Tumor-specific CD8+ T cells from the bone marrow resist exhaustion and exhibit increased persistence in tumor-bearing hosts as compared with tumor-infiltrating lymphocytes

Background: Immunotherapy is now an integral aspect of cancer therapy. Strategies employing adoptive cell therapy (ACT) have seen the establishment of chimeric antigen receptor (CAR)-T cells using peripheral blood lymphocytes as well as tumor-infiltrating lymphocytes (TILs) with significant clinical results. The bone marrow (BM) is an immunological niche housing T cells with specificity for previously encountered antigens, including tumor-associated antigens from certain solid cancers. This study sought to improve our understanding of tumor-specific BM T cells in the context of solid tumors by comparing them with TILs, and to assess whether there is a rationale for using the BM as a source of T cells for ACT against solid malignancies. Methods: We used the murine B16 melanoma model examining both the endogenous OVA-specific T cell response using an OVA-specific tetramer or examining the OVA-specific response with OVA-specific transgenic CD8+ (OT-1) T cells. Specifically, we compared baseline intrinsic properties of TILs or BM T cells from tumor-bearing mice and their changes following adoptive transfer in the tumor and bone marrow (as well as other compartments when indicated). Results: In tumor-bearing mice, endogenous tumor-specific T cells could be detected in the BM early in the course of tumor progression and possessed a more stem-cell-like and memory phenotype in an unsupervised cluster analysis compared with TILs which appeared more exhausted. The BM and tumor microenvironments significantly impact the fate of T cells. Naïve OT-1 transferred T cells acquired an exhausted phenotype in the tumor but maintained a more memory-like phenotype in the BM with tumor progression. Importantly, in a competitive transfer experiment, BM T cells infiltrated the tumor more efficiently than TILs, displayed a higher polyfunctionality with interleukin-2, interferon-γ, tumor necrosis factor-α production and showed greater persistence compared with TILs. Conclusions: T cells from the BM appear superior to TILs as a source of cells for cellular therapy. They possess a memory-enriched phenotype and exhibit improved effector function, greater persistence within a tumor-bearing host, and the capacity for increased tumor infiltration. These data provide a foundation for further exploring the BM as a source of tumor-specific T cells for ACT in solid malignancies.