Project description:Bisphenol compounds (BPs) have various industrial uses and can enter the environment through various sources. To evaluate the ecotoxicity of BPs and identify potential gene candidates involved in the plant toxicity, Arabidopsis thaliana was exposed to bisphenol A (BPA), BPB, BPE, BPF, and BPS at a concentration of 1, 3, 10 mg/L for a duration of 14 days, and their growth status were monitored. At day 14, roots and leaves samples were collected for internal BPs exposure concentration detection, RNA-seq, and morphological observations. As shown in the results, exposure to BPs significantly disturbed root elongation, exhibiting a trend of stimulation at low concentration and inhibition at high concentration. Additionally, BPs exhibited pronounced generation of ROS, while none of the pollutants caused significant changes in root morphology. Internal exposure concentration analysis indicate that BPs tend to accumulate in the roots, with BPS exhibiting the highest level of accumulation. The results of RNA-seq indicate that shared 211 differently expressed genes (DEGs) of these 5 exposure groups are enriched in defense response, generation of precursor metabolites, response to organic substance, response to oxygen-containing, response to hormone, oxidation-reduction process and so on. Regarding unique DEGs in each group, BPS was mainly associated with the redox pathway, BPB primarily influenced seed germination, and in BPA, BPE and BPF were primarily involved in metabolic signaling pathways. Our results provide new insights for BPs induced adverse effects on Arabidopsis thaliana and suggest that the ecological risks associated with BPA alternatives cannot be ignored. At 14 d, roots in 3 mg/kg BPA, BPB, BPE, BPF and BPS exposure groups and the control were collected for RNA-seq analysis.

Project description:Bisphenol A (BPA) analogs, bisphenol B (BPB) and bisphenol AF (BPAF) have been widely detected in the environment and human products with increasing frequency. However, uterine health risks caused by BPBBisphenol A (BPA) analogs, bisphenol B (BPB) and bisphenol AF (BPAF) have been widely detected in the environment and human products with increasing frequency. However, uterine health risks caused by BPB and BPAF exposure need to be further elucidated. The study aimed to explore whether BPB or BPAF exposure will induce adverse outcomes in uterus. We then performed gene expression profiling using data obtained from mouse uterus exposed to BPB and BPAF at 28 days.

Project description:Plasticizers with estrogenic activity, such as bisphenol A (BPA), have been reported to have potential adverse health effects in humans, especially in fetal and infant stages. Due to mounting evidence and public pressure BPA is being phased out by the plastics manufacturing industry and is being replaced by other bisphenol variants in “BPA-free” products. We have compared estrogenic activity of 7 bisphenol analogues (BPA; bisphenol S, BPS; bisphenol F, BPF; bisphenol AP, BPAP; bisphenol AF, BPAF; bisphenol Z, BPZ; bisphenol B, BPB) in human breast cancer cell lines. We used microarrays to detail the alterations in gene expression profiles associated with MCF-7 cell line exposure to bisphenol A analogues

Project description:Bisphenol A (BPA), which is used in a variety of consumer-related plastic products, was reported to cause metabolic disruption. Substitute compounds are increasingly emerging, but are not sufficiently investigated. In this study, we aimed to investigate the mode of action of BPA and four of its substitutes during the differentiation of human preadipocytes. Human preadipocytes were exposed to BPA, BPS, BPB, BPF, and BPAF, as well as the PPARγ-antagonist GW9662. After 12 days of differentiation, global protein profiles were assessed using LC-MS/MS-based proteomics.

Project description:Bisphenols F (BPF) and S (BPS) are BPA structural analogs used in many marketed products as a replacement for BPA. Since sparse toxicological data are available yet for these bisphenol substitutes, our objective was to comprehensively characterize bisphenols gene targets in a human primary adipocyte model, using chronic exposure at two concentrations: a “low-dose” similar to the dose usually encountered in human biological fluids and a higher dose.

Project description:Bisphenols F (BPF) and S (BPS) are BPA structural analogs used in many marketed products as a replacement for BPA. Since sparse toxicological data are available yet for these bisphenol substitutes, our objective was to comprehensively characterize bisphenols gene targets in a human primary adipocyte model, using chronic exposure at two concentrations: a “low-dose” similar to the dose usually encountered in human biological fluids and a higher dose.

Project description:Bisphenols are used in the process of polymerization of polycarbonate plastics and epoxy resins, which have numerous applications in a variety of consumer products. Due to their hydrophobic properties, bisphenols can easily migrate out of plastic products especially into fatty foods. They have been found in brain, liver, adipose tissue and body fluids, illustrating their environmental prevalence. By increasing colonic inflammation in mice, disrupting the intestinal bacterial community structure and altering the microbial membrane transport system in zebrafish, bisphenols seem to interfere with the gut microbiome. The highly abundant human commensal bacterium Bacteroides thetaiotaomicron was exposed to bisphenols (Bisphenol A (BPA), Bisphenol F (BPF), Bisphenol S (BPS)), to examine the mode of action, in particular of BPF. All chemicals caused a concentration-dependent growth inhibition and the half-maximal effective concentration (EC50) corresponded to their individual logP values, a measure of their hydrophobicity. B. thetaiotaomicron exposed to BPF decreased membrane fluidity with increasing BPF concentrations. Physiological changes including an increase of acetate concentration were observed in cells treated with 0.57 mM BPF. On the proteome level, a higher abundance of several ATP synthase subunits and multidrug efflux pumps suggested an increased energy demand for adaptive mechanisms after BPF exposure. Defence mechanisms were also implicated by a pathway analysis, that identified a higher abundance of members of resistance pathways/strategies to cope with xenobiotics (i.e. antibiotics). Here, we present further insights into the mode of action of bisphenols in a human commensal gut bacterium regarding growth inhibition, and the physiological and functional state of the cell. These results, combined with microbiota-directed effects, could lead to a better understanding of host health disturbances and disease development based on xenobiotic uptake.

Project description:Purpose: the goal of this study is to determine the changes in gene expression during EB differentiation after BPA, BPF and BPS treatments, as indications of potential developmental toxicity. Methods: Transcriptomics profiling for EB samples treated with 100 nM BPA, BPF, BPS or DMSO control at different time points were generated by RNA-seq, using a BGISEQ-500 platform. Reads were filtered and aligned to the reference genome with Bowtie2. Results: BPA, BPF and BPS disrupted many processes, during mESC global and neural differentiations, in very similar manners. In fact, analogous gene categories were differentially regulated by the three chemicals, at each time point, particularly the ones involved in cell-matrix and cell-cell adhesions, signal transduction pathways, and medical conditions such as cardiovascular diseases and cancer.

Project description:Bisphenol A (BPA), widely used in plastics and resins, raised health concerns for its endocrine-disrupting effects. BPA analogues like bisphenol S (BPS) and bisphenol F (BPF) emerged as alternatives but were found to exhibit similar risks. Despite many countries have implemented BPA regulations, alternatives remain insufficiently regulated Although the safety of BPS and BPF has not been sufficiently verified, they have already been detected in various surrounding environments and human urine, raising serious concerns Bisphenols are expected to have various adverse effects, but research on this is lacking. This study explores the adverse effects of bisphenol mixtures on rats from fetus to young adulthood, analyzing transcriptomes by tissue and gender to identify key genes impacted by bisphenol exposure. Dams were orally administered test substances from gestational day 6 to lactation day 6. F1 pups received the same substances at half the concentration from postnatal day 7 to day 63. The tissues collected from the pups were subjected to transcriptome analysis, and core genes were identified through integrated analysis. The study identifies core genes associated with high-density lipoprotein and hormone secretion. These genes provide insights into the mechanisms through which BPA may cause hormonal imbalances. Furthermore, the study suggests that a complex exposure of BPA, BPS, and BPF can exerts different effects than BPA alone, pronounced effects on the thyroid and reproductive organs, even though individual concentrations were below the no-observed-adverse-effect-level. It highlights the potential cumulative impact of endocrine disrupting chemicals in the body.

Project description:Since initial regulatory action in 2010 in Canada, bisphenol A (BPA) has been progressively replaced by structurally related alternative chemicals. Unfortunately, many of these chemicals are data-poor, limiting toxicological risk assessment. We used high-throughput transcriptomics to evaluate potential hazards and compare potencies of BPA and 15 BPA alternative chemicals in cultured breast cancer cells. MCF-7 cells were exposed to BPA and 15 alternative chemicals (0.0005 – 100 µM) for 48 hrs. TempO-Seq sequencing (BioSpyder Inc.) was used to examine general toxicological effects and estrogen receptor alpha (ERα)-associated transcriptional changes. Benchmark concentration (BMC) analysis was conducted to identify two global transcriptomic points of departure (tPODs): (a) the lowest pathway median gene BMC and (b) the 25th lowest rank-ordered gene BMC. ERα activation was evaluated using a published transcriptomic biomarker and an ERα-specific tPOD was derived. Genes fitting BMC models were subjected to upstream regulator and canonical pathway analysis in Ingenuity Pathway Analysis. Biomarker analysis identified BPA and eight alternative chemicals as ERα active. Global and ERα tPODs produced highly similar potency rankings with BPAF as the most potent chemical tested, followed by BPA, BPC, 4,4’-BPF, BPAP, BPS, BADGE, 2,4’-BPF, Pergafast201®, D-8, 2,4’-BPS, TGSA, and BPS-MAE. Further, BPA and transcriptionally active alternative chemicals enriched similar gene sets associated with increased cell division and cancer-related processes. These data provide support for future read-across applications of transcriptomic profiling for risk assessment of data-poor chemicals and suggest that several BPA alternative chemicals may cause hazards at similar concentrations to BPA.