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Juxtaposition of Bub1 and Cdc20 on phosphorylated Mad1 during catalytic mitotic checkpoint complex assembly

Author

Listed:
  • Elyse S. Fischer

    (Cambridge Biomedical Campus)

  • Conny W. H. Yu

    (Cambridge Biomedical Campus)

  • Johannes F. Hevler

    (University of Utrecht
    University of Utrecht)

  • Stephen H. McLaughlin

    (Cambridge Biomedical Campus)

  • Sarah L. Maslen

    (Cambridge Biomedical Campus)

  • Albert J. R. Heck

    (University of Utrecht
    University of Utrecht)

  • Stefan M. V. Freund

    (Cambridge Biomedical Campus)

  • David Barford

    (Cambridge Biomedical Campus)

Abstract

In response to improper kinetochore-microtubule attachments in mitosis, the spindle assembly checkpoint (SAC) assembles the mitotic checkpoint complex (MCC) to inhibit the anaphase-promoting complex/cyclosome, thereby delaying entry into anaphase. The MCC comprises Mad2:Cdc20:BubR1:Bub3. Its assembly is catalysed by unattached kinetochores on a Mad1:Mad2 platform. Mad1-bound closed-Mad2 (C-Mad2) recruits open-Mad2 (O-Mad2) through self-dimerization. This interaction, combined with Mps1 kinase-mediated phosphorylation of Bub1 and Mad1, accelerates MCC assembly, in a process that requires O-Mad2 to C-Mad2 conversion and concomitant binding of Cdc20. How Mad1 phosphorylation catalyses MCC assembly is poorly understood. Here, we characterized Mps1 phosphorylation of Mad1 and obtained structural insights into a phosphorylation-specific Mad1:Cdc20 interaction. This interaction, together with the Mps1-phosphorylation dependent association of Bub1 and Mad1, generates a tripartite assembly of Bub1 and Cdc20 onto the C-terminal domain of Mad1 (Mad1CTD). We additionally identify flexibility of Mad1:Mad2 that suggests how the Cdc20:Mad1CTD interaction brings the Mad2-interacting motif (MIM) of Cdc20 near O-Mad2. Thus, Mps1-dependent formation of the MCC-assembly scaffold functions to position and orient Cdc20 MIM near O-Mad2, thereby catalysing formation of C-Mad2:Cdc20.

Suggested Citation

  • Elyse S. Fischer & Conny W. H. Yu & Johannes F. Hevler & Stephen H. McLaughlin & Sarah L. Maslen & Albert J. R. Heck & Stefan M. V. Freund & David Barford, 2022. "Juxtaposition of Bub1 and Cdc20 on phosphorylated Mad1 during catalytic mitotic checkpoint complex assembly," Nature Communications, Nature, vol. 13(1), pages 1-18, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-34058-2
    DOI: 10.1038/s41467-022-34058-2
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    References listed on IDEAS

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    1. Kathryn Tunyasuvunakool & Jonas Adler & Zachary Wu & Tim Green & Michal Zielinski & Augustin Žídek & Alex Bridgland & Andrew Cowie & Clemens Meyer & Agata Laydon & Sameer Velankar & Gerard J. Kleywegt, 2021. "Highly accurate protein structure prediction for the human proteome," Nature, Nature, vol. 596(7873), pages 590-596, August.
    2. Tiziana Lischetti & Gang Zhang & Garry G. Sedgwick & Victor M. Bolanos-Garcia & Jakob Nilsson, 2014. "The internal Cdc20 binding site in BubR1 facilitates both spindle assembly checkpoint signalling and silencing," Nature Communications, Nature, vol. 5(1), pages 1-12, December.
    3. John Jumper & Richard Evans & Alexander Pritzel & Tim Green & Michael Figurnov & Olaf Ronneberger & Kathryn Tunyasuvunakool & Russ Bates & Augustin Žídek & Anna Potapenko & Alex Bridgland & Clemens Me, 2021. "Highly accurate protein structure prediction with AlphaFold," Nature, Nature, vol. 596(7873), pages 583-589, August.
    4. Gang Zhang & Thomas Kruse & Blanca López-Méndez & Kathrine Beck Sylvestersen & Dimitriya H. Garvanska & Simone Schopper & Michael Lund Nielsen & Jakob Nilsson, 2017. "Bub1 positions Mad1 close to KNL1 MELT repeats to promote checkpoint signalling," Nature Communications, Nature, vol. 8(1), pages 1-12, August.
    5. Alex C. Faesen & Maria Thanasoula & Stefano Maffini & Claudia Breit & Franziska Müller & Suzan van Gerwen & Tanja Bange & Andrea Musacchio, 2017. "Basis of catalytic assembly of the mitotic checkpoint complex," Nature, Nature, vol. 542(7642), pages 498-502, February.
    6. Daisuke Izawa & Jonathon Pines, 2015. "The mitotic checkpoint complex binds a second CDC20 to inhibit active APC/C," Nature, Nature, vol. 517(7536), pages 631-634, January.
    7. William C. H. Chao & Kiran Kulkarni & Ziguo Zhang & Eric H. Kong & David Barford, 2012. "Structure of the mitotic checkpoint complex," Nature, Nature, vol. 484(7393), pages 208-213, April.
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    1. Chu Chen & Valentina Piano & Amal Alex & Simon J. Y. Han & Pim J. Huis in ’t Veld & Babhrubahan Roy & Daniel Fergle & Andrea Musacchio & Ajit P. Joglekar, 2023. "The structural flexibility of MAD1 facilitates the assembly of the Mitotic Checkpoint Complex," Nature Communications, Nature, vol. 14(1), pages 1-11, December.

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