Project description:Epithelial ovarian cancer is the leading cause of death from gynecological malignancies. Currently platinum-based chemotherapy, coupled with a taxane based drug is the primary treatment for ovarian cancer. Approximately 25% of patients either present with or rapidly develop resistance to platinum based chemotherapy and all recurrent tumors ultimately become resistant. Epigenetic modifications have been associated with tumor formation and progression and may contribute to therapy response. We performed a methylation screen on a set of tumors and have found a number of genes and family members differentially methylated between resistant patients and sensitive patients. Here we show that loss of expression of CHD3, a member of the Mi-2/NuRD complex, causes increased resistance to platinum chemotherapy drugs. Additionally, ovarian cell lines transcriptionally silenced for CHD3 are more invasive, have migratory ability, and display a transformed epithelial to mesenchymal (EMT) phenotype. Taken together, we provide the first evidence of a role for CHD3 as an important epigenetic regulator of chemoresistance in ovarian cancer and hypothesize EMT as one of the underlying mechanisms. Furthermore, CHD3 expression might represent a therapy response predictor and could be a future therapeutic target for ovarian cancer. We have developed a method to profile genome wide methylation. 71 ovarian tumor samples and 9 normal tissue samples from individuals were analyzed for CpG methylation. Some of these regions were validated for their methylation as a proof of principle for the method. Kamalakaran S., et. al. Mol Oncol. 2011;5:77-92 (PMID: 21169070).

Project description:Background: Resistance to platinum-based chemotherapy remains a major impediment in the treatment of serous epithelial ovarian cancer. The objective of this study was to use gene expression profiling to delineate major deregulated pathways and biomarkers associated with the development of intrinsic chemotherapy resistance upon exposure to standard first-line therapy for ovarian cancer. Methods: The study cohort comprised 28 patients divided into two groups based on their varying sensitivity to first-line chemotherapy using progression free survival (PFS) as a surrogate of response. All 28 patients had advanced stage, high-grade serous ovarian cancer, and were treated with the same standard platinum-based chemotherapy. Twelve patient tumors demonstrating relative resistance to platinum chemotherapy corresponding to shorter PFS (< eight months) were compared to sixteen tumors from platinum-sensitive patients (PFS > eighteen months). Whole transcriptome profiling was performed using a Affymetrix high-resolution microarray platform to permit global comparisons of gene expression profiles between tumors from the resistant group and the sensitive group. Results: Microarray data analysis revealed a set of 204 discriminating genes possessing expression levels, which could influence differential chemotherapy response between the two groups. Robust statistical testing was then performed which eliminated a dependence on the normalization algorithm employed, producing a restricted list of differentially regulated genes, and which found IGF1 to be the most strongly differentially expressed gene. Pathway analysis, based on the list of 204 genes, revealed enrichment in genes primarily involved in the IGF1/PI3K/NFκB/ERK gene signalling networks. Conclusions: This study has identified pathway specific prognostic biomarkers possibly underlying a differential chemotherapy response in patients undergoing standard platinum-based treatment of serous epithelial ovarian cancer. Future studies to validate these markers are necessary to apply this knowledge to biomarker-based clinical trials. Total RNA from 12 chemotherapy resistant and 16 sensitive chemotherapy sensitive high-grade serous epithelial ovarian cancer samples was subjected to whole transcriptome profiling using Affymetrix U133 Plus 2.0 arrays

Project description:Pemetrexed is a drug largely used in lung cancer, mesothelioma and proposed in some cases of ovarian cancers, a particularly severe cancer type. In this latest tumor type, therapy relies on debulking surgery and platinum-based chemotherapy. Despite the initial high response rates to platinum drugs, most patients relapse and die from the disease. Considering the high levels of thymidylate synthase, dhydrofolate reductase and other folate related proteins in platinum drug resistant patients, pemetrexed was proposed as a second line drugs due to its known mechanism of action that engage the mentioned proteins. However a successful outcome could only be expected on the basis of patients’ stratifications. In the present study, a discovery proteomics approach was applied to tissue samples collected beforepemetrexed treatment from platinum resistant patients who relapsed after the first-line carboplatin-based chemotherapy but responded differently to the pemetrexed treatment.

Project description:Background: Resistance to platinum-based chemotherapy remains a major impediment in the treatment of serous epithelial ovarian cancer. The objective of this study was to use gene expression profiling to delineate major deregulated pathways and biomarkers associated with the development of intrinsic chemotherapy resistance upon exposure to standard first-line therapy for ovarian cancer. Methods: The study cohort comprised 28 patients divided into two groups based on their varying sensitivity to first-line chemotherapy using progression free survival (PFS) as a surrogate of response. All 28 patients had advanced stage, high-grade serous ovarian cancer, and were treated with the same standard platinum-based chemotherapy. Twelve patient tumors demonstrating relative resistance to platinum chemotherapy corresponding to shorter PFS (< eight months) were compared to sixteen tumors from platinum-sensitive patients (PFS > eighteen months). Whole transcriptome profiling was performed using a Affymetrix high-resolution microarray platform to permit global comparisons of gene expression profiles between tumors from the resistant group and the sensitive group. Results: Microarray data analysis revealed a set of 204 discriminating genes possessing expression levels, which could influence differential chemotherapy response between the two groups. Robust statistical testing was then performed which eliminated a dependence on the normalization algorithm employed, producing a restricted list of differentially regulated genes, and which found IGF1 to be the most strongly differentially expressed gene. Pathway analysis, based on the list of 204 genes, revealed enrichment in genes primarily involved in the IGF1/PI3K/NFκB/ERK gene signalling networks. Conclusions: This study has identified pathway specific prognostic biomarkers possibly underlying a differential chemotherapy response in patients undergoing standard platinum-based treatment of serous epithelial ovarian cancer. Future studies to validate these markers are necessary to apply this knowledge to biomarker-based clinical trials.

Project description:Purpose: Despite advances in radical surgery and chemotherapy delivery, ovarian cancer is the most lethal gynecologic malignancy. Most of these patients are treated with platinum-based chemotherapies, but there is no biomarker model to guide their responses to these therapeutic agents. We have developed and independently tested our novel multivariate molecular predictors for forecasting patients' responses to individual drugs on a cohort of 58 ovarian cancer patients. Experimental Design: We adapted and applied the previously-published COXEN algorithm to develop molecular predictors for therapeutic responses of patients' tumors based on expression signatures derived from the NCI-60 in vitro drug activities and genomic expression data. Genome-wide candidate biomarkers were first triaged by examining expression patterns of frozen and formalin-fixed paraffin embedded (FFPE) tissue samples. We then identify initial drug sensitivity biomarkers for carboplatin and paclitaxel, respectively. These biomarkers were further narrowed by examining concordant expression patterns between cell lines and a historical set of ovarian cancer patients. Multivariate predictors were obtained from the NCI-60 cell lines and refined using historical patient cohorts. To independent validate these molecular predictors, we performed genome-wide profiling on FFPE samples of 58 ovarian cancer patients obtained prior to adjuvant chemotherapy. Results: Carboplatin predictor significantly stratified platinum sensitive and resistant patients (p = 0.019) with sensitivity = 93%, specificity = 33%, PPV = 65%, and NPV = 78%. Paclitaxel predictor also significantly stratified patients' responses (p = 0.033) with sensitivity = 96%, specificity = 26%, PPV = 61%, and NPV = 86%. The combination predictor for platinum-taxane combination demonstrated a significant survival difference between the predicted responders and nonresponders with median survival of 12.9 months vs. 8.1 months (p = 0.045). Conclusions: COXEN predictors successfully stratified platinum resistance and taxane response in this retrospective cohort, especially based on their FFPE tumor samples. Accurate prediction of chemotherapeutic response, especially to platinum agents is highly clinically relevant and could alter primary management of ovarian cancer. Gene expression data from 58 stage III-IV ovarian cancer patients treated with Carboplatin and Taxol agents

Project description:Changes in chromatin organization are associated with resistance to anti-cancer drugs, such as platinum-based chemotherapy used as the primary treatment of ovarian cancer. We have examined the genomic distribution of chromatin accessibility changes, and relationship to gene expression changes, occurring during acquisition of resistance in vivo of high grade serous ovarian cancer (HGSOC) patients and whether this associates with genomic DNA damage distribution. Using matched chemo-sensitive and chemo-resistant ovarian cell lines isolated from HGSOC patients before and following acquisition of clinical resistance to platinum-based chemotherapy, we have examined the relationship between chromatin accessibility by ATAC-seq, platinum-DNA adduct distribution by Pt-Exo-seq and gene expression by RNA-seq. We have correlated chromatin changes between the lines at gene promoters, CpG islands, enhancer sequences and other genomic regions with changes in gene expression and platinum-DNA adduct distribution. We observe chromatin conformation differences following acquisition of platinum-resistance, with the HGSOC resistant lines clustering together, separately from their respective sensitive counterparts. Resistant lines show altered chromatin accessibility at intergenic regions, but less so at gene promoters. Super-enhancers, as defined by clusters of cis-regulatory elements, at these intergenic regions show chromatin changes that are associated with altered expression of linked genes, with enrichment for genes involved in the Fanconi anemia/BRCA DNA damage response pathway. Genome-wide distribution of platinum adducts associates with the chromatin changes and distinguish sensitive from resistant lines. Regions incurring fewer platinum-adducts showed a significant reduction in accessibility the resistant HGSOC cell line PEO4 compared to the sensitive PEO1 counterpart. Surprisingly, regions showing increased damage in PEO4 had an even greater reduction in accessibility. In the resistant line, we observe fewer adducts around gene promoters and more adducts at intergenic regions. In cell lines derived from patients following acquisition of clinical resistance to platinum-based chemotherapy, chromatin changes at super-enhancers correlate with gene expression changes in DNA repair pathways known to influence platinum sensitivity. Although cisplatin is a relatively non-specific DNA damaging agent, there are consistent differences in distribution of adducts between the matched sensitive and resistant ovarian cell lines, which is independent of the overall level of adducts formed.

Project description:Changes in chromatin organization are associated with resistance to anti-cancer drugs, such as platinum-based chemotherapy used as the primary treatment of ovarian cancer. We have examined the genomic distribution of chromatin accessibility changes, and relationship to gene expression changes, occurring during acquisition of resistance in vivo of high grade serous ovarian cancer (HGSOC) patients and whether this associates with genomic DNA damage distribution. Using matched chemo-sensitive and chemo-resistant ovarian cell lines isolated from HGSOC patients before and following acquisition of clinical resistance to platinum-based chemotherapy, we have examined the relationship between chromatin accessibility by ATAC-seq, platinum-DNA adduct distribution by Pt-Exo-seq and gene expression by RNA-seq. We have correlated chromatin changes between the lines at gene promoters, CpG islands, enhancer sequences and other genomic regions with changes in gene expression and platinum-DNA adduct distribution. We observe chromatin conformation differences following acquisition of platinum-resistance, with the HGSOC resistant lines clustering together, separately from their respective sensitive counterparts. Resistant lines show altered chromatin accessibility at intergenic regions, but less so at gene promoters. Super-enhancers, as defined by clusters of cis-regulatory elements, at these intergenic regions show chromatin changes that are associated with altered expression of linked genes, with enrichment for genes involved in the Fanconi anemia/BRCA DNA damage response pathway. Genome-wide distribution of platinum adducts associates with the chromatin changes and distinguish sensitive from resistant lines. Regions incurring fewer platinum-adducts showed a significant reduction in accessibility the resistant HGSOC cell line PEO4 compared to the sensitive PEO1 counterpart. Surprisingly, regions showing increased damage in PEO4 had an even greater reduction in accessibility. In the resistant line, we observe fewer adducts around gene promoters and more adducts at intergenic regions. In cell lines derived from patients following acquisition of clinical resistance to platinum-based chemotherapy, chromatin changes at super-enhancers correlate with gene expression changes in DNA repair pathways known to influence platinum sensitivity. Although cisplatin is a relatively non-specific DNA damaging agent, there are consistent differences in distribution of adducts between the matched sensitive and resistant ovarian cell lines, which is independent of the overall level of adducts formed.

Project description:Changes in chromatin organization are associated with resistance to anti-cancer drugs, such as platinum-based chemotherapy used as the primary treatment of ovarian cancer. We have examined the genomic distribution of chromatin accessibility changes, and relationship to gene expression changes, occurring during acquisition of resistance in vivo of high grade serous ovarian cancer (HGSOC) patients and whether this associates with genomic DNA damage distribution. Using matched chemo-sensitive and chemo-resistant ovarian cell lines isolated from HGSOC patients before and following acquisition of clinical resistance to platinum-based chemotherapy, we have examined the relationship between chromatin accessibility by ATAC-seq, platinum-DNA adduct distribution by Pt-Exo-seq and gene expression by RNA-seq. We have correlated chromatin changes between the lines at gene promoters, CpG islands, enhancer sequences and other genomic regions with changes in gene expression and platinum-DNA adduct distribution. We observe chromatin conformation differences following acquisition of platinum-resistance, with the HGSOC resistant lines clustering together, separately from their respective sensitive counterparts. Resistant lines show altered chromatin accessibility at intergenic regions, but less so at gene promoters. Super-enhancers, as defined by clusters of cis-regulatory elements, at these intergenic regions show chromatin changes that are associated with altered expression of linked genes, with enrichment for genes involved in the Fanconi anemia/BRCA DNA damage response pathway. Genome-wide distribution of platinum adducts associates with the chromatin changes and distinguish sensitive from resistant lines. Regions incurring fewer platinum-adducts showed a significant reduction in accessibility the resistant HGSOC cell line PEO4 compared to the sensitive PEO1 counterpart. Surprisingly, regions showing increased damage in PEO4 had an even greater reduction in accessibility. In the resistant line, we observe fewer adducts around gene promoters and more adducts at intergenic regions. In cell lines derived from patients following acquisition of clinical resistance to platinum-based chemotherapy, chromatin changes at super-enhancers correlate with gene expression changes in DNA repair pathways known to influence platinum sensitivity. Although cisplatin is a relatively non-specific DNA damaging agent, there are consistent differences in distribution of adducts between the matched sensitive and resistant ovarian cell lines, which is independent of the overall level of adducts formed.

Project description:Resistance to platinum-based chemotherapy is a clinical challenge in the treatment of ovarian cancer (OC) and limits survival. Therefore, innovative drugs against platinum-resistance are urgently needed. Our therapeutic concept is based on the conjugation of two chemotherapeutic compounds to a monotherapeutic pro-drug, which is taken up by cancer cells and cleaved into active cytostatic metabolites. Here, we explore the activity of the duplex-prodrug 5-FdU-ECyd, covalently linking 2'-deoxy-5-fluorouridine (5-FdU) and 3'-C-ethynylcytidine (ECyd), on platinum-resistant OC cells. RNA-Sequencing was used for characterization of 5-FdU-ECyd treated platinum-sensitive A2780 and isogenic platinum-resistant A2780cis.

Project description:Purpose: Despite advances in radical surgery and chemotherapy delivery, ovarian cancer is the most lethal gynecologic malignancy. Most of these patients are treated with platinum-based chemotherapies, but there is no biomarker model to guide their responses to these therapeutic agents. We have developed and independently tested our novel multivariate molecular predictors for forecasting patients' responses to individual drugs on a cohort of 58 ovarian cancer patients. Experimental Design: We adapted and applied the previously-published COXEN algorithm to develop molecular predictors for therapeutic responses of patients' tumors based on expression signatures derived from the NCI-60 in vitro drug activities and genomic expression data. Genome-wide candidate biomarkers were first triaged by examining expression patterns of frozen and formalin-fixed paraffin embedded (FFPE) tissue samples. We then identify initial drug sensitivity biomarkers for carboplatin and paclitaxel, respectively. These biomarkers were further narrowed by examining concordant expression patterns between cell lines and a historical set of ovarian cancer patients. Multivariate predictors were obtained from the NCI-60 cell lines and refined using historical patient cohorts. To independent validate these molecular predictors, we performed genome-wide profiling on FFPE samples of 58 ovarian cancer patients obtained prior to adjuvant chemotherapy. Results: Carboplatin predictor significantly stratified platinum sensitive and resistant patients (p = 0.019) with sensitivity = 93%, specificity = 33%, PPV = 65%, and NPV = 78%. Paclitaxel predictor also significantly stratified patients' responses (p = 0.033) with sensitivity = 96%, specificity = 26%, PPV = 61%, and NPV = 86%. The combination predictor for platinum-taxane combination demonstrated a significant survival difference between the predicted responders and nonresponders with median survival of 12.9 months vs. 8.1 months (p = 0.045). Conclusions: COXEN predictors successfully stratified platinum resistance and taxane response in this retrospective cohort, especially based on their FFPE tumor samples. Accurate prediction of chemotherapeutic response, especially to platinum agents is highly clinically relevant and could alter primary management of ovarian cancer.