Project description:Suppression of CCT3 inhibits tumor growth by downregulating CDK1 expression in melanoma

Project description:Effect of Cell cycle regulator CDK1 on Cell Differentiation (RNA-IP CDK1 inh KD)

Project description:We addressed the role of cell cycle regulator CDK1 during differentiation by either inhibiting its activity with the specific inhibitor RO3306 (10µM) or by knocking its expression down using specific shRNAs, during mesendoderm differentiation. Human pluripotent stem cells (H9 cells) were synchronized in their cell cycle and then induced to differentiate into mesendoderm for 24h. shRNAs against CDK1 were induced 4 days before starting the differentiation. The CDK1 inhibitor was added to the medium 8h after the induction of differentiation. At the end of the experiment, the cells were harvested and processed for total RNA extraction. RNA-IP was carried out using RiboCluster Profiler RIP-Assay Kit (MBL) following the manufacture’s recommendations.

Project description:In this study, we found that in ES cells the majority of Cdk1 substrates are localized on chromatin. Cdk1 phosphorylates a large number of proteins involved in epigenetic regulation, including writers and erasers of all major histone marks. High levels of Cdk1 in ES cells phosphorylate and partially inactivate Dot1l, the histone H3 lysine 79 methyltransferase responsible for placing activating H3K79 marks on gene bodies. Decrease of Cdk1 activity during ES cell differentiation de-represses Dot1l, thereby allowing coordinated expression of differentiation genes. These analyses indicate that Cdk1 functions to maintain the epigenetic identity of ES cells.

Project description:Analysis of gene expression across the cell cycle from wild type cells, and cells expressing alleles of Yox1, Yhp1, Hcm1, and Tos4 that cannot be phosphorylated by Cdk1. Expression of S-phase and M/G1 transcripts are downregulated when phosphorylation of these factors is blocked, demonstrating that Cdk1 promotes expression of late cell cycle genes.

Project description:Analysis of gene expression across the cell cycle from wild type cells, and cells expressing alleles of Yox1, Yhp1, Hcm1, and Tos4 that cannot be phosphorylated by Cdk1. Expression of S-phase and M/G1 transcripts are downregulated when phosphorylation of these factors is blocked, demonstrating that Cdk1 promotes expression of late cell cycle genes. These experiments are two-color hybridizations of RNA isolated from synchronized wild type (WT) or phosphomutant (4P) cells, compared to RNA from asyncrhonous wild type cells in mid-log phase. Wild type and mutant cells were synchronized in G1 phase, released into the cell cycle and samples collected at 15 minute intervals. Each time course was carried out in duplicate, the replicate experiment was performed as a dye swap.

Project description:Purpose: Determine whether Cdk1 only regulates a specific subset of tDNAs, or whether Cdk1 has a more global impact on tDNA expression; Method: We study the expression of tRNA genes in WT cells and cdk1-as1 mutants during S phase by small-RNAseq; Result: We found that expression of at least 77% of all tDNAs is significantly downregulated in S-phase in the cdk1-as1 mutant compared with the WT strain; Conclussions: Cdk1 promotes transcription of the majority of tRNA genes during the cell cycle.

Project description:We performed total proteome and phosphoproteome analysis to characterize the role of non-mitotic kinase activity of CDK1 in insulin signaling through pharmacological inhibition and translational repression via siRNA-based knockdown. Specifically, cultured myotubes were treated with RO-3306, a selective ATP competitive inhibitor to inhibit CDK1 activity, or transfected with a CDK1 targeting siRNA pool to decrease CDK1 expression.

Project description:Malignant peripheral nerve sheath tumors (MPNSTs) are highly aggressive Schwann cell-derived sarcomas that are sporadic or associated with NF1 gene mutations. Traditional therapies are `usually ineffective for treating MPNSTs, so new targets need to be identified for the treatment of MPNSTs. In the present study, the role of the mitochondrial translocator protein (TSPO) in the regulation of cell proliferation and the cell cycle in MPNSTs was investigated. TSPO expression was lower in MPNSTs than in NFs. Loss-of-function experiments revealed that TSPO deficiency promoted MPNST cell growth, migration, and invasion and influenced the cell cycle in vitro and in vivo. In addition, TSPO depletion suppressed cell apoptosis by downregulating the expression of caspase-3, caspase-8, HSP60, p27, p53, and BCL-2 and suppressed the cell cycle by upregulating CDK1, CDK2, CCNB1 and CCNA2. Furthermore, CDK1 was determined to be an upstream target of TSPO-mediated regulation via RNA-seq, qPCR, and Western blotting. Specifically, depletion of CDK1 weakened the effect of TSPO deficiency on cell proliferation and migration. More importantly, CDK1 knockdown induced significant cell cycle arrest in the G2/M phase. In summary, TSPO deficiency regulates the cell cycle in MPNSTs by targeting CDK1, which may be an effective molecular target for prognosis evaluation and treatment.

Project description:Cyclin-dependent kinase 1 (Cdk1) is an essential regulator of many mitotic processes including the reorganization of the cytoskeleton, chromosome segregation, and formation and separation of daughter cells. Deregulation of Cdk1 activity results in defects in these processes. Although the role of Cdk1 in mitosis is well established, only a limited number of Cdk1 substrates have been identified in mammalian cells. Thus to increase our understanding of Cdk1-dependent phosphorylation pathways in mitosis, we conducted a quantitative phosphoproteomics analysis in mitotic HeLa cells using two small molecule inhibitors of Cdk1, Flavopiridol and RO-3306. In these analyses we identified a total of 24,900 phosphopeptides on 4,274 proteins of which 1215 phosphopeptides on 551 proteins that were significantly reduced by 2.5-fold or more upon Cdk1 inhibitor addition. Comparison of phosphopeptide quantification upon either inhibitor treatment revealed a high degree of correlation (R2 value of 0.87) between the different inhibitor datasets. Motif enrichment analysis of significantly regulated phosphopeptides revealed enrichment of canonical Cdk1 kinase motifs. Interestingly, the majority of proteins identified in this analysis contained 2 or more Cdk1 inhibitor-sensitive phosphorylation sites, are highly connected with other candidate Cdk1 substrates as determined by protein-protein network analysis, are enriched at specific subcellular structures, or are part of protein complexes as identified by the CORUM database. Furthermore, candidate Cdk1 substrates were enriched in G2 and M phase-specific genes. Finally, we validated a subset of candidate Cdk1 substrates by in vitro kinase assays. Our findings provide a valuable resource for the cell signaling and mitosis research community and greatly increase our knowledge of Cdk1 substrates and Cdk1-dependent signaling pathways.