Humanized animal models are central to efforts aimed at improving hematopoietic stem cell (HSC) transplantation with or without genetic modification. Human cell engraftment is feasible in immunodeficient mice; however, high HSC doses and conditioning limit broad use of xenograft models. We assessed human CD45+ chimerism after transplanting varying doses of human CD34+ HSCs (2 × 105 to 2 × 106 cells/mouse) with or without busulfan (BU) pretransplant conditioning in c-kit mutant mice that do not require conditioning (non-obese diabetic [NOD]/B6/severe combined immunodeficiency [SCID]/ interleukin-2 receptor gamma chain null (IL-2rγ-/-) KitW41/W41 [NBSGW]). We then tested a range of BU (5-37.5 mg/kg) using 2 × 105 human CD34+ cells. Glycophorin-A erythrocyte chimerism was assessed after murine macrophage depletion using clodronate liposomes. We demonstrated successful long-term engraftment of human CD34+ cells at all cell doses in this model, and equivalent engraftment using 10-fold less CD34+ cells with the addition of BU conditioning. Low-dose BU (10 mg/kg) was sufficient to allow human engraftment using 2 × 105 CD34+ cells, whereas higher doses (≥37.5 mg/kg) were toxic. NBSGW mice support human erythropoiesis in the bone marrow; however, murine macrophage depletion provided only minimal and transient increases in peripheral blood human erythrocytes. Our xenograft model is therefore useful in HSC gene therapy and genome-editing studies, especially for modeling in disorders, such as sickle cell disease, where access to HSCs is limited.

Immunodeficient mice play a critical role in hematology research as in vivo models of hematopoiesis and immunology. Multiple strains have been developed, but hematopoietic stem cell engraftment and immune reconstitution have not been methodically compared among them. Four mouse strains were transplanted with human fetal bone marrow or adult peripheral blood CD34+ cells: NSG, NSG-3GS, hSCF-Tg-NSG, and hSIRPα-DKO. Hematopoietic engraftment in the bone marrow, blood, spleen, and liver was evaluated by flow cytometry 12 weeks after transplant. The highest levels of human engraftment were observed in the liver, spleen, and bone marrow, whereas peripheral blood cell chimerism was notably less. The highest levels of tissue engraftment were in hSCF-Tg-NSG mice, but NSG mice exhibited the highest blood leukocyte engraftment. hSCF-Tg-NSG mice also exhibited the highest levels of CD133+CD34++ stem cells. hSIRPα-DKO engrafted poorly and exhibited poor breeding. Myelopoiesis was greatest in NSG-3GS mice, followed by hSCF-Tg-NSG and NSG mice, whereas B cell engraftment exhibited the opposite pattern. Engraftment of CD3+ T cells, CD3+CD161+ T cells, and CD3-CD56+ NK cells was greatest in NSG-3GS mice. Mast cell engraftment was highest in hSCF-Tg-NSG mice, but was also elevated in spleen and livers of NSG-3GS mice. Basophils were most abundant in NSG-3GS mice. Overall, hSCF-Tg-NSG mice are the best recipient mice for studies requiring high levels of human hematopoiesis, stem cell engraftment, and an intermediate level of myelopoiesis, whereas NSG and NSG-3GS mice offer select advantages in the engraftment of certain blood cell lineages.