Project description:Epigenetic drugs exert a wide range of immune-related effects, but have strong drug-specific heterogeneity in immunomodulation, thus hampering selection of the most promising agent for innovative cancer immunotherapy approaches. Here we identified immune-related signatures induced by four classes of epigenetic drugs in melanoma cells to define the most active agent and to understand its biological activity in -vitro, in a pre-clinical model and in clinical samples. Gene modulation, induced by inhibitors of DNA methyltransferases (guadecitabine), histone deacetylases (givinostat), bromodomain and extraterminal domain proteins (JQ1 and OTX-015) and enhancer of zeste homolog 2 (GSK126), was assessed in human melanoma cell lines. All drugs modulated genes belonging to 20 families. Guadecitabine, followed by givinostat, was the most active drug and upregulated >160 immune-related genes characterized by low expression and high methylation. JQ1 and OTX-015 showed predominant inhibitory effects, GSK126 was the least active. A dominant immunomodulatory effect of guadecitabine and JQ1 was observed in combinatorial treatments.

Project description:Epigenetic drugs exert a wide range of immune-related effects, but have strong drug-specific heterogeneity in immunomodulation, thus hampering selection of the most promising agent for innovative cancer immunotherapy approaches. Here we identified immune-related signatures induced by four classes of epigenetic drugs in melanoma cells to define the most active agent and to understand its biological activity in -vitro, in a pre-clinical model and in clinical samples. Gene modulation, induced by inhibitors of DNA methyltransferases (guadecitabine), histone deacetylases (givinostat), bromodomain and extraterminal domain proteins (JQ1 and OTX-015) and enhancer of zeste homolog 2 (GSK126), was assessed in human melanoma cell lines. All drugs modulated genes belonging to 20 families. Guadecitabine, followed by givinostat, was the most active drug and upregulated >160 immune-related genes characterized by low expression and high methylation. JQ1 and OTX-015 showed predominant inhibitory effects, GSK126 was the least active. A dominant immunomodulatory effect of guadecitabine and JQ1 was observed in combinatorial treatments. This experiment deals with the characterization of gene expression in untreated human melanoma cell lines used throughout the project.

Project description:Epigenetic drugs exert a wide range of immune-related effects, but have strong drug-specific heterogeneity in immunomodulation, thus hampering selection of the most promising agent for innovative cancer immunotherapy approaches. Here we identified immune-related signatures induced by four classes of epigenetic drugs in melanoma cells to define the most active agent and to understand its biological activity in -vitro, in a pre-clinical model and in clinical samples. Gene modulation, induced by inhibitors of DNA methyltransferases (guadecitabine), histone deacetylases (givinostat), bromodomain and extraterminal domain proteins (JQ1 and OTX-015) and enhancer of zeste homolog 2 (GSK126), was assessed in human melanoma cell lines. All drugs modulated genes belonging to 20 families. Guadecitabine, followed by givinostat, was the most active drug and upregulated >160 immune-related genes characterized by low expression and high methylation. JQ1 and OTX-015 showed predominant inhibitory effects, GSK126 was the least active. A dominant immunomodulatory effect of guadecitabine and JQ1 was observed in combinatorial treatments. This experiment deals with the characterization of gene expression in tumor nodules removed from immunodeficient mice treated or not with guadecitabine (as described in Covre A et al. Seminars in Oncology 2015;42:506-513) after s.c. tranplant of human melanoma cells from two cell lines 313 and 195 (cell lines described in Coral S et al. J. Cell Physiol 2006;207:58-66).

Project description:We investigated that differentially expressed genes (DEG) targeted by BET inhibitors, JQ1 and OTX-015 in HCC cells using RNA sequencing. These DEGs are involved in HCC cells migration, of which SMARCA4 inhibition is effective in suppressing HCC cell migration.

Project description:Identification of the mechanisms through which BET inhibitor (OTX-015) stimulates natural killer (NK) activation. RNA-seq was performed comparing vehicle- (DMSO) to OTX-015-treated NK-92 cell line.

Project description:Purpose: To compare the transcriptomes of HCC1937 vector and wtBRCA1 cells which were treated with OTX-015. Methods: HCC1937 vector and wtBRCA1 cells were treated with 5 micromolar OTX-015 for 24 hours. Total RNA was extracted and processed with NEBNext Ultra Directional RNA Library Prep Kit for cDNA library preparation. The data are in duplicate and raw data were generated by Illumina 2500 sequencer. The Fastq format data were then processed with Tophat for genome mapping. After getting the bam files, they were further analyzed with cuffdiff for gene expression of different groups. Results: From the transcriotome profiling and analysis, we got gene expression data of DMSO control group and OTX-015 treatment group for the HCC1937 BRCA1 isogenic cell lines. Conclusion: The gene expression data revealed the transcriptome variation by OTX-015 treatment.

Project description:The combination of PD-1 and CTLA-4 blockade has determined an improved overall survival (OS) rate for malignant melanoma at 3 years of 58% as compared to ipilimumab alone. Immune checkpoint blockers (ICB) limit the tumor’s immune escape yet only for approximately a third of all tumors and, in most cases, for a limited amount of time. Several approaches to overcome resistance to ICB are being investigated among which the addition of epigenetic drugs that are expected to act on both immune and tumor cells. Guadecitabine, a dinucleotide prodrug of a decitabine linked via phosphodiester bond to a guanosine, showed promising results in the phase-1 clinical trial, NIBIT-M4 (NCT02608437). We used the syngeneic B16F10 murine melanoma model to study the effects of immune checkpoint blocking antibodies against CTLA-4 and PD-1 in combination, with and without the addition of Guadecitabine. We comprehensively characterized the tumor’s and the host’s responses under different treatments by flow cytometry, immunohistochemistry (MANTRA), gene methylation and scRNA sequencing. Guadecitabine in combination with ICBs significantly reduced tumor growth compared to ICB and Guadecitabine treatment. The demethylating drug led to a general DNA-demethylation and transcriptional modification of gene expression. In particular, Guadecitabine greatly enhanced the efficacy of combined ICBs by increasing effector memory CD8+ T cells, inducing effector NK cells in the spleen and reducing tumor infiltrating regulatory T cells and MDSC cells, in the TME. These results indicate Guadecitabine as a promising epigenetic drug to be added to ICB therapy.

Project description:Bromodomain and extra terminal domain (BET) inhibition reduces occupancy of BET-family proteins at promoter and enhancer sites finally leading to genome wide changes in gene transcription. We used ChIPSeq profiling to investigate genome wide changes in promoter and enhancer occupancy induced by BET inhibitors BAY 1238097 and OTX-015, respectively.

Project description:The bromodomain and extra-terminal domain inhibitors (BETi) are promising epigenetic drugs for the treatment of various cancers through suppression of oncogenic transcription factors including MYC. However, only a subset of CRC cells response to BETi, suggesting an intrinsic resistance to BETi in CRC. We investigated the effect of JQ1 on cell proliferation, apoptosis, angiogenesis and MYC expression in a panel of 11 CRC cells in vitro and in vivo. JQ1-resistant CRC cells were used for the screening for the effective combination therapies with JQ1. RNA-seq of single drug or combined drugs treatment was performed to explore the mechanism of action.

Project description:The sensitivity has been the key issue for EZH2 inhibitor in cancer therapy. Although it has been approved by Food and Drug Administration (FDA) in 2020, the relative narrow scope still limits its clinical application. In this study, we utilized B16F10 melanoma cell line which is resistant to EZH2 inhibitor GSK126 to an extent to investigate the underlying mechanism. We found that although the proliferative phenotype didn't show any difference upon treatment with GSK126 at 10 μM, the transcriptome and metabolome changed profoundly. Gene set enrichment analysis and metabolites pathway enrichment analysis revealed that GSK126 induced broad shifts in glucose, amino acids and lipid metabolism. Lipid synthesis were strengthened with elevated abundance of unsaturated fatty acids. We also found attenuated tricarboxylic acid cycle metabolism, and decreased amino acids levels. The liver lipid accumulation and the increased blood triglycerides level after GSK126 treatment were further confirmed in a mouse model. Indeed, the combination of GSK126 and lipolysis agent fenofibrate significantly attenuated the proliferation of B16F10 and increased the sensitivity to GSK126. Therefore, the dysregulated lipid metabolism blunts the sensitivity of B16F10 to GSK126. This study uncovered the iceberg under the sea and identified the Achilles heel of EZH2 inhibitor, so that it provides the novel strategy for further combination therapy.