ALBERT

Description: Background: T-cell depleted haplo-HSCT is an established treatment for children with primary immune deficiencies (PID). However, children given this type of allograft are exposed to the risk of fatal events due to viral infections because of the prolonged impairment of adaptive immunity. We recently developed a novel method of selective T-cell depletion based on physical elimination of α/β T cells (ClinicalTrial.gov identifier: NCT01810120), which was shown to be safe and more effective than transplantation of positively-selected CD34+ cells for preventing life-threatening infections. However, we recorded some severe and even fatal viral infections, which prompted us to explore innovative approaches to accelerate the recovery of adaptive immunity. For this purpose, we designed an ongoing phase I/II trial aimed at testing the safety and the efficacy of post-transplant infusion of BPX-501 cells in children with malignant or non-malignant disorders (ClinicalTrials.gov identifier: NCT02065869). We report 3 cases of children with either severe combined immune deficiency (SCID) or Wiskott-Aldrich syndrome (WAS), who were enrolled in the dose escalation phase of the study and who cleared cytomegalovirus (CMV) or Adenovirus (AdV) infections likely due to the contribution of the BPX-501 cells. Patients and methods: Patient #1, affected by SCID, was transplanted from the HLA-haploidentical father. Before transplantation she had CMV-DNAemia which was treated with ganciclovir until donor stem cell infusion. She was given 2.5 x 105/kg BPX-501 cells on day 17 after transplantation. Patient #2, also affected by SCID, was transplanted from the HLA-haploidentical mother. Before transplantation she had AdV-DNAemia and high load of the virus in stools. She was given 5 x 105/kg BPX-501 cells on day 15 after transplantation. Patient #3 was affected by WAS and referred to the transplant unit; in the months preceding haplo-HSCT the child had developed CMV retinitis and hepatitis with high levels of CMV-DNAemia. This patient was transplanted from the father and received 1 x 106/kg BPX-501 cells on day 15 after haplo-HSCT. Basic phenotype of circulating lymphocytes was assessed by flow cytometry on fresh heparinized peripheral blood samples at 10, 20, 30, 60, 90, 120 and 150 days post haplo-HSCT, respectively. Since BPX-501 cells are CD3+/CD19+, it was easy to track the presence of these genetically modified cells. CMV specific reconstitution was also monitored through the INF gamma ELISPOT assay. In particular, peripheral blood mononuclear cells were stimulated for 16hrs in the presence of peptide libraries derived from pp65, IE1 and IE2 CMV-specific antigens. Results: The increase in the number of both CD3+ T lymphocytes and BPX-501 cells over time after transplantation together with the modifications of DNAemia of both CMV and AdV in the 3 patients are reported in Panel A, B and C, respectively, of Figure 1. In all of these patients, the pre-existing viral infection was progressively cleared once the BPX-501 cells were infused. These cells expanded in vivo and are still persisting, contributing to the recovery of adoptive immunity. The median time to reach an absolute number of α/β CD3+ cells greater than 0.5x109/L was 90, 90 and 30 days, respectively. None of these patients experienced either acute or chronic Graft-versus-Host Disease (GvHD) and no organ inflammatory-related toxicity was recorded. All children are alive and disease free, without infections, at day +200, +180 and +160, respectively. The 2 patients with CMV infection showed a specific response for at least one CMV-derived antigen; indeed, one patient showed a prevalence in pp65 response, whereas in the second one, we observed a specific anti-CMV response against all three tested antigens (Figure 1 - Panel D). Conclusions: Infusion of BPX-501 cells is able to accelerate the recovery of adaptive T-cell immunity in children with PID given haplo-HSCT after depletion of α/β T cells, thus rendering the procedure safer even in children with active infections at time of transplantation. These cells, once infused, expand in vivo and persist over time, contributing to the clearance of viral infections, without inducing GvHD. Figure 1. Figure 1. Disclosures Moseley: Bellicum Pharmaceuticals: Employment, Equity Ownership.

Description: Background: Immune recovery is crucial for patients treated with allogeneic HSCT and in particular of those receiving a T-cell depleted haplo-HSCT. We recently developed a novel method of graft manipulation based on physical elimination of α/β T cells and B-lymphocytes for preventing graft-versus-host disease (GvHD) and EBV-related lymphoproliferative disorders, respectively. Thanks to this approach, we successfully conducted a prospective trial in children with malignant or non-malignant disorders (ClinicalTrial.gov identifier: NCT01810120). Although patients enrolled in this trial had faster immune recovery and lower incidence of infections than those given haplo-HSCT after infusion of positively selected CD34+ cells, reconstitution of adaptive T-cell immunity remains suboptimal. We therefore designed a phase I/II trial aimed at testing the effect on post-transplant immune recovery of adoptive infusion (within 14 + 4 days after transplantation) of BPX-501 cells in children given haplo-HSCT after depletion of α/β T and B cells (ClinicalTrials.gov identifier: NCT02065869). Patients and methods: As of July 25th 2015, 23 children have been infused with BPX-501 cells. The 9 children included in the phase I portion of the study were given 2.5x105, 5x105, and 1x106 BPX-501 cells/kg, respectively, while the 14 included in the phase II received 1x106 BPX-501 cells/kg. This analysis refers to the 16 patients with a minimum follow-up of 90 days; 7 children had acute leukemia and 9 non-malignant disorders. Basic phenotype of circulating lymphocytes was assessed by flow cytometry on fresh heparinized peripheral blood samples at 10, 20, 30, 60, 90, 120 and 150 days post haplo-HSCT, respectively. The following antibodies were used: anti-TCRαβ FITC/anti-TCRγδ PE/anti-CD3 PerCP-Cy™5.5 (WT31, 11F2, SK7), anti-CD4 APC Cy7 (RPA-T4), anti-CD19 BV 510 (SJ25C1), anti-CD3 BV 421 (UCHT1), anti-CD56 PeCy7 (B159), anti-CD16 APC (B73.1), anti-CD8 APC (RPA-T8) from BD Biosciences (San Diego, CA, USA). Antigen-driven activation of peripheral mononuclear cells was evaluated by standard lymphoproliferation assay (LPA) with 3H-thymidine pulsing on day 4 and harvesting 18 hours later. Antigens included PHA or CMV, EBV and AdV whole viral lysate. Results were scored positive with stimulation indexes (SI) 〉10 for PHA and 〉3 for viral antigens. Results: None of the patients died from transplant-related complications. Chimerism analysis investigated through short tandem repeats showed that in all but 4 patients, cells were of donor origin before the infusion of BPX-501 cells. In the 4 patients, there was a reversion to complete donor chimerism after infusion of BPX-501 cells. At early time points after haplo-HSCT, gδ T cells predominated over αβ T lymphocytes; subsequently, this latter population became the more largely represented. The number of both CD3+ T lymphocytes and of BPX-501 cells is shown in Panel A of Figure 1, reconstitution of whole T cells in historical children given haplo-HSCT after depletion of α/β T cells is also shown. The number of CD3+ T lymphocytes reached greater than 0.5x109/L 2 months after infusion of BPX-501 cells. Remarkably, while usually immune recovery after transplantation is characterized by prevalence of CD8+ cells, in our patients the physiological predominance of CD4+ lymphocytes was maintained (Panel B of Figure 1. Reconstitution of natural killer cells (NK) is shown in Panel C of Figure 1. As compared to patients receiving CD34+ selected cell haplo-HSCT, children included in this study had a faster reconstitution of mature KIR+/NKG2A- NK cells. Serum levels of IgA and IgM over time are shown in Panel D of Figure 1: there was a recovery of newly synthetized Ig at 3 months. The analysis of the function of T cells showed that the proliferative response to a polyclonal mitogen or to CMV lysate was comparable to that of a healthy control in 50% of patients as early as day + 60 after haplo-HSCT and BPX-501; on day +150, all patients reached a normal SI. Response to both EBV and AdV antigens was slightly delayed, but progressively improved over time (see also Figure 2). Conclusions: Overall, these data indicate that infusion of BPX-501 cells is able to accelerate the recovery of adaptive T-cell immunity since these cells, once infused, expand in vivo and persist over time, potentially contributing to protect patients from infections. Figure 1. Figure 1. Figure 2. Figure 2. Disclosures Moseley: Bellicum Pharmaceuticals: Employment, Equity Ownership.

Description: Background: Haplo-HSCT after depletion of α/β T and B cells is a suitable and effective option for those children with acute leukemia (AL) who need an allograft and lacking an immediately available HLA-identical donor. With this approach, recipients can benefit immediately after transplantation from the anti-leukemia effect mediated by donor natural killer (NK) and γd T cells, which can also protect against infections. A further improvement of the results achievable with this platform could achieved with a faster adaptive T-cell immunity recovery, which play a key role to augment the graft-versus-leukemia effect and the capacity to fight infections. In light of these considerations, we designed a phase I/II trial aimed at testing the safety and efficacy of post-transplant infusion of donor-derived T cells transduced with the new iC9 suicide gene (BPX-501) in children with either malignant or non-malignant disorders (NCT02065869). Remarkably, after the activation and transduction with the retroviral iC9 construct, BPX501 cells switch the phenotype towards a preferential CD45RO pattern. Patients and methods: The phase I portion of the trial consisted of a classical 3+3 design with 3 cohorts, receiving escalating doses of BPX-501 cells of 2.5x105, 5x105, and 1x106 cells/kg, respectively. Patients included in the phase II portion were planned to receive the recommended dose identified during the phase I part of the study.Enrollment of patients started in December 2014; so far, 25 patients with AL in morphological complete remission (CR) have been enrolled. Twenty patients had acute lymphoblastic leukemia (ALL) and 5 acute myeloid leukemia (AML). Details on patient, donor and transplant characteristics are reported in table 1. All patients transplanted in CR1 had either poor cytogenetic/molecular characteristics or high levels of minimal residual disease at the end of induction therapy, both factors predicting a high relapse rate. All patients were given a fully myeloablative conditioning regimen (table 1). Before haplo-HSCT, children received rabbit anti-thymocyte globulin (ATG NEOVII, 12 mg/Kg over 3 days, from day -4 to day -2) to prevent both graft-versus-host disease (GvHD) and graft failure, and Rituximab (200 mg/ m2 on day -1) to prevent EBV-related lymphoproliferative disorders. No post-transplantation GvHD prophylaxis was administered. Results: All patients engrafted and no secondary graft failure was recorded. Median time to neutrophil and platelet recovery was 18 days (range 10-22) and 11 days (range 9-13), respectively. Once documented the engraftment of donor cells, BPX-501 T lymphocytes were infused at a median time of 17 days (range 13-52) after the allograft. Two patients were enrolled in the phase I portion of the study; one each received 2.5x105 and 1x106 cells/kg. The remaining 23 children were treated in the phase II, where the recommended dose was 1x106 cells/kg. However, since we did not observe any acute GvHD requiring the infusion of the dimerizing agent (Rimiducid/AP1903) activating iC9 gene in the first 15 children receiving 1x106 cells/kg, we decided to emend the protocol to further increase the BPX501 cell dose infused to 2 and 4x106 cells/kg. Thus, the last 6 patients were enrolled in these 2 last dose levels (3 patients each). Six and 3 patients developed grade II-IV acute and chronic GvHD, respectively. In one child, given 4x106 cells/kg, we infused rimiducid for steroid-resistant grade II skin acute GvHD, with complete resolution of the disease in 24 hours. The cumulative incidence of grade II-III acute and chronic GvHD are shown in figure 1A and B, respectively. Median follow-up of these 25 children is 8 months (range 1-19 months). One of them died due to chronic GvHD-associated bronchiolitis obliterans and one child with ALL transplanted in CR2 relapsed; the cumulative incidence of non-relapse mortality and leukemia recurrence are shown in figure 1C. The probability of disease-free survival at 15 months is 87% (figure 1D). Once infused, BPX501 cells expanded and persisted over time in both peripheral blood and bone marrow. Conclusion: Overall, these data indicate that the infusion of BPX-501 cells in children with AL given selectively manipulated haplo-HSCT results in low non-relapse mortality and chronic GvHD. Although the median observation time is still limited, the cumulative incidence of disease recurrence is promising. Table 1 Table 1. Figure 1 Figure 1. Disclosures Stanson: Bellicum pharmaceuticals: Employment. Moseley:Bellicum Pharmaceuticals: Employment, Membership on an entity's Board of Directors or advisory committees.

Description: Background: We recently completed a prospective study (ClinicalTrial.gov identifier: NCT01810120) which showed that haplo-HSCT after depletion of α/β T cells is an effective option for those children in need of an allograft and lacking an immediately available HLA-identical related or unrelated donor. However, recovery of adaptive T-cell immunity remains suboptimal and some patients died due to viral infections in the early post-transplant period. Thus, strategies aimed at accelerating early recovery of adaptive T-cell immunity are desirable. Study design and patients: We designed a phase I/II trial aimed at testing the safety and the efficacy of post-transplant infusion of donor-derived T cells transduced with the new iC9 suicide gene (BPX-501) in children with malignant or non-malignant disorders (ClinicalTrials.gov identifier: NCT02065869); enrollment started in December 2014. Cells are administered within 14 + 4 days after haplo-HSCT. The phase I portion of the trial consists of a classical 3+3 design with 3 cohorts, receiving escalating doses of BPX-501 cells of 2.5 x 105, 5 x105, and 1x106 cells/kg, respectively. Patients included in the phase II portion received the highest dose identified during the phase I portion of the study for a maximum of 60 children in both phase I/II portions of the study. As of July 25th 2015, 25 children have been screened and included in the study: 23 have been infused with BPX-501 cells. The analysis refers to the 16 patients with a minimum follow-up of 90 days after transplantation; they had acute lymphoblastic leukemia (ALL, 6), acute myeloid leukemia (1), severe combined immune-deficiency (4), Wiskott-Aldrich syndrome (3) and Fanconi Anemia (2). All children with acute leukemia were transplanted in morphological complete remission (CR). Median age at haplo-HSCT was 3.5 years (range, 03-17.8); 7 patients (44%) were females. All children received 〉10x106 CD34+ cells/Kg and

Description: Background: Allogeneic HSCT is a widely used treatment for children with acute leukemia (AL) either relapsed or at high risk of treatment failure. However, an HLA-identical sibling is available for only 20-25% of patients and an UD can be located in a suitable time only for a portion of the remaining population. HSCT from an HLA-haploidentical relative (haplo-HSCT) is now considered an alternative option, especially in view of the recent insights in graft manipulation. We recently developed a novel method of more selective T-cell depletion based on physical elimination of α/β T cells (ClinicalTrial.gov identifier: NCT01810120), shown to be effective for both preventing graft-versus-host disease (GvHD) and for conferring improved protection against infections in comparison to haplo-HSCT performed through the infusion of positively selected CD34+ cells. The initial results on 40 patients with AL were reported at the ASH Meeting in 2013 (Bertaina et al). We now present the comparison of the outcome of 80 children with AL given haplo-HSCT after α/β T-cell depletion (group 1) with that of patients transplanted from an HLA-identical sibling (group 2) or an UD (group 3) in the same time period. Patients and methods: All patients with AL were transplanted at the Bambino Gesù Children's Hospital in Rome, Italy, between December 2010 and September 2014; 80 patients were included in group 1, 41 in group 2 and 51 in group 3. Patients were offered α/β T-cell-depleted haplo-HSCT in the absence of suitable conventional donor (HLA identical sibling or 10/10 UD evaluated using high resolution typing) or if affected by rapidly progressive disease not permitting time to identify an UD. Clinical characteristics of patients assigned to the 3 groups and those of their donor are shown in Table1. All children were given a fully myeloablative regimen. No group 1 patient was given any post-transplantation GvHD prophylaxis, while patients of group 2 and 3 were given Cyclosporine-A and short-term methotrexate. Group 1 and 3 patients received ATG Fresenius® (4 mg/Kg/day) from day -5 to -3 for preventing both graft rejection and GvHD. Results: All group 2 and 3 patients had sustained engraftment of donor cells, while 1 of the 80 patients included in group 1 experienced primary graft failure and was rescued by haplo-HSCT from the other parent. The cumulative incidence (CI) of acute GvHD was 30%, 41% and 42%, respectively. Remarkably, all children of the group 1 who developed acute GvHD had a skin-only involvement, while 17% and 16.3% of those of group 2 and 3 had either gut or liver involvement (p

Description: When prepared for transplantation with busulfan (BU) 14 mg/kg and cyclophosphamide (CY) 120 to 160 mg/kg, patients with thalassemia in risk class 3, aged younger than 17 years, who receive transplants from HLA-identical donors, had a 30% incidence of transplant rejection with recurrence of thalassemia. This, relatively poor, outcome was ascribed to insufficient immune suppression or to inadequate eradication of the thalassemic marrow, or both. In an attempt to enhance both immune suppression and eradication of the thalassemic clones, hydroxyurea, azathioprine, and fludarabine were added to the BU and CY. This regimen, called protocol 26, was applied to 33 consecutive patients with class 3 thalassemia aged younger than 17 years and was well tolerated with 93% survival. The incidence of recurrent thalassemia after the transplantation decreased from 30% to 8%. (Blood. 2004;104:1201-1203)

Description: Key Points Vδ1 and Vδ2 T cells promptly reconstitute in children given haploidentical stem cell transplantation depleted of αβ+ T and CD19+ B cells. Vδ1 cells are expanded in patients experiencing cytomegalovirus reactivation; ZOL potentiates Vδ2 killing against leukemia blasts.

Description: Abstract 45 Background: Adoptive transfer of regulatory T cells is a potentially attractive alternative to conventional immunosuppressive therapy in allogeneic hematopoietic stem cell transplantation (HSCT) (Roncarolo MG., Nat Rev Immunol 2007). Among CD4+ T cells, the subset known as Type 1 regulatory T (Tr1) cells are induced in an antigen specific manner by interleukin-10 (IL-10) and suppress via production of high levels of IL-10 (Groux H., Nature 1997). The aim of this phase I/II study was to establish the safety and efficacy of a new cellular therapy with Tr1 cells in a non-randomized study. Patients and Methods: A cellular therapy protocol for the adoptive transfer of IL-10 induced alloantigen specific donor-derived Tr1 cells in patients transplanted with CD34+ selected cells from haploidentical donor, has been applied to patients with high risk hematopoietic malignancies (www.risetfp6.org). Donor T cells, anergized ex vivo toward host alloantigens, presented by monocytes (original protocol) or tolerogenic dendritic cells (modified protocol) as host antigen presenting cells, in the presence of IL-10, are infused post-transplant into the host (IL-10 DLI). The infusion is made in the absence of immunosuppression for graft-versus-host-disease (GVHD) prophylaxis, with the ultimate goal to provide immune reconstitution without severe GVHD. The infused donor T cells, at the dose of 105 CD3+ cells/kg or 3 × 105 CD3+ cells/kg, are anergic towards host-HLA antigens and contain precursors of host-specific Tr1 cells but, at the same time, comprise memory T cells able to respond to nominal and viral antigens. Results: Eighteen patients have been enrolled, sixteen received CD34+ selected cells from haploidentical donor after myeloablative conditioning. Twelve patients have been treated with IL-10 anergized cell therapy at day +30 post transplant, at the dose of 105 CD3+ cells/kg with the exception of two patients who received 3 × 105 CD3+ cells/kg. No severe immediate reactions post infusion were registered. Five patients died from infections by day +30 after Tregs cell infusion and two patients dropped out for graft rejection. Five patients achieved immune reconstitution at a median of 30,5 days (range 15–46 days) after IL-10 DLI, followed by progressive normalization of TCR repertoire, memory/naïve phenotype and T cell functions in vitro and in vivo. Acute GVHD grade III was observed in one patient who received 3 × 105 CD3+ cells/kg; GVHD grade II was observed in 4 patients who received 105 CD3+ cells/kg and were successfully immune reconstituted. The median follow-up of the IL-10 DLI treated patients is 980 days (range 291–1624); 4 patients are alive and disease free and they do not require immunosuppressive treatment. Conclusions: Cellular therapy with IL-10 anergized donor T cells has proven to be safe and feasible, and to sustain immune reconstitution associated with a reduced severity of GVHD and no occurrence of relapse. This trial represents the first step towards an extended use of Tr1 cells as adjuvant treatment in allogeneic HSCT. Disclosures: No relevant conflicts of interest to declare.

Description: Background: Allogeneic HSCT from either an HLA-identical sibling or an unrelated donor is a potentially curative treatment for patients with hemoglobinopathies and erythroid disorders (ED), such as Thalassemia Major (TM), Sickle Cell Disease (SCD) and Diamond-Blackfan Anemia (DBA). The limited historical experience with HLA-haploidentical HSCT in this setting has reported a disease-free survival probability lower than that reported using HLA-matched donors. In the last few years, we have developed a novel method of graft manipulation, based on the selective depletion of α/β+ T-cells and CD19+ B-cells (ClinicalTrial.gov identifier: NCT01810120), which was shown to be safe and effective in children with multiple types of non-malignant disorders (Bertaina el al, Blood 2014). To further optimize this approach through the acceleration of the recovery of adaptive immunity, we designed an ongoing phase I/II trial aimed to test the safety and efficacy of post-transplant infusion of donor T-cells transduced with the iC9 suicide gene (BPX-501 cells) in children with either malignant or non-malignant disorders (ClinicalTrials.gov identifier: NCT02065869). As the transduced gene contains sequences for the CD19 marker, BPX-501 cells (CD3+/CD19+) can be easily tracked in peripheral blood. We report on 10 children with hemoglobinopathies and ED who were enrolled in the phase II portion of the study. Patients and methods: Five patients were males and 5 were females, and median age at diagnosis and at HSCT was 5.34 and 9.52 years (range 2.33-11.71), respectively. Seven patients had TM (all bo/bo), 2 DBA and 1 SCD. All 10 patients were transfusion-dependent and receiving iron-chelation therapy before haplo-HSCT. Among the thalassemia patients, 4 patients belonged to class I and 3 to class II of the Pesaro classification. All patients were transplanted from a parent. Median number of CD34+ and αβ+ T-cells infused was 22.5 x 106/kg and 0.3 x 105/kg, respectively. In all patients, conditioning regimen included busulfan (16 mg/Kg), thiotepa (10 mg/Kg) and fludarabine (160 mg/m2). Rabbit ATG (12 mg/Kg over 3 days, from day -4 to day -2) was administered to prevent graft-versus-host disease (GvHD) and graft failure and Rituximab (200 mg/ m2 on day -1) was administered to prevent EBV-related lymphoproliferative disorders. No post-transplantation GvHD prophylaxis was given. Median follow-up is 301 days (range 41-420 days). Basic phenotyping of circulating lymphocytes was assessed by flow cytometry on fresh heparinized peripheral blood samples at 10, 20, 30, 60, 90, 120 and 150 days post haplo-HSCT. Results: After haplo-HSCT, the median time to reach neutrophil and platelet recovery was 14 days (range 11-28) and 10 days (range 8-12), respectively. After engraftment of the allograft, BPX-501 cells were infused (dose: 1x106 cells/kg) at a median time of 13.5 days after HSCT (range 10-26). Nine of the 10 patients maintained sustained donor engraftment, reaching full chimerism. The patient who experienced secondary graft failure was successfully re-transplanted from the same parent and he is full donor chimeric with transfusion-independence. Grade I/II skin acute GvHD occurred in 2 patients (at 31 and 59 days after HSCT, respectively). There was no occurrence of chronic GVHD. Remarkably, no patient has died and none of the patients have been re-hospitalized after initial discharge. The last erythrocyte transfusion was administered on day +7 post-transplant (range 4-33 days). At last follow-up, the median hemoglobin value of these patients was 11.35 gr/dL (range 10.2-13.4). BPX-501 cells expanded after infusion and still persist in all patients at last follow-up. All children are alive and transfusion-independent. Details on T cell, NK cell and B cell recovery are shown in Figure 1 (Panel A-D). Conclusions: Children with hemoglobinopathies and DBA can benefit from curative haplo-HSCT after depletion of α/β T-cells followed by infusion of BPX-501 cells, which, expanding and persisting over time, contribute to speed immune recovery of adaptive T-cell immunity, thus rendering the procedure safer. Figure 1 Figure 1. Disclosures French: Bellicum Pharmaceuticals: Employment, Membership on an entity's Board of Directors or advisory committees. Moseley:Bellicum Pharmaceuticals: Employment, Membership on an entity's Board of Directors or advisory committees.

Description: T-cell depleted HLA-haploidentical hematopoietic stem cell transplantation (HSCT) is a suitable option for patients in need of an allograft who lack a HLA-matched donor. Although it offers the advantage of being immediately applicable to virtually all patients, so far, graft manipulation with removal of all T lymphocyte subsets and of natural killer (NK) cells has been associated with an increased risk of life-threatening infections, as well as, in some studies, of leukemia recurrence. We recently developed a new method of graft manipulation based on the physical removal of αβ+ T cells and CD19+ B cells, which permits to leave mature NK cells and γδ+ T cells in the graft. We, thus, started a formal study (NCT01810120) in children with acute leukemia aimed at evaluating the safety and efficacy of this approach. As of April 2013, we enrolled 45 patients (pts; 29 males, 16 females). Median age at HSCT was 10.1 years (range 0.9-17.9). Thirty-five pts had acute lymphoblastic leukemia (ALL) and 10 acute myeloid leukemia (AML); all children were transplanted in morphological complete remission (CR). Fifteen pts were transplanted in first CR, 27 in second CR and 3 in more advanced CR. All pts transplanted in CR1 had either poor cytogenetic/molecular characteristics or high levels of minimal residual disease (MRD) at the end of induction therapy. The donor was either the mother (n=25) or the father (n=20); according to the model of KIR/KIR ligand disparity, 22 pts were transplanted from an NK-alloreactive donor. The median number of CD34+ cells, NK cells, γδ+ T cells, B cells and αβ+ T cells were 14.6, 31.7, 7.8, 0.08 and 0.04x106/kg, respectively. A myeloablative regimen, containing Total Body Irradiation in 34 cases, was given to all children, who also received anti-thymocyte globulin (12 mg/kg over 3 days, from -5 to -3). Rituximab (200 mg/m2) was administered on day -1 to further prevent EBV-related lymphoproliferative disorders. No pharmacological graft-versus-host disease (GVHD) prophylaxis was employed after transplantation. Sustained primary engraftment occurred in 44/45 pts, the remaining child being successfully re-transplanted from the other parent. The median time to reach an absolute neutrophil count 〉0.5x109/L and a platelet count 〉50x109/L was 13 days (9-18) and 11 days (8-20). No child developed gut or liver acute GVHD. Thirteen pts experienced skin-only grade I-II GVHD, this leading to a cumulative incidence (CI) of 29% (95% confidence interval, CO. IN., 18-45). Only 2 pts developed skin limited chronic GVHD. Two pts died for causes other than disease relapse (both in the first 60 days after HSCT), the CI of transplantation-related mortality (TRM) being 4% (CO. IN. 1-16). Seven pts relapsed, the CI of disease recurrence being 16% (CO. IN. 6-32). With a median follow-up of 11 months (range 2-30), the 2-year Kaplan Meier estimate of leukemia-free survival (LFS) was equal to 75% (CO. IN. 57-86); this value was 73% (CO. IN. 52-85) for pts with ALL. LFS of pts who did or did not experience skin-only acute GVHD was 83% (CO. IN. 48-96) and 72% (CO. IN. 50-86), p=NS. The probability of LFS of the 39 pts with either negative or low (