Imprinting of lymphocytes with melanoma antigens acquired by trogocytosis facilitates identification of tumor-reactive T cells.

Trogocytosis is a contact-dependent intercellular transfer of membrane fragments and associated molecules from APCs to effector lymphocytes. We previously demonstrated that trogocytosis also occurs between tumor target and cognate melanoma Ag-specific cytotoxic T cells (CTL). In this study, we show that, following trogocytosis, immune effector cells acquire molecular components of the tumor, including surface Ags, which are detectable by specific mAbs. We demonstrate that CD8(+) and CD4(+) T cells from melanoma patients' PBMC and tumor-infiltrating lymphocytes (TIL) capture melanoma Ags, enabling identification of trogocytosing lymphocytes by staining with Ag-specific Abs. This finding circumvents the necessity of tumor prelabeling, which in the past was mandatory to detect membrane-capturing T cells. Through the detection of melanoma Ags on TIL, we sorted trogocytosing T cells and verified their preferential reactivity and cytotoxicity. Furthermore, tumor Ag-imprinted T cells were detected at low frequency in fresh TIL cultures shortly after extraction from the tumor. Thus, T cell imprinting by tumor Ags may allow the enrichment of melanoma Ag-specific T cells for research and potentially even for the adoptive immunotherapy of patients with cancer.

Trogocytosis is a gateway to characterize functional diversity in melanoma-specific CD8+ T cell clones.

Trogocytosis, the transfer of membrane patches from target to immune effector cells, is a signature of tumor-T cell interaction. In this study, we used the trogocytosis phenomenon to study functional diversity within tumor-specific T cell clones with identical TCR specificity. MART-1(26-35)-specific CD8 T cell clones, which differed in their trogocytosis capacity (low [2D11], intermediate [2G1], high [2E2]), were generated from melanoma patients. Functional evaluation of the clones showed that the percentage of trogocytosis-capable T cells closely paralleled each clone's IFN-γ and TNF-α production, lysosome degranulation, and lysis of peptide-pulsed targets and unmodified melanoma. The highly cytotoxic 2E2 clone displayed the highest TCR peptide binding affinity, whereas the low-activity 2D11 clone showed TCR binding to peptide-MHC in a CD8-dependent manner. TCR analysis revealed Vß16 for clones 2E2 and 2G1 and Vß14 for 2D11. When peptide-affinity differences were bypassed by nonspecific TCR stimulation, clones 2E2 and 2D11 still manifested distinctive signaling patterns. The high-activity 2E2 clone displayed prolonged phosphorylation of ribosomal protein S6, an integrator of MAPK and AKT activation, whereas the low-activity 2D11 clone generated shorter and weaker phosphorylation. Screening the two clones with identical TCR Vß by immunoreceptor array showed higher phosphorylation of NK, T, and B cell Ag (NTB-A), a SLAM family homophilic receptor, in clone 2E2 compared with 2G1. Specific blocking of NTB-A on APCs markedly reduced cytokine production by CD8 lymphocytes, pointing to a possible contribution of NTB-A costimulation to T cell functional diversity. This finding identifies NTB-A as a potential target for improving anti-cancer immunotherapy.

Soluble SLAMF6 Receptor Induces Strong CD8+ T-cell Effector Function and Improves Anti-Melanoma Activity In Vivo.

SLAMF6, a member of the SLAM (signaling lymphocyte activation molecules) family, is a homotypic-binding immune receptor expressed on NK, T, and B lymphocytes. Phosphorylation variance between T-cell subclones prompted us to explore its role in anti melanoma immunity. Using a 203-amino acid sequence of the human SLAMF6 (seSLAMF6) ectodomain, we found that seSLAMF6 reduced activation-induced cell death and had an antiapoptotic effect on tumor-infiltrating lymphocytes. CD8+ T cells costimulated with seSLAMF6 secreted more IFNγ and displayed augmented cytolytic activity. The systemic administration of seSLAMF6 to mice sustained adoptively transferred transgenic CD8+ T cells in comparable numbers to high doses of IL2. In a therapeutic model, lymphocytes activated by seSLAMF6 delayed tumor growth, and when further supported in vivo with seSLAMF6, induced complete tumor clearance. The ectodomain expedites the loss of phosphorylation on SLAMF6 that occurs in response to T-cell receptor triggering. Our findings suggest that seSLAMF6 is a costimulator that could be used in melanoma immunotherapy. Cancer Immunol Res; 6(2); 127-38. ©2018 AACR.

Human T cell crosstalk is induced by tumor membrane transfer.

Trogocytosis is a contact-dependent unidirectional transfer of membrane fragments between immune effector cells and their targets, initially detected in T cells following interaction with professional antigen presenting cells (APC). Previously, we have demonstrated that trogocytosis also takes place between melanoma-specific cytotoxic T lymphocytes (CTLs) and their cognate tumors. In the present study, we took this finding a step further, focusing on the ability of melanoma membrane-imprinted CD8+ T cells to act as APCs (CD8+ T-APCs). We demonstrate that, following trogocytosis, CD8+ T-APCs directly present a variety of melanoma derived peptides to fraternal T cells with the same TCR specificity or to T cells with different TCRs. The resulting T cell-T cell immune synapse leads to (1) Activation of effector CTLs, as determined by proliferation, cytokine secretion and degranulation; (2) Fratricide (killing) of CD8+ T-APCs by the activated CTLs. Thus, trogocytosis enables cross-reactivity among CD8+ T cells with interchanging roles of effectors and APCs. This dual function of tumor-reactive CTLs may hint at their ability to amplify or restrict reactivity against the tumor and participate in modulation of the anti-cancer immune response.

Capture of tumor cell membranes by trogocytosis facilitates detection and isolation of tumor-specific functional CTLs.

The success of adoptive cell transfer in the treatment of metastatic cancer in humans is dependent on the selection of highly active tumor-specific cytotoxic T cells. We report here that CTLs capture membrane fragments from their targets while exerting cytotoxic activity and thus gain a detectable functional signature by which they can be identified. Fluorochrome labeling or biotinylation was used to tag tumor cells. CD8(+) T cells were coincubated with the tagged targets, sorted, and functionally evaluated. Our results show that membrane capture by CD8(+) lymphocytes is T-cell receptor dependent, epitope specific, and preferentially associated with highly cytotoxic clonal subsets. CTLs that captured membranes from unmodified melanoma exhibited enhanced cytotoxic activity against tumor cell lines and autologous melanoma. In a human melanoma in vivo model, adoptive transfer of membrane-capturing, peptide-specific T cells, but not noncapturing or bulk CD8(+) T cells, inhibits tumor progression. Membrane capture is therefore a signature of antigen-specific CTLs endowed with high functional avidity and may have direct relevance in the clinical application of adoptive immunotherapy.