Project description:Metal toxicity is a global environmental challenge. Fish are particularly prone to metal exposure, which can be lethal or can cause sublethal physiological impairments. The objective of this study was to improve our understanding on how adverse effects of essential and non-essential metals in early life stage zebrafish may be explained by changes in the transcriptome after exposure to non-toxic levels. We therefore studied the effects of three different metals at low concentrations in zebrafish embryos by transcriptomics analysis. The study design compared exposure effects caused by different metals at different developmental stages (pre-hatch and post-hatch). Wild-type embryos were exposed to solutions of low concentrations of copper (CuSO4), cadmium (CdCl2) and cobalt (CoSO4) until 96 h post-fertilization (hpf) and microarray experiments were carried out to determine transcriptome profiles at 48 and 96 hpf. We found that the toxic metal cadmium affected the expression of more genes at 96 hpf than 48 hpf. The opposite effect was observed for the essential metals cobalt and copper, which also showed enrichment of different GO terms. Genes involved in neuromast and motor neuron development, were significantly enriched, agreeing with our previous results showing motor neuron and neuromast damage in the embryos. Our data provide evidence that the response of the transcriptome of fish embryos to metal exposure differs for essential and non-essential metals.

Project description:Concentration dependent transcriptome responses of zebrafish embryos after exposure to cadmium, cobalt and copper.

Project description:7 transition metals (silver, arsenic, cadmium, chromium, copper, mercury and zinc) were treated (2hr) on diploid yeast BY4743. Keywords: Response to metals

Project description:A convergence of technological breakthroughs in the past decade has facilitated the development of rapid screening tools for biomarkers of toxicant exposure and effect. Platforms using the whole adult organism to evaluate the genome-wide response to toxicants are especially attractive. Recent work demonstrates the feasibility of this approach in vertebrates using the experimentally robust zebrafish model. In the present study, we evaluated gene expression changes in whole adult zebrafish following an acute 24 hour exposure to three metals with known human health risks. Male adult zebrafish were exposed to nickel chloride, cobalt chloride, and sodium dichromate concentrations corresponding to their respective 96 hr LC20, LC40 and LC60. Histopathology was performed on a subset of metal-exposed zebrafish to phenotypically anchor transcriptional changes associated with each metal. Comparative analysis identified subsets of differentially expressed transcripts both overlapping and unique to each metal. Application of gene ontology (GO) and transcription factor enrichment algorithms revealed a number of key biological processes perturbed by metal exposures and the master transcriptional regulators mediating gene expression changes. Metal exposures differentially activated biological processes associated with ribosome biogenesis, proteosomal degradation and p53 signaling cascades, while repressing oxygen-generating pathways associated with amino acid and lipid metabolism. Despite appreciable effects on gene regulation, nickel exposures did not induce any morphological alterations in zebrafish organs and tissues. Histopathological effects of cobalt remained confined to the olfactory system, while chromium targeted the gills, pharynx and intestinal mucosa. A number of enriched transcription factors mediate the observed gene response to metal exposure, including known targets such as p53, HIF1M-oM-^AM-! and the myc oncogene and novel regulatory factors such as XBP1, GATA6 and HNF3M-oM-^AM-". This work uses an experimentally innovative approach to capture global responses to metal exposures and provides mechanistic insights into metal toxicity mechanisms. Metal induced changes in gene expression in zebrafish were measured after 24 h exposures to each of three metals (nickel, chromium or cobalt). A total of 48 arrays were processed - 16 arrays per metal with 4 replicates for each exposure condition (control, low, mid, and high).

Project description:In triplicate for each condition, 12 WT and acbd6 F0 crispant Danio rerio (zebrafish) embryos were incubated with 20 μM YnMyr for 24 h, either between 48-72 hpf or 96-120 hpf. After labelling, zebrafish were washed twice with fresh egg water, deyolked, flash frozen in liquid nitrogen and stored at -80°C until further analysis.

Project description:In triplicate for each condition, 12 WT and acbd6 F0 crispant Danio rerio (zebrafish) embryos were incubated with 20 μM YnMyr for 24 h, either between 48-72 hpf or 96-120 hpf. After labelling, zebrafish were washed twice with fresh egg water, deyolked, flash frozen in liquid nitrogen and stored at -80°C until further analysis.

Project description:Exposure experiments with the non-aromatizable fish androgen, 11-ketotestosterone in the range of 0.05-5000 nM were conducted in order to identify potential androgen-responsive genes in zebrafish embryos by microarray analysis. Zebrafish embryos were treated from 96 hpf to 120 hpf in a single experiment with three controls (embryonic medium). Microarray studies were performed using a Custom 8x60k Gene Expression Microarrays (Amadid G4102A, based on the ensembl zebrafish genome version 3) from total RNA with low input labelling and hybridization kit (Agilent Technologies) and one-color design according to the manufacturer instructions. Fluorescent intensities of individual microarray spots were extracted using the Agilent Feature Extraction software. Raw microarray data were converted to log2 values and quantile-normalized. For further statistical analysis, fold changes in relation to the mean of the controls were calculated for each treatment. Zebrafish embryos were treated from 96 hpf to 120 hpf in a single experiment with three controls and 11 concentrations of 11-ketotestosterone ranging from 0.05-5000 nM.

Project description:Metals, including copper (Cu) and nickel (Ni) are among the most common contaminants in soils in Europe. Although their effects are relatively well known regarding survival and reproduction of soil invertebrates, their modes of action in these organisms are still poorly studied. Enchytraeus albidus has been used in soil ecotoxicology for many years, and more recently has a gene library and an oligonucleotide microarray for this species which allowed gene expression studies. This has potentiated the means to study further in depth the mechanisms of response to stressors. The main aim of this study is to understand the mechanisms of response of E. albidus to Cu and Ni. For that we have 1) assessed and compared the transcriptomic profile of E. albidus in response to Cu and Ni and 2) compared the Cu, Ni, Cd and Zn transcriptomic profiles. For the microarray hybridizations, E. albidus were exposed to the reproduction effect concentrations EC50 and EC90 of Cu and Ni during 4 days. Results indicate that Cu and Ni have to some extent, similar mechanisms of toxicity and that have already been identified in other species, indicating cross-species conserved mechanisms. Based on hierarchical clustering, it was possible to observe a clear separation of Cd treatments from all other metals. This separation strongly correlates with the available information regarding the toxicokinetics of the tested metals, in which Ni shows properties similar to essential metals. Gene expression in E.albidus was measured 4 days after exposure to Copper, Nickel, Cadmium and Zinc at 2 concentrations of effect on reprocduction (EC50 and EC90). Three biological replicates per exposure condition and 6 biological replicates of control conditions were used.

Project description:Analysis of genome-wide gene expression patterns in response to copper in WT and COPR mutant in the cyanobacterium Synechocystis sp PCC 6803. Here we have used microarrays to interrogate the global responses to copper additions at non-toxic (0.3 micromolar) and toxic concentrations (3 micromolar) of copper in WT and in a mutant in the copR gene. Addition of the non-toxic copper concentration stimulated the metabolism and induced the switch in the use from cyitochrome c6 to plastocyanin. In contrast, high copper addition induced a stress response and affected the metabolism of several other metals. This included repression of ribosomal, photosynthetic and metabolic genes and induction of chaperones and antioxidant enzymes genes. Finally CopRS seems to control only the expression of the copMRS and copBAC operons as all other genes that were differentially expressed by copper seemed to be unaffected in copR strains.

Project description:The stress response of the soil bacterium Sinorhizobium meliloti towards elevated concentrations of the heavy metals cadmium and zinc was analyzed via transcriptional profiling.