Project description:Platinum-based chemotherapeutics are used in many combination regimens in cancer. Despite extensive use across diverse cancer types, there is room for improved efficacy and patient selection for treatment. Here, we use bladder cancer to address both issues. A multi-omic assessment of five human bladder cancer cell lines and their chemotherapy resistant derivatives, coupled with in vitro whole-genome CRISPR screens were used to define functional drivers of treatment resistance. We identified 46 genes that sensitized the resistant cell lines to cisplatin plus gemcitabine (GemCis), a standard combination therapy in bladder cancer. Most genes were involved with DNA damage and repair pathways, which have previously been associated with enhanced sensitivity to cisplatin. Evaluating expression of the 46 genes in the whole transcriptome and proteome data in parental and resistant lines identified the puromycin sensitive aminopeptidase, NPEPPS, as a novel hit. Depletion of NPEPPS resulted in sensitizing resistant bladder cancer cells to cisplatin in vitro and in xenograft experiments. Pharmacologic inhibition of NPEPPS with tosedostat in cells and in chemoresistant, bladder cancer patient-derived tumoroids improved response to cisplatin. Prior work found NPEPPS in a protein complex with volume regulated anion channels (VRACs) in several cell line models. Interestingly, depletion of two VRAC subunits, LRRC8A and LRRC8D, known importers of intracellular cisplatin, enhanced resistance to cisplatin. Our findings support NPEPPS as a novel and druggable driver of cisplatin resistance with the potential for rapid translation to clinical investigation.

Project description:Platinum-based chemotherapeutics are used in many combination regimens in cancer. Despite extensive use across diverse cancer types, there is room for improved efficacy and patient selection for treatment. Here, we use bladder cancer to address both issues. A multi-omic assessment of five human bladder cancer cell lines and their chemotherapy resistant derivatives, coupled with in vitro whole-genome CRISPR screens were used to define functional drivers of treatment resistance. We identified 46 genes that sensitized the resistant cell lines to cisplatin plus gemcitabine (GemCis), a standard combination therapy in bladder cancer. Most genes were involved with DNA damage and repair pathways, which have previously been associated with enhanced sensitivity to cisplatin. Evaluating expression of the 46 genes in the whole transcriptome and proteome data in parental and resistant lines identified the puromycin sensitive aminopeptidase, NPEPPS, as a novel hit. Depletion of NPEPPS resulted in sensitizing resistant bladder cancer cells to cisplatin in vitro and in xenograft experiments. Pharmacologic inhibition of NPEPPS with tosedostat in cells and in chemoresistant, bladder cancer patient-derived tumoroids improved response to cisplatin. Prior work found NPEPPS in a protein complex with volume regulated anion channels (VRACs) in several cell line models. Interestingly, depletion of two VRAC subunits, LRRC8A and LRRC8D, known importers of intracellular cisplatin, enhanced resistance to cisplatin. Our findings support NPEPPS as a novel and druggable driver of cisplatin resistance with the potential for rapid translation to clinical investigation.

Project description:Bladder cancer is a major and mortal disease in urological area. Cisplatin is a key drug for bladder cancer especially for muscle invasive cases. In most cases of bladder cancer, cisplatin is effective; however, resistance to cisplatin is critical for patient’s prognosis. Thus, treatment strategy for cisplatin resistant bladder cancer is essential to improve current prognosis. In this study, we established cisplatin resistant bladder cancer line (CR cells) using a urothelial carcinoma line UM-UC-3 cells. We screened potential targets for CR cells and found that claspin is overexpressed in CR cells. Claspin mRNA knockdown revealed that claspin has a role in cisplatin resistance in CR cells. In our previous study, we found HLA-A*02:01-restricted CLSPN peptide by an HLA ligandome analysis. We thus generated CLSPN peptide specific CTL clone and found that CLSPN peptide-specific CTL clone recognized CR cells at higher levels compared with that of UM-UC-3 wild type cells. These findings indicate that claspin is a driver for cisplatin resistance and claspin peptide-specific immunotherapy is effective for cisplatin resistant cases.

Project description:Chemo-resistance to platinum such as cisplatin is critical in the treatment of ovarian cancer. Recent evidences have linked epithelial-mesenchymal transition (EMT) with the drug resistance as a contributing mechanism. The current study explored the connection between cellular responses to cisplatin with EMT in ovarian cancer. 46 ovarian carcinoma cell lines expression data with and without Cisplatin treatment.

Project description:The development of drug resistance is still a major impediment for the successful treatment of cancer, such as advanced stage ovarian cancer, which has a 5-year survival rate of only 30%. The molecular processes that contribute to resistance have been extensively studied, however, not much is known about the role of microRNAs. We compared microRNA expression profiles of three isogenic cisplatin sensitive and resistant cell line pairs. The only microRNA that was consistently downregulated (FDR = 0.000) in all resistant cell lines was miR-634. We investigated the effects of miR-634 modulation in ovarian cancer cell lines and patient derived tumor cells. Overexpression of miR-634 gave rise to a modest G1 phase block and enhanced apoptosis. Furthermore, miR-634 resensitized resistant ovarian cancer cell lines and patient derived tumor cells to cisplatin chemotherapy. Similarly, miR-634 enhanced the response of tumor cells to carboplatin and doxorubicin, but not to paclitaxel. We showed that miR-634 regulates cyclin D1 (CCND1), which is required for the G1-S phase transition, explaining the effects on the cell cycle. In addition, miR-634 repressed expression of GRB2, ERK2, RSK1 and RSK2, components of the Ras-MAPK pathway. Altogether, our findings suggest that miR-634 modulates several cancer relevant targets and therefore miR-634 is an attractive therapeutic candidate to resensitize chemotherapy resistant ovarian tumors. The miRNA expression profile was determined of three cisplatin sensitive/resistant cell line pairs (ovarian cancer cell line pair A2780/A2780 DDP; colon cancer cell line pair HCT8/HCT8 DDP; bladder cancer cell line pairT24/T24 DDP10).

Project description:We previously reported that an aggressive subpopulation of highly tumorigenic, drug-resistant bladder cancer cells can arise from the bulk tumor cells without mutational events and that this phenotypic plasticity is driven at least in part by epigenetic mechanisms. In the current work, we analyzed the chromatin accessibility of enhancers to identify transcription factors that contribute to this transition to a drug-resistant state. Comparing the drug resistant side population (SP) cells and the less drug resistant non-side population (NSP) cells in bladder cancer cells, we identified differential accessible enhancers and differentially expressed genes. Transcription factor motif analysis showed that FOX family motif was enriched in accessible enhancers near SP-overexpressed genes. Among FOX family transcription factors, FOXC1 was the only overexpressed transcription factor, and it was also the most significantly overexpressed gene in SP cells. FOXC1 ChIP-seq confirmed that FOXC1 binding sites are more accessible in SP cells and showed a significantly more FOXC1 binding near the overexpressed genes in SP cells. When the FOXC1 is knocked out, bladder cancer cells exhibit decreased cisplatin resistance and less percentage of SP cells. This change in cisplatin resistance is partially related to the FOXC1-driven expression of ABCB1 gene. In summary, our observations suggest that differential expression and enhancer binding of FOXC1 promotes the previously observed, mutation-independent shift towards cisplatin resistance in bladder cancer.

Project description:We previously reported that an aggressive subpopulation of highly tumorigenic, drug-resistant bladder cancer cells can arise from the bulk tumor cells without mutational events and that this phenotypic plasticity is driven at least in part by epigenetic mechanisms. In the current work, we analyzed the chromatin accessibility of enhancers to identify transcription factors that contribute to this transition to a drug-resistant state. Comparing the drug resistant side population (SP) cells and the less drug resistant non-side population (NSP) cells in bladder cancer cells, we identified differential accessible enhancers and differentially expressed genes. Transcription factor motif analysis showed that FOX family motif was enriched in accessible enhancers near SP-overexpressed genes. Among FOX family transcription factors, FOXC1 was the only overexpressed transcription factor, and it was also the most significantly overexpressed gene in SP cells. FOXC1 ChIP-seq confirmed that FOXC1 binding sites are more accessible in SP cells and showed a significantly more FOXC1 binding near the overexpressed genes in SP cells. When the FOXC1 is knocked out, bladder cancer cells exhibit decreased cisplatin resistance and less percentage of SP cells. This change in cisplatin resistance is partially related to the FOXC1-driven expression of ABCB1 gene. In summary, our observations suggest that differential expression and enhancer binding of FOXC1 promotes the previously observed, mutation-independent shift towards cisplatin resistance in bladder cancer.

Project description:We previously reported that an aggressive subpopulation of highly tumorigenic, drug-resistant bladder cancer cells can arise from the bulk tumor cells without mutational events and that this phenotypic plasticity is driven at least in part by epigenetic mechanisms. In the current work, we analyzed the chromatin accessibility of enhancers to identify transcription factors that contribute to this transition to a drug-resistant state. Comparing the drug resistant side population (SP) cells and the less drug resistant non-side population (NSP) cells in bladder cancer cells, we identified differential accessible enhancers and differentially expressed genes. Transcription factor motif analysis showed that FOX family motif was enriched in accessible enhancers near SP-overexpressed genes. Among FOX family transcription factors, FOXC1 was the only overexpressed transcription factor, and it was also the most significantly overexpressed gene in SP cells. FOXC1 ChIP-seq confirmed that FOXC1 binding sites are more accessible in SP cells and showed a significantly more FOXC1 binding near the overexpressed genes in SP cells. When the FOXC1 is knocked out, bladder cancer cells exhibit decreased cisplatin resistance and less percentage of SP cells. This change in cisplatin resistance is partially related to the FOXC1-driven expression of ABCB1 gene. In summary, our observations suggest that differential expression and enhancer binding of FOXC1 promotes the previously observed, mutation-independent shift towards cisplatin resistance in bladder cancer.

Project description:Cisplatin resistance is a problem in cancer treatment. Using DNA microarray, we detected differentially expressed genes in cisplatin-resistant cervix carcinoma HeLa cells compared to parental cells. Three cisplatin resistant cell lines were established by stepwise increasing cisplatin concentration. RNA from these resistant lines and its parental HeLa cells were labeled with Cy5 and Cy3. Equal amount of RNA from resistant cell line and HeLa were mixed and were hybridized to cDNA array. Signals were scanned and analyzed to find out the candidate genes involved in cisplatin resistant mechanism.

Project description:Cisplatin resistance is a major therapeutic challenge in advanced head and neck squamous cell carcinoma (HNSCC). Here, we aimed to investigate the key signaling pathway for cisplatin resistance in HNSCC cells. HNSCC cell lines that were sensitive (HN4 and HN30) or resistant (HN4/DDP and HN30/DDP) to cisplatin were used for this study. Moreover, the cisplatin-resistant human melanoma cell lines (A375/DDP) and human lung cancer cell lines (A549/DDP) have also been established. To identify the role of proteins in the acquisition of cisplatin resistance, we analyzed the abnormally expressed protein via protein mass spectrometry methods (isobaric tags for relative and absolute quantitation, iTRAQ) in cisplatin-sensitive and cisplatin-resistant cancer cells, and found that VN1R5 was highly expressed in cisplatin-resistant cells. Long noncoding RNA lnc-POP1-1 upregulated by VN1R5. To deeply investigate the mechanism by which lnc-POP1-1 affects cisplatin resistance in HNSCC cells, we used RNA pull-down assays followed by mass spectrometry to explore the putative RNA-binding proteins (RBPs) interacting with lnc-POP1-1.