Your search keyword '"Moukhametzianov R"' showing total 4 results

1. The structural basis for agonist and partial agonist action on a β(1)-adrenergic receptor.

Author

Warne T, Moukhametzianov R, Baker JG, Nehmé R, Edwards PC, Leslie AG, Schertler GF, and Tate CG

Subjects

Adrenergic beta-1 Receptor Agonists metabolism, Adrenergic beta-1 Receptor Antagonists metabolism, Albuterol chemistry, Albuterol metabolism, Albuterol pharmacology, Amphetamines chemistry, Amphetamines metabolism, Amphetamines pharmacology, Animals, Binding Sites, Catecholamines metabolism, Crystallography, X-Ray, Dobutamine chemistry, Dobutamine metabolism, Dobutamine pharmacology, Drug Design, Hydrogen Bonding, Hydroxyquinolines chemistry, Hydroxyquinolines metabolism, Hydroxyquinolines pharmacology, Isoproterenol chemistry, Isoproterenol metabolism, Isoproterenol pharmacology, Ligands, Models, Molecular, Protein Conformation, Protein Stability drug effects, Serine chemistry, Serine metabolism, Structure-Activity Relationship, Turkeys, Adrenergic beta-1 Receptor Agonists chemistry, Adrenergic beta-1 Receptor Agonists pharmacology, Adrenergic beta-1 Receptor Antagonists chemistry, Adrenergic beta-1 Receptor Antagonists pharmacology, Drug Partial Agonism, Receptors, Adrenergic, beta-1 chemistry, Receptors, Adrenergic, beta-1 metabolism

Abstract

β-adrenergic receptors (βARs) are G-protein-coupled receptors (GPCRs) that activate intracellular G proteins upon binding catecholamine agonist ligands such as adrenaline and noradrenaline. Synthetic ligands have been developed that either activate or inhibit βARs for the treatment of asthma, hypertension or cardiac dysfunction. These ligands are classified as either full agonists, partial agonists or antagonists, depending on whether the cellular response is similar to that of the native ligand, reduced or inhibited, respectively. However, the structural basis for these different ligand efficacies is unknown. Here we present four crystal structures of the thermostabilized turkey (Meleagris gallopavo) β(1)-adrenergic receptor (β(1)AR-m23) bound to the full agonists carmoterol and isoprenaline and the partial agonists salbutamol and dobutamine. In each case, agonist binding induces a 1 Å contraction of the catecholamine-binding pocket relative to the antagonist bound receptor. Full agonists can form hydrogen bonds with two conserved serine residues in transmembrane helix 5 (Ser(5.42) and Ser(5.46)), but partial agonists only interact with Ser(5.42) (superscripts refer to Ballesteros-Weinstein numbering). The structures provide an understanding of the pharmacological differences between different ligand classes, illuminating how GPCRs function and providing a solid foundation for the structure-based design of novel ligands with predictable efficacies.

Published

2011

2. Structure of a beta1-adrenergic G-protein-coupled receptor.

Author

Warne T, Serrano-Vega MJ, Baker JG, Moukhametzianov R, Edwards PC, Henderson R, Leslie AG, Tate CG, and Schertler GF

Subjects

Adrenergic beta-1 Receptor Agonists, Adrenergic beta-1 Receptor Antagonists, Adrenergic beta-Antagonists chemistry, Adrenergic beta-Antagonists metabolism, Amino Acid Motifs, Animals, Binding Sites, Crystallization, Crystallography, X-Ray, Ligands, Models, Molecular, Mutant Proteins chemistry, Mutant Proteins genetics, Mutant Proteins metabolism, Mutation, Pindolol analogs & derivatives, Pindolol chemistry, Pindolol metabolism, Propanolamines chemistry, Propanolamines metabolism, Protein Conformation, Receptors, Adrenergic, beta-1 metabolism, Thermodynamics, Turkeys, Receptors, Adrenergic, beta-1 chemistry

Abstract

G-protein-coupled receptors have a major role in transmembrane signalling in most eukaryotes and many are important drug targets. Here we report the 2.7 A resolution crystal structure of a beta(1)-adrenergic receptor in complex with the high-affinity antagonist cyanopindolol. The modified turkey (Meleagris gallopavo) receptor was selected to be in its antagonist conformation and its thermostability improved by earlier limited mutagenesis. The ligand-binding pocket comprises 15 side chains from amino acid residues in 4 transmembrane alpha-helices and extracellular loop 2. This loop defines the entrance of the ligand-binding pocket and is stabilized by two disulphide bonds and a sodium ion. Binding of cyanopindolol to the beta(1)-adrenergic receptor and binding of carazolol to the beta(2)-adrenergic receptor involve similar interactions. A short well-defined helix in cytoplasmic loop 2, not observed in either rhodopsin or the beta(2)-adrenergic receptor, directly interacts by means of a tyrosine with the highly conserved DRY motif at the end of helix 3 that is essential for receptor activation.

Published

2008

3. Development of the signal in sensory rhodopsin and its transfer to the cognate transducer.

Author

Moukhametzianov R, Klare JP, Efremov R, Baeken C, Göppner A, Labahn J, Engelhard M, Büldt G, and Gordeliy VI

Subjects

Biological Evolution, Crystallography, X-Ray, Cytoplasm metabolism, Halobacteriaceae chemistry, Halobacteriaceae cytology, Hydrogen Bonding, Isomerism, Models, Molecular, Protein Conformation, Halobacteriaceae metabolism, Halorhodopsins chemistry, Halorhodopsins metabolism, Light Signal Transduction physiology, Sensory Rhodopsins chemistry, Sensory Rhodopsins metabolism

Abstract

The microbial phototaxis receptor sensory rhodopsin II (NpSRII, also named phoborhodopsin) mediates the photophobic response of the haloarchaeon Natronomonas pharaonis by modulating the swimming behaviour of the bacterium. After excitation by blue-green light NpSRII triggers, by means of a tightly bound transducer protein (NpHtrII), a signal transduction chain homologous with the two-component system of eubacterial chemotaxis. Two molecules of NpSRII and two molecules of NpHtrII form a 2:2 complex in membranes as shown by electron paramagnetic resonance and X-ray structure analysis. Here we present X-ray structures of the photocycle intermediates K and late M (M2) explaining the evolution of the signal in the receptor after retinal isomerization and the transfer of the signal to the transducer in the complex. The formation of late M has been correlated with the formation of the signalling state. The observed structural rearrangements allow us to propose the following mechanism for the light-induced activation of the signalling complex. On excitation by light, retinal isomerization leads in the K state to a rearrangement of a water cluster that partly disconnects two helices of the receptor. In the transition to late M the changes in the hydrogen bond network proceed further. Thus, in late M state an altered tertiary structure establishes the signalling state of the receptor. The transducer responds to the activation of the receptor by a clockwise rotation of about 15 degrees of helix TM2 and a displacement of this helix by 0.9 A at the cytoplasmic surface.

Published

2006

4. Molecular basis of transmembrane signalling by sensory rhodopsin II-transducer complex.

Author

Gordeliy VI, Labahn J, Moukhametzianov R, Efremov R, Granzin J, Schlesinger R, Büldt G, Savopol T, Scheidig AJ, Klare JP, and Engelhard M

Subjects

Archaeal Proteins genetics, Carotenoids genetics, Crystallography, X-Ray, Escherichia coli, Models, Molecular, Natronobacterium chemistry, Protein Conformation, Recombinant Proteins chemistry, Recombinant Proteins genetics, Structure-Activity Relationship, Archaeal Proteins chemistry, Archaeal Proteins metabolism, Carotenoids chemistry, Carotenoids metabolism, Cell Membrane metabolism, Halorhodopsins, Natronobacterium metabolism, Sensory Rhodopsins, Signal Transduction

Abstract

Microbial rhodopsins, which constitute a family of seven-helix membrane proteins with retinal as a prosthetic group, are distributed throughout the Bacteria, Archaea and Eukaryota. This family of photoactive proteins uses a common structural design for two distinct functions: light-driven ion transport and phototaxis. The sensors activate a signal transduction chain similar to that of the two-component system of eubacterial chemotaxis. The link between the photoreceptor and the following cytoplasmic signal cascade is formed by a transducer molecule that binds tightly and specifically to its cognate receptor by means of two transmembrane helices (TM1 and TM2). It is thought that light excitation of sensory rhodopsin II from Natronobacterium pharaonis (SRII) in complex with its transducer (HtrII) induces an outward movement of its helix F (ref. 6), which in turn triggers a rotation of TM2 (ref. 7). It is unclear how this TM2 transition is converted into a cellular signal. Here we present the X-ray structure of the complex between N. pharaonis SRII and the receptor-binding domain of HtrII at 1.94 A resolution, which provides an atomic picture of the first signal transduction step. Our results provide evidence for a common mechanism for this process in phototaxis and chemotaxis.

Published

2002