Selective targeting of HER2-overexpressing solid tumors with a next-generation CAR-T cell therapy.

2020 â—½  
Vol 38 (15_suppl) â—½  
pp. 3041-3041
Author(s):  
Jenny Mu â—½  
Justin Edwards â—½  
Liubov Zaritskaya â—½  
Jeffrey Swers â—½  
Ankit Gupta â—½  
...  
Keyword(s):  
T Cells â—½  
T Cell â—½  
Tumor Cells â—½  
T Cell Activation â—½  
Cell Activation â—½  
Antigen Receptor â—½  
Target Antigen â—½  
Target Cells â—½  
Car T

3041 Background: Conventional chimeric antigen receptor T cell (CAR-T) therapies have achieved limited clinical success in the treatment of solid tumors, in part due to the challenges of identifying tumor antigen(s) that are uniquely expressed on tumor cells. The dearth of such targets requires that current CAR-T therapies be re-engineered to preferentially target tumor cells thereby mitigating potential on-target off-tumor toxicity to normal cells. Herein we describe a novel cell therapy platform comprising Antigen Receptor Complex T (ARC-T) cells that are readily activated, silenced, and reprogrammed in vivo by administration of a novel tumor-targeting soluble protein antigen-receptor X-linker (sparX). The formation of the ARC-T, sparX, and tumor complex is required for the ARC-T to kill the tumor. Because ARC-T activity is entirely dependent on the dose of sparX administered, therapeutic doses of sparX may be defined that preferentially target cells over-expressing a target antigen and thus limit coincident kill of normal cells expressing lower levels of target antigen. Methods: We have created a library of sparX that bind different cell surface antigens, including HER2. The HER2 sparX was tested as both monovalent and bivalent constructs in vitro by assessing ARC-T cell activation, cytokine release and target cell cytotoxicity. In vivo efficacy models utilized NSG mice and incorporated tumor volume measurements and histopathologic assessments to evaluate tumor clearance. Results: In vitro studies demonstrate that co-culture of ARC-T cells, sparX-HER2 and HER2-expressing target cells drives T cell activation, expansion, cytokine secretion and cytotoxicity of target cells in a dose-dependent manner. Furthermore, by affinity tuning the HER2 binding domain and bivalent formatting of sparX-HER2, we achieved selective killing of HER2-overexpressing breast cancer cells with minimal effect on cells expressing HER2 levels representative of normal tissues. In vivo proof-of-principal studies with ARC-T/sparX-HER2 similarly demonstrate complete eradication of HER2-overexpressing solid tumor cells. Conclusions: These results demonstrate that a single intravenous dose of ARC-T cells can traffic to a solid tumor site and induce tumor eradication upon systemic administration and co-localization of tumor-targeting sparX in a mouse model. Bivalent formatting of sparX-HER2 further enabled ARC-T sensitivity to target antigen density to avoid the on-target off-tumor toxicity that has hindered conventional monovalent CAR-T treatments.

Inducible MyD88/CD40 Allows Rimiducid-Dependent Activation to Control Proliferation and Survival of Chimeric Antigen Receptor-Modified T Cells

Blood â—½  
2015 â—½  
Vol 126 (23) â—½  
pp. 4295-4295 â—½  
Author(s):  
Aaron Foster â—½  
Aruna Mahendravada â—½  
Nicholas P Shinners â—½  
Peter Chang â—½  
An Lu â—½  
...  
Keyword(s):  
T Cells â—½  
T Cell â—½  
Tumor Cells â—½  
T Cell Activation â—½  
Cell Activation â—½  
First Generation â—½  
Car T Cell â—½  
Car T â—½  
Equity Ownership

Abstract Introduction: Adoptive transfer of T cells, genetically engineered to express chimeric antigen receptors (CARs) containing costimulatory domains, such as CD28 or 4-1BB, has yielded impressive clinical results in some blood cancers, but severe toxicities have been observed due to unchecked T cell activation. In contrast, CAR-T cells have demonstrated limited clinical efficacy, associated with poor engraftment, survival and proliferation of adoptively transferred cells when used to target a variety of solid tumors. Thus, technologies that can regulate T cell activation and proliferation in vivo should both mitigate toxicities and maximize anti-tumor efficacy, expanding their clinical utility to a wider range of indications. Here, we describe a novel T cell costimulation switch, inducible MyD88/CD40 (iMC), activated by a small molecule chemical inducer of dimerization, rimiducid, to enhance survival and drive T cell proliferation. Methods: T cells were activated with anti-CD3/28 and transduced with a retrovirus encoding tandem rimiducid-binding domains (FKBP12v36),cloned in-frame with MyD88 and CD40 signaling elements, and first generation CARs (CAR.ζ) targeting CD19 or PSCA (SFG-iMC-2A-CD19.ζ or SFG-iMC-2A-PSCA.ζ, respectively). iMC activation was measured by treating T cells with and without rimiducid and measuring cytokine production by ELISA and T cell activation markers by flow cytometry. Coactivation through iMC and CAR was tested in coculture assays with or without rimiducid using various tumor cells (CD19+, Raji and Daudi lymphoma; PSCA+, Capan-1 and HPAC pancreatic adenocarcinoma). Efficacy of iMC-modified CAR-T cells were assessed using an immune-deficient NSG mouse tumor model. For CD19-targeted CARs, 1x105 Raji tumor cells were injected i.v. followed on day 7 by a single i.v. injection at various doses of iMC-CD19.ζ-modified T cells. For PSCA-targeted CARs, 2x106 HPAC tumor cells were injected s.c. followed by iMC-PSCA.ζ-modified T cells on day 10. In both models, iMC was activated in vivo by weekly i.p. injections of rimiducid (5 mg/kg). In some experiments, iMC-CAR-modified T cells were engrafted into tumor-free mice. Tumor burden and CAR-T cell expansion in vivo was assessed using luciferase bioluminescent imaging and flow cytometry. Results: T cells transduced with either iMC-CD19.ζ or iMC-PSCA.ζ produce cytokines (e.g., IFN-γ and IL-6) in response to rimiducid; however, the key growth and survival cytokine, IL-2, was only produced when both iMC and CAR were activated simultaneously by rimiducid and tumor antigen, respectively. CD19+ Raji tumor-bearing mice treated with iMC-CD19.ζ-modified T cells with or without rimiducid administration increased survival compared to non-transduced T cells (p = 0.01). However, rimiducid treatment induced a 7.3-fold CAR-T cell expansion compared to mice infused with iMC-CD19.ζ, but untreated with dimer drug (p = 0.02). Additionally, treatment of NSG mice bearing large (>200 mm3) HPAC tumors with a single dose iMC-PSCA.ζ, resulted in complete elimination in 10/10 mice (100%) of tumors both with and without rimiducid treatment compared to mice receiving non-transduced T cells (p = 0.0003). Rimiducid administration again dramatically increased CAR-T cell levels, resulting in a 23-fold expansion of iMC-PSCA.ζ-modified T cells compared to mice not receiving rimiducid (p = 0.02), justifying ongoing experiments using larger tumors at baseline with fewer T cells. In addition, in tumor-free mice, rimiducid prolonged iMC-PSCA.ζ-modified T cell engraftment and survival for 28 days compared to those mice not treated with dimerizer (p = 0.03). Importantly, following rimiducid withdrawal, CAR-T cell numbers declined, consistent with the requirement of MC-mediated costimulation in combination with CAR activation. Summary: Inducible MyD88/CD40 represents a novel activation switch that can be used to provide a controllable costimulatory signal to T cells transduced with a first generation CAR. The separation of the cytolytic signal 1 (CD3ζ) domain from a potent, regulatable, signal 2 costimulation (iMC) in the novel platform, called "GoCAR-T", allows the expansion of T cells only in response to both rimiducid and tumor antigen, and their decrease in number by withdrawal of rimiducid-induced iMC costimulation. The "GoCAR-T" platform may allow the development of a new generation of more effective CAR-T cell therapies. Disclosures Foster: Bellicum Pharmaceuticals: Employment. Mahendravada:Bellicum Pharmaceuticals: Employment. Shinners:Bellicum Pharmaceuticals: Employment. Chang:Bellicum Pharmaceuticals: Employment. Lu:Bellicum Pharmaceuticals: Employment. Morschl:Bellicum Pharmaceuticals: Employment. Shaw:Bellicum Pharmaceuticals: Employment. Saha:Bellicum Pharmaceuticals: Employment. Slawin:Bellicum Pharmaceuticals: Employment, Equity Ownership. Spencer:Bellicum Pharmaceuticals: Employment, Equity Ownership.

scholarly journals 206 The development of ‘chimeric CD3e fusion protein’ and ‘anti-CD3-based bispecific T cell activating element’ engineered T (CAB-T) cells for the treatment of solid malignancies

2021 â—½  
Vol 9 (Suppl 3) â—½  
pp. A217-A217
Author(s):  
Andy Tsun â—½  
Zhiyuan Li â—½  
Zhenqing Zhang â—½  
Weifeng Huang â—½  
Shaogang Peng â—½  
...  
Keyword(s):  
T Cells â—½  
T Cell â—½  
Fusion Protein â—½  
T Cell Activation â—½  
Cell Activation â—½  
In Vivo Studies â—½  
Cytokine Release â—½  
Car T Cells â—½  
Car T

BackgroundCancer immunotherapy has achieved unprecedented success in the complete remission of hematological tumors. However, serious or even fatal clinical side-effects have been associated with CAR-T therapies to solid tumors, which mainly include cytokine release syndrome (CRS), immune effector cell-associated neurotoxicity syndrome (ICANS), macrophage activation syndrome, etc. Furthermore, CAR-T therapies have not yet demonstrated significant clinical efficacy for the treatment of solid tumors. Here, we present a novel T cell therapeutic platform: a Chimeric CD3e fusion protein and anti-CD3-based bispecific T cell activating element (BiTA) engineered T (CAB-T) cells, which target tumor antigens via the secretion of BiTAs that act independently of MHC interactions. Upon BiTA secretion, CAB-T cells can simultaneously achieve anti-tumor cytotoxic effects from the CAB-T cells and simultaneously activate bystander T cells.MethodsCAB-T cells were generated by co-expressing a chimeric CD3e fusion protein and an anti-CD3-based bispecific T cell activating element. The chimeric CD3e contains the extracellular domain of CD3e, a CD8 transmembrane domain, 4-1BB costimulatory domain, CD3z T cell activation domain and a FLAG tag, while the BiTA element includes a tumor antigen targeting domain fused with an anti-CD3 scFv domain and a 6x His-tag. CAR-T cells were generated as a control. Cytokine release activity, T cell activation and exhaustion markers, T cell killing activity and T cell differentiation stages were analysed. We also tested their tumor growth inhibition activity, peripheral and tumor tissue distribution, and their safety-profiles in humanized mouse models.ResultsCAB-T cells have similar or better in vitro killing activity compared with their CAR-T counterparts, with lower levels of cytokine release (IL-2 and IFNγ). CAB-T cells also showed lower levels of exhaustion markers (PD-1, LAG-3 and TIM-3), and higher ratios of naive/Tscm and Tcm T cell populations, after co-culture with their target tumor cells (48h). In in vivo studies, CAIX CAB-T and HER2 CAB-T showed superior anti-tumor efficacy and tumor tissue infiltration activity over their corresponding CAR-T cells. For CLDN18.2 CAB-T cells, similar in vivo anti-tumor efficacy was observed compared to CAR-T after T cell infusion, but blood glucose reduction and animal mortality was observed in the mice administered with CAR-T cells.ConclusionsThe advantages of CAB-T in in vitro and in vivo studies may result from TCR signal activation of both the engineered CAB-T cells and the non-engineered bystander T cells via cross-bridging by the secreted BiTA molecules, thus offering superior anti-tumor efficacy with a potential better safety-profile compared to conventional CAR-T platforms.

scholarly journals Immunologic ignorance of vascular endothelial cells expressing minor histocompatibility antigen

Blood â—½  
2008 â—½  
Vol 111 (9) â—½  
pp. 4588-4595 â—½  
Author(s):  
Beatrice Bolinger â—½  
Philippe Krebs â—½  
Yinghua Tian â—½  
Daniel Engeler â—½  
Elke Scandella â—½  
...  
Keyword(s):  
T Cells â—½  
Endothelial Cells â—½  
T Cell â—½  
T Cell Activation â—½  
Cd8 T Cells â—½  
Cell Activation â—½  
Histocompatibility Antigen â—½  
Target Cells â—½  
Minor Histocompatibility Antigen

Abstract Endothelial cells (ECs) presenting minor histocompatibility antigen (mhAg) are major target cells for alloreactive effector CD8+ T cells during chronic transplant rejection and graft-versus-host disease (GVHD). The contribution of ECs to T-cell activation, however, is still a controversial issue. In this study, we have assessed the antigen-presenting capacity of ECs in vivo using a transgenic mouse model with beta-galactosidase (β-gal) expression confined to the vascular endothelium (Tie2-LacZ mice). In a GVHD-like setting with adoptive transfer of β-gal–specific T-cell receptor–transgenic T cells, β-gal expression by ECs was not sufficient to either activate or tolerize CD8+ T cells. Likewise, transplantation of fully vascularized heart or liver grafts from Tie2-LacZ mice into nontransgenic recipients did not suffice to activate β-gal–specific CD8+ T cells, indicating that CD8+ T-cell responses against mhAg cannot be initiated by ECs. Moreover, we could show that spontaneous activation of β-gal–specific CD8+ T cells in Tie2-LacZ mice was exclusively dependent on CD11c+ dendritic cells (DCs), demonstrating that mhAgs presented by ECs remain immunologically ignored unless presentation by DCs is granted.

A T Cell-Engaging CD3 Recruit-Tandab Potently Kills CD19+ Tumor B Cells

Blood â—½  
2012 â—½  
Vol 120 (21) â—½  
pp. 3721-3721
Author(s):  
Eugene Zhukovsky â—½  
Uwe Reusch â—½  
Carmen Burkhardt â—½  
Stefan Knackmuss â—½  
Ivica Fucek â—½  
...  
Keyword(s):  
T Cells â—½  
T Cell â—½  
Tumor Growth â—½  
B Cell â—½  
T Cell Activation â—½  
Cell Activation â—½  
Target Cells â—½  
Cytotoxicity Assays

Abstract Abstract 3721 Background: CD19 is expressed from early B cell development through differentiation into plasma cells, and is an attractive alternative to CD20 as a target for the development of therapeutic antibodies to treat B cell malignancies. T cells are potent tumor-killing effector cells that cannot be recruited by native antibodies. The CD3 RECRUIT-TandAb AFM11, a humanized bispecific tetravalent antibody with two binding sites for both CD3 and CD19, is a novel therapeutic for the treatment of NHL that harnesses the cytotoxic nature of T cells. Methods: We engineered a bispecific anti-CD19/anti-CD3e tetravalent TandAb with humanized and affinity-matured variable domains. The TandAb's binding properties, T cell-mediated cytotoxic activity, and target-mediated T cell activation were characterized in a panel of in vitro assays. In vivo efficacy was evaluated in a murine NOD/scid xenograft model reconstituted with human PBMC. Results: AFM11 mediates highly potent CD19+ tumor cell lysis in cytotoxicity assays performed on a panel of cell lines (JOK-1, Raji, Nalm-6, MEC-1, VAL, Daudi) and primary B-CLL tumors: EC50 values are in the low- to sub-picomolar range and do not correlate with the expression density of CD19 on the target cell lines. The cytotoxic activity of tetravalent AFM11 is superior to that of alternative bivalent antibody formats possessing only a single binding site for both CD19 and CD3. High affinity binding of AFM11 to CD19 and to CD3 is essential for efficacious T cell recruitment. Both CD8+ and CD4+ T cells mediate cytotoxicity however the former exhibit much faster killing. We observe that AFM11 displays similar cytotoxic efficacy at different effector to target ratios (from 5:1 to 1:5) in cytotoxicity assays; this suggests that T cells are engaged in the serial killing of CD19+ target cells. In the absence of CD19+ target cells in vitro, AFM11 does not elicit T cell activation as manifested by cytokine release (from a panel of ten cytokines associated with T cell activation), their proliferation, or their expression of activation markers. AFM11 activates T cells exclusively in the presence of its targets and mediates lysis of CD19+ cells while sparing antigen-negative bystanders. In the absence of CD19+ target cells, AFM11 concentrations in excess of 500-fold over EC50 induce down-modulation of the CD3/TCR complex. Yet, AFM11-treated T cells can be re-engaged for target cell lysis. All of these features of AFM11-induced T cell activation may contribute additional safety without compromising its efficacy. In vivo AFM11 demonstrates a robust dose-dependent inhibition of subcutaneous Raji tumors in mice. At 5 mg/kg AFM11 demonstrates a complete suppression of tumor growth, and even at 5 ug/kg tumor growth is reduced by 60%. Moreover, we observe that a single administration of AFM11 produces inhibition of tumor growth similar to that of 5 consecutive administrations. Conclusions: In summary, our in vitro and in vivo experiments with AFM11 demonstrate the high potency and efficacy of its anti-tumor cytotoxicity. Thus, AFM11 is a novel highly efficacious drug candidate for the treatment of B cell malignancies with an advantageous safety profile. Disclosures: Zhukovsky: Affimed Therapeutics AG: Employment, Equity Ownership. Reusch:Affimed Therapeutics AG: Employment. Burkhardt:Affimed Therapeutics AG: Employment. Knackmuss:Affimed Therapeutics AG: Employment. Fucek:Affimed Therapeutics AG: Employment. Eser:Affimed Therapeutics AG: Employment. McAleese:Affimed Therapeutics AG: Employment. Ellwanger:Affimed Therapeutics AG: Employment.

scholarly journals AMV564 Depletes Myeloid-Derived Suppressor Cells and Expands T Cells: Potential to Address Key Limitations of Cellular Therapies

Blood â—½  
2021 â—½  
Vol 138 (Supplement 1) â—½  
pp. 1702-1702
Author(s):  
Sterling Eckard â—½  
Bianca Rojo â—½  
Victoria Smith â—½  
Patrick Chun
Keyword(s):  
T Cells â—½  
T Cell â—½  
T Cell Activation â—½  
Cd8 T Cells â—½  
Cell Activation â—½  
Ex Vivo â—½  
Suppressor Cells â—½  
Target Cells â—½  
Myeloid Derived Suppressor Cells â—½  
Car T

Abstract Background Myeloid-derived suppressor cells (MDSC) contribute to an immunosuppressive tumor environment and are a barrier to immune therapeutic approaches, including cell-based therapies such as chimeric antigen receptor T cells (CAR T). Despite good overall response rates with certain subsets of B cell leukemias and lymphomas, a significant percentage of patients treated with CAR T therapy do not respond or subsequently relapse. Poor CAR T expansion, poor persistence of infused cells, and clinical treatment failure are associated with tumor and systemic immune dysregulation including high blood levels of peripheral blood monocytic MDSC (M-MDSCs) and interleukin-6, both of which are associated with lack of durable responses 1. In addition, CAR T therapy has been limited by the occurrence of severe cytokine release syndrome (CRS), which is associated with high IL-6 production 2 by myeloid cells such as MDSC. AMV564 is a potent T cell engager that selectively depletes MDSC while promoting T cell activation and proliferation without significant IL-6 induction 3. In phase 1 studies in acute myeloid leukemia (AML), myelodysplastic syndrome (MDS), and solid tumors, AMV564 has been demonstrated to be clinically safe and active with some patients achieving complete remissions. Methods Cell lines, primary human cells, and patient samples were analyzed using flow cytometry with appropriate marker panels. T cell activation and cytotoxicity assays were conducted using primary human T cells from healthy donors and target cells (3:1 ratio) for 72 hours. T cell activation using ImmunoCult Human CD3/CD28 served as an assay reference. Results Analysis of patients treated with AMV564 demonstrated statistically significant selective depletion of M-MDSC by cycle 2 (Fig. 1A). While on AMV564 therapy, median IL-6 levels remained below 100 pg/mL despite robust T cell activation and expansion. Granzyme B production by CD8 T cells increased significantly between Cycle 1 and Cycle 2 in patients on therapy, and effector CD8 T cells expand over the course of treatment (Fig. 1B-C). These data collectively support the finding that AMV564 both removes a key source of immune suppression and is a potent agonist of T cell function and differentiation in patients. AMV564 potently activates and expands primary T cells ex vivo. Across donors, peak proliferation was significantly higher with AMV564 than with the CD3/CD28 reference (Fig. 2A). Importantly, T cell viability remained significantly higher with AMV564 when compared to reference control (CD3/CD28), and there was no evidence of activation-induced cell death (AICD) in AMV564-treated samples (Fig. 2B). Conclusions AMV564 depletes MDSC and stimulates expansion and longevity of T cells without significant IL-6 induction, suggesting a possible strategy for improvement in efficacy of cell-based therapy such as CAR T approaches. As circulating M-MDSC both at baseline and after CAR T infusion correlate with poor clinical efficacy 4, AMV564 may have beneficial effects during the conditioning phase of cell therapy, after re-infusion of CAR T products into patients, or both. Ex vivo studies using donor T cells and ongoing in vitro studies using CAR T molecules suggest that AMV564 may provide dual benefit with respect to both depletion of MDSC and T cell agonism. References 1. Jain, et al; Blood 2021; 137 (19): 2621-2633. doi: https://doi.org/10.1182/blood.2020007445 2. Li et al., Sci. Transl. Med. 11, eaax8861 (2019) 3. Eckard et al; Cancer Res 2021; (81) (13 Supplement) 528; DOI: 10.1158/1538-7445.AM2021-528 4. Jain, et al; Blood 2019; 134 (Supplement_1): 2885. doi: https://doi.org/10.1182/blood-2019-131041 Figure 1 Figure 1. Disclosures Eckard: Amphivena Therapeutics: Current Employment. Rojo: Amphivena Therapeutics: Current Employment. Smith: Amphivena Therapeutics: Current Employment. Chun: Amphivena Therapeutics: Current Employment.

scholarly journals P07.01 A modular and controllable T cell therapy platform for AML

2021 â—½  
Vol 9 (Suppl 1) â—½  
pp. A22.2-A23
Author(s):  
M Benmebarek â—½  
B Loureiro Cadilha â—½  
M Herrmann â—½  
S Schmitt â—½  
S Lesch â—½  
...  
Keyword(s):  
T Cells â—½  
T Cell â—½  
Cell Therapy â—½  
T Cell Activation â—½  
Tumour Cell â—½  
Cell Activation â—½  
Cell Lysis â—½  
Target Cells â—½  
Single Chain

BackgroundTargeted immunotherapies have shown limited success in the context of acute myeloid leukemia (AML). The mutational landscape, heterogeneity attributed to this malignancy and toxicities associated with the targeting of myeloid lineage antigens, it has become apparent that a modular and controllable cell therapy approach with the potential to target multiple antigens is required. We propose a controlled ACT approach, where T cells are equipped with synthetic agonistic receptors (SARs) that are selectively activated only in the presence of a target AML-associated antigen, and a cross-linking tandem single chain variable fragment (taFv) specific for both (SAR) T cell and tumour cell.Materials and MethodsA SAR composed of an extracellular EGFRvIII, trans- membrane CD28, and intracellular CD28 and CD3z domains was fused via overlap- extension PCR cloning. T cells were retrovirally transduced to stably express our SAR construct. SAR-specific taFvs that target AML-associated antigens were designed and expressed in Expi293FTM cells and purified by nickel affinity and size exclusion chromatography (SEC). We validated our approach in three human cancer models and patient-derived AML blasts expressing our AML-associated target antigens CD33 and CD123.ResultsAnti-CD33-EGFRvIII and anti-CD123 EGFRvIII taFv, monovalently selective for our SAR, induced conditional antigen-dependent activation, proliferation and differentiation of SAR-T cells. Further, SAR T cells bridged to their target cells by taFv could form functional immunological synapses, resulting in efficient tumor cell lysis with specificity towards CD33-expressing AML cells. SAR-taFv combination could also mediate specific cytotoxicity against patient-derived AML blasts and leukemic stem cells whilst driving SAR T cell activation. In vivo, treatment with SAR-taFv combination could efficiently eradicate leukemia and enhance survival in an AML xenograft models. Furthermore, we could show selective activation of SAR T cells, as well as a controllable reversibility and modularity of said activation upon depletion of the T cell engaging molecule, both in vitro and in vivo.ConclusionsHere we apply the SAR-taFv platform in efforts to deliver specific and conditional activation of SAR-transduced T cells, and targeted tumour cell lysis. The modularity of our platform will allow for a multi-targeting ACT approach with the potential to translate the ACT successes of B cell malignancies to AML. With a lack of truly specific AML antigens, it is invaluable that this approach possesses an intrinsic safety switch via its taFv facet. Moreover, we are able to circumvent pan-T cell activation due to the specific targeting and activation of SAR T cells.Disclosure InformationM. Benmebarek: None. B. Loureiro Cadilha: None. M. Herrmann: None. S. Schmitt: None. S. Lesch: None. S. Stoiber: None. A. Darwich: None. C. Augsberger: None. B. Brauchle: None. M. Schwerdtfeger: None. A. Gottschlich: None. A. Gottschlich Rataj: None. N.C. Fenn: None. C. Klein: None. M. Subklewe: None. S. Endres: None. K. Hopfner: None. S. Kobold: None.

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

2021 â—½  
Vol 11 â—½  
Author(s):  
Radhika Thokala â—½  
Zev A. Binder â—½  
Yibo Yin â—½  
Logan Zhang â—½  
Jiasi Vicky Zhang â—½  
...  
Keyword(s):  
T Cells â—½  
T Cell â—½  
Tumor Cells â—½  
Chimeric Antigen Receptor â—½  
Antigen Receptor â—½  
Tumor Escape â—½  
Car T Cells â—½  
Car T Cell â—½  
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.

Evaluation of monovalent versus biparatopic CD3xPSMA bispecific antibodies for t-cell mediated killing of prostate tumor cells with minimal cytokine release.

2019 â—½  
Vol 37 (15_suppl) â—½  
pp. e16519-e16519
Author(s):  
Ben Buelow â—½  
Starlynn Clarke â—½  
Kevin Dang â—½  
Jacky Li â—½  
Chiara Rancan â—½  
...  
Keyword(s):  
T Cells â—½  
T Cell â—½  
Tumor Cells â—½  
T Cell Activation â—½  
Cell Activation â—½  
Bispecific Antibodies â—½  
Cytokine Release â—½  
Binding Domains â—½  
Prostate Tumor Cells

e16519 Background: Castration resistant prostate cancer (CRPC) remains an incurable disease and new treatments are needed. Therapies directed against Prostate specific membrane antigen (PSMA) -such as radiolabeled antibodies, chimeric antigen receptor T cells (CAR-Ts) and T-cell engaging bispecific antibodies (T-BsAbs)- have shown promising efficacy but also induce significant toxicity. In particular T-cell redirection leads to efficient killing of tumor cells but induces cytokine release-related toxicities. We have developed a panel of monovalent and biparatopic CD3xPSMA bispecific antibodies that eliminate prostate tumor cells while minimizing cytokine release. Methods: Antibodies targeting CD3 and PSMA were generated in transgenic rats (UniRatâ„¢, OmniFlicâ„¢) followed by deep sequencing of the antibody repertoire from draining lymph nodes in immunized animals, and high-throughput gene assembly/expression. PSMA x CD3 T-BsAbs were assembled and evaluated for stability, pharmacokinetics, and T cell activation and ability to eliminate PSMA+ tumor cells in vitro and in vivo. Results: Bispecific CD3xPSMA Abs. incorporating either monovalent or biparatopic anti-PSMA binding domains activated T-cells in the presence of PSMA (plate-bound or cell surface), while no T cell activation occurred in the absence of either PSMA antigen or bispecific antibody. Potent/selective cytotoxicity against PSMA+ cells was observed in co-cultures of primary human T cells and tumor cells treated with CD3xPSMA T-BsAbs. Similar results were observed in in vivo Xenograft models of prostate cancer. Strikingly, CD3xPSMA bispecifics containing a novel low affinity anti-CD3 domain produced similar levels of tumor cytotoxicity compared to those with a traditional high affinity anti-CD3 domain, but with reduced cytokine production. Conclusions: We have created novel CD3xPSMA bispecific antibodies incorporating both monovalent and biparatopic anti-PSMA binding domains that mediate T-cell killing of PSMA+ tumor cells with minimal production of cytokines. Such T-BsAbs may improve safety, efficacy, and opportunities for combination therapy to treat CRPC.

scholarly journals Repurposing endogenous immune pathways to tailor and control chimeric antigen receptor T cell functionality

2019 â—½  
Vol 10 (1) â—½  
Author(s):  
Mohit Sachdeva â—½  
Brian W. Busser â—½  
Sonal Temburni â—½  
Billal Jahangiri â—½  
Anne-Sophie Gautron â—½  
...  
Keyword(s):  
T Cells â—½  
T Cell â—½  
T Cell Activation â—½  
Chimeric Antigen Receptor â—½  
Cell Activation â—½  
Antigen Receptor â—½  
Car T Cells â—½  
Car T â—½  
Immune Pathways â—½  
And Control

Abstract Endowing chimeric antigen receptor (CAR) T cells with additional potent functionalities holds strong potential for improving their antitumor activity. However, because potency could be deleterious without control, these additional features need to be tightly regulated. Immune pathways offer a wide array of tightly regulated genes that can be repurposed to express potent functionalities in a highly controlled manner. Here, we explore this concept by repurposing TCR, CD25 and PD1, three major players of the T cell activation pathway. We insert the CAR into the TCRα gene (TRACCAR), and IL-12P70 into either IL2Rα or PDCD1 genes. This process results in transient, antigen concentration-dependent IL-12P70 secretion, increases TRACCAR T cell cytotoxicity and extends survival of tumor-bearing mice. This gene network repurposing strategy can be extended to other cellular pathways, thus paving the way for generating smart CAR T cells able to integrate biological inputs and to translate them into therapeutic outputs in a highly regulated manner.

scholarly journals Engineered Hypoimmune Allogeneic CAR T Cells Exhibit Innate and Adaptive Immune Evasion Even after Sensitization in Humanized Mice and Retain Potent Anti-Tumor Activity

Blood â—½  
2021 â—½  
Vol 138 (Supplement 1) â—½  
pp. 1690-1690
Author(s):  
Xiaomeng Hu â—½  
Mo Dao â—½  
Kathy White â—½  
Corie Gattis â—½  
Ryan Clarke â—½  
...  
Keyword(s):  
T Cells â—½  
T Cell â—½  
T Cell Activation â—½  
Cell Activation â—½  
Nk Cell â—½  
Publicly Traded â—½  
Car T Cells â—½  
Car T

Abstract Off-the-shelf CAR T cells may offer advantages over autologous strategies, including ease of manufacturing, improved quality control with avoidance of malignant contamination and T cell dysfunction as well as the ability to generate a final product from healthy T cells. While TCR editing can effectively prevent graft-versus-host reactions, the significant host-versus-graft immune response against histoincompatible T cells prevents the expansion and persistence of allogeneic CAR T cells and mitigates the efficacy of this approach. The goal is to achieve improved rates of durable complete remissions by improving allogeneic CD19CAR persistence since it has been shown that autologous CAR T cells have greater durability over years than allogeneic CAR T cells (N Engl J Med. 2021;384(7):673-674). We describe here the engineering of human immune evasive CAR T cells based on our previously described hypoimmune technology (Nat Biotechnol 2019;37(3):252-258 and Proc Natl Acad Sci U S A 2021;118(28):e2022091118). A major challenge is that, while HLA deletion can result in adaptive immune evasion, innate reactivity is enhanced by this strategy. Since CD47 overexpression can block both NK cell and macrophage killing (J Exp Med 2021;218(3):e20200839), we hypothesized that T cells would lose their immunogenicity when human leukocyte antigen (HLA) class I and II genes are inactivated and CD47 is over-expressed. Human T cells from healthy donors were obtained by leukapheresis. To generate hypoimmune CD19CAR T cells, gene editing was used to delete b2m, CIITA, and TCR expression and lentiviral transduction was used to overexpress CD47 and CD19CAR containing a 4-1BB costimulatory domain to generate hypoimmune CAR T cells. Control T cells were unmanipulated except for lentiviral transduction used to overexpress the same CD19CAR and the deletion of the TCR. When transplanted into allogeneic humanized mice, hypoimmune CD19CAR T cells evade immune recognition by T cells even in previously sensitized animals as evidenced by a lack of T cell activation measured using ELISPOT analysis. In contrast, transplantation of non-hypoimmune-edited CD19CAR T cells generated from the same human donor resulted in a significant T cell activation (see figure: mean 59 and 558 spot frequencies for hypoimmune CD19CAR T cells and non-edited CD19CAR T cells, respectively; p<0.0001 unpaired T-test). In addition to evading T cells, immune cell assays show that CD47 overexpression protects hypoimmune CD19CAR T cells from NK cell and macrophage killing in vitro and in vivo. Relative CD47 expression levels were analyzed to understand the relevance of CD47 for protection from macrophage and NK cell killing. A blocking antibody against CD47 made the hypoimmune CAR T cells susceptible to macrophage and NK cell killing in vitro and in vivo, confirming the importance of CD47 overexpression to evade innate immune clearance. The hypoimmune CD19 CAR T cells retained their antitumor activity in both the Daudi and Nalm-6 B cell leukemia models, in vitro and in vivo. This indicated that the hypoimmune technology-i.e. isolated CD47 overexpression, deletion of b2m, CIITA, and TCR- did not show any effect on the cytotoxic potential of CD19 CAR T cells (see figure). These studies demonstrate that in vivo clearance of leukemic cells in NSG mice occurs across a range of tumor cell toCD19 CAR T cell ratios in a manner comparable to control, unedited CD19 CAR T cells (see figure). This result was validated using T cells from 3 different donors These findings show that, in these models, hypoimmune CD19 CAR T cells are functionally immune evasive in allogeneic humanized mouse recipients and have cytotoxic anti-tumor capacity. They suggest that hypoimmune CAR T cells could provide universal CAR T cells that are able to persist without immunosuppression. Furthermore, these data suggest that hypoimmune CD19 CAR T cells can be used in sensitized patients and for re-dosing strategies. Figure 1 Figure 1. Disclosures Hu: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Dao: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. White: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Gattis: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Clarke: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Landry: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Basco: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Tham: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Tucker: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Luo: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Bandoro: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Chu: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Young: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Foster: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Dowdle: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Rebar: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Fry: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company. Schrepfer: Sana Biotechnology: Current Employment, Current equity holder in publicly-traded company.

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