Preclinical murine models of chimeric antigen receptor (CAR) T cell therapy are widely applied, but are greatly limited by their inability to model the complex human tumor microenvironment and adequately predict safety and efficacy in patients. We therefore sought to develop a system that would enable us to evaluate CAR T cell therapies in dogs with spontaneous cancers. We developed an expansion methodology that yields large numbers of canine T cells from normal or lymphoma-diseased dogs. mRNA electroporation was utilized to express a first-generation canine CD20-specific CAR in expanded T cells. The canine CD20 (cCD20) CAR expression was efficient and transient, and electroporated T cells exhibited antigen-specific interferon-gamma (IFN-γ) secretion and lysed cCD20+ targets. In a first-in-canine study, autologous cCD20-ζ CAR T cells were administered to a dog with relapsed B cell lymphoma. Treatment was well tolerated and led to a modest, but transient, antitumor activity, suggesting that stable CAR expression will be necessary for durable clinical remissions. Our study establishes the methodologies necessary to evaluate CAR T cell therapy in dogs with spontaneous malignancies and lays the foundation for use of outbred canine cancer patients to evaluate the safety and efficacy of next-generation CAR therapies and their optimization prior to translation into humans.
The layered cortex of the cerebellum is folded along the anterior-posterior axis into lobules separated by fissures, allowing the large number of cells needed for advanced cerebellar functions to be packed into a small volume. During development, the cerebellum begins as a smooth ovoid structure with two progenitor zones, the ventricular zone and upper rhombic lip, which give rise to distinct cell types in the mature cerebellum. Initially, the cerebellar primordium is divided into five cardinal lobes, which are subsequently further subdivided by fissures. The cellular processes and genes that regulate the formation of a normal pattern of fissures are poorly understood. The engrailed genes (En1 and En2) are expressed in all cerebellar cell types and are critical for regulating formation of specific fissures. However, the cerebellar cell types that En1 and En2 act in to control growth and/or patterning of fissures has not been determined. We conditionally eliminated En2 or En1 and En2 either in both progenitor zones and their descendents or in the two complementary sets of cells derived from each progenitor zone. En2 was found to be required only transiently in the progenitor zones and their immediate descendents to regulate formation of three fissures and for general growth of the cerebellum. In contrast, En1 and En2 have overlapping functions in the cells derived from each progenitor zone in regulating formation of additional fissures and for extensive cerebellar growth. Furthermore, En1/2 function in ventricular zone-derived cells plays a more significant role in determining the timing of initiation and positioning of fissures, whereas in upper rhombic lip-derived cells the genes are more important in regulating cerebellar growth. Our studies reveal the complex manner in which the En genes control cerebellar growth and foliation in distinct cell types.
Using lentiviral technology, we recently demonstrated that incorporation of CD27 costimulation into CARs greatly improves antitumor activity and T cell persistence. Still, virus-mediated gene transfer is expensive, laborious and enables long-term persistence, creating therapies which cannot be easily discontinued if toxic. To address these concerns, we utilized a non-integrating RNA platform to engineer human T cells to express FRα-specific, CD27 CARs and tested their capacity to eliminate human FRα+ cancer. Novel CARs comprised of human components were constructed, C4-27z and C4opt-27z, a codon-optimized variant created for efficient expression. Following RNA electroporation, C4-27z and C4opt-27z CAR expression is initially ubiquitous but progressively declines across T cell populations. In addition, C4-27z and C4opt-27z RNA CAR T cells secrete high levels of Th-1 cytokines and display strong cytolytic function against human FRα+ cancers in a time- and antigen-dependent manner. Further, C4-27z and C4opt-27z CAR T cells exhibit significant proliferation in vivo, facilitate the complete regression of fully disseminated human ovarian cancer xenografts in mice and reduce the progression of solid ovarian cancer. These results advocate for rapid progression of C4opt-27z RNA CAR to the clinic and establish a new paradigm for preclinical optimization and validation of RNA CAR candidates destined for clinical translation.
B7-H4 is a transmembrane protein that binds an unknown receptor on activated T cells resulting in inhibition of T-cell effector function via cell cycle arrest, decreased proliferation, and reduced IL-2 production. B7-H4 is up-regulated on the surface of cancer cells and immunosuppressive tumor-associated macrophages (TAMs) in a variety of human cancers. Notably, B7-H4 expression levels inversely correlate with patient survival in ovarian cancer, making B7-H4 an attractive candidate for therapeutic intervention. Here, we summarize the experimental data and methodologies that have revealed B7-H4's mRNA and protein expression and function in both mice and humans since its discovery in 2003, with a specific focus on B7-H4's role in ovarian cancer. We also underscore the discrepancies in published data due to high variability in methodology and use of different antibodies, most of which are not commercially available. Finally, since B7-H4 is expressed on tumor cells and TAMs in various cancer types, directing therapeutics against B7-H4 could have tremendous synergistic outcomes in favorably altering the tumor micro-environment and eliminating cancer cells. We highlight the therapeutic potential of targeting B7-H4, both by comparing other negative immune modulators such as PD-1 and CTLA-4 and by identifying novel methods to target B7-H4 directly or indirectly to overcome B7-H4-mediated T-cell inhibition.
Vaccination strategies incorporating the immunodominant HLA-A2-restricted HER2/neu-derived peptide 369-377 (HER2369-377) are increasingly utilized in HER2/neu-expressing cancer patients. The failure of post-vaccination HER2369-377-specific CD8+ T cells to recognize HLA-A2posHER2/neu-expressing cells in vitro, however, has been attributed to impaired MHC class I/HLA-A2 presentation observed in HER2/neu-overexpressing tumors. We reconcile this controversy by demonstrating that HER2369-377 is directly recognized by high functional-avidityHER2369-377-specific CD8+ T cells—either genetically modified to express a novel HER2369-377-TCR or sensitized using HER2369-377-pulsed type 1-polarized dendritic cells (DC1)—on class I-abundant HER2low, but not class I-deficient HER2high, cancer cells. Importantly, a critical cooperation between CD4+ T-helper type-1 (Th1) cytokines IFNγ/TNFα and HER2/neu-targeted antibody trastuzumab is necessary to restore class I expression in HER2high cancers, thereby facilitating recognition and lysis of these cells by HER2369-377-specific CD8+ T cells. Concomitant induction of PD-L1 on HER2/neu-expressing cells by IFNγ/TNF and trastuzumab, however, has minimal impact on DC1-sensitized HER2369-377-CD8+ T cell-mediated cytotoxicity. Although activation of EGFR and HER3 signaling significantly abrogates IFNγ/TNFα and trastuzumab-induced class I restoration, EGFR/HER3 receptor blockade rescues class I expression and ensuing HER2369-377-CD8+ cytotoxicity of HER2/neu-expressing cells. Thus, combinations of CD4+ Th1 immune interventions and multivalent targeting of HER family members may be required for optimal anti-HER2/neuCD8+ T cell-directed immunotherapy.
Chimeric-antigen receptor (CAR)-T cell immunotherapies have been remarkably effective in treating acute lymphoblastic leukemia. However, current strategies generally suffer from difficult, inefficient and costly manufacturing processes, significant patient side effects and poor durability of response in some patients. Here, we report for the first time a CAR-T cell therapeutic comprising a non-immunoglobulin alternative scaffold Centyrin molecule (a "CARTyrin") manufactured with a novel non-viral piggyBacTM (PB) transposon-based system. Our lead candidate, P-BCMA-101, encodes a CARTyrin that targets the B cell maturation antigen (BCMA) for the treatment of multiple myeloma (MM) and has several unique aspects that improve upon earlier CAR-T products. First, P-BCMA-101 is manufactured using only in vitro transcribed mRNA and plasmid DNA without the need for lentivirus or g-retrovirus, resulting in time and cost savings. Importantly, PB is also safer than viral systems due to a less mutagenic insertional profile and is non-oncogenic. Furthermore, PB can efficiently deliver transgenes as large as several hundred kilobases, and, once inserted, transgenes demonstrate more stable, prolonged and higher expression when compared to those delivered by virus. Second, a mutein of the dihydrofolate reductase (DHFR) gene is included in the P-BCMA-101 transgene that can be used in combination with the non-genotoxic drug methotrexate (MTX) to provide a simple and effective method of CARTyrin+ cell enrichment and reduces variability in patient product material. Third, P-BCMA-101 incorporates a safety switch for optional depletion in vivo in case of adverse events. Lastly, the CARTyrin is comprised of a BCMA-specific Centyrin, which are based on a human tenascin fibronectin type III (FN3) consensus sequence. Centyrins have similar binding affinities to the antibody-derived single chain variable fragments (scFv), but are smaller, more thermostable and predicted to be less immunogenic. Importantly, no signs of tonic signaling leading to T cell exhaustion have been observed with CARTyrins unlike scFv-based CAR molecules, which can interact with each other on the surface causing non-specific CAR signaling. The manufacture process of P-BCMA-101 from primary human T cells is straightforward, employs no cytokines, and easily produces enough CARTyrin+ cells to treat patients. Within 18 days of electroporation of purified T cells, we demonstrate > 95% of the cell product is positive for CARTyrin expression and ready to be administered. Notably, our manufacturing process results in > 60% of CARTyrin+ T cells exhibiting a stem-cell memory phenotype (i.e. CD45RA+ CD62L+). P-BCMA-101 cells exhibit specific and robust in vitro activity against BCMA+ tumor targets, ranging from high to very low levels of BCMA, as measured by target-cell killing and CARTyrin-T cell proliferation. Importantly, proliferating P-BCMA-101 cells were highly sensitive in vitro to activation of the safety switch. Finally, we have evaluated the anti-tumor efficacy of P-BCMA-101 in a model of human MM. NSG™ mice were injected IV with 1.5x106 luciferase+ MM.1S cells, an aggressive human MM-derived cell line. After the tumor cells were allowed to grow for 21 days, animals received a single IV administration of 5x106 P-BCMA-101 cells. All untreated control animals demonstrated a marked increase in serum M-protein levels, rapid growth of tumor cells demonstrated by bioluminescent imaging (BLI), and death within four weeks. In stark contrast, 100% of animals that received P-BCMA-101 rapidly eliminated tumors within 7 days as measured by BLI and serum M-protein levels and improved survival out to at least 60 days post-treatment. P-BCMA-101 is the first-in-class of Centyrin-based CAR therapeutics. The CARTyrin, combined with our advanced manufacturing processes, represents a significant improvement over first generation, immunoglobulin-based and virally-transduced CAR-T products. P-BCMA-101 exhibited an advantageous stem-cell memory phenotype and demonstrated specific and potent anti-tumor efficacy against BCMA+ myeloma cells both in vitro and in vivo. Based on these results, we plan to initiate a phase I clinical trial of P-BCMA-101 for the treatment of patients with relapsed and/or refractory MM. Disclosures Hermanson: Poseida Therapeutics: Employment. Barnett:Poseida Therapeutics: Employment. Rengarajan:Poseida Therapeutics: Employment. Codde:Poseida Therapeutics: Employment. Wang:Poseida Therapeutics: Employment. Tan:Poseida Therapeutics: Employment. Martin:Poseida Therapeutics: Employment. Smith:Poseida Therapeutics: Employment. Osertag:Poseida Therapeutics: Employment, Equity Ownership. Shedlock:Poseida Therapeutics: Employment.
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