Stephanie Mgebroff

remission rate was 93% in patients who received a CAR T-cell product and 100% in the subset of patients who received fludarabine and cyclophosphamide lymphodepletion. Twenty-three percent of patients developed reversible severe cytokine release syndrome and/or reversible severe neurotoxicity. These data demonstrate that manufacturing a defined-composition CD19 CAR T cell identifies an optimal cell dose with highly potent antitumor activity and a tolerable adverse effect profile in a cohort of patients with an otherwise poor prognosis. This trial was registered at www.clinicaltrials.gov as #NCT02028455.

Tumor-induced T-cell tolerance is a major mechanism that facilitates tumor progression and limits the efficacy of immune therapeutic interventions. Regulatory T cells (Treg) play a central role in the induction of tolerance to tumor antigens, yet the precise mechanisms regulating its induction in vivo remain to be elucidated. Using the A20 B-cell lymphoma model, here we identify myeloid-derived suppressor cells (MDSC) as the tolerogenic antigen presenting cells capable of antigen uptake and presentation to tumor-specific Tregs. MDSC-mediated Treg induction requires arginase but is transforming growth factor-beta independent. In vitro and in vivo inhibition of MDSC function, respectively, with NOHA or sildenafil abrogates Treg proliferation and tumor-induced tolerance in antigen-specific T cells. These findings establish a role for MDSCs in antigen-specific tolerance induction through preferential antigen uptake mediating the recruitment and expansion of Tregs. Furthermore, therapeutic interventions, such as in vivo phosphodiesterase 5-inhibition, which effectively abrogate the immunosuppressive role of MDSCs and reduce Treg numbers, may play a critical role in delaying and/or reversing tolerance induction.

Abstract Purpose: The identification and vetting of cell surface tumor-restricted epitopes for chimeric antigen receptor (CAR)–redirected T-cell immunotherapy is the subject of intensive investigation. We have focused on CD171 (L1-CAM), an abundant cell surface molecule on neuroblastomas and, specifically, on the glycosylation-dependent tumor-specific epitope recognized by the CE7 monoclonal antibody. Experimental Design: CD171 expression was assessed by IHC using CE7 mAb in tumor microarrays of primary, metastatic, and recurrent neuroblastoma, as well as human and rhesus macaque tissue arrays. The safety of targeting the CE7 epitope of CD171 with CE7-CAR T cells was evaluated in a preclinical rhesus macaque trial on the basis of CD171 homology and CE7 cross reactivity. The feasibility of generating bioactive CAR T cells from heavily pretreated pediatric patients with recurrent/refractory disease was assessed. Results: CD171 is uniformly and abundantly expressed by neuroblastoma tumor specimens obtained at diagnoses and relapse independent of patient clinical risk group. CD171 expression in normal tissues is similar in humans and rhesus macaques. Infusion of up to 1 × 108/kg CE7-CAR+ CTLs in rhesus macaques revealed no signs of specific on-target off-tumor toxicity. Manufacturing of lentivirally transduced CD4+ and CD8+ CE7-CAR T-cell products under GMP was successful in 4 out of 5 consecutively enrolled neuroblastoma patients in a phase I study. All four CE7-CAR T-cell products demonstrated in vitro and in vivo antitumor activity. Conclusions: Our preclinical assessment of the CE7 epitope on CD171 supports its utility and safety as a CAR T-cell target for neuroblastoma immunotherapy. Clin Cancer Res; 23(2); 466–77. ©2016 AACR.

BACKGROUND: The first step in the production of chimeric antigen receptor T cells is the collection of autologous T cells using apheresis technology. The procedure is technically challenging, because patients often have low leukocyte counts and are heavily pretreated with multiple lines of chemotherapy, marrow transplantation, and/or radiotherapy. Here, we report our experience of collecting T lymphocytes for chimeric antigen receptor T-cell manufacturing in pediatric and young adult patients with leukemia, non-Hodgkin lymphoma, or neuroblastoma. STUDY DESIGN AND METHODS: total mononuclear cells per kilogram. Data were collected regarding preapheresis and postapheresis blood counts, apheresis parameters, products, and adverse events. RESULTS: Ninety-nine patients (ages 1.3-25.7 years) and 102 apheresis events were available for analysis. Patients underwent apheresis at a variety of absolute lymphocyte cell counts, with a median absolute lymphocyte count of 944 cells/μL (range, 142-6944 cells/μL). Twenty-two patients (21.6%) had absolute lymphocyte counts less than 500 cells/μL. The mononuclear cell target was obtained in 100% of all apheresis harvests, and chimeric antigen receptor T-cell production was possible from the majority of collections (94%). Mononuclear cell collection efficiency was 65.4%, and T-lymphocyte collection efficiency was 83.4%. Ten patients (9.8%) presented with minor adverse events during the 102 apheresis procedures, with one exception of a severe allergy. CONCLUSIONS: Mononuclear cell apheresis for chimeric antigen receptor T-cell therapy is well tolerated and safe, and it is possible to obtain an adequate quantity of CD3+ lymphocytes for chimeric antigen receptor T-cell manufacturing in heavily pretreated patients who have low lymphocyte counts.

Abstract Introduction: Advances in chimeric antigen receptor (CAR) T cell therapy have yielded complete remission (CR) rates in relapsed/refractory B-ALL (rrB-ALL) of 70-95%. However, disease recurrence after CD19 or CD22 CAR therapy is greater than 50% at 1 year, and approximately half of recurrences are due to antigen escape. To reduce antigen escape and optimize the durability of remission, we sought to design a CAR T cell product with dual specificity that is capable of simultaneously targeting both CD19 and CD22. Preclinical testing of our bi-specific CAR showed a preference for signaling through CD22 over the CD19 CAR. In contrast, dual transduced T cells signaled through both the CD19 and CD22 CAR with lytic activity and cytokine production similar to single transduced CAR T cells of the same specificity. Therefore, we opted to move forward with dual transduced T cells for clinical use. We are currently testing SCRI-CAR19x22v1 in PLAT-05 (NCT03330691), a phase 1 clinical trial for pediatric and young adult patients with CD19+CD22+ rrB-ALL, with the primary objectives to determine the feasibility of manufacturing products with dual specificity, to assess the safety of the cryopreserved product infusion, and to describe the full toxicity profile. Methods: Subjects undergo apheresis, after which the CD4 and CD8 T cell subsets are immunomagnetically selected and seeded at a prescribed ratio for co-culture in a closed-system G-Rex bioreactor. Following anti-CD3xCD28 bead stimulation, T cells are transduced with two separate SIN lentiviral vectors that direct the expression of a CD19-specific FMC63scFv:IgG4hinge:CD28tm:4-1BB:ζ CAR with an Her2tG tag and expression of a CD22-specific m971scFv:IgG4hinge:CH2(L235D)-CH3:CD28tm:4-1BB:ζ CAR with an EGFRt tag, creating three distinct populations of CAR T cells (anti-CD19, anti-CD22, and anti-CD19x 22). Transduced cells are expanded in serum free media formulation with IL-7, IL-15, and IL-21. Following lymphodepleting chemotherapy, cryopreserved products are thawed and infused at the protocol-prescribed dose level. Cytokine release syndrome (CRS) is graded according to Lee et al. (Blood 2014) and is treated according to our early intervention strategy of tocilizumab and dexamethasone for persistent, mild CRS. Results: Seven subjects (ages 1-26 yr) with rrB-ALL have been enrolled with 4 treated at dose level 1 (1 x 106 CAR T cells/kg) and 3 treated at dose level 2 (3 x 106 CAR T cells/kg). The mean culture time was 7.9 days (range 7-11) and subjects received infusions with a mean CD8:CD4 ratio of 1.7 (range 0.2 - 3.1). CD8 CAR composition, on average, consisted of 21.6 % CD19 CAR, 37.8 % CD22 CAR, and 40.6 % CD22xCD19 CAR T cells. CD4 CAR composition, on average, consisted of 25.8 % CD19 CAR, 30.6 % CD22 CAR, and 43.6 % CD22xCD19 CAR T cells (Figure). Peak engraftment occurred between days 7 and 14 for all patients and was predominantly composed of the CD19 CAR population with median peak values for CD19 CAR, CD22 CAR, and CD19xCD22 CAR T cell populations of 9.1%, 1.2%, and 2.4%, respectively. A CR was achieved in 5/7 (71%) subjects by day 21, 4 of which were minimal residual disease negative. The two subjects without a CR did not exhibit evidence of CAR T cell engraftment; one had previously received CD19 CAR T cells, and the other had progressive disease and pursued alternative therapy at day 10. Therapy was well tolerated with no dose limiting toxicities. CRS occurred in 5 subjects (Grade 1) with 2 of these subjects experiencing mild neurotoxicity (Grade 1). Four subjects received tocilizumab +/- dexamethasone, and two of these received multiple doses of dexamethasone. Conclusions: Preclinical testing showed superior efficacy against both CD19 and CD22 when using two separate CARs and dual transduction, compared to a single bi-specific CAR. Preliminary analysis of PLAT-05 supports feasibility of product manufacturing, and toxicity and response rates that are consistent with the reported CD19 CAR T cell experience. While the infused SCRI-CAR19x22v1 products consist of a near-uniform distribution of the 3 distinct populations, we observed selective in vivo expansion of the CD19 CAR T cell population. Further investigation is required to understand the mechanism of CD19 CAR dominance in vivo. Continued accrual of subjects is ongoing to further assess the impact of dual antigen targeting on the prevention of antigen escape and the potential to provide a more durable remission. Figure. Figure. Disclosures Park: Bristol-Myers Squibb: Membership on an entity's Board of Directors or advisory committees. Jensen:Juno Therapeutics, Inc.: Consultancy, Patents & Royalties, Research Funding.