Transcriptional Response of Zebrafish Embryos Exposed to Neurotoxic Compounds Reveals a Muscle Activity Dependent hspb11 Expression

Acetylcholinesterase (AChE) inhibitors are widely used as pesticides and drugs. Their primary effect is the overstimulation of cholinergic receptors which results in an improper muscular function. During vertebrate embryonic development nerve activity and intracellular downstream events are critical for the regulation of muscle fiber formation. Whether AChE inhibitors and related neurotoxic compounds also provoke specific changes in gene transcription patterns during vertebrate development that allow them to establish a mechanistic link useful for identification of developmental toxicity pathways has, however, yet not been investigated. Therefore we examined the transcriptomic response of a known AChE inhibitor, the organophosphate azinphos-methyl (APM), in zebrafish embryos and compared the response with two non-AChE inhibiting unspecific control compounds, 1,4-dimethoxybenzene (DMB) and 2,4-dinitrophenol (DNP). A highly specific cluster of APM induced gene transcripts was identified and a subset of strongly regulated genes was analyzed in more detail. The small heat shock protein hspb11 was found to be the most sensitive induced gene in response to AChE inhibitors. Comparison of expression in wildtype, ache and sopfixe mutant embryos revealed that hspb11 expression was dependent on the nicotinic acetylcholine receptor (nAChR) activity. Furthermore, modulators of intracellular calcium levels within the whole embryo led to a transcriptional up-regulation of hspb11 which suggests that elevated intracellular calcium levels may regulate the expression of this gene. During early zebrafish development, hspb11 was specifically expressed in muscle pioneer cells and Hspb11 morpholino-knockdown resulted in effects on slow muscle myosin organization. Our findings imply that a comparative toxicogenomic approach and functional analysis can lead to the identification of molecular mechanisms and specific marker genes for potential neurotoxic compounds.

[1]  G. Whale,et al.  An information-rich alternative, chemicals testing strategy using a high definition toxicogenomics and zebrafish (Danio rerio) embryos. , 2010, Toxicological sciences : an official journal of the Society of Toxicology.

[2]  G. Thiel,et al.  Egr-1-A Ca(2+)-regulated transcription factor. , 2010, Cell calcium.

[3]  Hans-Georg Simon,et al.  Nucleocytoplasmic functions of the PDZ‐LIM protein family: new insights into organ development , 2010, BioEssays : news and reviews in molecular, cellular and developmental biology.

[4]  L. Kay,et al.  Quaternary dynamics and plasticity underlie small heat shock protein chaperone function , 2010, Proceedings of the National Academy of Sciences.

[5]  B. Aronow,et al.  Calcium influx is sufficient to induce muscular dystrophy through a TRPC-dependent mechanism , 2009, Proceedings of the National Academy of Sciences.

[6]  William H. Benson,et al.  Integrating Omic Technologies into Aquatic Ecological Risk Assessment and Environmental Monitoring: Hurdles, Achievements, and Future Outlook , 2009, Environmental health perspectives.

[7]  Hongjian Jin,et al.  Global identification and comparative analysis of SOCS genes in fish: insights into the molecular evolution of SOCS family. , 2008, Molecular immunology.

[8]  Devon R. O'Rourke,et al.  Developmental expression patterns of the zebrafish small heat shock proteins , 2008, Developmental dynamics : an official publication of the American Association of Anatomists.

[9]  P. Layer,et al.  Acetylcholinesterase in cell adhesion, neurite growth and network formation , 2008, The FEBS journal.

[10]  L. Hutson,et al.  Genome-wide analysis and expression profiling of the small heat shock proteins in zebrafish. , 2007, Gene.

[11]  Lixin Yang,et al.  Transcriptional profiling reveals barcode-like toxicogenomic responses in the zebrafish embryo , 2007, Genome Biology.

[12]  Hiromi Hirata,et al.  Zebrafish relatively relaxed mutants have a ryanodine receptor defect, show slow swimming and provide a model of multi-minicore disease , 2007, Development.

[13]  C. Brenner,et al.  p53 Activation by Knockdown Technologies , 2007, PLoS genetics.

[14]  R. Geisler,et al.  Differential gene expression as a toxicant-sensitive endpoint in zebrafish embryos and larvae. , 2007, Aquatic toxicology.

[15]  C. Bagowski,et al.  Gene expression patterns of the ALP family during zebrafish development. , 2007, Gene expression patterns : GEP.

[16]  D. Goldman,et al.  Activity-dependent gene regulation in skeletal muscle is mediated by a histone deacetylase (HDAC)-Dach2-myogenin signal transduction cascade , 2006, Proceedings of the National Academy of Sciences.

[17]  Gerald T Ankley,et al.  Toxicogenomics in regulatory ecotoxicology. , 2006, Environmental science & technology.

[18]  R. Geisler,et al.  Mutation in the δ‐subunit of the nAChR suppresses the muscle defects caused by lack of Dystrophin , 2005, Developmental dynamics : an official publication of the American Association of Anatomists.

[19]  Rachel Ashworth,et al.  Acetylcholine and calcium signalling regulates muscle fibre formation in the zebrafish embryo , 2005, Journal of Cell Science.

[20]  E. Küster Cholin- and carboxylesterase activities in developing zebrafish embryos (Danio rerio) and their potential use for insecticide hazard assessment. , 2005, Aquatic toxicology.

[21]  Pablo Tamayo,et al.  Gene set enrichment analysis: A knowledge-based approach for interpreting genome-wide expression profiles , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[22]  Y. Sun,et al.  Small heat shock proteins: molecular structure and chaperone function , 2005, Cellular and Molecular Life Sciences CMLS.

[23]  Thomas Hartung,et al.  Meeting Report: Validation of Toxicogenomics-Based Test Systems: ECVAM–ICCVAM/NICEATM Considerations for Regulatory Use , 2005, Environmental health perspectives.

[24]  M. Granato,et al.  Acetylcholinesterase function is dispensable for sensory neurite growth but is critical for neuromuscular synapse stability. , 2004, Developmental biology.

[25]  P. Brehm,et al.  Increased neuromuscular activity causes axonal defects and muscular degeneration , 2004, Development.

[26]  U. Strähle,et al.  The use of zebrafish mutants to identify secondary target effects of acetylcholine esterase inhibitors. , 2004, Toxicological sciences : an official journal of the Society of Toxicology.

[27]  L. Babiss,et al.  Toxicogenomics in predictive toxicology in drug development. , 2004, Chemistry & biology.

[28]  M. Daly,et al.  PGC-1α-responsive genes involved in oxidative phosphorylation are coordinately downregulated in human diabetes , 2003, Nature Genetics.

[29]  A I Saeed,et al.  TM4: a free, open-source system for microarray data management and analysis. , 2003, BioTechniques.

[30]  A. Arrigo,et al.  Actin cytoskeleton and small heat shock proteins: how do they interact? , 2002, Cell stress & chaperones.

[31]  F. Narberhaus α-Crystallin-Type Heat Shock Proteins: Socializing Minichaperones in the Context of a Multichaperone Network , 2002, Microbiology and Molecular Biology Reviews.

[32]  J. Vonesch,et al.  Acetylcholinesterase is required for neuronal and muscular development in the zebrafish embryo , 2002, Nature Neuroscience.

[33]  A. Amores,et al.  Zebrafish smoothened functions in ventral neural tube specification and axon tract formation. , 2001, Development.

[34]  M. Pfaffl,et al.  A new mathematical model for relative quantification in real-time RT-PCR. , 2001, Nucleic acids research.

[35]  R. Tibshirani,et al.  Significance analysis of microarrays applied to the ionizing radiation response , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[36]  H. Soreq,et al.  Acetylcholinesterase — new roles for an old actor , 2001, Nature Reviews Neuroscience.

[37]  J. Postlethwait,et al.  Zebrafish Acetylcholinesterase Is Encoded by a Single Gene Localized on Linkage Group 7 , 2001, The Journal of Biological Chemistry.

[38]  M. Berridge,et al.  The versatility and universality of calcium signalling , 2000, Nature Reviews Molecular Cell Biology.

[39]  D. Hilton,et al.  SOCS: physiological suppressors of cytokine signaling. , 2000, Journal of cell science.

[40]  H. Brinkmeier,et al.  Calcium ion in skeletal muscle: its crucial role for muscle function, plasticity, and disease. , 2000, Physiological reviews.

[41]  H. L. Stickney,et al.  The zebrafish slow-muscle-omitted gene product is required for Hedgehog signal transduction and the development of slow muscle identity. , 2000, Development.

[42]  H. Bading,et al.  Calcium as a versatile second messenger in the control of gene expression , 1999, Microscopy research and technique.

[43]  C. Pope Organophosphorus pesticides: do they all have the same mechanism of toxicity? , 1999, Journal of toxicology and environmental health. Part B, Critical reviews.

[44]  S. Christensen,et al.  A tool coming of age: thapsigargin as an inhibitor of sarco-endoplasmic reticulum Ca(2+)-ATPases. , 1998, Trends in pharmacological sciences.

[45]  C. Russom,et al.  Predicting modes of toxic action from chemical structure: Acute toxicity in the fathead minnow (Pimephales promelas) , 1997 .

[46]  M. Westerfield,et al.  Identification of separate slow and fast muscle precursor cells in vivo, prior to somite formation. , 1996, Development.

[47]  T. R. Fukuto,et al.  Mechanism of action of organophosphorus and carbamate insecticides. , 1990, Environmental health perspectives.

[48]  Fukuto Tr Mechanism of action of organophosphorus and carbamate insecticides. , 1990 .

[49]  C. Meshul,et al.  Calcium channel blocker reverses anticholinesterase-induced myopathy , 1989, Brain Research.

[50]  M. Salpeter,et al.  Calcium-mediated myopathy at neuromuscular junctions of normal and dystrophic muscle , 1982, Experimental Neurology.

[51]  M. Salpeter,et al.  Agonist-induced myopathy at the neuromuscular junction is mediated by calcium , 1979, The Journal of cell biology.

[52]  P. Mitchell,et al.  Respiration-driven proton translocation in rat liver mitochondria. , 1967, The Biochemical journal.

[53]  B. Thisse,et al.  High-resolution in situ hybridization to whole-mount zebrafish embryos , 2007, Nature Protocols.

[54]  A. Arrigo The cellular "networking" of mammalian Hsp27 and its functions in the control of protein folding, redox state and apoptosis. , 2007, Advances in experimental medicine and biology.

[55]  M. Welsh,et al.  Shocking degeneration , 2004, Nature Genetics.

[56]  M. Westerfield The zebrafish book : a guide for the laboratory use of zebrafish (Danio rerio) , 1995 .

[57]  M. Crow,et al.  Myosin expression and specialization among the earliest muscle fibers of the developing avian limb. , 1986, Developmental biology.