Literature DB >> 29872229

Molecular mechanism of modulating arrestin conformation by GPCR phosphorylation.

Andrija Sente1, Raphael Peer2, Ashish Srivastava3, Mithu Baidya3, Arthur M Lesk2,4, Santhanam Balaji2, Arun K Shukla3, M Madan Babu5, Tilman Flock6,7,8.   

Abstract

Arrestins regulate the signaling of ligand-activated, phosphorylated G-protein-coupled receptors (GPCRs). Different patterns of receptor phosphorylation (phosphorylation barcode) can modulate arrestin conformations, resulting in distinct functional outcomes (for example, desensitization, internalization, and downstream signaling). However, the mechanism of arrestin activation and how distinct receptor phosphorylation patterns could induce different conformational changes on arrestin are not fully understood. We analyzed how each arrestin amino acid contributes to its different conformational states. We identified a conserved structural motif that restricts the mobility of the arrestin finger loop in the inactive state and appears to be regulated by receptor phosphorylation. Distal and proximal receptor phosphorylation sites appear to selectively engage with distinct arrestin structural motifs (that is, micro-locks) to induce different arrestin conformations. These observations suggest a model in which different phosphorylation patterns of the GPCR C terminus can combinatorially modulate the conformation of the finger loop and other phosphorylation-sensitive structural elements to drive distinct arrestin conformation and functional outcomes.

Entities:  

Mesh:

Substances:

Year:  2018        PMID: 29872229      PMCID: PMC6101189          DOI: 10.1038/s41594-018-0071-3

Source DB:  PubMed          Journal:  Nat Struct Mol Biol        ISSN: 1545-9985            Impact factor:   15.369


  59 in total

1.  Scaffolding functions of arrestin-2 revealed by crystal structure and mutagenesis.

Authors:  Shawn K Milano; Helen C Pace; You-Me Kim; Charles Brenner; Jeffrey L Benovic
Journal:  Biochemistry       Date:  2002-03-12       Impact factor: 3.162

Review 2.  The molecular acrobatics of arrestin activation.

Authors:  Vsevolod V Gurevich; Eugenia V Gurevich
Journal:  Trends Pharmacol Sci       Date:  2004-02       Impact factor: 14.819

3.  Crystal structure of p44, a constitutively active splice variant of visual arrestin.

Authors:  Joachim Granzin; Anneliese Cousin; Moritz Weirauch; Ramona Schlesinger; Georg Büldt; Renu Batra-Safferling
Journal:  J Mol Biol       Date:  2012-01-27       Impact factor: 5.469

4.  Nonvisual arrestin oligomerization and cellular localization are regulated by inositol hexakisphosphate binding.

Authors:  Shawn K Milano; You-Me Kim; Frank P Stefano; Jeffrey L Benovic; Charles Brenner
Journal:  J Biol Chem       Date:  2006-01-26       Impact factor: 5.157

Review 5.  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

Review 6.  Fuzziness enables context dependence of protein interactions.

Authors:  Marton Miskei; Andrea Gregus; Rashmi Sharma; Norbert Duro; Fruzsina Zsolyomi; Monika Fuxreiter
Journal:  FEBS Lett       Date:  2017-08-20       Impact factor: 4.124

7.  The effect of phosphorylation on arrestin-rhodopsin interaction in the squid visual system.

Authors:  Kelly A Robinson; Wei-Lin Ou; Xinyu Guan; Kim S Sugamori; Abhishek Bandyopadhyay; Oliver P Ernst; Jane Mitchell
Journal:  J Neurochem       Date:  2015-10-28       Impact factor: 5.372

8.  HMMER web server: 2015 update.

Authors:  Robert D Finn; Jody Clements; William Arndt; Benjamin L Miller; Travis J Wheeler; Fabian Schreiber; Alex Bateman; Sean R Eddy
Journal:  Nucleic Acids Res       Date:  2015-05-05       Impact factor: 16.971

9.  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

10.  Intrinsically disordered segments affect protein half-life in the cell and during evolution.

Authors:  Robin van der Lee; Benjamin Lang; Kai Kruse; Jörg Gsponer; Natalia Sánchez de Groot; Martijn A Huynen; Andreas Matouschek; Monika Fuxreiter; M Madan Babu
Journal:  Cell Rep       Date:  2014-09-15       Impact factor: 9.423
View more
  32 in total

1.  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

2.  β-Arrestin2 expressed in mast cells regulates ciprofloxacin-induced pseudoallergy and IgE-mediated anaphylaxis.

Authors:  Saptarshi Roy; Kshitij Gupta; Anirban Ganguly; Hydar Ali
Journal:  J Allergy Clin Immunol       Date:  2019-05-09       Impact factor: 10.793

Review 3.  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

4.  A non-GPCR-binding partner interacts with a novel surface on β-arrestin1 to mediate GPCR signaling.

Authors:  Ya Zhuo; Vsevolod V Gurevich; Sergey A Vishnivetskiy; Candice S Klug; Adriano Marchese
Journal:  J Biol Chem       Date:  2020-08-04       Impact factor: 5.157

5.  A New Paroxetine-Based GRK2 Inhibitor Reduces Internalization of the μ-Opioid Receptor.

Authors:  Renee A Bouley; Zara Y Weinberg; Helen V Waldschmidt; Yu-Chen Yen; Scott D Larsen; Manojkumar A Puthenveedu; John J G Tesmer
Journal:  Mol Pharmacol       Date:  2020-03-31       Impact factor: 4.436

6.  The finger loop as an activation sensor in arrestin.

Authors:  Sergey A Vishnivetskiy; Elizabeth K Huh; Eugenia V Gurevich; Vsevolod V Gurevich
Journal:  J Neurochem       Date:  2020-11-27       Impact factor: 5.372

7.  Crystal Structure of β-Arrestin 2 in Complex with CXCR7 Phosphopeptide.

Authors:  Kyungjin Min; Hye-Jin Yoon; Ji Young Park; Mithu Baidya; Hemlata Dwivedi-Agnihotri; Jagannath Maharana; Madhu Chaturvedi; Ka Young Chung; Arun K Shukla; Hyung Ho Lee
Journal:  Structure       Date:  2020-06-23       Impact factor: 5.006

8.  Phosphorylation-dependent subfunctionalization of the calcium-dependent protein kinase CPK28.

Authors:  Melissa Bredow; Kyle W Bender; Alexandra Johnson Dingee; Danalyn R Holmes; Alysha Thomson; Danielle Ciren; Cailun A S Tanney; Katherine E Dunning; Marco Trujillo; Steven C Huber; Jacqueline Monaghan
Journal:  Proc Natl Acad Sci U S A       Date:  2021-05-11       Impact factor: 11.205

9.  Site-directed labeling of β-arrestin with monobromobimane for measuring their interaction with G protein-coupled receptors.

Authors:  Ashish Srivastava; Mithu Baidya; Hemlata Dwivedi-Agnihotri; Arun K Shukla
Journal:  Methods Enzymol       Date:  2019-12-05       Impact factor: 1.600

10.  Structure and function of β-arrestins, their emerging role in breast cancer, and potential opportunities for therapeutic manipulation.

Authors:  Arun K Shukla; Hemlata Dwivedi-Agnihotri
Journal:  Adv Cancer Res       Date:  2020-02-05       Impact factor: 6.242
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.