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In vivo prime editing rescues alternating hemiplegia of childhood in mice

Alexander A. Sousa, Markus Terrey, Holt A. Sakai, Christine Q. Simmons, Elena Arystarkhova, Natalia S. Morsci, Laura Anderson, Jun Xie, Fabian Suri‐Payer, Linda C. Laux, Emmanuel Roze, Sylvie Forlani, Guangping Gao, Simon D. W. Frost, Nina Frost, Kathleen J. Sweadner, Alfred L. George, Cathleen Lutz, David R. Liu

2025Cell31 citationsDOIOpen Access PDF

Abstract

ATPase subunit, cause 70% of AHC cases. Here, we present prime editing (PE) and base editing (BE) strategies to correct ATP1A3 and Atp1a3 mutations in human cells and in two AHC mouse models. We used PE and BE to correct five prevalent ATP1A3 mutations with 43%-90% efficiency. AAV9-mediated in vivo PE corrects Atp1a3 D801N and E815K in the CNS of two AHC mouse models, yielding up to 48% DNA correction and 73% mRNA correction in bulk brain cortex. In vivo PE rescued clinically relevant phenotypes, including restoration of ATPase activity; amelioration of paroxysmal spells, motor defects, and cognition deficits; and dramatic extension of animal lifespan. This work suggests a potential one-time PE treatment for AHC and establishes the ability of PE to rescue a neurological disease in animals.

Topics & Concepts

BiologyIn vivoPrime (order theory)GeneticsCell biologyCombinatoricsMathematicsCRISPR and Genetic EngineeringComplement system in diseases
In vivo prime editing rescues alternating hemiplegia of childhood in mice | Litcius