Project description:Pentavalent vanadium compounds induce intracellular changes in vitro that are consistent with those of other carcinogenic substances, including alteration of transcription factor levels, promotion of oxidative stress, inflammation, DNA damage, stimulation of mitogenic signals, and suppression of apoptosis. While there is no clear evidence that vanadium compounds cause cancer in humans, vanadium pentoxide causes lung cancer in rodents after long-term inhalation exposures and in turn IARC has categorized it as a group 2B possible human carcinogen. The goal of this study was to investigate the carcinogenicity of NaVO3 in the human immortalized bronchial epithelial cell line, Beas-2B. Cells were treated with 10 µM NaVO3 for 5 weeks, with or without recovery time, followed by gene expression microarray analysis. In a separate experiment, cells were exposed to 1-10 µM NaVO3 for 4 weeks and then grown in soft agar to test for anchorage-independent growth. A dose-dependent increase in the number of colonies was observed. NaVO3-transformed clones could repair a wound faster than controls during the scratch test. In a gene expression microarray analysis of soft agar clones there were 2010 differentially expressed genes (DEG) (adjusted p-value ≤ 0.05) in NaVO3-transformed clones relative to control clones. DEG from this experiment were compared with the DEG of 5 week NaVO3 exposure with or without recovery, all with adjusted p-values <0.05, and 469 genes were altered in the same direction for transformed clones, 5 week NaVO3-treated cells, and the recovered cells; a subset of these changes were validated by QRT-PCR. The data from this study imply that chronic exposure to NaVO3 causes changes that are consistent with cellular transformation including anchorage- independent growth, enhanced migration ability, and gene expression changes that were epigenetically inherited through cell division.

Project description:Pentavalent vanadium compounds induce intracellular changes in vitro that are consistent with those of other carcinogenic substances, including alteration of transcription factor levels, promotion of oxidative stress, inflammation, DNA damage, stimulation of mitogenic signals, and suppression of apoptosis. While there is no clear evidence that vanadium compounds cause cancer in humans, vanadium pentoxide causes lung cancer in rodents after long-term inhalation exposures and in turn IARC has categorized it as a group 2B possible human carcinogen. The goal of this study was to investigate the carcinogenicity of NaVO3 in the human immortalized bronchial epithelial cell line, Beas-2B. Cells were treated with 10 µM NaVO3 for 5 weeks, with or without recovery time, followed by gene expression microarray analysis. In a separate experiment, cells were exposed to 1-10 µM NaVO3 for 4 weeks and then grown in soft agar to test for anchorage-independent growth. A dose-dependent increase in the number of colonies was observed. NaVO3-transformed clones could repair a wound faster than controls during the scratch test. In a gene expression microarray analysis of soft agar clones there were 2010 differentially expressed genes (DEG) (adjusted p-value ≤ 0.05) in NaVO3-transformed clones relative to control clones. DEG from this experiment were compared with the DEG of 5 week NaVO3 exposure with or without recovery, all with adjusted p-values <0.05, and 469 genes were altered in the same direction for transformed clones, 5 week NaVO3-treated cells, and the recovered cells; a subset of these changes were validated by QRT-PCR. The data from this study imply that chronic exposure to NaVO3 causes changes that are consistent with cellular transformation including anchorage- independent growth, enhanced migration ability, and gene expression changes that were epigenetically inherited through cell division. Beas-2B cells were chronically exposed to sodium metavanadate in growth media for 4 weeks. Then exposed cells and unexposed control cells were grown in soft agar for 3 weeks in the absence of vanadate. Transformed colonies (arising from vanadate-exposed cells) and control colonies (spontaneously grew from unexposed cells) were extracted from soft agar and expanded in the absence of vanadate, then processed for gene expression analysis on Affymetrix GeneChip Human Exon 1.0 ST array. 5 transformed clones, 3 control clones, 1 parental Beas-2B cell sample, and acute 24 hour vanadate exposed cell samples were analyzed.

Project description:Pentavalent vanadium compounds induce intracellular changes in vitro that are consistent with those of other carcinogenic substances, including alteration of transcription factor levels, promotion of oxidative stress, inflammation, DNA damage, stimulation of mitogenic signals, and suppression of apoptosis. While there is no clear evidence that vanadium compounds cause cancer in humans, vanadium pentoxide causes lung cancer in rodents after long-term inhalation exposures and in turn IARC has categorized it as a group 2B possible human carcinogen. The goal of this study was to investigate the carcinogenicity of NaVO3 in the human immortalized bronchial epithelial cell line, Beas-2B. Cells were treated with 10 M-BM-5M NaVO3 for 5 weeks, with or without recovery time, followed by gene expression microarray analysis. In a separate experiment, cells were exposed to 1-10 M-BM-5M NaVO3 for 4 weeks and then grown in soft agar to test for anchorage-independent growth. A dose-dependent increase in the number of colonies was observed. NaVO3-transformed clones could repair a wound faster than controls during the scratch test. In a gene expression microarray analysis of soft agar clones there were 2010 differentially expressed genes (DEG) (adjusted p-value M-bM-^IM-$ 0.05) in NaVO3-transformed clones relative to control clones. DEG from this experiment were compared with the DEG of 5 week NaVO3 exposure with or without recovery, all with adjusted p-values <0.05, and 469 genes were altered in the same direction for transformed clones, 5 week NaVO3-treated cells, and the recovered cells; a subset of these changes were validated by QRT-PCR. The data from this study imply that chronic exposure to NaVO3 causes changes that are consistent with cellular transformation including anchorage- independent growth, enhanced migration ability, and gene expression changes that were epigenetically inherited through cell division. Beas-2B cells were chronically exposed to sodium metavanadate in growth media for 4 weeks. Then, one set of exposed cells and unexposed control cells were grown in soft agar for 3 weeks in the absence of vanadate. Transformed colonies (arising from vanadate-exposed cells) and control colonies (spontaneously grew from unexposed cells) were extracted from soft agar and expanded in the absence of vanadate, then processed for gene expression analysis . A second set of exposed cells continued treatment for a total of 5 weeks exposure. A third set of cells recovered for 1 week after the 4 week long exposure. The gene expression of 5 transformed clones, 3 control clones, 2 5 week exposures, 2 recovery, and 2 unexposed control cells, and 1 parental Beas-2B cell samples were analyzed (15 total samples) with an Affymetrix GeneChip Human Exon 1.0 ST array.

Project description:To determine early changes leading to human cell transformation (cancer) we exposed an immortalized human bronchial epithelial cell line, BEAS-2B, to one of four different metals that may cause cancer via inhalation in humans or rodents: 2.0 micro-Molar soluble sodium arsenite (NaAsO2), 0.50 micro-Molar potassium chromate (K2CrO4), 250 micro-Molar nickel (II) sulfate (NiSO4), 10 micro-Molar sodium meta-vanadate (NaVO3), or were left untreated (control). After a 30-60 day exposure, cells were rinsed of metals and seeded in soft agar. A small number of the cells formed colonies in the soft agar, demonstrating the potential for anchorage independent growth, a characteristic of cancer. These colonies that originated from a single cell were extracted from the agar and grown out in monolayer for 3-4 weeks. The RNA data provided here is taken from these cells. The significance it that the metal exposure was stopped many generations before the analysis, yet each sample demonstrates changes in gene expression based on the original metal exposure. A total of 39 samples were analyzed, consisting of 3 parental cell lines (BEAS-2B cells that were never seeded in agar or exposed to any metal), 11 controls cells (grouped into three sets, based on those seeded at the same time as the V-treated clones, the Cr-treated clones, or the As-treated and Ni-treated clones), and 25 metal-treated clones (7 each for Ni and As, processed in two separate batches of 3 and 4 clones each, 6 Cr clones and 5 Vanadium clones). Because the samples were processed in different batches, the data was batch-normalized using the COMBAT package in R prior to importing into GeneSpring. Once in GeneSpring the data was base-lined with each sample compared to its control samples (Batch 1: Cr 1-6, P-2, Ctrls 6-8; Batch 2: As1-3, Ni 1-3, P-1 and Ctrl 1-3; Batch 3: As4-7, Ni 4-7, and Ctrl 4-5; Batch 4: V 1-5, P-3 and Ctrl 9-11). When the same analysis was performed but with baseline of samples to all controls combined, a similar result was obtained, albeit with less tight clustering. Arsenic clones 2 and 5 appear to be outliers as their removal nicely cleans up the PCA, but this appears to be genuine biological variation as we did not identify any significant problems with the data.

Project description:The immortalized human urothelial cell line, UROtsa, was transformed in six parallel cultures with continual passaging in1 µM Cd+2 until the cells were able to attain the ability to form colonies in soft agar and subcutaneous tumors in nude mice. The gene expression profiles between cadmium-transformed and control samples were compared and the differentially expressed genes were identified.

Project description:The immortalized human urothelial cell line, UROtsa, was transformed in six parallel cultures with continual passaging in1 µM Cd+2 until the cells were able to attain the ability to form colonies in soft agar and subcutaneous tumors in nude mice. The gene expression profiles between cadmium-transformed and control samples were compared and the differentially expressed genes were identified. Six independent Cadmium-transformed UROtsa cell cultures, three control UROtsa cell cultures

Project description:To determine early changes leading to human cell transformation (cancer) we exposed an immortalized human bronchial epithelial cell line, BEAS-2B, to one of four different metals that may cause cancer via inhalation in humans or rodents: 2.0 micro-Molar soluble sodium arsenite (NaAsO2), 0.50 micro-Molar potassium chromate (K2CrO4), 250 micro-Molar nickel (II) sulfate (NiSO4), 10 micro-Molar sodium meta-vanadate (NaVO3), or were left untreated (control). After a 30-60 day exposure, cells were rinsed of metals and seeded in soft agar. A small number of the cells formed colonies in the soft agar, demonstrating the potential for anchorage independent growth, a characteristic of cancer. These colonies that originated from a single cell were extracted from the agar and grown out in monolayer for 3-4 weeks. The RNA data provided here is taken from these cells. The significance it that the metal exposure was stopped many generations before the analysis, yet each sample demonstrates changes in gene expression based on the original metal exposure.

Project description:RNAseq transcriptomic analysis of MCF10A-CT, MC26 and M1B26 cell lines. MCF10A cells are human not transformed mammary stem-like cells that do not form colonies in soft-agar assay and do not engraft in immunocompromised mice. MC26 are MCF10A derivatives that were submitted to long-term culture in presence of human recombinant BMP2 and IL6 for several weeks until colony formation in soft-agar was detected. M1B26 are MCF10A derivatives that were sorted for high expression of the BMPR1b BMP receptor prior to BMP2 and IL6 treatment and expanded from several soft-agar colonies. M1B26 are more transformed than MC26 based on the frequency of soft-agar colonies forming cells and on the ability to engraft in mice. As a control, MCF10A-CT were kept in culture for similar length of time than MC26 and M1B26 but without BMP2 and IL6 and do not generate soft-agar colonies or engraft in mice. This study aims to document the transcriptomic changes associated with early transformation events mediated by abnormal exposure to BMP2 and inflammatory signal.

Project description:We established chromate transformed cell lines by chronic exposure of normal human bronchial epithelial BEAS-2B cells to low doses of hexavalent chromium followed by anchorage-independent growth. The gene expression profiles were analyzed in the established cell lines. The gene expression profiles from six chromate transformed cell lines were remarkably similar to each other yet differed significantly from that of either control cell line or normal Beas-2B cells. A total of 409 differentially expressed genes were identified in chromate transformed cells compared to control cells.

Project description:Genome-wide SNP profilling for loss of heterozygosity (LOH) during FOXM1B-induced malignant transformation in a human premalignant oral keratinocyte line SVpgC2a. Experiment Overall Design: Eight FOXM1B-induced malignant clones (SVFN1-8) that grew in soft agar were grown as individual cell lines and gDNA harvested from each clone for SNP array analysis compared to wild-type non-transformed SVpgC2a as control to obtain loss of heterozygosity profiles.