Abstract
CRISPR-Cas is a revolutionary technology but has already demonstrated significant feasibility for clinical and non-clinical applications. While the efficiency and precision of this remarkable genetic tool is unprecedented, unfortunately, a series of collateral genetic rearrangement have been reported in response to double-stranded DNA breakage. Once these molecular scissions occur, the cascade of DNA repair reactions can lead to genomic rearrangements especially if breakage takes place within a family of sequence related genes. Here, we demonstrate that CRISPR- directed gene editing near the sickle cell mutation site generates a curious genetic outcome; a footprint of the δ globin gene proximal to the CRISPR/Cas cut site(s). This rearrangement is not dependent on the presence of an exogenously added DNA template but is apparently dependent on a double strand break. Our results the highlight recombinational capacity of double strand breaks in human chromosomes where the aim is to edit a human gene.
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