Project description:To examine the global impact of iAs on DNA methylation patterns. Genomic DNA was Bisulfite converted and analyzed using Mini methly-seq.

Project description:To examine the global impact of iAs on DNA hdroxymethylation patterns. Genomic DNA was glucosylated, digested and analyzed using Reduced Representation Hydroxymethylation Profiling.

Project description:This study was carried out to compare the changes in the gene expression in the liver of 5 day post fertilization zebrafish larvae in response to 24 hour exposure to 1.0 and 1.5mM iAs and to compare this to changes in gene expression as a result of overexpress as3mt in hepatocytes. CL1 CAAX 1.5 = WT larvae exposed to 1.5 mM iAs; CL2 CAAX 1 = WT larvae exposed to 1.5 mM iAs

Project description:To examine the global impact of iAs on DNA methylation patterns. Genomic DNA was bisulfite converted and analyzed using Infinium MethylationEPIC BeadChip.

Project description:Prenatal exposure to inorganic arsenic (iAs) is detrimental to the health of newborns and increases the risk of disease development later in life. Here we examined a subset of newborn cord blood leukocyte samples collected from mothers enrolled in the Biomarkers of Exposure to ARsenic (BEAR) pregnancy cohort in Gomez Palacio, Mexico who were exposed to a range of drinking water arsenic concentrations (0.456-236 µg/L). Changes in iAs-associated DNA 5-methyl cytosine methylation were assessed across 424,935 CpG sites representing 18,761 genes and were compared to corresponding expression levels and birth outcomes. In the context of arsenic exposure, a total of 2,705 genes were identified with iAs-associated differences in DNA methylation. Site-specific analyzes identified DNA methylation changes that were most predictive of gene expression levels. Specifically, CpG methylation within CpG islands positioned within the first exon and 200bp upstream of the transcription start site yielded the most significant association with gene expression levels. A set of 16 genes was identified with correlated iAs-associated changes in DNA methylation and mRNA expression and all were highly enriched for binding sites of the early growth response (EGR) and CCCTC-binding factor (CTCF) transcription factors. Furthermore, DNA methylation levels of seven of these genes were associated with differences in birth outcomes including gestational age, placental weight and head circumference. These data highlight the complex interplay between DNA methylation and functional changes in gene expression and health outcomes and underscore the need for functional analyzes coupled to epigenetic assessments. 48 DNA methylation profiles were obtained but only 38 samples corresponding to samples also analyzed for gene expression (see Rager 2014) were further normalized and used in the publication from the Biomarkers of Arsenic (BEAR) cohort were analyzed for DNA methylation profiles.

Project description:Replicative senescent cells reportedly share similar DNA methylation changes with cancer cells, which are purported to facilitate tumorigenesis in cells bypassing senescence. However, we now report biologically critical and distinct patterns of DNA methylation evolution between replicative and oncogene-induced senescence and transformation in a classic human cell transformation model. While overall DNA methylation losses and gains occur in both replicative senescent and transformed cells, the patterns evolve more programmatically for the former and stochastically for the latter. Oncogene-induced senescence is an acute process involving minimal changes to DNA methylation. The stochastic DNA methylation alterations in transformation mainly involve a set of pro-survival promoter CpG-island methylation events targeting genes controlling development and differentiation processes, while the senescence-specific promoter changes occur in genes involved in positive regulation of cellular biosynthesis and macromolecular metabolism. The above set of pro-survival promoter CpG-island hypermethylation events, but not the senescence-specific events, are prone to occur in primary tumors and aging tissues. Importantly, cells manifest senescence-specific epigenomic patterns very early during commitment to senescence, and while these “near-senescent” cells can be immortalized, they are refractory to transformation by H-Ras oncoprotein (H-rasV12). The senescence-specific methylation is retained during immortalization and transformation attempts, suggesting it does not function to promote tumorigenesis. Thus, abnormalities in cancer-related methylation has their origins in aging and not replicative senescence, and senescence-associated methylation potentially prevents malignant transformation.

Project description:Replicative senescent cells reportedly share similar DNA methylation changes with cancer cells, which are purported to facilitate tumorigenesis in cells bypassing senescence. However, we now report biologically critical and distinct patterns of DNA methylation evolution between replicative and oncogene-induced senescence and transformation in a classic human cell transformation model. While overall DNA methylation losses and gains occur in both replicative senescent and transformed cells, the patterns evolve more programmatically for the former and stochastically for the latter. Oncogene-induced senescence is an acute process involving minimal changes to DNA methylation. The stochastic DNA methylation alterations in transformation mainly involve a set of pro-survival promoter CpG-island methylation events targeting genes controlling development and differentiation processes, while the senescence-specific promoter changes occur in genes involved in positive regulation of cellular biosynthesis and macromolecular metabolism. The above set of pro-survival promoter CpG-island hypermethylation events, but not the senescence-specific events, are prone to occur in primary tumors and aging tissues. Importantly, cells manifest senescence-specific epigenomic patterns very early during commitment to senescence, and while these “near-senescent” cells can be immortalized, they are refractory to transformation by H-Ras oncoprotein (H-rasV12). The senescence-specific methylation is retained during immortalization and transformation attempts, suggesting it does not function to promote tumorigenesis. Thus, abnormalities in cancer-related methylation has their origins in aging and not replicative senescence, and senescence-associated methylation potentially prevents malignant transformation.

Project description:This study was carried out to compare the changes in gene expression in whole larvae 120 hours post fertilization zebrafish larvae in response to whole body mutation of the arsenic methylation gene (as3mt) - 8 bp deletion in exon 3 with and without 6-120 hpf exposure to 1 mM sodium arsenite (iAs).

Project description:Prenatal exposure to inorganic arsenic (iAs) is detrimental to the health of newborns and increases the risk of disease development later in life. Here we examined a subset of newborn cord blood leukocyte samples collected from mothers enrolled in the Biomarkers of Exposure to ARsenic (BEAR) pregnancy cohort in Gomez Palacio, Mexico who were exposed to a range of drinking water arsenic concentrations (0.456-236 µg/L). Changes in iAs-associated DNA 5-methyl cytosine methylation were assessed across 424,935 CpG sites representing 18,761 genes and were compared to corresponding expression levels and birth outcomes. In the context of arsenic exposure, a total of 2,705 genes were identified with iAs-associated differences in DNA methylation. Site-specific analyzes identified DNA methylation changes that were most predictive of gene expression levels. Specifically, CpG methylation within CpG islands positioned within the first exon and 200bp upstream of the transcription start site yielded the most significant association with gene expression levels. A set of 16 genes was identified with correlated iAs-associated changes in DNA methylation and mRNA expression and all were highly enriched for binding sites of the early growth response (EGR) and CCCTC-binding factor (CTCF) transcription factors. Furthermore, DNA methylation levels of seven of these genes were associated with differences in birth outcomes including gestational age, placental weight and head circumference. These data highlight the complex interplay between DNA methylation and functional changes in gene expression and health outcomes and underscore the need for functional analyzes coupled to epigenetic assessments.

Project description:Arsenic (As) exposure is a significant worldwide environmental health concern. Low dose, chronic arsenic exposure has been associated with higher risk of skin, lung, and bladder cancer, as well as cardiovascular disease and diabetes. While arsenic-induced biological changes play a role in disease pathology, little is known about the dynamic cellular changes due to arsenic exposure and withdrawal. In these studies, we seek to understand the molecular mechanisms behind the biological changes induced by chronic low doses of arsenic exposure. We used a comprehensive approach involving chromatin structural studies and mRNA microarray analyses to determine how chromatin structure and gene expression patterns change in response to chronic low dose arsenic exposure and its subsequent withdrawal. Our results show that cells exposed to low doses of sodium arsenite have distinct temporal and coordinated chromatin, gene expression and miRNA changes that are consistent with differentiation and activation of multiple biochemical pathways. Most of these temporal patterns in gene expression are reversed when arsenic was withdrawn. However, some of the gene expression patterns remained altered, plausibly as a result of an adaptive response by these cells. Additionally, these gene expression patterns correlated with changes in chromatin structure, further solidifying the role of chromatin structure in gene regulatory changes due to arsenite exposure. Lastly, we show that arsenite exposure influences gene regulation both at the transcription initiation as well as at the splicing level. Thus our results suggest that general patterns of alternative splicing, as well as expression of particular gene regulators, can be indicative of arsenite-induced cell transformation. A total of eight (8) samples with two biological replicates under four separate conditions: wild-type treated with deionized H2O for 36 days (NT); chronic low-dose arsenic exposure of 1 uM of sodium arsenite (iAs-T) for 36 days; chronic arsenic exposure of 1 uM of sodium arsenite for 26 days followed by removal of sodium arsenite for 10 days, measured at day 36 (iAs-Rev); and chronic arsenic exposure of 1 uM of sodium arsenite for 26 days, followed by removal of sodium arsenite exposure for 10 days, followed by 1 uM of chronic sodium arsenite exposure for 10 days (measured at day 46) (iAs-Rev-T).