305

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Three members of the ghrelin receptor family were characterized in parallel: the ghrelin receptor, the neurotensin receptor 2 and the orphan receptor GPR39. In transiently transfected COS-7 and human embryonic kidney 293 cells, all three receptors displayed a high degree of ligand-independent signaling activity. The structurally homologous motilin receptor served as a constitutively silent control; upon agonist stimulation, however, it signaled with a similar efficacy to the three related receptors. The constitutive activity of the ghrelin receptor and of neurotensin receptor 2 through the G q , phospholipase C pathway was ϳ50% of their maximal capacity as determined through inositol phosphate accumulation. These two receptors also showed very high constitutive activity in activation of cAMP response element-driven transcription. GPR39 displayed a clear but lower degree of constitutive activity through the inositol phosphate and cAMP response element pathways. In contrast, GPR39 signaled with the highest constitutive activity in respect of activation of serum response element-dependent transcription, in part, possibly, through G 12/13 and Rho kinase. Antibody feeding experiments demonstrated that the epitope-tagged ghrelin receptor was constitutively internalized but could be trapped at the cell surface by an inverse agonist, whereas GPR39 remained at the cell surface. Mutational analysis showed that the constitutive activity of both the ghrelin receptor and GPR39 could systematically be tuned up and down depending on the size and hydrophobicity of the side chain in position VI:16 in the context of an aromatic residue at VII:09 and a large hydrophobic residue at VII:06. It is concluded that the three ghrelin-like receptors display an unusually high degree of constitutive activity, the structural basis for which is determined by an aromatic cluster on the inner face of the extracellular ends of TMs VI and VII.

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The Three-dimensional Structure of Bovine Rhodopsin Determined by Electron Cryomicroscopy

Cited by 42 publications

References 53 publications

Crystal structure of the ligand-free G-protein-coupled receptor opsin

Crystal structure of the ligand-free G-protein-coupled receptor opsin

Determining the Environment of the Ligand Binding Pocket of the Human Angiotensin II Type I (hAT1) Receptor Using the Methionine Proximity Assay

Common Structural Basis for Constitutive Activity of the Ghrelin Receptor Family

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