Proliferation-competent Tcf1+ CD8 T cells in dysfunctional populations are CD4 T cell help independent

T cell maintenance in chronic infection and cancer follows a hierarchical order. Short-lived effector CD8 T cells are constitutively replaced from a proliferation-competent Tcf1-expressing progenitor population. This occurs spontaneously at low levels and increases in magnitude upon blocking PD-1 signaling. We explore how CD4 T cell help controls transition and survival of the progenitors and their progeny by utilizing single-cell RNA sequencing. Unexpectedly, absence of CD4 help caused reductions in cell numbers only among terminally differentiated cells while proliferation-competent progenitor cells remained unaffected with regard to their numbers and their overall phenotype. In fact, upon restoration of a functional CD4 compartment, the progenitors began to regenerate the effector CD8 T cells. Thus, unlike memory T cells for which secondary expansion requires CD4 T cell help, this is not a necessity for proliferation-competent progenitor cells in dysfunctional populations. Our data therefore reveals that proliferation-competent cells in dysfunctional populations show a previously unrecognized uncoupling of CD4 T cell help that is otherwise required by conventional memory T cells.

A tissue-like platform for studying engineered quiescent human T-cells’ interactions with dendritic cells

Research in the field of human immunology is restricted by the lack of a system that reconstitutes the in-situ activation dynamics of quiescent human antigen-specific T-cells interacting with dendritic cells. Here we report a tissue-like system that recapitulates the dynamics of engineered primary human immune cell. Our approach facilitates real-time single cell manipulations, tracking of interactions and functional responses complemented by population-based measurements of cytokines, activation status and proliferation. As a proof of concept, we recapitulate immunological phenomenon such as CD4 help to CD8 T-cells through enhanced maturation of DCs and effect of PD-1 checkpoint blockades. In addition, we characterise unique dynamics of T-cell/DC interactions as a function of antigen affinity.

Eomesodermin Regulates The Early Activation Of Alloreactive CD4 T Cells and Is Critical For Both Gvh and GVL Responses

Despite increasing insights into its immunobiology, graft vs host disease (GVHD) remains a major obstacle for successful allogeneic hematopoietic stem/progenitor cell transplantation (allo-HCT). Separation of GVHD from graft vs. leukemia/lymphoma (GVL) responses also remains an elusive goal for allo-HSCT. Efforts to delineate the transcriptional networks regulating T cell differentiation post-HCT have suggested that multiple transcription factors may be involved in the regulation of alloreactive helper T (Th) cells and GVHD. However, conflicting data have emerged regarding the role of Th1 and Th17 pathways, and it remains unclear which transcription factors mediate the early activation of alloreactive T cells necessary for subsequent GVHD development. The T-box transcription factor eomesodermin (Eomes) cooperates with T-bet to regulate CD8 T cell cytotoxic function, IFNy production, and memory cell formation. Recently, a role for Eomes in CD4 Th cell polarization has been described as well. In order to evaluate the role of Eomes in T cell function in the context of allo-HCT, we used a MHC-disparate mouse model (C57BL/6 into BALB/c) with T cell depleted donor bone marrow (TCD-BM) and wild-type (WT) or Eomes knock out (KO) donor T cells. Recipients were conditioned with lethal total body irradiation. Eomes deficiency in donor T cells led to a significant reduction in GVHD mortality (Fig 1, p<.001), morbidity (p<.001), and intestinal pathology (p<.05, colon). Notably, Eomes KO T cells exerted significantly less GVHD mortality than T-bet KO T cells (Fig 1, p<.001). Given the reduced gastrointestinal (GI) GVHD observed with Eomes KO T cells, we next analyzed the expression of homing molecules important for T cell migration to the GI tract. Consistent with reduced GI GVHD, we detected reduced expression of α4β7 integrin on Eomes KO donor CD8 T cells one week post-HCT. We also observed an increase in the proportion and absolute numbers of Foxp3+ regulatory T cells, as well as a decrease in expression of T-bet in mesenteric lymph nodes (MLNs). Moreover, we found decreased production of IFNy by Eomes KO donor CD4 T cells two weeks (spleen and MLN, p<.001) and three weeks (spleen, p<.01) post-HCT without a comcomitant increase in IL-17. We also found increased IL-4 production by Eomes KO CD4 T cells two weeks post-HCT (MLN, p<.05), indicating a shift from Th1 to Th2 polarization in the absence of Eomes. Strikingly, one of the greatest differences we observed between WT and Eomes KO donor T cells was impaired early activation of CD4 T cells; Eomes deficiency was associated with reduced proliferation (p<.001), reduced expression of CD25 (p<.001, spleen; p<.001, MLN), and increased expression of CD62L (p<.01, spleen; p<.001, MLN) in CD4 T cells within the first 72 hours post-HCT (Fig 2). In order to determine if Eomes was important for T cell-mediated GVL responses, we performed allo-HCT in the presence of A20 lymphoma cells. Despite the reduction in GVHD mortality as described above, A20 tumor challenge led to increased mortality in recipients of Eomes KO T cells, indicating that Eomes was also critical for effective GVL function. Given the importance of Eomes in early alloactivation of CD4 T cells, we evaluated if the impaired GVL function was due to an intrinsic CD8 defect or lack of CD4 help. B6 TCD-BM was transplanted into BALB/c recipients along with either WT or Eomes KO CD4 or CD8 T cells. Eomes deficiency in both CD4 and CD8 T cells again led to significant mortality, but HCT with Eomes KO CD4 T cells and WT CD8 T cells led to the greatest survival due to less GVHD and intact GVL (Fig 3), suggesting that Eomes is essential for intrinsic CD8 function during GVL, but not for CD4 help. In summary, we identified distinct requirements for Eomes in CD4 versus CD8 T cells in the context of allo-HCT. Eomes regulated multiple aspects of CD4 T cell function following allo-HCT, including early activation, cytokine production, and gut trafficking. The multifacted functions of Eomes in CD4 T cells likely explain its requirement for GVHD. In contrast, Eomes deficiency in CD8 T cells led to impaired GVL, consistent with its established importance for cytotoxic CD8 T cell differentiation. To our knowledge, this is one of the first descriptions of a transcription factor necessary for effective GVL capacity. Our results suggest that selective manipulation of Eomes function in T cell subsets may be useful for both limiting GVHD and enhancing GVL. Disclosures: No relevant conflicts of interest to declare.

CD4 Cells Engineered to Express an MHC Class I Restricted TCR Can Rescue CD8 Cells Tolerized to Tumour-Associated Antigens

Abstract 952 Background: The efficacy of T cell therapies for cancer may be limited when targeting tumour-associated antigens (TAA) which are also self-antigens. Ongoing exposure to TAA on normal cells may lead to tolerance via anergy or exhaustion of antigen-specific T cells. Methods: We have designed a model of tolerance to TAA in which T cell receptor (TCR)-transduced CD8 T cells recognise pMDM2, a TAA that is also a ubiquitous self-antigen. CD8+ T cells were transduced with pMDM2-specific TCR (MDM-CD8) and transferred to sub-lethally irradiated B6 mice that express pMDM2 in the context of MHC Class I (H2-Kb). MDM-CD8 cells are detectable 4 weeks after transfer but show defective in vivo killing of target cells pulsed with MDM2 peptide. We have used this model to determine the mechanism of tolerance and to evaluate whether tolerant CD8+ T cells can be rescued by CD4 help. Results: To determine whether tolerance of MDM-CD8 cells was dependent upon recognition of cognate antigen, we transferred MDM-CD8 cells into mice of a different MHC background (BALB/c) which lack H2-Kb required for presentation of the TCR-recognised MDM2 peptide. When BALB/c MDM-CD8 cells were transferred to BALBc hosts their functions were preserved and they retained efficient antigen-specific cytolysis. To determine whether tolerance could be modified by provision of CD4+ T cell help, we co-transferred MDM-CD8 with transgenic OT-II CD4+ cells. OT-II cells were primed with dendritic cells (DCs) loaded with cognate pOVA323-339 or irrelevant peptide. When activated through their TCR, OT-II cells increased both the frequency of MDM2-specific CD8 cells and their cytotoxic functions, indicating that CD4 help can overcome CD8 tolerance to TAA. Ineffective antigen presentation to CD4 cells and lack of known MHC class II-restricted TAA are major limitations to providing CD4 help in T cell therapy for cancer. We therefore tested whether transfer of the MHC Class I-restricted MDM2 TCR into CD4 cells could provide help upon transfer to antigen-expressing hosts. Co-transfer of MDM2-TCR-transduced CD4 cells with CD8 cells improved antigen-specific killing of target cells when compared to single transfer of either TCR-transduced CD8 or CD4 cells. Conclusion: CD4 cells rendered capable of responding to an MHC class I restricted TAA by TCR transfer can rescue tolerance developing in a CD8 population with the same specificity. This is potentially a novel way to circumvent defective immune responses arising in adoptively transferred effector cells due to prolonged exposure to cognate antigen on normal host cells. Disclosures: Stauss: Cell Medica: Scientific Advisor Other.