Publication Date:
2019-11-13
Description:
Base editing with fusions of RNA-guided DNA-binding proteins and nucleotide deaminases represents a promising approach to permanently remedy genetic blood disorders without obligatory double strand breaks, however its application in engrafting hematopoietic stem cells (HSCs) remains unexplored. Here we purified A3A(N57Q)-BE3 protein for RNP electroporation of human peripheral blood (PB) mobilized CD34+ hematopoietic stem and progenitor cells (HSPCs). We found that sgRNAs targeting for cytidine base editing the core GATA1 binding motif of the BCL11A +58 erythroid enhancer resulted in efficient on-target base edits (81% allele frequency) with low indels. There was similar HbF induction in erythroid progeny as compared to Cas9:sgRNA RNP nuclease mediated modification of the same target sequence (36% median HbF in base edited cells with 81% allele modifications, 39% HbF in 3xNLS-SpCas9:sgRNA#1617 nuclease edited cells with 99% indels, and 5%HbF in unedited cells). A single therapeutic base edit of the BCL11A enhancer was sufficient to ameliorate the pathobiology of both sickle cell disease (SCD) and beta-thalassemia. Base editing of CD34+ HSPCs from plerixafor mobilized PB SCD patient donors resulted in potent HbF induction (24-31% HbF level in bulk cells with 87-90% on-target allele modifications) and reduced sodium metabisulfite induced sickling (from 84% to 29% of erythrocytes). Base editing of non-mobilized PB CD34+ HSPCs from 3 beta-thalassemia patient donors potently induced gamma-globin and improved ineffective erythropoiesis in vitro, with 59-75% on-target allele modifications. Moreover highly efficient multiplex editing could be achieved in HSPCs. Simultaneous disruption of the BCL11A +58 erythroid enhancer core GATA1 motif and correction of the HBB -28A〉G promoter mutation in HSPCs resulted in production of at least one therapeutic allele in 35 of 35 erythroid colonies analyzed, with each colony achieving improved alpha-to-non-alpha globin chain balance. Finally we found that base editing could be efficiently produced in engrafting HSCs. Using 3 donors, we observed 62-64% base edits at the BCL11A +58 enhancer GATA1 motif in input HSPCs with one round of electroporation and 73-85% base edits with two rounds of electroporation (separated by 24 hours), albeit with modest reduction of cell viability with tandem electroporation. We observed 70-94% human chimerism and 35-82% base edits in engrafting human cells in primary recipients and 11-61% base edits in secondary recipients as measured 16 weeks following cell infusion. Similar edit frequencies were observed across all assayed hematopoietic lineages including engrafting B-lymphocytes, erythroid precursors, and HSPCs. We observed that compared to non-engrafting progenitors, long-term engrafting HSCs favored C to T (as compared to C to G/A) editing. There was a strong correlation (Spearman r 0.86, P
Print ISSN:
0006-4971
Electronic ISSN:
1528-0020
Topics:
Biology
,
Medicine
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