Litcius/Paper detail

Correction of Beta-Thalassemia IVS-II-654 Mutation in a Mouse Model Using Prime Editing

Haokun Zhang, Ruilin Sun, Jian Fei, Hongyan Chen, Daru Lu

2022International Journal of Molecular Sciences23 citationsDOIOpen Access PDF

Abstract

Prime editing was used to insert and correct various pathogenic mutations except for beta-thalassemia variants, which disrupt functional beta-globin and prevent hemoglobin assembly in erythrocytes. This study investigated the effect of gene correction using prime editor version 3 (PE3) in a mouse model with the human beta-thalassemia IVS-II-654 mutation (C > T). The T conversion generates a 5′ donor site at intron 2 of the beta-globin gene resulting in aberrant splicing of pre-mRNA, which affects beta-globin expression. We microinjected PE3 components (pegRNA, nick sgRNA, and PE2 mRNA) into the zygotes from IVS-II-654 mice to generate mutation-edited mice. Genome sequencing of the IVS-II-654 site showed that PE3 installed the correction (T > C), with an editing efficiency of 14.29%. Reverse transcription-PCR analysis showed that the PE3-induced conversion restored normal splicing of beta-globin mRNA. Subsequent comprehensive phenotypic analysis of thalassemia symptoms, including anemic hematological parameters, anisocytosis, splenomegaly, cardiac hypertrophy, extramedullary hematopoiesis, and iron overload, showed that the corrected IVS-II-654 mice had a normal phenotype identical to the wild type mice. Off-target analysis of pegRNA and nick sgRNA additionally showed the genomic safety of PE3. These results suggest that correction of beta-thalassemia mutation by PE3 may be a straightforward therapeutic strategy for this disease.

Topics & Concepts

Prime (order theory)Beta thalassemiaBETA (programming language)ThalassemiaMutationComputer scienceGeneticsBiologyComputational biologyProgramming languageMathematicsCombinatoricsGeneCRISPR and Genetic EngineeringGenetics and Neurodevelopmental DisordersRNA regulation and disease