Transient Inhibition of Transforming Growth Factor-β1 in Human Blood-Derived CD34+ Cells Enhances Survival and Proliferation in Vitro and Vascular Reparative functions In Vivo.
Abstract Abstract 3546 Poster Board III-483 CD34+ cells from diabetic patients demonstrate reduced vascular reparative function due to decreased proliferation as well as diminished migration prowess which is largely due to lower levels of bioavailable nitric oxide (NO). We asked whether a transient TGF-β1 blockade in CD34+ cells from diabetics would improve their reparative ability given that TGF-β is a key factor modulating stem cell quiescence. Peripheral blood lin-CD34+ cells or lin-CD34+CD38+/− cells were treated ex vivo with antisense phosphorodiamidate morpholino oligomers (TGF-β1 -PMO), demonstrated to inhibit TGF-β1 protein expression in stem cells. Cells were then analyzed for cell surface TGF-β Receptor 2 (TGF-β R2) and CXCR4 expression, their ability to generate NO, their ability to migrate toward SDF-1, their ability to survive in the absence of added growth factors, and tested in vivo for their vascular reparative ability. After TGF-β1-PMO treatment, healthy and diabetic CD34+CD38+ and - cells downregulated TGF-βR2, upregulated CXCR4 expression, survived in the absence of added growth factors ex vivo and migrated more efficiently to SDF-1 compared to controls. TGF-β1-PMO treated diabetic CD34+ cells restored NO production to non-diabetic levels. In contrast, TGF-β1-PMO did not enhance NO generation in CD34+ cells from healthy subjects. Using an in vivo retinal ischemia reperfusion model, we observed that TGF-β1-PMO treatment increased the ability of both healthy and diabetic CD34+ cells to home to injured capillaries compared to control PMO treated cells. As also observed in our current study, a reduction of TGF-β1 levels in murine hematopoietic stem cells correlates with a reduction in TGF-βR2 expression which may induce proliferation in vivo. We also show that both diabetic and healthy lin-CD34+CD38+ cells express TGF-βR2 by FACS. In contrast, only healthy lin-CD34+CD38- cells expressTGF-βR2 while diabetic lin-CD34+CD38 - cells express essentially no cell surface TGF-βR2 (<5 % of cells are TGF-βR2+). Our results suggest that a transient blockade of TGF-β1 may represent a promising therapeutic strategy in restoring vascular reparative function in diabetic CD34+ cells. Disclosures: Bartelmez: BetaStem Therapeutics: Employment, Equity Ownership, Head, SRB, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding. Iversen:AVI-Biopharma: Employment, Equity Ownership, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding.
Successful Plerixafor-Mediated Mobilization, Apheresis, and Lentiviral Vector Transduction of Hematopoietic Stem Cells in Patients with Severe Sickle Cell Disease
Abstract Background Patients with severe sickle cell disease (SCD) may benefit from β-globin gene transfer into autologous hematopoietic stem cells (HSC). Successful HBB gene transfer requires vector-mediated transduction of primitive HSCs. Steady-state bone marrow (BM) is the default HSC source in patients with SCD. Normal human BM contains up to 30% CD34+CD19+ pro-B cells and other lineage-committed cell types (CD34dim) that will not contribute to improved long-term erythropoiesis via gene therapy; these cells mobilize at low rates. CD34+ cell yields from BM harvest (BMH) are typically lower than those after mobilization and peripheral blood (PB) apheresis; multiple rounds of BMH may be required to obtain adequate cell doses for autologous gene therapy (GT) protocols. As G-CSF can cause life-threatening SCD complications and is contraindicated, plerixafor, a CXCR4 receptor antagonist, may accomplish HSC mobilization without the neutrophil or endothelial activation that elicit vaso-occlusion. We modified the protocol for the HGB-206 phase 1 study of LentiGlobin GT in severe SCD (NCT02140554) to assess HSC mobilization with plerixafor alone, followed by apheresis and transduction of mobilized cells. We also characterized BM-derived and plerixafor-mobilized HSC populations from patients with SCD. Methods HGB-206 is a phase 1 study of LentiGlobin Drug Product (DP), which contains autologous HSCs transduced ex vivo with the betibeglogene darolentivec (BB305) lentiviral vector, in patients with severe SCD (defined as a history of recurrent vaso-occlusive crisis [VOC], acute chest syndrome, stroke, or tricuspid regurgitant jet velocity of >2.5 m/s). Patients in group B receive 240 µg/kg plerixafor followed 4-6 hours later by apheresis, processing ~3 total blood volumes to collect backup HSCs. If < 1.5 x 106 CD34+ cells are collected, patients undergo a second day of apheresis. Cells collected in excess of those required for backup in case of graft failure are transduced with BB305 lentiviral vector for exploratory analyses. Group B patients then proceed to BMH to obtain cells for clinical DP manufacture. Group C will receive DP manufactured from mobilized PB. Mass cytometry (CyTOF) was used to analyze ex vivo cultured CD34+ cells with over 35 cell surface markers. Results To date, 3 patients have undergone plerixafor mobilization. Patients had a transient 1.5- to 3-fold increase in peak white blood cell and absolute neutrophil levels after plerixafor. Peak absolute CD34+ cell counts in PB were 170, 58, and 160 x 106 CD34+ cells/liter. A total of 15.3, 5.6, and 9.0 x 106 CD34+ cells/kg were collected in a single day of apheresis, and no subsequent apheresis or mobilization was required. In the same study, a mean of 5.0 (range 0.3-10.8) x 106 CD34+ cells/kg were collected per BMH (N=21). The mobilization and apheresis procedures had an acceptable toxicity profile. No dose-limiting toxicities were observed after plerixafor dosing. One patient had a single VOC approximately 48 hours after receiving plerixafor; this patient also experienced VOCs of similar severity after BMH. In contrast, after 21 BMHs in 9 patients, 18 ≥ grade 3 AEs were reported in 6 patients, primarily pain. Ex vivo cultured CD34+ cells isolated from BMH consisted of an average of 41.0% (17.3%-50.7%) CD34dim cells, with 16%-50% of the CD34dim cells expressing lymphoid markers. In contrast, ex vivo cultured CD34+ cells isolated from plerixafor mobilized PB contained an average of 8.2% (1.5-19.5%) CD34dim cells. Similar drug product vector copy numbers were obtained after research-scale transduction of CD34+ cells from marrow and PB from the same patient. Conclusion Initial results suggest that obtaining adequate doses of CD34+ cells from plerixafor-mobilized PB of patients with SCD may be safe and feasible, without the life-threatening complications associated with G-CSF, and with fewer, less invasive procedures compared with BMH. PB-derived CD34+ cells may contain lower proportions of lineage-committed CD34+ cells than BM-derived cells from patients with SCD. Cells collected by BMH and PB mobilization/apheresis appear to have an equivalent transduction efficiency. Together these results indicate that it may be possible to use plerixafor-only mobilization in clinical studies of autologous HSC GT in SCD. Results of mobilization, apheresis, and DP manufacturing at clinical scale for additional patients will be available for presentation. Disclosures Pierciey: bluebird bio: Employment. Kanter: American Society of Hematology (Sickle Cell Disease Guideline Panel): Membership on an entity's Board of Directors or advisory committees; AstraZeneca: Membership on an entity's Board of Directors or advisory committees; Novartis: Membership on an entity's Board of Directors or advisory committees, Research Funding; MUSC: Other: The site PI for sponsored research conducted at MUSC who receives funds from: Novartis, bluebird bio, GBT, Sancillo, Apopharma, Pfizer; NHLBI (sickle cell disease research advisory committee): Membership on an entity's Board of Directors or advisory committees, Research Funding; Sancillo: Research Funding; Apopharma: Research Funding; Pfizer: Research Funding; GBT: Research Funding; Bluebird Bio: Membership on an entity's Board of Directors or advisory committees, Research Funding. Kwiatkowski: Novartis: Research Funding; Bluebird Bio: Research Funding; Apopharma: Research Funding; Agios: Consultancy, Honoraria; Ionis: Consultancy, Honoraria. Thompson: Novartis: Consultancy, Research Funding; bluebird bio: Consultancy, Research Funding; Baxalta: Research Funding; Celgene: Consultancy, Research Funding. Shestopalov: bluebird bio: Employment, Equity Ownership. Bonner: bluebird bio: Employment, Equity Ownership. Joseney-Antoine: bluebird bio: Employment, Equity Ownership. Asmal: bluebird bio: Employment, Equity Ownership. Walters: bluebird bio: Research Funding; ViaCord Processing Lab: Other: Medical Director; Sangamo Therapeutics: Consultancy; AllCells, Inc: Other: Medical Director.
Background Granulocyte colony-stimulating factor (G-CSF) is the standard of care for mobilization of hematopoietic stem cells (HSCs). G-CSF requires 4-7 days of injections and often multiple aphereses to acquire sufficient CD34+ cells for transplant. The number of CD34+ HSCs mobilized can be variable and patients who fail to mobilize enough CD34+ cells are treated with the combination of G-CSF plus plerixafor. G-CSF use is associated with bone pain, nausea, headaches, fatigue, rare episodes of splenic rupture, and is contraindicated for patients with autoimmune and sickle cell disease. MGTA-145 (GroβT) is a CXCR2 agonist. MGTA-145, in combination with plerixafor, a CXCR4 inhibitor, has the potential to rapidly and reliably mobilize robust numbers of HSCs with a single dose and same-day apheresis for transplant that is free from G-CSF. MGTA-145 plus plerixafor work synergistically to rapidly mobilize HSCs in both mice and non-human primates (Hoggatt, Cell 2018; Goncalves, Blood 2018). Based on these data, Magenta initiated a Phase 1 dose-escalating study to evaluate the safety, PK and PD of MGTA-145 as a single agent and in combination with plerixafor. Methods This study consists of four parts. In Part A, healthy volunteers were dosed with MGTA-145 (0.0075 - 0.3 mg/kg) or placebo. In Part B, MGTA-145 dose levels from Part A were selected for use in combination with a clinically approved dose of plerixafor. In Part C, a single dose MGTA-145 plus plerixafor will be administered on day 1 and day 2. In Part D, MGTA-145 plus plerixafor will be administered followed by apheresis. Results MGTA-145 monotherapy was well tolerated in all subjects dosed (Table 1) with no significant adverse events. Some subjects experienced mild (Grade 1) transient lower back pain that dissipated within minutes. In the ongoing study, the combination of MGTA-145 with plerixafor was well tolerated, with some donors experiencing Grade 1 and 2 gastrointestinal adverse events commonly observed with plerixafor alone. Pharmacokinetic (PK) exposure and maximum plasma concentrations increased dose proportionally and were not affected by plerixafor (Fig 1A). Monotherapy of MGTA-145 resulted in an immediate increase in neutrophils (Fig 1B) and release of plasma MMP-9 (Fig 1C). Neutrophil mobilization plateaued within 1-hour post MGTA-145 at doses greater than 0.03 mg/kg. This plateau was followed by a rebound of neutrophil mobilization which correlated with re-expression of CXCR2 and presence of MGTA-145 at pharmacologically active levels. Markers of neutrophil activation were relatively unchanged (<2-fold vs baseline). A rapid and statistically significant increase in CD34+ cells occurred @ 0.03 and 0.075 mg/kg of MGTA-145 (p < 0.01) relative to placebo with peak mobilization (Fig 1D) 30 minutes post MGTA-145 (7-fold above baseline @ 0.03 mg/kg). To date, the combination of MGTA-145 plus plerixafor mobilized >20/µl CD34s in 92% (11/12) subjects compared to 50% (2/4) subjects receiving plerixafor alone. Preliminary data show that there was a significant increase in fold change relative to baseline in CD34+ cells (27x vs 13x) and phenotypic CD34+CD90+CD45RA- HSCs (38x vs 22x) mobilized by MGTA-145 with plerixafor. Mobilized CD34+ cells were detectable at 15 minutes with peak mobilization shifted 2 - 4 hours earlier for the combination vs plerixafor alone (4 - 6h vs 8 - 12h). Detailed results of single dose administration of MGTA-145 and plerixafor given on one day as well as also on two sequential days will be presented along with fully characterized graft analysis post apheresis from subjects given MGTA-145 and plerixafor. Conclusions MGTA-145 is safe and well tolerated, as a monotherapy and in combination with plerixafor and induced rapid and robust mobilization of significant numbers of HSCs with a single dose in all subjects to date. Kinetics of CD34+ cell mobilization for the combination was immediate (4x increase vs no change for plerixafor alone @ 15 min) suggesting the mechanism of action of MGTA-145 plus plerixafor is different from plerixafor alone. Preliminary data demonstrate that MGTA-145 when combined with plerixafor results in a significant increase in CD34+ fold change relative to plerixafor alone. Magenta Therapeutics intends to develop MGTA-145 as a first line mobilization product for blood cancers, autoimmune and genetic diseases and plans a Phase 2 study in multiple myeloma and non-Hodgkin lymphoma in 2020. Disclosures DiPersio: Magenta Therapeutics: Equity Ownership; NeoImmune Tech: Research Funding; Cellworks Group, Inc.: Membership on an entity's Board of Directors or advisory committees; Karyopharm Therapeutics: Consultancy; Incyte: Consultancy, Research Funding; RiverVest Venture Partners Arch Oncology: Consultancy, Membership on an entity's Board of Directors or advisory committees; WUGEN: Equity Ownership, Patents & Royalties, Research Funding; Macrogenics: Research Funding, Speakers Bureau; Bioline Rx: Research Funding, Speakers Bureau; Celgene: Consultancy; Amphivena Therapeutics: Consultancy, Research Funding. Hoggatt:Magenta Therapeutics: Consultancy, Equity Ownership, Research Funding. Devine:Kiadis Pharma: Other: Protocol development (via institution); Bristol Myers: Other: Grant for monitoring support & travel support; Magenta Therapeutics: Other: Travel support for advisory board; My employer (National Marrow Donor Program) has equity interest in Magenta. Biernat:Medpace, Inc.: Employment. Howell:Magenta Therapeutics: Employment, Equity Ownership. Schmelmer:Magenta Therapeutics: Employment, Equity Ownership. Neale:Magenta Therapeutics: Employment, Equity Ownership. Boitano:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties. Cooke:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties. Goncalves:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties. Raffel:Magenta Therapeutics: Employment, Equity Ownership. Falahee:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties. Morrow:Magenta Therapeutics: Employment, Equity Ownership, Patents & Royalties. Davis:Magenta Therapeutics: Employment, Equity Ownership.
Abstract Abstract 3224 Poster Board III-161 Background While most centers use 2 × 106 CD34+ cells/kg as the minimal cell dose for autologous hematopoietic stem cell (HSC) transplantation (auto-HSCT), infusion of higher CD34+ cell dose is associated with better outcomes in patients with multiple myeloma (MM) or non-Hodgkin's lymphoma (NHL). Recent evidence suggests a correlation between CD34+ cell yield on Day 1 of collection and total CD34+ cell yield as well as post-transplant outcomes. This analysis was designed to: 1) compare Day 1 collection between patients with NHL or MM mobilized with plerixafor plus G-CSF or placebo plus G-CSF; and 2) determine whether Day 1 CD34+ cell yields correlated with the total mobilization yield and number of apheresis days. Methods Data were obtained from two prospective, randomized, double-blind, placebo-controlled, phase 3 clinical trials that compared the safety and efficacy of plerixafor (0.24 mg/kg/day SQ) plus G-CSF (10 μg/kg/day) with placebo plus G-CSF for mobilization of HSC for auto-HSCT in patients with NHL (3101 Study) or MM (3102 Study). Pearson correlation coefficient was used to evaluate the association of day 1 CD34+ cell collection with total CD34+ cell yield and the number of days of apheresis. Results In the NHL trial, 150 patients were mobilized with plerixafor plus G-CSF and 148 patients underwent mobilization with placebo plus G-CSF. More than half the patients (55.3%) in the plerixafor group collected ≥2 × 106 CD34+ cells/kg on Day 1 of apheresis (Figure 1A). In contrast, 19.6% patients in the placebo group collected ≥ 2 × 106 CD34+ cells/kg on Day 1 of apheresis (p< 0.001). In the MM study, 148 patients were mobilized with plerixafor plus G-CSF and 154 patients were mobilized with placebo plus G-CSF. More than half the patients (52.7%) in the plerixafor group collected ≥6 × 106 CD34+ cells/kg on the first day of collection compared to only 16.9% patients in the placebo group (p<0.001; Figure 1B). There was a strong positive correlation between day 1 collection and the total CD34+ cell yield in patients with NHL (r= 0.86, p-value= <0.0001) or MM (r= 0.87, p-value= <0.0001) in both the plerixafor and placebo groups. For NHL patients, the median Day 1 collection was higher in the plerixafor group compared to the placebo group: 2.66 × 106 vs. 0.77 × 106 CD34+ cells/kg (p<0.001) and this translated into higher total CD34+ cell yields in the two groups respectively: 5.69 × 106 vs. 1.98 × 106 CD34+ cells/kg (p<0.001). Similarly, for MM patients, the median CD34+ cells/kg collected on Day 1 was higher in the plerixafor group compared to the placebo group: 7.01 × 106 vs. 2.29 × 106 CD34+ cells/kg (p<0.001) and this translated into better overall collection in the plerixafor vs. placebo groups: 10.96 × 106 vs. 6.18 × 106 CD34+ cells/kg (p<0.001). A negative correlation was observed between CD34+ cells collected on Day 1 and the number of days of apheresis performed in patients with NHL (r= -0.67, p-value=<0.0001) or MM (r= -0.50, p-value= <0.0001) in both the plerixafor and placebo groups. Consequently, better Day 1 collection in plerixafor-treated NHL or MM patients translated into significantly fewer apheresis days to achieve the target collection compared to placebo treated patients. Conclusions These data support previous reports demonstrating a strong correlation between day 1 CD34+ cell collection and total CD34+ cell yield and apheresis days. These data also demonstrate that addition of plerixafor to G-CSF allows significantly more patients to achieve the target cell collection within 1 day of apheresis compared to G-CSF alone. These findings support the observation that mobilization with plerixafor plus G-CSF reduces the number of apheresis days required to achieve the minimal or optimal cell dose to proceed to transplantation. Disclosures Bolwell: Genzyme Corporation: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding. Nademanee:Genzyme Corporation: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding. Stiff:Genzyme Corp.: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding. Stadtmauer:Genzyme Corporation: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding. Maziarz:Genzyme Corp.: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding. Micallef:Genzyme Corporation: Membership on an entity's Board of Directors or advisory committees, Research Funding. Marulkar:Genzyme Corporation: Employment, Equity Ownership. Gandhi:Genzyme Corporation: Employment, Equity Ownership. DiPersio:Genzyme: Honoraria.
Abstract Introduction There is a strong clinical need to overcome the increased early non relapse mortality (NRM) associated with delayed neutrophil recovery following cord blood transplant (CBT). Therefore we established a methodology using Notch ligand (Delta1) as a strategy for increasing the absolute number of marrow repopulating CB hematopoietic stem/progenitor cells (HSPC). We previously reported preliminary results of the first 10 patients in 2010 demonstrating the ability of Notch-expanded CB HSPC to provide rapid myeloid recovery post-CBT.1 Herein we present the updated results on 23 patients accrued to this trial aimed at assessment of efficacy as well as the feasibility of overnight shipment of the expanded cell product to three outside institutions. Methods Between July 2006 and March 2013, 23 patients with hematologic malignancies were enrolled in this prospective multi-center Phase I trial coordinated by the Fred Hutchinson Cancer Research Center in which one CB unit was ex vivo expanded prior to infusion. Conditioning consisted of Fludarabine (75mg/m2), Cyclophosphamide (120mg/kg) and TBI (13.2 Gy) over 8 days. On day 0, the unmanipulated CB unit was infused first followed 4 hours later by infusion of the freshly harvested expanded CB cells. Graft versus host disease (GVHD) prophylaxis consisted of cyclosporine and MMF beginning on day -3. All CB grafts were 4-6/6 HLA-matched (A/B antigen level, DRB1 allele level) to the recipient. Engraftment, NRM, relapse and GVHD were calculated using cumulative incidence rates to accommodate competing risks. Overall survival was analyzed using Kaplan-Meier estimates. Results Patient diagnosis was AML (n=16), ALL (n=5) and biphenotypic leukemia (n=2). Nine patients (39%) were ≥CR2 and 5 were MRD+ at the time of transplant. Median age was 28 years (range, 4-43) and weight 70 kg (range, 16-91) with a median follow-up of 614 days (range, 271-2443). 22 patients received the expanded graft with one product not meeting release criteria. The cell doses infused were significantly higher in the expanded CB graft: 2.7 (1.5-6.3) vs 6.9 (0.4-27.6) x107 TNC/kg, p<0.0008; 0.15 (0.02-0.57) vs 7.7 (0.62-49.5) x106 CD34/kg, p<0.0001. HLA-matching and ABO incompatibility of the expanded and unmanipulated products were similar. The incidence of neutrophil recovery was 95% (95% CI, 71-100) at a median of 13 days (range, 6-41 days) among the 22 patients receiving expanded CB cells which is significantly faster than that observed in 40 recipients of two unmanipulated units otherwise treated identically at a median time of 25 days (range, 14 to 45; p<0.0001). The incidence of platelet recovery (>20 x 10^9/L) was 77% (CI 95%: 53- 89) by day 100 at a median of 38 days (range, 19 – 134). There was one case of primary graft failure. Importantly, rate of neutrophil recovery correlated with CD34+ cell dose/kg with 8 out of 11 patients receiving greater than 8x106 CD34+cells/kg achieved an ANC ≥ 500/µl within 10 days. 21 patients were evaluable for in vivo persistence of the expanded cells. Ten (48%) demonstrated in vivo persistence beyond one month post infusion. The expanded cell graft was persistent at day 180 in 7 patients, and in those that survived to one year, dominance of the expanded cell graft persisted in one patient. The incidences of grade II-IV and III-IV acute GVHD was 77% (95% CI, 53-89) and 18% (95% CI, 5-36%), respectively; mild chronic GVHD was observed in 4 patients and severe chronic GVHD in one. Probability of OS was 62% (95% CI, 37-79%) at 4 years. Notably, the cumulative incidence of NRM at day 100 was 8% (95% CI, 14-24%) and at 4 years was 32% (95% CI, 8-40%). Nine patients died at a median time of 216 days (range, 31-1578 days) with respiratory failure/infection the most common cause (n=6). There were two relapses at day 156 and 365 post-transplant, with one death due to relapse. Secondary malignancy and primary graft failure were the other 2 causes of death. Conclusions Infusion of Notch-expanded CB progenitors is safe and effective, significantly reducing the time to neutrophil recovery and risks of NRM during the first 100 days. An advantage for infusion of higher numbers of CD34+ cells/kg further demonstrates the need to develop methods that reproducibly provide even greater expansion of repopulating cells than currently achieved to improve efficacy and potentially cost effectiveness. 1. Delaney C, et al, Nat Med. 2010 Feb;16(2):232-6. Disclosures: Delaney: Novartis: DSMB, DSMB Other; Biolife: Membership on an entity’s Board of Directors or advisory committees; medac: Research Funding. Wagner:Novartis: Research Funding; cord use: Membership on an entity’s Board of Directors or advisory committees.
Abstract Background CD47 is over-expressed by many tumor types and protects tumor cells from destruction via tumor-intrinsic and -extrinsic means. The fully human anti-CD47 monoclonal antibody (mAb) SRF231 has previously been shown to block the "don't eat me" CD47/signal regulatory protein alpha (SIRPα) interaction and induce macrophage-mediated phagocytic uptake of CD47-expressing tumor cells, either alone or in the presence of anti-CD20 mAb. Furthermore, SRF231 inhibited tumor growth in preclinical models of aggressive non-Hodgkin lymphoma (Holland P, et al. ASH 2016). Here, we explored the activity of SRF231 against CLL cells for the first time, both as monotherapy and in combination with rituximab or venetoclax (VEN). Methods Peripheral blood mononuclear cells from 24 CLL patients were evaluated for CD47 surface expression by flow cytometry. Primary CLL or Jurkat target cells were treated ex vivo with SRF231 or isotype control and evaluated in phagocytosis and cell death assays. Human monocyte-derived macrophages were cocultured with fluorescently-labeled target tumor cells and exposed to SRF231 and/or rituximab (commercial supply). BH3 profiling was performed by gently permeabilizing primary CLL cells and measuring the release of cytochrome C (Cyto-C) in response to BH3-only peptides by flow cytometry. Priming for apoptosis was measured by Cyto-C release in response to BIM BH3 peptide, and pro-survival protein dependencies were measured by response to specific BH3-only sensitizer peptides. Statistical analyses were by unpaired and paired t-test with a two-tailed nominal p ≤ 0.05 considered as significant. In vivo antitumor activity was assessed using tumor xenograft studies in CB17 SCID mice. Mice with established, subcutaneous Ri-1 tumors were randomized and treated with either isotype control, SRF231, VEN (Medkoo), or combination of SRF231 and VEN. Results CD47 was expressed in all primary CLL cells (n = 24, median mean fluorescence intensity [MFI] 7913, range 3575-18,329) with a slightly higher expression in unmutated CLL (U-CLL) vs mutated CLL (M-CLL) samples (U-CLL median MFI = 9106, n = 8 vs M-CLL, median MFI = 7713, n = 14, 2 unknown, p = 0.047). Primary CLL cells were significantly more susceptible to phagocytosis upon ex vivo treatment with SRF231 in combination with rituximab (median % increase in phagocytosis over isotype control of 32.28% in the combination vs 11.78% with rituximab alone, n = 24, p < 0.0001). Upon coculture of Jurkat cells with macrophages, SRF231 not only induced phagocytosis (EC50, 332 ± 65 ng/mL, n = 3), but also induced cell death of non-phagocytosed target tumor cells (EC50, 295 ± 43 ng/mL, n = 3). While soluble SRF231 did not induce significant target tumor cell killing, immobilized SRF231 induced Jurkat cell and primary CLL cell death (median % alive of 34.6% in SRF231 treated cells vs 64.4% in controls, n = 24, p < 0.0001). To assess the mechanism of cell death induction, tumor cells were pretreated with a pan-caspase inhibitor, Z-VAD-FMK, which revealed that SRF231-mediated tumor cell death is caspase-independent. In primary CLL cells, BH3 profiling confirmed that SRF231 did not alter mitochondrial priming for apoptosis or pro-survival Bcl-2 family protein dependencies. Pre-treatment with the phospholipase C (PLC) inhibitor U73122 prior to SRF231 exposure partially blocked the ability of SRF231 to kill CLL cells (median % alive of 45.4% in pre-treated cells vs 25.4% in controls, n = 6, p = 0.0029). In addition to these in vitro studies, SRF231 displayed profound antitumor activity in a xenograft model of B-cell lymphoma as a single agent, and led to complete and durable tumor regression in combination with VEN. Conclusion Ex vivo treatment of primary CLL cells with SRF231 led to dual antitumor effects of tumor cell-extrinsic plus -intrinsic mechanisms by augmenting rituximab-induced phagocytosis and inducing tumor cell death. SRF231 induced death of tumor cells through a caspase-independent mechanism that depends at least partially on PLC. In vivo, SRF231 in combination with VEN led to complete and durable tumor regression in a xenograft model. SRF231 is currently being evaluated across multiple tumor types in a Phase 1 clinical trial (NCT03512340). Disclosures Valentin: Roche: Other: Travel reimbursement; AbbVie: Other: Travel reimbursement. Peluso:Surface Oncology: Employment, Equity Ownership. Adam:Surface Oncology: Employment, Equity Ownership. Zhang:Surface Oncology: Employment, Equity Ownership. Armet:Surface Oncology: Employment, Equity Ownership. Guerriero:GSK: Research Funding; Eli Lilly: Research Funding. Lee:Surface Oncology: Employment, Equity Ownership. Palombella:Surface Oncology: Employment, Equity Ownership. Holland:Surface Oncology: Employment, Equity Ownership. Paterson:Surface Oncology: Employment, Equity Ownership. Davids:Surface Oncology: Research Funding; Celgene: Consultancy; Verastem: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding; MEI Pharma: Consultancy, Research Funding; Pharmacyclics: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding; Roche/Genentech: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding; BMS: Research Funding; Astra-Zeneca: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding; AbbVie, Inc: Consultancy, Membership on an entity's Board of Directors or advisory committees; Gilead: Membership on an entity's Board of Directors or advisory committees; Merck: Consultancy; TG Therapeutics: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding; Janssen: Consultancy, Membership on an entity's Board of Directors or advisory committees.
Abstract Adoptive transfer of cytolitic Natural Killer (NK) cells is a promising immunotherapeutic modality for hematologic and other malignancies. However, limited NK cell in vivo persistence and proliferation have been challenging clinical success of this therapeutic modality. Here we present a reliable, scalable and GMP-compliant culture method for the expansion of highly functional donor NK cells for clinical use. Nicotinamide (NAM), a form of vitamin B-3, serves as a precursor of nicotinamide adenine dinucleotide (NAD) and is a potent inhibitor of enzymes that require NAD including ADP ribosyltransferases and cyclic ADP ribose/NADase. As such, NAM is implicated in the regulation of cell adhesion, polarity, migration, proliferation, and differentiation. We have previously reported that NAM augments tumor cytotoxicity and cytokine (TNFα and IFN-γ) secretion of NK cells expanded in feeder-free culture conditions stimulated with IL-2 or IL-15. Immunophenotype studies demonstrated NK cells expanded with NAM underwent typical changes observed with cytokine only-induced NK cell activation with no significant differences in the expression of activating and inhibitory receptors. CD200R and PD-1 receptors were expressed at low levels in resting NK cells, but their expression was up-regulated following activation in typical cytokine expansion cultures. Interestingly, the increase in CD200R and PD-1 was reduced by NAM, suggesting these NK cells to be less susceptible to cancer immunoevasion mechanisms (Fig 1). In vivo retention and proliferation is a pre-requisite for the success of NK therapy. We have reported that NK expanded with NAM displayed substantially better retention in the bone marrow, spleen and peripheral blood of irradiated NSG mice. Using a carboxyfluorescein succinimidyl ester (CFSE) dilution assay, we demonstrated increased in vivo proliferation of NAM-cultured NK cells compared with cells cultured without NAM. These results were recently confirmed using a BrdU incorporation assay in irradiated NSG mice (Fig.2). These findings were mechanistically supported by a substantial increase in CD62L (L-selectin) expression in cultures treated with NAM. CD62L is pivotal for NK cell trafficking and homeostatic proliferation and its expression is down regulated in IL-2 or IL-15 stimulated cultures (Fig. 3). These data provided the foundation for the development of a feeder cell-free scalable culture method for clinical therapy using apheresis units obtained from healthy volunteers. CD3+ cells were depleted using a CliniMACS T cell depletion set. Following depletion, the CD3- fraction was analyzed for phenotypic markers and cultured in closed-system flasks (G-Rex100 MCS, Wilson Wolf) supplemented with 20ng/ml IL-15 or 50ng/ml IL-2 GMP, 10% human serum, minimum essential medium-α and NAM USP for two weeks. While at seeding, NK cells comprised 5-20% of total culture seeded cells, at harvest, NK cells comprised more than 97% of the culture. Although overall contamination of the NK cultures was low with either IL-15 or IL-2, a lower fraction of CD3+ and CD19+ cells was observed with IL-15 vs IL-2 (0.2±0.1% vs. 0.4±0.2% and 1.3±0.4% vs. 2.4±0.6%, respectively). Consequently, we decided to use IL-15 for clinical manufacturing. Optimization of NAM concentration studies showed similar expansion with 2.5 and 5 mM and a decrease in expansion with 7.5 mM NAM. Since NAM at 5 mM had a stronger impact on CD62L expression and on the release of IFNγ and TNFα than NAM at 2.5 mM, we selected 5mM NAM for clinical manufacturing. Overall median NK expansion after two weeks in closed G-Rex flasks supplemented with IL-15 and 5mM NAM was 50-fold (range 37-87). An additional and significant increase in expansion was obtained after doubling the culture medium one week post seeding. While there was a marked advantage for single culture feeding, more feedings had less impact on NK expansion and had a negative effect on the in vivo retention potential. Our optimized expansion protocol therefore involved one feeding during the two weeks expansion duration resulting in 162±30.7-fold expansion of NK cells relative to their input number in culture. Based on these data, we have initiated a clinical trial at University of Minnesota, to test the safety and efficacy of escalating doses (2 x 107/kg - 2 x 108/kg) of our novel NAM NK cell product in patients with refractory non-Hodgkins lymphoma and multiple myeloma (NCT03019666). Disclosures Peled: Gamida Cell: Employment, Equity Ownership. Brachya: Gamida Cell: Employment. Persi: Gamida Cell: Employment. Lador: gamida Cell: Employment, Equity Ownership. Olesinski: gamida cell: Employment. Landau: gamida cell: Employment, Equity Ownership. Galamidi: gamida cell: Employment. Peled: Biokine: Consultancy; Biosight: Consultancy. Miller: Celegene: Consultancy; Oxis Biotech: Consultancy; Fate Therapeutics: Consultancy, Research Funding. Bachanova: Oxis: Membership on an entity's Board of Directors or advisory committees, Research Funding; Zymogen: Consultancy, Membership on an entity's Board of Directors or advisory committees; Seattle-Genetics: Consultancy, Membership on an entity's Board of Directors or advisory committees; Novartis Pharmaceuticals Corporation: Membership on an entity's Board of Directors or advisory committees, Research Funding; Juno: Membership on an entity's Board of Directors or advisory committees.
Introduction: Our group has developed a novel vaccine using patient-derived acute myeloid leukemia (AML) cells and autologous dendritic cells (DCs), capable of presenting a broad array of leukemia antigens. In a phase I/II clinical trial DC/AML vaccination led to an expansion of leukemia-specific T cells. We hypothesized that the fusion vaccine offered a unique platform for ex vivo expansion of functionally potent leukemia specific T cells with broad specificity targeting shared and tumor specific neoantigens. We postulated that incorporating 4-1BB (CD137) mediated co-stimulation would further enhance activation of antigen specific T cells and the development of a crucial memory response as well as promote survival and persistence. Here we describe therapeutic exploration of the use of 4-1BB to augment vaccine-educated T cells for adoptive cellular therapy in an immunocompetent murine model. Methods: DC/AML fusion vaccine was generated using DCs obtained from C57BL/6J mice and syngeneic C1498 AML cells as previously described. T cells were obtained from splenocytes after magnetic bead isolation and cultured with irradiated DC/AML fusion vaccine in the presence of IL-15 and IL-7. Following co-culture, 4-1BB positive T cells were ligated using agonistic 4-1BB antibody (3H3 clone, BioXCell) and further selected with RatIgG2a magnetic beads (Easy Sep). Subsequently T cells were expanded with anti-CD3/CD28 activation beads (Dynabeads). In vivo, mice underwent retro-orbital inoculation with C1498 and vaccination with irradiated fusion cells the following day. Agonistic mouse anti-4-1BB antibody was injected intraperitoneally on day 4 and day 7. In addition, C1498 cells were transduced with Mcherry/luciferase and a reproducible model of disease progression was established. Results: DC/fusion stimulated T cells showed increased immune activation as measured by multichannel flow cytometric analysis. Compared to unstimulated T cells, there was 5-fold increase in CD4+CD25+CD69+, and a 10-fold and 7-fold increase in 4-1BB and intracellular IFNƔ expression on CD8+ cells respectively. Following agonistic 4-1BB ligation and bead isolation, the proliferation rate was increased in the 4-1BB positive fraction as compared to both 4-1BB negative cells and unstimulated T cells. In addition, the 4-1BB positive fraction demonstrated increased cytotoxicity, as measured by a CTL assay detecting granzyme B with 1:10 tumor to effector cells. A shift from naïve to memory T cell phenotype was also observed. Following DC/fusion stimulation, CD44+CD62L- cells comprised 67% of CD8+ cells versus 20% without stimulation, the latter reflecting the effect of cytokines alone. Following 4-1BB ligation and anti-CD3/CD28 bead expansion, this phenotype was retained with the CD4+ and CD8+ effector memory and central memory compartments comprising the majority of T cells. Such findings are significant as presence of memory T cell populations are a critical component for successful adoptive cell transfer. The effect of agonistic 4-1BB antibody following vaccination was evaluated in vivo in an aggressive immunocompetent murine AML model. The combination of DC/AML fusion vaccine with 4-1BB antibody was associated with increased long-term survival (>120 days) of 40% versus 20% of mice treated with vaccine alone while all controls required euthanasia by 40 days. Conclusion: In the current study we have demonstrated the ability of DC/AML fusion vaccine to stimulate T cells ex-vivo as demonstrated by both early-activation (CD25,CD69), upregulation of antigen-specific markers (CD137) and cytokine secretion. Further enhancement of the cellular product using agonistic 4-1BB ligation and isolation simultaneously enriches for antigen-activated cells, as demonstrated by more potent cytotoxicity, as well as promoting memory phenotype and survival. Use of 4-1BB ligation for antigen-specific selection while providing an agonistic co-stimulatory signal is a potentially novel approach for development of non-engineered T cells. Ongoing experiments evaluating the efficacy of 4-1BB selected vaccine educated T cells using bioluminescence monitoring will be reported as well as in vitro use of patient-derived T cells. Disclosures Kufe: Canbas: Consultancy, Honoraria; Victa BioTherapeutics: Consultancy, Equity Ownership, Honoraria, Membership on an entity's Board of Directors or advisory committees; Genus Oncology: Equity Ownership; Hillstream BioPharma: Equity Ownership; Reata Pharmaceuticals: Consultancy, Equity Ownership, Honoraria; Nanogen Therapeutics: Equity Ownership, Membership on an entity's Board of Directors or advisory committees. Rosenblatt:Dava Oncology: Other: Education; Partner Tx: Other: Advisory Board; Parexel: Consultancy; Celgene: Research Funding; BMS: Research Funding; Amgen: Other: Advisory Board; Merck: Other: Advisory Board; BMS: Other: Advisory Board ; Imaging Endpoint: Consultancy. Avigan:Takeda: Consultancy; Parexel: Consultancy; Celgene: Membership on an entity's Board of Directors or advisory committees, Research Funding; Pharmacyclics: Research Funding; Juno: Membership on an entity's Board of Directors or advisory committees; Partners Tx: Membership on an entity's Board of Directors or advisory committees; Partner Tx: Membership on an entity's Board of Directors or advisory committees; Karyopharm: Membership on an entity's Board of Directors or advisory committees; Bristol-Myers Squibb: Membership on an entity's Board of Directors or advisory committees; Janssen: Consultancy.
Abstract Background Transfusion-dependent β-thalassemia (TDT) is a severe genetic disease caused by impaired β-globin production, leading to severe anemia, lifelong transfusion dependence with iron overload and serious comorbidities. Gene therapy (GT) offers a potentially transformative option for these patients. LentiGlobin GT contains autologous CD34+ hematopoietic stem cells (HSCs) transduced ex vivo with the BB305 lentiviral vector (LVV) encoding β-globin with a T87Q substitution. The safety and efficacy of LentiGlobin in patients with TDT was assessed in the phase 1/2 Northstar study in which 8/10 patients with non-β0/β0 genotypes and 3/8 patients with a β0/β0 genotype stopped transfusions. A refined manufacturing process to improve drug product (DP) characteristics is being evaluated in the studies presented here. Methods Northstar-2 (HGB-207; NCT02906202) and Northstar-3 (HGB-212; NCT03207009) are ongoing, international, single-arm, phase 3 studies in patients with TDT (≥ 100 mL/kg/yr of red blood cells [RBCs] or ≥ 8 RBC transfusions/yr) and non-β0/β0 genotypes or a β0/β0 genotype, respectively. HSCs were collected by apheresis after G-CSF and plerixafor mobilization. CD34+ HSCs were transduced with the BB305 LVV using a refined manufacturing process. Patients received single-agent, myeloablative busulfan conditioning and transduced cells were infused. The primary endpoint in Northstar-2 is the proportion of patients achieving transfusion independence (TI, weighted average hemoglobin [Hb] ≥ 9g/dL without RBC transfusions for ≥ 12 months continuously) and in Northstar-3 is the proportion of patients achieving transfusion reduction (≥ 60% reduction in transfused RBC volume post-DP infusion compared to pre-DP infusion). Patients were evaluated for engraftment, DP and peripheral blood vector copy number (VCN), GT-derived Hb (HbAT87Q), adverse events (AEs), vector integration, and evidence of replication competent lentivirus (RCL). Patients are followed for 2 years and offered participation in a long-term follow-up study. Results Eleven patients (median age 20 [min - max: 12 - 24] years) with TDT and non-β0/β0 genotypes (5 β+/β0, 4 βE/β0, 2 β+/β+) have been treated in Northstar-2 as of May 15, 2018 with a median follow-up of 8.5 (min - max: 0.3 - 16.2) months. DPs had a median cell dose of 7.4 x 106 (min - max: 5.0 - 19.4 x 106) CD34+ cells/kg, median VCN of 3.4 (min - max: 2.4 - 5.6) copies/diploid genome (c/dg) and a median of 82% (min - max: 53 - 90%) CD34+ cells were transduced. Median time to neutrophil and platelet engraftment was 21.5 (min - max: 16 - 28) and 44.5 (min - max: 34 - 84) days, respectively, in 10 patients; 1 patient was not yet evaluable. Serious AEs after DP infusion included 2 events of grade 4 liver veno-occlusive disease treated with defibrotide and 1 event each of hypotension, hypoxia, sepsis, and transfusion reaction, all resolved. Only 1 AE (grade 1 abdominal pain) was related to LentiGlobin. There were no deaths or graft failure and no evidence of vector-mediated RCL or clonal dominance. Of 8 patients with ≥ 6 months follow-up, 7 have stopped RBC transfusions. At last study visit, peripheral blood VCN was 1.1 - 5.0 c/dg and total Hb was 11.1 - 13.3 g/dL of which 7.6 - 10.2 g/dL (68 - 92%) was contributed by HbAT87Q. Median Hb at month 6 was 11.9 (min - max: 11.2 - 13.3) g/dL. The first treated patient achieved TI. The additional patient with ≥ 6 months follow-up had no transfusions for 11 months, however had a peripheral blood VCN of 0.2 c/dg and resumed transfusions due to symptomatic anemia. Bone marrow assessment of dyserythropoesis and data with longer follow-up will be presented. Two patients, 26- and 7- years old, have been treated in Northstar-3. Both had 2 DP lots manufactured with DP VCNs of 2.9/3.3 and 3.4/3.9 c/dg and 82%/85% and 78%/78% CD34+ cells were transduced, respectively. Both successfully engrafted. Additional data for these patients will be presented. Summary Seven of 8 patients with TDT and non-β0/β0 genotypes produced sufficient HbAT87Q to stop chronic transfusions following LentiGlobin GT in Northstar-2. The safety profile appears consistent with busulfan myeloablative conditioning with no grade ≥ 3 DP-related AEs. Initial results show DP characteristics in Northstar-3 are consistent with those in Northstar-2. Additional data from Northstar-3 will determine the impact of HbAT87Q production on transfusion reduction in patients without endogenous β-globin production. Disclosures Locatelli: bluebird bio: Consultancy; Novartis: Consultancy, Membership on an entity's Board of Directors or advisory committees; Miltenyi: Honoraria; Bellicum: Consultancy, Membership on an entity's Board of Directors or advisory committees; Amgen: Honoraria, Membership on an entity's Board of Directors or advisory committees. Walters:AllCells Inc.: Other: Medical Director; ViaCord Processing Lab: Other: Medical Director; bluebird bio: Research Funding; Sangamo Therapeutics: Consultancy. Kwiatkowski:Terumo: Research Funding; Apopharma: Research Funding; Novartis: Research Funding; Agios Pharmaceuticals: Consultancy, Research Funding; bluebird bio: Consultancy, Honoraria, Research Funding. Porter:Agios: Honoraria; Cerus: Honoraria; Novartis: Consultancy. Thuret:Addmedica: Research Funding; bluebird bio: Research Funding; Novartis: Research Funding. Kulozik:bluebird bio: Consultancy, Honoraria. Lal:Terumo Corporation: Research Funding; Celgene Corporation: Research Funding; Insight Magnetics: Research Funding; Bluebird Bio: Research Funding; La Jolla Pharmaceutical Company: Consultancy, Research Funding; Novartis: Research Funding. Thrasher:Orchard Therapeutics: Consultancy, Equity Ownership; Generation Bio: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Rocket Pharmaceuticals: Consultancy, Membership on an entity's Board of Directors or advisory committees. Elliot:bluebird bio: Employment, Equity Ownership. Tao:bluebird bio: Employment, Equity Ownership. Asmal:bluebird bio: Employment, Equity Ownership. Thompson:Amgen: Research Funding; Baxalta/Shire: Research Funding; La Jolla Pharmaceutical: Research Funding; Novartis: Research Funding; bluebird bio: Consultancy, Research Funding; Celgene: Research Funding; Biomarin: Research Funding.
Abstract Background: Interferon-alpha (IFNα) is a pleiotrophic cytokine with direct anti-tumor and immunostimulatory effects. Currently IFNα is approved for the treatment of multiple hematologic malignancies, including non-Hodgkin lymphoma (NHL). However, its clinical utility has been hindered by dose-limiting toxicitiy due to systemic activation of the interferon receptor. To overcome this limitation, we engineered anti-tumor antibody-IFNα fusion proteins to selectively increase delivery of IFN to the tumor site and reduce systemic toxicity. We previously reported that IGN002, an anti-CD20-IFNα fusion protein, exhibits enhanced complement-dependent cytotoxicity (CDC) compared to rituximab, and inhibits proliferation and induces apoptosis of human B-cell NHL (Yamada et al, ASCO 2013). We now extend these previous findings and show that IGN002 possesses enhanced antibody-dependent cell-mediated cytotoxicity (ADCC) effector function and superior in vivo anti-tumor activity against B-cell NHL, compared to rituximab. Methods: IGN002 was evaluated against a panel of human Burkitt and diffuse large B-cell lymphoma (DLBCL) cell lines. Proliferation was measured by [3 H]-thymidine incorporation, STAT1 activation by flow cytometry, ADCC by lactate dehydrogenase release using human PBMC effectors, and IFN bioactivity by encephalomyocarditis (EMC) viral protection assay. NHL xenografts were grown in SCID mice. Results: IGN002 more potently inhibited the growth of NHL cell lines expressing CD20 than rituximab or unfused IFNα. Intrinsic IFNα activity of IGN002 was reduced in viral protection and anti-proliferation assays using cells lacking CD20 expression. STAT1 activation by IGN002 was enhanced on cells expressing the target antigen, whereas a control antibody-IFNα fusion protein showed reduced STAT activation activity compared to unfused IFNα. Together, these results indicate that fusion of IFNα to the antibody results in reduced IFN effects on cells not bearing the tumor antigen target. IGN002 exhibited enhanced ADCC activity compared to rituximab against Daudi, Ramos, and Raji NHL cells in long-term (overnight incubation) assays, demonstrating both higher potency and higher maximal cytotoxicity. This result is possibly due to activation of the effector cell populations by the fused IFNα moiety, as IFN is known to activate both NK cells and monocytes. The in vivo anti-tumor efficacy of IGN002 was compared to rituximab and a control antibody-IFNα fusion protein against 10-day established Raji NHL xenografts. IGN002 was superior to both rituximab and the control fusion protein, achieving a longer median survival and higher long-term survival rate (p = 0.0015 and < 0.0001 vs. rituximab and control fusion protein, respectively). The in vivo anti-tumor efficacy of IGN002 was also compared to rituximab at three equimolar dose levels (5 mg/kg, 1 mg/kg, and 0.2 mg/kg antibody) against 10-day established Daudi NHL xenografts. IGN002 showed superior efficacy compared to rituximab at all doses (p < 0.001), achieving tumor eradication (100% long-term survival) in all mice treated at all three dose levels, whereas rituximab only delayed tumor progression. Conclusions: IGN002 demonstrated more robust direct anti-proliferative and antibody effector functions than rituximab against human NHL cells in vitro, and also showed the ability to eradicate established NHL xenografts in vivo. Against cells expressing the CD20 target antigen, IGN002 exhibited greater anti-proliferative potency than unfused IFNα. In contrast, the anti-proliferative and anti-viral potency of IGN002 was reduced against cells lacking CD20, compared to unfused IFNα. These findings support the hypothesis that tumor antigen-targeted IFN therapeutics may possess a broader therapeutic index than unfused IFNα, inhibiting tumor growth by multiple mechanisms while reducing systemic toxicity. These results support the further development of IGN002 for the treatment of B-cell NHL, and a first-in-human phase I clinical study will begin later this year in the United States. Disclosures Timmerman: Janssen: Research Funding; Bristol-Myers Squibb: Honoraria, Research Funding; Valor Biotherapeutics: Research Funding. Steward:ImmunGene, Inc.: Employment. Minning:Valor Biotherapeutics, LLC: Consultancy. Sachdev:ImmunGene, Inc.: Employment, Equity Ownership, Membership on an entity's Board of Directors or advisory committees. Gresser:ImmunGene, Inc.: Employment, Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Valor Biotherapeutics: Membership on an entity's Board of Directors or advisory committees. Khare:Valor Biotherapeutics: Membership on an entity's Board of Directors or advisory committees; ImmunGene, Inc.: Employment, Equity Ownership, Membership on an entity's Board of Directors or advisory committees. Morrison:ImmunGene, Inc.: Membership on an entity's Board of Directors or advisory committees, Research Funding.
Abstract Several promising new, targeted agents are being developed for the treatment of AML. The BH3 mimetic venetoclax (ABT-199) is a specific inhibitor of BCL2, with results from a phase 2 study showing transient activity of venetoclax in relapsed/refractory AML (Konopleva et al, 2014). The bone marrow (BM) microenvironment is known to protect AML cells from drug therapy and we showed earlier that conditioned medium (CM) from BM stromal cells applied to AML patient cells conferred resistance to venetoclax, which could be reversed by the addition of the JAK1/2 inhibitor ruxolitinib (Karjalainen et al, 2015). Here, we investigated the mechanisms mediating the BM stromal cell induced resistance to venetoclax and its reversal by ruxolitinib. To identify the soluble factor(s) contributing to stroma-induced protection of BCL2 inhibition, we analyzed the cytokine content of 1) CM from the human BM stromal cell line HS-5, 2) CM from BM mesenchymal stromal cells (MSCs) isolated from AML patients, 3) supernatants from BM aspirates collected from AML patients, and 4) supernatants from BM aspirates collected from healthy donors. Although expression levels varied, the cytokines detected were similar among the different samples. In HS-5 CM, IL-6, IL-8 and MIP-3α were among the most abundant cytokines. In addition, gene expression analysis showed the receptors for these cytokines were expressed in AML patient samples. IL-6, IL-8 and MIP-3α were added individually to mononuclear cells collected from AML patients, which were then treated with venetoclax. However, none of the cytokines alone could mimic the reduced sensitivity to venetoclax conferred by the HS-5 CM suggesting that stromal cell induced cytoprotection is likely multi-factorial. Next we tested the effect of AML-derived BM MSCs on the ex vivo response of AML patient samples (n=8) to ruxolitinib or venetoclax alone or in combination in a co-culture setting. Apoptosis assays showed negligible effects of ruxolitinib at a concentration of 300 nM, while venetoclax at a dose of 100 nM induced reduction in the percentage of CD34+ AML cells. Co-treatment with venetoclax and ruxolitinib demonstrated synergistic effects in 6 out of 8 samples and significantly reduced the number of CD34+ AML cells. Mechanistic studies showed that ruxolitinib treatment inhibited the BM stromal medium-induced expression of BCL-XL mRNA on AML cells and the drugs in combination down-regulated BCL2, MCL1 and BCL-XL protein expression, which was in correlation with sensitivity to the drugs. To further evaluate the ability of the venetoclax and ruxolitinib combination to eradicate leukemic cells in vivo we used an orthotopic xenograft model of AML. NSG mice were injected with genetically engineered MOLM-13luc cells and after engraftment treated with venetoclax (25 mg/kg, i.p.), ruxolitinib (50 mg/kg BID, p.o) or both and imaged once per week for 4 weeks. At the end of the treatment period bioluminescent imaging showed significantly reduced leukemia burden in the ruxolitinib and venetoclax co-treated mice compared to controls demonstrating superior anti-tumor efficacy than either agent alone (Figure 1). In summary, our data demonstrate that the combined blockade of JAK/STAT and BCL2 pathways with ruxolitinib and ventoclax is synergistic in ex vivo co-culture models and in vivo in an AML mouse model. The addition of ruxolitinib was able to overcome intrinsic resistance to venetoclax by reducing expression of MCL1, a known escape mechanism of BCL2 inhibition. These results support further clinical investigation of this combination, particularly for relapsed/refractory AML. Disclosures Porkka: Novartis: Honoraria, Research Funding; Pfizer: Honoraria, Research Funding; Bristol-Myers Squibb: Honoraria, Research Funding. Wennerberg:Pfizer: Research Funding. Gjertsen:BerGenBio AS: Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Boehringer Ingelheim: Membership on an entity's Board of Directors or advisory committees; Kinn Therapeutics AS: Equity Ownership. Heckman:Celgene: Research Funding; Pfizer: Research Funding.
