Project description:The ID family of proteins (ID1-4), which bind to basic helix-loop-helix (bHLH) transcription factors and prevent bHLH-directed transcription, are critical regulators of the differentiation and chemoresistance of cancer cells derived from multiple cellular lineages. ID2 was previously shown to impair the in vitro differentiation of human mesenchymal stem cells. However, the functional role, if any, of ID2 in regulating differentiation, developmental pathways, and the oncogenic phenotype of Ewing sarcoma tumors is unknown. We used CRISPR/Cas9 to knockout ID2 in Ewing sarcoma cell lines and identified that the loss of ID2 significantly decreases cell growth in vitro and in vivo in a xenograft experiment. Using RNA-seq and gene set enrichment analysis with ID2-knockout and ID2-Knockout-Rescue cell lines we identified that ID2 regulates genes related to differentiation and development in Ewing sarcoma cell lines.

Project description:Tissue-specific cerebellum knockouts of Anaphase-promoting complex subunits CDH1 and APC7 were compared to littermate controls to investigate the protein targets of the APC in post-mitotic neurons, as well as the effect of these proteins on the cerebellar phosphoproteome.

Project description:The spindle checkpoint is a mitotic surveillance system which ensures equal segregation of sister chromatids. It delays anaphase onset by inhibiting the action of the E3 ubiquitin ligase known as the anaphase promoting complex or cyclosome (APC/C). Mads/BubR1 is a key component of the mitotic checkpoint complex (MCC) which binds and inhibits the APC/C early in mitosis. Mps1Mph1 kinase is critical for checkpoint signalling and MCC-APC/C inhibition, yet few substrates have been identified. Here we identify Mad3 as a substrate of fission yeast Mps1Mph1 kinase. We map and mutate phosphorylation sites in Mad3, producing mutants that are targeted to kinetochores and assembled into MCC, yet display reduced APC/C binding and are unable to maintain checkpoint arrests. We chow biochemically that Mad3 phospho-mimics are potent APC/C inhibitors in vitro, demonstrating that Mad3p modification can directly influence Cdc20Slp1-APC/C activity. This genetic dissection of APC/C inhibition demonstrates that Mps1Mph1 kinase-dependant modification of Mad3 and Mad2 act in a concerted manner to maintain spindle checkpoint arrests.

Project description:Induced oncoproteins degradation provides an attractive anti-cancer modality. Activation of anaphase-promoting complex (APC/CCDH1) prevents cell cycle entry by targeting crucial mitotic proteins for degradation. Phosphorylation of its co-activator CDH1 modulates the E3 ligase activity, but little is known about its regulation after phosphorylation and how to effectively harness APC/CCDH1 activity to treat cancer. Notably, Proline-directed phosphorylation is regulated by PIN1-catalyzed cis-trans prolyl isomerization to drive tumor malignancy. However, the mechanisms controlling its protein turnover remain elusive. Through proteomic screens, we identify a reciprocal antagonism of PIN1-APC/CCDH1 mediated by domain-oriented phosphorylation-dependent dual interactions as a fundamental mechanism governing mitotic protein stability and cell cycle entry.

Project description:Entry into and exit from mitosis is driven by precisely-timed changes in protein abundance, and involves transcriptional regulation and protein degradation. However, the role of translational regulation in modulating cellular protein content during mitosis remains poorly understood. Here, using ribosome profiling, we show that translational, rather than transcriptional regulation is the dominant mechanism for modulating protein synthesis at mitotic entry. The vast majority of regulated mRNAs are translationally repressed, which contrasts previous findings of selective mRNA translational activation at mitotic entry. One of the most pronounced translationally repressed genes in mitosis is Emi1, an inhibitor of the anaphase promoting complex (APC), which is degraded during mitosis. We show that Emi1 degradation is insufficient for full APC activation and that simultaneous translational repression is required. These results provide a genome-wide view of protein translation during mitosis and suggest that translational repression may be used to ensure complete protein inactivation Ribosome profiling and mRNA-seq from 3 time points in the cell cycle

Project description:In this study, we wanted to explore the protein interactors of Cdh1, a subunit of the E3 Ubiquitin-Ligase Cdh1-APC. Our data show that in addition to interacting with other components of the Cdh1-APC complex, Cdh1 interacts with regulators of translation.

Project description:Signal transduction by Small Ubiquitin-like Modifier (SUMO) regulates a myriad of nuclear processes. Here, we report on the role of SUMO in mitosis in human cell lines. Knocking down the SUMO conjugation machinery resulted in a delay in mitosis and defects in mitotic chromosome separation. Searching for relevant SUMOylated proteins in mitosis, we identified the APC/C complex, a master regulator of metaphase to anaphase transition, as a SUMO target. The APC4 subunit is the major SUMO target in the complex, containing SUMO acceptor lysines at positions 772 and 798. SUMOylation increased APC/C ubiquitylation activity towards a subset of its targets, including the newly identified target KIF18B. Intriguingly, SUMOylation of APC/C was regulated by casein kinase driven phosphorylation of serines at positions 777 and 779. Combined, our findings demonstrate the importance of SUMO signal transduction for genome integrity during mitotic progression and reveal a triad of PTMs, cooperating to drive mitosis.

Project description:Transcriptional profiling of mouse intestinal crypt epithelial cells comparing Apc+/Δ716 mice with Apc+/Δ716 Id2-/- mice. One-condition experiment, Apc+/Δ716 mice vs. Apc+/Δ716 Id2-/- mice, Biological replicates: 1 pooled intestinal crypt epithelium from 3 Apc+/Δ716 mice, 1 pooled intestinal crypt epithelium from 3 Apc+/Δ716 Id2-/- mice. One replicate per array.

Project description:Entry into and exit from mitosis is driven by precisely-timed changes in protein abundance, and involves transcriptional regulation and protein degradation. However, the role of translational regulation in modulating cellular protein content during mitosis remains poorly understood. Here, using ribosome profiling, we show that translational, rather than transcriptional regulation is the dominant mechanism for modulating protein synthesis at mitotic entry. The vast majority of regulated mRNAs are translationally repressed, which contrasts previous findings of selective mRNA translational activation at mitotic entry. One of the most pronounced translationally repressed genes in mitosis is Emi1, an inhibitor of the anaphase promoting complex (APC), which is degraded during mitosis. We show that Emi1 degradation is insufficient for full APC activation and that simultaneous translational repression is required. These results provide a genome-wide view of protein translation during mitosis and suggest that translational repression may be used to ensure complete protein inactivation

Project description:The anaphase promoting complex/cyclosome (APC/C) is a ubiquitin ligase that controls progression through the eukaryotic cell cycle by targeting key substrates for degradation through the ubiquitin proteasome pathway. During G1, the APC/C works in concert with its co-activator Cdh1 to recognize and ubiquitinate specific substrates during this phase of the cell cycle. While many APC/CCdh1 substrates play a role cell cycle regulation, others are involved in distinct cellular processes, indicating that diverse biological pathways are subject to APC/C-mediated control. To identify novel pathways and substrates regulated by APC/CCdh1, we conducted an unbiased proteomic screen in G1-arrested RPE1 cells acutely treated with small molecule APC/C inhibitors. Combining these results with degron prediction analysis, we discovered a range of putative APC/C substrates. We validated IRS2, a key adaptor protein involved in signaling downstream of the insulin and IGF1 receptors, as a novel direct APC/CCdh1 target. We demonstrate that genetic deletion of IRS2 reduces the expression of proteins involved in cell division and functionally impairs the spindle assembly checkpoint. Together, these findings reveal a novel connection between the insulin/IGF1 signaling network and the cell cycle regulatory machinery.