Project description:Arsenic is a carcinogen that is known to induce cell transformation and tumor formation. Although studies have been performed to examine the modulation of signaling molecules caused by arsenic exposure, the molecular mechanisms by which arsenic causes cancer are still unclear. We hypothesized that arsenic alters gene expression leading to carcinogenesis in the lung. In this study, we examined global gene expression in response to 0.75 M-BM-5M arsenic treatment for 1-7 days in a rat lung epithelial cell line (L2) using an in-house 10k rat DNA microarray. One hundred thirty one genes were identified using the one-class statistical analysis of microarray (SAM) test. Of them, 33 genes had a fold change of M-bM-^IM-% 2 at least between two time points. These genes were then clustered into 5 groups using K-means cluster analysis based on their expression patterns. Seven selected genes, all associated with cancer, were confirmed by real-time PCR. These genes have functions directly or indirectly related to metabolism, glycolysis, cell proliferation and differentiation, and regulation of transcription, all of which may be involved in neoplastic transformation of cells. Our findings provide important insight for the future studies of arsenic-mediated lung cancer. Keywords: Lung, aresenic, L2, micorarray L2 cells were exposed with 0.75 uM of arsenite for 0, 1, 3, 5, and 7 days (C, D1, D3, D5 and D7). The samples were arranged for hybridization using a loop design. For each paired sample, dye flip and three biological replications were performed for each sample.

Project description:To reduce cancer mortality, understanding of mechanisms of cancer metastasis is crucial. We have established 6 rat hepatocellular carcinoma (HCC) cell lines, which exhibit differing metastatic potential to the lung after inoculation into the tail veins of nude mice. Micorarray analysis of 4 kinds of HCC cells and rat normal liver tissue was performed to find a potent molecular target for prevention of cancer metastasis. By the microarray analysis, mRNA expression was compared among two low-metastatic rat HCC cell lines (C5F and C6) and two high-metastatic rat HCC cell lines (N1 and L2) as well as non-treated rat liver tissue (as a reference sample).

Project description:To reduce cancer mortality, understanding of mechanisms of cancer metastasis is crucial. We have established 6 rat hepatocellular carcinoma (HCC) cell lines, which exhibit differing metastatic potential to the lung after inoculation into the tail veins of nude mice. Micorarray analysis of 4 kinds of HCC cells and rat normal liver tissue was performed to find a potent molecular target for prevention of cancer metastasis.

Project description:SCLC transformation is one of the mechanisms of TKI resistance in lung cancer. To clarify its epigenetic changes, we used RNA-seq to detect the changes of genes in pre-LUAD and post-SCLC transformation cells.

Project description:Aberrant DNA methylation is frequently observed in cancer. The aim of this study was to determine how DNA methylation is changed after arsenic-induced malignant transformation.

Project description:Arsenic transformation in high arsenic groundwater

Project description:Arsenic-induced Changes in L2 Cells

Project description:Arsenic is environmental risk factor and has been linked to urothelial carcinoma incidence. Arsenic exposure-induced malignant transformed cells was established from normal urothelial cells by chronic arsenic exposure for 10 months. The purpose of the present study is to elucidate the relevant molecular alterationon on arsenic-induced malignant transformation.

Project description:SCLC transformation is one of the mechanisms of TKI resistance in lung cancer. To clarify its epigenetic changes, we used Chip-seq to detect the changes of H3K9me2 in pre-LUAD and post-SCLC transformation cells.

Project description:The MUC1 oncoprotein is aberrantly overexpressed in diverse human malignancies including breast and lung cancer. Although MUC1 modulates the activity of several transcription factors, there is no information regarding the effects of MUC1 on global gene expression patterns and the potential role of MUC1-induced genes in predicting outcome for cancer patients. We have developed an experimental model of MUC1-induced transformation that has identified the activation of gene families involved in oncogenesis, angiogenesis and extracellular matrix remodeling. A set of experimentally-derived MUC1-induced genes associated with tumorigenesis was applied to the analysis of breast and lung adenocarcinoma cancer databases. A 35-gene MUC1-induced tumorigenesis signature (MTS) predicts significant decreases in both disease-free and overall survival in patients with breast (n = 295) and lung (n = 442) cancers. The data demonstrate that the MUC1 oncoprotein contributes to the regulation of genes that are highly predictive of clinical outcome in breast and lung cancer patients. Experiment Overall Design: To investigate the genes associated with MUC1-CD-induced transformation and tumorigenesis, we performed expression profiling of 3Y1/Vector (empty vector-transfected 3Y1) and 3Y1/MUC1-CD (MUC1-CD-transfected 3Y1) cells growing in vitro, and of 3Y1/MUC1-CD cells growing as tumor xenografts in athymic mice. Cells grown in vitro or as tumor xenografts were lysed to collect total RNA for hybridization with GeneChip® Rat Genome 230 2.0 Arrays.