Cxcr4-haploinsufficient bone marrow transplantation corrects leukopenia in an unconditioned WHIM syndrome model
Ji-Liang Gao, … , David H. McDermott, Philip M. Murphy
Ji-Liang Gao, … , David H. McDermott, Philip M. Murphy
Published May 1, 2018
Citation Information: J Clin Invest. 2018;128(8):3312-3318. https://doi.org/10.1172/JCI120375.
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Concise Communication Immunology

Cxcr4-haploinsufficient bone marrow transplantation corrects leukopenia in an unconditioned WHIM syndrome model

Abstract

For gene therapy of gain-of-function autosomal dominant diseases, either correcting or deleting the disease allele is potentially curative. To test whether there may be an advantage of one approach over the other for WHIM (warts, hypogammaglobulinemia, infections, and myelokathexis) syndrome — a primary immunodeficiency disorder caused by gain-of-function autosomal dominant mutations in chemokine receptor CXCR4 — we performed competitive transplantation experiments using both lethally irradiated WT (Cxcr4+/+) and unconditioned WHIM (Cxcr4+/w) recipient mice. In both models, hematopoietic reconstitution was markedly superior using BM cells from donors hemizygous for Cxcr4 (Cxcr4+/o) compared with BM cells from Cxcr4+/+ donors. Remarkably, only approximately 6% Cxcr4+/o hematopoietic stem cell (HSC) chimerism after transplantation in unconditioned Cxcr4+/w recipient BM supported more than 70% long-term donor myeloid chimerism in blood and corrected myeloid cell deficiency in blood. Donor Cxcr4+/o HSCs differentiated normally and did not undergo exhaustion as late as 465 days after transplantation. Thus, disease allele deletion resulting in Cxcr4 haploinsufficiency was superior to disease allele repair in a mouse model of gene therapy for WHIM syndrome, allowing correction of leukopenia without recipient conditioning.

Authors

Ji-Liang Gao, Erin Yim, Marie Siwicki, Alexander Yang, Qian Liu, Ari Azani, Albert Owusu-Ansah, David H. McDermott, Philip M. Murphy

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Figure 2

The superiority of Cxcr4+/o BM for blood reconstitution after competitive transplantation in lethally irradiated mice involves an early HSC proliferative advantage and superior long-term engraftment, but not an HSC BM-homing advantage.

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The superiority of Cxcr4+/o BM for blood reconstitution after competitiv...
(A) Homing. Equal numbers of Cxcr4+/o and Cxcr4+/w lineage-negative BM cells were cotransplanted into lethally irradiated mice. Four hours later, the recipient BM was analyzed for donor-derived cells. (B) Long-term engraftment of HSCs and HPCs. (C) Mature leukocyte retention. Blood and BM cells of the mice in Figure 1B were analyzed on day 465 after transplantation. Data (n = 5) are the percentage (mean ± SEM) of total donor-derived cells specific for the indicated Cxcr4 genotype (abbreviated as +/o, +/+, and +/w) for the indicated HSCs and HPCs (A and B) and mature leukocytes (C) from individual experiments and are representative of 2 independent experiments in AC. (D) HSC proliferation (see Supplemental Figure 5 for details). Data (n = 5) are the percentage (mean ± SEM) of BrdU+ HSCs for each donor from a single experiment representative of 2 independent experiments. (E) Survival. Cxcr4+/+ (n = 15) and Cxcr4+/o (n = 27) littermates were observed in specific pathogen-free conditions. Lin, lineage-negative leukocytes; LT-HSC, long-term engrafting HSCs; ST-HSC, short-term engrafting HSCs; LSK, linSca1+c-kit; MPP, multipotent progenitors. *P < 0.05; **P < 0.01; ***P < 0.005; **** P < 0.001; NS, not significant, Student’s t test.