Negative Depletion of B Cells and T Cells Expressing the αβ Chain of the T-Cell Receptor (TCR) for Haploidentical Stem Cell Transplantation

Abstract 343 Introduction. Allogeneic hematopoietic stem cell transplantation (HSCT) from a HLA-haploidentical relative is a suitable option for patients (pts) lacking a compatible donor, either related or unrelated. The two main approaches for overcoming the obstacles of HLA barriers are based either on the infusion of large numbers of T-cell-depleted HSC or on intensive pharmacological prevention of graft-versus-host disease (GVHD). While for many years T-cell depletion (TCD) of the graft has been based on either immunomagnetic positive selection of CD34+ cells or on physical removal of all subsets of T cells by virtue of mAb, we and other groups have recently developed a novel method of ex vivo TCD based on the selective elimination of αβ+ T cells through labeling with a biotinylated anti-TCRαβ Ab, followed by incubation with an anti-biotin Ab conjugated to paramagnetic beads (Miltenyi Biotec, Germany). This approach also allows the removal of B cells to prevent post-transplant EBV-associated lymphoproliferative disease (PTLD). Here, we report the results of graft manipulation using this approach. Methods. Twenty-two children entered the study, 15 with hematological malignancies and 7 with non-malignant disorders. No post-transplant GvHD prophylaxis was employed. HLA-haploidentical family donors received G-CSF (12–16 μg/kg of body weight) to mobilize HSC prior to large-volume leukapheresis, which was commenced when circulating CD34+ HSC were >20 cells/μl. Cell therapy products containing up to 60×109 white blood cells (WBC) were processed according to the manufacturer's protocol. In some cases, leukapheresis bags were stored overnight at 4°C in appropriate media at a WBC concentration Results. Median recovery of CD34+ HSC and median number of infused CD34+ HSC were 99.3% (range 55.4–100) and 14.7×106/kg (range 7.9–37), respectively. The graft contained 3.9×106 CD3+ T cells/kg (range 0.9–30.9) and 0.08×106 B cells/kg (range 0.002–0.32). The log-depletion of αβ+ T cells was 4.5 (range 3.2–6.1), with a median number of transplanted αβ+ T cells equal to 36×103/kg (range 1–139.9). Patients received 36×106 CD56+ NK cells/kg (range 1.6–80.3) and 4.1×106 γδ+ T cells/kg (range 0.9–30.8). A median of 40.8% NK cells (range 30.3–60.2) co-expressed Tim-3, an activating co-receptor promoting IFN-γ production and being scarcely expressed on NK cells that reconstitute after allogeneic HSCT. The αβ/CD19-depleted grafts also contained DC1 and DC2 precursors, which were identified based on BDCA-1 (0.23% of all nucleated cells, range 0.02–2.4), BDCA-3 (0.93%, range 0.57–9.4) and BDCA-2 (0.66%, range 0.49–1.28) or BDCA-4 expression (0.69%, range 0.02–1.5), respectively. Invariant NKT cells were enumerated using mAb reacting against the TCR Vα24-Jα18 chain and were detected in minute percentages ( Conclusions. The immunomagnetic removal of αβ+ T cells and B cells was effective and gave reproducible results. In all cases, a remarkable depletion of unwanted T and B cells was attained. The depleted graft contained high numbers of CD34+ HSC, as well as of immune effector cells implicated in the control of leukemia growth and GVHD, such as γδ+ T cells, NK cells, DC1, DC2 and non-classical CD14+CD16+ monocytes. From a clinical standpoint, the infusion of αβ/CD19-depleted grafts from HLA-haploidentical family donors was safe, resulting into sustained donor engraftment without life-threatening complications. Disclosures: No relevant conflicts of interest to declare.