β-thalassemia and HbE result from mutations in the β-globin locus that impedes the production of functional β-hemoglobin and represents one of the most common genetic disorders worldwide. Recent advances in genome engineering have opened up new therapeutic opportunities to directly correct these pathogenic mutations using base editors that install transition mutations (A>G and C>T) in the target region with minimal generation of indels. Herein, for the first time, we demonstrate the usage of base editor in the correction of point mutations spanning multiple regions of the HBB gene, including promoter, intron and exon. To this end, we have engineered human erythroid cells harbouring the diverse HBB mutations, thus eliminating the requirement of patient CD34+ HSPCs with desired mutations for the primary screening by base editors. We further performed precise creation and correction of individual HBB point mutations in human erythroid cells using base editors, which were effectively corrected in the HBB-engineered erythroid model. Intriguingly, most bystander effects produced by the base editor at the target site were reported to exhibit normal hemoglobin variants. Overall, our study provides the proof-of-concept for the precise, efficient and scarless creation and correction of various pathogenic mutations at the coding and non-coding regions of HBB gene in human erythroid cells using base editors and establishes a novel therapeutic platform for the treatment of β-thalassemia/HbE patients. This study can be further explored in correcting the other monogenic disorders caused due to single base substitutions.
