A Biosensor for the Mitotic Kinase MPS1 Reveals Spatiotemporal Activity Dynamics and Regulation
Kuijt, Timo E.F.; Lambers, Maaike L.A.; Weterings, Sonja; Ponsioen, Bas; Bolhaqueiro, Ana C.F.; Staijen, Debbie H.M.; Kops, Geert J.P.L.
(2020) Current Biology, volume 30, issue 19, pp. 3862 - 3870.e6
(Article)
Abstract
Accurate chromosome segregation during cell division critically depends on error correction of chromosome-spindle interactions and the spindle assembly checkpoint (SAC) [1–3]. The kinase MPS1 is an essential regulator of both processes, ensuring full chromosome biorientation before anaphase onset [3, 4]. To understand when and where MPS1 activation occurs and how
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MPS1 signaling is modulated during mitosis, we developed MPS1sen, a sensitive and specific FRET-based biosensor for MPS1 activity. By placing MPS1sen at different subcellular locations, we show that MPS1 activity initiates in the nucleus ∼9–12 min prior to nuclear envelope breakdown (NEB) in a kinetochore-dependent manner and reaches the cytoplasm at the start of NEB. Soon after initiation, MPS1 activity increases with switch-like kinetics, peaking at completion of NEB. We further show that timing and extent of pre-NEB MPS1 activity is regulated by Aurora B and PP2A-B56. MPS1sen phosphorylation declines in prometaphase as a result of formation of kinetochore-microtubule attachments, reaching low but still detectable levels at metaphase. Finally, leveraging the sensitivity and dynamic range of MPS1sen, we show deregulated MPS1 signaling dynamics in colorectal cancer cell lines and tumor organoids with diverse genomic instability phenotypes.
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Keywords: aneuploidy, biosensor, cancer, centromere, FRET, kinase, kinetochore, mitosis, phosphatase, General Agricultural and Biological Sciences, General Biochemistry,Genetics and Molecular Biology, Journal Article
ISSN: 0960-9822
Publisher: Cell Press
Note: Funding Information: We thank M. Lampson (University of Pennsylvania) for sharing reagents and MATLAB code, and I. Cheeseman (Whitehead Institute), S. Lens (UMC Utrecht), and H. Snippert (UMC Utrecht) for sharing reagents. We thank S. Sonneveld (Hubrecht Institute) for providing MATLAB code to run analysis in batch mode. We are grateful to members of the Lens, Saurin (Dundee University) and Kops labs for fruitful discussions. The Kops lab is a member of the Oncode Institute, which is partly financed by the Dutch Cancer Society. This study was financially supported by the Netherlands Organization for Scientific Research ( NWO/ALWOP.153 ). Funding Information: We thank M. Lampson (University of Pennsylvania) for sharing reagents and MATLAB code, and I. Cheeseman (Whitehead Institute), S. Lens (UMC Utrecht), and H. Snippert (UMC Utrecht) for sharing reagents. We thank S. Sonneveld (Hubrecht Institute) for providing MATLAB code to run analysis in batch mode. We are grateful to members of the Lens, Saurin (Dundee University) and Kops labs for fruitful discussions. The Kops lab is a member of the Oncode Institute, which is partly financed by the Dutch Cancer Society. This study was financially supported by the Netherlands Organization for Scientific Research (NWO/ALWOP.153). T.E.F.K. and G.J.P.L.K. conceived the project. T.E.F.K. and G.J.P.L.K. designed all experiments. T.E.F.K. M.L.A.L. and S.W. performed and analyzed experiments. A.C.F.B. performed organoid culturing and selection. D.H.M.S. contributed to validating the first generations of MPS1sen. S.W. generated reagents used in this study. B.P. provided analysis reagent. T.E.F.K. and G.J.P.L.K. wrote the manuscript. A patent application has been filed by Stichting Oncode Institute for the technology disclosed in this publication. Publisher Copyright: © 2020 The Author(s)
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