Adoptive transfer of T cells engineered with tumor-specific T cell receptors (TCRs) has shown limited efficacy in solid tumors, hindered by insufficient persistence, tumor trafficking, and dependence on tumor-associated co-stimulatory ligands. In a phase I trial (NCT04639245) for patients with metastatic MAGE-A1-expressing tumors and adequate organ function; one participant received treatment, which was well-tolerated. In this case and NSG murine models, infusion of CD4/CD8 T cells co-expressing a class-I MAGE-A1-specific TCR and CD8αβ, failed to control tumor progression. To enhance function downstream of TCR signaling, here we investigate the adaptability of TCR components to synthetic modification. Leverag... More
Adoptive transfer of T cells engineered with tumor-specific T cell receptors (TCRs) has shown limited efficacy in solid tumors, hindered by insufficient persistence, tumor trafficking, and dependence on tumor-associated co-stimulatory ligands. In a phase I trial (NCT04639245) for patients with metastatic MAGE-A1-expressing tumors and adequate organ function; one participant received treatment, which was well-tolerated. In this case and NSG murine models, infusion of CD4/CD8 T cells co-expressing a class-I MAGE-A1-specific TCR and CD8αβ, failed to control tumor progression. To enhance function downstream of TCR signaling, here we investigate the adaptability of TCR components to synthetic modification. Leveraging the obligate co-expression of CD8αβ required for class-I TCR function in CD4 T cells, we identify CD8β as a tractable site for engineering without loss of function. In vitro screening demonstrates incorporation of the CD28 intracellular tail, yielding a CD8/CD28 chimeric co-receptor, most effectively enhances cytokine production, T cell persistence, and tumor control in immunodeficient murine models while preserving stem-like transcriptional features compared to native CD8β. Further rational modification of the CD28 binding motifs improves tumor control in vivo with increased intratumoral accumulation and reduced exhaustion. This benefit also extends to PRAME and WT1-specific TCRs in vitro supporting generalizability.
