481. Targeted Genome Editing in Mouse Hematopoietic Stem/Progenitor Cells (HSPC) To Model Gene Correction of SCID-X1

Abstract

Targeted genome editing by artificial nucleases has brought the goal of gene correction within the reach of gene therapy. A candidate disease for HSPC gene correction is SCID-X1, because gene therapy with early generation integrating vectors showed robust clinical efficacy even from few corrected cells but also the occurrence of adverse events due to insertional mutagenesis and unregulated transgene expression. We recently reported a strategy that enabled targeted integration of a corrective cDNA into the IL2RG gene in 6% of human HSPC with high specificity. Gene corrected HSPC generated polyclonal lymphoid cells that express the IL2RG protein and have a selective growth advantage over those carrying disruptive IL2RG mutations (Genovese, Nature, 2014). Here, to model SCID-X1 disease correction, we developed a mouse model carrying the IL2RG human gene including a common disease-causing mutation in place of the murine Il2rg gene, allowing to use the same reagents utilized for gene correction of human cells. These mice have impairment in lymphoid development which phenocopies that reported for Il2rg-/- mice. To assess the minimal level of corrected HSPC required to achieve immune reconstitution we first performed competitive transplants with wild-type (WT) and Il2rg-/- HSPC and found that 1% of WT cells are sufficient to reconstitute at least in part the T and B cell compartments. We then developed a protocol to obtain gene correction in murine Lin- HSPC based on the delivery of donor DNA template by IDLVs followed by transfection of ZFN mRNAs. This protocol was associated with high on-target nuclease activity (40%) and a mean of 6% transgene integration by HDR, but also with high levels of acute cytotoxicity (65% cell loss). The surviving cells remained capable of expansion in culture and preserved their clonogenic potential. Importantly, upon transplant into lethally irradiated mice, only the gene corrected cells were able to generate lymphoid lineages (B and T cells), showing a clear selective advantage over un-corrected cells. These data indicate functional correction of the IL2RG gene by our strategy. Yet, measuring percentage of correction within myeloid cells at long-term we found that it was almost undetectable. Despite the lack of HSC marking, gene corrected lymphoid cells stably persisted in the mice up to 7 months post transplantation within all the hematopoietic organs. Furthermore, upon challenging the transplanted mice with a murine pathogen (LCMV Arm.) we observed viral-specific γIFN production by CD8+ gene corrected cells at a similar extent as for WT mice, proving in vivo the functionality of corrected T cells. These results suggest that our protocol achieves biologically relevant levels of gene correction in progenitors that sustain long-term lymphopoiesis but is limited in multipotent HSC. Ongoing studies aim to improve murine HSC gene targeting and to compare safety and efficacy of gene correction vs gene replacement in our disease model.