Project description:We report a comparison of the genome-wide binding patterns of MYC and WDR5, and the effects of a mutation in MYC (WBM) that disrupt the MYC-WDR5 interaction.

Project description:Collectively, the MYC family of oncoprotein transcription factors are overexpressed or deregulated in more than half of all malignancies. The ability of MYC proteins to access chromatin is fundamental to their role in promoting oncogenic gene expression programs in cancer and this function depends on MYC-cofactor interactions. One such cofactor is the chromatin regulator WDR5, which in models of Burkitt’s lymphoma facilitates recruitment of the c-MYC protein to chromatin at select target genes associated with protein synthesis, allowing for tumor progression and maintenance. However, beyond Burkitt’s lymphoma it is unknown whether these observations extend to other cancers or MYC family members, and whether WDR5 can be deemed as a “universal” MYC recruiter. Here, we focus on N-MYC amplified neuroblastoma to determine the extent of colocalization between N-MYC and WDR5 on chromatin while also demonstrating that like c-MYC, WDR5 can facilitate recruitment of N-MYC to known conserved WDR5-bound genes. We conclude based on this analysis that N-MYC and WDR5 colocalize invariantly across cell lines at predicted sites of facilitated recruitment associated with protein synthesis genes. Surprisingly, we also identify N-MYC-WDR5 cobound genes that are associated with DNA repair and cell cycle processes. Dissection of chromatin binding characteristics of N-MYC and WDR5 at all cobound genes reveals that sites of facilitated recruitment are inherently different than most N-MYC-WDR5 cobound sites. Our data reveals that WDR5 acts as a universal MYC recruiter at a small cohort of previously identified genes and highlights novel biological functions that may be coregulated by N-MYC and WDR5 to sustain the neuroblastoma state.

Project description:Background: During mitosis the cell depends on proper attachment and segregation of replicated chromosomes to generate two identical progeny. In cancers defined by overexpression or dysregulation of the MYC oncogene this process becomes impaired, leading to genomic instability and tumor evolution. Recently it was discovered that the chromatin regulator WDR5—a critical MYC cofactor—regulates expression of genes needed in mitosis through a direct interaction with the master kinase PDPK1. However, whether PDPK1 and WDR5 contribute to similar mitotic gene regulation in MYC-overexpressing cancers remains unclear. Therefore, to characterize the influence of WDR5 and PDPK1 on mitotic gene expression in cells with high MYC levels, we performed a comparative transcriptomic analysis in neuroblastoma cell lines defined by MYCN-amplification, which results in high cellular levels of the N-MYC protein. Results: Using RNA-seq analysis, we identify the genes regulated by N-MYC and PDPK1 in multiple engineered CHP-134 neuroblastoma cell lines and compare them to previously published gene expression data collected in CHP-134 cells following inhibition of WDR5. We find that as expected N-MYC regulates a multitude of genes, including those related to mitosis, but that PDPK1 regulates specific sets of genes involved in development, signaling, and mitosis. Analysis of N-MYC- and PDPK1-regulated genes reveals a small group of commonly controlled genes associated with spindle pole formation and chromosome segregation, which overlap with genes that are also regulated by WDR5. We also find that N-MYC physically interacts with PDPK1 through the WDR5-PDPK1 interaction suggesting regulation of mitotic gene expression may be achieved through a N-MYC-WDR5-PDPK1 nexus. Conclusions: Overall, we identify a small group of genes highly enriched within functional gene categories related to mitotic processes that are commonly regulated by N-MYC, WDR5, and PDPK1 and suggest that a tripartite interaction between the three regulators may be responsible for setting the level of mitotic gene regulation in N-MYC amplified cell lines. This study provides a foundation for future studies to determine the exact mechanism by which N-MYC, WDR5, and PDPK1 converge on cell cycle related processes.

Project description:Background: During mitosis the cell depends on proper attachment and segregation of replicated chromosomes to generate two identical progeny. In cancers defined by overexpression or dysregulation of the MYC oncogene this process becomes impaired, leading to genomic instability and tumor evolution. Recently it was discovered that the chromatin regulator WDR5—a critical MYC cofactor—regulates expression of genes needed in mitosis through a direct interaction with the master kinase PDPK1. However, whether PDPK1 and WDR5 contribute to similar mitotic gene regulation in MYC-overexpressing cancers remains unclear. Therefore, to characterize the influence of WDR5 and PDPK1 on mitotic gene expression in cells with high MYC levels, we performed a comparative transcriptomic analysis in neuroblastoma cell lines defined by MYCN-amplification, which results in high cellular levels of the N-MYC protein. Results: Using RNA-seq analysis, we identify the genes regulated by N-MYC and PDPK1 in multiple engineered CHP-134 neuroblastoma cell lines and compare them to previously published gene expression data collected in CHP-134 cells following inhibition of WDR5. We find that as expected N-MYC regulates a multitude of genes, including those related to mitosis, but that PDPK1 regulates specific sets of genes involved in development, signaling, and mitosis. Analysis of N-MYC- and PDPK1-regulated genes reveals a small group of commonly controlled genes associated with spindle pole formation and chromosome segregation, which overlap with genes that are also regulated by WDR5. We also find that N-MYC physically interacts with PDPK1 through the WDR5-PDPK1 interaction suggesting regulation of mitotic gene expression may be achieved through a N-MYC-WDR5-PDPK1 nexus. Conclusions: Overall, we identify a small group of genes highly enriched within functional gene categories related to mitotic processes that are commonly regulated by N-MYC, WDR5, and PDPK1 and suggest that a tripartite interaction between the three regulators may be responsible for setting the level of mitotic gene regulation in N-MYC amplified cell lines. This study provides a foundation for future studies to determine the exact mechanism by which N-MYC, WDR5, and PDPK1 converge on cell cycle related processes.

Project description:Active gene transcription requires accessible chromatin. Post-translational modifications of histone proteins modulate accessibility to target genes, a process that is controlled by multiple chromatin modifying enzymes, remodelers and epigenetic reader proteins. Histone H3K4 methylation serves as hallmark of actively transcribed genes and is introduced by histone methyltransferases (HMTs). For proper function of HMT activity, several adaptor proteins are required. One of these proteins is the WD-repeat containing protein 5 (WDR5) that acts as scaffolding component in HMT complexes and that has been associated with controlling transcription factors including MYC and long non-coding RNAs. The wide influence of dysfunctional HMTs complexes and the typically upregulated MYC levels in diverse tumor types has made WDR5 an attractive cancer drug target. Indeed, protein-protein interface inhibitors for two protein interaction interfaces on WDR5 have been developed. While such compounds only inhibit a subset of WDR5 interactions, chemically induced proteasomal degradation of WDR5 might be an elegant way to target all oncogenic function. In this study, we present the design, synthesis and evaluation of two diverse WDR5 degrader series based on two WIN site binding scaffolds. We show that linker nature and length are essential for successful degradation and strongly influences the degradation rate. In the presented datasets, we determined the intracellular degradation specificity of the WDR5 PROTACs (8g, 6, 17b, 14). We therefore treated MV4-11 cells with 8g and 17b, the corresponding ligands 6 and 14, or DMSO and quantified the induced degradation using a label free approach.

Project description:The MYC axis is commonly disrupted in cancer, mostly by activation of the MYC family of oncogenes, but also by genetic inactivation of MAX, the obligate partner of MYC, and of the MAX partner, MGA, both of which are members of the polycomb repressive complex, ncPRC1.6. While the oncogenic properties of the MYC family have been extensively studied, the tumor suppressor functions of MAX and MGA and the role of the MYC genes in MAX-mutant cells remain unclear. To address these knowledge gaps, we used chromatin immunoprecipitation, RNA-sequencing and mass spectrometry-based proteomic analysis in MAX-restituted and MYC oncogenic-transformed cell lines derived from human small cell lung cancer (SCLC), which is a high-grade neuroendocrine type of lung cancer. We found that MAX-mutant SCLC cells express ASCL1 and ASCL1-dependent targets, implying that these cells belong to the ASCL1-dependent group of SCLCs. In the absence of MAX, even after ectopic overexpression of MYC, we found no recruitment of MYC to the DNA. Furthermore, MAX reconstitution triggered pro-differentiation expression profiles that shifted when MAX and oncogenic MYC were co-expressed. Although ncPRC1.6 could be formed, the lack of MAX restricted global MGA occupancy, selectively driving its recruitment towards E2F6 motifs. Conversely, MAX restitution enhanced MGA occupancy and global gene repression of genes involved in different functions, including stem-cell and DNA repair/replication. Our data reveal that MAX-mutant SCLCs have ASCL1 characteristics, and are MYC-independent, and that their oncogenic features include deficient ncPRC1.6-mediated gene repression.

Project description:We report a comparison of the genome-wide binding patterns of MYC and WDR5, and the effects of a mutation in MYC (WBM) that disrupt the MYC-WDR5 interaction. The experimental design included two distinct experimental strategies. For comparison of genome-wide binding patters of wild-type (WT) and WDR5 binding-deficient (WBM) MYC, HEK293 cells were engineered by retroviral transduction to express either FLAG-tagged WT-MYC, FLAG-tagged WBM-MYC, or an empty vector control ("vec") ChIP was performed on all samples using the anti-FLAG antibody, and co-precipitating DNAs subject to next-generation sequencing. Samples "2514-WPT-1_1", "2514-WPT-5_1" and "2514-WPT-13_1" are three independent biological replicates of ChIPs performed on the "vec" control cells (i.e., those not expressing any exogenous MYC). Samples "2514-WPT-2_1", "2514-WPT-6_1" and "2514-WPT-10_1" are three independent biological replicates of ChIPs performed on the WT-MYC expressing cells. "2514-WPT-3_1", "2514-WPT-7_1" and "2514-WPT-11_1" are three independent biological replicates of ChIPs performed on the WBM-MYC expressing cells. For comparison of these binding patterns with those of WDR5, we performed ChIP in HEK293 cells with either an antibody against WDR5, or with IgG (negative control). Samples "2514-WPT-23_1", "2514-WPT-25_1", and "2514-WPT-27_1" are independent biological replicates of ChIPs performed with the anti-WDR5 antibody. Samples "2514-WPT-24_1", "2514-WPT-26_1", and "2514-WPT-28_1" are independent biological replicates of ChIPs performed with the negative IgG control.

Project description:This study describes the binding profile of MAX in mouse embryonic bodies at day 2 (WT, Wdr5 KO, Wdr5 and p53 double knockout)

Project description:This study demonstrates the impact of WIN site inhibitors versus WDR5 degradation on H3K4me and transcriptional processes in human Burkitt's lymphoma cells. We use RNA-seq to measure global transcript levels, ChIP-seq to map genomic H3K4me3, and PRO-seq to map genomic polymerase density and primary transcripts. Our data show that WIN site inhibition disables only a specific subset of WDR5 activity, and that H3K4me changes  induced by WDR5 depletion do not explain accompanying transcriptional responses.

Project description:WD repeat domain 5 (WDR5), a chromatin regulator associated with MLL complex and MYC oncoproteins, was shown to be critical for oncogenesis in human cancers and represents an attractive drug target. Inhibitors for targeting protein-protein interaction interfaces (PPIs) within WDR5 were developed; however, they inhibited only a part of WDR5-mediated functional interactions, exerting rather limited antitumor effects. We report a cereblon (CRBN)-based proteolysis targeting chimera (PROTAC) of WDR5, MS40, which is capable of selectively degrading cellular WDR5 and well-established imide:CRBN targets such as Ikaros (IKZF1). MS40-induced WDR5 degradation caused disassociation of MLL complex off chromatin, resulting in a decrease of global H3K4me2. Transcriptomic profiling also revealed targets of both WDR5 and imide:CRBN to be repressed by MS40. In MLL-rearranged acute leukemias, which exhibit high IKZF1 expression and IKZF1 dependency, co-suppression of WDR5 and IKZF1/3 by MS40 is superior at suppressing tumor growth not only to WDR5 PPI inhibitors but also to a VHL-based WDR5 PROTAC, MS169, which selectively targets WDR5 only. Furthermore, MS40 suppressed growth of primary leukemia patient cells in vitro and patient-derived xenografts (PDX) in vivo. Collectively, we report the discovery of a dual WDR5 and Ikaros degrader as anti-cancer therapeutic.