scholarly journals Low CD19 Antigen Density Diminishes Efficacy of CD19 CAR T Cells and Can be Overcome By Rational Redesign of CAR Signaling Domains

Blood ◽  
2018 ◽  
Vol 132 (Supplement 1) ◽  
pp. 963-963 ◽  
Author(s):  
Robbie G. Majzner ◽  
Skyler P. Rietberg ◽  
Louai Labanieh ◽  
Elena Sotillo ◽  
Evan W. Weber ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Tumor Cells ◽  
Cytokine Production ◽  
Xenograft Model ◽  
Target Antigen ◽  
Tumor Escape ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T

Abstract Target antigen density has emerged as a major factor influencing the potency of CAR T cells. Our laboratory has demonstrated that the activity of numerous CARs is highly dependent on target antigen density (Walker et al., Mol Ther, 2017), and high complete response rates in a recent trial of CD22 CAR T cells for B-ALL were tempered by frequent relapses due to decreased CD22 antigen density on lymphoblasts (Fry et al., Nat Med, 2018). To assess if antigen density is also a determinant of CD19 CAR T cell therapeutic success, we analyzed CD19 antigen density from fifty pediatric B-ALL patients treated on a clinical trial of CD19-CD28ζ CAR T cells. We found that patients whose CD19 expression was below a threshold density (2000 molecules/lymphoblast) were significantly less likely to achieve a clinical response than those whose leukemia expressed higher levels of CD19. In order to further understand this limitation and how it may be overcome, we developed a model of variable CD19 antigen density B-ALL. After establishing a CD19 knockout of the B-ALL cell line NALM6, we used a lentivirus to reintroduce CD19 and then FACS sorted and single cell cloned to achieve a library of NALM6 clones with varying CD19 surface densities. CD19-CD28ζ CAR T cell activity was highly dependent on CD19 antigen density. We observed decreases in cytotoxicity, proliferation, and cytokine production by CD19 CAR T cells when encountering CD19-low cells, with an approximate threshold of 2,000 molecules of CD19 per lymphoblast, below which, cytokine production in response to tumor cells was nearly ablated. Given that a CD19-4-1BBζ CAR is FDA approved for children with B-ALL and adults with DLBCL, we wondered whether CARs incorporating this alternative costimulatory domain would have similar antigen density thresholds for activation. Surprisingly, CD19-4-1BBζ CAR T cells made even less cytokine, proliferated less, and had further diminished cytolytic capacity against CD19-low cells compared to CD19-CD28ζ CAR T cells. Analysis by western blot of protein lysates from CAR T cells stimulated with varying amounts of antigen demonstrated that CD19-CD28ζ CAR T cells had higher levels of downstream signals such as pERK than CD19-4-1BBζ CAR T cells at lower antigen densities. Accordingly, calcium flux after stimulation was also significantly higher in CD19-CD28ζ than CD19-4-1BBζ CAR T cells. In a xenograft model of CD19-low B-ALL, CD19-4-1BBζ CAR T cells demonstrated no anti-tumor activity, while CD19-CD28ζ CAR T cells eradicated CD19-low leukemia cells. Therefore, the choice of costimulatory domain in CAR T cells plays a major role in modulating activity against low antigen density tumors. CD28 costimulation endows high reactivity towards low antigen density tumors. We confirmed the generalizability of this finding using Her2 CAR T cells; Her2-CD28ζ CAR T cells cleared tumors in an orthotopic xenograft model of Her2-low osteosarcoma, while Her2-4-1BBζ CAR T cells had no effect. This finding has implications for CAR design for lymphoma and solid tumors, where antigen expression is more heterogeneous than B-ALL. To enhance the activity of CD19-4-1BBζ CAR T cells against CD19-low leukemia, we designed a CAR with two copies of intracellular zeta in the signaling domain (CD19-4-1BBζζ). T cells expressing this double-zeta CAR demonstrated enhanced cytotoxicity, proliferation, cytokine production, and pERK signaling in response to CD19-low cells compared to single-zeta CARs. Additionally, in a xenograft model, CD19-4-1BBζζ CAR T cells demonstrated enhanced activity against CD19-low leukemia compared to CD19-4-1BBζ CAR T cells, significantly extending survival. The addition of a third zeta domain (CD19-4-1BBζζζ) further enhanced the activity of CAR T cells. However, inclusion of multiple copies of the costimulatory domains did not improve function. In conclusion, CD19 antigen density is an important determinant of CAR T cell function and therapeutic response. CD19-CD28ζ CARs are more efficient at targeting CD19-low tumor cells than CD19-4-1BBζ CARs. The addition of multiple zeta domains to the CAR enhances its ability to target low antigen density tumors. This serves as proof of concept that rational redesign of CAR signaling endodomains can result in enhanced function against low antigen density tumors, an important step for extending the reach of these powerful therapeutics and overcoming a significant mechanism of tumor escape. Disclosures Lee: Juno: Consultancy.

scholarly journals Efficacy and safety of CAR19/22 T-cell cocktail therapy in patients with refractory/relapsed B-cell malignancies

Blood ◽  
2020 ◽  
Vol 135 (1) ◽  
pp. 17-27 ◽  
Author(s):  
Na Wang ◽  
Xuelian Hu ◽  
Wenyue Cao ◽  
Chunrui Li ◽  
Yi Xiao ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Tumor Cells ◽  
Target Antigen ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T Cell Therapy ◽  
Car T ◽  
Negative Tumor

Relapse following chemeric antigen receptor (CAR) T-cell therapy can arise from progressive loss of the CAR T cells or from loss of the target antigen by tumor cells. Wang et al report that using a mix of CAR T cells targeting CD19 and CD22 reduces relapse with antigen-negative tumor cells. However, a lack of CAR T-cell persistence leads to increased relapse with antigen-positive cells.

scholarly journals High-Affinity Chimeric Antigen Receptor With Cross-Reactive scFv to Clinically Relevant EGFR Oncogenic Isoforms

2021 ◽  
Vol 11 ◽  
Author(s):  
Radhika Thokala ◽  
Zev A. Binder ◽  
Yibo Yin ◽  
Logan Zhang ◽  
Jiasi Vicky Zhang ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Tumor Cells ◽  
Chimeric Antigen Receptor ◽  
Antigen Receptor ◽  
Tumor Escape ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T

Tumor heterogeneity is a key reason for therapeutic failure and tumor recurrence in glioblastoma (GBM). Our chimeric antigen receptor (CAR) T cell (2173 CAR T cells) clinical trial (NCT02209376) against epidermal growth factor receptor (EGFR) variant III (EGFRvIII) demonstrated successful trafficking of T cells across the blood–brain barrier into GBM active tumor sites. However, CAR T cell infiltration was associated only with a selective loss of EGFRvIII+ tumor, demonstrating little to no effect on EGFRvIII- tumor cells. Post-CAR T-treated tumor specimens showed continued presence of EGFR amplification and oncogenic EGFR extracellular domain (ECD) missense mutations, despite loss of EGFRvIII. To address tumor escape, we generated an EGFR-specific CAR by fusing monoclonal antibody (mAb) 806 to a 4-1BB co-stimulatory domain. The resulting construct was compared to 2173 CAR T cells in GBM, using in vitro and in vivo models. 806 CAR T cells specifically lysed tumor cells and secreted cytokines in response to amplified EGFR, EGFRvIII, and EGFR-ECD mutations in U87MG cells, GBM neurosphere-derived cell lines, and patient-derived GBM organoids. 806 CAR T cells did not lyse fetal brain astrocytes or primary keratinocytes to a significant degree. They also exhibited superior antitumor activity in vivo when compared to 2173 CAR T cells. The broad specificity of 806 CAR T cells to EGFR alterations gives us the potential to target multiple clones within a tumor and reduce opportunities for tumor escape via antigen loss.

scholarly journals Low-affinity CAR T cells exhibit reduced trogocytosis, preventing fratricide and antigen-negative tumor escape while preserving anti-tumor activity

2021 ◽  
Author(s):  
Michael L. Olson ◽  
Erica R. Vander Mause ◽  
Sabarinath V. Radhakrishnan ◽  
Joshua D. Brody ◽  
Aaron P. Rapoport ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Tumor Cells ◽  
Tumor Escape ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
Negative Tumor ◽  
Antigen Loss ◽  
Anti Tumor Activity

ABSTRACTChimeric antigen receptor (CAR) T cells using the high-affinity CD19 binding domain FMC63 are an effective treatment for patients with relapsed and aggressive B cell lymphoma. However, antigen loss and poor CAR T cell persistence remain common causes for relapse in these patients. Using primary patient samples, we now show that FMC63-based CAR T cells confer rapid antigen loss in all major tumor types currently approved for treatment with CD19 CAR T cells via trogocytosis, the stripping of antigen from tumor cells by CAR T cells. We show that CAR T cell-mediated trogocytosis can be dramatically reduced across a wide range of B cell malignancies by replacing FMC63 with a low affinity CD19 antibody. This reduction in trogocytosis does not alter the direct anti-tumor activity of CD19 CAR T cells but prevents the emergence of antigen-negative tumor cells and significantly increases CAR T cell viability by reducing fratricide of CD19 CAR T cells following trogocytosis.TEASERA reduction in CAR affinity does not affect tumor killing but prolongs T cell persistence and prevents antigen-negative tumor escape.

Evaluating the reversible control of an engineered CAR T cell ON-switch.

2017 ◽  
Vol 35 (15_suppl) ◽  
pp. e14550-e14550 ◽  
Author(s):  
Amy Gilbert ◽  
Stephen Santoro ◽  
Tiffany Tse ◽  
Tara Candelario-Chopra ◽  
Tina Gomes ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Tumor Cells ◽  
Small Molecule ◽  
Cytokine Production ◽  
Polypeptide Chain ◽  
Car T Cells ◽  
Small Molecule Drug ◽  
Car T Cell ◽  
Car T

e14550 Background: CAR T cell therapy holds enormous promise for many cancer types but its application may be limited by serious toxicities. To lower this hurdle, our aim is to engineer tunable cell therapies. One of our approaches includes a “ON-switch” chimeric antigen receptor (Wu et al., Science 2015) that requires the administration of a small molecule acting as a dimerizing agent between one polypeptide chain containing the antigen recognition domain and half of an inducible heterodimerization system and another polypeptide chain containing the second half of the inducible heterodimerization motif, the CD3ζ chain and a costimulatory motif. Using an FDA approved small molecule drug, we evaluate the reversibility of ON-switch CAR T cells in preclinical models. Methods: First, we evaluated the proliferation, cytotoxicity and cytokine production of several ON-switch constructs in human primary T cells. Next, to address the reversibility of the ON-switch (ON→OFF→ON), we performed a series of co-culture experiments where the small molecule drug was added to tumor cells and ON-switch CAR T cells, then washed out, and then re-introduced back into the co-cultures. We compared CAR T cell mediated killing and cytokine production from the On-switch CAR T cells relative to a canonical CAR T control. Results: Our On-switch CAR T cells were shown to proliferate, secrete cytokines as well as mediate dose dependent cytotoxicity in the presence of the small molecule drug. Importantly, in the presence of antigen but in absence of the small molecule drug we did not measure any significant functional activity in our ON-switch CARs. Additonally, following the removal of the small molecule drug over a period several days we did not observe any significant CAR mediated cytotoxicity. Following the subsequent re-addition of the small molecule, we observed further CAR T cell mediated cytotoxicity against tumor cells. Conclusions: These results show that the small molecule inducible On-switch CARs maintain functional activity as well as reversibility allowing for the tunable control of a CAR T cell.

scholarly journals High Affinity Chimeric Antigen Receptor with Cross-Reactive scFv to Clinically Relevant EGFR Oncogenic Isoforms

2021 ◽  
Author(s):  
Radhika Thokala ◽  
Zev A. Binder ◽  
Yibo Yin ◽  
Logan Zhang ◽  
Jiasi Vicky Zhang ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Tumor Cells ◽  
Chimeric Antigen Receptor ◽  
Antigen Receptor ◽  
Tumor Escape ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T

Tumor heterogeneity is a key reason for therapeutic failure and tumor recurrence in glioblastoma (GBM). Our chimeric antigen receptor (CAR) T cell (2173 CAR T cells) clinical trial (NCT02209376) against Epidermal growth factor receptor (EGFR) variant III (EGFRvIII) demonstrated successful trafficking of T cells across the blood brain barrier into GBM active tumor sites. However, CAR T cell infiltration was associated only with a selective loss of EGFRvIII+ tumor, demonstrating little to no effect on EGFRvIII- tumor cells. Post-CAR T treated tumor specimens showed continued presence of EGFR amplification and oncogenic EGFR extracellular domain (ECD) missense mutations, despite loss of EGFRvIII. To address tumor escape, we generated an EGFR-specific CAR by fusing monoclonal antibody (mAb) 806 to a 4-1BB co-stimulatory domain. The resulting construct was compared to 2173 CAR T cells in GBM, using in vitro and in vivo models. 806 CAR T cells specifically lysed tumor cells and secreted cytokines in response to amplified EGFR, EGFRvIII, and EGFR-ECD mutations in U87MG cells, GBM neurosphere-derived cell lines, and patient-derived GBM organoids. 806 CAR T cells did not lyse fetal brain astrocytes or primary keratinocytes to a significant degree. They also exhibited superior antitumor activity in vivo when compared to 2173 CAR T cells. The broad specificity of 806 CAR T cells to EGFR alterations gives us the potential to target multiple clones within a tumor and reduce opportunities for tumor escape via antigen loss.

scholarly journals B-CLL Mediated Resistance to CAR T Cell Therapy Via Insufficient Activation Is CAR-Independent

Blood ◽  
2020 ◽  
Vol 136 (Supplement 1) ◽  
pp. 44-44
Author(s):  
McKensie Collins ◽  
Weimin Kong ◽  
Inyoung Jung ◽  
Stefan M Lundh ◽  
J. Joseph Melenhorst
Keyword(s):  
Flow Cytometry ◽  
T Cells ◽  
T Cell ◽  
Research Funding ◽  
Cytokine Production ◽  
Cell Function ◽  
T Cell Therapy ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T

Chronic Lymphocytic Leukemia (CLL) is a B cell malignancy that accounts for nearly 1/3rd of adult leukemia diagnoses in the Western world. Conventional chemo-immunotherapies initially control progression, but in the absence of curative options patients ultimately succumb to their disease. Chimeric Antigen Receptor (CAR) T cell therapy is potentially curative, but only 26% of CLL patients have a complete response. CLL-stimulated T cells have reduced effector functions and B-CLL cells themselves are believed to be immunosuppressive. Our work demonstrates that insufficient activation of CAR T cells by CLL cells mediates some of these effects and that the results are conserved between ROR1- and CD19-targeting CARs. Results: In this study we used an in vitro system to model the in vivo anti-tumor response in which CAR T cells serially engage with CLL cells. Multiple stimulations of CD19 or ROR1-targeting CAR T cells with primary CLL cells recapitulated many aspects of known T cell dysfunction including reduced proliferation, cytokine production, and activation. While the initial stimulation induced low level proliferation, subsequent stimulations failed to elicit additional effector functions. We further found that these functional defects were not permanent, and that CAR T cell function could be restored by switching to a stimulus with an aAPC (artificial Antigen Presenting Cell) control cell line. The aAPCs are well-characterized as potent stimulators of CAR T cell effector responses. Flow cytometry revealed that CLL-stimulated CAR T cells retained a non-activated, baseline differentiation profile, suggesting that CLL cells fail to stimulate CAR T cells rather than rendering them non-functional. One mechanism that could dampen activation is immune suppression. We assessed this at a high level by stimulating CAR T cells with CLL cells and aAPCs mixed at known ratios. However, even cultures containing 75% CLL cells stimulated proliferation and cytokine production. Extensive immune-phenotyping revealed high level expression of the IL-2 Receptor on 90% (18/20) of the B-CLL cells tested. Since cytokine sinking via IL-2 receptor expression is a well-known mechanism of regulatory T cell suppression, we hypothesized that CLL cells similarly sink IL-2, blunting T cell activation. To test this, we supplemented IL-2 into CLL/CAR T cell co-cultures and showed that this rescued proliferation but only partially restored cytokine production. In contrast to our hypothesis, analysis of cytokine production by flow cytometry showed that CLL-stimulated CAR T cells did not produce IL-2 following a 6- or 12-hour stimulus, but TNFα was expressed after 12-hours. Similarly, CAR T cell degranulation, a prerequisite for target cell lysis was triggered after CLL recognition. These data again suggested that CLL cells insufficiently stimulate CAR T cell cytokine production, but also showed that cytolytic activity against CLL cells is intact. We further proposed that CLL cells express insufficient levels of co-stimulatory and adhesion molecules to activate CAR T cells. Flow cytometry showed that most CLL cells expressed co-stimulatory and adhesion molecules at low levels; we hypothesized that up-regulating these molecules would enhance CAR T cell targeting of CLL cells. CLL cells were activated with CD40L and IL-4, which increased expression of CD54, CD58, CD80, and CD86. Stimulating CAR T cells with activated CLL cells enhanced CAR T cell proliferation and induced cell conjugate formation, indicating cell activation. Therefore, improving CLL stimulatory capacity can rescue T cell dysfunctions. To assess whether IL-2 addition and CD40 ligation were synergistic, we combined the two assays; however, we saw no additional improvement over IL-2 addition alone, suggesting that the two interventions may act upon the same pathway. Importantly, we also showed that rescue of CAR T cell function via IL-2 addition or CD40 ligation was not CAR-specific, as we observed the functional defects and subsequent rescue with both a ROR1-targeting CAR and the gold standard CD19-targeting CAR. Conclusions: Together, these data show that CAR T cell "defects" in CLL are actually insufficient activation, and improving the stimulatory capacity of CLL cells may enable better clinical responses. Further, this effect is not CAR-specific and these results may therefore be broadly applicable to multiple therapies for this disease. Disclosures Melenhorst: IASO Biotherapeutics: Membership on an entity's Board of Directors or advisory committees, Research Funding; Kite Pharma: Research Funding; Novartis: Other: Speaker, Research Funding; Johnson & Johnson: Consultancy, Other: Speaker; Simcere of America: Consultancy; Poseida Therapeutics: Consultancy.

scholarly journals A Preclinical Embryonic Zebrafish Xenograft Model to Investigate CAR T Cells in Vivo

Cancers ◽  
2020 ◽  
Vol 12 (3) ◽  
pp. 567 ◽  
Author(s):  
Susana Pascoal ◽  
Benjamin Salzer ◽  
Eva Scheuringer ◽  
Andrea Wenninger-Weinzierl ◽  
Caterina Sturtzel ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cellular Therapy ◽  
Xenograft Model ◽  
Model Systems ◽  
Preclinical Model ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T

Chimeric antigen receptor (CAR) T cells have proven to be a powerful cellular therapy for B cell malignancies. Massive efforts are now being undertaken to reproduce the high efficacy of CAR T cells in the treatment of other malignancies. Here, predictive preclinical model systems are important, and the current gold standard for preclinical evaluation of CAR T cells are mouse xenografts. However, mouse xenograft assays are expensive and slow. Therefore, an additional vertebrate in vivo assay would be beneficial to bridge the gap from in vitro to mouse xenografts. Here, we present a novel assay based on embryonic zebrafish xenografts to investigate CAR T cell-mediated killing of human cancer cells. Using a CD19-specific CAR and Nalm-6 leukemia cells, we show that live observation of killing of Nalm-6 cells by CAR T cells is possible in zebrafish embryos. Furthermore, we applied Fiji macros enabling automated quantification of Nalm-6 cells and CAR T cells over time. In conclusion, we provide a proof-of-principle study that embryonic zebrafish xenografts can be used to investigate CAR T cell-mediated killing of tumor cells. This assay is cost-effective, fast, and offers live imaging possibilities to directly investigate CAR T cell migration, engagement, and killing of effector cells.

scholarly journals "IF-Better" Gating: Combinatorial Targeting and Synergistic Signaling for Enhanced CAR T Cell Efficacy

Blood ◽  
2021 ◽  
Vol 138 (Supplement 1) ◽  
pp. 2774-2774
Author(s):  
Sascha Haubner ◽  
Jorge Mansilla-Soto ◽  
Sarah Nataraj ◽  
Xingyue He ◽  
Jae H Park ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Target Antigen ◽  
Normal Cells ◽  
Car T Cells ◽  
Car T Cell ◽  
Car T ◽  
Provision Of Services ◽  
Xenograft Models

Abstract CAR T cell therapy provides a potent therapeutic option in various B cell-related hematologic malignancies. One of the major efficacy challenges is escape of tumor cells with low antigen density, which has been clinically observed in several malignancies treated with CAR therapy. Novel concepts of CAR design are needed to address phenotypic heterogeneity including clonal variability of target antigen expression. In the study presented here, we focused on AML and selected ADGRE2 as CAR target due to its high rate of positivity on AML bulk and leukemic stem cells (LSC) in a molecularly heterogeneous AML patient population. We chose an ADGRE2-CAR with optimized scFv affinity and fine-tuned CD3zeta signaling to achieve an ideal killing threshold that would allow for sparing of ADGRE2-low normal cells. We hypothesized that co-targeting of a second AML-related antigen may mitigate potential CAR target antigen-low AML escape and we identified CLEC12A as preferential co-target due to its non-overlapping expression profiles in normal hematopoiesis and other vital tissues. We developed ADCLEC.syn1, a novel combinatorial CAR construct consisting of an ADGRE2-targeting 28z1XX-CAR and a CLEC12A-targeting chimeric costimulatory receptor (CCR). ADCLEC.syn1 operates based on what we describe as "IF-BETTER" gate: High CAR target expression alone triggers killing, whereas low CAR target expression does not, unless a CCR target is present. Additional CCR interaction lowers the threshold for CAR-mediated killing through increased avidity and costimulation, allowing for higher CAR sensitivity that is purposefully limited to target cells expressing both antigens. In the context of ADCLEC.syn1, ADGRE2-high/CLEC12A-negative AML cells can trigger cell lysis while ADGRE2-low/CLEC12A-negative normal cells are spared. Importantly, ADGRE2-low/CLEC12A-high AML cells are also potently eliminated, preventing ADGRE2-low AML escape. Using NSG in-vivo xenograft models of engineered MOLM13 AML cell line variants with low levels of ADGRE2 to model antigen escape, we found that ADCLEC.syn1 outperforms a single-ADGRE2-CAR lacking assistance via CLEC12A-CCR. Importantly, ADCLEC.syn1 also outperformed an otherwise identical alternative dual-CAR version (OR-gated ADGRE2-CAR+CLEC12A-CAR) in the setting of both ADGRE2-high and ADGRE2-low MOLM13, further underlining the importance of fine-tuned overall signaling. We confirmed high in-vivo potency against diverse AML cell lines with a wide range of ADGRE2 and CLEC12A levels reflecting population-wide AML heterogeneity. At clinically relevant CAR T cell doses, ADCLEC.syn1 induced complete and durable remissions in xenograft models of MOLM13 (ADGRE2-high/CLEC12A-low) and U937 (ADGRE2-low/CLEC12A-high). ADCLEC.syn1 CAR T cells were found to be functionally persistent for >70 days, with a single CAR T cell dose potently averting relapse modeled via AML re-challenges. In summary, we provide pre-clinical evidence that an "IF-BETTER"-gated CAR+CCR T cell (ADCLEC.syn1) can outperform a single-CAR T cell (ADGRE2-CAR) and a dual-CAR T cell (ADGRE2-CAR+CLEC12A-CAR). ADCLEC.syn1 enhances antileukemic efficacy and prevents antigen-low AML escape via detection of a rationally selected combinatorial target antigen signature that is commonly found in AML but limited in vital normal cells. Using phenotypically representative AML xenograft models and clinically relevant T cell doses, we demonstrate high therapeutic potential of ADCLEC.syn1 CAR T cells, further supporting clinical translation of an "IF-BETTER"-gated CAR concept into a phase 1 trial. Disclosures Haubner: Takeda Pharmaceuticals Company Ltd.: Patents & Royalties: Co-inventor of IP that MSK licensed to Takeda, Research Funding. Mansilla-Soto: Takeda Pharmaceuticals Company Ltd.: Patents & Royalties; Atara Biotherapeutics: Patents & Royalties; Fate Therapeutics: Patents & Royalties; Mnemo Therapeutics: Patents & Royalties. He: Takeda Pharmaceuticals Company Ltd.: Ended employment in the past 24 months, Patents & Royalties. Park: Curocel: Consultancy; BMS: Consultancy; Innate Pharma: Consultancy; Autolus: Consultancy; Servier: Consultancy; Kite Pharma: Consultancy; Affyimmune: Consultancy; Intellia: Consultancy; Minerva: Consultancy; PrecisionBio: Consultancy; Amgen: Consultancy; Kura Oncology: Consultancy; Artiva: Consultancy; Novartis: Consultancy. Rivière: Juno Therapeutics: Patents & Royalties; Fate Therapeutics: Other: Provision of Services, Patents & Royalties; Centre for Commercialization of Cancer Immunotherapy: Other: Provision of Services; The Georgia Tech Research Corporation (GTRC): Other: Provision of Services (uncompensated); FloDesign Sonics: Other: Provision of Services. Sadelain: NHLBI Gene Therapy Resource Program: Other: Provision of Services (uncompensated); St. Jude Children's Research Hospital: Other: Provision of Services; Minerva Biotechnologies: Patents & Royalties; Mnemo Therapeutics: Patents & Royalties; Juno Therapeutics: Patents & Royalties; Fate Therapeutics: Other: Provision of Services (uncompensated), Patents & Royalties; Ceramedix: Patents & Royalties; Takeda Pharmaceuticals: Other: Provision of Services, Patents & Royalties; Atara Biotherapeutics: Patents & Royalties.

scholarly journals Therapeutic Targeting of Monokine Production Is a Promising Strategy to Attenuate Cytokine-Release Syndrome in CAR-T Cell Therapy

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 2067-2067
Author(s):  
Muneyoshi Futami ◽  
Keisuke Suzuki ◽  
Satomi Kato ◽  
Yoshio Tahara ◽  
Yoichi Imai ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Research Funding ◽  
Cytokine Production ◽  
Cytokine Release ◽  
Killing Effect ◽  
Car T Cells ◽  
Car T Cell ◽  
Tnf Α ◽  
Car T

Cancer immunotherapy using chimeric antigen receptor-armed T cells (CAR-T cells) have shown excellent outcomes in hematological malignancies. However, cytokine release syndrome (CRS), characterized by excessive activation of CAR-T cells and macrophages remains to be overcome. Steroid administration usually resolves signs and symptoms of CRS but abrogates CAR-T cell expansion and persistence. Tocilizumab, a humanized monoclonal antibody against interleukin-6 receptor (IL-6R), attenuates CRS without significant loss of CAR-T cell activities, while perfect rescue of CRS symptoms cannot be achieved by IL-6/IL-6R blockade. There is actual need for novel strategies to prevent or cure CRS. TO-207, an N-benzoyl-L-phenylalanine derivative compound, significantly inhibits inflammatory cytokine production in a human monocyte/macrophage-specific manner. Here we tested TO-207 for its ability to inhibit cytokine production without impaired CAR-T cell function in a CRS-simulating co-culture system consisting of CAR-T cells, target leukemic cells and monocytes. To observe a precise pattern of cytokine release from CAR-T cells and monocytes, we first established a co-culture system that mimics CRS using K562/CD19 cells, 19-28z CAR-T cells, and peripheral blood CD14+ cells. IFN-γ was produced exclusively from CAR-T cells, and TNF-α, MIP-1α, M-CSF, and IL-6 were produced from both CAR-T cells and monocytes, but monocytes were the major source of these cytokine production. MCP-1, IL-1β, IL-8, and IL-10 were released exclusively from monocytes. To observe the effect of drugs on cytokine production, prednisolone (PSL), TO-207, tocilizumab, and anakinra (an IL-1R antagonist) were added to the co-culture. PSL exhibited suppressive effects on TNF-α and MCP-1 production. Tocilizumab did not suppress these cytokines. Anakinra up-regulated IL-6 and IL-1β production, probably due to activation of negative feedback loops. Interestingly, TO-207 widely suppressed all of these monocyte-derived cytokines including TNF-α, IL-6, IL-1β, MCP-1, IL-8, and GM-CSF. Next, we observed whether the cytokine inhibition by TO-207 attenuates killing effect of CAR-T cells. PSL attenuated killing effect of CD4+ CAR-T cells and CD8+ CAR-T cells toward K562/CD19 cells. In contrast, TO-207 did not exhibit any change in cytotoxicity of CD4+ CAR-T cells and CD8+ CAR-T cells. To determine whether the effect of PSL and TO-207 on cytotoxicity changes in the presence of CD14+ monocytes, CD14+ cells were added to the co-culture. In the absence of CAR-T cells, PSL induced a modest attenuation of cytotoxicity, whereas to the CAR-T cells, PSL exhibited a significant attenuation of cytotoxicity. TO-207 exhibited a minimal effect on cytotoxicity in the absence or presence of CAR-T cells. These results suggested that CAR-T cells play a major role in the cytotoxicity toward leukemia cells, and drugs that do not affect CAR-T cell functions, such as TO-207, maintain their cytotoxic effects on leukemia cells. In conclusion, our present co-culture model with K562/CD19 cells, 19-28z CAR-T cells, and CD14+ monocytes accurately recapitulate killing effect and cytokine release profiles. IFN-γ was produced exclusively by CAR-T cells, but majority of other cytokines such as TNF-α, MIP-1α, M-CSF, IL-6, MCP-1, IL-1β, IL-8, and IL-10 were from CD14+ monocytes/macrophages. Because killing effect was largely dependent on CAR-T cells while cytokine production was dependent on monocytes/macrophages, selective inhibition of pro-inflammatory cytokines from monocytes by TO-207 would be ideal for treatment of CAR-T-related CRS. These results encourage us to consider a clinical application for CRS. Figure Disclosures Futami: Torii Pharmaceutical: Research Funding. Suzuki:Torii Pharmaceutical: Employment. Kato:Torii Pharmmaceutical: Research Funding. Tahara:Torii Pharmaceutical: Employment. Imai:Celgene: Honoraria, Research Funding; Janssen Pharmaceutical K.K: Honoraria, Research Funding; Bristol-Myers Squibb: Research Funding. Mimura:Torii Pharmaceutical: Employment. Watanabe:Torii Pharmaceutical: Employment. Tojo:AMED: Research Funding; Torii Pharmaceutical: Research Funding.

IL-18 Secreting CAR T Cells Enhance Cell Persistence, Induce Prolonged B Cell Aplasia and Eradicate CD19+ Tumor Cells without Need for Prior Conditioning

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 816-816 ◽  
Author(s):  
Mauro P. Avanzi ◽  
Dayenne G. van Leeuwen ◽  
Xinghuo Li ◽  
Kenneth Cheung ◽  
Hyebin Park ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Tumor Cells ◽  
Car T Cells ◽  
Car T Cell ◽  
Cytokine Analysis ◽  
Car T ◽  
Ifn Γ

Abstract Chimeric antigen receptor (CAR) T cell therapy has consistently shown significant results against acute lymphoblastic leukemia (ALL) in clinical trials1. However, results with other hematological or solid malignancies have been far more modest2. These disparate outcomes could be partially due to an inhibitory tumor microenvironment that suppresses CAR T cell function3. Thus, in order to expand the anti-tumor CAR T cell applications, a novel strategy in which these cells are capable of overcoming the hostile tumor microenvironment is needed. The cytokine interleukin-18 (IL-18) induces IFN-γ secretion, enhances the Th1 immune response and activates natural killer and cytotoxic T cells4. Early phase clinical trials that utilized systemic administration of recombinant IL-18 for the treatment of both solid and hematological malignancies have demonstrated the safety of this therapy5. We hypothesize that CAR T cells that constitutively secrete IL-18 could enhance CAR T cell survival and anti-tumor activity, and also activate cells from the endogenous immune system. To generate CAR T cells that constitutively secrete IL-18, we modified SFG-1928z and SFG-19m28mz CAR T cell constructs and engineered bicistronic human and murine vectors with a P2A element to actively secrete the IL-18 protein (1928z-P2A-hIL18 and 19m28mz-P2A-mIL18, respectively). Human and mouse T cells were transduced with these constructs and in vitro CAR T cell function was validated by coculturing the CAR T cells with CD19+ tumor cells and collecting supernatant for cytokine analysis. Both human and mouse CAR T cells secreted increased levels of IL-18, IFN-γ and IL-2. Proliferation and anti-tumor cytotoxic experiments were conducted with human T cells by coculturing CAR T cells with hCD19+ expressing tumor cells. 1928z-P2A-hIL18 CAR T cells had enhanced proliferation over 7 days and enhanced anti-tumor cytotoxicity over 72 hours when compared to 1928z CAR T cells (p=0.03 and 0.01, respectively) Next, the in vivo anti-tumor efficacy of the IL-18 secreting CAR T cell was tested in xenograft and syngeneic mouse models. Experiments were conducted without any prior lympho-depleting regimen. In the human CAR T cell experiments, Scid-Beige mice were injected with 1x106 NALM-6 tumor cells on day 0 and 5x106 CAR T cells on day 1. Survival curves showed a significant improvement in mouse survival with the 1928z-P2A-hIL18 CAR T cell treatment when compared to 1928z CAR T cell (p=0.006). Subsequently, to determine if IL-18 secreting CAR T cells could also improve anti-tumor efficacy in immunocompetent mice, we tested the murine 19m28mz-P2A-mIL18 CAR T cells in a syngeneic mouse model. The C57BL/6 hCD19+/- mCD19+/- mouse model was utilized and injected with 1x106 EL4 hCD19+ tumor cells on day 0 and 2.5 x106 CAR T cells on day 1. Mice treated with 19m28mz-P2A-mIL18 CAR T cells had 100% long-term survival, when compared to 19m28mz (p<0.0001). 19m28mz-P2A-mIL18 CAR T cells were detected in peripheral blood for up to 30 days after injection, whereas the 19m28mz CAR T cells were not detectable at any time point. In addition, 19m28mz-P2A-mIL18 CAR T cells were capable of inducing B cell aplasia for greater than 70 days, whereas 19m28mz treatment was not capable of inducing B cell aplasia. In vivo serum cytokine analysis demonstrated that 19m28mz-P2A-mIL18 CAR T cells, as compared to 19m28mz, significantly increased the levels of IFN-γ and TNF-α in the peripheral blood for up to 14 days after injection (p<0.0001 and 0.01, respectively). Despite the increase in IFN-γ and TNF-α cytokines, there was no increase in IL-6 levels. Our findings demonstrate that anti-CD19 CAR T cells that constitutively secrete IL-18 significantly increase serum cytokine secretion, enhance CAR T cell persistence, induce long-term B cell aplasia and improve mouse survival, even without any prior preconditioning. To our knowledge, this is the first description of an anti-CD19 CAR T cell that constitutively secretes IL-18 and that induces such high levels of T cell proliferation, persistence and anti-tumor cytotoxicity. We are currently investigating other mechanisms by which this novel CAR T cell functions, its interactions with the endogenous immune system, as well as testing its applicability in other tumor types. We anticipate that the advances presented by this new technology will expand the applicability of CAR T cells to a wider array of malignancies. Disclosures Brentjens: Juno Therapeutics: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding.

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