Project description:Environmental factors during perinatal development influence developmental plasticity and disease susceptibility via alterations to the epigenome. Developmental exposure to the endocrine active compound, bisphenol A (BPA), has previously been associated with altered methylation at candidate gene loci. Here, we undertake the first genome-wide characterization of DNA methylation profiles in the liver of murine offspring perinatally exposed to multiple doses of BPA through the maternal diet. Using a tiered focusing approach, our strategy proceeds from unbiased broad DNA methylation analysis using methylation-based next generation sequencing technology to in-depth quantitative site-specific CpG methylation determination using the Sequenom EpiTYPER MassARRAY platform to profile liver DNA methylation patterns in offspring maternally exposed to BPA during gestation and lactation to doses ranging from 0 BPA/kg (Ctr), 50 M-BM-5g BPA/kg (UG), or 50 mg BPA/kg (MG) diet (N=4 per group). Genome-wide analyses indicate non-monotonic effects of DNA methylation patterns following perinatal exposure to BPA, corroborating previous studies using multiple doses of BPA with non-monotonic outcomes. We observed enrichment of regions of altered methylation (RAMs) within CpG island (CGI) shores, but little evidence of RAM enrichment in CGIs. An analysis of promoter regions identified several hundred novel BPA-associated methylation events, and methylation alterations in the Myh7b and Slc22a12 gene promoters were validated. Using the Comparative Toxicogenomics Database, a number of candidate genes that have previously been associated with BPA-related gene expression changes were identified, and gene set enrichment testing identified epigenetically dysregulated pathways involved in metabolism and stimulus response. In this study, non-monotonic dose dependent alterations in DNA methylation among BPA-exposed mouse liver samples and their relevant pathways were identified and validated. The comprehensive methylome map presented here provides candidate loci underlying the role of early BPA exposure and later in life health and disease status. For this study, liver DNA from a subset of a/a wild-type animals was analyzed for full methylome characteristics: 1) standard diet (Ctr, n = 4 offspring; 2 male and 2 female); 2) 50 M-BM-5g BPA/kg diet (UG, n = 4 offspring; 2 male and 2 female); 3) 50 mg BPA/kg diet (MG, n = 4 offspring; 1 male and 3 female).

Project description:Here, we undertake the first epigenome-wide analysis of the effect of BPA concentration on human fetal liver DNA methylation. Enzymatic enrichment of genomic DNA for high CG density and methylation followed by next-generation sequencing yielded data for positional methylation across the genome. Comparing three groups of BPA-exposed subjects (n = 18; 6 per group), high (35.44–96.76 ng/g), low (3.50 to 5.79 ng/g), and non-detect (<0.83 ng/g), revealed regions of altered methylation. Similar numbers of regions of altered methylations were detected in pairwise comparisons; however, their genomic locations were distinct between the non-detect and low or high BPA groups. In general, BPA levels were positively associated with methylation in CpG islands and negatively associated with methylation in CpG shores, shelves, and repetitive regions. DNA methylation at the SNORD imprinted cluster (15q11q13) illustrated both linear and non-monotonic associations with BPA levels. BPA levels in human fetal liver tissue are associated with complex linear and non-monotonic as well as sequence-dependent alterations in DNA methylation.

Project description:We treated gestating female mice with vinclozolin (VZ), bisphenol A (BPA), di-(2-ethylhexyl) phthalate (DEHP), or control oil, during the time when the prospermatogonia of the exposed fetus undergo global de novo DNA methylation. Using genome-wide assays we detected changes in transcription and DNA methylation, respectively, in fetal prospermatogonia. Our results suggest that EDs exert direct epigenetic effects in the exposed fetal germ cells, but the germline corrects against deleterious effects in the subsequent generation. Pregnant mice were administered endocrine distruptors (VZ at 100 mg/kg/day, DEHP at 750 mg/kg/day, and BPA at 0.2 mg/kg/day) startin g at 12.5 days post coitum (dpc) and tissue samples were collected at 17.5 dpc.

Project description:According to recent reports, exposure to environmental endocrine disrupting chemicals (EDs) during pregnancy may harm multiple subsequent generations. We hypothesized that EDs must directly alter DNA methylation and/or transcription in the exposed fetal germ cells to affect the grandchild. In addition, the aberrant pattern must be retained in the germ cells of the grandchild -- withstanding global epigenome remodeling -- to affect the great-grandchild. To test this hypothesis, we extensively searched for immediate and persistent epigenetic effects in purified germ cells of the exposed fetus and those of the next generation. We treated gestating female mice with previously validated doses of vinclozolin (VZ), bisphenol A (BPA), di-(2-ethylhexyl) phthalate (DEHP), or control oil, during the time when the prospermatogonia of the exposed fetus undergo global de novo DNA methylation. Using genome-wide assays, we detected changes in transcription and DNA methylation in the exposed prospermatogonia but these did not persist into the prospermatogonia of the next generation. There was no evidence for transgenerational inheritance of these epigenetic aberrations. Our results suggest that EDs exert direct epigenetic effects in the exposed fetal germ cells, but the germline corrects against deleterious effects in the next generation. Pregnant mice were gavaged daily with endocrine distruptors (VZ at 100 mg/kg/day, DEHP at 750 mg/kg/day, BPA at 0.2 mg/kg/day or control oil) starting at 12.5 days post coitum (dpc) and the G1R germ cells were purified from the exposed fetuses at 17.5 dpc. The G2R germ cells were purified from fetuses that were sired by males that had been treated in utero in a G0 mother. G1R spermatozoa were collected from adult males that had been treated in utero at the fetal stages. G2R spermatozoa were collected from adult males who were sired by in-uteo-treated males.

Project description:According to recent reports, exposure to environmental endocrine disrupting chemicals (EDs) during pregnancy may harm multiple subsequent generations. We hypothesized that EDs must directly alter DNA methylation and/or transcription in the exposed fetal germ cells to affect the grandchild. In addition, the aberrant pattern must be retained in the germ cells of the grandchild -- withstanding global epigenome remodeling -- to affect the great-grandchild. To test this hypothesis, we extensively searched for immediate and persistent epigenetic effects in purified germ cells of the exposed fetus and those of the next generation. We treated gestating female mice with previously validated doses of vinclozolin (VZ), bisphenol A (BPA), di-(2-ethylhexyl) phthalate (DEHP), or control oil, during the time when the prospermatogonia of the exposed fetus undergo global de novo DNA methylation. Using genome-wide assays, we detected changes in transcription and DNA methylation in the exposed prospermatogonia but these did not persist into the prospermatogonia of the next generation. There was no evidence for transgenerational inheritance of these epigenetic aberrations. Our results suggest that EDs exert direct epigenetic effects in the exposed fetal germ cells, but the germline corrects against deleterious effects in the next generation. Pregnant mice were gavaged daily with endocrine distruptors (VZ at 100 mg/kg/day, DEHP at 750 mg/kg/day, BPA at 0.2 mg/kg/day or control oil) starting at 12.5 days post coitum (dpc) and the G1R germ cells were purified from the exposed fetuses at 17.5 dpc. The G2R germ cells were purified from fetuses that were sired by males that had been treated in utero in a G0 mother. G1R spermatozoa were collected from adult males that had been treated in utero at the fetal stages. G2R spermatozoa were collected from adult males who were sired by in-uteo-treated males.

Project description:Bisphenol A (BPA) is used in the plastic industry as the monomer of polycarbonates and epoxy resins. Heat and changes in pH conditions lead to its leakage from the plastics in which it is incorporated. This largely contributes to the widespread exposure of the general population to this environmental contaminant. The exposure levels in humans are likely below the Tolerable Daily Intake (TDI: 50 µg/kg/day) and well below the No Observable Adverse Effect Level (NOAEL: 5000 µg/kg/day) defined from reprotoxicity studies. However, several studies suggest that BPA could induce deleterious effects specifically at low, environmentally relevant, doses. BPA has been described as an endocrine disruptor with estrogenic activity. Recently, it has been shown that BPA exposure has an impact on metabolic functions including stimulation of adipogenesis and of insulin production by the pancreas. Here, we investigated the effects of oral exposure to low (TDI) and high (NOAEL) doses of BPA on mouse liver transcriptome. Liver gene expression was measured from CD-1 mice (6 mice/group) exposed for 28 days to bisphenol A at doses 0 (controls), 50 (TDI or low dose) or 5000 µg/kg/day (NOAEL or high dose) via food contamination.

Project description:Background：Bisphenol-A (BPA) has estrogenic activity and adversely affects humans and animals' reproductive systems and functions. There has been a disagreement with the safety of BPA exposure at Tolerable daily intake (TDI) (0.05 mg/kg/d) value and non-observed adverse effect level (5 mg/kg/d). The current study investigated the effects of BPA exposure at various doses starting from Tolerable daily intake (0.05 mg/kg/d) to the lowest observed adverse effect level (50 mg/kg/d) on the testis development in male mice offspring. The BPA exposure lasted for 63 days from pregnancy day 0 of the dams to post-natal day (PND) 45 of the offspring. Results：The results showed that BPA exposure significantly increased testis and serum BPA contents of PND 45 mice. The spermatogenic cells became loose, and the lumen of seminiferous tubules enlarged when BPA exposure at 0.05 mg/kg/d TDI. BPA exposure at a low dose (0.05 mg/kg/d) significantly reduced the expression of Scp3 proteins and elevated sperm abnormality. The significant decrease in Scp3 suggested that BPA inhibits the transformation of spermatogonia into spermatozoa in the testis. The RNA-seq proved that the spliceosome was significantly inhibited in the testes of mice exposed to BPA. According to the RT-qPCR, BPA exposure significantly reduced the expression of Snrpc and Hnrnpu. Conclusions：This study indicated that long-term BPA exposure at Tolerable daily intake (0.05 mg/kg/d) is not safe because low-dose long-term exposure to BPA inhibits spermatogonial meiosis in mice testis impairs reproductive function in male offspring.

Project description:The purpose of this study was to determine 1) the transcriptional program elicited by exposure to three estrogen receptor (ER) agonists: 17 a-ethynyl estradiol (EE), genistein (Ges) and bisphenol A (BPA) during fetal development of the rat testis and epididymis; and 2) whether very low dosages of estrogens (evaluated over five orders of magnitude of dosage) produce unexpected changes in gene expression (i.e., a non-monotonic dose-response curve). In three independently conducted experiments, Sprague-Dawley rats were dosed (s.c.) with 0.001-10mg EE/kg/day, 0.001-100 mg Ges/kg/day or 0.002-400mg BPA/kg/day. While morphological changes in the developing reproductive system were not observed, the gene expression profile of target tissues were modified in a dose-responsive manner. Independent dose-response analyses of the three studies identified 56 genes that are significantly modified by EE, 28 genes by Ges and 15 genes by BPA (out of 8740). Even more genes were observed to be significantly changed when only the high dose is compared with all lower doses: 141, 46 and 67 genes, respectively. Global analyses aimed at detecting genes consistently modified by all of the chemicals identified 52 genes whose expression changed in the same direction across the three chemicals. The dose-response curve for gene expression changes was monotonic for each chemical, with both the number of genes significantly changed and the magnitude of change, for each gene, decreasing with decreasing dose. Using the available annotation of the gene expression changes induced by ER-agonist, our data suggest that a variety of cellular pathways are affected by estrogen exposure. These results indicate that gene expression data are diagnostic of mode of action and, if they are evaluated in the context of traditional toxicological end-points, can be used to elucidate dose-response characteristics.

Project description:Perinatal exposure to bisphenol A (BPA) has been shown to cause aberrant mammary gland morphogenesis and mammary neoplastic transformation. Yet, the underlying mechanism is poorly understood. We tested the hypothesis that mammary glands exposed to BPA during a susceptible window may lead to its susceptibility to tumorigenesis through a stem-cell mediated mechanism. We exposed 21-day-old Balb/c mice to BPA by gavage (25 µg/kg/day) during puberty for 3 weeks, and a subset of animals were further challenged with one oral dose (30 mg/kg) of 7,12-dimethylbenz[a]anthracene (DMBA) at 2 months of age. Primary mammary cells were isolated at 6 weeks, and 2 and 4 months of age for mammary stem cell (MaSC) quantification and function analysis. Pubertal exposure to the low-dose BPA increased lateral branches and hyperplasia in adult mammary glands and caused an acute increase of MaSC in 6-week-old glands and a delayed increase of luminal progenitors in 4-month-old adult gland. Most importantly, pubertal BPA exposure altered the function of MaSC from different age groups, causing pre-neoplastic lesions in their regenerated glands similar to those induced by DMBA exposure, which indicates that MaSCs are susceptible to BPA-induced transformation. Deep sequencing analysis on MaSC-enriched mammospheres identified a set of aberrantly expressed genes associated with pre-neoplastic lesions in human breast cancer patients. Thus, our study for the first time shows that pubertal BPA exposure altered MaSC gene expression and function such that they induced early neoplastic transformation.

Project description:Bisphenol A (BPA) is used in the plastic industry as the monomer of polycarbonates and epoxy resins. Heat and changes in pH conditions lead to its leakage from the plastics in which it is incorporated. This largely contributes to the widespread exposure of the general population to this environmental contaminant. The exposure levels in humans are likely below the Tolerable Daily Intake (TDI: 50 µg/kg/day) and well below the No Observable Adverse Effect Level (NOAEL: 5000 µg/kg/day) defined from reprotoxicity studies. However, several studies suggest that BPA could induce deleterious effects specifically at low, environmentally relevant, doses. BPA has been described as an endocrine disruptor with estrogenic activity. Recently, it has been shown that BPA exposure has an impact on metabolic functions including stimulation of adipogenesis and of insulin production by the pancreas. Here, we investigated the effects of oral exposure to low (TDI) and high (NOAEL) doses of BPA on mouse liver transcriptome.