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AAGGG repeat expansions trigger <i>RFC1</i> -independent synaptic dysregulation in human CANVAS neurons

Connor J. Maltby, Amy Krans, Samantha Grudzien, Yomira Palacios, Jessica Muiños, Andrea Suárez, Melissa Asher, Sydney Willey, Kinsey Van Deynze, Camille Mumm, Alan P. Boyle, Andrea Cortese, Alain Ndayisaba, Vikram Khurana, Sami J. Barmada, Anke A. Dijkstra, Peter K. Todd

2024Science Advances15 citationsDOIOpen Access PDF

Abstract

Cerebellar ataxia with neuropathy and vestibular areflexia syndrome (CANVAS) is a recessively inherited neurodegenerative disorder caused by intronic biallelic, nonreference CCCTT/AAGGG repeat expansions within RFC1 . To investigate how these repeats cause disease, we generated patient induced pluripotent stem cell–derived neurons (iNeurons). CCCTT/AAGGG repeat expansions do not alter neuronal RFC1 splicing, expression, or DNA repair pathway function. In reporter assays, AAGGG repeats are translated into pentapeptide repeat proteins. However, these proteins and repeat RNA foci were not detected in iNeurons, and overexpression of these repeats failed to induce neuronal toxicity. CANVAS iNeurons exhibit defects in neuronal development and diminished synaptic connectivity that is rescued by CRISPR deletion of a single expanded AAGGG allele. These deficits were neither replicated by RFC1 knockdown in control iNeurons nor rescued by RFC1 reprovision in CANVAS iNeurons. These findings support a repeat-dependent but RFC1 protein–independent cause of neuronal dysfunction in CANVAS, with implications for therapeutic development in this currently untreatable condition.

Topics & Concepts

BiologyTrinucleotide repeat expansionInduced pluripotent stem cellGeneticsGene knockdownAtaxiaCell biologyNeuroscienceAlleleGeneEmbryonic stem cellGenetic Neurodegenerative DiseasesMitochondrial Function and PathologyDNA Repair Mechanisms
AAGGG repeat expansions trigger <i>RFC1</i> -independent synaptic dysregulation in human CANVAS neurons | Litcius