Project description:Cytotoxic CD8+ T cells are the main focus of efforts to understand anti-tumor immunity and immunotherapy. The adoptive transfer of tumor-reactive cytotoxic CD8+ T lymphocytes expanded and differentiated in vitro has long been considered the primary strategy in adaptive anti-tumor immunity, however, the majority of the transferred tumor antigen-specific CD8+ T cells differentiated into CD39+CD69+ exhausted progenies, limiting its effects in repressing tumor growth. Contrarily, less attention has been addressed to the role of CD4+ T cells during tumorigenesis. Using a mouse model of metastatic melanoma, we found that transferring tumor-specific CD4+ T cells into recipients induces substantial regression of the established metastatic tumors. Notably, in vitro activated CD4+ T cells developed into cytotoxic CD4- T cells in vivo and get exhausted gradually. The blockade of PD-L1 signaling resulted in an expansion of tumor specific CD4+ T cells, which could better control the established metastatic melanoma. Moreover, the tumor-specific memory CD4+ T cell can prevent mice from tumor metastasis, and the tumor-specific effector CD4+ T cells can also mitigate the established metastatic tumor. Overall, our findings suggest a novel mechanism of CD4+ T cells in curtailing tumor metastasis and confirm their therapeutic role in combination with PD-L1 blockade in cancer immunotherapy. Hence, a better understanding of cytotoxic CD4- T cell-mediated tumor regression could provide an alternative choice for patients exhibiting suboptimal or no response to CD8+ T cell-based immunotherapies.

Project description:Primary tumours establish metastases by interfering with distinct organs. In pre-metastatic organs, a tumour-friendly microenvironment supports metastatic cells and is prepared by many factors including tissue resident cells, bone marrow-derived cells and abundant fibrinogen depositions. However, other components are unclear. Here, we show that a third organ, originally regarded as a bystander, plays an important role in metastasis by directly affecting the pre-metastatic soil. In our model system, the liver participated in lung metastasis as a leucocyte supplier. These liver-derived leucocytes displayed liver-like characteristics and, thus, were designated hepato-entrained leucocytes (HepELs). HepELs had high expression levels of coagulation factor X (FX) and vitronectin (Vtn) and relocated to fibrinogen-rich hyperpermeable regions in pre-metastatic lungs; the cells then switched their expression from Vtn to thrombospondin, both of which were fibrinogen-binding proteins. Cell surface marker analysis revealed that HepELs contained B220+CD11c+NK1.1+ cells. In addition, an injection of B220+CD11c+NK1.1+ cells successfully eliminated fibrinogen depositions in pre-metastatic lungs via FX Moreover, B220+CD11c+NK1.1+ cells demonstrated anti-metastatic tumour ability with IFN? induction. These findings indicate that liver-primed B220+CD11c+NK1.1+ cells suppress lung metastasis.

Project description:Although all murine MDSCs are defined as Gr1+CD11b+, their true immunophenotype remains elusive. In this study, we found murine Gr1+CD11b+ cells can be divided into two subsets: Gr1+CD11b+B220- and Gr1+CD11b+B220+, especially in the spleen tissues. Unlike the dominant B220- subset, the B220+ subpopulation was not induced by tumor in vivo. Moreover, Gr1+CD11b+B220+ cells from tumor-bearing mice spleens were unable to induce arginase 1 and inducible nitric oxide synthase expression, inhibit T cell proliferation, or promote tumor growth in primary tumor site. Nevertheless, these cells suppressed tumor metastasis in vivo and reduced cancer cell motility in vitro, while Gr1+CD11b+B220- cells from tumor-bearing mice spleens promoted tumor metastasis and enhanced cancer cell motility. Furthermore, both the polymorphonuclear (PMN-MDSCs) and monocytic MDSCs (Mo-MDSCs) could be further divided into B220- and B220+ subsets; interestingly, tumor only induced the expansion of B220- PMN-MDSCs and B220- Mo-MDSCs, but not the B220+ counterparts. Compared with B220- PMN-MDSCs and B220- Mo-MDSCs, the Ly6G+Ly6C-CD11b+B220+ and Ly6G-Ly6C+CD11b+B220+ cells from tumor-bearing mice spleens exhibited a more mature phenotype without immunosuppressive activity. Additionally, IL-6 deficiency attenuated the tumor-induced accumulation of MDSCs, B220- MDSCs and B220- PMN-MDSCs but increased the percentages of Gr1+CD11b+B220+, Ly6G+Ly6C-CD11b+B220+, and Ly6G-Ly6C+CD11b+B220+ cells, indicating the opposing roles of the IL-6 signaling pathway in the expansion of B220- MDSCs and their B220+ counterparts. Taken together, our findings indicate that the B220+ subset is a distinct subset of Gr1+CD11b+ cells functionally different from the B220- subpopulation during tumorigenesis and induction of MDSCs to B220+ cells may be helpful for cancer therapy.

Project description:CD4+ NKG2D+ T cells are associated with tumour, infection and autoimmune diseases. Some CD4+ NKG2D+ T cells secrete IFN-γ and TNF-α to promote inflammation, but others produce TGF-β and FasL to facilitate tumour evasion. Here, murine CD4+ NKG2D+ T cells were further classified into NK1.1- CD4+ NKG2D+ and NK1.1+ CD4+ NKG2D+ subpopulations. The frequency of NK1.1- CD4+ NKG2D+ cells decreased in inflamed colons, whereas more NK1.1+ CD4+ NKG2D+ cells infiltrated into colons of mice with DSS-induced colitis. NK1.1- CD4+ NKG2D+ cells expressed TGF-β and FasL without secreting IFN-γ, IL-21 and IL-17 and displayed no cytotoxicity. The adoptive transfer of NK1.1- CD4+ NKG2D+ cells suppressed DSS-induced colitis largely dependent on TGF-β. NK1.1- CD4+ NKG2D+ cells did not expressed Foxp3, CD223 (LAG-3) and GITR. The subpopulation was distinct from NK1.1+ CD4+ NKG2D+ cells in terms of surface markers and RNA transcription. NK1.1- CD4+ NKG2D+ cells also differed from Th2 or Th17 cells because the former did not express GATA-3 and ROR-γt. Thus, NK1.1- CD4+ NKG2D+ cells exhibited immune regulatory functions, and this T cell subset could be developed to suppress inflammation in clinics.

Project description:We sought to define cellular immune mechanisms of synergy between tumor-antigen-targeted monoclonal antibodies and chemotherapy. Established B16 melanoma in mice was treated with cytotoxic doses of cyclophosphamide in combination with an antibody targeting tyrosinase-related protein 1 (?TRP1), a native melanoma differentiation antigen. We find that Fc? receptors are required for efficacy, showing that antitumor activity of combination therapy is immune mediated. Rag1(-/-) mice deficient in adaptive immunity are able to clear tumors, and thus innate immunity is sufficient for efficacy. Furthermore, previously treated wild-type mice are not significantly protected against tumor reinduction, as compared with mice inoculated with irradiated B16 alone, consistent with a primarily innate immune mechanism of action of chemo-immunotherapy. In contrast, mice deficient in both classical natural killer (NK) lymphocytes and nonclassical innate lymphocytes (ILC) due to deletion of the IL2 receptor common gamma chain IL2?c(-/-)) are refractory to chemo-immunotherapy. Classical NK lymphocytes are not critical for treatment, as depletion of NK1.1? cells does not impair antitumor effect. Depletion of CD90?NK1.1? lymphocytes, however, both diminishes therapeutic benefit and decreases accumulation of macrophages within the tumor. Tumor clearance during combination chemo-immunotherapy with monoclonal antibodies against native antigen is mediated by the innate immune system. We highlight a novel potential role for CD90?NK1.1? ILCs in chemo-immunotherapy.

Project description:Primary tumours establish metastases by interfering with distinct organs. In pre-metastatic organs, a tumour-friendly microenvironment supports metastatic cells, and is prepared by many factors including tissue resident cells, bone marrow-derived cells and abundant fibrinogen depositions. However, other components are unclear. Here we show that a third organ, originally regarded as a bystander, plays an important role in metastasis by directly affecting the pre-metastatic soil. In our model system, the liver participated in lung metastasis as a leukocyte supplier. These liver-derived leukocytes displayed liver-like characteristics and, thus, were designated hepato-entrained leukocytes (HepELs). HepELs had high expression levels of coagulation factor X (FX) and vitronectin (Vtn), and relocated to fibrinogen-rich hyperpermeable regions in pre-metastatic lungs; the cells then switched their expression from Vtn to thrombospondin, both of which were fibrinogen-binding proteins. Cell surface marker analysis revealed that HepELs contained B220+CD11c+NK1.1+ cells. In addition, an injection of B220+CD11c+NK1.1+ cells successfully eliminated fibrinogen depositions in pre-metastatic lungs via FX. Moreover, B220+CD11c+NK1.1+ cells demonstrated anti-metastatic tumour ability with IFNγ induction. These findings indicate that liver-primed B220+CD11c+NK1.1+ cells suppress lung metastasis.

Project description:In vitro differentiated CD8(+) T cells have been the primary focus of immunotherapy of cancer with little focus on CD4(+) T cells. Immunotherapy involving in vitro differentiated T cells given after lymphodepleting regimens significantly augments antitumor immunity in animals and human patients with cancer. However, the mechanisms by which lymphopenia augments adoptive cell therapy and the means of properly differentiating T cells in vitro are still emerging. We demonstrate that naive tumor/self-specific CD4(+) T cells naturally differentiated into T helper type 1 cytotoxic T cells in vivo and caused the regression of established tumors and depigmentation in lymphopenic hosts. Therapy was independent of vaccination, exogenous cytokine support, CD8(+), B, natural killer (NK), and NKT cells. Proper activation of CD4(+) T cells in vivo was important for tumor clearance, as naive tumor-specific CD4(+) T cells could not completely treat tumor in lymphopenic common gamma chain (gamma(c))-deficient hosts. gamma(c) signaling in the tumor-bearing host was important for survival and proper differentiation of adoptively transferred tumor-specific CD4(+) T cells. Thus, these data provide a platform for designing immunotherapies that incorporate tumor/self-reactive CD4(+) T cells.

Project description:Uterine natural killer (uNK) cells accumulate at the maternal-fetal interface during gestation and are thought to have an important role during pregnancy in both mice and humans. While the cell surface phenotype of human uNK cells is increasingly well defined, less is known regarding the cell surface expression profile of murine uNK cells both before and during gestation. Herein, we demonstrate that murine NK1.1(+) (KLRB1C) endometrial NK (eNK) cells, derived from virgin mice, and NK1.1(+) decidual NK (dNK) cells, obtained from pregnant mice, belong to the B220(+) (PTPRC) CD11c(+) (ITGAX) subset of NK cells. While B220 expression was low on NK1.1(+) eNK cells, it was increased on a subset of NK1.1(+) dNK cells at Embryonic Day 10.5. Endometrial NK and dNK cells also differed somewhat in their expression patterns of two activation markers, namely, CD69 and inducible costimulator (ICOS). The eNK cells acquired a B220(hi)ICOS(+) dNK cell surface phenotype when cultured in vitro in the presence of uterine cells and murine interleukin 15. Thus, the cell surface profiles generated for both NK1.1(+) eNK cells and dNK cells demonstrate that they belong to the recently described B220(+)CD11c(+) subset of NK cells, which are potent cytokine producers.

Project description:Lymphoid organs contain a B220(+)CD11c(+)NK1.1(+) cell population that was recently characterized as a novel dendritic cell (DC) subset that functionally overlaps with natural killer (NK) cells and plasmacytoid DCs (PDCs). Using Siglec-H and NK1.1 markers, we unambiguously dissected B220(+)CD11c(+) cells and found that PDCs are the only professional interferon (IFN)-alpha-producing cells within this heterogeneous population. In contrast, B220(+)CD11c(+)NK1.1(+) cells are a discrete NK cell subset capable of producing higher levels of IFN-gamma than conventional NK cells. Unlike DCs, only a minute fraction of B220(+)CD11c(+)NK1.1(+) cells in the spleen expressed major histocompatibility complex class II ex vivo or after stimulation with CpG. Consistent with being a NK cell subset, B220(+)CD11c(+)NK1.1(+) cells depended primarily on interleukin 15 and common cytokine receptor gamma chain signaling for their development. In terms of function, expression of distinctive cell surface receptors, and location in lymphoid organs, NK1.1(+)B220(+)CD11c(+) appear to be the murine equivalent of human CD56(bright) NK cells.

Project description:Adoptive transfer of CD4+ T cells (TRP-1 CD4+ T cells) specific for tyrp-1 (tyrosinase-related protein 1) eradicate established tumors (melanoma) in lymphopenic RAG-/- hosts. In vitro differentiated CD8+ T cells have been the primary focus of immunotherapy of cancer with little focus on CD4+ T cells. Immunotherapy involving in vitro differentiated T cells given after lymphodepleting regimens significantly augments antitumor immunity in animals and human patients with cancer. However, the mechanisms by which lymphopenia augments adoptive cell therapy and the means of properly differentiating T cells in vitro are still emerging. We demonstrate that naïve tumor/self-specific CD4+ T cells naturally differentiated into T helper type 1 (Th1) cytotoxic T cells in vivo and caused the regression of established tumors and depigmentation in lymphopenic hosts. Therapy was independent of vaccination, exogenous cytokine support, CD8+-, B-, NK and NK-T cells. Proper activation of CD4+ T cells in vivo was important for tumor clearance as naïve tumor-specific CD4+ T cells could not completely treat tumor in lymphopenic common gamma chain-deficient (gc-/-) hosts. gc signaling in the tumor-bearing host was important for survival and proper differentiation of adoptively transferred tumor-specific CD4+ T cells. Thus, these data provide a platform for designing immunotherapies that incorporate tumor/self-reactive CD4+ T cells. 2 x 10^5 sorted TRP-1 CD4+ T cells were transferred i.v. into tumor-bearing RAG-/- hosts on day 7-10 after tumor challenge, and ~1 x 10^6 CD4+ T cells were isolated 1 week later by flow sorting from pooled lymph nodes (LN) or spleens. Dye-swaps were performed.