scholarly journals Ligand Based CAR T-Cell Targeting BAFF Receptors Asa Novel Therapy for B Cell Malignancies

Blood ◽  
2020 ◽  
Vol 136 (Supplement 1) ◽  
pp. 31-32
Author(s):  
Reshmi Parameswaran ◽  
Derek Wong ◽  
Keman Zhang ◽  
Abhishek Asthana ◽  
Marcos de Lima ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cells ◽  
B Cell ◽  
Research Funding ◽  
Advisory Board ◽  
B Cell Malignancies ◽  
Car T Cells ◽  
Car T

Background: Autologous T cells engineered to express chimeric antigen receptors (CARs) targeting CD19 have shown rapid and durable responses in B cell malignancies. Although CD19 CAR-T cells have demonstrated remarkable success, CD19-negative relapses occur in 30-45% of patients, highlighting the need for adoptive immunotherapies with alternative targeting approaches. B-cell activating factor (BAFF) is a critical B cell survival factor. Receptors of BAFF (BAFF-R, TACI and BCMA) are expressed by a wide range of B cell neoplasms, including ALL, CLL, NHL and MM, making them attractive therapeutic targets. We developed a novel ligand-based CAR that when expressed in T cells, targets and eliminates malignant B cells expressing BAFF receptors (BAFF CAR-T). This approach has several potential advantages over CD19 targeting CAR-T therapy: CD19 is expressed on all B cells, but BAFF receptors are expressed only on mature B cells, making it a more specific antigen for targeting and potentially narrowing down the side effect profile. BAFF CAR-T cells are a potential therapeutic strategy to treat CD19 CAR-T relapsed patients as well as chemotherapy resistant patients. Methods: BAFF ligand was fused to a second generation CAR backbone containing 4-1BB costimulatory and CD3ζ intracellular signaling domains. T cells were isolated from human blood, activated and transduced with BAFF-CAR lentiviral particles. In vitro tumor cell killing was analyzed using calcein-AM cytotoxicity assay. For in vivo testing of BAFF CAR-T cytotoxicity, we used mantle cell lymphoma (MCL) Jeko-1 xenograft model. Immunocompromised NSG mice were subcutaneously injected with human MCL cell line Jeko-1 (10.106 cells at day 0). Once these mice developed measurable tumors, we injected T cells transduced with empty vector (control T cells) or BAFF-CAR T cells (10 x 106 cells) or PBS intra-tumorally as a one-time injection. Tumor volumes were measured every other day using calipers. Results: BAFF CAR-T cells showed significant cytotoxicity in vitro (not shown) and in vivo against human MCL cell line Jeko-1. Mice treated with BAFF-CAR-T showed significant reduction in tumor volume compared to mice treated with control T cells and PBS (Figure 1A, B). Tumor progression was observed after control T cell and PBS treatment, whereas the cohort treated with BAFF CAR-T did not show any tumor progression, and with complete or near-complete tumor eradication. Survival analysis showed the BAFF CAR-T treated cohort had significantly longer survival compared to control-T cell and PBS treated cohorts (Figure 1C). Mice were sacrificed when tumor volume reached 2 cm3. Conclusion: Our data suggest that targeting BAFF receptors with a novel, ligand-based BAFF-CAR-T is a feasible and effective immunotherapeutic strategy to eliminate malignant B cells, warranting further development. BAFF-CAR-T cells have therapeutic potential against a wide spectrum of B cell malignancies, including CD19 negative relapsed disease. Clinical grade expansion and clinical trials are in development for BAFF CAR-T therapy non Hodgkin lymphoma patients. Disclosures Parameswaran: Luminary Therapeutics: Consultancy; Luminary therapeutics: Research Funding. de Lima:Kadmon: Other: Personal Fees, Advisory board; BMS: Other: Personal Fees, advisory board; Incyte: Other: Personal Fees, advisory board; Celgene: Research Funding; Pfizer: Other: Personal fees, advisory board, Research Funding. Caimi:Amgen: Other: Advisory Board; Bayer: Other: Advisory Board; Verastem: Other: Advisory Board; Kite pharmaceuticals: Other: Advisory Board; ADC therapeutics: Other: Advisory Board, Research Funding; Celgene: Speakers Bureau.

Clinical Responses In Patients Infused With T Lymphocytes Redirected To Target κ-Light Immunoglobulin Chain

Blood ◽  
2013 ◽  
Vol 122 (21) ◽  
pp. 506-506 ◽  
Author(s):  
Carlos A. Ramos ◽  
Barbara Savoldo ◽  
Enli Liu ◽  
Adrian P. Gee ◽  
Zhuyong Mei ◽  
...  
Keyword(s):  
Multiple Myeloma ◽  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Light Chain ◽  
Stable Disease ◽  
Research Funding ◽  
B Cell Malignancies ◽  
Car T Cells ◽  
Car T

Abstract Adoptive transfer of T cells with a CD19-specific chimeric antigen receptor (CAR) to treat B-cell malignancies shows remarkable clinical efficacy. However, long-term persistence of T cells targeting CD19, a pan-B cell marker, causes sustained depletion of normal B cells and consequent severe hypogammaglobulinemia. In order to target B-cell malignancies more selectively, we exploited the clonal restriction of mature B-cell malignancies, which express either a κ or a λ-light immunoglobulin (Ig) chain. We generated a CAR specific for κ-light chain (CAR.κ) to selectively target κ+ lymphoma/leukemia cells, while sparing the normal B cells expressing the reciprocal λ-light chain, thus minimizing the impairment of humoral immunity. After preclinical validation, we designed a phase I clinical trial in which patients with refractory/relapsed κ+ non-Hodgkin lymphoma (NHL) or chronic lymphocytic leukemia (CLL) are infused with autologous T cells expressing a CAR.κ that includes a CD28 costimulatory domain. The protocol also included patients with multiple myeloma with the aim of targeting putative myeloma initiating cells. Three dose levels (DL) are being assessed, with escalation determined by a continual reassessment method: 0.2 (DL1), 1 (DL2) and 2 (DL3) ×108 T cells/m2. Repeat infusions are allowed if there is at least stable disease after treatment. End points being evaluated include safety, persistence of CAR+T cells and antitumor activity. T cells were generated for 13 patients by activating autologous PBMC with immobilized OKT3 (n=5) or CD3/CD28 monoclonal antibodies (n=8). In 2 patients with >95% circulating leukemic cells, CD3 positive selection was performed using CliniMACS. After transduction, T cells (1.2×107±0.5×107) were expanded ex vivo for 18±4 days in the presence of interleukin (IL)-2 to reach sufficient numbers for dose escalation. CAR expression was 81%±13% by flow cytometry (74,112±23,000 transgene copy numbers/mg DNA). Products were composed predominantly of CD8+ cells (78%±10%), with a small proportion of naïve (5±4%) and memory T cells (17%±12%). CAR+ T cells specifically targeted κ+ tumors as assessed by 51Cr release assays (specific lysis 79%±10%, 20:1 E:T ratio) but not κ–tumors (11%±7%) or the NK-sensitive cell line K562 (26%±13%). Ten patients have been treated: 2 on DL1, 3 on DL2 and 5 on DL3. Any other treatments were discontinued at least 4 weeks prior to T-cell infusion. Patients with an absolute leukocyte count >500/µL received 12.5 mg/kg cyclophosphamide 4 days before T-cell infusion to induce mild lymphopenia. Infusions were well tolerated, without side effects. Persistence of infused T cells was assessed in blood by CAR.κ-specific Q-PCR assay and peaked 1 to 2 weeks post infusion, remaining detectable for 6 weeks to 9 months. Although the CAR contained a murine single-chain variable fragment (scFv), we did not detect human anti-mouse antibodies following treatment and CAR.κ+T cell expansion continued to be observed even after repeated infusions. We detected modest (<20 fold) elevation of proinflammatory cytokines, including IL-6, at the time of peak expansion of T cells, but systemic inflammatory response syndrome (cytokine storm) was absent. No new-onset hypogammaglobulinemia was observed. All 10 patients are currently evaluable for clinical response. Of the patients with relapsed NHL, 2/5 entered complete remission (after 2 and 3 infusions at dose level 1 and 3, respectively), 1/5 had a partial response and 2 progressed; 3/3 patients with multiple myeloma have had stable disease for 2, 8 and 11 months, associated with up to 38% reduction in their paraprotein; and 2/2 patients with CLL progressed before or shortly after the 6-week evaluation. In conclusion, our data indicate that infusion of CAR.κ+ T cells is safe at every DL and can be effective in patients with κ+ lymphoproliferative disorders. Disclosures: Savoldo: Celgene: Patents & Royalties, Research Funding. Rooney:Celgene: Patents & Royalties, Research Funding. Heslop:Celgene: Patents & Royalties, Research Funding. Brenner:Celgene: Patents & Royalties, Research Funding. Dotti:Celgene: Patents & Royalties, Research Funding.

Therapy of B Cell Malignancies with CD19-Specific Chimeric Antigen Receptor-Modified T Cells of Defined Subset Composition

Blood ◽  
2014 ◽  
Vol 124 (21) ◽  
pp. 384-384 ◽  
Author(s):  
Cameron J Turtle ◽  
Daniel Sommermeyer ◽  
Carolina Berger ◽  
Michael Hudecek ◽  
David M Shank ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Cd4 T Cells ◽  
Research Funding ◽  
T Cell Subsets ◽  
B Cell Malignancies ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T

Abstract BACKGROUND: The adoptive transfer of CD19-specific chimeric antigen receptor-modified (CD19 CAR) T cells is a promising strategy for treating patients with CD19+ B cell acute lymphoblastic leukemia (ALL), chronic lymphocytic leukemia (CLL), and non-Hodgkin lymphoma (NHL). Dramatic responses have been observed in a subset of patients receiving CD19 CAR T cell therapy, and prior studies suggest that persistence of transferred T cells may correlate with the extent of tumor regression. The use of unselected T cells to prepare CAR T cells results in variation in the phenotypic composition of the infused product in individual patients, making it difficult to determine whether particular T cell subsets contribute to efficacy and/or toxicity. Studies in our lab demonstrated that genetically modified effector T cells derived from purified T cell subsets differ in the capacity to persist in vivo after adoptive transfer, and that a combination of CAR-modified CD8+ central memory (TCM) and CD4+ T cells provides optimal antitumor activity in tumor xenograft models. Based on these data, we designed the first clinical trial in which patients with CD19+ B cell malignancies receive CD19 CAR T cells comprised of a defined composition of CD8+ TCM and CD4+T cells engineered to express a CD19 CAR. METHODS: Patients with relapsed or refractory CD19+ ALL, CLL or NHL are eligible for this phase I/II study. CD8+ TCM and CD4+ T cells were separately enriched by immunomagnetic selection from a leukapheresis product from each patient, and cryopreserved. The CD8+ TCM and CD4+ T cells were stimulated in independent cultures with anti-CD3/anti-CD28 paramagnetic beads, and transduced with a lentivirus encoding the murine FMC63 anti-CD19 scFv, 4-1BB and CD3 zeta signaling domains. After in vitro expansion, the cell product for infusion was formulated in a 1:1 ratio of CD4+:CD8+ CAR+ T cells. A truncated non-functional human epidermal growth factor receptor (EGFRt) encoded in the transgene cassette allowed identification of transgene-expressing T cells by flow cytometry. Lymphodepleting chemotherapy was administered followed by infusion of EGFRt+ CAR T cells at one of three dose levels (2 x 105 EGFRt+ cells/kg, 2 x 106 EGFRt+ cells/kg, 2 x 107 EGFRt+cells/kg). RESULTS: Twenty patients with relapsed or refractory ALL (n = 9), NHL (n = 10) or CLL (n = 1), including those who failed prior autologous (n = 4) or allogeneic (n = 4) stem cell transplant have been treated on the trial. Fifteen of 20 treated patients received a product that conformed to the prescribed CD8+ T­CM:CD4 composition. Five patients received a product manufactured using a modified strategy either due to low blood lymphocyte counts (n = 3) or due to failure to propagate T cells in culture (n = 2). CD8+ TCM and CD4+ T cells have been isolated from 12 additional patients and cryopreserved for therapy. Patients have been treated at all three dose levels without acute infusional toxicity. Severe cytokine release syndrome (sCRS) consisting of fever, hypotension, and reversible neurotoxicity associated with elevated serum IFN-γ and IL-6 was only observed in ALL patients with a high tumor burden. One ALL patient treated at the highest cell dose died of complications associated with sCRS. None of the NHL patients had sCRS. Of patients who are >6 weeks after CD19 CAR T cell therapy, best responses included complete (n=1) or partial (n=5) remission in 6/9 patients with NHL and complete remission in 5/7 patients with ALL. Both CD4+ and CD8+ CAR-T cells expanded in vivo and could be detected in blood, marrow and CSF. The peak level and duration of persistence of both CD4+ and CD8+ EGFRt+ T cells were associated with clinical response. TCRBV gene sequencing of flow sorted CD4+ and CD8+ EGFRt+CAR T cells from 2 patients showed that proliferating CAR T cells were polyclonal. A subset of NHL patients in whom CAR T cells became undetectable developed a T cell immune response to sequences in the murine CD19-specific scFv component of the CAR transgene. CONCLUSION: Adoptive immunotherapy with CD19 CAR T cells of defined subset composition is feasible and safe in a majority of heavily pretreated patients with refractory B cell malignancies and has potent anti-tumor activity. Persistence of CAR-T cells may be limited in some patients by transgene product immunogenicity. Data from this ongoing clinical trial will be updated at the meeting. Disclosures Turtle: Juno Therapeutics: Research Funding. Berger:Juno Therapeutics: Patents & Royalties. Hudecek:Juno Therapeutics: Patents & Royalties. Jensen:Juno: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding. Riddell:Juno Therapeutics: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding. Maloney:Juno Therapeutics: Research Funding.

Donor-Derived Anti-CD19 Chimeric-Antigen-Receptor-Expressing T Cells Cause Regression Of Malignancy Persisting After Allogeneic Hematopoietic Stem Cell Transplantation

Blood ◽  
2013 ◽  
Vol 122 (21) ◽  
pp. 151-151 ◽  
Author(s):  
James N Kochenderfer ◽  
Mark E. Dudley ◽  
Robert O. Carpenter ◽  
Sadik H Kassim ◽  
Jeremy J. Rose ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cells ◽  
B Cell ◽  
B Cell Malignancies ◽  
Hematopoietic Stem ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
Grade 3

Abstract Progressive malignancy is a leading cause of death in patients undergoing allogeneic hematopoietic stem cell transplantation (alloHSCT). To improve treatment of B-cell malignancies that persist despite alloHSCT, we conducted a clinical trial of allogeneic T cells genetically modified to express a chimeric antigen receptor (CAR) targeting the B-cell antigen CD19. Ten patients were treated on this trial. Four patients were recipients of human-leukocyte-antigen (HLA)-matched unrelated donor (URD) transplants and 6 patients were recipients of HLA-matched sibling transplants. T cells for genetic modification were obtained from each patient’s healthy alloHSCT donor. Patients received a single infusion of anti-CD19-CAR T cells. Cell doses ranged from 1x106 to 10x106 T cells/kg. A mean of 58% of the infused cells expressed the CAR. Patients did not receive chemotherapy or other anti-malignancy therapy with the CAR-T-cell infusions, so the responses observed in these patients are not confounded by the effects of chemotherapy. In contrast to other reports of successful treatment of B-cell malignancies with anti-CD19-CAR T cells, the patients on this study were not lymphocyte-depleted at the time of the CAR-T-cell infusions. Two patients with chronic lymphocytic leukemia (CLL) refractory to standard unmanipulated allogeneic donor lymphocyte infusions (DLIs) had regressions of large malignant lymph node masses after infusion of allogeneic anti-CD19-CAR T cells. One of these CLL patients obtained a complete remission that is ongoing 9 months after treatment with allogeneic anti-CD19-CAR T cells. This patient also had complete eradication of blood B cells within 9 days after her CAR-T-cell infusion. Another patient had tumor lysis syndrome requiring rasburicase treatment as his CLL dramatically regressed in lymph nodes, bone marrow, and blood within 2 weeks of his anti-CD19-CAR-T-cell infusion. A patient with mantle cell lymphoma obtained a partial remission that is ongoing 3 months after infusion of anti-CD19-CAR T cells. A fourth patient with diffuse large B-cell lymphoma has ongoing stable disease 11 months after infusion of anti-CD19-CAR T cells. The other 6 treated patients all had short periods of stable malignancy or progressive disease after their CAR-T-cell infusions. Specific eradication of blood B cells occurred after infusion of CAR T cells in 3 of 4 patients with measurable blood B cells pretreatment. None of the patients treated on this study developed GVHD after their anti-CD19-CAR-T-cell infusions, despite the fact that 6 of 10 treated patients had experienced GVHD at earlier time-points after their most recent alloHSCT. One patient, who had a history of cardiac dysfunction with prior acute illnesses, had temporary cardiac dysfunction after infusion of anti-CD19-CAR T cells. The most prominent toxicities experienced by patients were fever and hypotension; these peaked 5 to 12 days after CAR-T-cell infusions and resolved within 14 days after the T-cell infusions. Two patients had Grade 3 fever, and 2 patients had Grade 3 hypotension. No patients experienced Grade 4 toxicities that were attributable to the CAR-T-cell infusions. Elevated levels of serum interferon gamma were detected in 3 patients at the time that they were experiencing toxicities. We detected cells containing the anti-CD19-CAR gene in the blood of 8 of 10 patients. The peak blood levels of CAR T cells varied from undetec to 2.8% of peripheral blood mononuclear cells. The persistence of the CAR T cells in the blood of patients was limited to one month or less. When we assessed T cells from the blood of patients ex vivo, we found elevated levels of the T-cell inhibitory molecule programmed cell death protein-1 (PD-1) on CAR+ T cells compared to CAR-negative T cells. These results show for the first time that small numbers of donor-derived allogeneic anti-CD19-CAR T cells can cause regression of highly treatment-resistant B-cell malignancies after alloHSCT without causing GVHD. Malignancies that were resistant to standard DLIs regressed after anti-CD19-CAR-T-cell infusions. Future goals for improving this approach include enhancing the persistence of anti-CD19-CAR T cells and reducing toxicities. Infusion of allogeneic T cells genetically modified to recognize malignancy-associated antigens is a promising approach for treating residual malignancy after alloHSCT. Disclosures: No relevant conflicts of interest to declare.

scholarly journals Pluripotent Cell-Derived Off-the-Shelf TCR-Less CAR-Targeted Cytotoxic T Cell Therapeutic for the Allogeneic Treatment of B Cell Malignancies

Blood ◽  
2018 ◽  
Vol 132 (Supplement 1) ◽  
pp. 4546-4546 ◽  
Author(s):  
Raedun Clarke ◽  
Sjoukje Van Der Stegen ◽  
Chia-Wei Chang ◽  
Mushtaq Husain ◽  
Yi-Shin Lai ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Board Of Directors ◽  
Peripheral Blood ◽  
Research Funding ◽  
B Cell Malignancies ◽  
Advisory Committees ◽  
Car T Cells ◽  
Car T

Abstract The advent of off-the-shelf chimeric antigen receptor (CAR) T cell therapeutics is widely recognized to be a major potential advancement for the treatment of cancer. Several obstacles currently hamper the broad use of CAR T cells, including the inherent variability and cost of manufacturing of autologous cellular populations, the absolute requirement for precise genetic editing in the allogeneic setting, and the challenge to keep pace with clonal heterogeneity. Here we present pre-clinical data for FT819, a first-of-kind off-the-shelf human induced pluripotent stem cell (hiPSC)-derived CAR T cell product. FT819 is defined by the precise genetic engineering of multiple targeting events at the single cell level to create a clonal master iPSC line. The engineered features include the targeted integration of a novel, modified CD19 CAR into the T cell receptor α (TRAC) locus to provide antigen specificity and enhanced efficacy while eliminating the possibility of graft versus host disease (GvHD), and the expression of a high-affinity, non-cleavable form of CD16 (hnCD16) to deliver an adjustable system to address tumor antigen escape. Through a proprietary cellular reprogramming platform, peripheral blood derived T cells are converted to hiPSCs, engineered to contain the modified CD19 CAR targeted into the TRAC locus and hnCD16, and clonally selected to create a master hiPSC line (TRAC-TiPSC, FT819). Molecular characterization of the TRAC-TiPSC master cell line by 5' junction, 3' junction and internal sequence PCR confirmed homology directed repair and bi-allelic targeting of the CD19 CAR into the TRAC locus. The origin of the clonal master cell bank was confirmed to be a TCRαβ T cell by PCR-mediated detection of TCRδ locus deletion and methyl-seq analysis of the TCRα locus. Flow cytometric analysis demonstrated the maintenance of a uniform population of hiPSCs (>95% SSEA4/TRA-1-81/OCT4/NANOG) and expression of hnCD16 transgene (>95% CD16). Utilizing our stage-specific T cell differentiation protocol, we demonstrate that the TRAC-TiPSCs yield TRAC-iT cells with uniform expression of the CAR (>95%), complete elimination of TCR surface expression and clinically enabling expansion through the manufacturing process (>50,000 fold). To confirm the lack of alloreactivity conferred by the deletion of endogenous TCR expression, mixed lymphocyte reactions were performed using TRAC-iT, primary TCR+ T cells and primary TCR+CAR+ T cells as responders and HLA-mismatched peripheral blood mononuclear cells (PBMCs) as targets. In comparison to primary T cells and primary CAR-T cells, TRAC-iT did not respond and proliferate in response to TCR stimulation or HLA-mismatched PBMCs indicating that the risk of GvHD was alleviated. In vitro functional studies established that TRAC-iT possess a potent cytotoxic T lymphocyte response to CD19 antigen challenge in a similar manner to peripheral blood CAR T cells as demonstrated by expression of markers indicative of degranulation (CD107a/b, Granzyme B), T cell activation (CD69, CD25), and production of INFγ, TNFα and IL2. Importantly, TRAC-iT targeted tumor in an antigen specific manner as verified by lysis of CD19+, but not CD19-, tumor cell lines as seen by in vitro cytolytic assays (50% killing E:T; TRAC-iT = 1:8, primary CAR-T = 1:4). In vivo studies demonstrated that TRAC-iT cells effectively control tumor progression in a mouse model of acute lymphoblastic leukemia Nalm6 (TRAC-iT versus no treatment, p<0.0001). To validate the capability of TRAC-iT to simultaneously target multiple antigens, TRAC-iT was co-cultured with mixtures of CD19+CD20+ and CD19-CD20+ tumor cells in the presence of anti-CD20 monoclonal antibody, Rituxan. In vitro cytolytic assays demonstrate that only TRAC-iT cells can effectively identify and eliminate CD19-CD20+ tumor cells when combined with Rituxan. Importantly, the antibody-dependent cellular-cytotoxicity did not appear to interfere with CAR function as TRAC-iT maintained its directed cytotoxic capacity. Collectively, these preclinical studies suggest that FT819 is a consistent and uniform off-the-shelf product than can be effectively and safely used in the treatment of B cell malignancies in the allogeneic setting. Disclosures Clarke: Fate Therapeutics Inc.: Employment. Chang:Fate Therapeutics Inc.: Employment. Husain:Fate Therapeutics Inc.: Employment. Lai:Fate Therapeutics Inc.: Employment. Peralta:Fate Therapeutics Inc.: Employment. Stokely:Fate Therapeutics Inc.: Employment. Abujarour:Fate Therapeutics Inc.: Employment. Dinella:Fate Therapeutics Inc.: Employment. Lee:Fate Therapeutics Inc.: Employment. Pribadi:Fate Therapeutics Inc.: Employment. Chu:Fate Therapeutics Inc.: Employment. Truong:Fate Therapeutics Inc.: Employment. Sabouri-Ghomi:Fate Therapeutics Inc.: Employment. Meza:Fate Therapeutics Inc.: Employment. Riviere:Juno Therapeutics, a Celgene Company: Membership on an entity's Board of Directors or advisory committees, Research Funding; Fate Therapeutics Inc.: Research Funding. Sadelain:Juno Therapeutics: Consultancy, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties, Research Funding; Fate Therapeutics Inc.: Research Funding. Valamehr:Fate Therapeutics Inc.: Employment.

Suppression of EBV-induced LCLs using CAR T cells redirected against HLA-DR.

2017 ◽  
Vol 35 (7_suppl) ◽  
pp. 146-146
Author(s):  
Chungyong Han ◽  
Rohit Singh ◽  
Seon-Hee Kim ◽  
Beom K. Choi ◽  
Byoung S. Kwon
Keyword(s):  
T Cells ◽  
B Cells ◽  
B Cell ◽  
Side Effect ◽  
B Cell Malignancies ◽  
Car T Cells ◽  
Hla Dr ◽  
Car T

146 Background: Recent studies demonstrated a therapeutic potential of T cells with chimeric antigen receptor (CAR) targeting CD19 in refractory B cell malignancies. However, CD19-CAR T cells frequently caused on-target off-tumor side effect, i.e. B cell aplasia, and led to the recurrence of CD19-negative leukemic cells. Alternative target antigen for B cell malignancies has to be excavated. Methods: We developed antibody clone, MVR, which specifically bound to HLA-DR that is highly expressed on malignant B cells. In particular, MVR recognized polymorphic region of HLA-DR, and indicated different binding affinity against various HLA-DR alleles. Based on MVR binding strength, PBMCs from high binder (MVRHigh) and low binder (MVRLow) were tested to generate MVR-CAR T cells. To evaluate the anti-tumor efficacy on B cell malignancies, MVR-CAR T cells were assessed for immune responses against Epstein-Barr virus (EBV)-induced lymphoblastoid cell line (LCL) in vitro and in vivo. Results: Final yield of MVR-CAR T cells generated from MVRHigh PBMCs was 10-fold lower than that of CD19-CAR T cells, presumably caused by "fratricide" among HLA-DR-upregulated MVR-CAR T cells. In contrast, fratricidal effect was ameliorated in MVR-CAR T cells generated from MVRLow PBMCs indicating that the interaction between MVR-CAR and MVRLow-HLA-DR was weak enough to achieve tolerance to fratricide. Of note, in spite of such low binding, MVRLow-LCLs were killed efficiently by the CAR T cells. Further quantitative analysis revealed that HLA-DR was far more upregulated on LCLs compared with normal T and B cells which did not undergo EBV-transformation. In accordance with this observation, MVR-CAR T cells successfully induced LCL-specific cytotoxicity without causing normal B cell damage in vitro and efficiently suppressed the outgrowth of metastasized tumors in LCL-xenografted immune-deficient mice. Conclusions: MVR-CAR T cells redirected against HLA-DR for B cell malignancies were evaluated for the cytotoxic efficacy in vitro and in vivo. Considering the alleviated on-target off-tumor side effect and the feasibility of targeting HLA-DR for CD19-deficient malignant B cells, MVR-CAR T cells can be an alternative option for B cell malignancies.

scholarly journals Allogeneic Anti-CD19 CAR T Cells Manufactured from Healthy Donors Provide a Unique Cellular Product with Distinct Phenotypic Characteristics Compared to CAR T Cells Generated from Patients with Mature B Cell Malignancies

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 3228-3228 ◽  
Author(s):  
Charlotte Graham ◽  
Agnieszka Jozwik ◽  
Ruby Quartey-Papafio ◽  
Nikolaos Ioannou ◽  
Ana M Metelo ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Board Of Directors ◽  
Research Funding ◽  
B Cell Malignancies ◽  
Advisory Committees ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T

Despite the success of autologous anti-CD19 CAR T cell therapy in B-Acute lymphoblastic leukaemia (B-ALL) and Diffuse Large B Cell Lymphoma (DLBCL), treatment failures occur. One contributing factor may be the intrinsic T cell fitness of the CAR T cell product that is influenced by the underlying malignancy and prior treatments. With the advent of gene editing, 'off the shelf' non-HLA matched healthy donor (HD) CAR T cells are under investigation for the treatment of patients (pts) in clinical trials. UCART19 (S68587) is a first-in-class allogeneic CAR T cell product expressing a second generation anti-CD19 CAR with TALEN®-mediated gene knockouts of T cell receptor alpha chain (TRAC) and CD52 to prevent graft versus host disease and to render them resistant to anti-CD52 antibody used for lymphodepletion. Preliminary clinical trial data on the use of UCART19 in B-ALL was previously reported at ASH (Benjamin et al, 2018). The phenotypic and functional characteristics of CAR T cell products manufactured from B-ALL, Chronic Lymphocytic Leukaemia (CLL) and DLBCL pts were compared to young adult healthy donor (HD) CAR T cell products. In addition, potential effects related to knocking out TRAC in HD TCR-CAR T cells were examined. Thawed PBMCs from B-ALL, CLL, DLBCL pts and HDs underwent T cell enrichment, activation with anti-CD3/CD28 beads and IL-2, followed by transduction with anti-CD19 4-1BB CD3ζ lentiviral CAR construct and expansion. HD TCR- CAR T cells were manufactured by electroporation of HD CAR T cells with mRNA coding for TRAC TALEN® and residual TCRαβ+cells were removed by magnetic bead selection. CAR expression levels, T cell subsets, and exhaustion markers were examined by flow cytometry. Expression of activation markers CD25 and CD69 was measured in response to co-culture with the CD19+cell line NALM-6. Cytotoxicity against NALM-6 and Raji was assessed and antigen-mediated proliferation measured over 14 days. HD CAR T cells (n=11) expanded significantly more during manufacture than CAR T cells derived from B-ALL (n=9), CLL (n=8) or DLBCL (n=8) pts. As expected, the electroporation step resulted in a transient decrease in viability which recovered over time in culture (n=10). Median CAR expression level was higher on CLL CAR T cell products compared to those from B-ALL pts and HDs, thought to be due to a higher CD4:CD8 ratio in some CLL products. As a consequence of TCR knockout, CD3 expression was lost on HD TCR- CAR T cells (n=10), apart from a small population of γδ CAR T cells. CLL and DLBCL CD8+CAR+cells expressed higher levels of PD1 than HD CD8+CAR+cells. DLBCL CD4+CAR+cells also expressed significantly higher levels of PD1 than HD or HD TCR-CD4+CAR+T cells. CAR+CD8+CD27+PD1- T cells have been previously described as a functionally important population that correlated with clinical outcome in pts who received CLL CAR T cells (Fraietta et al, 2018). We found HD (n=13) and HD TCR- (n=10) CAR T cells had significantly more CD8+CD27+PD1- CAR T cells compared to those derived from CLL (n=8) and DLBCL (n=6) pts, but similar levels to B-ALL pts (n=10). In the absence of CD19 antigen, DLBCL CAR+CD8+ T cells (n=6) had greater expression of CD25 and CD69. However, in response to stimulation with CD19+ NALM-6 cells, HD (n=12), HD TCR- (n=10) and B-ALL (n=10) CAR T cells had higher fold increase in CD69+ cells compared to DLBCL (n=6) CAR T cells. On paired analysis (n=6), no difference was seen in activation in response to CD19 antigen on HD compared to HD TCR- CAR T cells. All CAR T cell products demonstrated comparable cytotoxicity against NALM-6 and Raji cell lines in short term in vitro assays. However, long-term cytotoxicity will be evaluated in a murine model. We performed a detailed comparison of the phenotypic and functional characteristics of CAR T cells derived from pts with B-cell malignancies and HDs. DLBCL CAR T cells showed lower antigen specific activation but higher baseline activation which could lead to more differentiated exhausted T cells. CAR T cells derived from HDs show a higher proportion of the therapeutically relevant CAR+CD8+CD27+PD1- cells compared to patients with mature B cell malignancies (CLL and DLBCL), which is maintained after TRAC knockout. This suggests allogeneic CAR T cells, such as UCART19, may provide a more effective product for pts with T cell dysfunction. Disclosures Graham: Gillead: Other: Funding to attend educational meeting; Servier: Research Funding. Jozwik:Servier: Research Funding. Metelo:Pfizer: Research Funding; Allogene: Research Funding. Almena-Carrasco:Servier: Employment. Peranzoni:Servier: Employment. Ramsay:Celgene Corporation: Research Funding; Roche Glycart AG: Research Funding. Dupouy:Servier: Employment. Farzaneh:Autolus Ltd: Equity Ownership, Research Funding. Patten:Gilead: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Novartis: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees; Abbvie: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees; Janssen: Consultancy, Honoraria; Roche: Honoraria, Research Funding. Benjamin:Amgen: Honoraria; Allogene: Research Funding; Gilead: Honoraria; Servier: Research Funding; Eusapharm: Consultancy; Pfizer: Research Funding; Takeda: Honoraria; Novartis: Honoraria.

scholarly journals 221 CRISPR screen identifies loss of IFNγR signaling and downstream adhesion as a resistance mechanism to CAR T-cell cytotoxicity in solid but not liquid tumors

2021 ◽  
Vol 9 (Suppl 3) ◽  
pp. A234-A234
Author(s):  
Rebecca Larson ◽  
Michael Kann ◽  
Stefanie Bailey ◽  
Nicholas Haradhvala ◽  
Kai Stewart ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Solid Tumors ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T Cell Therapy ◽  
Car T

BackgroundChimeric Antigen Receptor (CAR) therapy has had a transformative impact on the treatment of hematologic malignancies1–6 but success in solid tumors remains elusive. We hypothesized solid tumors have cell-intrinsic resistance mechanisms to CAR T-cell cytotoxicity.MethodsTo systematically identify resistance pathways, we conducted a genome-wide CRISPR knockout screen in glioblastoma cells, a disease where CAR T-cells have had limited efficacy.7 8 We utilized the glioblastoma cell line U87 and targeted endogenously expressed EGFR with CAR T-cells generated from 6 normal donors for the screen. We validated findings in vitro and in vivo across a variety of human tumors and CAR T-cell antigens.ResultsLoss of genes in the interferon gamma receptor (IFNγR) signaling pathway (IFNγR1, JAK1, JAK2) rendered U87 cells resistant to CAR T-cell killing in vitro. IFNγR1 knockout tumors also showed resistance to CAR T cell treatment in vivo in a second glioblastoma line U251 in an orthotopic model. This phenomenon was irrespective of CAR target as we also observed resistance with IL13Ralpha2 CAR T-cells. In addition, resistance to CAR T-cell cytotoxicity through loss of IFNγR1 applied more broadly to solid tumors as pancreatic cell lines targeted with either Mesothelin or EGFR CAR T-cells also showed resistance. However, loss of IFNγR signaling did not impact sensitivity of liquid tumor lines (leukemia, lymphoma or multiple myeloma) to CAR T-cells in vitro or in an orthotopic model of leukemia treated with CD19 CAR. We isolated the effects of decreased cytotoxicity of IFNγR1 knockout glioblastoma tumors to be cancer-cell intrinsic because CAR T-cells had no observable differences in proliferation, activation (CD69 and LFA-1), or degranulation (CD107a) when exposed to wildtype versus knockout tumors. Using transcriptional profiling, we determined that glioblastoma cells lacking IFNγR1 had lower upregulation of cell adhesion pathways compared to wildtype glioblastoma cells after exposure to CAR T-cells. We found that loss of IFNγR1 reduced CAR T-cell binding avidity to glioblastoma.ConclusionsThe critical role of IFNγR signaling for susceptibility of solid tumors to CAR T-cells is surprising given that CAR T-cells do not require traditional antigen-presentation pathways. Instead, in glioblastoma tumors, IFNγR signaling was required for sufficient adhesion of CAR T-cells to mediate productive cytotoxicity. Our work demonstrates that liquid and solid tumors differ in their interactions with CAR T-cells and suggests that enhancing T-cell/tumor interactions may yield improved responses in solid tumors.AcknowledgementsRCL was supported by T32 GM007306, T32 AI007529, and the Richard N. Cross Fund. ML was supported by T32 2T32CA071345-21A1. SRB was supported by T32CA009216-38. NJH was supported by the Landry Cancer Biology Fellowship. JJ is supported by a NIH F31 fellowship (1F31-MH117886). GG was partially funded by the Paul C. Zamecnik Chair in Oncology at the Massachusetts General Hospital Cancer Center and NIH R01CA 252940. MVM and this work is supported by the Damon Runyon Cancer Research Foundation, Stand Up to Cancer, NIH R01CA 252940, R01CA238268, and R01CA249062.ReferencesMaude SL, et al. Tisagenlecleucel in children and young adults with B-cell lymphoblastic leukemia. N Engl J Med 2018;378:439–448.Neelapu SS, et al. Axicabtagene ciloleucel CAR T-cell therapy in refractory large B-cell lymphoma. N Engl J Med 2017;377:2531–2544.Locke FL, et al. Long-term safety and activity of axicabtagene ciloleucel in refractory large B-cell lymphoma (ZUMA-1): a single-arm, multicentre, phase 1–2 trial. The Lancet Oncology 2019;20:31–42.Schuster SJ, et al. Chimeric antigen receptor T cells in refractory B-cell lymphomas. N Engl J Med 2017;377:2545–2554.Wang M, et al. KTE-X19 CAR T-cell therapy in relapsed or refractory mantle-cell lymphoma. N Engl J Med 2020;382:1331–1342.Cohen AD, et al. B cell maturation antigen-specific CAR T cells are clinically active in multiple myeloma. J Clin Invest 2019;129:2210–2221.Bagley SJ, et al. CAR T-cell therapy for glioblastoma: recent clinical advances and future challenges. Neuro-oncology 2018;20:1429–1438.Choi BD, et al. Engineering chimeric antigen receptor T cells to treat glioblastoma. J Target Ther Cancer 2017;6:22–25.Ethics ApprovalAll human samples were obtained with informed consent and following institutional guidelines under protocols approved by the Institutional Review Boards (IRBs) at the Massachusetts General Hospital (2016P001219). Animal work was performed according to protocols approved by the Institutional Animal Care and Use Committee (IACUC) (2015N000218 and 2020N000114).

scholarly journals Identification of Two CAR T-Cell Populations Associated with Complete Response or Progressive Disease in Adult Lymphoma Patients Treated with Axi-Cel

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 779-779 ◽  
Author(s):  
Zinaida Good ◽  
Jay Y. Spiegel ◽  
Bita Sahaf ◽  
Meena B. Malipatlolla ◽  
Matthew J. Frank ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Board Of Directors ◽  
Research Funding ◽  
Advisory Board ◽  
Advisory Committees ◽  
Car T Cells ◽  
Scientific Advisory Board ◽  
Car T ◽  
Scientific Advisory

Axicabtagene ciloleucel (Axi-cel) is an autologous anti-CD19 chimeric antigen receptor (CAR) T-cell therapy approved for the treatment of relapsed or refractory diffuse large B-cell lymphoma (r/r DLBCL). Long-term analysis of the ZUMA-1 phase 1-2 clinical trial showed that ~40% of Axi-cel patients remained progression-free at 2 years (Locke et al., Lancet Oncology 2019). Those patients who achieved a complete response (CR) at 6 months generally remained progression-free long-term. The biological basis for achieving a durable CR in patients receiving Axi-cel remains poorly understood. Here, we sought to identify CAR T-cell intrinsic features associated with CR at 6 months in DLBCL patients receiving commercial Axi-cel at our institution. Using mass cytometry, we assessed expression of 33 surface or intracellular proteins relevant to T-cell function on blood collected before CAR T cell infusion, on day 7 (peak expansion), and on day 21 (late expansion) post-infusion. To identify cell features that distinguish patients with durable CR (n = 11) from those who developed progressive disease (PD, n = 14) by 6 months following Axi-cel infusion, we performed differential abundance analysis of multiparametric protein expression on CAR T cells. This unsupervised analysis identified populations on day 7 associated with persistent CR or PD at 6 months. Using 10-fold cross-validation, we next fitted a least absolute shrinkage and selection operator (lasso) model that identified two clusters of CD4+ CAR T cells on day 7 as potentially predictive of clinical outcome. The first cluster identified by our model was associated with CR at 6 months and had high expression of CD45RO, CD57, PD1, and T-bet transcription factor. Analysis of protein co-expression in this cluster enabled us to define a simple gating scheme based on high expression of CD57 and T-bet, which captured a population of CD4+ CAR T cells on day 7 with greater expansion in patients experiencing a durable CR (mean±s.e.m. CR: 26.13%±2.59%, PD: 10.99%±2.53%, P = 0.0014). In contrast, the second cluster was associated with PD at 6 months and had high expression of CD25, TIGIT, and Helios transcription factor with no CD57. A CD57-negative Helios-positive gate captured a population of CD4+ CAR T cells was enriched on day 7 in patients who experienced progression (CR: 9.75%±2.70%, PD: 20.93%±3.70%, P = 0.016). Co-expression of CD4, CD25, and Helios on these CAR T cells highlights their similarity to regulatory T cells, which could provide a basis for their detrimental effects. In this exploratory analysis of 25 patients treated with Axi-cel, we identified two populations of CD4+ CAR T cells on day 7 that were highly associated with clinical outcome at 6 months. Ongoing analyses are underway to fully characterize this dataset, to explore the biological activity of the populations identified, and to assess the presence of other populations that may be associated with CAR-T expansion or neurotoxicity. This work demonstrates how multidimensional correlative studies can enhance our understanding of CAR T-cell biology and uncover populations associated with clinical outcome in CAR T cell therapies. This work was supported by the Parker Institute for Cancer Immunotherapy. Figure Disclosures Muffly: Pfizer: Consultancy; Adaptive: Research Funding; KITE: Consultancy. Miklos:Celgene: Membership on an entity's Board of Directors or advisory committees; BMS: Membership on an entity's Board of Directors or advisory committees; Kite-Gilead: Membership on an entity's Board of Directors or advisory committees, Research Funding; AlloGene: Membership on an entity's Board of Directors or advisory committees; Precision Bioscience: Membership on an entity's Board of Directors or advisory committees; Miltenyi Biotech: Membership on an entity's Board of Directors or advisory committees; Becton Dickinson: Research Funding; Adaptive Biotechnologies: 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; Juno: Membership on an entity's Board of Directors or advisory committees. Mackall:Vor: Other: Scientific Advisory Board; Roche: Other: Scientific Advisory Board; Adaptimmune LLC: Other: Scientific Advisory Board; Glaxo-Smith-Kline: Other: Scientific Advisory Board; Allogene: Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Apricity Health: Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Unum Therapeutics: Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Obsidian: Research Funding; Lyell: Consultancy, Equity Ownership, Other: Founder, Research Funding; Nektar: Other: Scientific Advisory Board; PACT: Other: Scientific Advisory Board; Bryologyx: Other: Scientific Advisory Board.

scholarly journals Combination of NKTR-255, a Polymer Conjugated Human IL-15, with CD19 CAR T Cell Immunotherapy in a Preclinical Lymphoma Model

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 2866-2866 ◽  
Author(s):  
Cassie Chou ◽  
Simon Fraessle ◽  
Rachel Steinmetz ◽  
Reed M. Hawkins ◽  
Tinh-Doan Phi ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Research Funding ◽  
Board Member ◽  
Ad Hoc ◽  
Advisory Board ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
Equity Ownership

Background CD19 CAR T immunotherapy has been successful in achieving durable remissions in some patients with relapsed/refractory B cell lymphomas, but disease progression and loss of CAR T cell persistence remains problematic. Interleukin 15 (IL-15) is known to support T cell proliferation and survival, and therefore may enhance CAR T cell efficacy, however, utilizing native IL-15 is challenging due to its short half-life and poor tolerability in the clinical setting. NKTR-255 is a polymer-conjugated IL-15 that retains binding affinity to IL15Rα and exhibits reduced clearance, providing sustained pharmacodynamic responses. We investigated the effects of NKTR-255 on human CD19 CAR T cells both in vitro and in an in vivo xenogeneic B cell lymphoma model and found improved survival of lymphoma bearing mice receiving NKTR-255 and CAR T cells compared to CAR T cells alone. Here, we extend upon these findings to further characterize CAR T cells in vivo and examine potential mechanisms underlying improved anti-tumor efficacy. Methods CD19 CAR T cells incorporating 4-1BB co-stimulation were generated from CD8 and CD4 T cells isolated from healthy donors. For in vitro studies, CAR T cells were incubated with NKTR-255 or native IL-15 with and without CD19 antigen. STAT5 phosphorylation, CAR T cell phenotype and CFSE dilution were assessed by flow cytometry and cytokine production by Luminex. For in vivo studies, NSG mice received 5x105 Raji lymphoma cells IV on day (D)-7 and a subtherapeutic dose (0.8x106) of CAR T cells (1:1 CD4:CD8) on D0. To determine optimal start date of NKTR-255, mice were treated weekly starting on D-1, 7, or 14 post CAR T cell infusion. Tumors were assessed by bioluminescence imaging. Tumor-free mice were re-challenged with Raji cells. For necropsy studies mice received NKTR-255 every 7 days following CAR T cell infusion and were euthanized at various timepoints post CAR T cell infusion. Results Treatment of CD8 and CD4 CAR T cells in vitro with NKTR-255 resulted in dose dependent STAT5 phosphorylation and antigen independent proliferation. Co-culture of CD8 CAR T cells with CD19 positive targets and NKTR-255 led to enhanced proliferation, expansion and TNFα and IFNγ production, particularly at lower effector to target ratios. Further studies showed that treatment of CD8 CAR T cells with NKTR-255 led to decreased expression of activated caspase 3 and increased expression of bcl-2. In Raji lymphoma bearing NSG mice, administration of NKTR-255 in combination with CAR T cells increased peak CAR T cell numbers, Ki-67 expression and persistence in the bone marrow compared to mice receiving CAR T cells alone. There was a higher percentage of EMRA like (CD45RA+CCR7-) CD4 and CD8 CAR T cells in NKTR-255 treated mice compared to mice treated with CAR T cells alone and persistent CAR T cells in mice treated with NKTR-255 were able to reject re-challenge of Raji tumor cells. Additionally, starting NKTR-255 on D7 post T cell infusion resulted in superior tumor control and survival compared to starting NKTR-255 on D-1 or D14. Conclusion Administration of NKTR-255 in combination with CD19 CAR T cells leads to improved anti-tumor efficacy making NKTR-255 an attractive candidate for enhancing CAR T cell therapy in the clinic. Disclosures Chou: Nektar Therapeutics: Other: Travel grant. Fraessle:Technical University of Munich: Patents & Royalties. Busch:Juno Therapeutics/Celgene: Consultancy, Equity Ownership, Research Funding; Kite Pharma: Equity Ownership; Technical University of Munich: Patents & Royalties. Miyazaki:Nektar Therapeutics: Employment, Equity Ownership. Marcondes:Nektar Therapeutics: Employment, Equity Ownership. Riddell:Juno Therapeutics: Equity Ownership, Patents & Royalties, Research Funding; Adaptive Biotechnologies: Consultancy; Lyell Immunopharma: Equity Ownership, Patents & Royalties, Research Funding. Turtle:Allogene: Other: Ad hoc advisory board member; Novartis: Other: Ad hoc advisory board member; Humanigen: Other: Ad hoc advisory board member; Nektar Therapeutics: Other: Ad hoc advisory board member, Research Funding; Caribou Biosciences: Equity Ownership, Membership on an entity's Board of Directors or advisory committees; T-CURX: Membership on an entity's Board of Directors or advisory committees; Juno Therapeutics: Patents & Royalties: Co-inventor with staff from Juno Therapeutics; pending, Research Funding; Precision Biosciences: Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Eureka Therapeutics: Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Kite/Gilead: Other: Ad hoc advisory board member.

scholarly journals P01.22 Extending CAR T cell therapy applications via drug inducible control of transgene expression

2020 ◽  
Vol 8 (Suppl 2) ◽  
pp. A18.2-A19
Author(s):  
B Kotter ◽  
N Werchau ◽  
W Krueger ◽  
A Roy ◽  
J Mittelstaet ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Transgene Expression ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
Part Time ◽  
Anti Cd20

BackgroundAdoptive transfer of chimeric antigen receptor (CAR)-modified T cells has emerged as a promising treatment modality for a broad range of cancers highlighted by the approval of Kymriah™ and Yescarta™ for the treatment of B cell malignancies. However, lack of control of CAR T cell function and consequent excessive inflammation in patients can result in severe side effects especially when targeting tumor-associated rather than tumor-specific antigens. Thus, temporal and tunable control of CAR activity is of major importance for the clinical translation of innovative CAR designs. While the activation of suicide switches results in the apoptotic elimination of the transferred cells, other strategies, e.g. anti-tag CARs or small molecule-gated CARs, enable the reversible control of CAR-mediated function at the protein level but are restricted to a particular CAR design. Focusing on the control of expression rather than CAR signaling, transcriptional regulators represent a versatile tool facilitating a wide range of CAR T cell applications.Materials and MethodsTo maintain control over the infused CAR T cell product and mitigate risks for the patient, we describe here the development of an inducible switch system for the transcriptional regulation of transgene expression in primary, human T cells. Chemically regulated synthetic transcription factors composed of a zinc finger DNA-binding domain, an inducible control domain and a transcription activation domain were designed, screened for functionality, and evaluated in T cells regarding their potential to control CAR expression both in vitro and in vivo.ResultsBy screening, we identified a synthetic transcription factor, which shows high transcriptional output in T cells in the presence of a clinically relevant inducer drug and absence of background activity in the non-induced state. Using this system we were able to control the expression of a CAR recognizing the CD20 antigen present on B cells and B cell leukemic blasts. The addition of the inducer drug resulted in rapid expression of the anti-CD20 CAR on the T cell surface. Moreover, inducible anti-CD20 CAR T cells executed cytolytic activity against CD20 positive target cells and secreted cytokines upon stimulation in vitro. Effectivity in co-cultures was thereby comparable to T cells expressing the anti-CD20 CAR under a conventional constitutive promoter. Furthermore, we could fine-tune CAR activity by titrating the inducer concentration. By defining the time-point of induction, modulation of the onset of therapy was achieved. Upon inducer drug discontinuation, inducible CD20 CAR T cells lost CAR expression and concurrently all CAR-related functions, indicating that the ‘on’ and ‘off’ status can be tightly controlled by the administration of the drug. After pausing of CAR T cell-mediated activity, we could re-induce CAR expression suggesting complete reversibility of effector function. Finally, we were able to show that inducible CD20 CAR T cells mediate a significant, strictly inducer-dependent antitumor activity in a well-established mouse model of B cell lymphoma.ConclusionsThe zinc-finger-based transcriptional control system investigated in this study provides small molecule-inducible control over a therapeutically relevant anti-CD20 CAR in primary T cells in a time- and dose-dependent manner. The tight regulation of CAR expression will pave the way for safer cellular therapies.Disclosure InformationB. Kotter: A. Employment (full or part-time); Significant; Miltenyi Biotec B.V. & Co. KG. N. Werchau: A. Employment (full or part-time); Significant; Miltenyi Biotec B.V. & Co. KG. W. Krueger: A. Employment (full or part-time); Significant; Lentigen Technology Inc. A. Roy: A. Employment (full or part-time); Significant; Lentigen Technology Inc. J. Mittelstaet: A. Employment (full or part-time); Significant; Miltenyi Biotec B.V. & Co. KG. A. Kaiser: A. Employment (full or part-time); Significant; Miltenyi Biotec B.V. & Co. KG.

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