Litcius/Paper detail

Chemical engineering of therapeutic siRNAs for allele-specific gene silencing in Huntington’s disease models

Faith Conroy, Rachael Miller, Julia F. Alterman, Matthew Hassler, Dimas Echeverria, Bruno M.D.C. Godinho, Emily G. Knox, Ellen Sapp, Jaquelyn Sousa, Ken Yamada, Farah Mahmood, Adel Boudi, Kimberly B. Kegel-Gleason, Marian DiFiglia, Neil Aronin, Anastasia Khvorova, Edith L. Pfister

2022Nature Communications48 citationsDOIOpen Access PDF

Abstract

Small interfering RNAs are a new class of drugs, exhibiting sequence-driven, potent, and sustained silencing of gene expression in vivo. We recently demonstrated that siRNA chemical architectures can be optimized to provide efficient delivery to the CNS, enabling development of CNS-targeted therapeutics. Many genetically-defined neurodegenerative disorders are dominant, favoring selective silencing of the mutant allele. In some cases, successfully targeting the mutant allele requires targeting single nucleotide polymorphism (SNP) heterozygosities. Here, we use Huntington's disease (HD) as a model. The optimized compound exhibits selective silencing of mutant huntingtin protein in patient-derived cells and throughout the HD mouse brain, demonstrating SNP-based allele-specific RNAi silencing of gene expression in vivo in the CNS. Targeting a disease-causing allele using RNAi-based therapies could be helpful in a range of dominant CNS disorders where maintaining wild-type expression is essential.

Topics & Concepts

Gene silencingHuntingtinRNA interferenceAlleleBiologyMutantSmall interfering RNAGeneticsHuntington's diseaseGeneDiseaseRNAMedicinePathologyRNA Interference and Gene DeliveryRNA Research and SplicingCRISPR and Genetic Engineering