Background: Adoptive cell therapies, including T and natural killer T (NKT) cells expressing GD2-specific chimeric antigen receptors (CAR), have shown promise in treating relapsed/refractory neuroblastoma (NB) but remain non-curative. A significant barrier to improving these therapies is the reliance on xenogeneic models, which fail to capture the full spectrum of innate and adaptive immune responses. We recently reported that CAR-NKTs have superior in vivo antitumor activity in several syngeneic tumor models (PMID: 39354225), but a relevant syngeneic model has not yet been developed for NB.
Aims: To develop syngeneic NB models for evaluating CAR-T and CAR-NKT cell therapies.
Methods: Murine NB cell lines expressing GD2 and B7H3 were created via lentiviral transduction and optimized through orthotopic implantation into C57BL/6 mice. These cell lines were engineered for cyclophosphamide (Cy) resistance to model relapsed/refractory NB and support lymphodepleting preconditioning. The tumor microenvironment (TME) was characterized using high-parameter flow cytometry. Murine T and NKT cells were transduced with GD2- or B7H3-specific CARs encoding CD28 or 4-1BB costimulatory domains. Cytotoxicity, cytokine production, and in vivo efficacy were evaluated.
Results: GD2 and B7H3 NB models exhibited high tumor inoculation rates and stable antigen expression. The TME featured diverse immune populations, predominantly myeloid cells. In vitro, CAR-T and CAR-NKTs eliminated antigen-specific NB cells. In vivo, both therapies reduced tumor burden post-Cy preconditioning, mirroring clinical trial outcomes but without achieving complete tumor control.
Conclusions: We developed Cy-resistant syngeneic orthotopic NB models with stable GD2 and B7H3 expression. These models enable detailed study of cell therapies in the context of an intact immune system and TME, advancing the development of effective immunotherapeutic strategies.