Project description:Molecular Characterization of Spontaneously Transformed Epithelial Murine Colon Cell Lines as a Model of Human Colorectal Neoplasia (expression)
Project description:Molecular Characterization of Spontaneously Transformed Epithelial Murine Colon Cell Lines as a Model of Human Colorectal Neoplasia (CGH)
Project description:To characterize a series of mouse colon cells that have become spontaneously transformed over time in order to identify the chromosomal and genomic alterations that take place during the development of tumorigenesis. Colorectal cancer is the third common malignancy in the United States. The stepwise progression from adenoma to carcinoma is accompanied by specific genomic alterations. Existing mouse models of human colon cancer have been induced by chemicals, viruses, or through genetic manipulation. Presented here is a unique mouse model of spontaneous transformation designed to identify the sequential steps of tumorigenesis. Normal epithelial colon cells were selectively isolated from the large intestine from eight different isogenic five-six week old C57BL/6 mice. Primary colon cells were grown in vitro with reduced serum concentration. The cells were sequentially recovered from culture based on distinct morphological changes: first, when the cells were in the pre-immortal stage and established as adherent cultures; second, as the cells bypassed crisis, increased their mitotic activity and became immortal; third, at early transformation, as the cells first formed foci; fourth, mid-transformed where the cells had higher proliferation rates in later passages; and finally, late transformed with rapid proliferation, contact inhibition, and multiple foci. The cells within each stage were analyzed using the molecular cytogenetic techniques of spectral karyotyping (SKY) and array comparative genomic hybridization (aCGH), and gene expression profiling. The late transformed cells were injected into nude mice to assess their tumorigenic potential. Spectral karyotyping revealed many recurrent structural and numerical aberrations, specifically in the late transformed cells. Loss of chromosome 4 is a consistent chromosomal aberration observed in all stages of the transformed colon cells, as well as in other tissues during the process of spontaneous transformation. Array CGH identified a pattern of gains and losses, and showed deletions of APC and Trp53 as well as a gain of Kras similar that observed in human colorectal cancer. Gene expression profiling identified the deregulation of several genes known to be involved in the progression of human colon cancer. Tumors resulted from three of the eight late transformed cultures confirming tumorigenic potential. Ultimately, the molecular characterization of spontaneously transformed murine epithelial colon cells indeed recapitulated the step wise progression of human colon cancer, and will prove to be an invaluable system in which to test potential rational intervention strategies. Mouse colon epithelial cells were isolated from the colon of 8 isogenic C57BL\6 mice. These cells were grown in reduced serum and over time spontaneously became immortal and transformed. Our objective is to compare these changes to those that occur during human colon cancer development.
Project description:To characterize a series of mouse colon cells that have become spontaneously transformed over time in order to identify the chromosomal and genomic alterations that take place during the development of tumorigenesis. Colorectal cancer is the third common malignancy in the United States. The stepwise progression from adenoma to carcinoma is accompanied by specific genomic alterations. Existing mouse models of human colon cancer have been induced by chemicals, viruses, or through genetic manipulation. Presented here is a unique mouse model of spontaneous transformation designed to identify the sequential steps of tumorigenesis. Normal epithelial colon cells were selectively isolated from the large intestine from eight different isogenic five-six week old C57BL/6 mice. Primary colon cells were grown in vitro with reduced serum concentration. The cells were sequentially recovered from culture based on distinct morphological changes: first, when the cells were in the pre-immortal stage and established as adherent cultures; second, as the cells bypassed crisis, increased their mitotic activity and became immortal; third, at early transformation, as the cells first formed foci; fourth, mid-transformed where the cells had higher proliferation rates in later passages; and finally, late transformed with rapid proliferation, contact inhibition, and multiple foci. The cells within each stage were analyzed using the molecular cytogenetic techniques of spectral karyotyping (SKY) and array comparative genomic hybridization (aCGH), and gene expression profiling. The late transformed cells were injected into nude mice to assess their tumorigenic potential. Spectral karyotyping revealed many recurrent structural and numerical aberrations, specifically in the late transformed cells. Loss of chromosome 4 is a consistent chromosomal aberration observed in all stages of the transformed colon cells, as well as in other tissues during the process of spontaneous transformation. Array CGH identified a pattern of gains and losses, and showed deletions of APC and Trp53 as well as a gain of Kras similar that observed in human colorectal cancer. Gene expression profiling identified the deregulation of several genes known to be involved in the progression of human colon cancer. Tumors resulted from three of the eight late transformed cultures confirming tumorigenic potential. Ultimately, the molecular characterization of spontaneously transformed murine epithelial colon cells indeed recapitulated the step wise progression of human colon cancer, and will prove to be an invaluable system in which to test potential rational intervention strategies. Mouse colon epithelial cells were isolated from the colon of 8 isogenic C57BL\6 mice. These cells were grown in reduced serum and over time spontaneously became immortal and transformed. Our objective is to compare these changes to those that occur during human colon cancer development.
Project description:To characterize a series of mouse colon cells that have become spontaneously transformed over time in order to identify the chromosomal and genomic alterations that take place during the development of tumorigenesis. Colorectal cancer is the third common malignancy in the United States. The stepwise progression from adenoma to carcinoma is accompanied by specific genomic alterations. Existing mouse models of human colon cancer have been induced by chemicals, viruses, or through genetic manipulation. Presented here is a unique mouse model of spontaneous transformation designed to identify the sequential steps of tumorigenesis. Normal epithelial colon cells were selectively isolated from the large intestine from eight different isogenic five-six week old C57BL/6 mice. Primary colon cells were grown in vitro with reduced serum concentration. The cells were sequentially recovered from culture based on distinct morphological changes: first, when the cells were in the pre-immortal stage and established as adherent cultures; second, as the cells bypassed crisis, increased their mitotic activity and became immortal; third, at early transformation, as the cells first formed foci; fourth, mid-transformed where the cells had higher proliferation rates in later passages; and finally, late transformed with rapid proliferation, contact inhibition, and multiple foci. The cells within each stage were analyzed using the molecular cytogenetic techniques of spectral karyotyping (SKY) and array comparative genomic hybridization (aCGH), and gene expression profiling. The late transformed cells were injected into nude mice to assess their tumorigenic potential. Spectral karyotyping revealed many recurrent structural and numerical aberrations, specifically in the late transformed cells. Loss of chromosome 4 is a consistent chromosomal aberration observed in all stages of the transformed colon cells, as well as in other tissues during the process of spontaneous transformation. Array CGH identified a pattern of gains and losses, and showed deletions of APC and Trp53 as well as a gain of Kras similar that observed in human colorectal cancer. Gene expression profiling identified the deregulation of several genes known to be involved in the progression of human colon cancer. Tumors resulted from three of the eight late transformed cultures confirming tumorigenic potential. Ultimately, the molecular characterization of spontaneously transformed murine epithelial colon cells indeed recapitulated the step wise progression of human colon cancer, and will prove to be an invaluable system in which to test potential rational intervention strategies.
Project description:To characterize a series of mouse colon cells that have become spontaneously transformed over time in order to identify the chromosomal and genomic alterations that take place during the development of tumorigenesis. Colorectal cancer is the third common malignancy in the United States. The stepwise progression from adenoma to carcinoma is accompanied by specific genomic alterations. Existing mouse models of human colon cancer have been induced by chemicals, viruses, or through genetic manipulation. Presented here is a unique mouse model of spontaneous transformation designed to identify the sequential steps of tumorigenesis. Normal epithelial colon cells were selectively isolated from the large intestine from eight different isogenic five-six week old C57BL/6 mice. Primary colon cells were grown in vitro with reduced serum concentration. The cells were sequentially recovered from culture based on distinct morphological changes: first, when the cells were in the pre-immortal stage and established as adherent cultures; second, as the cells bypassed crisis, increased their mitotic activity and became immortal; third, at early transformation, as the cells first formed foci; fourth, mid-transformed where the cells had higher proliferation rates in later passages; and finally, late transformed with rapid proliferation, contact inhibition, and multiple foci. The cells within each stage were analyzed using the molecular cytogenetic techniques of spectral karyotyping (SKY) and array comparative genomic hybridization (aCGH), and gene expression profiling. The late transformed cells were injected into nude mice to assess their tumorigenic potential. Spectral karyotyping revealed many recurrent structural and numerical aberrations, specifically in the late transformed cells. Loss of chromosome 4 is a consistent chromosomal aberration observed in all stages of the transformed colon cells, as well as in other tissues during the process of spontaneous transformation. Array CGH identified a pattern of gains and losses, and showed deletions of APC and Trp53 as well as a gain of Kras similar that observed in human colorectal cancer. Gene expression profiling identified the deregulation of several genes known to be involved in the progression of human colon cancer. Tumors resulted from three of the eight late transformed cultures confirming tumorigenic potential. Ultimately, the molecular characterization of spontaneously transformed murine epithelial colon cells indeed recapitulated the step wise progression of human colon cancer, and will prove to be an invaluable system in which to test potential rational intervention strategies.
Project description:We present evidence for cytogenetic changes in two transformed ovarian surface epithelium cell lines, TOSE1 and TOSE4. hTERT-immortalised ovarian surface epithelial cell line spontaneously transformed as measured by growth in soft agar. These cells were grown on plastic, and genomic DNA was extracted and analyzed for cytogenetic changes.
Project description:Studying cell differentiation and transformation allows a better understanding of the mechanisms involved in the initiation and the evolution of cancer. The role of proteins which participate in these processes is dependent on their location within the cell. Determining the subcellular localization of proteins or the changes in localization is, therefore, paramount in elucidating their role. Using quantitative mass spectrometry, we characterized the protein expression and subcellular localization of nearly 5,000 proteins from seven different colorectal cancer (CRC) cell lines, as well as normal colon fibroblasts and intestinal epithelial cells. This cellular characterization allowed the identification of colon cancer-associated proteins with differential expression patterns as well as deregulated protein networks and pathways. Indeed, our results demonstrate differential expression of proteins involved in cell adhesion, cytoskeleton, and transcription in colon cancer cells compared to normal colon-derived cells. Pathway analyses identified different cellular functions, including endocytosis and eIF2 signaling, whose deregulation correlates with mutations found in the different CRC phenotypes. Our results provide an unbiased, quantitative and high-throughput approach to measure changes in protein expression and subcellular protein locations in different colorectal cancer cell lines.