Literature DB >> 33387531

An Eight Amino Acid Segment Controls Oligomerization and Preferred Conformation of the two Non-visual Arrestins.

Qiuyan Chen1, Ya Zhuo2, Pankaj Sharma1, Ivette Perez3, Derek J Francis2, Srinivas Chakravarthy4, Sergey A Vishnivetskiy3, Sandra Berndt3, Susan M Hanson3, Xuanzhi Zhan3, Evan K Brooks5, Christian Altenbach5, Wayne L Hubbell5, Candice S Klug2, T M Iverson6, Vsevolod V Gurevich7.   

Abstract

G protein coupled receptors signal through G proteins or arrestins. A long-standing mystery in the field is why vertebrates have two non-visual arrestins, arrestin-2 and arrestin-3. These isoforms are ~75% identical and 85% similar; each binds numerous receptors, and appear to have many redundant functions, as demonstrated by studies of knockout mice. We previously showed that arrestin-3 can be activated by inositol-hexakisphosphate (IP6). IP6 interacts with the receptor-binding surface of arrestin-3, induces arrestin-3 oligomerization, and this oligomer stabilizes the active conformation of arrestin-3. Here, we compared the impact of IP6 on oligomerization and conformational equilibrium of the highly homologous arrestin-2 and arrestin-3 and found that these two isoforms are regulated differently. In the presence of IP6, arrestin-2 forms "infinite" chains, where each promoter remains in the basal conformation. In contrast, full length and truncated arrestin-3 form trimers and higher-order oligomers in the presence of IP6; we showed previously that trimeric state induces arrestin-3 activation (Chen et al., 2017). Thus, in response to IP6, the two non-visual arrestins oligomerize in different ways in distinct conformations. We identified an insertion of eight residues that is conserved across arrestin-2 homologs, but absent in arrestin-3 that likely accounts for the differences in the IP6 effect. Because IP6 is ubiquitously present in cells, this suggests physiological consequences, including differences in arrestin-2/3 trafficking and JNK3 activation. The functional differences between two non-visual arrestins are in part determined by distinct modes of their oligomerization. The mode of oligomerization might regulate the function of other signaling proteins.
Copyright © 2020 Elsevier Ltd. All rights reserved.

Entities:  

Keywords:  IP(6); isoforms; oligomer; signaling protein; structure

Mesh:

Substances:

Year:  2020        PMID: 33387531      PMCID: PMC7870585          DOI: 10.1016/j.jmb.2020.166790

Source DB:  PubMed          Journal:  J Mol Biol        ISSN: 0022-2836            Impact factor:   5.469


  67 in total

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

2.  A model for the solution structure of the rod arrestin tetramer.

Authors:  Susan M Hanson; Eric S Dawson; Derek J Francis; Ned Van Eps; Candice S Klug; Wayne L Hubbell; Jens Meiler; Vsevolod V Gurevich
Journal:  Structure       Date:  2008-06       Impact factor: 5.006

3.  Mechanism of quenching of phototransduction. Binding competition between arrestin and transducin for phosphorhodopsin.

Authors:  J G Krupnick; V V Gurevich; J L Benovic
Journal:  J Biol Chem       Date:  1997-07-18       Impact factor: 5.157

4.  Ambiguity assessment of small-angle scattering curves from monodisperse systems.

Authors:  Maxim V Petoukhov; Dmitri I Svergun
Journal:  Acta Crystallogr D Biol Crystallogr       Date:  2015-04-24

5.  Conformation of receptor-bound visual arrestin.

Authors:  Miyeon Kim; Sergey A Vishnivetskiy; Ned Van Eps; Nathan S Alexander; Whitney M Cleghorn; Xuanzhi Zhan; Susan M Hanson; Takefumi Morizumi; Oliver P Ernst; Jens Meiler; Vsevolod V Gurevich; Wayne L Hubbell
Journal:  Proc Natl Acad Sci U S A       Date:  2012-10-22       Impact factor: 11.205

6.  Crystal structure of rhodopsin bound to arrestin by femtosecond X-ray laser.

Authors:  Yanyong Kang; X Edward Zhou; Xiang Gao; Yuanzheng He; Wei Liu; Andrii Ishchenko; Anton Barty; Thomas A White; Oleksandr Yefanov; Gye Won Han; Qingping Xu; Parker W de Waal; Jiyuan Ke; M H Eileen Tan; Chenghai Zhang; Arne Moeller; Graham M West; Bruce D Pascal; Ned Van Eps; Lydia N Caro; Sergey A Vishnivetskiy; Regina J Lee; Kelly M Suino-Powell; Xin Gu; Kuntal Pal; Jinming Ma; Xiaoyong Zhi; Sébastien Boutet; Garth J Williams; Marc Messerschmidt; Cornelius Gati; Nadia A Zatsepin; Dingjie Wang; Daniel James; Shibom Basu; Shatabdi Roy-Chowdhury; Chelsie E Conrad; Jesse Coe; Haiguang Liu; Stella Lisova; Christopher Kupitz; Ingo Grotjohann; Raimund Fromme; Yi Jiang; Minjia Tan; Huaiyu Yang; Jun Li; Meitian Wang; Zhong Zheng; Dianfan Li; Nicole Howe; Yingming Zhao; Jörg Standfuss; Kay Diederichs; Yuhui Dong; Clinton S Potter; Bridget Carragher; Martin Caffrey; Hualiang Jiang; Henry N Chapman; John C H Spence; Petra Fromme; Uwe Weierstall; Oliver P Ernst; Vsevolod Katritch; Vsevolod V Gurevich; Patrick R Griffin; Wayne L Hubbell; Raymond C Stevens; Vadim Cherezov; Karsten Melcher; H Eric Xu
Journal:  Nature       Date:  2015-07-22       Impact factor: 49.962

7.  Uncovering missing pieces: duplication and deletion history of arrestins in deuterostomes.

Authors:  Henrike Indrischek; Sonja J Prohaska; Vsevolod V Gurevich; Eugenia V Gurevich; Peter F Stadler
Journal:  BMC Evol Biol       Date:  2017-07-06       Impact factor: 3.260

8.  Structural basis of arrestin-3 activation and signaling.

Authors:  Qiuyan Chen; Nicole A Perry; Sergey A Vishnivetskiy; Sandra Berndt; Nathaniel C Gilbert; Ya Zhuo; Prashant K Singh; Jonas Tholen; Melanie D Ohi; Eugenia V Gurevich; Chad A Brautigam; Candice S Klug; Vsevolod V Gurevich; T M Iverson
Journal:  Nat Commun       Date:  2017-11-10       Impact factor: 14.919

9.  Structure of active β-arrestin-1 bound to a G-protein-coupled receptor phosphopeptide.

Authors:  Arun K Shukla; Aashish Manglik; Andrew C Kruse; Kunhong Xiao; Rosana I Reis; Wei-Chou Tseng; Dean P Staus; Daniel Hilger; Serdar Uysal; Li-Yin Huang; Marcin Paduch; Prachi Tripathi-Shukla; Akiko Koide; Shohei Koide; William I Weis; Anthony A Kossiakoff; Brian K Kobilka; Robert J Lefkowitz
Journal:  Nature       Date:  2013-04-21       Impact factor: 49.962

10.  BioXTAS RAW: improvements to a free open-source program for small-angle X-ray scattering data reduction and analysis.

Authors:  Jesse Bennett Hopkins; Richard E Gillilan; Soren Skou
Journal:  J Appl Crystallogr       Date:  2017-09-05       Impact factor: 3.304
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  4 in total

1.  The Two Non-Visual Arrestins Engage ERK2 Differently.

Authors:  Nicole A Perry-Hauser; Jesse B Hopkins; Ya Zhuo; Chen Zheng; Ivette Perez; Kathryn M Schultz; Sergey A Vishnivetskiy; Ali I Kaya; Pankaj Sharma; Kevin N Dalby; Ka Young Chung; Candice S Klug; Vsevolod V Gurevich; T M Iverson
Journal:  J Mol Biol       Date:  2022-01-22       Impact factor: 5.469

Review 2.  Solo vs. Chorus: Monomers and Oligomers of Arrestin Proteins.

Authors:  Vsevolod V Gurevich; Eugenia V Gurevich
Journal:  Int J Mol Sci       Date:  2022-06-29       Impact factor: 6.208

Review 3.  Structural basis of GPCR coupling to distinct signal transducers: implications for biased signaling.

Authors:  Mohammad Seyedabadi; Mehdi Gharghabi; Eugenia V Gurevich; Vsevolod V Gurevich
Journal:  Trends Biochem Sci       Date:  2022-04-05       Impact factor: 14.264

4.  GPCR-mediated β-arrestin activation deconvoluted with single-molecule precision.

Authors:  Wesley B Asher; Daniel S Terry; G Glenn A Gregorio; Alem W Kahsai; Alessandro Borgia; Bing Xie; Arnab Modak; Ying Zhu; Wonjo Jang; Alekhya Govindaraju; Li-Yin Huang; Asuka Inoue; Nevin A Lambert; Vsevolod V Gurevich; Lei Shi; Robert J Lefkowitz; Scott C Blanchard; Jonathan A Javitch
Journal:  Cell       Date:  2022-04-27       Impact factor: 66.850
  4 in total

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