Project description:Methylmercury (MeHg) toxicity in humans manifests deficits in neurological function. Cases of prenatal exposure to mercury have established that the developing nervous system is most highly susceptible to perturbation by MeHg. At a cellular level, MeHg-induced defects result from altered neuronal proliferation, migration and pathfinding. However, the molecular targets of MeHg that give rise to these outcomes are not fully understood. In an overall effort to identify the fundamental molecular targets of MeHg in neural development, we are investigating the effects of MeHg on gene expression and protein function in the Drosophila model. Since the fundamental signaling pathways in development of multicellular animals have been extensively characterized in Drosophila, and demonstrate high degree of conservation in vertebrates, we believe these data will lead us to the most pertinent pathways affected by MeHg and begin to elucidate the mechanism of MeHg neural toxicity relevant to cases of human exposure to this prevalent environmental toxin. Our aim is to identify fundamental signaling pathways in neural development that are targets for MeHg poisoning. Our hypothesis is that MeHg, by direct interaction with cysteine thiol groups, alters the function signaling pathway proteins and subsequently alters transcription of target genes in the respective pathways. Our hypothesis is supported by our recent data demonstrating a direct action of MeHg in activating the Notch receptor pathway and upregulating target gene expression. We anticipate a microarray analysis will elucidate additional fundamental signaling pathways where transcription is affected by this toxin. Fertilized female flies are fed on food containing methylmercury (1-20 micromolar) or solvent control (DMSO) for a period of five days to allow for MeHg penetration in to eggs. Flies are then transfered to a cage for embryo collection for a discrete window of time (e.g. 1hr). Embryos are aged 16-24 hours and collected for total RNA extraction using the Trizol reagent. Total RNA is quantitated by spectrophotometry with a Nanodrop reader. While concentration dependent effects of MeHg are of interest, initial experiments will be conducted on samples exposed to a single concetration known to illicit effect in other bioassays (e.g. 10 micromolar). The goal is to see which genes are up- or down-regulated with MeHg exposure, as compared to control embryos that are not exposed. Emphasis in the analysis stage will be in identifying target genes of known signaling pathways. Keywords: dose response

Project description:Methylmercury is a bioaccumulated environmental neurotoxicant, however, it remains largely unknown regarding impacts of non-apoptotic low dose methylmercury on embryonic cerebral cortex development. Here, using single cell RNA-seq analysis we show that prenatal exposure of MeHg favors RGP developmental trajectory towards directly producing cortical neurons, omitting intermediate progenitor stage. Our findings reveal the outcomes of low dose MeHg exposure on the fetal brain development and provide insights into its underlying mechanisms and potential therapeutic strategy.

Project description:Methylmercury (MeHg) is a highly toxic environmental pollutant. To understand the mechanisms of toxicity of the compound and possibly to discover new biomarkers for environmental monitoring, we have conducted toxicogenomics studies. We designed 126k-cod-oligonucleotide arrays and performed genome-wide gene expression assays in liver samples from juvenile cod treated with MeHg (0.5 and 2 mg/kg body weight). Microarray analysis showed MeHg differentially regulated hundreds of genes. Gene Ontology and pathway analyses of differentially regulated genes revealed that MeHg modulated mainly genes involved in immune response, oxidative stress response, tissue remodelling, and energy pathways such as lipid, carbohydrate and amino acid metabolism. The results provide insights into the mechanisms of toxicity of MeHg and provide candidate biomarkers of exposure to MeHg for further evaluation. Analyzed 5 samples from each of 3 groups: control, 0.5 mg/BW MeHg treated, and 2 mg/BW MeHg treated. Liver total RNA was reverse transcribed, Cy3-labeled, and hybridized (one-color hybridzation).

Project description:Methylmercury (MeHg) is an environmental pollutant of global public health concern. MeHg is associated with immune dysfunction but the underlying mechanisms are unclear. The most common route of MeHg exposure is through consumption of fatty fish that contain beneficial n-3 polyunsaturated fatty acids (PUFA) that may protect against MeHg toxicity. To better inform individual costs and benefits of fish consumption, we aimed to identify candidate epigenetic biomarkers of biological responses that reflect MeHg toxicity and PUFA protection.

Project description:Methylmercury (MeHg) is a highly toxic environmental pollutant. To understand the mechanisms of toxicity of the compound and possibly to discover new biomarkers for environmental monitoring, we have conducted toxicogenomics studies. We designed 126k-cod-oligonucleotide arrays and performed genome-wide gene expression assays in liver samples from juvenile cod treated with MeHg (0.5 and 2 mg/kg body weight). Microarray analysis showed MeHg differentially regulated hundreds of genes. Gene Ontology and pathway analyses of differentially regulated genes revealed that MeHg modulated mainly genes involved in immune response, oxidative stress response, tissue remodelling, and energy pathways such as lipid, carbohydrate and amino acid metabolism. The results provide insights into the mechanisms of toxicity of MeHg and provide candidate biomarkers of exposure to MeHg for further evaluation.

Project description:The developing human brain is uniquely vulnerable to methylmercury (MeHg) intoxication. Given the limited experimental access to MeHg-intoxicated human fetal brain, neither the threshold levels for neurotoxic effects nor the mechanisms underlying neurodevelopmental MeHg toxicity are clear. The observed persistent and latent effects in human and animal exposures and the relatively nonspecific neurodevelopmental changes suggest that MeHg impacts fundamental neurodevelopmental processes. Human cortical development is characterized by the sequential emergence of different neural stem cells, precursors, intermediate progenitors and postmitotic neurons, a sequence that can be replicated in human-induced pluripotent stem cell (hiPSC)-derived differentiating neuronal cultures. As the developing human cortex has been shown to be particularly vulnerable to fetal MeHg exposure, we assessed here by means of single cell RNA sequencing (scRNAseq) MeHg’s effects on different stages of differentiation and cell types present in early cortical cultures differentiated from hiPSC cells. Cortical cultures differentiating from hiPSC were exposed to toxicologically relevant MeHg (0.1 and 1.0 µM) continuously for 6 days at two different time points (days 4-10; and/or days 14-20) of early cortical differentiation under conditions below the cytotoxic threshold. Previous analysis at days 21-23 revealed subtle changes in cortical differentiation markers and cellular energetics, but no effect on glutathione levels, a biomarker of acute MeHg toxicity. Therefore, here we assessed the possibility of persistent effects on neurodevelopment at day 38 of differentiation (18 or 28 days after cessation of MeHg exposure). At this time, we observed subtle but significant changes in the population size of different cell types and the fractions of cells present in the different phases of the cell cycle. The observed MeHg-induced changes were developmental-stage and MeHg paradigm-specific. We further assessed overall differential gene expression, quantifying the number of genes showing significantly up- or down-regulated expression and identifying the genes affected at least partially identified biological processes affected. Importantly, the MeHg-induced changes in gene expression were also developmental-stage and MeHg-exposure paradigm specific. Thus, our studies demonstrate for the first time in a human model that MeHg exposure induces persistent changes in gene expression well after cessation of exposure, these changes are cell type- and developmental stage-specific, and this outcome is highly dependent on the concentration and timing of MeHg exposure. We conclude hiPSC-derived developing neuronal cultures provide an excellent human model to study persistent neurodevelopmental toxicity of MeHg in the developing human cortex.

Project description:Methylmercury (MeHg) is an environmental neurotoxicant known to cause adverse effects in fish, such as locomotor abnormalities, visual deficits or teratogenesis. However, very few studies have investigated the effects of environmentally realistic MeHg exposures on the gene expression of fish embryos. Since the primary source of MeHg exposure in wild fish is through the diet, this study analyzed differential gene expression in zebrafish embryos from parents that had been subjected to environmentally relevant dietary MeHg exposures (0, 1, 3, and 10ppm) throughout their whole life cycle.

Project description:Methylmercury (MeHg) is a ubiquitous environmental neurotoxicant, with human exposures predominantly resulting from fish consumption. Developmental exposure of zebrafish to MeHg is known to alter their neurobehavior. The current study investigated the direct exposure and transgenerational effects of MeHg, at tissue doses similar to those detected in exposed human populations, on sperm epimutations (i.e., differential DNA methylation regions [DMRs]) and neurobehavior (i.e., visual startle and spontaneous locomotion) in zebrafish, an established human health model. F1 generation embryos were exposed to MeHg (0, 1, 3, 10, 30, and 100 nM) for 24 hours ex vivo. F1 generation control and MeHg-exposed lineages were reared to adults and bred to yield the F2 generation, which was subsequently bred to the F3 generation. Direct exposure (F1 generation) and transgenerational actions (F3 generation) were then evaluated. Hyperactivity and visual deficit were observed in the unexposed descendants (F3 generation) of the MeHg-exposed lineage compared to control. An increase in F3 generation sperm epimutations was observed relative to the F1 generation. Investigation of the DMRs in the F3 generation MeHg-exposed lineage sperm revealed associated genes in the neuroactive ligand-receptor interaction and actin-cytoskeleton pathways being effected, which correlate to the observed neurobehavioral phenotypes. Developmental MeHg-induced epigenetic transgenerational inheritance of abnormal neurobehavior is correlated with sperm epimutations in F3 generation adult zebrafish. Therefore, mercury has the ability to promote the epigenetic transgenerational inheritance of disease in zebrafish, which significantly impacts its environmental health considerations in all species including humans.

Project description:Methylmercury (MeHg) is a potent neurotoxin and endocrine disruptor that accumulates in aquatic systems. Previous studies have shown suppression of hormone levels in both male and female fish, suggesting effects on gonadotropin regulation in the brain. We investigated the gene expression profile in adult female zebrafish whole brain induced by acute (96 hr) MeHg exposure. Fish were exposed by injection to 0 or 0.5 µg MeHg/g. Gene expression changes in the brain were examined using a two-color 22,000 feature zebrafish microarray. At a significance level of p<0.01, 79 genes were up-regulated and 76 genes were down-regulated in response to MeHg exposure. Individual genes exhibiting altered expression in response to MeHg exposure implicate effects on glutathione metabolism and GABA-A receptors in the mechanism of MeHg neurotoxicity. Gene ontology (GO) terms significantly enriched among altered genes included protein folding, cell redox homeostasis, and steroid biosynthetic process. The most affected biological functions were related to the nervous system development and function, as well as lipid metabolism and molecular transport. These results support the involvement of oxidative stress and effects on protein structure in the mechanism of action of MeHg in the female brain. Future studies will compare the gene expression profile induced in response to MeHg with that induced by other toxins and investigate responsive genes as potential biomarkers of MeHg exposure.

Project description:Methylmercury (MeHg) is a teratogen with adverse effects on embryogenesis from fish to man. The adverse developmental outcomes of MeHg are well understood, but molecular understanding of teratogenic effects is rather limited. We performed here a genome - wide transcriptional analyses of 6, 30 and 50 μg/L MeHg treated zebrafish embryos from 4 to 72 h post-fertilization (hpf) using RNA-sequencing and self-printed microarray, and conducted a systematical comparison of MeHg - induced transcriptomic responses observed in this and our previous studies. We found that genes linked to gene ontology in terms of oxidative stress, visual, photoreception and cilium, and GABAergic synapse were enriched in embryo exposed from 4 to 72 hpf. The significantly altered genes involved in MAP kinase, TGF beta signaling pathway, oxidative phosphorylation, and glutathione metabolism were enriched across different exposure scenarios. We obtain 22 genes significantly regulated by MeHg, particularly the significant changes were determined in embryos exposed to 6 μg/L MeHg, which did not cause obviously teratogenic effects. Our findings show that the genes whose expression is altered by MeHg in embryonic stages may play important roles in adverse developmental endpoints and might be served as signatures for teratogenic effects.