Abstract

The fetal hemoglobin repressor BCL11A represents a therapeutic target for β-hemoglobinopathies as reduced expression of BCL11A leads to simultaneous increased γ-globin and reduced β-globin expression. Reversing this hemoglobin switch is particularly relevant in sickle cell disease to reduce the βS concentration and increase expression of the protective fetal hemoglobin (HbF, α2γ2). Here we show that despite use of optimized shRNAs embedded into a miRNA (shRNAmiR) architecture to reduce non-specific cellular toxicities (Guda et al. MT, 2015), the knockdown of BCL11A profoundly and specifically impaired long-term engraftment of both human and mouse hematopoietic stem cells (HSCs). In competitive transplantation assays cells transduced with shRNAmiRs targeting the BCL11A mRNA were consistently underrepresented after hematopoietic reconstitution with gene modified HSCs. Although this effect was particularly pronounced in the B-cell compartment, it was also the case for all other assessed hematopoietic lineages. Mechanistically, while knock-down of BCL11A did not lead to a detectable phenotype in terms of apoptosis, growth or differentiation in human or mouse HSCs in vitro, a significant increase in S/G2-phase human HSCs after engraftment into NSG mice was found, a phenotype associated with stem cell exhaustion. To avoid this BCL11A-specific HSC toxicity, we suppressed BCL11A in erythroid cells in a lineage-specific fashion by using transcriptional regulatory elements derived from the β-globin locus. Utilizing this approach for the expression of the optimized shRNAmiRs led to stable long-term engraftment of mouse and human gene modified cells in congenic or NSG-mice, respectively. Transduced primary normal or sickle cell disease (SCD) human HSCs gave rise to erythroid cells with up to 90% reduction of BCL11A protein. These erythrocytes demonstrated 60-70% γ-chain expression and a corresponding increase in HbF at low vector copy numbers per cell (VCN<1.5). Similar results were obtained after in vitro differentiation of CD34+ cells harvested 16 weeks following engraftment in NSG mice. Transplantation of gene modified murine HSCs from BERK sickle cell mice led to a substantial improvement of sickle-associated hemolytic anemia and reticulocytosis, key phenotypes of SCD. In summary, we have shown an unexpected and severe toxicity of BCL11A knockdown in repopulating HSCs that has direct and important consequences for translation into human gene therapy trials. By utilizing erythroid lineage-specific and microRNA embedded expression of targeting shRNAs we demonstrate the capacity of lentivirus vectors to effect significant γ-globin induction leading to clinically relevant increases in HbF while obviating HSC toxicity.

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