Sergey A. Vishnivetskiy scite author profile

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.,...

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Differential interaction of spin-labeled arrestin with inactive and active phosphorhodopsin

Hanson

Francis

Vishnivetskiy

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

169

290

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Arrestins regulate signaling and trafficking of G protein-coupled receptors by virtue of their preferential binding to the phosphorylated active form of the receptor. To identify sites in arrestin involved in receptor interaction, a nitroxide-containing side chain was introduced at each of 28 different positions in visual arrestin, and the dynamics of the side chain was used to monitor arrestin interaction with phosphorylated forms of its cognate receptor, rhodopsin. At physiological concentrations, visual arrestin associates with both inactive dark phosphorylated rhodopsin (P-Rh) and light-activated phosphorylated rhodopsin (P-Rh*). Residues distributed over the concave surfaces of the two arrestin domains are involved in weak interactions with both states of phosphorhodopsin, and the flexible C-terminal sequence (C-tail) of arrestin becomes dynamically disordered in both complexes. A large-scale movement of the C-tail is demonstrated by direct distance measurements using a doubly labeled arrestin with one nitroxide in the C-tail and the other in the N-domain. Despite some overlap, the molecular "footprint" of arrestin bound to P-Rh and P-Rh* is different, showing the structure of the complexes to be unique. Strong immobilizing interactions with residues in a highly flexible loop between beta-strands V and VI are only observed in complex with the activated state. This result identifies this loop as a key recognition site in the arrestin-P-Rh* complex and supports the view that flexible sequences are key elements in protein-protein interactions.

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Light-Dependent Redistribution of Arrestin in Vertebrate Rods Is an Energy-Independent Process Governed by Protein-Protein Interactions

Nair

Hanson

Méndez

et al. 2005

Neuron

162

258

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In rod photoreceptors, arrestin localizes to the outer segment (OS) in the light and to the inner segment (IS) in the dark. Here, we demonstrate that redistribution of arrestin between these compartments can proceed in ATP-depleted photoreceptors. Translocation of transducin from the IS to the OS also does not require energy, but depletion of ATP or GTP inhibits its reverse movement. A sustained presence of activated rhodopsin is required for sequestering arrestin in the OS, and the rate of arrestin relocalization to the OS is determined by the amount and the phosphorylation status of photolyzed rhodopsin. Interaction of arrestin with microtubules is increased in the dark. Mutations that enhance arrestin-microtubule binding attenuate arrestin translocation to the OS. These results indicate that the distribution of arrestin in rods is controlled by its dynamic interactions with rhodopsin in the OS and microtubules in the IS and that its movement occurs by simple diffusion.

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Crystal Structure of β-Arrestin at 1.9 Å

et al. 2001

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Based on structural analysis and mutagenesis data, we propose a previously unappreciated part in beta-arrestin's mode of action by which a cationic amphipathic helix may function as a reversible membrane anchor. This novel activation mechanism would facilitate the formation of a high-affinity complex between beta-arrestin and an activated receptor regardless of its specific subtype. Like the interaction between beta-arrestin's polar core and the phosphorylated receptor, such a general activation mechanism would contribute to beta-arrestin's versatility as a regulator of many receptors.

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Arrestin Mobilizes Signaling Proteins to the Cytoskeleton and Redirects their Activity

Hanson

Cleghorn

Francis

et al. 2007

Journal of Molecular Biology

123

229

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SummaryArrestins regulate the activity and subcellular localization of G protein-coupled receptors and other signaling molecules. Here we demonstrate that arrestins bind microtubules (MTs) in vitro and in vivo. The MT-binding site on arrestins significantly overlaps with the receptor-binding site, but the conformations of MT-bound and receptor-bound arrestin are different. Arrestins recruit ERK1/2 and the E3 ubiquitin ligase Mdm2 to microtubules in cells, similar to the arrestin-dependent mobilization of these proteins to the receptor. Arrestin-mediated sequestration of ERK to MTs reduces the level of ERK activation. In contrast, recruitment of Mdm2 to microtubules by arrestin channels Mdm2 activity toward cytoskeleton-associated proteins, dramatically increasing their ubiquitination. The mobilization of signaling molecules to microtubules is a novel biological function of arrestin proteins.

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