Genetic ablation of adhesion ligands averts rejection of allogeneic immune cells

Allogeneic cell therapies hold promise for broad clinical implementation, but face limitations due to potential rejection by the recipient immune system. Silencing of beta-2-microglobulin ( B2M ) expression is commonly employed to evade T cell-mediated rejection, although absence of B2M triggers missing-self responses by recipient natural killer (NK) cells. Here, we demonstrate that deletion of the adhesion ligands CD54 and CD58 on targets cells robustly dampens NK cell reactivity across all sub-populations. Genetic deletion of CD54 and CD58 in B2M -deficient allogeneic chimeric antigen receptor (CAR) T and multi-edited induced pluripotent stem cell (iPSC)-derived NK cells reduces their susceptibility to rejection by NK cells in vitro and in vivo without affecting their anti-tumor effector potential. Thus, these data suggest that genetic ablation of adhesion ligands effectively alleviates rejection of allogeneic immune cells for immunotherapy.

A chimeric antigen receptor uniquely recognizing MICA/B stress proteins provides an effective approach to target solid tumors

BACKGROUND

The advent of chimeric antigen receptor (CAR) T cell therapies has transformed the treatment of hematological malignancies; however, broader therapeutic success of CAR T cells has been limited in solid tumors because of their frequently heterogeneous composition. Stress proteins in the MICA and MICB (MICA/B) family are broadly expressed by tumor cells following DNA damage but are rapidly shed to evade immune detection.

METHODS

We have developed a novel CAR targeting the conserved α3 domain of MICA/B (3MICA/B CAR) and incorporated it into a multiplexed-engineered induced pluripotent stem cell (iPSC)-derived natural killer (NK) cell (3MICA/B CAR iNK) that expressed a shedding-resistant form of the CD16 Fc receptor to enable tumor recognition through two major targeting receptors.

FINDINGS

We demonstrated that 3MICA/B CAR mitigates MICA/B shedding and inhibition via soluble MICA/B while simultaneously exhibiting antigen-specific anti-tumor reactivity across an expansive library of human cancer cell lines. Pre-clinical assessment of 3MICA/B CAR iNK cells demonstrated potent antigen-specific in vivo cytolytic activity against both solid and hematological xenograft models, which was further enhanced in combination with tumor-targeted therapeutic antibodies that activate the CD16 Fc receptor.

CONCLUSIONS

Our work demonstrated 3MICA/B CAR iNK cells to be a promising multi-antigen-targeting cancer immunotherapy approach intended for solid tumors.

FUNDING

Funded by Fate Therapeutics and NIH (R01CA238039).

Quadruple gene-engineered natural killer cells enable multi-antigen targeting for durable antitumor activity against multiple myeloma

Allogeneic natural killer (NK) cell adoptive transfer is a promising treatment for several cancers but is less effective for the treatment of multiple myeloma. In this study, we report on quadruple gene-engineered induced pluripotent stem cell (iPSC)-derived NK cells designed for mass production from a renewable source and for dual targeting against multiple myeloma through the introduction of an NK cell-optimized chimeric antigen receptor (CAR) specific for B cell maturation antigen (BCMA) and a high affinity, non-cleavable CD16 to augment antibody-dependent cellular cytotoxicity when combined with therapeutic anti-CD38 antibodies. Additionally, these cells express a membrane-bound interleukin-15 fusion molecule to enhance function and persistence along with knock out of CD38 to prevent antibody-mediated fratricide and enhance NK cell metabolic fitness. In various preclinical models, including xenogeneic adoptive transfer models, quadruple gene-engineered NK cells consistently demonstrate durable antitumor activity independent of exogenous cytokine support. Results presented here support clinical translation of this off-the-shelf strategy for effective treatment of multiple myeloma.

Abstract 2828: A novel synthetic stealth receptor that redirects host immune cell alloreactivity and potentiates functional persistence of adoptively transferred off-the-shelf cell-based cancer therapy

Chimeric antigen receptor (CAR) T-cell therapies have revolutionized the treatment of hematologic malignancies and have shown significant potential in solid tumor indications. However, logistical complexities associated with patient-specific CAR T-cell therapies often limit broad accessibility. Many of these challenges can be overcome with an allogeneic cellular product, but immune cell-mediated rejection of allogeneic cellular therapies remains a significant concern. Both allogeneic and autologous cell therapies currently rely on lymphodepleting conditioning to modulate the immune system and create greater access to homeostatic cytokines. However, protracted lympho-conditioning has been associated with poor immune reconstitution and increased susceptibility to opportunistic infections. Therefore, an ideal allogeneic cell therapy would be able to avoid immune rejection while reducing or eliminating the need for chemotherapeutic conditioning to deplete host lymphocytes.

To address many of these challenges, we engineered our novel alloimmune defense receptor (ADR) that targets 41BB+ alloreactive immune cells while providing a CD3z signaling boost into our off-the-shelf iPSC derived NK cells expressing anti-CD19 CAR (CAR iNK). The ability of ADR+ CAR iNK cells to resist alloimmune rejection was tested by co-culturing ADR+ CAR iNK cells with allogeneic PBMCs from ten donors in a mixed lymphocyte reaction assay. Notably, ADR+ CAR iNK cells co-cultured with allogeneic PBMCs persisted to similar levels as the PBMC-free culture while ADR negative CAR iNK cells were eliminated when co-cultured with allogeneic PBMCs. Furthermore, all PBMC donors screened in ADR+ CAR iNK cell co-cultures showed ablation of reactive 41BB+ NK and T cells, with non-activated T cells remaining intact.

CAR iNK cells +/- ADR were then compared in a Nalm6 disseminated in vivo model for anti-tumor efficacy. ADR+ CAR iNK cells and their ADR negative counterparts were found to equivalently control tumor. Building on this tumor model, we co-infused allogeneic T cells to mimic an immuno-competent setting. The data demonstrated that ADR negative CAR iNK cells were depleted and were unable to control tumor growth while significant levels of allogeneic T cells persisted. In contrast, ADR+ CAR iNK cells were able to resist allogeneic T cell attack, control tumor, and persist when compared to the ADR negative control.

Collectively, our preliminary data suggest that ADR-armed CAR iNK cells withstand immune cell-mediated rejection with uncompromised effector function. We are actively developing models to confirm our initial finding that ADR+ effector cells also benefit from their engagement with alloreactive cells in immuno-competent settings to promote enhanced anti-tumor responses, proliferation, and persistence.

Citation Format: Alan M. Williams, Ken Hayama, Yijia Pan, Brian Groff, Rina Mbofung, Lauren Fong, Nicholas Brookhouser, Berhan Mandefro, Ramzey Abujarour, Tom Lee, Quirin Hammer, Karl-Johan Malmberg, Maksim Mamonkin, Ryan Bjordahl, Jode Goodridge, Bahram Valamehr. A novel synthetic stealth receptor that redirects host immune cell alloreactivity and potentiates functional persistence of adoptively transferred off-the-shelf cell-based cancer therapy [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2828.

117 FT536 Path to IND: Ubiquitous targeting of solid tumors with an off-the-shelf, first-of-kind MICA/B-specific CAR-iNK cellular immunotherapy

Background

Chimeric antigen receptor (CAR)-T cell therapy has revolutionized cancer treatment, but it is associated with significant dose-limiting toxicities, restricted tumor targeting (limited by specific antigen expression), and, notably, a lack of multi-antigen targeting capability to mitigate tumor associated immune evasion and heterogeneity. Furthermore, dysfunctional starting material, product inconsistency, and small manufacturing lot size limits the application and on-demand availability of CAR-T cell therapy.

Methods

To overcome these considerable limitations, we have developed FT536, a first-of-kind, induced pluripotent stem cell (iPSC)-derived NK (iNK) cell with a novel CAR that ubiquitously targets cancer cells through canonical stress ligand recognition. We have previously reported FT536 recognizes the conserved α3 domain of the pan-tumor associated antigens MICA and MICB (MICA/B), and is derived from a renewable master iPSC line that contains multiplexed genetic edits to enhance effector cell functionality, persistence, and multi-antigen targeting capabilities via high affinity non cleavable CD16 (hnCD16) mediated antibody dependent cellular cytotoxicity (ADCC). Here we preview the nonclinical study for the investigational new drug (IND) application for FT536.

Results

Utilizing a manufacturing process analogous to pharmaceutical drug product development, we demonstrate FT536 can be consistently and uniformly produced with a greater than 4x10E7 fold cellular expansion per manufacturing campaign. Furthermore, FT536 can be cryopreserved at clinical scale to support off-the-shelf clinical application, with rapid product thaw and immediate patient infusion in an out-patient setting. Functional evaluation demonstrated that FT536 uniquely possesses potent and persistent antigen specific cytolytic activity against an array of solid and hematological tumor lines. Through its hnCD16 modality, FT536 can be utilized in combination with monoclonal antibodies to provide multi-antigen targeting capabilities and in conjunction with chemotherapeutics and/or radiation that augment surface MICA/B expression. In addition, directly thawed and infused FT536 demonstrated significant tumor growth inhibition in multiple solid and liquid in vivo xenograft models, in which tumor control was further enhanced in combination with a therapeutic antibody (figure 1). Finally, ongoing studies utilizing a lung adenocarcinoma model have highlighted the sustained persistence of FT536 in lung tissue up to 33 days following a single dose infusion without the need for exogenous cytokine support.

Abstract 117 Figure 1

FT536 provides statistically significant in vivo anti-tumor activity which is enhanced in combination with ADCC active monoclonal antibody therapy. (A-B) FT536 significantly reduced the number of lung and liver (not shown) metastases compared to CAR negative iNK control cells in a murine metastatic melanoma model using B16-F10 cells engineered to overexpress human MICA. (C-D) FT536 alone, and in combination with Herceptin, demonstrate significant tumor growth inhibition (TGI) compared to Herceptin alone in an orthotopic xenograft model of human lung adenocarcinoma.

Conclusions

Collectively, these studies demonstrate that FT536 is a highly potent, multi-tumor targeting CAR-iNK cell product that is uniform in composition and can be effectively and safely used off-the-shelf for on-demand treatment of multiple solid and hematological malignancies. An IND submission is planned for 2021, with an initial Phase 1 clinical trial to follow.

Abstract 1591: FT536: Preclinical development of a novel off-the-shelf CAR-MICA/B NK cell immunotherapy combined with radiation and antibody treatments as a first-of-kind pan-cancer targeting strategy

Cancer immunotherapies have revolutionized cancer treatment by showing clinical efficacy across multiple cancer indications. However, tumor heterogeneity and evasion from host immune cell surveillance often limit the durability and efficacy of these strategies as monotherapies. Consequently, it is becoming common practice to combine existing anticancer treatments and novel immunotherapies to maximize clinical efficacy. The pan tumor-associated antigens MICA and MICB (MICA/B) are surface proteins induced by cellular stress, often associated with tumorigenesis, and are recognized by the NK cell activating receptor NKG2D. To evade immune recognition, cancer cells often proteolytically shed the membrane distal domains of MICA/B, leading to reduced NKG2D recognition. To combat this pervasive tumor escape mechanism and create a ubiquitous cancer targeting platform, we have developed a novel CAR-iPSC-derived NK (iNK) cell that targets the conserved α3 domain of MICA/B, rendering it resistant to inhibition by shed MICA/B. To enhance effector cell function, persistence and multi-antigen capacity, further genetic editing at the iPSC stage was conducted to equip the CAR-iNK cells with a unique IL-15/IL-15 receptor fusion, the knockout of CD38 and a novel high-affinity, non-cleavable CD16 (hnCD16) to enhance antibody-dependent cellular cytotoxicity (ADCC). In this study, we evaluated the function of multiplexed engineered MICA/B CAR iNK cells (termed FT536) in combination with monoclonal antibodies (mAbs), to elicit multi-antigen targeting, and radiation therapy, to augment surface MICA/B expression. FT536 showed superior in vitro cytotoxicity and in vivo tumor control against an array of MICA/B expressing tumor lines. Furthermore, ADCC, induced in combination with cetuximab or trastuzumab, enhanced the potency of FT536 against various solid tumor lines (p <0.05). To demonstrate the capability of FT536 to synergize with irradiation therapy, we utilized a panel of tumor lines, divergent in tissue origin and MICA/B expression profiles. This approach highlighted that irradiation of the SK-BR-3 tumor line, a breast adenocarcinoma that expresses low levels of surface MICA/B and high levels of EGFR, induced the upregulation of MICA/B expression (p <0.05). As anticipated, FT536 exhibited enhanced, CAR-dependent cytotoxicity against irradiated SK-BR-3 cells. Ongoing work is focused on the development of in vivo models that combine FT536 with in situ tumor irradiation and mAbs in order to promote durable responses and the elimination of resistant and heterogenous cancer cells. These data demonstrate successful targeting of MICA/B positive tumors by FT536 can be augmented by mAb and radiation therapies as first-of-kind combinatorial strategies to broadly target escape-prone tumors.

Citation Format: John Goulding, Robert Blum, Bryan Hancock, Moyar Ge, Brian Groff, Soheila Shirinbak, Joy Grant, Martin Hosking, Mochtar Pribadi, Yijia Pan, Hui-Yi Chui, Shohreh Sikaroodi, Lauren Fong, Janel Huffman, Wen-I Yeh, Chia-Wei Chang, Thomas Dailey, Miguel Meza, Cokey Nguyen, Lucas Ferrari de Andrade, Tom Lee, Ryan Bjordahl, Kai W. Wucherpfennig, Bahram Valamehr. FT536: Preclinical development of a novel off-the-shelf CAR-MICA/B NK cell immunotherapy combined with radiation and antibody treatments as a first-of-kind pan-cancer targeting strategy [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 1591.

Abstract 1550: FT576 path to first-of-kind clinical trial: translation of a versatile multi-antigen specific off-the-shelf NK cell for treatment of multiple myeloma

Chimeric antigen receptor (CAR) directed therapies have been used successfully to treat a variety of hematological malignancies. With the advent of multi-modal engineering, adoptive cell therapy offers the opportunity to tackle increasingly complex disease settings such as multiple myeloma (MM), where targeting of single tumor associated antigen by CAR or monoclonal antibodies (mAb) is confounded by antigen loss and clonal heterogeneity. Further, expanding treatment options beyond primary T and NK cell based therapies has multiple advantages, including the use of induced pluripotent stem cells (iPSC) to derive effector cells using precision genetic engineering that can be uniformly manufactured at scale from a clonally-derived master cell bank (MCB).FT576 is a multiplex-edited, iPSC-derived CAR-NK (CAR-iNK) cell therapy designed for treatment of Multiple Myeloma. FT576 is engineered 1) to express a recombinant IL-15/IL-15 receptor signaling complex (IL-15RF) for enhanced persistence; 2) to express an enhanced high-affinity, non-cleavable CD16 (hnCD16) ; 3) to disrupt expression of CD38, allowing for enhanced ADCC without NK cell fratricide; and 4) to express a BCMA-targeted CAR with NK-cell optimized signaling.CAR-directed specificity of the FT576 cells for BCMA was demonstrated using a short-term cytotoxicity assay (90.8% cytotoxicity against BCMA+ vs 22.1% BCMA- cells, p<0.0001). Utilizing a long-range tumor clearance assay without exogenous cytokine support, serial restimulation by repeated rounds of exposure to fresh MM target cells showed remarkable persistence and antigen-mediated expansion of FT576 by CAR alone or combined with anti-CD38 mAb. Continuous long-range clearance assays demonstrated levels of BCMA targeting activity of FT576 alone was equivalent to primary BCMA-targeted CAR-T cells against a panel of BCMA+ target cells. BCMA-CAR targeting was tested in combination with multiple therapeutic mAbs to explore breadth of tumor clearance in primary bone marrow samples.In xenograft models, dosing of FT576 as a monotherapy was highly protective against MM progression, resulting in deeper tumor regression and delayed outgrowth. The treatment of MM-bearing mice with both FT576 and daratumumab produced greater myeloma control than either agent alone, demonstrating combined CAR and antibody-directed cytotoxicity. Additionally, FT576 demonstrated enhanced persistence compared to peripheral blood NK cells, suggestive of antigen mediated expansion. Together, these studies demonstrate the versatility of FT576 as a highly effective multi-antigen targeting and cost-effective, off-the-shelf BCMA-CAR iNK cell product and support the rational for a first-of-kind Phase I Study of FT576 as a monotherapy or in combination with therapeutic mAbs targeted to MM-associated surface antigens.

Citation Format: Jode P. Goodridge, Ryan Bjordahl, Sajid Mahmood, John Reiser, Svetlana Gaidarova, Robert Blum, Frank Cichocki, Hui-yi Chu, Greg Bonello, Tom Lee, Brian Groff, Miguel Meza, Thomas Daley, Yu-waye Chu, Bruce Walcheck, Karl-Johan Malmberg, Jeffrey S. Miller, Armin Rehm, Bahram Valamehr. FT576 path to first-of-kind clinical trial: translation of a versatile multi-antigen specific off-the-shelf NK cell for treatment of multiple myeloma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 1550.

Abstract 2216: Combinational strategy targeting B cell malignancy using iPSC engineered CAR-NK (FT596) and CAR-T cell (FT819) platforms with therapeutic antibody to achieve an effective deep and durable response

The use of induced pluripotent stem cells (iPSCs) to derive immune effector cells offers distinct advantages for immune therapy over existing patient- or donor- derived platforms, not only in terms of scalable manufacturing and precision genetic engineering at the clonal level, but also in allowing the generation and combinational use of multiple effector cell types each with distinct characteristics. Taking cues from the natural propagation of innate to adaptive effector responses, here we describe the combined use of multi-engineered iPSC derived Natural Killer (iNK) and T (iT) cell platforms in order to exploit the unique properties of each cell type to achieve both depth and durability of response for hematological malignancies. As innate cells, NK cells are characterized by the capacity for spontaneous reactivity, either in response to cell surface antigen or downregulation of class I MHC, and the rapid kinetic under which NK cells operate make them an ideal candidate to achieve a depth of response that outpaces the limiting effects of cytokine support. FT596 was developed as a dual-targeted iNK cell platform engineered to express both a CD19-directed, NK cell-optimized (NKG2D-2B4-CD3ζ) chimeric antigen receptor (CAR) and a high-affinity, non-cleavable Fc receptor (hnCD16), enabling multi-targeting through combination with therapeutic antibodies. The activity of each receptor is further enhanced by the expression of an IL15-IL15Ra fusion receptor, which also allows the cells to expand in the absence of exogenous cytokine support and prolongs cell survival in vitro and in vivo. T cells are exquisitely specific and undergo rapid clonal expansion and differentiation in response to target antigen, and antigen driven persistence has been demonstrated as a key determinant in efficacy in primary CAR-T cell immune therapy. FT819 is an iT cell platform engineered to express a functionally optimized CD19-CAR (1XX) that has been genome edited into the T cell receptor (TCR) alpha constant (TRAC) locus to provide ideal CAR activity and to prevent TCR expression, thereby avoiding the complications of GVH reactivity in an allogeneic setting. In vivo, both FT596 and FT819 showed stable levels of tumor cell clearance against the CD19+ acute lymphoblastic leukemia cell line NALM6, comparable to that of primary CAR19 T cells (p*<0.0001 for FT596, FT819 or Primary CART vs NALM6 alone). FT596 also shows enhanced clearance of CD19+CD20+ Burkitts lymphoma cell line RAJI when used in combination with rituximab (p=0.0002 vs rituximab alone). Collectively, these studies suggest a compounded anti-tumor effect can be achieved utilizing the inherent properties of engineered CAR-iNK cells together with therapeutic antibody combined with engineered CAR-iT cells which will be highlighted in this presentation.

Citation Format: Jode P. Goodridge, John W. Reiser, Ryan Bjordahl, Milli Mandal, Chia-wei Chang, Raedun Clarck, Sajid Mahmood, Huang Zhu, Svetlana Gaidarova, Robert Blum, Frank Cichocki, Hui-ting Hsu, Greg Bonello, Tom Lee, Brian Groff, Karl-Johan Mamlberg, Bruce Walcheck, Jeffrey S. Miller, Dan Kaufman, Bahram Valamehr. Combinational strategy targeting B cell malignancy using iPSC engineered CAR-NK (FT596) and CAR-T cell (FT819) platforms with therapeutic antibody to achieve an effective deep and durable response [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 2216.

Abstract 3191: FT516, an off-the-shelf engineered NK cell therapeutic product for universal anti-tumor targeting strategy in combination with monoclonal antibodies

Monoclonal antibody (mAb) treatment is an effective therapeutic strategy for many cancer types, with significant opportunity to optimize natural killer (NK) cell and mAb interaction to improve antibody-dependent cellular cytotoxicity (ADCC). NK cells are critical mediators of ADCC, where they recognize and kill malignant cells coated with antibody through the Fc receptor CD16. However, NK cell function is often impaired in cancer patients, which limits the induction of ADCC in mAb therapy. To enhance ADCC in combination with commercialized mAb therapies, we have developed FT516; a novel, off-the-shelf NK cell immunotherapeutic engineered to uniformly express a high-affinity, non-cleavable version of CD16 (hnCD16).

FT516 is manufactured from a renewable master induced pluripotent stem cell (iPSC) line with the potential to generate hundreds to thousands of doses of allogeneic NK cells uniformly expressing hnCD16 (hnCD16 iNK cells) per manufacturing run. In an in vivo xenograft model of disseminated lymphoma, FT516 reduced tumor burden below the limit of detection at day 28 after transplant when delivered in combination with rituximab, which was significantly more potent than peripheral blood NK cells (p = 0.03). This was attributed to enhanced CD16-mediated activation of FT516, as observed through improved calcium flux and enhanced activation of signaling pathways such as ERK (p = 0.016), LAT (p = 0.0007), and ZAP70 (p = 0.0003), leading to enhanced ADCC and cytokine production. FT516 also maintained tumor cell specificity, with preferential targeting of K562 leukemia cells when presented with a mixture of K562 and normal PBMC targets (p < 0.0001).

We also explored strategies to further engineer therapeutic function to enhance FT516 efficacy. Combined expression of hnCD16 with an IL-15/IL-15ra fusion construct enhanced the persistence of iNK cells and allowed survival of up to 8 weeks in vivo without exogenous cytokine (p < 0.0001), with correlation to improved efficacy.

In vitro modeling of FT516 with daratumumab demonstrated ADCC against multiple myeloma (MM) targets. However, as reported, daratumumab induced NK cell fratricide through binding of CD38 on NK cells. To rescue daratumumab-mediated fratricide, we specifically deleted CD38 at the iPSC level and demonstrated that fratricide was undetectable in hnCD16 CD38-/- iNK cells (<1% vs. 35% for peripheral blood NK). By avoiding fratricide, hnCD16 CD38-/- iNK cells had improved persistence and efficacy against MM cells in vitro and in a disseminated xenograft model of MM. These data support clinical development of FT516 in combination with rituximab for the treatment of B cell malignancies and demonstrate a targeting platform that enables further modifications to address challenges related to efficacy, safety, and persistence of allogeneic adoptive immunotherapies.

Citation Format: Ryan Bjordahl, Huang Zhu, Paul Rogers, Svetlana Gaidarova, Moyar Q. Ge, Robert Blum, Frank Cichocki, Jode Goodridge, Helen Chu, Greg Bonello, Tom Lee, Brian Groff, Ramzey Abujarour, Bruce Walcheck, Jeffrey Miller, Dan Kaufman, Bahram Valamehr. FT516, an off-the-shelf engineered NK cell therapeutic product for universal anti-tumor targeting strategy in combination with monoclonal antibodies [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 3191.

Abstract 3207: Preclinical development of first-of-kind dual-targeted off-the-shelf CAR-NK cell product with engineered persistence for an effective treatment of B cell malignancies

The unprecedented success of chimeric antigen receptor (CAR) and monoclonal antibody (mAb) -based immune-therapies has provided a clear indication that a system as complex as human immunity can be harnessed, even enhanced, toward a growing number of hematological cancers. Here we describe pre-clinical progress to develop a multi-functional induced pluripotent stem cell (iPSC)-derived natural killer (iNK) cell platform that combines engineered longevity with CAR and mAb-based modalities to leverage the intrinsic polyfunctionality of NK cells. As frontrunners of immune surveillance, NK cells employ a diverse array of germline encoded receptors in distinct combinations, which engage multiple signaling pathways to deliver potent effector responses that can be directed toward tumor cells, drive rapid proliferation, and pave the way for recruitment of adaptive immunity. Specific engagement of multiple signaling pathways was achieved in iNK cells through design of an NK cell-centric CAR combining the transmembrane domain of activating receptor NKG2D with intracellular signaling domains of 2B4 and CD3ζ. Recombining an anti-CD19 scFv onto this signaling platform, CAR modified iNK cells produced specific in vitro recognition of CD19+ B cell lymphoma cells in short term and long term cytotoxicity assays (84% vs 40% clearance of tumor cells at 60H, p<0.001). Further introduction of a fusion receptor consisting of Interleukin-15 (IL15) with IL15 receptor α, enabling autonomous IL15 stimulation, greatly improved iNK longevity and functional persistence in animal models. Moreover, iNK cells modified with IL15 fusion receptor showed enhanced functional maturation including KIR expression and effector molecules such as granzyme B ( ≥2 fold). While iNK cells with anti-CD19 CAR delayed tumor progression in vivo prior to relapse, iNK cells engineered with anti-CD19 CAR and IL15/IL15 receptor were curative against B cell lymphoma, (p<0.002). Expression of CAR and IL15 fusion receptor was then combined with a third modality, a high affinity CD16a receptor modified to prevent proteolytic cleavage (hnCD16). These multifunctional iNK cells demonstrated enhanced directed cytotoxicity in vitro in combination with rituximab against CD19+ targets (>99% vs 90% clearance of tumor cells) and CD19- targets (>99% vs 50% clearance of tumor cells by iNK with anti-CD19 CAR alone, p<0.0001), revealing a unique opportunity to combine CAR with a universal targeting modality to mitigate antigen escape and address heterogeneity in the tumor population by a multi-node targeting strategy. The resulting product, FT519, is designed to provide a flexible, potent and persistent engineered immune cell that utilizes the intrinsic versatility of NK cells to enable a highly effective combination therapy in a single, standardized, scalable, off-the-shelf platform.

Citation Format: Jode Goodridge, Sajid Mahmood, Huang Zhu, Svetlana Gaidarova, Robert Blum, Ryan Bjordahl, Frank Cichocki, Hui-Yi Chu, Greg Bonello, Tom Lee, Brian Groff, Karl-Johan Malmberg, Bruce Walcheck, Jeffrey Miller, Dan Kaufman, Bahram Valamehr. Preclinical development of first-of-kind dual-targeted off-the-shelf CAR-NK cell product with engineered persistence for an effective treatment of B cell malignancies [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 3207.

Abstract 3755: Renewable and genetically engineered natural killer cells for off-the-shelf adoptive cellular immunotherapy

The unique attributes of a combinatorial tumor recognition system, diminished off-tumor cytotoxicity, and multifaceted effector function make natural killer (NK) cells a prime candidate for a universal approach to cancer immunotherapy. In addition, NK cells are the principal mediator of antibody-directed cellular cytotoxicity (ADCC). However, NK cell function is often impaired in the setting of cancer, reducing the effectiveness of the endogenous immune system and the therapeutic efficacy of monoclonal antibodies. To address the need for advanced and combinatorial cancer therapies, we developed a unique and effective strategy to create a renewable source of engineered “off-the-shelf” NK cells with augmented function, including enhanced ADCC and persistence. Key challenges associated with genetic editing, limited expansion, persistence and variability of peripheral blood (PB)-derived NK cells were overcome by utilizing our induced pluripotent stem cell (iPSC) technology as the unlimited starting material for the reproducible and consistent derivation of engineered NK cells. Through targeted transgene integration, we produced a clonal iPSC master cell line to continuously produce NK cells engineered to uniformly express a high affinity, non-cleavable version of CD16 (hnCD16-NK). In directed differentiation, the hnCD16-NK cells displayed homogeneous expression of CD16 (>95%) and a mature CD56+ NK cell phenotype, as exhibited by expression of KIR, NCRs, DNAM-1, and NKG2D. In contrast to endogenous CD16 expression, the engineered hnCD16 molecule was shown to be cleavage resistant upon NK cell activation (>95% CD16+ hnCD16-NK vs. <10% CD16+ PB-derived NK cell, upon target cell-mediated activation), and demonstrated enhanced antibody binding compared to PB-derived NK cells expressing the low-affinity variant. In addition to increased expression of the cytolytic molecules perforin and granzyme B and enhanced direct cytotoxicity against tumor targets, hnCD16-NK cells displayed superior ADCC capacity and cytokine production in response to CD16 stimulation. Importantly, manufacture of hnCD16-NK cells was proven to be highly scalable, delivering up to 107 fold expansion over a 35 day period. The maintained proliferative capacity can be in part associated with longer telomere length seen in hnCD16-NK cells. Furthermore, deletion of classical human leukocyte antigen molecules and ectopic expression of immunosuppressive proteins engineered at the iPSC level provided the ability of hnCD16-NK cells to potentially overcome the host histocompatibility barrier and to improve persistence in the allogeneic setting. In conclusion, the preclinical data presented herein highlight the therapeutic value of hnCD16-iNK cells as an ideal ADCC-mediated “off-the-shelf” NK cell-based immunotherapeutic product with augmented persistence, anti-tumor capacity, manufacturing reliability and preclinical efficacy.

Citation Format: Ryan Bjordahl, Frank Cichocki, Raedun Clarke, Svetlana Gaidarova, Brian Groff, Paul Rogers, Stacey Moreno, Ramzey Abujarour, Greg Bonello, Tom Lee, Weijie Lan, Matthieu Bauer, Dave Robbins, Betsy Rezner, Sarah Cooley, Bruce Walcheck, Stewart Abbot, Bruce Blazar, Scott Wolchko, Daniel Shoemaker, Jeffrey S. Miller, Bahram Valamehr. Renewable and genetically engineered natural killer cells for off-the-shelf adoptive cellular immunotherapy [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 3755. doi:10.1158/1538-7445.AM2017-3755

Abstract 609: Overcoming host histocompatibility barrier to create a renewable source of off-the-shelf effector lymphocytes for adoptive immunotherapy

Encouraging clinical outcomes in autologous cellular immunotherapy have garnered hope and excitement. However, limitations of patient-derived cancer immunotherapies remain to be addressed to deliver reliable and efficacious therapies with broader applicability. Induced pluripotent stem cells (iPSCs) are a unique, renewable source for the continuous generation of cellular therapeutics and represent a highly promising approach for overcoming many of the limitations of autologous therapy. To advance the promise of iPSC technology as an “off-the-shelf” (OTS) source of cellular therapeutics, several considerations need to be addressed. Ensuring the persistence of allogeneic OTS therapies after adoptive cell transfer across histocompatibility barriers is a key requirement. Establishing a master cell line from genetically engineered clonal iPSC lines with the capacity to continuously generate homogenous populations of highly functional effector cells will also be necessary. Here we demonstrate a comprehensive approach for the generation of immune tolerant effector cells derived from a genetically engineered iPSC master cell line. We successfully combined deletion of classical human leukocyte antigen molecules with expression of immunosuppressive proteins to generate clonal iPSC lines with the ability to escape immune rejection. Utilizing in vitro quantitative live cell analysis we show that OTS-iPSCs elicit a significantly decreased cytotoxic response from both peripheral blood (PB)-NK cells (47.9 vs. 91.4% survival at 3:1 E:T ratio) and PB-T cells (>2.7-fold greater number of OTS-iPSC derived cells remaining at 88 hrs). Additionally, mixed lymphocyte reactions employing unfractionated PB mononuclear cells resulted in significantly decreased activation and proliferation of CD8+ T cells (63.4 vs. 29.6%), CD4+ T cells (70.9 vs. 17.3%) and NK cells (46.8 vs. 11.6%). In preclinical mouse models we demonstrate that OTS-iPSCs exhibit improved persistence in vivo. Bilateral engraftments were established in non-conditioned, fully immune-competent recipient mice using luciferized wildtype and OTS-iPSCs. Daily bioluminescence imaging revealed a significant increase in persistence of OTS-iPSCs during the 48-196 hour post injection window (>5.5 fold greater luminescence at 96 hrs). Using our potent chemically-defined stage-specific monolayer hematopoietic differentiation platform, we demonstrate that OTS-iPSC derived CD34 expressing hematopoietic cells are reproducibly scaled and readily give rise to functional lymphocytes carrying the engineered targeted modality in a homogenous manner (95 +/- 5%). The outlined preclinical data illustrate that iPSCs are an ideal renewable source for OTS hematopoietic cell-based immunotherapies and represent a potentially exponential advancement in adoptive immunotherapy.

Citation Format: Raedun L. Clarke, Matthieu Bauer, Ryan Bjordahl, Jeffrey Sasaki, Brian Groff, Svetlana Gaidarova, Tom Tong Lee, Weijie Lan, Michelle Burrascano, Ramzey Abujarour, Greg Bonello, Megan Robinson, Stewart Abbot, Scott Wolchko, Daniel Shoemaker, Bob Valamehr. Overcoming host histocompatibility barrier to create a renewable source of off-the-shelf effector lymphocytes for adoptive immunotherapy [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 609. doi:10.1158/1538-7445.AM2017-609

[Pertinence of the preoperative exploration in the evaluation of the risk of lymph node metastasis in endometrial cancer]

PURPOSE

To assess the relevance of MRI, endometrial biopsy and curettage in the diagnosis of endometrial cancer at high risk of lymph node metastasis.

PATIENTS AND METHODS

A retrospective study on continuous series of patients treated for endometrial cancer limited to the uterus between 2004 and 2008, results of preoperative evaluation of tumor stage using MRI, histological type and grade by endometrial curettage and biopsies were compared to final histological examination.

RESULTS

One hundred and sixty-nine patients were included in the study. Ninety (53.3%) had MRI, 112 (66.2%) curettage and 61 (36.6%) endometrial biopsy using Pipelle de Cornier. Sensibility (SN), specificity (SP), positive (PPV) and negative predictive values (NPV) of MRI, in the diagnosis of endometrial cancer at high risk of lymph nodes metastases were of 65.6%, 87.2%, 77.7%, 79.2%. For EB and curettage SN, SP, PPV and NPV were of 42.9%, 96.9%, 85%, 79.5%; 80.6%, 98.3%, 96.2% and 90.6% respectively. 37.8% of cancers diagnosed to be at low risk of lymph node metastasis were at high risk in definitive histologic examination.

DISCUSSION AND CONCLUSION

Preoperative evaluation by MRI, endometrial curettage and biopsy has good diagnostic value in the identification of endometrial cancer susceptible to benefit from lymphadenectomy. Underestimation, however, is encountered in approximately one third of cases.