Project description:Mitotic exit is an important part of the cell cycle that requires coordination of many chromatin and cytoskeleton remodelling events to successfully complete cell division and maintain cell identity. Protein de-phosphorylation is a key step in directing mitotic exit and protein phosphatase 1 (PP1) is essential to this process. However, the specific contribution of its numerous targeting subunits is still unknown. Here we have investigated the function of three chromatin-associated PP1 targeting subunits in exiting mitosis: Repo-Man, Ki-67 and PNUTS. We have generated endogenously tagged, auxin-degradable alleles for each subunit and used a multi-omic approach to address their specific contribution to transcription resumption, chromatin accessibility and protein phosphorylation at the transition from mitosis to G1. This approach has identified their distinct role in mitotic exit, provided unique datasets for the cell cycle community, and highlighted specific and novel functions for Ki-67 and Repo-Man in genome stability and organisation.

Project description:Mitotic exit is an important part of the cell cycle that requires coordination of many chromatin and cytoskeleton remodelling events to successfully complete cell division and maintain cell identity. Protein de-phosphorylation is a key step in directing mitotic exit and protein phosphatase 1 (PP1) is essential to this process. However, the specific contribution of its numerous targeting subunits is still unknown. Here we have investigated the function of three chromatin-associated PP1 targeting subunits in exiting mitosis: Repo-Man, Ki-67 and PNUTS. We have generated endogenously tagged, auxin-degradable alleles for each subunit and used a multi-omic approach to address their specific contribution to transcription resumption, chromatin accessibility and protein phosphorylation at the transition from mitosis to G1. This approach has identified their distinct role in mitotic exit, provided unique datasets for the cell cycle community, and highlighted specific and novel functions for Ki-67 and Repo-Man in genome stability and organisation.

Project description:Ki-67 molecular functions and properties have remained quite obscure for a long time, despite its importance as a major proliferation marker in clinic. Only recently it has been shown that Ki-67 has a major role in the formation of the mitotic chromosome periphery compartment, and it is a protein phosphatase 1 (PP1) binding protein. Understanding Ki-67 functions at different stages of the cell cycle has been so far hindered by the fact that the different phenotypes observed in cells upon Ki-67 depletion could be the outcome of secondary effects. Here, by using Auxin-inducible-degron (AID) system, we show that Ki-67 degradation at the G1/S boundary causes the disassembly of the replication machinery and leads to DNA damage. This triggers the interferon response and causes replication delay. Our results support the model whereby Ki-67 contributes to replication forks protection, and it is important for timely DNA replication and genome maintenance.

Project description:Mitotic exit requires extensive dephosphorylation of Ser/Thr residues by the PP1 and PP2A-B55 protein phosphatases in human cells. Several aspects of this are poorly understood including specific substrates and determinants of phosphatase specificity. Here we develop a novel in vitro assay, MRBLE-dephos, that allows multiplexing of dephosphorylation reactions to determine phosphatase specificity. Using MRBLE-dephos, we establish amino acid preferences of the residues surrounding the phosphorylation site for PP1 and PP2A-B55, which reveals common and unique preferences for the two phosphatases. We use specific inhibition of PP1 and PP2A-B55 in mitotic exit lysates coupled with quantitative phosphoproteomics to identify more than 2000 regulated phosphorylation sites and integrate this with mitotic interactomes to obtain a comprehensive map of mitotic dephosphorylation events. Importantly, the sites dephosphorylated during mitotic exit reveal key signatures that are consistent with the MRBLE-dephos results. We use these insights to specifically alter INCENP dephosphorylation kinetics at mitotic exit resulting in defective cytokinesis underscoring the biological relevance of our determined specificity principles. Finally, we provide a comprehensive characterization of PP1 binding motifs and show how these can shape dephosphorylation and how PP1 primes its own association with these motifs at mitotic exit. Collectively we provide a framework for understanding mitotic exit regulation by dephosphorylation and novel approaches to dissect protein phosphatase specificity.

Project description:Meiosis creates haploid gametes through two sequential M phases. While many studies have focused on meiosis I, the molecular events which drive and define meiosis II are largely unknown. Here, we report a novel cell synchronization strategy which allows for collection of yeast cells arrested at metaphase I or metaphase II, enabling better characterisation of meiosis II events. The method relies on chemically-inducible dimerization of ectopic copies of spindle assembly checkpoint (SAC) proteins Mps1 and Spc105. Using this synthetic SAC (SynSAC) approach, we found that the SAC response is weaker in metaphase I compared to metaphase II and that the PP1 binding site within Spc105 contributes to restraining the MI SAC response. Furthermore, we demonstrate the utility of the SynSAC approach by analysing the composition and phosphorylation of kinetochores from metaphase I and metaphase II. This revealed an increase in the abundance of outer kinetochore proteins in meiotic metaphase I and reduced phosphorylation on metaphase II kinetochore proteins. Overall, we present the SynSAC method as a valuable tool for analysis of both meiotic metaphases.

Project description:Differential contribution of the chromatin-associated PP1 binding proteins PNUTS, Repo-Man and Ki-67 to mitotic exit and G1 re-establishment.

Project description:Differential contribution of the chromatin-associated PP1 binding proteins PNUTS, Repo-Man and Ki-67 to mitotic exit and G1 re-establishment.

Project description:Differential contribution of the chromatin-associated PP1 binding proteins PNUTS, Repo-Man and Ki-67 to mitotic exit and G1 re-establishment.

Project description:Ki-67 is highly expressed in proliferating cells, characteristic that made the protein a very important marker widely used in the clinic. However, its molecular functions and properties have remained quite obscure for a long time. Only recently important discoveries have shed some light on Ki-67 function and shown that Ki-67 has a major role in the formation of mitotic chromosome periphery compartment, it is associated with protein phosphatase one (PP1) and regulates chromatin structure in both interphase and mitosis. However, it is still difficult to understand the specific molecular function of this protein since the different phenotypes could be the outcome of secondary effects. In fact, the studies so far conducted have used either RNAi or knock-out cells: the former could lead to phenotypes which are the sum of a cascade of complex events while the latter could be the outcome of compensatory mechanisms taking place. To address these problems, we have generated a cell line system for the rapid manipulation of Ki-67 by introducing an Auxin-inducible-degron (AID) tag in both alleles of the endogenous Ki-67 gene in HCT116 cells. This AID system allows rapid protein depletion by the addition of Auxin.

Project description:Background:HuR/ELAV1, a ubiquitous RNA-binding protein, belongs to the RNA-binding protein family and is crucial for stabilizing and regulating the translation of various mRNA targets, influencing gene expression. Elevated HuR levels are associated with multiple disorders, including cancer and neurodegenerative diseases. Despite the identification of small molecule inhibitors targeting HuR, their detailed characterization remains limited. Recently, Eltrombopag, an FDA-approved drug for immune thrombocytopenic purpura and chemotherapy-induced thrombocytopenia, emerged as a potential HuR inhibitor. However, the specific molecular pathways influenced by both HuR and Eltrombopag are not fully understood. Results:Our study demonstrates that Eltrombopag operates via HuR inhibition, affecting gene expression regulation at the posttranscriptional level. We show that both HuR knockout and Eltrombopag treatment modulate iron metabolism by decreasing ferritin heavy chain (FTH1) and light chain (FTL) synthesis while increasing the expression of Iron-regulatory protein 2 (IRP2), a key regulator of ferritin translation. Additionally, HuR inhibition reduces the levels of Glycoprotein Hormones, Alpha Polypeptide (CGA), a marker associated with hormone-induced tumors, suggesting a potential use of Eltrombopag in treatment of cancers overexpressing CGA. We observed that the main of control is manifested at the level of translation inhibition, with proteosome-mediated regulation also playing an important role.Conclusions:These findings uncover novel posttranscriptional mechanisms governed by HuR and its inhibitor, elucidating pathways relevant to HuR-mediated regulation and molecular therapies aimed at targeting this protein. Project financed under DIOSCURI, a program initiated by the Max Planck Society, jointly managed with the National Science Centre in Poland, and mutually funded by Polish Ministry of Science and Higher Education and German Federal Ministry of Education and Research [2019/02/H/NZ1/00002 to G.M.]. The project was co-financed Polish National Agency for Academic Exchange within Polish Returns Programme [PPN/PPO/2020/1/00006/U/00001] as well as National Science Centre [2021/01/1/NZ1/00001 and 2023/49/B/NZ1/02456 to G.M.]. This work was financed by the statutory funding of the International Institute of Molecular and Cell Biology in Warsaw. This research was performed thanks to the IIMCB IN-MOL-CELL Infrastructure (RRID:SCR_021630) funded by the European Union – NextGenerationEU under National Recovery and Resilience Plan. IN-MOL-CELL Infrastructure was also funded by the European Union under Horizon Europe (Project 101059801—RACE) and by RACE-PRIME project carried out within the IRAP program of the Foundation for Polish Science co-financed by the European Union under the European Funds for Smart Economy 2021–2027 (FENG). This work was funded by the National Science Centre Poland grant number 2019/35/B/NZ4/04355 to MD. J.R. was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Germany’s Excellence Strategy – EXC 2008 – 390540038 – UniSysCat and project 449713269. The Wellcome Centre for Cell Biology is supported by core funding from the Wellcome Trust (Grant number 203149). C.S. was funded by Wellcome instrument grant 108504. This work was supported by funding for the Wellcome Discovery Research Platform for Hidden Cell Biology (226791), and we gratefully acknowledge support from the Proteomics core.