Literature DB >> 28753425

Identification of Phosphorylation Codes for Arrestin Recruitment by G Protein-Coupled Receptors.

X Edward Zhou1, Yuanzheng He2, Parker W de Waal2, Xiang Gao2, Yanyong Kang2, Ned Van Eps3, Yanting Yin1, Kuntal Pal2, Devrishi Goswami4, Thomas A White5, Anton Barty5, Naomi R Latorraca6, Henry N Chapman7, Wayne L Hubbell8, Ron O Dror6, Raymond C Stevens9, Vadim Cherezov10, Vsevolod V Gurevich11, Patrick R Griffin4, Oliver P Ernst12, Karsten Melcher2, H Eric Xu13.   

Abstract

G protein-coupled receptors (GPCRs) mediate diverse signaling in part through interaction with arrestins, whose binding promotes receptor internalization and signaling through G protein-independent pathways. High-affinity arrestin binding requires receptor phosphorylation, often at the receptor's C-terminal tail. Here, we report an X-ray free electron laser (XFEL) crystal structure of the rhodopsin-arrestin complex, in which the phosphorylated C terminus of rhodopsin forms an extended intermolecular β sheet with the N-terminal β strands of arrestin. Phosphorylation was detected at rhodopsin C-terminal tail residues T336 and S338. These two phospho-residues, together with E341, form an extensive network of electrostatic interactions with three positively charged pockets in arrestin in a mode that resembles binding of the phosphorylated vasopressin-2 receptor tail to β-arrestin-1. Based on these observations, we derived and validated a set of phosphorylation codes that serve as a common mechanism for phosphorylation-dependent recruitment of arrestins by GPCRs.
Copyright © 2017 Elsevier Inc. All rights reserved.

Entities:  

Keywords:  GPCR; GRK; arrestin; biased signaling; drug discovery; membrane proteins; phosphorylation codes; rhodopsin

Mesh:

Substances:

Year:  2017        PMID: 28753425      PMCID: PMC5567868          DOI: 10.1016/j.cell.2017.07.002

Source DB:  PubMed          Journal:  Cell        ISSN: 0092-8674            Impact factor:   41.582


  63 in total

Review 1.  The structural basis of arrestin-mediated regulation of G-protein-coupled receptors.

Authors:  Vsevolod V Gurevich; Eugenia V Gurevich
Journal:  Pharmacol Ther       Date:  2006-02-03       Impact factor: 12.310

2.  Structural origin of weakly ordered nitroxide motion in spin-labeled proteins.

Authors:  Mark R Fleissner; Duilio Cascio; Wayne L Hubbell
Journal:  Protein Sci       Date:  2009-05       Impact factor: 6.725

3.  Time window expansion for HDX analysis of an intrinsically disordered protein.

Authors:  Devrishi Goswami; Srikripa Devarakonda; Michael J Chalmers; Bruce D Pascal; Bruce M Spiegelman; Patrick R Griffin
Journal:  J Am Soc Mass Spectrom       Date:  2013-07-25       Impact factor: 3.109

4.  Protein conformation ensembles monitored by HDX reveal a structural rationale for abscisic acid signaling protein affinities and activities.

Authors:  Graham M West; Bruce D Pascal; Ley-Moy Ng; Fen-Fen Soon; Karsten Melcher; H Eric Xu; Michael J Chalmers; Patrick R Griffin
Journal:  Structure       Date:  2013-01-03       Impact factor: 5.006

5.  iMOSFLM: a new graphical interface for diffraction-image processing with MOSFLM.

Authors:  T Geoff G Battye; Luke Kontogiannis; Owen Johnson; Harold R Powell; Andrew G W Leslie
Journal:  Acta Crystallogr D Biol Crystallogr       Date:  2011-03-18

6.  Regulation of arrestin binding by rhodopsin phosphorylation level.

Authors:  Sergey A Vishnivetskiy; Dayanidhi Raman; Junhua Wei; Matthew J Kennedy; James B Hurley; Vsevolod V Gurevich
Journal:  J Biol Chem       Date:  2007-09-11       Impact factor: 5.157

Review 7.  Molecular mechanism of β-arrestin-biased agonism at seven-transmembrane receptors.

Authors:  Eric Reiter; Seungkirl Ahn; Arun K Shukla; Robert J Lefkowitz
Journal:  Annu Rev Pharmacol Toxicol       Date:  2011-09-19       Impact factor: 13.820

8.  Visualization of arrestin recruitment by a G-protein-coupled receptor.

Authors:  Arun K Shukla; Gerwin H Westfield; Kunhong Xiao; Rosana I Reis; Li-Yin Huang; Prachi Tripathi-Shukla; Jiang Qian; Sheng Li; Adi Blanc; Austin N Oleskie; Anne M Dosey; Min Su; Cui-Rong Liang; Ling-Ling Gu; Jin-Ming Shan; Xin Chen; Rachel Hanna; Minjung Choi; Xiao Jie Yao; Bjoern U Klink; Alem W Kahsai; Sachdev S Sidhu; Shohei Koide; Pawel A Penczek; Anthony A Kossiakoff; Virgil L Woods; Brian K Kobilka; Georgios Skiniotis; Robert J Lefkowitz
Journal:  Nature       Date:  2014-06-22       Impact factor: 49.962

9.  Engineered hyperphosphorylation of the β2-adrenoceptor prolongs arrestin-3 binding and induces arrestin internalization.

Authors:  Diana Zindel; Adrian J Butcher; Suleiman Al-Sabah; Peter Lanzerstorfer; Julian Weghuber; Andrew B Tobin; Moritz Bünemann; Cornelius Krasel
Journal:  Mol Pharmacol       Date:  2014-11-25       Impact factor: 4.436

10.  Recent developments in CrystFEL.

Authors:  Thomas A White; Valerio Mariani; Wolfgang Brehm; Oleksandr Yefanov; Anton Barty; Kenneth R Beyerlein; Fedor Chervinskii; Lorenzo Galli; Cornelius Gati; Takanori Nakane; Alexandra Tolstikova; Keitaro Yamashita; Chun Hong Yoon; Kay Diederichs; Henry N Chapman
Journal:  J Appl Crystallogr       Date:  2016-03-29       Impact factor: 3.304
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  131 in total

Review 1.  GPCRs and Signal Transducers: Interaction Stoichiometry.

Authors:  Vsevolod V Gurevich; Eugenia V Gurevich
Journal:  Trends Pharmacol Sci       Date:  2018-05-05       Impact factor: 14.819

2.  Mechanism of β-arrestin recruitment by the μ-opioid G protein-coupled receptor.

Authors:  Amirhossein Mafi; Soo-Kyung Kim; William A Goddard
Journal:  Proc Natl Acad Sci U S A       Date:  2020-06-29       Impact factor: 11.205

3.  Conformational Sensors and Domain Swapping Reveal Structural and Functional Differences between β-Arrestin Isoforms.

Authors:  Eshan Ghosh; Hemlata Dwivedi; Mithu Baidya; Ashish Srivastava; Punita Kumari; Tomek Stepniewski; Hee Ryung Kim; Mi-Hye Lee; Jaana van Gastel; Madhu Chaturvedi; Debarati Roy; Shubhi Pandey; Jagannath Maharana; Ramon Guixà-González; Louis M Luttrell; Ka Young Chung; Somnath Dutta; Jana Selent; Arun K Shukla
Journal:  Cell Rep       Date:  2019-09-24       Impact factor: 9.423

4.  Molecular mechanism of biased signaling in a prototypical G protein-coupled receptor.

Authors:  Carl-Mikael Suomivuori; Naomi R Latorraca; Laura M Wingler; Stephan Eismann; Matthew C King; Alissa L W Kleinhenz; Meredith A Skiba; Dean P Staus; Andrew C Kruse; Robert J Lefkowitz; Ron O Dror
Journal:  Science       Date:  2020-02-21       Impact factor: 47.728

Review 5.  Plethora of functions packed into 45 kDa arrestins: biological implications and possible therapeutic strategies.

Authors:  Vsevolod V Gurevich; Eugenia V Gurevich
Journal:  Cell Mol Life Sci       Date:  2019-08-17       Impact factor: 9.261

6.  Molecular mechanism of GPCR-mediated arrestin activation.

Authors:  Naomi R Latorraca; Jason K Wang; Brian Bauer; Raphael J L Townshend; Scott A Hollingsworth; Julia E Olivieri; H Eric Xu; Martha E Sommer; Ron O Dror
Journal:  Nature       Date:  2018-05-02       Impact factor: 49.962

Review 7.  Structural biology of G protein-coupled receptors: new opportunities from XFELs and cryoEM.

Authors:  Andrii Ishchenko; Cornelius Gati; Vadim Cherezov
Journal:  Curr Opin Struct Biol       Date:  2018-03-16       Impact factor: 6.809

Review 8.  Serial Femtosecond Crystallography of G Protein-Coupled Receptors.

Authors:  Benjamin Stauch; Vadim Cherezov
Journal:  Annu Rev Biophys       Date:  2018-03-15       Impact factor: 12.981

Review 9.  The structural basis of the arrestin binding to GPCRs.

Authors:  Vsevolod V Gurevich; Eugenia V Gurevich
Journal:  Mol Cell Endocrinol       Date:  2019-01-28       Impact factor: 4.102

10.  Sphingosine 1-phosphate-regulated transcriptomes in heterogenous arterial and lymphatic endothelium of the aorta.

Authors:  Eric Engelbrecht; Michel V Levesque; Liqun He; Michael Vanlandewijck; Anja Nitzsche; Hira Niazi; Andrew Kuo; Sasha A Singh; Masanori Aikawa; Kristina Holton; Richard L Proia; Mari Kono; William T Pu; Eric Camerer; Christer Betsholtz; Timothy Hla
Journal:  Elife       Date:  2020-02-24       Impact factor: 8.140
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