Project description:Identification and characterization of epigenetically silenced genes is very important for cancer research. Particularly, information of hypermethylated genes provides clues to understand roles of epigenetics in tumorigeneses, and genes frequently methylated in a tumor-specific manner can be used as tumor markers. DNA methylation inhibitors such as 5-aza-cytidine or 5-aza-2M-bM-^@M-^Y-deoxycytidine were widely used to search epigenetically silenced genes. However, these inhibitors frequently upregulate genes whose promoters remain unmethylated. We tried to improve the specificity and sensitivity in detecting such methylation-mediated silenced genes in cancer and successfully developed a new method termed M-bM-^@M-^\methyl-CpG targeted transcriptional activation (MeTA)M-bM-^@M-^] by using a transcriptional activating fragment with a methyl-CpG binding domain (MBD) that specifically recognizes and binds to methylated DNAs. Because MBD proteins in fact mediate transcriptional repression of tumor suppressor genes associated with promoter hypermethylation in cancer, MeTA is thought to be one of the ideal methods to search such genes. In the present study, we applied this method to three representative pancreatic cancer cell lines, AsPC-1, MIA PaCa-2, and PANC-1, with a normal pancreatic ductal epithelial cell line HPDE (as the control). All of these cell lines have already been analyzed their expression profiles by 5-aza-2M-bM-^@M-^Y-deoxycytidine. We first analyzed the expression of five genes by RT-PCR with Southern hybridization, NEFH, NPTX2, SFRP1, TIMP3, and UCHL1; these genes are known to be methylated in at least any one of these cancer cell lines. Upregulation by M-bM-^@M-^\MeTAM-bM-^@M-^] was confirmed in all of these genes. Then we searched for upregulated-genes, by two-folds or more, in all the three cancer cell lines after MeTA; nineteen such upregulated genes were identified. Among these, sixteen genes except NEFH, HOXA9, and CLDN5 have not been reported previously using the conventional DNA methylation inhibitors. Methylation status of two genes, SLC32A1 and CSMD2, were further analyzed by methylation-specific PCR and found that SLC32A1 and CSMD2 were methylated in 100% (21/21) and 83% (15/18) pancreatic cancer cell lines analyzed, respectively. Our results suggest that M-bM-^@M-^\MeTAM-bM-^@M-^] is a highly efficient method to isolate methylation-mediated transcriptionally silenced genes in human pancreatic cancer and that this method can be applied to other types of human cancer. Three representative pancreatic cancer cell lines, AsPC-1, MIA PaCa-2, and PANC-1, with a normal pancreatic ductal epithelial cell line HPDE (as the control) were transfected with pcDNA6/myc-His vector or pcDNA6-3xFLAG-NFkB (AD)-MBD and were harvested 48 h after transfection.

Project description:Aberrant DNA hypermethylation, the most well defined epigenetic changes in cancer, is associated with inappropriate gene silencing and this feature is utilized to search for tumor-specific DNA methylation biomarkers. Methyl-CpG binding domain (MBD) proteins (MBPs) can elicit the repressive potential of methylated DNA and play a major role in gene silencing mechanisms. Therefore, if the genes governed by MBPs are specifically reactivated, it should be possible to uncover them. We developed a method termed “methyl-CpG targeted transcriptional activation (MeTA)” that employs a fusion gene comprised of the MBD from MBD2 and the NFkB transcriptional activation domain. Microarray coupled with MeTA (MeTA-array) provides not only the information about methylated genes but also the one about transcriptional repression in a single experiment. We applied MeTA-array to 12 pancreatic cancer cell lines along with HPDE (normal pancreatic ductal epithelial cell line) and identified 31 candidate tumor-specific hypermethylated genes; 26 of them have never been reported previously using the conventional DNA demethylating agents. Seven genes, IRX4, LHX6, NEFH, NEFL, NEFM, NPTX2 and TMEM204 were further examined their methylation statuses by MSP, and we found that 100% (21/21) of IRX4, 62% (13/21) of LHX6, 100% (21/21) of NEFH, 100% (21/21) of NEFL, 100% (21/21) of NEFM, 100% (21/21) of NPTX2 and 95% (20/21) of TMEM204 were methylated in our series of pancreatic cancer cell lines. Furthermore, 68% (15/22) of IRX4, 55% (12/22) of LHX6, 55% (12/22) of NEFH, 59% (23/22) of NEFL, 82% (18/22) of NEFM and 82% (18/22) of NPTX2 were also hypermethylated in primary pancreatic cancer specimens in a tumor-specific manner. Our results suggest that MeTA-array is a highly efficient method to identify methylation-mediated transcriptionally silenced genes in human cancer.

Project description:Identification and characterization of epigenetically silenced genes is very important for cancer research. Particularly, information of hypermethylated genes provides clues to understand roles of epigenetics in tumorigeneses, and genes frequently methylated in a tumor-specific manner can be used as tumor markers. DNA methylation inhibitors such as 5-aza-cytidine or 5-aza-2’-deoxycytidine were widely used to search epigenetically silenced genes. However, these inhibitors frequently upregulate genes whose promoters remain unmethylated. We tried to improve the specificity and sensitivity in detecting such methylation-mediated silenced genes in cancer and successfully developed a new method termed “methyl-CpG targeted transcriptional activation (MeTA)” by using a transcriptional activating fragment with a methyl-CpG binding domain (MBD) that specifically recognizes and binds to methylated DNAs. Because MBD proteins in fact mediate transcriptional repression of tumor suppressor genes associated with promoter hypermethylation in cancer, MeTA is thought to be one of the ideal methods to search such genes. In the present study, we applied this method to three representative pancreatic cancer cell lines, AsPC-1, MIA PaCa-2, and PANC-1, with a normal pancreatic ductal epithelial cell line HPDE (as the control). All of these cell lines have already been analyzed their expression profiles by 5-aza-2’-deoxycytidine. We first analyzed the expression of five genes by RT-PCR with Southern hybridization, NEFH, NPTX2, SFRP1, TIMP3, and UCHL1; these genes are known to be methylated in at least any one of these cancer cell lines. Upregulation by “MeTA” was confirmed in all of these genes. Then we searched for upregulated-genes, by two-folds or more, in all the three cancer cell lines after MeTA; nineteen such upregulated genes were identified. Among these, sixteen genes except NEFH, HOXA9, and CLDN5 have not been reported previously using the conventional DNA methylation inhibitors. Methylation status of two genes, SLC32A1 and CSMD2, were further analyzed by methylation-specific PCR and found that SLC32A1 and CSMD2 were methylated in 100% (21/21) and 83% (15/18) pancreatic cancer cell lines analyzed, respectively. Our results suggest that “MeTA” is a highly efficient method to isolate methylation-mediated transcriptionally silenced genes in human pancreatic cancer and that this method can be applied to other types of human cancer.

Project description:Epigenetic gene silencing induced by aberrant DNA methylation is an important mechanism leading to the loss of key cellular pathways in tumorigenesis. Although DNA demethylating agents reverse DNA methylation and have significant cytostatic and cytotoxic effects, it remains elusive whether their effects on cellular phenotypes are solely on reactivation of hypermethylated genes. To address this issue, we constructed LNCaP-derived human prostate cancer cell lines that can pharmacologically induce the expression of fusion gene comprising NFkB transcriptional activation domain (AD) and methyl-CpG binding domain (MBD). Tetracycline induction of NFkB (AD)-MBD protein led to so-called methyl-CpG targeted transcriptional activation (MeTA), as demonstrated by the reactivation of hypermethylated genes such as MT1M, NEFH, and NEFM. The cell proliferation assay indicated that MeTA suppressed the growth of LNCaP cells. Furthermore, both flow cytometry and TUNEL assay clearly demonstrated that MeTA induced apoptosis. In order to search genes responsible for apoptosis, we performed gene expression microarray analysis of MeTA-uninduced and -induced LNCaP cells: Several tumor necrosis factor receptor superfamily (TNFRSF) genes upregulated in accordance with the induction of MeTA. These results suggest that DNA methylation confers cancer cells the ability to avoid apoptosis and MeTA may provide an efficient mean to analyze the change in cancer cell phenotypes by DNA methylation alterations. This is the first report showing that the reactivation of hypermethylated genes by the method other than DNMT inhibition induces growth arrest and apoptosis in cancer cells.

Project description:The identification of genes transcriptionally silenced by DNA hypermethylation is important in understanding the molecular basis of epigenetically regulated biological processes such as X chromosome inactivation, genomic imprinting, and cancer development. Our previously developed methyl-CpG targeted transcriptional activation (MeTA) method reactivates epigenetically silenced genes by using a methyl-CpG binding domain from MBD2 with a transcriptional activation domain. We applied either MeTA or a conventional DNA demethylating agent, 5-aza-cytidine (Aza-CR), to a human embryonic kidney cell line 293T and analyzed gene expression profiles by microarray; 138 and 202 genes that are upregulated 5-fold or more were identified by MeTA and Aza-CR, respectively. The top ten upregulated genes detected by MeTA were further analyzed. We found associations between expressional restorations by MeTA, methylation status, and NFkB(AD)-MBD fusion protein bindings in CpG islands (CGIs) around the transcription start site of the genes. Importantly, MeTA can upregulate genes meeting the stringent criteria of CGIs defined by Takai and Jones at the promoter region at higher frequency; 109 of 138 (79.0%) genes in MeTA vs. 121 of 202 (59.9%) genes in Aza-CR. Interestingly, only 27 genes were upregulated by both methods; MeTA may identify methylated genes that show low levels of induction by the DNA demethylating agents; demethylating agents may also induce factors that help re-expression of genes that harbor less stringent or no CGIs. These results suggest that microarray coupled with MeTA (MeTA-array) is an efficient alternative way to identify transcriptionally silenced genes by DNA hypermethylation. 293T cells were transfected with pcDNA6/myc-His vector or pcDNA6-3xFLAG-NFkB (AD)-MBD and were harvested 48 h after transfection. In contrast, 293T cells were treated with 5-aza-cytidine (Aza-CR, 25 uM) or the same volume of PBS for 96 h and medium replaced every 24 h.

Project description:Expression data from pancreatic cancer cell lines and non-neoplastic pancreatic cell line HPDE To identify genes epigenetically silenced and regulated in pancreatic cancer

Project description:Expression data from pancreatic cancer cell lines and non-neoplastic pancreatic cell line HPDE To identify genes epigenetically silenced and regulated in pancreatic cancer We compared the gene expression profiles of 6 pancreatic cancer cell lines (panc215, A32-1, A38-5, panc2.5, panc2.8, and panc3.014), to the non-neoplastic pancreas cell line, HPDE. We also compared the baseline gene expression of the pancreatic cancer cell lines to expression patterns after treatment with 5-aza-dC alone, TSA alone, and to a combination of 5-aza-dC/TSA.

Project description:The identification of genes transcriptionally silenced by DNA hypermethylation is important in understanding the molecular basis of epigenetically regulated biological processes such as X chromosome inactivation, genomic imprinting, and cancer development. Our previously developed methyl-CpG targeted transcriptional activation (MeTA) method reactivates epigenetically silenced genes by using a methyl-CpG binding domain from MBD2 with a transcriptional activation domain. We applied either MeTA or a conventional DNA demethylating agent, 5-aza-cytidine (Aza-CR), to a human embryonic kidney cell line 293T and analyzed gene expression profiles by microarray; 138 and 202 genes that are upregulated 5-fold or more were identified by MeTA and Aza-CR, respectively. The top ten upregulated genes detected by MeTA were further analyzed. We found associations between expressional restorations by MeTA, methylation status, and NFkB(AD)-MBD fusion protein bindings in CpG islands (CGIs) around the transcription start site of the genes. Importantly, MeTA can upregulate genes meeting the stringent criteria of CGIs defined by Takai and Jones at the promoter region at higher frequency; 109 of 138 (79.0%) genes in MeTA vs. 121 of 202 (59.9%) genes in Aza-CR. Interestingly, only 27 genes were upregulated by both methods; MeTA may identify methylated genes that show low levels of induction by the DNA demethylating agents; demethylating agents may also induce factors that help re-expression of genes that harbor less stringent or no CGIs. These results suggest that microarray coupled with MeTA (MeTA-array) is an efficient alternative way to identify transcriptionally silenced genes by DNA hypermethylation.

Project description:GNAS, a gene encoding G-protein stimulating alpha subunit, is frequently mutated in intraductal papillary mucinous neoplasms (IPMNs), which is an indolent and slow-growing pancreatic neoplasm that secretes abundant mucin. GNAS mutation is not observed in conventional ductal adenocarcinomas of the pancreas. To determine the functional significance of GNAS mutation in pancreatic ductal cells, we examined in vitro phenotypes and gene expression profiles of cells of pancreatic ductal lineage, HPDE, PK-8, PCI-35, and MIA PaCa-2, with exogenous expression of either wild-type or mutated (R201H) GNAS. We found that exogenous GNAS upregulated intracellular cyclic-adenine monophosphate, particularly in the mutated GNAS transfectants. Exogenous GNAS induced no obvious cell-growth promotion, but induced suppression in some cells. The exogenous GNAS upregulated MUC2 and MUC5AC in HPDE and PK-8, and the latter was most sensitive to exogenous GNAS, exhibiting drastic alteration of the global gene expression that is consistent with that of IPMN. Hence, PK-8 expressing exogenous mutated GNAS may be an ideal in vitro model of IPMN. On the other hand, exogenous GNAS downregulated expression of mucin genes and produced modest alteration of gene expression profiles in PCI-35 and MIA PaCa-2, indicating lower sensitivity to exogenous GNAS. Furthermore, we showed diverse and cell-type specific mucin expression pathways with complicated interactions between signaling pathways of the G-protein coupled receptor (GPCR), the mitogen-activated protein kinase (MAPK), and the phosphatidylinositol 3 kinase (PI3K), in which the GPCR pathway appeared to be dominant in some and the MAPK pathway in others. In conclusion, mutated GNAS found in IPMNs may extensively alter gene expression profiles, including expression of mucin genes, with the interaction with MAPK and PI3K pathways in pancreatic ductal-lineage cells, which may determine the characteristic phenotype of the neoplasm.

Project description:GNAS, a gene encoding G-protein stimulating alpha subunit, is frequently mutated in intraductal papillary mucinous neoplasms (IPMNs), which is an indolent and slow-growing pancreatic neoplasm that secretes abundant mucin. GNAS mutation is not observed in conventional ductal adenocarcinomas of the pancreas. To determine the functional significance of GNAS mutation in pancreatic ductal cells, we examined in vitro phenotypes and gene expression profiles of cells of pancreatic ductal lineage, HPDE, PK-8, PCI-35, and MIA PaCa-2, with exogenous expression of either wild-type or mutated (R201H) GNAS. We found that exogenous GNAS upregulated intracellular cyclic-adenine monophosphate, particularly in the mutated GNAS transfectants. Exogenous GNAS induced no obvious cell-growth promotion, but induced suppression in some cells. The exogenous GNAS upregulated MUC2 and MUC5AC in HPDE and PK-8, and the latter was most sensitive to exogenous GNAS, exhibiting drastic alteration of the global gene expression that is consistent with that of IPMN. Hence, PK-8 expressing exogenous mutated GNAS may be an ideal in vitro model of IPMN. On the other hand, exogenous GNAS downregulated expression of mucin genes and produced modest alteration of gene expression profiles in PCI-35 and MIA PaCa-2, indicating lower sensitivity to exogenous GNAS. Furthermore, we showed diverse and cell-type specific mucin expression pathways with complicated interactions between signaling pathways of the G-protein coupled receptor (GPCR), the mitogen-activated protein kinase (MAPK), and the phosphatidylinositol 3 kinase (PI3K), in which the GPCR pathway appeared to be dominant in some and the MAPK pathway in others. In conclusion, mutated GNAS found in IPMNs may extensively alter gene expression profiles, including expression of mucin genes, with the interaction with MAPK and PI3K pathways in pancreatic ductal-lineage cells, which may determine the characteristic phenotype of the neoplasm. Cells of pancreatic cancer cell lines, PK-8, PCI-35,and MIA PaCa-2, were seeded at 4 M-CM-^W 10^5 cells/well in 6-well plates and incubated for 24 hours at 37M-BM-0C in 5% CO2 with humid atmosphere. Then the cells were transfected with either pcDNA 3.1/V5-His vector or pcDNA3.1-GNAS(R201H)-V5-His vector using Lipofectamine 2000 reagent (Life Technologies) according to the manufacturerM-bM-^@M-^Ys recommendations. The cells were incubated for 24 hours and collected by dissociation using trypsin. Total RNAs were isolated using the RNeasy Mini kit (Qiagen, Hilden, Germany). Serial analysis of gene expression (SAGE) library was constructed using a SOLiD SAGE Kit (Life Technologies) according to the manufactureM-bM-^@M-^Ys instruction. The constructed libraries were analysed by means of the massively parallel sequencing method using SOLiD 4 System (Life Technologies). The SAGE analysis was performed for samples obtained from single transfection experiment.