Abstract 5121: Next-generation immunocompetent and humanized neuroblastoma murine models for the discovery and validation of novel immunotherapies

Abstract The success of CD19-directed chimeric antigen receptor (CAR)-T cell therapy for ALL has yet to be matched in solid pediatric malignancies. Moreover, immune checkpoint blockade has shown limited benefit in pediatric cancer. Despite this unmet need, there is a lack of reliable preclinical models to facilitate novel target discovery, validate therapeutic benefit, anticipate on- or off-target toxicity, and understand mechanisms of resistance. Syngeneic murine model systems are a critical intermediate for preclinical translation, preserving the complex and heterogenous immune landscape and host-immunotherapy interactions. However, model interpretation and validity are limited as expression and function of murine targets and immune effector cells are not always conserved. We have developed a syngeneic immunocompetent C57BL/6 neuroblastoma system to study CAR efficacy, toxicity, and mechanisms of resistance, as well a variety of vaccination strategies. Specifically, we have built two murine CAR T constructs containing a 100% conserved antigen-directed scFv joined to orthologous murine TCR signaling machinery. In parallel, we engineered the murine neuroblastoma cell line 9464D to stably express surface antigen Gpc2 (Bosse, Cancer Cell 2017), or a novel chimeric single chain trimer of a 9mer peptide from intracellular oncoprotein PHOX2B discovered on HLA-A*24:02 (Yarmarkovich, Nature 2023) as Phox2b/A24*02/H2-kb to generate tumor-bearing B6 or B6-A24-Tg mice. We are currently using this system to demonstrate how vaccination approaches enhance the persistence and potency of CART directed to both targets and are extending our syngeneic murine constructs to additional TH-MYCN allograft models. To further study the innate and adaptive immune response to various therapeutics, we have developed peripheral blood mononuclear cell (PBMC) humanized models. Our autologous humanized PDX mouse models of neuroblastoma use immunocompromised NSG mice engrafted with a PDX and humanized with patient-matched PBMCs to evaluate personalized vaccines in vivo. We have shown the ability to stably engraft both lymphoid and myeloid populations in various human cytokine transgenic NSG variants (i.e. SGM3, Flt3L), allowing for T/B cell and APC crosstalk, thus providing a robust means to study targeted interventions. We are currently using this autologously humanized PDX model to test the ability of multivalent, personalized neoantigen vaccines developed specific to the neoantigen landscape of individual PDXs, with a focus on endogenous T cell responses of patient PBMC against their own PDX in vivo. Citation Format: Timothy T. Spear, Elisabeth Posthill, David Groff, Anna M. Giudice, Kristopher R. Bosse, Leyuan Ma, Stephen P. Schoenberger, John M. Maris. Next-generation immunocompetent and humanized neuroblastoma murine models for the discovery and validation of novel immunotherapies [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 5121.