CD8+ T cell activation in cancer comprises an initial activation phase in lymph nodes followed by effector differentiation within the tumor.

Improvements in tumor immunotherapies depend on better understanding of the anti-tumor T cell response. By studying human tumor-draining lymph nodes (TDLNs), we found that activated CD8+ T cells in TDLNs shared functional, transcriptional, and epigenetic traits with TCF1+ stem-like cells in the tumor. The phenotype and TCR overlap suggested that these TDLN cells were precursors to tumor-resident stem-like CD8+ T cells. Murine tumor models revealed that tumor-specific CD8+ T cells were activated in TDLNs but lacked an effector phenotype. These stem-like cells migrated into the tumor, where additional co-stimulation from antigen-presenting cells drove effector differentiation. This model of CD8+ T cell activation in response to cancer is different from that of canonical CD8+ T cell activation to acute viruses, and it proposes two stages of tumor-specific CD8+ T cell activation: initial activation in TDLNs and subsequent effector program acquisition within the tumor after additional co-stimulation.

Differentiation fate of a stem-like CD4 T cell controls immunity to cancer.

The T cell response to cancer controls disease progression and response to immunotherapy1-3. Despite extensive knowledge regarding CD8 T cells, how CD4 T cells contribute to this process is less well understood. Here we identified a population of PD1+TCF1+ CD4 T cells with stem-like properties that are capable of self-renewal and differentiation into canonical CD4 effector cells. Primarily residing in tumour-draining lymph nodes (TDLNs), these tumour-specific CD4 T cells are restricted by T regulatory (Treg) cells to a stem-like fate that predominantly generated induced Treg (iTreg) cells, limiting effector CD8 T cell responses to the tumour. By contrast, upon Treg depletion, stem-like CD4 T cells differentiated into T helper 1 (TH1) cells, and via IFNγ production induced robust effector differentiation from TCF1+ CD8 T cells in TDLNs, a state we defined as 'active'. Notably, enforcing TBET expression in transferred stem-like CD4 T cells was sufficient to overcome the established restricted T cell state. Despite the presence of Treg cells, endogenous stem-like CD4 T cells actively generated TH1 cells, which were required to restore TDLN effector CD8 T cell differentiation, enhance tumour control and rescue response to immunotherapy. In agreement, TH1 differentiation in patients with kidney cancer predicted successful immunotherapy responses and improved progression-free survival. Together, these findings identify a stem-like CD4 T cell population that through alternative differentiation fates controls the switch between restricted and active T cell states with implications for cancer immunotherapies.