Project description:Synthetic lethality-based strategy has been developed to identify therapeutic targets in cancer harboring tumor suppressor gene mutations, as exemplified by the effectiveness of poly(ADP)-ribose polymerase (PARP) inhibitors in BRCA1/2-mutated tumors. However, many synthetic lethal interactors are less reliable due to the fact that such genes usually do not perform fundamental housekeeping functions in the cell. Here we explore an approach to identify the “essential lethality” arose from these mutated/deleted essential genes, which are largely tolerated in cancer cells due to genetic redundancy. In additional to the known synthetic-lethal interactions, this approach uncovered the cohesion subunit SA1 as a putative synthetic-essential target in cancers carrying inactivating mutations of its paralog, SA2. In SA2-deficient Ewing sarcoma and bladder cancers, further depletion of SA1 profoundly and specifically suppressed cancer cell proliferation, survival and tumorigenic potential. Mechanistically, inhibition of SA1 in the SA2-mutated cells leads to premature chromatid separation and dramatic extension of mitotic duration, which is accompanied by lethal failure of cell division. More importantly, depletion of SA1 renders those SA2-mutated cells not only more susceptible to DNA damage, especially double-strand breaks (DSBs), but also defective in DNA repair. Furthermore, inhibition of SA1 sensitizes the SA2-deficient cancer cells to PARP inhibitors in vitro and in vivo, providing a potential therapeutic strategy for patients with SA2-deficient tumors. This study provides a framework for the discovery of therapeutic targets in cancers that harbor specific essential gene deficiency.

Project description:Two genes have a synthetic lethal relationship when silencing or inhibition of one gene is only lethal in the context of a mutation or activation of the second gene. This situation offers an attractive therapeutic strategy, as inhibition of such a gene will only trigger cell death in tumor cells with an activated second oncogene but spare normal cells without activation of the second oncogene. Here we present evidence that CDK2 is synthetic lethal to neuroblastoma cells with MYCN amplification and overexpression. Neuroblastomas are childhood tumors with an often lethal outcome. Twenty percent of the tumors have MYCN amplification and these tumors are ultimately refractory to any therapy. Targeted silencing of CDK2 by three RNA interference techniques induced apoptosis in MYCN-amplified neuroblastoma cell lines, but not in MYCN single copy cells. Silencing of MYCN abrogated this apoptotic response in MYCN-amplified cells. Inversely, silencing of CDK2 in MYCN single copy cells did not trigger apoptosis, unless a MYCN transgene was activated. The MYCN induced apoptosis after CDK2 silencing was accompanied by nuclear stabilization of P53 and mRNA profiling showed up-regulation of P53 target genes. Silencing of P53 rescued the cells from MYCN-driven apoptosis. The synthetic lethality of CDK2 silencing in MYCN activated neuroblastoma cells can also be triggered by inhibition of CDK2 with a small molecule drug. Treatment of neuroblastoma cells with Roscovitine, a CDK inhibitor, at clinically achievable concentrations induced MYCN-dependent apoptosis. The synthetic lethal relation between CDK2 and MYCN indicates CDK2 inhibitors as potential MYCN-selective cancer therapeutics. CDK2 shRNA in a tet repressor system was stably transfected in the IMR32 cell line. Time course analysis was performed in triplicate after induction of CDK2 shRNA at 5 time points.

Project description:O-GlcNAc transferase (OGT) is overexpressed in aggressive prostate cancer. Here, we employed ChIP-seq to map chromatin-bound O-GlcNAc loci in prostate cancer cells and discovered that these overlap with sites of active transcription and MYC binding. Using RNA-seq, we show that inhibition of OGT promotes MYC-dependent transcriptional repression of mRNAs involved in G1-S transition. O-GlcNAc ChIP-seq regions are highly enriched to transcription start sites and identify the ‘GFY’-motif. Proteins binding to this motif have not been established and we use synthetic oligonucleotides as a bait to enrich protein complexes associated with this sequence. By comparing the unbiased proteomic data from oligonucleotide enrichment with proteomic data from O-GlcNAc and MYC ChIP-mass spectrometry, we identified host cell factor 1 (HCF-1) as an interaction partner of MYC. Inhibition of OGT disrupted the interaction between MYC and HCF-1, and compromised MYC’s ability to promote proliferation of prostate cancer cells in the absence of androgens. Reverse phase protein arrays identified a set of proteins involved in mitosis that are dependent on MYC and OGT activity for expression. In conclusion, we show that OGT activity regulates MYC-driven proliferation by coordinating transcription and translation of cell cycle genes.

Project description:O-GlcNAc transferase (OGT) is overexpressed in aggressive prostate cancer. Here, we employed ChIP-seq to map chromatin-bound O-GlcNAc loci in prostate cancer cells and discovered that these overlap with sites of active transcription and MYC binding. Using RNA-seq, we show that inhibition of OGT promotes MYC-dependent transcriptional repression of mRNAs involved in G1-S transition. O-GlcNAc ChIP-seq regions are highly enriched to transcription start sites and identify the ‘GFY’-motif. Proteins binding to this motif have not been established and we use synthetic oligonucleotides as a bait to enrich protein complexes associated with this sequence. By comparing the unbiased proteomic data from oligonucleotide enrichment with proteomic data from O-GlcNAc and MYC ChIP-mass spectrometry, we identified host cell factor 1 (HCF-1) as an interaction partner of MYC. Inhibition of OGT disrupted the interaction between MYC and HCF-1, and compromised MYC’s ability to promote proliferation of prostate cancer cells in the absence of androgens. Reverse phase protein arrays identified a set of proteins involved in mitosis that are dependent on MYC and OGT activity for expression. In conclusion, we show that OGT activity regulates MYC-driven proliferation by coordinating transcription and translation of cell cycle genes.

Project description:These datasets use diploid-based synthetic lethality analysis on microarrays (dSLAM) as a new technology for identifying genetic interactions of various types. These interactions include synthetic lethality (CIN8, BIM1, SGS1), synthetic haploinsufficiency (TUB1), dosage suppression (LCD1), suppression of a lethal mutation (SML1), suppression of an overexpressed conditionally lethal allele (CDC102), and gene-chemical interactions (Benomyl). Keywords = dSLAM yeast heterozygotes barcode tag synthetic lethality suppression Keywords: other

Project description:ARID1A, an epigentic modifier, is often mutated in ovarian clear cell carcinoma (OCCC). In addition, EZH2 is frequently upregulated in OCCC. Inhibtion of EZH2 with an inhibitor (GSK126) selectively inhibits ARID1A-mutated cells. This study was designed to understand changes in gene expression profiles following EZH2 inhibition or ARID1A restoration. Chromatin remodelers such as ARID1A are frequently mutated in a broad array of cancers. However, targeted cancer therapy based on ARID1A mutation status has not been described. Intriguingly, ARID1A mutated cancers typically lack genomic instability, suggesting significant involvement of epigenetic mechanisms. Here we show that inhibition of the EZH2 methyltransferase acts in a synthetic lethal manner in ARID1A mutated cells. Remarkably, ARID1A mutation status correlated with response to EZH2 inhibitor. Genome-wide profiling revealed antagonistic roles of ARID1A and EZH2 in gene regulation. Further, we identified PIK3IP1 as a direct ARID1A/EZH2 target gene whose upregulation contributes to the observed synthetic lethality in the EZH2 inhibitor treated ARID1A mutated cells. Significantly, EZH2 inhibitor caused the regression of established ARID1A mutated tumors in vivo. Together, this data demonstrate a synthetic lethality between ARID1A mutation and EZH2 inhibition. They indicate that pharmacological inhibition of EZH2 represents a novel treatment strategy for ARID1A mutated cancers.

Project description:CDK9 is the kinase subunit of P-TEFb that enables RNA polymerase (Pol) II to transit from promoter-proximal pausing to productive elongation. Although considerable interest exists in CDK9 as a therapeutic target, little progress has been made due to the lack of highly selective inhibitors. Here, we describe the development of i-CDK9 as such an inhibitor that potently suppresses CDK9 phosphorylation of substrates and causes genome-wide Pol II pausing. While most genes experience reduced expression, MYC and other primary response genes increase expression upon sustained i-CDK9 treatment. Essential for this increase, the bromodomain protein BRD4 captures P-TEFb from 7SK snRNP to deliver to target genes and also enhances CDK9’s activity and resistance to inhibition. Because the i-CDK9-induced MYC expression and binding to P-TEFb compensate for P-TEFb’s loss of activity, only the simultaneous inhibition of CDK9 and MYC can efficiently induce growth arrest and apoptosis of cancer cells, suggesting the potential of a combinatorial treatment strategy. ChIP-seq of Pol II in HeLa cells before or after i-CDk9 treatment

Project description:Myc is an oncogenic transcription factor frequently dysregulated in human cancer. To identify pathways supporting the Myc oncogenic program, we employed a genome-wide RNAi screen for Myc-synthetic-lethal (MySL) genes and uncovered a role for the SUMO-activating-enzyme (SAE1/2). Loss of SAE1/2 enzymatic activity drives synthetic lethality with Myc. Mechanistically, SAE2 inhibition switches a transcriptional subprogram of Myc from activated to repressed. A subset of these SUMOylation-dependent Myc-switchers (SMS genes) governs mitotic spindle function and is required to support the Myc oncogenic program. comparison of 4 treatments: normal HMEC, High Myc in HMEC, SUMO depleted in HMEC, High Myc+Sumo Depleted in HMEC

Project description:Two genes have a synthetic lethal relationship when silencing or inhibition of one gene is only lethal in the context of a mutation or activation of the second gene. This situation offers an attractive therapeutic strategy, as inhibition of such a gene will only trigger cell death in tumor cells with an activated second oncogene but spare normal cells without activation of the second oncogene. Here we present evidence that CDK2 is synthetic lethal to neuroblastoma cells with MYCN amplification and overexpression. Neuroblastomas are childhood tumors with an often lethal outcome. Twenty percent of the tumors have MYCN amplification and these tumors are ultimately refractory to any therapy. Targeted silencing of CDK2 by three RNA interference techniques induced apoptosis in MYCN-amplified neuroblastoma cell lines, but not in MYCN single copy cells. Silencing of MYCN abrogated this apoptotic response in MYCN-amplified cells. Inversely, silencing of CDK2 in MYCN single copy cells did not trigger apoptosis, unless a MYCN transgene was activated. The MYCN induced apoptosis after CDK2 silencing was accompanied by nuclear stabilization of P53 and mRNA profiling showed up-regulation of P53 target genes. Silencing of P53 rescued the cells from MYCN-driven apoptosis. The synthetic lethality of CDK2 silencing in MYCN activated neuroblastoma cells can also be triggered by inhibition of CDK2 with a small molecule drug. Treatment of neuroblastoma cells with Roscovitine, a CDK inhibitor, at clinically achievable concentrations induced MYCN-dependent apoptosis. The synthetic lethal relation between CDK2 and MYCN indicates CDK2 inhibitors as potential MYCN-selective cancer therapeutics.

Project description:Synthetic lethality exploits the genetic vulnerabilities of cancer cells enabling, a targeted, precision approach to treat cancer. Synthetic lethal discovery approaches have led to clinical successes of PARP inhibitors and the progression of several next-generation therapeutic targets such as WRN, USP1, PKMYT1, POLQ, and PRMT5 into the clinic. To date, however, most discovery efforts in the synthetic lethal space have focused on DNA repair. Here, we show, for the first time in humans, a frequent synthetic lethal interaction between two complexes of the translational repair pathway, PELO/HBS1L and the superkiller (SKI) complex. In distinct genetic contexts, either in 9p21.3 (FOCAD) deleted or MSI-H tumors, we found that phenotypically destabilized SKI complex leads to dependence on the PELO/HBS1L ribosomal rescue complex. We estimate that 20% of all tumors have a destabilized SKI complex. The concomitant loss of PELO in a SKI destabilized tumor drives an unfolded protein stress response, cell cycle arrest, and robust tumor growth inhibition. Furthermore, we demonstrate that the loss of HBS1L phenocopies PELO loss, presenting a second potential therapeutic target within the rescue complex. Our results indicate that PELO/HBS1L represent novel therapeutic targets whose dependence converges upon SKI complex destabilization, a common phenotypic biomarker in diverse genetic contexts and a significant patient population.