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PAM-altering SNP-based allele-specific CRISPR-Cas9 therapeutic strategies for Huntington’s disease

Jun Wan Shin, Eun Pyo Hong, Seri S. Park, Doo Eun Choi, Sophia Zeng, Richard Z. Chen, Jong‐Min Lee

2022Molecular Therapy — Methods & Clinical Development16 citationsDOIOpen Access PDF

Abstract

Huntington's disease (HD) is caused by an expanded CAG repeat in huntingtin ( HTT ). Since HD is dominant and loss of HTT leads to neurological abnormalities, safe therapeutic strategies require selective inactivation of mutant HTT . Previously, we proposed a concept of CRISPR-Cas9 using mutant-specific PAM sites generated by SNPs to selectively inactivate mutant HTT . Aiming at revealing suitable targets for clinical development, we analyzed the largest HD genotype dataset to identify target PAM-altering SNPs (PAS) and subsequently evaluated their allele specificities. The gRNAs based on the PAM sites generated by rs2857935, rs16843804, and rs16843836 showed high levels of allele specificity in patient-derived cells. Simultaneous use of two gRNAs based on rs2857935-rs16843804 or rs2857935-rs16843836 produced selective genomic deletions in mutant HTT and prevented the transcription of mutant HTT mRNA without impacting the expression of normal counterpart or re-integration of the excised fragment elsewhere in the genome. RNA-seq and off-target analysis confirmed high levels of allele specificity and the lack of recurrent off-targeting. Approximately 60% of HD subjects are eligible for mutant-specific CRISPR-Cas9 strategies of targeting one of these three PAS in conjunction with one non-allele-specific site, supporting high applicability of PAS-based allele-specific CRISPR approaches in the HD patient population.

Topics & Concepts

HuntingtinCRISPRBiologyAlleleMutantCas9GeneticsGenotypeSingle-nucleotide polymorphismHuntington's diseasePopulationGeneDiseaseMedicineEnvironmental healthPathologyGenetic Neurodegenerative DiseasesCRISPR and Genetic EngineeringRNA and protein synthesis mechanisms