Zebrafish Embryo as an Emerging Model Organism in Neurodevelopmental Toxicity Research
Year 2021,
, 179 - 187, 17.12.2021
Sukriye Caliskan
Ebru Emekli Alturfan
Abstract
Zebrafish is a model organism that has become increasingly popular in recent years due to some of the advantages it has when compared to traditional model organisms. Its genetic similarity with humans has contributed significantly to the elucidation of the molecular mechanisms underlying diseases. Moreover, external fertilization and rapid embryonic development of zebrafish embryos have made it attractive in many research areas. The genome of humans and zebrafish are found to be highly conserved having 76-82 % of the disease genes in humans that are also present in zebrafish. Zebrafish have been used in different studies in several concepts of neurogenesis. Unlike mammals, the external development of a zebrafish embryo makes it accessible for experimental manipulation in central nervous system research. It was observed that neurotoxic agents induced similar responses to other vertebral models in zebrafish embryos, whose brain development and blood-brain barrier were similar to those of other vertebrates. This review provides brief information about the availability of zebrafish embryos in neurodevelopmental toxicity research while giving brief information on embryogenesis and neurogenesis in zebrafish. Evaluation of neurotoxicity and the specific effects of various neurotoxins on motor and dopaminergic neurons, neuronal proliferation, mobility, and neurodevelopment are also explained.
Supporting Institution
Marmara University Scientific Research Projects Commission
Project Number
Grant number: TYL-2021-10205
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Year 2021,
, 179 - 187, 17.12.2021
Sukriye Caliskan
Ebru Emekli Alturfan
Project Number
Grant number: TYL-2021-10205
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scholar
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29: 6142-53. google scholar
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scholar
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166: 509-30. google scholar
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2009; 106: 19895-900. google scholar
- 37. Tallafuss A, Adolf B, Bally-Cuif L. Selective control of neuronal clus-ter size at the forebrain/midbrain boundary by signaling from the prechordal plate. Dev Dyn 2003; 227:
524-35. google scholar
- 38. Geling A, Itoh M, Tallafuss A, Chapouton P, Tannhauser B, Kuwa-da JY, Chitnis AB, Bally-Cuif L. bHLH transcription factor Her5 links patterning to regional inhibition of
neurogenesis at the mid-brain-hindbrain boundary. Development 2003; 130: 1591-604. google scholar
- 39. Ninkovic J, Tallafuss A, Leucht C, Topczewski J, Tannhauser B, Solni-ca-Krezel L, Bally-Cuif L. Inhibition of neurogenesis at the zebrafish midbrain-hindbrain boundary by the
combined and dose-depen-dent activity of a new hairy/E(spl) gene pair. Development 2005; 132(1): 75-88. google scholar
- 40. Lyons DA, Guy AT, Clarke JDW. Monitoring neural progenitor fate through multiple rounds of division in an intact vertebrate brain. Development 2003; 130: 3427-36. google
scholar
- 41. Wysowski DK, Swartz L. Adverse drug event surveillance and drug withdrawals in the United States, 1969-2002: the importance of re-porting suspected reactions. Arch Intern
Med 2005; 165(12): 13639. google scholar
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1996; 104(Suppl 2): 193204. google scholar
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methylmercury. Neuro-toxicology 1989; 10(1): 41-52. google scholar
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