scholarly journals Redirecting T-Cells Against AML in a Multidimensional Targeting Space Using T-Cell Engaging Antibody Circuits (TEAC)

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 2653-2653 ◽  
Author(s):  
Eleanor Minogue ◽  
David Millar ◽  
Yan Chuan ◽  
Songfa Zhang ◽  
Korneel Grauwet ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Lines ◽  
T Cell Activation ◽  
Cleavage Site ◽  
Cell Activation ◽  
Surface Antigens ◽  
Research Support ◽  
Car T ◽  
Equity Ownership

Background T cell redirection strategies, such as CAR-T and bispecific antibodies (bsAb), are rapidly changing the way in which we approach and treat cancer. While CAR-T and bsAb have shown impressive clinical efficacy in a limited number of cancers, both strategies are ultimately limited by on-target toxicity that currently restricts application to B-cell lineage tumors as the number of genuinely tumor-specific surface antigens is extremely limited. BsAb also suffer from off-target toxicity relating their ability to directly active T-cells severely restricting the therapeutic window. We sought to solve these inherent problems with the current generation bsAb by re-designing the molecule to alter the mechanism of T-cell activation. By splitting the T-cell engaging VHVL antibody paratope between two separate molecules we created two molecules that formed an active T-cell engaging unit through protein domain complementation following proteolytic activation. Each antibody could target independent surface antigens vastly increasing targeting permutations. Thus, these two antibodies functioned as an "antibody circuit" permitting Boolean type logic to precisely control T-cell activation in multi-dimensional targeting space. We selected AML as model cancer to develop T-cell Engaging Antibody Circuits (TEACs) due to the highly characterized surface antigen landscape and the clear challenges and limitations of single-antigen targeting approaches. Results We first screened 10 AML cell lines for candidate surface antigens based upon prior studies of surface antigen display (Perna F et al, 2016) and identified CD33, CD123, CD49d, CD70, CD71, CD38, CLEC12A, Flt3, CD24, CD244, TIM3 and CCR1 as promising targets. We developed a secondary TEACs screening assay where the two TEAC molecules contained either a FITC or biotin binding domain and paired these to commercial FITC or biotin conjugated antibodies targeting the antigens above. We screened 72 TEAC pairs against the 10 cell lines which identified optimal antigen target combinations which included CD33xCD123, CD33xCLEC12A, CD33xCD49d and CD33xCD24. Using a FRET-based fluorescent peptide assay to identify peptide linkers susceptible to proteases we found MMP2 to be highly expressed in AML samples and thus designed all our TEACs with this cleavage site. We next generated IgG4 format TEACs targeting CD33, CD123, CLEC12A and CD24 that included the MMP2 cleavage activation site and tested these as TEAC pairs in vitro. This screen identified the CD123xCD33 as the most active TEAC pair which was active in 9/10 cells lines. To assess potential safety concerns, we tested TEACs and CD123 and CD33 BiTEs individually and as pairs on PBMCs and on plate-immobilized molecules. These data demonstrated that BiTEs were extremely active against healthy monocytes and also activate T-cells non-specifically once plate-immobilized. In contrast CD123xCD33 IgG TEACs pairs did not activate T-cells when plate-immobilized and did not target healthy monocytes.Finally, we examined the activity of both CD33 BiTEs and CD123xCD33 TEACs on primary patient AML samples. We conducted FRET based assays which confirmed high activity of MMP2 cleavage site on all primary AML samples. When we examined T-cell activation, CD123xCD33 TEACs were active in all CD123+ CD33+ AML samples evaluated with an EC50 of 30ug/ml. Conclusion These data suggest T-cell engaging antibody circuits is a new approach that could be safely applied toward AML. TEAC agents do not directly activate T-cells and CD123xCD33 TEAC pairs do not activate PBMC or monocytes. However, CD123xCD33 TEACs show strong activity against AML cell lines and primary CD123+CD33+ AML cells. Disclosures Millar: Revitope Oncology: Equity Ownership. Minshull:Atum Biotechnology: Employment, Equity Ownership. Narayan:Takeda: Other: Employment (spouse); Genentech: Other: Equity ownership (spouse); Merck: Other: Equity ownership (spouse). Graubert:Biogen: Other: Spouse Employee; Calico Life Sciences: Other: Research Support; Janssen Pharmaceuticals: Other: Research Support. Cobbold:Gritstone Oncology: Equity Ownership; Revitope Oncology: Consultancy; Revitope Oncology: Equity Ownership.

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

Blood ◽  
2015 ◽  
Vol 126 (23) ◽  
pp. 4295-4295 ◽  
Author(s):  
Aaron Foster ◽  
Aruna Mahendravada ◽  
Nicholas P Shinners ◽  
Peter Chang ◽  
An Lu ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Tumor Cells ◽  
T Cell Activation ◽  
Cell Activation ◽  
First Generation ◽  
Car T Cell ◽  
Car T ◽  
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 Inducible MyD88/CD40 Allows AP1903-Dependent Costimulation to Control Proliferation and Survival of Chimeric Antigen Receptor-Modified T Cells

Blood ◽  
2014 ◽  
Vol 124 (21) ◽  
pp. 1121-1121 ◽  
Author(s):  
Aaron Foster ◽  
Aruna Mahendravada ◽  
Peter Chang ◽  
Nicholas Shinners ◽  
Kevin Slawin ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Cell Lines ◽  
T Cell Activation ◽  
Cell Activation ◽  
First Generation ◽  
Employment Equity ◽  
Co Activation ◽  
Equity Ownership

Abstract Introduction: Adoptive transfer of T cells genetically engineered to express chimeric antigen receptors (CARs) has begun to show impressive clinical results. The efficacy of T cell therapy is dependent not only on tumor recognition, but also on the survival and expansion of T cells following infusion. T cells modified with CAR constructs encoding costimulatory domains such as CD28 or 4-1BB have the capacity to rapidly proliferate in vivo, but severe toxicities have been observed due to unchecked T cell activation. Thus, strategies to regulate T cell activation in vivowould allow physicians to prevent toxicities and maximize anti-tumor efficacy. Here, we describe a novel T cell costimulation switch, inducible MyD88/CD40 (iMC), that can be activated by a small molecule chemical inducer of dimerization, AP1903, to enhance survival and drive T cell proliferation. Methods: T cells were activated with anti-CD3/28 antibodies and subsequently transduced with a biscistronic retrovirus encoding myristolated tandem AP1903 binding domains (FKBPv36), cloned in-frame with MyD88 and CD40 cytoplasmic signaling molecules, and truncated CD19 to identify transduced T cells (SFG-iMC.2A.ΔCD19). Control vectors without signaling elements, or with only MyD88 or cytoplasmic CD40 were also used to generate gene-modified T cell lines. iMC activation was measured by treating T cells with and without AP1903 and measuring cytokine production by ELISA, and assessing cell surface activation markers by flow cytometry. Co-activation of T cells through CD3ζ in combination with iMC was accomplished using anti-CD3 antibodies, or by co-transducing T cells with first generation CAR constructs recognizing prostate stem cell antigen or CD19 (PSCA.ζ or CD19.ζ, respectively), and coculturing T cells with PSCA+ (Capan-1) or CD19+ tumor cell lines (Raji, Daudi and Nalm-1) with and without AP1903. Efficacy of iMC-modified CAR T cells were assessed using NOD scid gamma (NSG) immune deficient mice engrafted with tumor cell lines followed by intravenous injection of T cells. The iMC costimulatory molecule was subsequently activated in vivo by intraperitoneal injection of AP1903 (5 mg/kg). Tumor burden was assessed and T cell expansion in vivowas measured by bioluminescent imaging using an IVIS instrument. Results: T cells transduced with iMC produce cytokines (e.g. IFN-γ, TNF-α, IL-6) in response to AP1903. iMC activation permits T cell survival in the absence of growth cytokines, such as IL-2, but by itself is not sufficient to induce IL-2 production or autonomous growth. Interestingly, AP1903-induction of MyD88 or cytoplasmic CD40 alone showed minimal T cell activation, suggesting potential synergy of the two signaling molecules. However, co-activation of the T cell receptor (TCR) with soluble anti-CD3 and iMC with AP1903 upregulated CD25 expression, induced IL-2 production and promoted T cell expansion. Importantly, endogenous TCR signaling could be substituted by a PSCA-specific CAR linked to the CD3 ζ endodomain (PSCA.ζ CAR), where co-activation of iMC by AP1903, and CAR by tumor cells expressing PSCA (Capan-1) induced high levels of IL-2 secretion, CD25 upregulation and rapid T cell proliferation. Similar results were achieved using T cells transduced with iMC-enabled CD19 CAR (SFG-iMC.2A.CD19.ζ) when cocultured with CD19+lymphoma cell lines. Treatment of tumor bearing immunodeficient mice with T cells modified with iMC and PSCA.ζ CAR showed enhanced antitumor efficacy when mice were administered with AP1903 dimerizer. Bioluminescence imaging also demonstrated marked proliferation and persistence of iMC-transduced T cells in response to AP1903 administration. Following AP1903 withdrawal, T cell levels declined, consistent with the requirement for 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 (CD3 ζ) domain from signal 2 costimulation (iMC) provides a unique mechanism by which T cells can be expanded only in response to both AP1903 and tumor antigen, or reduced in number by withdrawal of AP1903-induced iMC costimulation. Disclosures Foster: Bellicum Pharmaceuticals: Employment, Patents & Royalties. Mahendravada:Bellicum Pharmaceuticals: Employment. Chang:Bellicum Pharmaceuticals: Employment. Shinners:Bellicum Pharmaceuticals: Employment. Slawin:Bellicum Pharmaceuticals: Employment, Equity Ownership, Patents & Royalties. Spencer:Bellicum Pharmaceuticals: Employment, Equity Ownership, Patents & Royalties.

107 Effects of IL-2 and IL-15 on the proliferative and antitumor capacities of allogeneic CD20 CAR-engineered γδ T cells in a 3D B cell lymphoma spheroid assay

2020 ◽  
Vol 8 (Suppl 3) ◽  
pp. A119-A119
Author(s):  
Lu Bai ◽  
Kevin Nishimoto ◽  
Mustafa Turkoz ◽  
Marissa Herrman ◽  
Jason Romero ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
T Cell Activation ◽  
Cell Activation ◽  
Cytokine Production ◽  
Γδ T Cells ◽  
Γδ T Cell ◽  
Car T

BackgroundAutologous chimeric antigen receptor (CAR) T cells have been shown to be efficacious for the treatment of B cell malignancies; however, widespread adoption and application of CAR T cell products still face a number of challenges. To overcome these challenges, Adicet Bio is developing an allogeneic γδ T cell-based CAR T cell platform, which capitalizes on the intrinsic abilities of Vδ1 γδ T cells to recognize and kill transformed cells in an MHC-unrestricted manner, to migrate to epithelial tissues, and to function in hypoxic conditions. To gain a better understanding of the requirements for optimal intratumoral CAR Vδ1 γδ T cell activation, proliferation, and differentiation, we developed a three-dimensional (3D) tumor spheroid assay, in which tumor cells acquire the structural organization of a solid tumor and establish a microenvironment that has oxygen and nutrient gradients. Moreover, through the addition of cytokines and/or tumor stromal cell types, the spheroid microenvironment can be modified to reflect hot or cold tumors. Here, we report on the use of a 3D CD20+ Raji lymphoma spheroid assay to evaluate the effects of IL-2 and IL-15, positive regulators of T cell homeostasis and differentiation, on the proliferative and antitumor capacities of CD20 CAR Vδ1 γδ T cells.MethodsMolecular, phenotypic, and functional profiling were performed to characterize the in vitro dynamics of the intraspheroid CD20 CAR Vδ1 γδ T cell response to target antigen in the presence of IL-2, IL-15, or no added cytokine.ResultsWhen compared to no added cytokine, the addition of IL-2 or IL-15 enhanced CD20 CAR Vδ1 γδ T cell activation, proliferation, survival, and cytokine production in a dose-dependent manner but were only able to alter the kinetics of Raji cell killing at low effector to target ratios. Notably, differential gene expression analysis using NanoString nCounter® Technology confirmed the positive effects of IL-2 or IL-15 on CAR-activated Vδ1 γδ T cells as evidenced by the upregulation of genes involved in activation, cell cycle, mitochondrial biogenesis, cytotoxicity, and cytokine production.ConclusionsTogether, these results not only show that the addition of IL-2 or IL-15 can potentiate CD20 CAR Vδ1 γδ T cell activation, proliferation, survival, and differentiation into antitumor effectors but also highlight the utility of the 3D spheroid assay as a high throughput in vitro method for assessing and predicting CAR Vδ1 γδ T cell activation, proliferation, survival, and differentiation in hot and cold tumors.

scholarly journals P07.02 Regulation of CD19 CAR T- cell activation based on engineered Nuclear factor of activated T cells artificial transcription factors

2021 ◽  
Vol 9 (Suppl 1) ◽  
pp. A23-A23
Author(s):  
D Lainšček ◽  
V Mikolič ◽  
Š Malenšek ◽  
A Verbič ◽  
R Jerala
Keyword(s):  
T Cells ◽  
T Cell ◽  
T Cell Activation ◽  
Cell Activation ◽  
Cell Activity ◽  
External Control ◽  
Car T Cells ◽  
Car T Cell ◽  
Artificial Transcription Factors ◽  
Car T

BackgroundCD19 CAR T- cells (Chimeric antigen receptor T cells that recognize CD19) present a therapeutic option for various malignant diseases based on their ability to specifically recognize the selected tumour surface markers, triggering immune cell activation and cytokine production that results in killing cancerous cell expressing specific surface markers recognized by the CAR. The main therapeutic effect of CAR is a specific T cell activation of adequate cell number with sequential destruction of tumorous cells in a safe therapeutic manner. In order to increase T cell activation, different activation domains were introduced into CAR. CAR T-cells are highly efficient in tumour cell destruction, but may cause serious side effects that can also result in patient death so their activity needs to be carefully controlled.1 Several attempts were made to influence the CAR T cell proliferation and their activation by adding T cell growth factors, such as IL-2, into patients, however this approach of increasing the number of activating T cells with no external control over their number can again lead to non-optimal therapeutic effects. Different improvements were made by designing synthetic receptors or small molecule-inducible systems etc., which influence regulated expansion and survival of CAR T cells.2Material and MethodsIn order to regulate CD19 CAR-T cell activity, different NFAT2 based artificial transcription factors were prepared. The full length NFAT2, one of the main players in T cell IL2 production, a key cytokine for T cell activation and proliferation was truncated by deletion of its own activation domain. Next, we joined via Gibson assembly tNFAT21-593 coding sequence with domains of different heterodimerization systems that interact upon adding the inductor of heterodimerization. The interaction counterparts were fused to a strong tripartite transcriptional activator domain VPR and/or strong repressor domain KRAB resulting in formation of an engineered NFAT artificial transcription (NFAT-TF) factors with external control. To determine the activity of NFAT-TF HEK293, Jurkat or human T cells were used.ResultsBased on luciferase assay, carried out on NFAT-TF transfected HEK293 cells we first established that upon adding the external inductor of heterodimerization, efficient gene regulation occurs, according to VPR or KRAB domain appropriate functions. Findings were then transferred to Jurkat cells that were electroporated with appropriate DNA constructs, coding for NFAT-TF and CD19 CAR. After Raji:Jurkat co-culture ELISA measurements revealed that IL2 production and therefore CD19 CAR-T cell activity can be controlled by the action of NFAT-TF. The same regulation over the activity and subsequent proliferation status was also observed in retrovirally transduced human T-cells.ConclusionWe developed a regulatory system for therapeutic effect of CD19 CAR-T cells, a unique mechanism to control T cell activation and proliferation based on the engineered NFAT2 artificial transcription factor.ReferencesBonifant CL, et al. Toxicity and management in CAR T-cell therapy. Mol Ther Oncolytics 2016;3:16011.Wu C-Y, et al. Remote control of therapeutic T cells through a small molecule-gated chimeric receptor. Science 2015;80:350.Disclosure InformationD. Lainšček: None. V. Mikolič: None. Š. Malenšek: None. A. Verbič: None. R. Jerala: None.

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 ◽  
Vol 9 (Suppl 3) ◽  
pp. A217-A217
Author(s):  
Andy Tsun ◽  
Zhiyuan Li ◽  
Zhenqing Zhang ◽  
Weifeng Huang ◽  
Shaogang Peng ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
Fusion Protein ◽  
T Cell Activation ◽  
Cell Activation ◽  
In Vivo Studies ◽  
Cytokine Release ◽  
Car T Cells ◽  
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 Tonic Signaling Leads to Off-Target Activation of T Cells Engineered with Chimeric Antigen Receptors That Is Not Seen in T Cells Engineered with T Cell Antigen Coupler (TAC) Receptors

Blood ◽  
2020 ◽  
Vol 136 (Supplement 1) ◽  
pp. 31-32
Author(s):  
Duane Moogk ◽  
Arya Afsahi ◽  
Vivian Lau ◽  
Anna Dvorkin-Gheva ◽  
Jonathan Bramson
Keyword(s):  
T Cells ◽  
T Cell ◽  
T Cell Activation ◽  
Cell Activation ◽  
Transcriptional Profiling ◽  
Binding Domain ◽  
Antigen Binding ◽  
Knock Out ◽  
Car T Cells ◽  
Car T

Chimeric antigen receptors (CARs) are powerful tools that enable MHC-independent activation of T cells. Recent reports have indicated that constitutive, low-level (tonic) signaling by CARs can impair the utility of the engineered T cells. The single-chain antibody (scFv) binding domain was one of the features determined to promote tonic signaling. We have recently developed a novel chimeric receptor, known as the T cell antigen coupler (TAC), that is less prone to tonic signaling than second-generation CARs. The TAC consists of a scFv-based antigen binding domain, a CD3-binding domain that couples the TAC to endogenous T cell receptor (TCR), and a transmembrane and cytoplasmic coreceptor (CD4) domain. In contrast to CARs, this design enables TAC-T cells to signal through the endogenous TCR, which we propose provides a fidelity to natural T cell signal regulation. Interestingly, we have recently reported that CAR-T cells have a greater propensity for off-target activation than TAC-T cells, suggesting a safety advantage to TAC-T cells (Helsen et al., Nat. Comm., 2019). Further characterization of the differences between CAR- and TAC-T cell signal initiation and activation is required to understand how their design affects sensitivity, specificity and regulation of T cell activation. Examination of the activation requirements for BCMA-specific CAR-T cells and TAC-T cells confirmed that TAC-T cells are reliant upon the endogenous TCR for T cell activation whereas CAR-T cells are TCR-independent. TRAC knock-out CAR-T cells retained potent effector function at levels similar to CAR-T cells with intact TCR expression, whereas TRAC knock-out TAC T-cells showed significant impairment in effector function. Consistent with TCR-dependence, the immunological synapse produced by TAC-T cells displays all the hallmarks of a conventional immunological synapse, whereas CAR-T cells form unconventional synapses. Unlike TAC-T cells, immunological synapses formed by CAR-T cells display non-uniform central supramolecular activation clusters, disperse Lck distribution, a lack of an LFA-1 associated adhesion ring (Figure), as well as more disperse delivery of perforin to the cell interface. CAR-T cells also formed synapses faster than TAC-T cells. This suggests that while TAC T-cells are beholden to the requirement of organized, mature synapse formation, CAR T-cells can rapidly form less structurally organized synapses. Transcriptional profiling of CAR-T cells in the absence of antigen stimulation revealed a basal activation status associated with upregulation of Nur77, a transcription factor that is downstream of TCR activation. Transcriptional profiling of TAC-T cells failed to reveal evidence of TCR signaling in the absence of stimulation. Further evaluation of CAR- and TAC- T cells in the absence of stimulation revealed elevated levels of CD69, PD-1 and LAG-3 in CAR-T cells compared with TAC-T cells, as well as higher expression of IL-2, IFNγ, and TNF in CAR-T cells. Interestingly, the level of tonic signaling was dependent on the antigen-binding scFV, as otherwise identical BCMA-specific CAR- and TAC-T cells displayed different levels of CD69, PD-1 and LAG-3 depending on the identity of the BCMA-specific scFv. Despite different levels of basal activation, both CAR- and TAC-T cells displayed comparable activation kinetics as measured by upregulation of CD69 and Ki-67, as well as proliferation. However, the elevated level of basal activation rendered the CAR-T cells more easily activated by a cross-reactive off-target antigen that failed to stimulate TAC-T cells carrying the same binding domain. These data suggest that the TAC receptor offers a valuable alternate platform to CAR-T cells. The antigen-binding scFv domain has a direct impact on tonic signaling and basal activation in CAR-T cells. Conversely, TAC-T cells are less susceptible to basal activation and this works suggests that the TAC receptor can deploy scFv binding domains that are not suitable for CARs. This work was supported by Triumvira Immunologics and Genome Canada. Figure 1 Disclosures Bramson: McMaster University: Current Employment, Patents & Royalties; Triumvira Immunologics: Current Employment, Current equity holder in private company, Research Funding.

Characterisation of Human CD83 Expression on Immune Cells and Their Targeting with CD83 Antibodies to Prevent Graft Versus Host Disease in Allogeneic Haematopoietic Cell Transplantation

Blood ◽  
2015 ◽  
Vol 126 (23) ◽  
pp. 3081-3081
Author(s):  
Derek NJ Hart ◽  
Xinsheng Ju ◽  
Zehra Elgundi ◽  
Nirupama Verma ◽  
Pablo Silveira ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
T Cell Activation ◽  
Immune Cells ◽  
Cell Activation ◽  
Splice Variants ◽  
Scid Mice ◽  
Human Pbmc ◽  
Graft Versus Host ◽  
Equity Ownership

Abstract Introduction: CD83 is an important marker of activated dendritic cells (DC) but it is also expressed on other immune cells. Polyclonal anti-CD83 antibody depletes activated DC and prevents human peripheral blood mononuclear cell (PBMC) induced xenogeneic graft versus host disease (GVHD) in immunosuppressed SCID mice (J Exp Med 2009;206;387). We therefore generated a potential therapeutic human anti-CD83 mAb (3C12C), which had similar efficacy and T cell sparing effects in the same model (Leukemia 2015; in press). To investigate the specific immunosuppressive effect of 3C12C further, we undertook a comprehensive analysis of CD83 expression and its glycosylation pattern on various immune cell populations and tested the effect of 3C12C on T cell function using preclinical models, including a human CD83 (hCD83) knock in (KI) mouse. Methods: A panel of mouse and recombinant mAbs to hCD83 were used to analyse its expression by flow cytometry on resting and activated healthy donor PBMC. The expression of potential CD83 splice variants was examined by PCR. T cell expression was examined by flow cytometry and confocal microscopy after PHA, CD3/CD28 beads and allogeneic mixed leukocyte reaction (alloMLR) culture. Control human IgG1 (trastuzumab) and 3C12C mAbs were tested (0.125mg d-1) in a xenogeneic model of GVHD utilizing human PBMC transplanted into total body irradiation and anti-NK conditioned SCID mice. The genetically engineered hCD83 KI mouse was shown to be immune-competent and used to test the effect of 3C12C on LPS activated DC and T cells. Results: There were distinct CD83 splice variants (full length CD83, splicing variant CD83a, CD83b and CD83c) in different immune cells. CD83 glycosylation status also differed with high glycosylation required for surface expression on activated DC, whereas its expression on activated B cells and monocytes was resistant to de-glycosylation. Increases in CD83 expression on T cells occurred early with different kinetics, underlining the distinct signal pathway involved. The 3C12C mAb reduced T cell proliferation in the alloMLR but did not affect cytomegalovirus (CMV) or influenza (Flu) specific CD8+T cell numbers. Treatment with 3C12C prevented GVHD in human PBMC transplanted SCID mice, which otherwise developed histological GVHD between d8-13. Human DC were activated by d2 and expressed the CMRF-44 activation marker plus CD83, CD80 and CD86. Treatment with 3C12C mAb eliminated CD83+ CMRF44+ DC early post-transplant and reduced T cell activation. Further studies, established CMV and Flu specific T cells were retained and responded to antigen by IFNg production. Furthermore, Treg numbers were preserved. The 3C12C mAb depleted LPS activated DC in hCD83 KI mice in experiments performed prior to commencing transplant studies. Conclusion: These findings suggest that the potential therapeutic human anti-CD83 mAb induced significant immune suppression, by depletion of activated DC and consequential modulation of T cell activation. The reduction in allo/xeno activated T cells may result in part from a direct effect of anti-CD83 on early T cell responses. This apparently selective immunosuppressive effect preserves anti-viral T cell immunity and Treg pathways, suggesting that 3C12C merits further investigation as a novel agent for GVHD prophylaxis. Disclosures Hart: DendroCyte BioTech Pty Ltd: Equity Ownership. Clark:DendroCyte BioTech Pty Ltd: Equity Ownership.

A Novel and Highly Potent CAR T Cell Drug Product for Treatment of BCMA-Expressing Hematological Malignances

Blood ◽  
2015 ◽  
Vol 126 (23) ◽  
pp. 3094-3094 ◽  
Author(s):  
Alena A. Chekmasova ◽  
Holly M. Horton ◽  
Tracy E. Garrett ◽  
John W. Evans ◽  
Johanna Griecci ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Cell Lines ◽  
Drug Product ◽  
Single Chain ◽  
Employment Equity ◽  
Car T Cells ◽  
Car T ◽  
Equity Ownership

Abstract Recently, B cell maturation antigen (BCMA) expression has been proposed as a marker for identification of malignant plasma cells in patients with multiple myeloma (MM). Nearly all MM and some lymphoma tumor cells express BCMA, while normal tissue expression is restricted to plasma cells and a subset of mature B cells. Targeting BCMA maybe a therapeutic option for treatment of patients with MM and some lymphomas. We are developing a chimeric antigen receptor (CAR)-based therapy for the treatment of BCMA-expressing MM. Our anti-BCMA CAR consists of an extracellular single chain variable fragment (scFv) antigen recognition domain derived from an antibody specific to BCMA, fused to CD137 (4-1BB) co-stimulatory and CD3zeta chain signaling domains. Selection of our development candidate was based on the screening of four distinct anti-BCMA CARs (BCMA01-04) each comprised of unique single chain variable fragments. One candidate, BCMA02 (drug product name bb2121) was selected for further studies based on the robust frequency of CAR-positive cells, increased surface expression of the CAR molecule, and superior in vitro cytokine release and cytolytic activity against the MM cell lines. In addition to displaying specific activity against MM (U226-B1, RPMI-8226 and H929) and plasmacytoma (H929) cell lines, bb2121 was demonstrated to react to lymphoma cell lines, including Burkitt's (Raji, Daudi, Ramos), chronic lymphocytic leukemia (Mec-1), diffuse large B cell (Toledo), and a Mantle cell lymphoma (JeKo-1). Based on receptor density quantification, bb2121 can recognize tumor cells expressing less than 1000 BCMA molecules per cell. The in vivo pharmacology of bb2121 was studied in NSG mouse models of human MM and Burkitt's lymphoma. NSG mice were injected subcutaneously (SC) with 107 RPMI-8226 MM cells. After 18 days, mice received a single intravenous (IV) administration of vehicle or anti-CD19Δ (negative control, anti-CD19 CAR lacking signaling domain) or anti-BCMA CAR T cells, or repeated IV administration of bortezomib (Velcade®; 1 mg/kg twice weekly for 4 weeks). Bortezomib, which is a standard of care for MM, induced only transient reductions in tumor size and was associated with toxicity, as indicated by substantial weight loss during dosing. The vehicle and anti-CD19Δ CAR T cells failed to inhibit tumor growth. In contrast, treatment with bb2121 resulted in rapid and sustained elimination of the tumors, increased body weights, and 100% survival. Flow cytometry and immunohistochemical analysis of bb2121 T cells demonstrated trafficking of CAR+ T cells to the tumors (by Day 5) followed by significant expansion of anti-BCMA CAR+ T cells within the tumor and peripheral blood (Days 8-10), accompanied by tumor clearance and subsequent reductions in circulating CAR+ T cell numbers (Days 22-29). To further test the potency of bb2121, we used the CD19+ Daudi cell line, which has a low level of BCMA expression detectable by flow cytometry and receptor quantification analysis, but is negative by immunohistochemistry. NSG mice were injected IV with Daudi cells and allowed to accumulate a large systemic tumor burden before being treated with CAR+ T cells. Treatment with vehicle or anti-CD19Δ CAR T cells failed to prevent tumor growth. In contrast, anti-CD19 CAR T cells and anti-BCMA bb2121 demonstrated tumor clearance. Adoptive T cell immunotherapy approaches designed to modify a patient's own lymphocytes to target the BCMA antigen have clear indications as a possible therapy for MM and could be an alternative method for treatment of other chemotherapy-refractory B-cell malignancies. Based on these results, we will be initiating a phase I clinical trial of bb2121 for the treatment of patients with MM. Disclosures Chekmasova: bluebird bio, Inc: Employment, Equity Ownership. Horton:bluebird bio: Employment, Equity Ownership. Garrett:bluebird bio: Employment, Equity Ownership. Evans:bluebird bio, Inc: Employment, Equity Ownership. Griecci:bluebird bio, Inc: Employment, Equity Ownership. Hamel:bluebird bio: Employment, Equity Ownership. Latimer:bluebird bio: Employment, Equity Ownership. Seidel:bluebird bio, Inc: Employment, Equity Ownership. Ryu:bluebird bio, Inc: Employment, Equity Ownership. Kuczewski:bluebird bio: Employment, Equity Ownership. Horvath:bluebird bio: Employment, Equity Ownership. Friedman:bluebird bio: Employment, Equity Ownership. Morgan:bluebird bio: Employment, Equity Ownership.

Clinical Dosing Regimen of Selinexor Maintains Normal Immune Homeostasis and T Cell Effector Function in Mice: Implications for Combination with Immunotherapy

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 2525-2525
Author(s):  
Paul M Tyler ◽  
Mariah M Servos ◽  
Boris Klebanov ◽  
Trinayan Kashyap ◽  
Sharon Shacham ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
T Cell Activation ◽  
Cd8 T Cells ◽  
Cell Activation ◽  
T Cell Development ◽  
Immune Homeostasis ◽  
Dosing Regimen ◽  
Employment Equity ◽  
Equity Ownership

Abstract Selinexor (KPT-330) is a first in class nuclear transport inhibitor of exportin-1(XPO1) currently in advanced clinical trials to treat patients with solid and hematological malignancies. To determine how selinexor might impact anti-tumor immunity, we analyzed immune homeostasis in mice treated with high selinexor doses (15 mg/kg, three times a week: M, W, F) and found disruptions in T cell development, a progressive loss of CD8 T cells and increases in inflammatory monocytes. Antibody production in response to immunization was mostly normal. Precursor populations in bone marrow and thymus were unaffected by high doses of selinexor, suggesting that normal immune homeostasis could recover. We found that high dose of selinexor given once per week preserved nearly normal immune functioning, whereas a lower dose given 3 times per week (7.5 mg/kg, M, W, F) was not able to restore immune homeostasis. Both naïve and effector CD8 T cells cultured in vitro showed impaired activation in the presence of selinexor. These experiments suggest that XPO1 function is required for T cell development and function. We then determined the minimum concentration of selinexor required to block T cell activation, and showed that T cell inhibitory effects of selinexor occur at levels above 100nM, corresponding to the first 24 hours post-oral dosing of 10 mg/kg. In a model of implantable melanoma, we used selinexor treatment at the clinically relevant dosing regimen of 10 mg/kg with a 5-day drug holiday (M, W selinexor treatment). After two weeks of treatment, tumors were harvested and tumor infiltrating leukocyte (TIL) populations were analyzed. This treatment led to intratumoral IFNg+, granzyme B+ cytotoxic CD8 T cells that were comparable to vehicle treated mice. Overall, selinexor treatment leads to transient inhibition of T cell activation but the clinically relevant once and twice weekly dosing schedules that incorporate sufficient drug holidays allow for normal CD8 T cell functioning and development of anti-tumor immunity. These results provide additional support to the recommended selinexor phase 2 dosing regimen, as was determined recently (Razak et al. 2016). Disclosures Klebanov: Karyopharm Therapeutics: Employment, Equity Ownership. Kashyap:Karyopharm Therapeutics: Employment, Equity Ownership. Shacham:Karyopharm Therapeutics: Employment, Equity Ownership, Membership on an entity's Board of Directors or advisory committees. Landesman:Karyopharm Therapeutics: Employment, Equity Ownership. Dougan:Karyopharm Therapeutics: Consultancy. Dougan:Karyopharm Therapeutics: Consultancy.

Targeting T-Cell Receptor β-Constant Domain for Immunotherapy of T-Cell Malignancies

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 811-811
Author(s):  
Paul Michael Maciocia ◽  
Patrycja Wawrzyniecka ◽  
Brian Philip ◽  
Ida Ricciardelli ◽  
Ayse U. Akarca ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Cell Lines ◽  
Jurkat Cells ◽  
Car T Cells ◽  
T Cell Lymphomas ◽  
Car T ◽  
Equity Ownership ◽  
T Cell Malignancies

Abstract T-cell lymphomas and leukemias are aggressive, treatment-resistant cancers with poor prognosis. Immunotherapeutic approaches have been limited by a lack of target antigens discriminating malignant from healthy T-cells. While treatment of B-cell cancers has been enhanced by targeting pan B-cell antigens, an equivalent approach is not possible for T-cell malignancies since profound T-cell depletion, unlike B-cell depletion, would be prohibitively toxic. We propose an immunotherapeutic strategy for targeting a pan T-cell antigen without causing severe depletion of normal T-cells. The α/β T-cell receptor (TCR) is a pan T-cell antigen, expressed on >90% of T-cell lymphomas and all normal T-cells. An overlooked feature of the TCR is that the β-constant region comprises 2 functionally identical genes: TRBC1 and TRBC2. Each T-cell expresses only one of these. Hence, normal T-cells will be a mixture of individual cells expressing either TRBC1 or 2, while a clonal T-cell cancer will express TRBC1 or 2 in its entirety. Despite almost identical amino acid sequences, we identified an antibody with unique TRBC1 specificity. Flow cytometry (FACS) of T-cells in normal donors (n = 27) and patients with T-cell cancers (n = 18) revealed all subjects had TRBC1 and 2 cells in both CD4 and CD8 compartments, with median TRBC1 expression of 35% (range 25-47%). In addition, we examined viral-specific T-cells in healthy volunteers, by generation of Epstein Barr virus-specific primary cytotoxic T-cell lines (3 donors) or by identification of cytomegalovirus-specific (3 donors) or adenovirus-specific (5 donors) T-cells by peptide stimulation. We demonstrated similar TRBC1: 2 ratios in viral-specific cells, suggesting that depletion of either subset would not remove viral immunity. Next, using FACS and immunohistochemistry, we showed that TCR+ cell lines (n = 8) and primary T-cell lymphomas and leukemias (n = 55) across a wide range of histological subtypes were entirely restricted to one compartment (34% TRBC1). As proof of concept for TRBC-selective therapy, we developed anti-TRBC1 chimeric antigen receptor (CAR) T-cells. After retroviral transduction of healthy donor T-cells, comprising mixed TRBC1/2 populations, 90% of T-cells expressed CAR on the cell surface. No detectable TRBC1 T-cells remained in the culture, suggesting selective depletion of this population. Anti-TRBC1 CAR T-cells secreted interferon-γ in response to TRBC1-expressing target cell lines (p<0.001) or autologous normal TRBC1+ cells (p<0.001), and not TRBC2 cell lines or autologous normal TRBC2 cells. Anti-TRBC1 CAR killed multiple TRBC1 cell lines (p<0.001) and autologous normal TRBC1 cells (p<0.001), and not TRBC2 cell lines or autologous normal TRBC2 cells. These cell-line based findings were confirmed using primary cells from two patients with TRBC1+ adult T-cell leukaemia/lymphoma. We demonstrated specific tumour kill by allogeneic or autologous T-cells in vitro, despite partial downregulation of surface TCR by tumour cells. We developed a xenograft murine model of disseminated T-cell leukemia by engrafting engineered firefly luciferase+ TRBC1+ Jurkat cells in NOD.Cg-Prkdcscid Il2rgtm1Wjl/SzJ (NSG) mice. Bioluminescent imaging and FACS of marrow at 5 days following IV T-cell injection showed that while mice treated with untransduced T-cells progressed, mice receving anti-TRBC1 CAR T-cells had disease clearance (p<0.0001). In a further model, mice were engrafted with equal proportions of TRBC1-Jurkat and TRBC2-Jurkat cells. FACS analysis of bone marrow at 5 days following T-cell injection demonstrated specific eradication of TRBC1 and not TRBC2 tumour by anti-TRBC1 CAR (p<0.001). In summary, we have demonstrated a novel approach to investigation and targeting of T-cell malignancies by distinguishing between two possible TCR β-chain constant regions. Using CART-cells targeting TRBC1 we have demonstrated proof of concept for anti-TRBC immunotherapy. Unlike non-selective approaches targeting the entire T-cell population, TRBC targeting could eradicate a T-cell tumour while preserving sufficient normal T-cells to maintain cellular immunity. Disclosures Maciocia: Autolus: Equity Ownership, Patents & Royalties: TRBC1 and 2 Targeting for the Diagnosis and Treatment of T-cell Malignancies. Philip:Autolus: Equity Ownership. Onuoha:Autolus: Employment, Equity Ownership. Pule:Amgen: Honoraria; Roche: Honoraria; UCL Business: Patents & Royalties; Autolus Ltd: Employment, Equity Ownership, Research Funding.

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