A locust embryo as predictive developmental neurotoxicity testing system for pioneer axon pathway formation

Exposure to environmental chemicals during in utero and early postnatal development can cause a wide range of neurological defects. Since current guidelines for identifying developmental neurotoxic chemicals depend on the use of large numbers of rodents in animal experiments, it has been proposed to...

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Bibliographic Details
Published in:Archives of toxicology 2020-12, Vol.94 (12), p.4099-4113
Main Authors: Bode, Karsten, Bohn, Maja, Reitmeier, Jennifer, Betker, Philine, Stern, Michael, Bicker, Gerd
Format: Article
Language:English
Subjects:
Animal research
Axon guidance
Axons
Batteries
Biomedical and Life Sciences
Biomedicine
Cell culture
Cell recognition
Chemical agents
Chemicals
Defects
Elongation
Embryos
Environmental Health
Evolutionary conservation
Fluorescence
Fluorescence microscopy
In vitro methods and tests
Invertebrates
Navigation
Navigation behavior
Neural networks
Neuronal-glial interactions
Neurotoxicity
Occupational Medicine/Industrial Medicine
Pharmacology/Toxicology
Reproductive Toxicology
Steering
Toxicity
Wiring
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Summary:Exposure to environmental chemicals during in utero and early postnatal development can cause a wide range of neurological defects. Since current guidelines for identifying developmental neurotoxic chemicals depend on the use of large numbers of rodents in animal experiments, it has been proposed to design rapid and cost-efficient in vitro screening test batteries that are mainly based on mixed neuronal/glial cultures. However, cell culture tests do not assay correct wiring of neuronal circuits. The establishment of precise anatomical connectivity is a key event in the development of a functional brain. Here, we expose intact embryos of the locust ( Locusta migratoria ) in serum-free culture to test chemicals and visualize correct navigation of identified pioneer axons by fluorescence microscopy. We define separate toxicological endpoints for axonal elongation and navigation along a stereotyped pathway. To distinguish developmental neurotoxicity (DNT) from general toxicity, we quantify defects in axonal elongation and navigation in concentration–response curves and compare it to the biochemically determined viability of the embryo. The investigation of a panel of recognized DNT-positive and -negative test compounds supports a rather high predictability of this invertebrate embryo assay. Similar to the semaphorin-mediated guidance of neurites in mammalian cortex, correct axonal navigation of the locust pioneer axons relies on steering cues from members of this family of cell recognition molecules. Due to the evolutionary conserved mechanisms of neurite guidance, we suggest that our pioneer axon paradigm might provide mechanistically relevant information on the DNT potential of chemical agents on the processes of axon elongation, navigation, and fasciculation.
ISSN:0340-5761
1432-0738
DOI:10.1007/s00204-020-02929-6