Project description:Background: Acrylamide (ACR) is a broadly spread neurotoxic chemical of public health concern, as occupational or environmental exposure of humans to ACR may lead to a synaptopathy characterized by ataxia, skeletal muscles weakness and numbness of the extremities. Currently, only the mildly affected patients undergo complete recovery, and identification of new molecules with therapeutic bioactivity against ACR acute neurotoxicity is urgently needed. Objectives: We aimed to develop a zebrafish model for human ACR neurotoxicity. Methods: Adverse effects have been assessed at different levels, including analysis of the motor function (basal locomotor activity, visual motor response, kinematic of the touch-evoked escape response), histopathological evaluation (toluidine blue and whole-mount immunofluorescence), analysis of neural transcriptional markers (qPCR), proteomic analysis (μLC-MS-MS) and neurotransmitters profile (LC-MS/MS). Results: Our results show that zebrafish mimics most of the pathophysiological processes described in humans and mammalian models. Motor function was altered, including the response to sudden changes in light intensity. Specific effects were found on the presynaptic nerve terminals at the neuromuscular junction level, but not on the axonal tracts or myelin sheath integrity. Transcriptional markers of proteins involved in synaptic vesicle cycle were selectively altered, and the proteomic analysis showed that ACR-adducts were formed on cysteine residues of some synaptic proteins. Finally, analysis of neurotransmitters profile showed a significant effect found on cholinergic and dopaminergic systems. Conclusions: Thus, the zebrafish model for ACR acute neurotoxicity is suitable to be used larvae for in vivo high-throughput screening of small molecule libraries for identifying new drugs against this synaptopathy.

Project description:In this study, we used the adult zebrafish model of ACR acute neurotoxicity for determining the suitability of NAC to protect the brain against ACR toxicity. First, the potential protective effects of NAC on the ACR neurotoxicity were evaluated at the behavioral and molecular (transcriptome and proteome) levels. Then, in order to understand the mild to negligible protective effect of NAC, the ability of this drug to cross BBB by passive diffusion was evaluated by different approaches. Whereas the BBB parallel artificial membrane permeability assay (BBB-PAMPA) was used to determine the ability of NAC to cross BBB-like phospholipid membranes by passive diffusion, the determination of the NAC content in the brain provides direct evidences of the BBB permeability in vivo. Finally, we evaluated the ability of drug to recover the depleted GSx stores and to scavenge ACR in the brain of ACR-exposed fish.

Project description:Limited studies on multi-omics have been conducted to comprehensively investigate the molecular mechanism underlying the developmental neurotoxicity of perfluorooctanesulfonic acid (PFOS). In this study, the locomotor behavior of zebrafish larvae was assessed under the exposure to 0.1–20 μM PFOS based on its reported neurobehavioral effect. After the number of zebrafish larvae was optimized for proteomics and metabolomics studies, three kinds of omics (i.e., transcriptomics, proteomics, and metabolomics) were carried out with zebrafish larvae exposed to 0.1, 1, 5, and 10 μM PFOS. More importantly, a data-driven integration of multi-omics was performed to elucidate the toxicity mechanism involved in developmental neurotoxicity. In a concentration-dependent manner, exposure to PFOS provoked hyperactivity and hypoactivity under light and dark conditions, respectively. Individual omics revealed that PFOS exposure caused perturbations in the pathways of neurological function, oxidative stress, and energy metabolism. Integrated omics implied that there were decisive pathways for axonal deformation, neuroinflammatory stimulation, and dysregulation of calcium ion signaling, which are more clearly specified for neurotoxicity. Overall, our findings broaden the molecular understanding of the developmental neurotoxicity of PFOS, for which multi-omics and integrated omics analyses are efficient for discovering the significant molecular pathways related to developmental neurotoxicity in zebrafish.

Project description:To invistigate the role of IL-1B in acrylamide toxicity in mice, we establish the IL-1B knockdown mice to invistagate if it have a protective effect against acrylamide neurotoxicity

Project description:Persistent organic pollutants (POPs) are widespread in the environment and bioaccumulate in organisms. Previously we observed hyperactivity of zebrafish larvae exposed to a mixture of POPs based on average blood levels from the Scandinavian population and identified perfluorooctanesulfonic acid (PFOS) as the driving agent for the behavioral changes. We exposed zebrafish larvae from 6 to 96 h post fertilization to the same mixture of POPs in two concentrations or a single PFOS exposure (0.3 and 2.06mg/L) and performed behavioral tests and transcriptomics analysis. Results confirmed previous observations that exposure to POPs and PFOS causes hyperactivity and higher anxiety levels. Transcriptomic analysis showed upregulation of transcripts related to muscle contraction. Muscle contraction is highly regulated by the availability of calcium in the sarcoplasmic reticulum. Ingenuity pathway analysis showed that one of the affected pathways in larvae exposed to the POPs mixture and PFOS was calcium signalling via the activation of the ryanodine receptors. We also found effect on lipid metabolism in those larvae exposed to the lower concentration of PFOS. By using omics technology, we observed that the altered behavioral pattern in exposed zebrafish larvae might be controlled directly by mechanisms affecting muscle function rather than from mechanisms connected to neurotoxicity.

Project description:Purpose: S. pneumoniae infection in both zebrafish larvae and adult fish can be used to model pneumococcal bacteremia. Here, we used unchallenged, PBS injected and S. pneumoniae (T4) infected adult zebrafish to study the genome-wide role of pcsk9 in vivo in steady-state and upon immune system stimulation. Methods: Adult pcsk9 KO zebrafish and their WT siblings were infected with S. pneumoniae (3,370,000 CFU; SD 840,000 CFU) and their total liver RNA isolated at 1-day post infection. RNA-sequencing data was produced by NovaSeq. Data processing pipeline was built on Snakemake wrappers, and used STAR to quantify features from quality and adapter trimmed reads in gene level. Prior to the normalisation and differential gene expression analysis with DESeq2, the matrix of raw gene counts was prefiltered to keep only rows that have at least 10 reads total and then split by treatment to analyze each case separately. Result tables were annotated with biomaRt. Results: Snakemake preprocessing pipeline measured 32,520 genes against GRCz11, ENSEMBL release 97. 20,709 of them was used for statistical testing. Full result tables for each treatment were ranked by p-value and the normalized DESeq2 abundances in samples were included. The genes with BH-adjusted p-value <0.05 was considered differentially expressed. Conclusions: Our study identified up- and down-regulated genes in unchallenged, PBS injected and pneumococcal infected pcsk9 KO zebrafish liver compared to WT zebrafish.

Project description:To investigate the transcriptional changes following acute liver injury, we exposed WT and Nrf2KO zebrafish larvae to APAP for 12 and 24 hours. We then dissected out zebrafish larval livers and pooled 20 livers per sample for RNA-seq.

Project description:Acrylamide is a type-2 alkene monomer with established human neurotoxic effects. While the primary source of human exposure to acrylamide is occupational, other exposure sources include food, drinking water, and smoking. In this study, neurobehavioral assays coupled with transcriptional profiling analysis were conducted to assess both behavioral and gene expression effects induced by acrylamide neurotoxicity in rats when administered during early postnatal life. Acrylamide administration in rat pups induced significant characteristic neurotoxic symptoms including increased heel splay, decrease in grip strength, and decrease in locomotor activity. Transcriptome analysis with the Affymetrix Rat Genome 230 2.0 array indicated that acrylamide treatment caused a significant alteration in the expression of genes involved in muscle contraction, pain regulation, and dopaminergic neuronal pathways. First, in agreement with the observed behavioral effects, expression of the Mylpf gene involved in muscle contraction was downregulated in the spinal cord in response to acrylamide. Second, in sciatic nerves, acrylamide repressed the expression of the opioid receptor gene Oprk1 that is known to play a role in neuropathic pain regulation. Finally, in the cerebellum, acrylamide treatment caused a decrease in the expression of the nuclear receptor gene Nr4a2 that is required for development of dopaminergic neurons. Thus, our work examining the effect of acrylamide at the whole-genome level on a developmental mammalian model has identified novel genes previously not implicated in acrylamide neurotoxicity that can be further developed into biomarkers for assessing the risk of acrylamide exposure. Three-week-old male Wistar rat pups were treated with either acrylamide or saline daily (30 mg/kg) for 21 days, then tissues (cerebellum, spinal cord, and sciatic nerve) were harvested and frozen. Two biological replicate samples, each sample consisting of pooled tissue from 2 rats, were analyzed for each treatment.

Project description:We sequenced mRNA from embryonic heart of zebrafish larvae 4 days post fertilization, adult heart of 6-month-old WIK fish, and adult muscle of adult fish consisting of both fast-twitch and slow-twitch fibers.

Project description:Individuals in a population respond differently to stressful situations. While resilient individuals recover efficiently, others are susceptible to the same stressors. Most existing information regarding the factors regulating stress resilience in vertebrates is from specific areas of the brain from adult rodents or humans. In order to study resilience during development, we established a new paradigm to identify resilience in zebrafish larvae. Using this assay, we identified resilient and susceptible subsets of zebrafish larvae at 6 days post fertilization and performed gene expression analysis on whole larvae.