Project description:PFAS are persistent man-made chemicals considered to be emerging pollutants, with PFOA, PFOS, and PFHxS having associations with liver toxicity and steatosis. PFOA, PFOS, and PFHxS can undergo placental/lactational transfer, however, little is known about the impact of PFAS mixtures during the developmental window, nor maternal diet on PFAS adverse effects. It was hypothesized that gestational/lactational PFAS exposure would alter the pup liver proteome. The work herein evaluated the liver proteome in offspring, identifying potential biochemical/signaling pathways altered via maternal PFAS exposure. Timed-pregnant CD-1 dams were fed a standard chow or 60% kcal high-fat diet. From GD1 until PND20, dams were orally gavaged daily with either 0.5% Tween 20, individual PFOA, PFOS, PFHxS at 1 mg/kg, or a mixture (1 mg/kg each, totaling 3 mg/kg). Livers were collected from PND21 offspring and SWATH-MS pro-teomics was performed. IPA analysis revealed disease and biological function pathways involved in liver damage, xenobiotics, and lipid regulation were modulated by PFAS exposure in the PND21 liver: lipid transport, storage, oxidation, and synthesis, xenobiotic metabolism and transport, liver damage and inflammation, and fatty acid metabolism, oxidation and transport. This indicates the pup liver proteome is altered via maternal exposure and predisposes the pup to metabolic dysfunctions.

Project description:Understanding the mechanisms by which environmental chemicals cause toxicity is necessary for effective human health risk assessment. High-Throughput Transcriptomics (HTTr) can be used to inform risk assessment on toxicological mechanisms, hazards, and potencies. We applied HTTr to elucidate the molecular mechanisms by which Per- and Polyfluoroalkyl Substances (PFAS) cause liver toxicity. We contrasted transcriptomic profiles of four prototype PFAS against transcriptomic profiles from liver-toxic and non-liver-toxic reference compounds, alongside chemicals that activate peroxisome proliferator-activated receptors (PPARs). Our analysis was conducted on metabolically competent 3-D human liver spheroids produced from primary cells of 10 donors. Pathway analysis showed that PFOS and PFDS perturb many of the same pathways as the liver-toxic compounds in the spheroids, and that the cholesterol biosynthesis pathways are significantly affected by exposure to these compounds. PFOA alters lipid metabolism-related pathways but its expression profile does not closely match reference compounds. PFBS upregulates many degradation-related pathways and targets many of the same pathways as the PPAR agonists and acetaminophen. Our transcriptional analysis does not support that these PFAS are DNA damaging in this model. A multidimensional scaling analysis revealed that PFOS, PFOA, and PFDS cluster together in the same 3-D space as liver-damaging compounds; whereas, PFBS clusters more closely with the non-liver-damaging compounds. Benchmark concentration-response modeling predicts that all the PFAS are sufficiently bioactive to be liver-toxic. Overall, our results show that these PFAS produce unique transcriptional changes as well as altering pathways associated with established liver-toxic chemicals in this liver spheroid model.

Project description:This study set out to evaluate the hypothesis that PFAS exposure alters EV regulation via upstream molecular mediators of EV-based alterations through cellular transcriptomics assessment in a concentration-response manner. To evaluate this hypothesis, HepG2 liver cells were treated in concentration-response with individual PFOS, PFOA, or PFHxA, in addition to an equimolar PFAS mixture. Global gene expression was measured. These analyses set out to evaluate concentration-dependent changes in mRNA signatures within HepG2 immortalized liver cells exposed to individual PFOS, PFOA, PFHxA or an equimolar mixture containing all three PFAS.

Project description:Per- and polyfluoroalkyl substances (PFAS) are pervasive environmental pollutants with diverse toxic effects, including endocrine disruption and hepatotoxicity. As a key class of immune cells, macrophages are critical target for endocrine disrupting chemicals (EDCs); however, their role in PFAS-induced toxicity and the underlying mechanisms remain poorly understood. In this study, we developed a high-content cell model by utilizing the activation and differentiation of human THP-1 monocytes into macrophages, enabling rapid quantitative screening of various PFAS chemicals. Our results identified that PFOA, PFUnDA, and HFPODA suppressed macrophage alternative activation to varying extents by disrupting the PPAR signaling pathway. In vivo, oral exposure to PFOA and PFUnDA in wild-type C57BL/6J mice significantly impaired macrophage alternative activation in the liver, resulting in hepatocyte hypertrophy, liver dysfunction, and systemic lipid metabolism disorders. Furthermore, macrophage-specific PPARγ knockout exacerbated PFAS-induced hepatotoxicity. These findings highlight the immunometabolic regulatory role of macrophage activation in PFAS-induced liver toxicity and provide novel insights into the health risks posed by PFAS exposure in humans.

Project description:Per- and polyfluoroalkyl substances (PFAS) are pervasive environmental pollutants with diverse toxic effects, including endocrine disruption and hepatotoxicity. As a key class of immune cells, macrophages are critical target for endocrine disrupting chemicals (EDCs); however, their role in PFAS-induced toxicity and the underlying mechanisms remain poorly understood. In this study, we developed a high-content cell model by utilizing the activation and differentiation of human THP-1 monocytes into macrophages, enabling rapid quantitative screening of various PFAS chemicals. Our results identified that PFOA, PFUnDA, and HFPODA suppressed macrophage alternative activation to varying extents by disrupting the PPAR signaling pathway. In vivo, oral exposure to PFOA and PFUnDA in wild-type C57BL/6J mice significantly impaired macrophage alternative activation in the liver, resulting in hepatocyte hypertrophy, liver dysfunction, and systemic lipid metabolism disorders. Furthermore, macrophage-specific PPARγ knockout exacerbated PFAS-induced hepatotoxicity. These findings highlight the immunometabolic regulatory role of macrophage activation in PFAS-induced liver toxicity and provide novel insights into the health risks posed by PFAS exposure in humans.

Project description:We investigated the effects of per- and polyfluroralkyl substance exposure on FRG liver-chimeric humanized mice on a C57Bl/6 background. These PFAS included PFOA, PFOS, and GenX. These mice were exposed to water ad libitum for 28 days to reach human relevant serum concentrations. We then performed RNA-Sequencing on isolated whole liver lysate to determine differentially expressed genes.

Project description:Per- and polyfluoroalkyl substances (PFAS) are a group of organic chemicals that contain multiple carbon-fluorine bonds, which make them highly stable and widespread in our environment, even in the human body. They have been detected in cord blood and showed correlation with neonatal health abnormalities such as weight loss. Here, we utilized human embryonic stem cell-based model to assess the early developmental toxicity of six PFAS (PFOA, PFHxA, PFBA, PFOS, PFHxS, and PFBS) and their skin developmental toxicity. We employed global monolayer differentiated model to mimic the early embryonic development and performed non-neural ectoderm (NNE) differentiation which can give rise to keratinocytes to imitate early skin development. Transcriptomic analysis revealed that PFOS caused the most differentially expressed genes (DEGs) both in day 16 global monolayer samples and NNE samples to making it the most toxic of the six PFAS. Further validation of gene expression levels showed that the TGF-β signaling pathways were involved in the early global developmental toxicity and in the early skin developmental toxicity of PFOS. Interestingly, our results showed that PFOS inhibited the ciliogenesis of NNE cells, which may interfere with the transduction of TGF-β, Notch, Hedgehog, and Hippo signaling pathways, ultimately inhibiting early embryonic skin development and posing a potential threat to the occurrence of congenital skin diseases. Overall, our study suggests a potential toxicity mechanism by which PFAS inhibit ciliogenesis to interfere with the transduction of important signaling pathways, leading to early global developmental toxicity as well as early embryonic skin developmental toxicity and potential congenital skin diseases.

Project description:Per- and polyfluoroalkyl substances (PFAS) are environmental contaminants of concern due to their persistence and potential adverse health effects. Epidemiological studies have linked PFAS with an increased risk of uterine diseases including fibroids however, the mechanisms involved remain to be elucidated. This study investigated the effects of individual PFAS, including long-chain “legacy” PFAS [perfluorooctanoic acid (PFOA), perfluorooctanesulfonic acid (PFOS)] and short-chain “alternative” PFAS compounds [undecafluoro-2-methyl-3-oxahexanoic acid (GENX/HFPO-DA), perfluorobutanesulfonic acid (PFBS)], as well as a mixture of these chemicals on the function and transcriptome of an immortalized human myometrial cell line (UT-TERT). UT-TERT cells exposed to individual PFAS displayed increased cell viability and proliferation. Flow cytometry analysis revealed that PFOS and the PFAS mixture altered cell cycle progression. Migration assays demonstrated that PFOS and the PFAS mixture significantly enhanced UT-TERT cell migration. Gap junction intercellular communication (GJIC) was impaired following PFOA, PFBS, and PFAS mixture exposure, indicating potential disruptions in cell-to-cell communication within the uterine environment. Transcriptomic analysis using RNA-seq identified substantial changes in gene expression after exposure to environmentally relevant levels of individual PFAS and PFAS mixture. Pathway analysis revealed common molecular pathways associated with PFAS exposure, including Cell-to-Cell Signaling, Lipid Metabolism, and Cell Death and Survival, while other pathways were unique to specific PFAS. These findings highlight the multifaceted effects of PFAS on myometrial cells, providing insights into the potential mechanisms underlying PFAS-associated health risks. Further research is necessary to elucidate the long-term implications of PFAS exposure on uterine function and overall reproductive health.

Project description:Accumulating evidence suggests that poly- and perfluoroalkyl substances (PFAS), a class of persistent organic pollutants, cause changes in hepatic lipid, amino acid, and glucose metabolism. Our study explores the molecular mechanisms whereby PFHxS, PFOA, PFOS, and PFNA disrupt liver metabolism.

Project description:Per- and poly-fluoroalkyl substances (PFAS) are persistent environmental contaminants prevalent in industrial manufacturing processes and various consumer products. Human health consequences include reduced fertility, liver damage, thyroid disease, kidney disease, cancer, inflammation, hypertension, and obesity. In this study, various approaches were used to determine toxicological points of departure (PODs) for 9 PFAS (PFDS, PFDS, PFOA, PFOS, PFBA, PFBS, PFHxA, PFHxS, PFNA) in Zebrafish embryos exposed for 5 days from 4 to 120 hours post-fertilization. Apical PODs (aPODs) were assessed for developmental toxicity (based on mortality and malformation), behaviour (based in distance swum under light and dark conditions) and metabolism (based on NADH-dependent changes in alamarBlue fluorescence). Transcriptional PODs (tPODs) were determined using TempO-Seq S1500+ Zebrafish Surrogate Assay Panel applied to pools of 10 embryos. Count data were generated using the Omics data analysis framework for regulatory application (R-ODAF) pipeline, available at https://github.com/R-ODAF/R-ODAF_Health_Canada. Transcriptomic BMC modeling was performed using BMDExpress. PFAS toxicity was highest for PFAS with longer carbon chain length, and with a functional group of sulfonic acid compared with carboxylic acid. This toxicity ranking was similar across all aPODs and tPODs. This study demonstrates that for PFAS chemicals, transcriptional PODs can be used to reliably predict other aPOD estimates generated through assessments of metabolism, behaviour, or mortality/malformation.