Project description:The aim of these experiments was to quantify PLK1 tyrosine phosphosites with respect to EYA4 and EYA1. PRM was performed on immunopurified PLK1. This was part of a larger project to characterize the effects of EYA4 mediated dephosphorylation on PLK1 functions.

Project description:Polo-like kinase 1 (Plk1) is an essential protein kinase that promotes faithful mitotic progression in eukaryotes. Plk1 subcellular localization and substrate interactions are tightly controlled and require binding of Plk1 to phosphorylated sequences. Here, we use quantitative proteomics to identify phosphorylation-dependent interactions within the Plk1 network in human mitotic HeLa cells using kinase inhibitors and a Plk1 mutant deficient in phosphorylation-dependent substrate binding. We find that many interactions are abolished upon kinase inhibition; however, a subset are protected from phosphatase opposition or are unopposed, resulting in persistent Plk1-substrate interactions. This subset includes Phosphoprotein Phosphatase 6 (PP6), whose activity towards Aurora kinase A (AURKA) is inhibited by Plk1. This Plk1-PP6 interaction creates a feedback loop that coordinates and reinforces the activities of Plk1 and AURKA during mitotic entry and is terminated by Plk1 degradation during mitotic exit. Collectively, this work provides a cellular mechanism for the observed regulation of AURKA by Plk1.

Project description:The Epstein-Barr virus nuclear antigen 2 (EBNA2) initiates and maintains the proliferation of infected B cells. In search of additional cellular strategies, that control EBNA2 function, we have performed a label-free mass spectrometry-based quantification of cellular proteins in EBNA2 immuno-precipitates and found polo-like kinase 1 (PLK1) to be bound to EBNA2. EBNA2/PLK1 complex formation is strongly enforced by EBNA2 S379 phosphorylation catalyzed by the mitotic CYCLIN B/CDK1 complex.

Project description:Plk1 is a key mitotic kinase that localizes to distinct subcellular structures to promote accurate mitotic progression. Plk1 recruitment depends on direct interaction between polo-box domain (PBD) on Plk1 and PBD binding motif (PBD BM) on the interactors. However, recent study showed that PBD BM alone is not enough for stable binding between CENP-U and Plk1 highlighting the complexity of the interaction which warrants further investigation. An important interactor for Plk1 during mitosis is the checkpoint protein BubR1. Plk1 bound to BubR1 via PBD interaction with pT620 phosphorylates BubR1 S676/T680 to promote BubR1-PP2A/B56 interaction. The BubR1-PP2A/B56 complex counteracts the destablizing effect on kinetochore-microtubule attachments by mitotic kinases to promote mitotic progression. Here we show that Plk1 phosphorylates T600/T608 on BubR1 and the double phosphorylation is critical for BubR1-Plk1 interaction. A similar mechanism for Plk1-Bub1 interaction also exists indicating a general principle for Plk1 kinetochore recruitment through self-priming. Mechanistically preventing BubR1 T600/T608 phosphorylation impairs chromosome congression and checkpoint silencing by reducing Plk1 and PP2A/B56 binding to BubR1. Increasing the binding affinity towards Plk1 and PP2A/B56 in BubR1 through protein engineering bypasses the requirement of T600/T608 phosphorylation for mitotic progression. These results reveal a new layer of regulation for accurate mitotic progression.

Project description:Bub1 is required for the kinetochore/centromere localization of two essential mitotic kinases Plk1 and Aurora B. Surprisingly, stable depletion of Bub1 by ~95% in human cells marginally affects whole chromosome segregation fidelity. We show that CENP-U, which is recruited to kinetochores by the CENP-P and CENP-Q subunits of the CENP-O complex, is required to prevent chromosome mis-segregation in Bub1-depleted cells. Mechanistically, Bub1 and CENP-U redundantly recruit Plk1 to kinetochores to stabilize kinetochore-microtubule attachments, thereby ensuring accurate chromosome segregation. Furthermore, unlike its budding yeast homolog, the CENP-O complex does not regulate centromeric localization of Aurora B. Consistently, depletion of Bub1 or CENP-U sensitizes cells to the inhibition of Plk1 but not Aurora B kinase activity. Taken together, our findings provide mechanistic insight into the regulation of kinetochore function, which may have implications for targeted treatment of cancer cells with mutations perturbing kinetochore recruitment of Plk1 by Bub1 or the CENP-O complex.

Project description:The O-linked N-acetylglucosamine (O-GlcNAc) transferase (OGT) mediates intracellular O-GlcNAcylation modification, whose function and substrates have entranced biologists and chemists alike. O-GlcNAcylation occurs on Ser/Thr residues and takes part in a vast array of physiological processes. OGT is essential for dividing mammalian cells, and it underscores many human diseases. Yet many of its fundamental substrates in the cell division process remains to be unveiled. Here we focus on its effect on Polo-like kinase 1 (PLK1), a mitotic master kinase that governs DNA replication, mitotic entry, chromosome segregation and mitotic exit. We found that PLK1 interacts with OGT and is O-GlcNAcylated.

Project description:NK/T cell lymphoma (NKTCL) is a highly aggressive subtype of non-Hodgkin lymphoma. GELOX (gemcitabine, oxaliplatin, and L-asparaginase) is one of the first-line chemotherapy regimens of NKTCL. Yet, the prognosis of NKTCL is poor. Icaritin (ICT) is an herb-derived monomer from icariin with antitumor effects. We found that icaritin induced proliferation inhibition and apoptosis of NKTCL both in vitro and in vivo. Moreover, icaritin inhibited the dissemination of NKTCL in vivo. RNA sequencing (RNA-seq) revealed the polo-like kinase 1 (PLK1) gene and DNA damage response (DDR) as the targets of icaritin. Mechanistically, icaritin inhibited PLK1 to promote checkpoint kinase 2 (Chk2) homodimerization and its T387 phosphorylation, which further activated p53, leading to the activation of the DDR pathway. Moreover, inhibiting PLK1 increased Forkhead box O3a (FOXO3a) nuclear localization, the latter of which activated Ataxia-telangiectasia mutated (ATM), an early sensor of DNA damage. Then ATM phosphorylated Chk2 T68 and initiated Chk2 activation. Remarkably, combined treatment of icaritin and GELOX achieved better antitumor efficacy than single treatment in vivo. In summary, our results proved the efficacy of icaritin treating NKTCL, and provided insights into its antitumor molecular mechanism, and revealed the application value of icaritin in facilitating clinical NKTCL treatment.

Project description:Polo-like kinase 1 (PLK1) is a serine/threonine kinase required for mitosis and cytokinesis. As cancer cells are often hypersensitive to partial PLK1 inactivation, chemical inhibitors of PLK1 have been developed and tested in clinical trials. However, these molecules alone were not completely effective. PLK1 promotes numerous molecular and cellular events in the cell division cycle. To date, it is unclear which of these events most crucially depend on PLK1 activity. We used a CRISPR-based genome-wide screening strategy to identify genes whose inactivation enhances cell proliferation defects upon partial chemical inhibition of PLK1. Genes identified encode proteins that are functionally linked to PLK1 in multiple ways. Among them, factors that promote centromere and kinetochore function were clearly enriched. In particular, inactivation of the kinesin KIF18A or SKA1 in PLK1-compromised cells results in mitotic defects, activation of the spindle assembly checkpoint and nuclear reassembly defects. Our results suggest that functions of PLK1 at kinetochores are most sensitive to its inhibition, and point at KIF18A as a possible target for combinatorial therapies using existing PLK1 inhibitors.

Project description:To dissect the molecular mechanisms of HILPS in promoting cell survival under hypoxia, we conducted RNA pull-down assay in combination with mass spectrometry analysis to identify HILPS-interacting proteins. Pull-down of antisense HILPS was used as a negative control. To identify the potential phosphorylation site(s), we conducted the in vitro kinase assay in combination with mass spectrometry analysis using PLK1-T210D, recombinant GST-HIF1a and cold ATP. A kinase assay using PLK1-K82R was included as a control.

Project description:Checkpoint kinase 2 (CHK2) plays an important role in safeguarding the mitotic progression, specifically the spindle assembly, though the mechanism of regulation remains poorly understood. Here, we identified a novel mitotic phosphorylation site on CHK2 Tyr156, and its responsible kinase JAK2. Expression of a phospho-deficient mutant CHK2 Y156F or treatment with JAK2 inhibitor IV compromised mitotic spindle assembly, leading to genome instability. In contrast, a phospho-mimicking mutant CHK2 Y156E restored mitotic normalcy in JAK2-inhibited cells. Mechanistically, we show that this phosphorylation is required for CHK2 interaction with and phosphorylation of the spindle assembly checkpoint (SAC) kinase Mps1, and failure of which results in impaired Mps1 kinetochore localization and defective SAC. Concordantly, analysis of clinical cancer datasets revealed that deletion of JAK2 is associated with increased genome alteration; and alteration in CHEK2 and JAK2 is linked to preferential deletion or amplification of cancer-related genes. Thus, our findings not only reveal a novel JAK2-CHK2 signaling axis that maintains genome integrity through SAC but also highlight the potential impact on genomic stability with clinical JAK2 inhibition.