Publikation: Small-molecule dissolution of stress granules by redox modulation benefits ALS models
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2025
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Uechi, Hiroyuki
Sridharan, Sindhuja
Nijssen, Jik
Bilstein, Jessica
Iglesias-Artola, Juan M.
Kishigami, Satoshi
Hyman, Anthony A.
Wheeler, Richard J.
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Nature Chemical Biology. Springer. ISSN 1552-4450. eISSN 1552-4469. Verfügbar unter: doi: 10.1038/s41589-025-01893-5
Zusammenfassung
Neurodegenerative diseases, such as amyotrophic lateral sclerosis, are often associated with mutations in stress granule proteins. Aberrant stress granule condensate formation is associated with disease, making it a potential target for pharmacological intervention. Here, we identified lipoamide, a small molecule that specifically prevents cytoplasmic condensation of stress granule proteins. Thermal proteome profiling showed that lipoamide stabilizes intrinsically disordered domain-containing proteins, including SRSF1 and SFPQ, which are stress granule proteins necessary for lipoamide activity. SFPQ has redox-state-specific condensate dissolving behavior, which is modulated by the redox-active lipoamide dithiolane ring. In animals, lipoamide ameliorates aging-associated aggregation of a stress granule reporter protein, improves neuronal morphology and recovers motor defects caused by amyotrophic lateral sclerosis-associated FUS and TDP-43 mutants. Thus, lipoamide is a well-tolerated small-molecule modulator of stress granule condensation, and dissection of its molecular mechanism identified a cellular pathway for redox regulation of stress granule formation.
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UECHI, Hiroyuki, Sindhuja SRIDHARAN, Jik NIJSSEN, Jessica BILSTEIN, Juan M. IGLESIAS-ARTOLA, Satoshi KISHIGAMI, Julius FÜRSCH, Florian STENGEL, Anthony A. HYMAN, Richard J. WHEELER, 2025. Small-molecule dissolution of stress granules by redox modulation benefits ALS models. In: Nature Chemical Biology. Springer. ISSN 1552-4450. eISSN 1552-4469. Verfügbar unter: doi: 10.1038/s41589-025-01893-5BibTex
@article{Uechi2025-05-14Small-73712,
title={Small-molecule dissolution of stress granules by redox modulation benefits ALS models},
year={2025},
doi={10.1038/s41589-025-01893-5},
issn={1552-4450},
journal={Nature Chemical Biology},
author={Uechi, Hiroyuki and Sridharan, Sindhuja and Nijssen, Jik and Bilstein, Jessica and Iglesias-Artola, Juan M. and Kishigami, Satoshi and Fürsch, Julius and Stengel, Florian and Hyman, Anthony A. and Wheeler, Richard J.}
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<dcterms:abstract>Neurodegenerative diseases, such as amyotrophic lateral sclerosis, are often associated with mutations in stress granule proteins. Aberrant stress granule condensate formation is associated with disease, making it a potential target for pharmacological intervention. Here, we identified lipoamide, a small molecule that specifically prevents cytoplasmic condensation of stress granule proteins. Thermal proteome profiling showed that lipoamide stabilizes intrinsically disordered domain-containing proteins, including SRSF1 and SFPQ, which are stress granule proteins necessary for lipoamide activity. SFPQ has redox-state-specific condensate dissolving behavior, which is modulated by the redox-active lipoamide dithiolane ring. In animals, lipoamide ameliorates aging-associated aggregation of a stress granule reporter protein, improves neuronal morphology and recovers motor defects caused by amyotrophic lateral sclerosis-associated FUS and TDP-43 mutants. Thus, lipoamide is a well-tolerated small-molecule modulator of stress granule condensation, and dissection of its molecular mechanism identified a cellular pathway for redox regulation of stress granule formation.</dcterms:abstract>
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