Publikation: Toxicity, recovery, and resilience in a 3D dopaminergic neuronal in vitro model exposed to rotenone
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To date, most in vitro toxicity testing has focused on acute effects of compounds at high concentrations. This testing strategy does not reflect real-life exposures, which might contribute to long-term disease outcome. We used a 3D-human dopaminergic in vitro LUHMES cell line model to determine whether effects of short-term rotenone exposure (100 nM, 24 h) are permanent or reversible. A decrease in complex I activity, ATP, mitochondrial diameter, and neurite outgrowth were observed acutely. After compound removal, complex I activity was still inhibited; however, ATP levels were increased, cells were electrically active and aggregates restored neurite outgrowth integrity and mitochondrial morphology. We identified significant transcriptomic changes after 24 h which were not present 7 days after wash-out. Our results suggest that testing short-term exposures in vitro may capture many acute effects which cells can overcome, missing adaptive processes, and long-term mechanisms. In addition, to study cellular resilience, cells were re-exposed to rotenone after wash-out and recovery period. Pre-exposed cells maintained higher metabolic activity than controls and presented a different expression pattern in genes previously shown to be altered by rotenone. NEF2L2, ATF4, and EAAC1 were downregulated upon single hit on day 14, but unchanged in pre-exposed aggregates. DAT and CASP3 were only altered after re-exposure to rotenone, while TYMS and MLF1IP were downregulated in both single-exposed and pre-exposed aggregates. In summary, our study shows that a human cell-based 3D model can be used to assess cellular adaptation, resilience, and long-term mechanisms relevant to neurodegenerative research.
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HARRIS, Georgina, Melanie ESCHMENT, Sebastian Perez OROZCO, J Michael MCCAFFERY, Richard MACLENNAN, Daniel SEVERIN, Marcel LEIST, Andre KLEENSANG, Thomas HARTUNG, Lena SMIRNOVA, 2018. Toxicity, recovery, and resilience in a 3D dopaminergic neuronal in vitro model exposed to rotenone. In: Archives of toxicology. 2018, 92(8), pp. 2587-2606. ISSN 0340-5761. eISSN 1432-0738. Available under: doi: 10.1007/s00204-018-2250-8BibTex
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year={2018},
doi={10.1007/s00204-018-2250-8},
title={Toxicity, recovery, and resilience in a 3D dopaminergic neuronal in vitro model exposed to rotenone},
number={8},
volume={92},
issn={0340-5761},
journal={Archives of toxicology},
pages={2587--2606},
author={Harris, Georgina and Eschment, Melanie and Orozco, Sebastian Perez and McCaffery, J Michael and Maclennan, Richard and Severin, Daniel and Leist, Marcel and Kleensang, Andre and Hartung, Thomas and Smirnova, Lena}
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<dcterms:abstract xml:lang="eng">To date, most in vitro toxicity testing has focused on acute effects of compounds at high concentrations. This testing strategy does not reflect real-life exposures, which might contribute to long-term disease outcome. We used a 3D-human dopaminergic in vitro LUHMES cell line model to determine whether effects of short-term rotenone exposure (100 nM, 24 h) are permanent or reversible. A decrease in complex I activity, ATP, mitochondrial diameter, and neurite outgrowth were observed acutely. After compound removal, complex I activity was still inhibited; however, ATP levels were increased, cells were electrically active and aggregates restored neurite outgrowth integrity and mitochondrial morphology. We identified significant transcriptomic changes after 24 h which were not present 7 days after wash-out. Our results suggest that testing short-term exposures in vitro may capture many acute effects which cells can overcome, missing adaptive processes, and long-term mechanisms. In addition, to study cellular resilience, cells were re-exposed to rotenone after wash-out and recovery period. Pre-exposed cells maintained higher metabolic activity than controls and presented a different expression pattern in genes previously shown to be altered by rotenone. NEF2L2, ATF4, and EAAC1 were downregulated upon single hit on day 14, but unchanged in pre-exposed aggregates. DAT and CASP3 were only altered after re-exposure to rotenone, while TYMS and MLF1IP were downregulated in both single-exposed and pre-exposed aggregates. In summary, our study shows that a human cell-based 3D model can be used to assess cellular adaptation, resilience, and long-term mechanisms relevant to neurodegenerative research.</dcterms:abstract>
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