Project description:We demonstrate that, in human bladder cancer, amplification of the E2F3 gene, located at 6p22, is associated with overexpression of its encoded mRNA transcripts and high levels of expression of E2F3 protein. Immunohistochemical analyses of E2F3 protein levels have established that around one-third (33/101) of primary transitional cell carcinomas of the bladder overexpress nuclear E2F3 protein, with the proportion of tumours containing overexpressed nuclear E2F3 increasing with tumour stage and grade. When considered together with the established role of E2F3 in cell cycle progression, these results suggest that the E2F3 gene represents a candidate bladder cancer oncogene that is activated by DNA amplification and overexpression. Keywords: Tumour vs normal comparison, array CGH

Project description:Background: Previous array CGH analyses have revealed several recurring genomic alterations in urothelial carcinoma. The most common genomic amplifications occur at 6p22 and 1q21-24. The main target gene at 6p22 is believed to be E2F3. This gene is frequently co-amplified with CDKAL1 and SOX4 and there are reports on 6p22 amplifications that do not include the E2F3 locus. Previous array CGH analyses have indicated multiple possible target regions at 1q21-24. However, due to complex rearrangements it has been difficult to identify specific 1q21-24 target regions and target genes. Results: We show that the most commonly amplified gene at 6p22 is SOX4 and that SOX4 can be amplified and over expressed without E2F3 or CDKAL1 being included in the amplicon. Hence, our data point to SOX4 as an auxiliary amplification target at 6p22. We further show that at least three amplified regions are observed at 1q21-24. Copy number data, combined with gene expression data, highlighted BCL9 and CHD1L as possible targets in the most proximal region and MCL1, SETDB1, and HIF1B as targets in the middle region, whereas no obvious gene targets could be determined in the most distal amplicon. We also highlight the enrichment of G4 quadruplex sequence motifs and the high number of intraregional sequence duplications, both known to contribute to genomic instability, as prominent features of the 1q21-24 region. Conclusions: Our detailed analyses of the 6p22 amplicon in urothelial carcinomas suggest SOX4 as an auxiliary target gene for amplification. We further demonstrate three separate target regions for amplification at 1q21-24 and identified BCL9, CHD1L, MCL1, SETDB1, and HIF1B as likely target genes within these regions.

Project description:Background: Previous array CGH analyses have revealed several recurring genomic alterations in urothelial carcinoma. The most common genomic amplifications occur at 6p22 and 1q21-24. The main target gene at 6p22 is believed to be E2F3. This gene is frequently co-amplified with CDKAL1 and SOX4 and there are reports on 6p22 amplifications that do not include the E2F3 locus. Previous array CGH analyses have indicated multiple possible target regions at 1q21-24. However, due to complex rearrangements it has been difficult to identify specific 1q21-24 target regions and target genes. Results: We show that the most commonly amplified gene at 6p22 is SOX4 and that SOX4 can be amplified and over expressed without E2F3 or CDKAL1 being included in the amplicon. Hence, our data point to SOX4 as an auxiliary amplification target at 6p22. We further show that at least three amplified regions are observed at 1q21-24. Copy number data, combined with gene expression data, highlighted BCL9 and CHD1L as possible targets in the most proximal region and MCL1, SETDB1, and HIF1B as targets in the middle region, whereas no obvious gene targets could be determined in the most distal amplicon. We also highlight the enrichment of G4 quadruplex sequence motifs and the high number of intraregional sequence duplications, both known to contribute to genomic instability, as prominent features of the 1q21-24 region. Conclusions: Our detailed analyses of the 6p22 amplicon in urothelial carcinomas suggest SOX4 as an auxiliary target gene for amplification. We further demonstrate three separate target regions for amplification at 1q21-24 and identified BCL9, CHD1L, MCL1, SETDB1, and HIF1B as likely target genes within these regions. The study was conducted on genomic DNA from 68 primary fresh-frozen urothelial carcinoma tumors analysed using a Agilent SurePrint G3 4x180k Custom CGH Microarray Platform (028432). Samples were selected based on the presence of copy number alterations observed on lower resolution genomic data (32K BAC array). The majority of the BAC data is publicly available in GEO submissions GSE32535 and GSE19915. CN profiles for a minority of samples were derived from Illumina Methylation27k arrays according to Lauss et al 2012 [PMID: 22705924] and can be recreated from the data deposited in GSE33510 (derived CN data). Sample names are the same between all studies. This dataset also partly overlaps with Series GSE32894 (gene expression data). Names of the overlapping sample names are the same and indicated in the description field. Data from GSE32894 was used to calculate correlations between CN and gene expression.

Project description:The activating E2F-transcription factors are best known for their dependence on the Retinoblastoma protein and their role in cellular proliferation. E2F3 is uniquely amplified in specific human tumours where its expression is inversely correlated with the survival of patients. Here, E2F3 interaction partners were identified by mass spectrometric analysis. We show that the SNF2-like HELLS interacts with E2F3 in vivo and cooperates with its oncogenic functions. Depletion of HELLS severely perturbs the induction of E2F-target genes, hinders cell cycle re-entry and growth. Using chromatin immmunoprecipitation coupled to sequencing we identified genome-wide targets of HELLS and E2F3. Our analysis revealed that HELLS binds near promoters of active genes, including the trithorax-related MLL1, and co-regulates E2F3-dependent genes. Our analysis is the first to link HELLS with E2F-controlled processes that are critical to establish a proliferative tumour circuitry. Strikingly, just as E2F3, HELLS is overexpressed in human tumours including prostate cancer, indicating that either factor may contribute to the malignant progression of tumours. Our work reveals that HELLS is important for E2F3 in tumour cell proliferation. Examination of E2F3, Hells, and H3K27me3 in 2 cell types.

Project description:Role of E2F3 expression in human bladder and prostate cancer cells

Project description:The activating E2F-transcription factors are best known for their dependence on the Retinoblastoma protein and their role in cellular proliferation. E2F3 is uniquely amplified in specific human tumours where its expression is inversely correlated with the survival of patients. Here, E2F3 interaction partners were identified by mass spectrometric analysis. We show that the SNF2-like HELLS interacts with E2F3 in vivo and cooperates with its oncogenic functions. Depletion of HELLS severely perturbs the induction of E2F-target genes, hinders cell cycle re-entry and growth. Using chromatin immmunoprecipitation coupled to sequencing we identified genome-wide targets of HELLS and E2F3. Our analysis revealed that HELLS binds near promoters of active genes, including the trithorax-related MLL1, and co-regulates E2F3-dependent genes. Our analysis is the first to link HELLS with E2F-controlled processes that are critical to establish a proliferative tumour circuitry. Strikingly, just as E2F3, HELLS is overexpressed in human tumours including prostate cancer, indicating that either factor may contribute to the malignant progression of tumours. Our work reveals that HELLS is important for E2F3 in tumour cell proliferation.

Project description:Bladder cancer is common and one of the most costly cancer forms, due to a lack of curative therapies. Recently, clinical safety and efficacy of the alpha1-oleate complex was demonstrated in a placebo-controlled study of non-muscle invasive bladder cancer. This study investigated if long-term therapeutic efficacy is improved by repeated treatment cycles and by combining alpha1-oleate with low-dose chemotherapy. Rapidly growing bladder tumors were treated by intravesical instillation of alpha1-oleate, Epirubicin or Mitomycin C alone or in combination. One treatment cycle arrested tumor growth, with a protective effect lasting at least four weeks in mice receiving 8.5 mM of alpha1-oleate alone or 1.7 mM of alpha-oleate combined with Epirubicin or Mitomycin C. Repeated treatment cycles extended protection, defined by a lack of bladder pathology and a virtual absence of bladder cancer-specific gene expression. Synergy with Epirubicin was detected at the lower alpha1-oleate concentration and alpha1-oleate was shown to enhance the uptake and nuclear translocation of Epirubicin, by tumor cells. Effects at the chromatin level affecting cell proliferation were further suggested by reduced BrdU incorporation. In addition, alpha1-oleate triggered DNA fragmentation, defined by the TUNEL assay. The results suggest that bladder cancer development may be prevented long-term in the murine model, by alpha1-oleate alone or in combination with low-dose Epirubicin. In addition, the combination of alpha1-oleate and Epirubicin reduced the size of established tumors. Exploring these potent preventive and therapeutic effects will be of immediate interest in patients with bladder cancer.

Project description:Bladder cancer is common and one of the most costly cancer forms, due to a lack of curative therapies. Recently, clinical safety and efficacy of the alpha1-oleate complex was demonstrated in a placebo-controlled study of non-muscle invasive bladder cancer. This study investigated if long-term therapeutic efficacy is improved by repeated treatment cycles and by combining alpha1-oleate with low-dose chemotherapy. Rapidly growing bladder tumors were treated by intravesical instillation of alpha1-oleate, Epirubicin or Mitomycin C alone or in combination. One treatment cycle arrested tumor growth, with a protective effect lasting at least four weeks in mice receiving 8.5 mM of alpha1-oleate alone or 1.7 mM of alpha-oleate combined with Epirubicin or Mitomycin C. Repeated treatment cycles extended protection, defined by a lack of bladder pathology and a virtual absence of bladder cancer-specific gene expression. Synergy with Epirubicin was detected at the lower alpha1-oleate concentration and alpha1-oleate was shown to enhance the uptake and nuclear translocation of Epirubicin, by tumor cells. Effects at the chromatin level affecting cell proliferation were further suggested by reduced BrdU incorporation. In addition, alpha1-oleate triggered DNA fragmentation, defined by the TUNEL assay. The results suggest that bladder cancer development may be prevented long-term in the murine model, by alpha1-oleate alone or in combination with low-dose Epirubicin. In addition, the combination of alpha1-oleate and Epirubicin reduced the size of established tumors. Exploring these potent preventive and therapeutic effects will be of immediate interest in patients with bladder cancer.

Project description:Long-lasting changes in neuronal gene expression in brain reward regions, including the nucleus accumbens (NAc), contribute to the persistent functional changes in the addicted brain. Our group and others have demonstrated that altered expression or activity of several candidate transcription factors in NAc regulates drug responses. In a recent study from our group (Feng et al., 2014), involving large-scale genome-wide datasets, E2F3 was predicted as a prominent upstream regulator of cocaine-induced changes in gene expression and alternative splicing. Here, we show that E2F3a, but not E2F3b, expression in NAc regulates cocaine-induced locomotor and reward behavior. Furthermore, we demonstrate that E2F3a overexpression recapitulates a considerable portion of genome-wide transcriptional profiles and alternative splicing induced by cocaine administration. We further validate functional binding of E2F3a at several target genes following cocaine exposure. These novel findings support a crucial role for E2F3a in the regulation of cocaine-elicited behavioral states and molecular mechanisms.

Project description:Translocations of ETS transcription factors are driver mutations in diverse cancers. We investigated the genomic network of the ETS fusion EWS/FLI1 in Ewing's sarcoma (ESFT) as a model of ETS-driven tumorigenesis. ChIP-Seq and transcriptional analysis identified E2F3 as a principle co-factor of EWSFLI1 defining functionally distinct gene sets. While EWS/FLI1 binding independent of E2F3 predominantly associated with repressed differentiation genes, significant co-localization with E2F3 was discovered at proximal promoters of activated growth-related genes. Thus, EWS/FLI1 promotes oncogenesis by simultaneously perturbing differentiation state and augmenting the expression of genes co-regulated by E2F3. Integration of additional E2F3 and ERG localization data from prostate cancer containing TMPRSS2/ERG verified that the ETS-E2F module is also found in prostate cancer and may be of general relevance to ETS driven cancers. Timecourse with 6 timepoints of a doxicyclin inducible EWS-FLI1 knockdown in the A673 Ewing's Sarcoma celline