ALBERT

Description: Neurologic toxicity has been observed with anti-CD19 chimeric antigen receptor (CAR) T cells and the anti-CD19 BiTE blinatumomab. Both focal (e.g., cranial nerve palsy) and global (e.g., generalized seizures) abnormalities have been reported, often associated with systemic cytokine release syndrome (CRS) but also observed after recovery from or in absence of CRS. CART-BCMA consists of expanded autologous T cells transduced with a 4-1BB:CD3-zeta-based CAR specific for B Cell Maturation Antigen. Here, we report clinical features and management of a severe neurotoxicity observed on a phase 1 trial of CART-BCMA for multiple myeloma (MM) (NCT02546167). The subject is a 55-year-old female with high-risk IgA lambda MM. At time of CART-BCMA infusion, her MM manifestations included cytopenias and plasmacytomas of the pleura and paravertebral muscles. Bone marrow (BM) was 〉95% BCMA+ plasma cells. Pre-treatment brain MRI showed pachymeningeal thickening and enhancement over the left cerebral convexity, possibly due to extension of calvarial MM lesions. There was no evidence of CNS MM on a neurologist's exam or by CSF cytology. The subject received 2x108 CART-BCMA cells, 40% of the planned dose, over two consecutive days, without lymphodepleting chemotherapy; a third planned infusion was held due to fevers. Over the next 4 days, fevers persisted, hypoxia and delirium developed, and cytopenias worsened. Brain MRI and lumbar puncture on day 4 showed no new abnormalities. Evaluation for infection was negative. These symptoms coincided with rise in serum IL-6 (nl range

Description: Background: Though CD19 is expressed only rarely on multiple myeloma (MM) plasma cells (PC), rare CD19+ B cells can be identified in MM patients that are clonally related to the MM PC. These clonotypic B cells may exhibit properties of cancer stem cells (enhanced MM-propagating properties and drug resistance compared to MM PC) and thus be a potential therapeutic target in conjunction with therapies that target MM PC. CTL019 consists of autologous T cells transduced via lentiviral vector with an anti-CD19 scFv coupled to CD3-zeta and 4-1BB signaling domains and expanded ex vivo with anti-CD3/CD28-conjugated beads. To target both clonotypic B cells and MM PC, we conducted a pilot clinical trial of CTL019 administered after high-dose melphalan and autologous stem cell transplantation (ASCT) in relapsed/refractory MM patients who had previously undergone first-line ASCT with short progression-free survival (PFS). Methods: Subjects were required to be medically fit for ASCT and have progressed within 1 year of a prior ASCT performed as part of first-line therapy. Study therapy consisted of ASCT with melphalan 140-200 mg/m2 followed by 1-5x107 CTL019 cells 12-14 days later. The primary endpoint was safety and feasibility of CTL019 manufacturing and administration in this clinical setting. Secondary endpoints included assessments of CTL019 in vivo persistence and activity against normal B cells, plasma cell immunophenotype as a response biomarker, and PFS after ASCT + CTL019 in comparison to PFS after initial ASCT. Results: Twelve subjects enrolled, and 10 received study therapy; autologous T cells failed to expand ex vivo in one enrolled subject, and one enrolled subject elected to pursue off-study therapy. Median age was 61 (range 48-68). Median prior lines of therapy was 6 (range 2-10). Poor-prognosis features were present in 8/10 subjects (6/10 with poor-prognosis cytogenetics, 2/10 with BRAF V600E mutations, 1/10 with secondary plasma cell leukemia). Median PFS after first-line ASCT was 258 days (range 100-342). In pre-ASCT bone marrow (BM), the dominant MM PC population was CD19-negative by flow cytometry in 9/9 evaluable subjects, though 7/9 exhibited rare CD19+ subsets comprising 0.05-1.5% of MM PC. Melphalan dose was 140 (N=7) or 200 (N=3) mg/m2. All subjects infused received the maximum target dose of 5x107 CTL019 cells. Adverse events (AE) consisted mostly of expected ASCT toxicities. Grade ³3 AE that were at least possibly related to CTL019 included grade 3 autologous GVHD (N=1, resolved with corticosteroids) and oral mucositis (N=1). Grade 1 cytokine release syndrome occurred in 1 subject. There was no ASCT-related mortality. After infusion, CTL019 cells were detectable in peripheral blood (PB) of all subjects and persisted for median of 44 days (range 14-156). Presence of PB CTL019 cells was associated with absence of PB B cells. Notably, CTL019 cells were detected in BM in 9/10 subjects at day 42 and/or 100 post-ASCT. Median PFS after ASCT + CTL019 was 185 days (range 42-479); all subjects have progressed. The peak BM CTL019 frequency correlated significantly with favorable PFS (SpearmanÕs rho=0.77, P=0.009). There was no association between PFS and peak frequency of CTL019 or duration of CTL019 persistence in PB. In 3/10 subjects, PFS after ASCT + CTL019 met or exceeded PFS after first-line ASCT (Figure). For comparison, in a historical cohort of 18 patients who received first-line and salvage ASCT at our institution since 2008, no patients exhibited longer PFS after salvage ASCT. Conclusion: CTL019 manufacturing and administration post-ASCT is safe and feasible in patients with advanced MM. Correlation of PFS with CTL019 frequency in BM and prolonged PFS in 3 subjects is suggestive of clinical efficacy. A phase-two study of CTL019 using a 10-fold higher dose after first-line ASCT in high-risk MM patients is ongoing. Figure. Figure. Disclosures Garfall: Medimmune: Consultancy; Bioinvent: Research Funding; Novartis: Consultancy, Research Funding. Stadtmauer:Novartis: Consultancy; Takada: Consultancy; Janssen: Consultancy; Amgen: Consultancy; Teva: Consultancy; Celgene: Consultancy. Maus:Novartis: Patents & Royalties: related to CTL019, Research Funding. Hwang:Novartis: Research Funding. Vogl:Takeda: Consultancy, Research Funding; GSK: Research Funding; Calithera: Research Funding; Teva: Consultancy; Constellation: Research Funding; Celgene: Consultancy; Acetylon: Research Funding; Karyopharm: Consultancy. Cohen:Bristol-Meyers Squibb: Consultancy, Research Funding; Janssen: Consultancy. Weiss:Novartis: Consultancy. Porter:Genentech: Employment; Novartis: Patents & Royalties, Research Funding. Frey:Novartis: Research Funding; Amgen: Consultancy. Milone:Novartis: Patents & Royalties, Research Funding. Mangan:Novartis: Speakers Bureau. Lacey:Novartis: Research Funding. Melenhorst:Novartis: Patents & Royalties: Novartis, Research Funding. Ambrose:Novartis: Research Funding. Chen:Novartis: Research Funding. Kulikovskaya:Novartis: Research Funding. Levine:Novartis: Patents & Royalties, Research Funding; GE Healthcare Bio-Sciences: Consultancy. June:Johnson & Johnson: Honoraria; Tmunity Therapeutics: Equity Ownership; Novartis: Honoraria, Patents & Royalties, Research Funding; Immune Design: Consultancy, Equity Ownership; Celldex: Consultancy, Equity Ownership; Novartis: Honoraria, Patents & Royalties, Research Funding; Pfizer: Honoraria.

Description: Background Despite recent therapeutic advances, multiple myeloma (MM) remains primarily an incurable cancer. Patients experiencing rapid recovery of T cells post autologous stem cell transplant (auto-SCT) may have improved outcomes, and spontaneous cellular responses to tumor can occur, suggesting immune mediated control of tumor is possible. We and others have investigated therapeutic cancer vaccines that have shown promise in pilot studies, in particular following post-transplant infusion of activated autologous T cells. However, efficacy of these approaches may be limited by thymic selection which restricts the repertoire of T cell receptors (TCRs) to low affinity TCRs that cannot recognize the low level of antigen present on most tumor cells. We hypothesized that incorporation of affinity-enhanced tumor antigen-specific TCRs into autologous T cells infused post-transplant would overcome this limitation and improve response rates in the post auto-SCT setting. Methods We report interim results of a Phase II clinical trial (NCT01352286) to evaluate the safety and activity of autologous T cells genetically engineered to express an affinity-enhanced TCR that recognizes the NY-ESO-1/LAGE-1 peptide complex HLA‐A*0201‐SLLMWITQC; these cells are infused in the setting of profound lymphodepletion that accompanies high dose chemotherapy administered during auto-SCT. Patients with high risk or relapsed MM, who are HLA‐A*0201 positive, and whose tumor is positive for NY-ESO-1 and/or LAGE-1 by RT-PCR are eligible. CD25 depleted CD4 and CD8 T cells are activated and expanded using anti-CD3/CD28 antibody conjugated microbeads, and genetically modified with a lentiviral vector containing the TCR construct at a multiplicity of infection of 1. Engineered T cells are administered four days after high dose melphalan and two days following auto-SCT, at a dose range of 1-10 billion total cells with a minimum gene modification requirement of 10%. Patients are evaluated for MM responses in accordance with the IMWG criteria at 6 weeks, and 3 and 6 months post infusion. At 3 months, patients start lenalidomide maintenance. The initial 6 patient phase is complete and a 20 patient extension phase is ongoing. Results Prior to enrollment on study, patients had received a median of 3 prior therapies including 6 with prior transplant. 50% of tumors contained high risk chromosomal abnormalities, and NY-ESO-1 expression is correlated with adverse prognosis. 20 patients (average age of 57) have been infused with an average of 2.3 X 109 engineered T cells (range 4.5 X 108-3.9 X 109); this reflects an average clinical scale transduction efficiency of 34% (range 18% – 49%). Infusions have been well tolerated, and the majority of adverse events were related to the high dose melphalan. Possibly related SAEs were neutropenia and thrombocytopenia, and GI and metabolism disorders including diarrhea, colitis, hyponatremia and hypomagnesemia. 10, 4, 2, and 2 patients have reached the 1 year, 9 month, 6 month and 3 month assessment timepoints, respectively, and 17/20 patients are alive. Best response by day 100 is sCR/CR in 2/15 (13%), nCR in 10/15 (67%), and PR in 3/15% (20%), which compares favorably to historic responses in patients undergoing first or second transplant. Engineered T cells expanded and persisted in blood and marrow at 180 days by Q-PCR and flow-cytometry in all but one case (Figure). 7 patients progressed after day 100, which was accompanied either by loss of engineered T cells or loss of tumor antigen. Detailed phenotyping and functional analysis of engineered T cells, and correlates with clinical responses, is underway. Summary This is the first clinical evaluation of engineered T cells in the MM setting. Infusions are safe, well tolerated, and are associated with encouraging responses in a high risk myeloma population. A study evaluating the engineered T cells in a non-transplant study is underway. Disclosures: Stadtmauer: Celgene: Consultancy. Binder-Scholl:Adaptimmune: Employment. Smethurst:Adaptimmune: Employment. Brewer:Adaptimmune: Employment. Bennett:Adaptimmune: Employment. Gerry:Adaptimmune: Employment. Pumphrey:Adaptimmune: Employment. Tayton-Martin:Adaptimmune: Employment. Ribeiro:Adaptimmune: Employment. Levine:Novartis: cell and gene therapy IP, cell and gene therapy IP Patents & Royalties. Jakobsen:Adaptimmune: Employment. Kalos:Novartis corporation: CART19 technology, CART19 technology Patents & Royalties; Adaptive biotechnologies: Member scientific advisory board , Member scientific advisory board Other. June:Novartis: Patents & Royalties, Research Funding.

Description: Abstract 755 Background: Adoptive transfer of T cells genetically engineered to express affinity-enhanced T cell receptors (TcRs) specific for self-antigens is one approach to generate potent anti-tumor immunity, and this approach is being evaluated in a number of clinical trials. Although persistence of engineered T cells is positively correlated with response rates, a recurring observation to-date has been poor T cell persistence beyond the initial treatment window. We have recently initiated a Phase II clinical trial (NCT01352286) in patients with recurrent multiple myeloma (MM), to evaluate the safety and activity of autologous T cells genetically engineered to express an HLA-A201 restricted, affinity-enhanced TCR that targets an epitope shared by the NY-ESO-1 and LAGE-1 cancer testis antigens commonly expressed by MM. Clinical study details and outcomes are reported elsewhere in this meeting (Rapoport, A, Stadtmauer, E. et al.). Here we report the in vivo expansion, bioactivity, trafficking, durable persistence, and anti-tumor activity of TcR modified cells in this trial. Methods: Subjects received high-dose melphalan, infusion of autologous hematopoietic stem cells on day 0, and infusion of gene engineered cells (GEC) on day +2. Persistence of GEC was assessed by quantitative ABI-Taqman based PCR and a qualified assay that detects the lentivirus backbone sequence. Surface expression of the introduced affinity-enhanced TcR α/β receptor was detected by multiparametric flow cytometry and TcR-specific dextramer™reagents. NY-ESO-1 and LAGE-1 antigen expression in marrow samples was assessed by quantitative ABI-taqman based PCR and inventoried primer/probe sets. Results: As of August 2012, we have screened marrow from 46 patients for NY-ESO- and LAGE-1 expression. Of these, 29 (63%) and 17 (37%) expressed LAGE-1 and NY-ESO-1, respectively by PCR. LAGE-1 co-expression was observed in all cases with NY-ESO-1. To date 12 patients have been infused with GEC. Robust engraftment was observed, with peak levels of gene-marked cells in peripheral blood and marrow ranging from 1 × 102-1 × 103 cells/μL and peak levels detected within the first 21 days post infusion. By day +100 the absolute number of GEC showed patient-specific and variable contraction, with a subset of patients maintaining GEC at 1 × 102-1 × 103 cells/μL, and a second subset where GEC contracted to 1 × 101-1 × 102cells/μL. Trafficking to and persistence of GEC in marrow was observed. At both early (up to day +30) and, in a subset of patients, late timepoints (post day+42), circulating CD3+ T cells could be detected with surface expression of the affinity enhanced TcR. Engineered cells are detected in all patients at their latest timepoint by Q-PCR. To date we see no evidence for TCR mispairing with endogenous TCR. Tumor-antigen and tumor-specific targeting by GEC was evaluated using Q-PCR and quantifying transcript levels of NY-ESO-1, LAGE-1, and CD138 (as a plasma cell marker) in marrow biopsies at enrollment, and days +42, +100, and +180. In the initial cohort of 5 patients, selective reappearance of CD138 transcript is observed in 4 cases (2 sCR, 1 VGPR, 1 PR), with non-detectable or very weak expression of LAGE-1/NY-ESO-1 transcripts, suggesting specific targeting of tumor cells that express LAGE-1/NY-ESO-1. In the fifth patient, who has progressive disease and low engineered cell persistence, CD138 and LAGE-1/NY-ESO-1 transcripts are both present above pre-treatment levels. A second infusion was recently given to this patient. Summary: Our studies show for the first time that adoptive transfer of affinity-enhanced TCR engineered T cells in MM patients results in prolonged T cell persistence, homing to marrow, and anti-tumor activity. Disclosures: Binder-Scholl: Adaptimmune: Employment. Smethurst:Adaptimmune Ltd: Employment. Brewer:Adaptimmune Ltd: Employment. Bennett:Adaptimmune Ltd: Employment. Gerry:Adaptimmune Ltd: Employment. Pumphrey:Adaptimmune Ltd: Employment. Tayton-Martin:Adaptimmune Ltd: Employment. Levine:TxCell: Consultancy, Membership on an entity's Board of Directors or advisory committees; University of Pennsylvania: financial interest due to intellectual property and patents in the field of cell and gene therapy. Conflict of interest is managed in accordance with University of Pennsylvania policy and oversight, financial interest due to intellectual property and patents in the field of cell and gene therapy. Conflict of interest is managed in accordance with University of Pennsylvania policy and oversight Patents & Royalties. Jakobsen:Adaptimmune Ltc: Employment. June:Novartis: Research Funding, entitled to receive royalties from patents licensed to Novartis, entitled to receive royalties from patents licensed to Novartis Patents & Royalties.

Description: Background : BCMA is expressed on MM cells, and CAR T cells targeting BCMA have pre-clinical anti-MM activity. CART-BCMA is an autologous T cell product engineered by lentiviral transduction to express a fully human BCMA-specific CAR with CD3ζ and 4-1BB signaling domains, and then expanded ex vivo using CD3/CD28 beads. Methods: In this ongoing, 3+3 dose-escalation study, relapsed/refractory MM patients (pts) receive CART-BCMA cells as split-dose infusions (10% on day 0, 30% on day 1, and 60% on day 2). Three cohorts are planned: 1) 1-5 x 108 CART cells alone; 2) cyclophosphamide (CTX) 1.5 g/m2 + 1-5 x 107 CART cells; and 3) CTX 1.5 g/m2 + 1-5 x 108 CART cells. Pts need serum creatinine (Cr)

Description: Background Recent advances in T cell engineering have enabled clinical trials to evaluate the potential for adoptive transfer of T cells to target malignancy. A single treatment with engineered gene-modified T cells has the potential to generate potent and long-lasting anti-tumor immunity. We have reported initial clinical data on the use of T cells engineered to express a Chimeric Antigen Receptor (CAR) that targets CD19 (CTL019) in patients with advanced treatment-refractory CLL and pediatric ALL (Porter, et al NEJM 2011; Kalos et al. Sci Trans Med 2011, Grupp et al. NEJM 2013). The initial cohort of patients is now disease free between 1 and 3 years post-infusion. In this report we present data on the functional persistence, trafficking, and bioactivity of CTL019 cells from the initial cohort of CLL patients, a larger and more recently treated cohort of CLL patients, a cohort of pediatric ALL patients, as well as an initial cohort of adult ALL patients. Methods CAR engineering of patient T cells was accomplished by lentivirus transduction followed by in-vitro expansion using anti-CD3 and anti-CD28 antibody-coated beads. Persistence of gene-modified T cells was assessed by quantitative PCR. CAR19 surface expression was detected by flow. B cell aplasia was evaluated by multiparametric flow cytometry. Multiplex cytokine analyses were performed using LuminexTMtechnology. Results Detailed clinical outcomes for each patient cohort will be reported separately at this meeting (Porter, D.L.et al, Grupp S. et al). In summary, as of July 15, 2013: For CLL: A total of 24 adult patients with advanced relapsed and/or treatment-refractory CLL have been treated under two separate protocols. To date 5 patients have achieved ongoing CR, 7 patients PR and 12 patients were NR at the primary endpoint (within 3 months post infusion). For ALL (pediatric): A total of 14 pediatric patients with treatment refractory ALL have been treated and were evaluable under a single protocol. To date 8 patients have ongoing CR, 4 patients have relapsed including 2 with CD19-negative disease and 2 patients were NR. For ALL (Adult): A total of 3 adult patients with advanced relapsed and/or treatment-refractory ALL have been treated under a single protocol. All 3 patients have ongoing CR; one patient went into an allogeneic transplant while in CTL019-induced CR. In all patients with CR, robust in vivo expansion of CTL019 cells was observed, as assessed by both molecular and flow cytometric analysis, followed by contraction and in all but one patient ongoing stable persistence of engineered cells, elimination of tumor B cells and ongoing B cell aplasia in blood and marrow at all evaluated time points (minimum 3 months, maximum ongoing at 35 months). In CR patients, peak marking exceeded 5% of total CD3+. Patients with PR demonstrated less robust in-vivo expansion accompanied by transient B cell elimination, while NR patients demonstrated minimal in-vivo expansion. Clinical MRD analysis in patients was supplemented with Illumina-HiSeq/MiSeq-deep sequencing based molecular MRD analysis. These analyses demonstrate that CRs were accompanied with deep and sustained molecular remissions as assessed by the absence of the tumor specific clonotype defined in the enrollment samples. All patients in CR experienced on-target cytokine release syndrome (CRS) and macrophage activation syndrome (MAS). Multiplex-cytokine analysis of serum samples from patients in CR demonstrated a broad pro-inflammatory signature with significant elevation in a subset of soluble immune modulators including IFN-g, IL-6, and IL2ra. In contrast, patients with NR did not have elevated serum cytokines. Elevation of cytokines coincided with expansion of CTL019 cells, elimination of B cells, and toxicity suggesting the potential for a cytokine-based diagnostic signature to monitor CTL019 treatment efficacy. Conclusions Adoptive transfer of CTL019 cells engineered to express CD137 and TCR-zeta signaling domains can result in in-vivo expansion, homing to marrow, and long-term functional persistence of engineered cells, accompanied by ongoing complete clinical responses and long-term B cell aplasia in a substantial fraction of patients with advanced, refractory and high risk CLL and relapsed refractory pre- B cell ALL. These results highlight the potential of CTL019 therapy to effectively target CD19-positive malignancy. Disclosures: Kalos: Novartis corporation: CART19 technology, CART19 technology Patents & Royalties; Adaptive biotechnologies: Member scientific advisory board , Member scientific advisory board Other. Zheng:Novartis: Patents & Royalties. Levine:Novartis: cell and gene therapy IP, cell and gene therapy IP Patents & Royalties. Grupp:Novartis: Research Funding. June:Novartis: Patents & Royalties, Research Funding.

Description: We recently demonstrated that sustained remission in 41 CLL patients treated with the CD19-specific, 4-1BB/CD3zeta-signaling chimeric antigen receptor (CAR19) T-cells correlated strongly with the expansion and persistence of the engineered T cells and that important pathways such as T cell exhaustion, glycolysis and T cell differentiation segregated responders from non-responders (Fraietta et al., 2018, Nature Medicine). We here report two advanced, chemotherapy-resistant CLL patients with the longest (7 years) follow-up on any trial of CART19 cells. Both patients had received five therapies before being treated at the University of Pennsylvania with autologous, murine CTL019 (tisagenlecleucel) cells for their CLL in 2010, receiving 1.1e9 and 1.4e7 CAR19+ T cells, respectively. Both patients have persistence of CAR-engineered T cells and both patients are still in remission as determined by flow cytometry and deep sequencing of IgH rearrangements for 5.5-7 years. Thus, the infused CAR-T cells have maintained these patients in deep molecular remission of their disease for the longest period of time that has been reported to date. To understand the fate of the infused CAR-T cells we determined the phenotype, function, and clonal nature of the persisting CTL019 cells. Flow cytometric CART19 cell analyses demonstrated that early during the anti-leukemia response, activated, HLA-DR-expressing CD8+ CAR-T cells rapidly expanded, followed by similarly activated CD4+ CAR-T cells. With tumor clearance the CAR-T cell population contracted, but an activated CD4+ CAR-T cell population was maintained and was still detectable at the last follow-up of 7 years. The CD8+ CAR-T cell pool remained present at low frequencies. Both populations had acquired and maintained an effector memory phenotype, a phenotype most consistent with active disease control. Furthermore, the analysis of the classical immune checkpoint inhibitory markers PD1, TIM3, LAG3, and CTLA4 showed that only PD1 was expressed from the earliest to the latest time point on 〉80% of all CAR-T cells, whereas LAG3 and TIM3 were expressed only early on but lost after tumor clearance. These data suggest that the initial tumor clearance was mediated by CD8+ CAR-T cells, but sustained by a CD4+ CAR-T cell population that still actively engages with target cells. To understand the clonal nature of these long-term persisting CAR-T cells we used two complementary methods: a) CAR T cells were sorted from post-infusion aliquots during the first two years for T cell receptor-beta deep-sequencing (TCR-seq); b) the CAR integration sites in the genome were sequenced in the infusion product and in circulating CAR-T cells. TCR-seq analysis of early post-infusion time points demonstrated that the circulating CAR-T cell populations consisted of hundreds to thousands of distinct clones which in patient 1 and 2 displayed clonal focusing by 21 and 1 month post-infusion, respectively, with some clones making up as much as 12% (patient 1) and 48% (patient 2) of the CAR-T cell repertoire. The analysis of clonotype sharing at the various time points via Morisita's overlap index analysis similarly showed repertoire stabilization late (21 months; patient 1) and early (1 month; patient 2) after infusion. Lastly, fate mapping of the infused CART19 cells via CAR integration site analysis in the infusion product until the latest time point indicated that the infusion products for both patients had a very diverse, non-clonal make-up, containing over 8,000 and 3,700 integration sites in patients 1 and 2, respectively. The higher degree of clonality in patient 2 but not 1 CAR-T cells as seen by TCR-seq was confirmed by integration site analysis, as was the sharing of CAR-T cell clones over time. Importantly, whereas the CAR integration site repertoire in patient 1 was diverse in the first two years, it stabilized and trended towards oligoclonality 21 months after infusion. Lastly, CAR integration site analysis revealed a high degree of clonal persistence, suggesting that tumor control and B cell aplasia were maintained by few, highly functional CD4+ CAR-T cell clones. In summary, we demonstrate that in both patients with the longest persistence of CAR-T cells reported thus far, early and late phases of the anti-CLL response are dominated by highly activated CD8+ and CD4+ CAR-T cells, respectively, largely comprised of a small number of persisting CD4+ CAR-T cell clones. Disclosures Melenhorst: Parker Institute for Cancer Immunotherapy: Research Funding; Incyte: Research Funding; Casi Pharmaceuticals: Consultancy; novartis: Patents & Royalties, Research Funding; Shanghai UNICAR Therapy, Inc: Consultancy. Porter:Genentech: Other: Spouse employment; Novartis: Other: Advisory board, Patents & Royalties, Research Funding; Kite Pharma: Other: Advisory board. Lacey:Novartis Pharmaceuticals Corporation: Research Funding; Tmunity: Research Funding; Novartis Pharmaceuticals Corporation: Patents & Royalties; Parker Foundation: Research Funding. Fraietta:Novartis: Patents & Royalties: WO/2015/157252, WO/2016/164580, WO/2017/049166. Frey:Novartis: Consultancy; Servier Consultancy: Consultancy. Young:Novartis: Patents & Royalties, Research Funding. Siegel:Novartis: Research Funding. June:Novartis Pharmaceutical Corporation: Patents & Royalties, Research Funding; Immune Design: Membership on an entity's Board of Directors or advisory committees; Tmunity Therapeutics: Equity Ownership, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding; Immune Design: Membership on an entity's Board of Directors or advisory committees; Celldex: Consultancy, Membership on an entity's Board of Directors or advisory committees; Novartis Pharmaceutical Corporation: Patents & Royalties, Research Funding; Tmunity Therapeutics: Equity Ownership, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding.