Project description:Behavioral deficits encompassing motor, cognitive, and psychological domains can emerge after removal of manganese (Mn) exposures in humans and other mammals. While epidemiological studies provide substantial evidence supporting latent persistent Mn neurotoxicity, reproducing such effects in cellular and non-mammalian model systems has slowed mechanistic understanding. Here we report in human induced pluripotent stem cell (hiPSC)-derived cortical cultures that chronic Mn exposure elicits clear latent and persistent neurotoxic effects in gene expression and functional outcomes. To identify persistent and latent effects, and investigate underlying mechanisms, single-cell RNA sequencing was employed in the hiPSC model to provide a comprehensive cell-type specific comparison of transcriptomic changes immediately at the termination versus after a prolonged cessation of chronic Mn exposures. Transcriptomic alterations revealed clear latency of effects after Mn cessation that were not detected immediately following the 40-day exposure. Identified alterations support the linkage between the latent and persistent effects of chronic Mn exposure and a broad range of neurodegenerative pathogenesis and provide insight into the cellular pathways involved.

Project description:The dataset contained concentration course exposures of 24hpf old zebrafish embryos with tetrachloroethylene (PCE). The exposure duration was set to 12h and 24h and the concentrations were chosen to be not higher than the LC10.

Project description:We report the application of RNA-Seq analysis to determine the transcriptional responses to Mn dose, ranging from physiological to toxicological levels in human SH-SY5Y neuroblastoma cells. We find that Mn dose showed widespread effects in abundance of protein coding genes for metabolism of reactive oxygen species, energy sensing, glycolysis, protein homeostasis including the unfolded protein response and transcriptional regulation. Adaptive responses at physiological Mn concentration-10 μM Mn for 5 h, a concentration that did not result in cell death after 24 h increased abundance of differentially expressed genes (DEGs) in the protein secretion pathway that function in protein trafficking and cellular homeostasis.These include BET1 (Golgi vesicular membrane trafficking protein), ADAM10 (ADAM metallopeptidase domain 10) and ARFGAP3 (ADP-ribosylation factor GTPase activating protein 3). In contrast, 5 h exposure to 100 μM Mn, a concentration that caused cell death after 24 h, increased abundance of DEGs for components of the mitochondrial oxidative phosphorylation pathway. In conclusion, this study provides a framework for Mn dose dependent exposure in a human in vitro cell culture model and provides a testable hypothesis for in vivo studies. Importantly, the transcriptome responses at toxic Mn dose demonstrated patterns observed with neurological diseases and suggest that differential functions of the secretory pathway and mitochondria could provide a basis to improve detection and management of adverse environmental and occupational Mn exposures.

Project description:Using a novel flood source construct, we performed a direct comparison of genome-wide gene expression regulations resulting from exposure of primary human prostate fibroblast cultures to acute (10cGy and 200cGy) and longer-term chronic (1.0-2.45cGy cumulative over 24hr) exposures. Samples were collected at 24 hours after an acute 10cGy or 200cGy exposure (48cGy per minute) versus immediately after an accumulated 24 hour chronic 1.0 to 2.45cGy low dose-rate exposure (7 to 17M-BM-5Gy per minute). Control 0cGy samples were collected at the same time. A total of 4 independent experimental replicates were used for each sample resulting in (2 individuals M-CM-^W 4 experimental conditions M-CM-^W 4 experimental replicates) 32 microarrays.

Project description:Exposure of adult humans to manganese (Mn) has long been known to cause neurotoxicity. Recent evidence also suggests that exposure of children to Mn is associated with developmental neurotoxicity. Astrocytes are critical for the proper functioning of the nervous system, and they play active roles in neurogenesis, synaptogenesis and synaptic neurotransmission. In this report, to help elucidate the molecular events underlying Mn neurotoxicity, we systematically identified the molecular targets of Mn in primary human astrocytes by using microarray gene expression profiling and computational data analysis algorithms. We found that Mn altered the expression of diverse genes ranging from those encoding cytokines and transporters to signal transducers and transcriptional regulators. Particularly, 28 genes encoding proinflammatory chemokines, cytokines and related functions were up-regulated whereas 15 genes encoding functions involved in DNA replication and repair and cell cycle checkpoint control were down-regulated. These results are further supported by data from real-time RT-PCR, Western blotting and flow cytometric analyses. In addition, analysis of common regulators revealed that 16 targets known to be positively affected by the IFN-gamma signaling pathway were up-regulated by Mn, suggesting that the proinflammatory IFN-gamma signaling pathway was likely activated. These results raise the possibility that inflammatory activation of astrocytes and the increased expression of proinflammatory cytokines and chemokines and/or the activation of related signaling pathways might be an important mechanism leading to Mn neurotoxicity. Keywords: treatment comparison

Project description:Here, we performed RNA-seq of hMSNs in triplicate (20-30 million reads per sample) exposed to dopamine, assessed their responses over time, and also compared their transcriptomic and functional responses to acute and chronic exposures. We also identified responses to agonists of interest. From this work, we identified ranges of experimental conditions that elicited cellular responses, identified specific genes and ontological functions induced by dopamine exposure, and observed desensitization to chronic exposures. These results provide a foundation on which to further develop hMSN models and to derive context for and comparisons between human and rodent responses.

Project description:Exposure of adult humans to manganese (Mn) has long been known to cause neurotoxicity. Recent evidence also suggests that exposure of children to Mn is associated with developmental neurotoxicity. Astrocytes are critical for the proper functioning of the nervous system, and they play active roles in neurogenesis, synaptogenesis and synaptic neurotransmission. In this report, to help elucidate the molecular events underlying Mn neurotoxicity, we systematically identified the molecular targets of Mn in primary human astrocytes by using microarray gene expression profiling and computational data analysis algorithms. We found that Mn altered the expression of diverse genes ranging from those encoding cytokines and transporters to signal transducers and transcriptional regulators. Particularly, 28 genes encoding proinflammatory chemokines, cytokines and related functions were up-regulated whereas 15 genes encoding functions involved in DNA replication and repair and cell cycle checkpoint control were down-regulated. These results are further supported by data from real-time RT-PCR, Western blotting and flow cytometric analyses. In addition, analysis of common regulators revealed that 16 targets known to be positively affected by the IFN-gamma signaling pathway were up-regulated by Mn, suggesting that the proinflammatory IFN-gamma signaling pathway was likely activated. These results raise the possibility that inflammatory activation of astrocytes and the increased expression of proinflammatory cytokines and chemokines and/or the activation of related signaling pathways might be an important mechanism leading to Mn neurotoxicity. Experiment Overall Design: Primary human astrocytes (passage 4) were treated with or without 200 uM MnCl2 for 7 days. Total RNA was extracted by using TRIzol reagent (GIBCOBRL Life Technologies). The quality of RNA was high as assessed by measuring absorbance at 260 and 280 nm, by gel electrophoresis, and by the quality of microarray data (see below). We isolated RNA from three independent batches of human astrocytes, which were from different subjects. No identifiable information from these subjects was available, in keeping with the guidelines on human subjects. Three independent batches of astrocytes from three different subjects, not the same subject, were used to ensure that our data and conclusions would not totally rely on one unidentified subject, who may have experienced influential environmental or genetic conditions. The synthesis of cDNAs and biotin-labeled cRNAs were carried out exactly as described in the Affymetrix GeneChip Expression Analysis Technical Manual (2000). The human genome U133 plus 2.0 arrays were purchased from Affymetrix, Inc. Probe hybridization and data collection were carried out by the Columbia University Affymetrix GeneChip processing center. Initial data analysis was performed by using the Affymetrix Microarray suite.

Project description:Our study makes use of zebrafish and has determined hepatic transcriptional changes after exposure to four single pharmaceuticals, a pharmaceutical mixture (MIX), and wastewater effluent (WWE) exposures. The pharmaceuticals chosen include acetaminophen, carbamazepine, gemfibrozil, and venlafaxine. We have performed chronic (6 week), low concentration (0.5 and 10 μgL-1 or 5 and 25% effluent) exposure of male and female fish and previously determined a range of effects (reproductive, histological, hormonal) after exposure to single compounds, a mixture of these compounds or wastewater effluent. Herein we determine by microarray the hepatic transcriptional responses of male and female zebrafish from the same exposures.

Project description:The ability of chromatin to switch back and forth from open euchromatin to closed heterochromatin is vital for transcriptional regulation and genomic stability, and subject to disruption by exposure to environmental agents such as hexavalent chromium. Cr(VI) exposure can cause chromosomal disruption through formation of Cr-DNA adducts, free radical-induced DNA damage, and DNA-Cr-protein and DNA-Cr-DNA cross-links, all of which may disrupt chromatin remodeling mechanisms responsible for maintenance or controlled modification of epigenetic homeostasis. In addition, dose-response analyses have shown that acute exposures to high-concentrations of Cr(VI) and chronic exposures to low-concentrations of the same agent lead to significantly different transcriptomic and genomic stability outcomes. To investigate how transcriptional responses to chromium exposure might correlate to structural changes in chromatin, we have used whole genome Formaldehyde-Assisted Isolation of Regulatory Elements (FAIRE) analysis coupled with deep sequencing to identify regions of the genome that switch from open to closed chromatin or vice versa in response to exposure to varying Cr(VI) concentrations. We find that the switch affects gene expression levels in the target areas that vary depending on Cr(VI) concentration. At either Cr(VI) concentration, chromatin domains surrounding binding sites for AP-1 transcription factors become significantly open, treatment whereas BACH2 and CTCF binding sites are open solely at the low and high concentrations, respectively. Our results suggest that FAIRE may be a useful technique to map chromatin elements targeted by DNA damaging agents for which there is no prior knowledge of their specificity, and to identify subsequent transcriptomic changes induced by those agents.

Project description:We report differential mRNA sequencing data on C57BL/6 background of both Wildtype and Alkbh8Def in saline and acetaminophen exposure conditions in acute (6 hour) and chronic (4 day) conditions.