Literature DB >> 26150415

Conserved Mode of Interaction between Yeast Bro1 Family V Domains and YP(X)nL Motif-Containing Target Proteins.

Yoko Kimura1, Mirai Tanigawa2, Junko Kawawaki3, Kenji Takagi4, Tsunehiro Mizushima4, Tatsuya Maeda2, Keiji Tanaka3.   

Abstract

Yeast Bro1 and Rim20 belong to a family of proteins which possess a common architecture of Bro1 and V domains. Alix and His domain protein tyrosine phosphatase (HD-PTP), mammalian Bro1 family proteins, bind YP(X)nL (n = 1 to 3) motifs in their target proteins through their V domains. In Alix, the Phe residue, which is located in the hydrophobic groove of the V domain, is critical for binding to the YP(X)nL motif. Although the overall sequences are not highly conserved between mammalian and yeast V domains, we show that the conserved Phe residue in the yeast Bro1 V domain is important for binding to its YP(X)nL-containing target protein, Rfu1. Furthermore, we show that Rim20 binds to its target protein Rim101 through the interaction between the V domain of Rim20 and the YPIKL motif of Rim101. The mutation of either the critical Phe residue in the Rim20 V domain or the YPIKL motif of Rim101 affected the Rim20-mediated processing of Rim101. These results suggest that the interactions between V domains and YP(X)nL motif-containing proteins are conserved from yeast to mammalian cells. Moreover, the specificities of each V domain to their target protein suggest that unidentified elements determine the binding specificity.
Copyright © 2015, American Society for Microbiology. All Rights Reserved.

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Year:  2015        PMID: 26150415      PMCID: PMC4588623          DOI: 10.1128/EC.00091-15

Source DB:  PubMed          Journal:  Eukaryot Cell        ISSN: 1535-9786


  41 in total

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2.  Human ESCRT and ALIX proteins interact with proteins of the midbody and function in cytokinesis.

Authors:  Eiji Morita; Virginie Sandrin; Hyo-Young Chung; Scott G Morham; Steven P Gygi; Christopher K Rodesch; Wesley I Sundquist
Journal:  EMBO J       Date:  2007-09-13       Impact factor: 11.598

Review 3.  The ESCRT pathway.

Authors:  William M Henne; Nicholas J Buchkovich; Scott D Emr
Journal:  Dev Cell       Date:  2011-07-19       Impact factor: 12.270

4.  Activation of the retroviral budding factor ALIX.

Authors:  Qianting Zhai; Michael B Landesman; Hyo-Young Chung; Adam Dierkers; Cy M Jeffries; Jill Trewhella; Christopher P Hill; Wesley I Sundquist
Journal:  J Virol       Date:  2011-06-29       Impact factor: 5.103

Review 5.  The signaling mechanism of ambient pH sensing and adaptation in yeast and fungi.

Authors:  Tatsuya Maeda
Journal:  FEBS J       Date:  2012-03-23       Impact factor: 5.542

6.  Structural and biochemical studies of ALIX/AIP1 and its role in retrovirus budding.

Authors:  Robert D Fisher; Hyo-Young Chung; Qianting Zhai; Howard Robinson; Wesley I Sundquist; Christopher P Hill
Journal:  Cell       Date:  2007-03-09       Impact factor: 41.582

7.  An inhibitor of a deubiquitinating enzyme regulates ubiquitin homeostasis.

Authors:  Yoko Kimura; Hideki Yashiroda; Tai Kudo; Sumiko Koitabashi; Shigeo Murata; Akira Kakizuka; Keiji Tanaka
Journal:  Cell       Date:  2009-05-01       Impact factor: 41.582

8.  A crescent-shaped ALIX dimer targets ESCRT-III CHMP4 filaments.

Authors:  Ricardo Pires; Bettina Hartlieb; Luca Signor; Guy Schoehn; Suman Lata; Manfred Roessle; Christine Moriscot; Sergei Popov; Andreas Hinz; Marc Jamin; Veronique Boyer; Remy Sadoul; Eric Forest; Dmitri I Svergun; Heinrich G Göttlinger; Winfried Weissenhorn
Journal:  Structure       Date:  2009-06-10       Impact factor: 5.006

9.  Bro1 binding to Snf7 regulates ESCRT-III membrane scission activity in yeast.

Authors:  Megan Wemmer; Ishara Azmi; Matthew West; Brian Davies; David Katzmann; Greg Odorizzi
Journal:  J Cell Biol       Date:  2011-01-24       Impact factor: 10.539

10.  ALIX binds a YPX(3)L motif of the GPCR PAR1 and mediates ubiquitin-independent ESCRT-III/MVB sorting.

Authors:  Michael R Dores; Buxin Chen; Huilan Lin; Unice J K Soh; May M Paing; William A Montagne; Timo Meerloo; JoAnn Trejo
Journal:  J Cell Biol       Date:  2012-04-30       Impact factor: 10.539
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  5 in total

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Authors:  Chun-Che Tseng; Robert C Piper; David J Katzmann
Journal:  Bioessays       Date:  2022-06-30       Impact factor: 4.653

2.  Structural Study of the HD-PTP Bro1 Domain in a Complex with the Core Region of STAM2, a Subunit of ESCRT-0.

Authors:  Juhyeon Lee; Kyoung-Jin Oh; Dasom Lee; Bo Yeon Kim; Joon Sig Choi; Bonsu Ku; Seung Jun Kim
Journal:  PLoS One       Date:  2016-02-11       Impact factor: 3.240

3.  Structural Basis for Selective Interaction between the ESCRT Regulator HD-PTP and UBAP1.

Authors:  Deepankar Gahloth; Colin Levy; Graham Heaven; Flavia Stefani; Lydia Wunderley; Paul Mould; Matthew J Cliff; Jordi Bella; Alistair J Fielding; Philip Woodman; Lydia Tabernero
Journal:  Structure       Date:  2016-11-10       Impact factor: 5.006

4.  The open architecture of HD-PTP phosphatase provides new insights into the mechanism of regulation of ESCRT function.

Authors:  Deepankar Gahloth; Graham Heaven; Thomas A Jowitt; A Paul Mould; Jordi Bella; Clair Baldock; Philip Woodman; Lydia Tabernero
Journal:  Sci Rep       Date:  2017-08-22       Impact factor: 4.379

5.  Natural Genetic Variation in Yeast Reveals That NEDD4 Is a Conserved Modifier of Mutant Polyglutamine Aggregation.

Authors:  Theodore W Peters; Christopher S Nelson; Akos A Gerencser; Kathleen J Dumas; Brandon Tavshanjian; Kyu Chul Chang; Gordon J Lithgow; Robert E Hughes
Journal:  G3 (Bethesda)       Date:  2018-11-06       Impact factor: 3.154
  5 in total

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