Project description:Occupational and consumer exposure to GRMs will increase but their impact on human health is still largely unknown. We sought to perform a transcriptome comparison of the bioresponses of MDM and THP-1 macrophages exposed to 5 or 20 µg/ml graphene oxide (GO) or graphene nanoplatelets (GNP) for 6 and 24 h to capture early and more persistent acute responses. Cristalline silica (DQ) was included as immunotoxic reference material.

Project description:circRNA sequencing for 6 samples.The increasing use of graphene oxide-silver nanoparticle nanocomposites (GO-AgNPs) in biomedical sciences and research also increases the chances of human and animal exposure to its chronic non-toxic doses. However, the available information is truly little for profound understanding of the effect of low-dose chronic exposure to GO-AgNPs on the epigenetic modification of the organism. In this research, we have investigated the impact of non-toxic doses of GO-AgNPs (0.5 µg/mL for 10 weeks, this dose does not interfere cell viability and ROS level) on the differential expression of circular RNAs (circRNAs) in caprine fetal fibroblast cells (CFFCs). In addition, using bioinformatics tools we have predicted the functions of those differentially expressed circRNAs on CFFCs. Furthermore, we have validated the expression of ten circRNAs using qRT-PCR to ensure the reliability of the sequencing data. The results showed that the differentially expressed circRNAs potentially regulates the GO-AgNPs induced epigenetic toxicity through a regulatory network consisted of circRNAs, miRNAs and mRNAs. Therefore, the inclusion of epigenetics approaches is essential to assess the biosafety level of GO-AgNPs nanomaterials.

Project description:Pulmonary exposure to high doses of nanoparticles (NP) leads to well characterized lung toxicity in addition to long-term NP retention. However, pulmonary NP accumulation and toxicity following low dose exposures are not well described. In the present study we sought to: (1) investigate particle retention in mouse lungs following intratracheal instillation of varying doses of nano-sized titanium dioxide (nano-TiO2) and (2) determine the effects of long-term particle accumulation on pulmonary systems. Female C57BL/6 mice were exposed to rutile nano-TiO2 (primary size of 20.6 nm and surface area of 107.7 m2/g) via single intratracheal instillations of 18, 54 and 162 µg/mouse and sampled 1, 3 and 28 days post-exposure. The deposition of nano-TiO2 in the lungs was assessed using Nanoscale Hyperspectral Microscope. DNA microarrays, pathway-specific real-time RT-PCR (qPCR) and gene-specific qPCR arrays, and tissue protein analyses were employed to characterize pulmonary responses. Hyperspectral mapping showed dose-dependent retention of nano-TiO2 in the lungs up to 28 days post-exposure time. Retention did not correlate with the extent of inflammatory neutrophil influx into the lungs. DNA microarray analysis showed altered expression of approximately 3000 genes across all treatment groups (±1.3 fold; p<0.1). Several inflammatory mediators changed in a dose- and time-dependent manner at both the mRNA and protein levels. Although the low dose exposure failed to induce observable inflammation, significant changes in the expression of genes and proteins associated with inflammation were observed. Moreover, diminished (or absent) neutrophil influx in the low and medium dose groups was correlated with negative regulation of genes associated with ion homeostasis and muscle regulation. Gene expression changes for several inflammatory mediators have previously been noted in mice exposed to the same nano-TiO2 via inhalation. Our results suggest that retention of nano-TiO2 in the absence of inflammation and effective clearance can perturb calcium and ion homeostasis, and affect smooth muscle activities over time.

Project description:Developmental lead (Pb) exposure results in persistent cognitive/behavioral impairments as well as an elevated risk for developing a variety of diseases in later life. Environmental exposures during development can result in a variety of epigenetic changes, including alterations in DNA methylation, that can influence gene expression patterns and affect the function and development of the nervous system. The present promoter-based methylation microarray profiling study explored the extent to which developmental Pb exposure may modify the methylome of a brain region, hippocampus, known to be sensitive to the effects of Pb exposure. Male and female Long Evans rats were exposed to 0 ppm, 150 ppm, 375 ppm, or 750 ppm Pb through perinatal exposures (gestation through lactation), early postnatal exposures (birth through weaning), or long-term postnatal exposures (birth through postnatal day 55). Results showed a significant contribution of sex to the hippocampal methylome and effects of Pb exposure level, with non-linear dose response effects on methylation. Surprisingly, the developmental period of exposure contributed only a small amount of variance to the overall data and gene ontology (GO) analysis revealed the largest number of overrepresented GO terms in the groups with the lowest level of exposure. The highest number of significant differentially methylated regions was found in females exposed to Pb at the lowest exposure level. Our data reinforce the significant effect that low level Pb exposure may have on gene-specific DNA methylation patterns in brain and that this occurs in a sex-dependent manner. NimbleGen Rat CpG Island plus RefSeq Promoter 720k array

Project description:This study investigates transcriptomic differences in the lung and liver after pulmonary exposure to two Graphene based materials with similar physical properties, but different surface chemistry. Female C57BL/6 mouse were exposed by a single intratracheal instillation of 0, 18, 54 or 162 μg/mouse of graphene oxide (GO) or reduced graphene oxide (rGO). Pulmonary and hepatic transcriptional changes were compared to identify commonly and uniquely perturbed functions and pathways by GO and rGO. These changes were then related to previously analyzed endpoints. GO exposure induced more differentially expressed genes, affected more functions, and perturbed more pathways compared to rGO, both in the lung and liver.

Project description:Human bronchial lung cells (BEAS-2B) were treated for 6 weeks with low doses (1 µg/mL) of Ag nanoparticles (10 nm citrate-coated). At the end of the exposure control and treated samples were submitted for DNA methylation analysis (Illumina 450k). The overall goal of this experiment was to evaluate potential epigenetic changes associated with low-dose, long-term exposure to Ag nanoparticles.

Project description:Bronchial epithelial cells, which line the airway of the respiratory tract, undergo genome-wide level changes in gene expression and DNA methylation particularly when exposed to fine (< 2.5 µm) PM (PM2.5). Although some of these changes have been reported in other studies, a comparison of how different doses and duration of exposure affect both the gene transcriptome and DNA methylome has not been done. We exposed BEAS-2B, a bronchial epithelial cell line, to a single exposure of high (30 µg/cm2) or low (1 µg/cm2) dose of PM2.5 (obtained from Beijing, China in 2015) for 24 hours. We also exposed BEAS-2B cells to repeated exposures of low dose (1 µg/cm2) PM2.5 every day for seven days. We then examined the transcriptomic changes (by RNA-Seq) and DNA methylomic changes (by enhanced reduced representation bisulfite sequencing). Widespread changes in gene expression occurred after cells were exposed to a single, high dose (30 µg/cm2) exposure of PM2.5 for 24 h. These genes were enriched in pathways regulating MAPK signaling, PI3K-Akt signaling, cytokine interactions, IL6, and P53. DNA methylomic analysis showed that nearly half of the differentially expressed genes were found to also have DNA methylation changes. Cells exposed to a lower dose (1 µg/cm2) of PM2.5 demonstrated a similar, but more attenuated change in gene expression. Cells exposed to repeated doses of PM2.5 for seven days, however, demonstrated a different set of genes that were differentially expressed compared to a single exposure. The DNA methylation changes that occurred with repeated, low dose exposure were also different from single high dose exposures and skewed towards overall hypomethylation. This hypomethylation corresponded with an increase in expression of ten-eleven translocation enzymes. Overall, these data demonstrate how variations in dose and duration of PM2.5 exposure induce distinct differences in the transcriptomic and DNA methylomic profile of bronchial epithelial cells.

Project description:Bronchial epithelial cells, which line the airway of the respiratory tract, undergo genome-wide level changes in gene expression and DNA methylation particularly when exposed to fine (< 2.5 µm) PM (PM2.5). Although some of these changes have been reported in other studies, a comparison of how different doses and duration of exposure affect both the gene transcriptome and DNA methylome has not been done. We exposed BEAS-2B, a bronchial epithelial cell line, to a single exposure of high (30 µg/cm2) or low (1 µg/cm2) dose of PM2.5 (obtained from Beijing, China in 2015) for 24 hours. We also exposed BEAS-2B cells to repeated exposures of low dose (1 µg/cm2) PM2.5 every day for seven days. We then examined the transcriptomic changes (by RNA-Seq) and DNA methylomic changes (by enhanced reduced representation bisulfite sequencing). Widespread changes in gene expression occurred after cells were exposed to a single, high dose (30 µg/cm2) exposure of PM2.5 for 24 h. These genes were enriched in pathways regulating MAPK signaling, PI3K-Akt signaling, cytokine interactions, IL6, and P53. DNA methylomic analysis showed that nearly half of the differentially expressed genes were found to also have DNA methylation changes. Cells exposed to a lower dose (1 µg/cm2) of PM2.5 demonstrated a similar, but more attenuated change in gene expression. Cells exposed to repeated doses of PM2.5 for seven days, however, demonstrated a different set of genes that were differentially expressed compared to a single exposure. The DNA methylation changes that occurred with repeated, low dose exposure were also different from single high dose exposures and skewed towards overall hypomethylation. This hypomethylation corresponded with an increase in expression of ten-eleven translocation enzymes. Overall, these data demonstrate how variations in dose and duration of PM2.5 exposure induce distinct differences in the transcriptomic and DNA methylomic profile of bronchial epithelial cells.

Project description:Domoic acid (DA) is a neuroexcitatory amino acid that is naturally produced by some marine diatom species of the genus Pseudo-nitzschia. Ingestion of DA-contaminated seafood by humans results in a severe neurotoxic disease known as amnesic shellfish poisoning (ASP). Clinical signs of ASP include seizures and neuronal damage from activation of AMPA and kainate receptors. However, the impacts of DA exposure at levels below those known to induce outward signs of neurobehavioral exicitotoxicity have not been well characterized. To further understand the mechanisms of neurotoxic injury associated with DA exposure, we examined the transcriptome of whole brains from zebrafish (Danio rerio) receiving intracoelomic (IC) DA at both symptomatic and asymptomatic doses. A majority of zebrafish exposed to high-dose DA (1.2 µg DA/g) exhibited clinical signs of neuroexcitotoxicity (EC50 of 0.86 µg DA/g) within 5 to 20 minutes of IC injection. All zebrafish receiving low-dose DA (0.47 µg DA/g) or vehicle only maintained normal behavior. Microarray analysis of symptomatic and asymptomatic exposures collectively yielded 306 differentially expressed genes (1.5-fold, p = 0.05) predominately represented by signal transduction, ion transport, and transcription factor functional categories. Transcriptional profiles were suggestive of neuronal apoptosis following an overwhelming of protective adaptive pathways. Further, potential molecular biomarkers of neuropathic injury, including Nrdg4, were identified and may be relevant to DA exposure levels below that causing neurobehavioral injury. Our results validate zebrafish as a vertebrate model to study mechanisms of DA neurotoxicity and provide a basis for identifying pathways of DA-induced injury as well as biomarkers of asymptomatic and symptomatic DA exposure levels. Keywords: neurotoxic disease To further understand the mechanisms of neurotoxic injury associated with DA exposure, we examined the transcriptome of whole brains from zebrafish (Danio rerio) receiving intracoelomic (IC) DA at both symptomatic and asymptomatic doses. A majority of zebrafish exposed to high-dose DA (1.2 µg DA/g) exhibited clinical signs of neuroexcitotoxicity (EC50 of 0.86 µg DA/g) within 5 to 20 minutes of IC injection. All zebrafish receiving low-dose DA (0.47 µg DA/g) or vehicle only maintained normal behavior. Microarray analysis of symptomatic and asymptomatic exposures collectively yielded 306 differentially expressed genes (1.5-fold, p = 0.05) predominately represented by signal transduction, ion transport, and transcription factor functional categories. All animal studies were carried out under approved IACUC protocols at the University of Washington.

Project description:Pulmonary exposure to high doses of nanoparticles (NP) leads to well characterized lung toxicity in addition to long-term NP retention. However, pulmonary NP accumulation and toxicity following low dose exposures are not well described. In the present study we sought to: (1) investigate particle retention in mouse lungs following intratracheal instillation of varying doses of nano-sized titanium dioxide (nano-TiO2) and (2) determine the effects of long-term particle accumulation on pulmonary systems. Female C57BL/6 mice were exposed to rutile nano-TiO2 (primary size of 20.6 nm and surface area of 107.7 m2/g) via single intratracheal instillations of 18, 54 and 162 M-BM-5g/mouse and sampled 1, 3 and 28 days post-exposure. The deposition of nano-TiO2 in the lungs was assessed using Nanoscale Hyperspectral Microscope. DNA microarrays, pathway-specific real-time RT-PCR (qPCR) and gene-specific qPCR arrays, and tissue protein analyses were employed to characterize pulmonary responses. Hyperspectral mapping showed dose-dependent retention of nano-TiO2 in the lungs up to 28 days post-exposure time. Retention did not correlate with the extent of inflammatory neutrophil influx into the lungs. DNA microarray analysis showed altered expression of approximately 3000 genes across all treatment groups (M-BM-11.3 fold; p<0.1). Several inflammatory mediators changed in a dose- and time-dependent manner at both the mRNA and protein levels. Although the low dose exposure failed to induce observable inflammation, significant changes in the expression of genes and proteins associated with inflammation were observed. Moreover, diminished (or absent) neutrophil influx in the low and medium dose groups was correlated with negative regulation of genes associated with ion homeostasis and muscle regulation. Gene expression changes for several inflammatory mediators have previously been noted in mice exposed to the same nano-TiO2 via inhalation. Our results suggest that retention of nano-TiO2 in the absence of inflammation and effective clearance can perturb calcium and ion homeostasis, and affect smooth muscle activities over time. This experiment consists of three different dosages of TiO2, e.g., low (18 ug), medium (54 ug) and high (162 ug), and one control. There are 3 time points for each treatment and control group, e.g., day 1, day 3 and day 28. Each dose or time point has 5-6 biological replicates. There are total 65 samples (arrays)