1. Preclinical evaluation for engraftment of CD34+ cells gene-edited at the sickle cell disease locus in xenograft mouse and non-human primate models
- Author
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Naoya Uchida, Linhong Li, Tina Nassehi, Claire M. Drysdale, Morgan Yapundich, Jackson Gamer, Juan J. Haro-Mora, Selami Demirci, Alexis Leonard, Aylin C. Bonifacino, Allen E. Krouse, N. Seth Linde, Cornell Allen, Madhusudan V. Peshwa, Suk See De Ravin, Robert E. Donahue, Harry L. Malech, and John F. Tisdale
- Subjects
genome editing ,CRISPR/Cas9 ,sickle cell disease ,hematopoietic stem cell ,transplantation ,electroporation ,Medicine (General) ,R5-920 - Abstract
Summary: Sickle cell disease (SCD) is caused by a 20A > T mutation in the β-globin gene. Genome-editing technologies have the potential to correct the SCD mutation in hematopoietic stem cells (HSCs), producing adult hemoglobin while simultaneously eliminating sickle hemoglobin. Here, we developed high-efficiency viral vector-free non-footprint gene correction in SCD CD34+ cells with electroporation to deliver SCD mutation-targeting guide RNA, Cas9 endonuclease, and 100-mer single-strand donor DNA encoding intact β-globin sequence, achieving therapeutic-level gene correction at DNA (∼30%) and protein (∼80%) levels. Gene-edited SCD CD34+ cells contributed corrected cells 6 months post-xenograft mouse transplant without off-target δ-globin editing. We then developed a rhesus β-to-βs-globin gene conversion strategy to model HSC-targeted genome editing for SCD and demonstrate the engraftment of gene-edited CD34+ cells 10–12 months post-transplant in rhesus macaques. In summary, gene-corrected CD34+ HSCs are engraftable in xenograft mice and non-human primates. These findings are helpful in designing HSC-targeted gene correction trials.
- Published
- 2021
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