The differential engagement of arrestin surface charges by the various functional forms of the receptor. - Wikidata - wikimedia - TriplyDB

The differential engagement of arrestin surface charges by the various functional forms of the receptor.

The differential engagement of arrestin surface charges by the various functional forms of the receptor.

http://www.wikidata.org/entity/Q36737719

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Arrestins: ubiquitous regulators of cellular signaling pathways Analyzing the roles of multi-functional proteins in cells: The case of arrestins and GRKs Crystal Structure of Arrestin-3 Reveals the Basis of the Difference in Receptor Binding Between Two Non-visual Subtypes Crystal structure of pre-activated arrestin p44 Opposing effects of inositol hexakisphosphate on rod arrestin and arrestin2 self-association.Seven transmembrane receptors as shapeshifting proteins: the impact of allosteric modulation and functional selectivity on new drug discovery.Progressive reduction of its expression in rods reveals two pools of arrestin-1 in the outer segment with different roles in photoresponse recovery.The effect of arrestin conformation on the recruitment of c-Raf1, MEK1, and ERK1/2 activation Monomeric rhodopsin is sufficient for normal rhodopsin kinase (GRK1) phosphorylation and arrestin-1 binding Differential interaction of spin-labeled arrestin with inactive and active phosphorhodopsin.Robust self-association is a common feature of mammalian visual arrestin-1.Few residues within an extensive binding interface drive receptor interaction and determine the specificity of arrestin proteins.Identification of arrestin-3-specific residues necessary for JNK3 kinase activation A single mutation in arrestin-2 prevents ERK1/2 activation by reducing c-Raf1 binding.The functional cycle of visual arrestins in photoreceptor cells.Role of receptor-attached phosphates in binding of visual and non-visual arrestins to G protein-coupled receptors.Manipulation of very few receptor discriminator residues greatly enhances receptor specificity of non-visual arrestins Distinct loops in arrestin differentially regulate ligand binding within the GPCR opsin.Involvement of distinct arrestin-1 elements in binding to different functional forms of rhodopsin Engineering visual arrestin-1 with special functional characteristics Visual arrestin binding to microtubules involves a distinct conformational change Binding between a distal C-terminus fragment of cannabinoid receptor 1 and arrestin-2.Critical role of the central 139-loop in stability and binding selectivity of arrestin-1.Arrestin binds to different phosphorylated regions of the thyrotropin-releasing hormone receptor with distinct functional consequences.Functional map of arrestin binding to phosphorylated opsin, with and without agonist.Regulation of arrestin binding by rhodopsin phosphorylation level.How and why do GPCRs dimerize?The role of arrestin alpha-helix I in receptor binding.Custom-designed proteins as novel therapeutic tools? The case of arrestins.Synthetic biology with surgical precision: targeted reengineering of signaling proteins.Structural determinants of arrestin functions Uncovering missing pieces: duplication and deletion history of arrestins in deuterostomes.β-Arrestin biosensors reveal a rapid, receptor-dependent activation/deactivation cycle Mutations in arrestin-3 differentially affect binding to neuropeptide Y receptor subtypes Nonvisual arrestins function as simple scaffolds assembling the MKK4-JNK3α2 signaling complex Phosphorylation of the delta-opioid receptor regulates its beta-arrestins selectivity and subsequent receptor internalization and adenylyl cyclase desensitization.Arrestin mobilizes signaling proteins to the cytoskeleton and redirects their activity.A model for the solution structure of the rod arrestin tetramer.Structural evidence for the role of polar core residue Arg175 in arrestin activation.Targeting individual GPCRs with redesigned nonvisual arrestins.

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The differential engagement of arrestin surface charges by the various functional forms of the receptor.

http://www.wikidata.org/entity/Q36737719

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Susan M Hanson

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Vsevolod V Gurevich

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P2860

The 2.8 A crystal structure of visual arrestin: a model for arrestin's regulation

Crystal structure of beta-arrestin at 1.9 A: possible mechanism of receptor binding and membrane Translocation

Phosphorylated rhodopsin and heparin induce similar conformational changes in arrestin

Arresting developments in heptahelical receptor signaling and regulation.

Possible involvement of the endocannabinoid system in the actions of three clinically used drugs.

The new face of active receptor bound arrestin attracts new partners.

Light-dependent redistribution of arrestin in vertebrate rods is an energy-independent process governed by protein-protein interactions.

Helix I of beta-arrestin is involved in postendocytic trafficking but is not required for membrane translocation, receptor binding, and internalization.

Mapping the arrestin-receptor interface. Structural elements responsible for receptor specificity of arrestin proteins.

The nature of the arrestin x receptor complex determines the ultimate fate of the internalized receptor.

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3458-3462

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10.1074/JBC.M512148200

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281

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