Project description:Insights into the epigenetic mechanisms of CD8 T cell differentiation are delivering novel opportunities for modulating fate decisions and immune responses. The histone methyltransferase DOT1L is emerging as central epigenetic regulator in immune cells. However, its cell-intrinsic role in CD8 T cell programming remains unclear as positive as well as negative roles have been ascribed to DOT1L. Here, we determined the cell-intrinsic role of DOT1L in CD8 T cells using conditional ablation. In contrast to deletion of Dot1L early in the T cell lineage, conditional ablation of Dot1L in isolated mature CD8 T cells in vitro did not compromise the in vivo proliferative capacity and anti-tumor reactivity. In vitro, Dot1L knock-out CD8 T cells showed accelerated and enhanced antigen-specific cytotoxic activity towards tumor cells. Mechanistically, transcriptome and proteome profiling revealed that loss of DOT1L results in an altered cell-identity program with loss of T-cell and gain of NK-cell features. This role of DOT1L was linked to its catalytic activity since treatment with specific DOT1L inhibitors phenocopied genetic deletion of Dot1L. Our findings show that ablation of DOT1L activity is well-tolerated in mature CD8 T cells, rewires their cell identity in a tunable way towards the NK-cell lineage and enhances their cytolytic activity cell intrinsically. Highlights • Differentiation and identity of cytotoxic T cells critically depend on the methyltransferase DOT1L • DOT1L limits the cytotoxic activity of mature CD8 T cells • DOT1 prohibits the acquisition of NK cell features in CD8 T cells • DOT1L maintains CD8 T cell identity through its catalytic activity in a dose-dependent manner

Project description:Insights into the epigenetic mechanisms of CD8 T cell differentiation are delivering novel opportunities for modulating fate decisions and immune responses. The histone methyltransferase DOT1L is emerging as a central epigenetic regulator in immune cells. However, its cell-intrinsic role in CD8 T cell programming remains unclear as positive as well as negative roles have been ascribed to DOT1L. Here, we determined the cell-intrinsic role of DOT1L in mouse CD8 T cells using conditional ablation. In contrast to deletion of Dot1L early in the T cell lineage, conditional ablation of Dot1L in isolated mature CD8 T cells in vitro did not compromise the in vivo proliferative capacity and anti-tumor reactivity. In vitro, Dot1L knock-out CD8 T cells showed accelerated and enhanced antigen-specific cytotoxic activity towards tumor cells. Mechanistically, transcriptome and proteome profiling revealed that loss of DOT1L results in an altered cell-identity program with loss of T-cell and gain of NK-cell features. This role of DOT1L was linked to its catalytic activity since treatment with specific DOT1L inhibitors phenocopied genetic deletion of Dot1L. Our findings show that ablation of DOT1L activity is well-tolerated in mature CD8 T cells, rewires their cell identity in a tunable way towards the NK-cell lineage and enhances their cytolytic activity cell intrinsically.

Project description:Insights into the epigenetic mechanisms of CD8 T cell differentiation are delivering novel opportunities for modulating fate decisions and immune responses. The histone methyltransferase DOT1L is emerging as a central epigenetic regulator in immune cells. However, its cell-intrinsic role in CD8 T cell programming remains unclear as positive as well as negative roles have been ascribed to DOT1L. Here, we determined the cell-intrinsic role of DOT1L in mouse CD8 T cells using conditional ablation. In contrast to deletion of Dot1L early in the T cell lineage, conditional ablation of Dot1L in isolated mature CD8 T cells in vitro did not compromise the in vivo proliferative capacity and anti-tumor reactivity. In vitro, Dot1L knock-out CD8 T cells showed accelerated and enhanced antigen-specific cytotoxic activity towards tumor cells. Mechanistically, transcriptome and proteome profiling revealed that loss of DOT1L results in an altered cell-identity program with loss of T-cell and gain of NK-cell features. This role of DOT1L was linked to its catalytic activity since treatment with specific DOT1L inhibitors phenocopied genetic deletion of Dot1L. Our findings show that ablation of DOT1L activity is well-tolerated in mature CD8 T cells, rewires their cell identity in a tunable way towards the NK-cell lineage and enhances their cytolytic activity cell intrinsically.

Project description:Epigenetic modifiers are promising targets to improve therapies in patients with cancer. Targeting the methyltransferase DOT1L with small molecule inhibitors has shown promising effects on the control of cancerous cells. However, these small molecules are given systemically and may have a profound impact on non-cancerous cells, such as the cells of the immune system. In the innate immune system, natural killer (NK) cells are a critical subset of cells with important roles in controlling transformed cells and tumour inflammation. Previous studies have shown that NK cells can convert into ILC1-like cells in a TGFβ-rich tumour microenvironment (TME). Additionally, cancer patients with acute myeloid leukemia (AML) or chronic lymphocytic leukemia (CLL) have increased frequencies of ILC1 cells in peripheral blood mononuclear cells (PBMCs), which show reduced production of proinflammatory cytokines and decreased granzyme B production. In this study, we identify DOT1L as a critical regulator of NK cell activation and lineage integrity. We generated NKp46-conditional DOT1L knockout mice (DOT1L.Ncr1) and observed increased frequencies of ILC1-like cells (CD49b+ CD49a+, CD62L-) and reduced frequencies of NK cells (CD49b+ CD49a-, CD62L+) in these mice. While the absence of DOT1L increases the sensitivity to TGFβ, the increased expression of CD49a is highly intrinsic and only partially dependent on TGFβ signalling. Functionally, the increased presence of ILC1-like cells in the tumour microenvironment of DOT1L.Ncr1 mice leads to decreased tumour control. Our assessment of the transcriptional program reveals alternative uses of transcription factors, such as the AP-1 family or SMAD2/3, to maintain NK cell activation and lineage integrity. Our findings provide evidence for a previously unknown role of DOT1L in NK cell biology, and demonstrate the importance of maintaining NK cell lineage integrity for effective tumour control. These findings have significant implications for the development of improved therapies for cancer or other NK cell-lineage dependent malignancies.

Project description:Epigenetic modifiers are promising targets to improve therapies in patients with cancer. Targeting the methyltransferase DOT1L with small molecule inhibitors has shown promising effects on the control of cancerous cells. However, these small molecules are given systemically and may have a profound impact on non-cancerous cells, such as the cells of the immune system. In the innate immune system, natural killer (NK) cells are a critical subset of cells with important roles in controlling transformed cells and tumour inflammation. Previous studies have shown that NK cells can convert into ILC1-like cells in a TGFβ-rich tumour microenvironment (TME). Additionally, cancer patients with acute myeloid leukemia (AML) or chronic lymphocytic leukemia (CLL) have increased frequencies of ILC1 cells in peripheral blood mononuclear cells (PBMCs), which show reduced production of proinflammatory cytokines and decreased granzyme B production. In this study, we identify DOT1L as a critical regulator of NK cell activation and lineage integrity. We generated NKp46-conditional DOT1L knockout mice (DOT1L.Ncr1) and observed increased frequencies of ILC1-like cells (CD49b+ CD49a+, CD62L-) and reduced frequencies of NK cells (CD49b+ CD49a-, CD62L+) in these mice. While the absence of DOT1L increases the sensitivity to TGFβ, the increased expression of CD49a is highly intrinsic and only partially dependent on TGFβ signalling. Functionally, the increased presence of ILC1-like cells in the tumour microenvironment of DOT1L.Ncr1 mice leads to decreased tumour control. Our assessment of the transcriptional program reveals alternative uses of transcription factors, such as the AP-1 family or SMAD2/3, to maintain NK cell activation and lineage integrity. Our findings provide evidence for a previously unknown role of DOT1L in NK cell biology, and demonstrate the importance of maintaining NK cell lineage integrity for effective tumour control. These findings have significant implications for the development of improved therapies for cancer or other NK cell-lineage dependent malignancies.

Project description:Epigenetic modifiers are promising targets to improve therapies in patients with cancer. Targeting the methyltransferase DOT1L with small molecule inhibitors has shown promising effects on the control of cancerous cells. However, these small molecules are given systemically and may have a profound impact on non-cancerous cells, such as the cells of the immune system. In the innate immune system, natural killer (NK) cells are a critical subset of cells with important roles in controlling transformed cells and tumour inflammation. Previous studies have shown that NK cells can convert into ILC1-like cells in a TGFβ-rich tumour microenvironment (TME). Additionally, cancer patients with acute myeloid leukemia (AML) or chronic lymphocytic leukemia (CLL) have increased frequencies of ILC1 cells in peripheral blood mononuclear cells (PBMCs), which show reduced production of proinflammatory cytokines and decreased granzyme B production. In this study, we identify DOT1L as a critical regulator of NK cell activation and lineage integrity. We generated NKp46-conditional DOT1L knockout mice (DOT1L.Ncr1) and observed increased frequencies of ILC1-like cells (CD49b+ CD49a+, CD62L-) and reduced frequencies of NK cells (CD49b+ CD49a-, CD62L+) in these mice. While the absence of DOT1L increases the sensitivity to TGFβ, the increased expression of CD49a is highly intrinsic and only partially dependent on TGFβ signalling. Functionally, the increased presence of ILC1-like cells in the tumour microenvironment of DOT1L.Ncr1 mice leads to decreased tumour control. Our assessment of the transcriptional program reveals alternative uses of transcription factors, such as the AP-1 family or SMAD2/3, to maintain NK cell activation and lineage integrity. Our findings provide evidence for a previously unknown role of DOT1L in NK cell biology, and demonstrate the importance of maintaining NK cell lineage integrity for effective tumour control. These findings have significant implications for the development of improved therapies for cancer or other NK cell-lineage dependent malignancies.

Project description:Elucidating the mechanisms by which immune cells become dysfunctional in tumors is critical to developing next-generation immunotherapies. We profiled proteomes of cancer cells, monocyte/macrophages, CD4+ and CD8+ T cells, and NK cells isolated from tumors, liver, and blood of 48 patients with hepatocellular carcinoma. We found that tumor macrophages induce the sphingosine-1-phospate-degrading enzyme SGPL1, which dampened their inflammatory phenotype and anti-tumor function in vivo. We further discovered that the signaling scaffold protein AFAP1L2, typically only found in activated NK cells, is also upregulated in chronically stimulated CD8+ T cells in tumors. Ablation of AFAP1L2 in CD8+ T cells increased their viability upon repeated stimulation and enhanced their antitumor activity synergistically with PD-L1 blockade in mouse models. Our data revealed new targets for immunotherapy and provide a resource on immune cell proteomes in liver cancer (www.immunomics.ch/liver).

Project description:In the innate immune system, natural killer (NK) cells represent a highly important subset of cells with utmost importance in the control of transformed cell and tumour inflammation. Previous studies showed that NK cells can convert into ILC1-like cells in a TGF-β-rich tumour microenvironment (TME). In addition, cancer patients with acute myeloid leukemia (AML) or chronic lymphocytic leukemia (CLL) have increased frequencies of ILC1 cells in peripheral blood mononuclear cells (PBMCs), which show reduced production of the proinflammatory cytokines IFN-γ and TNF in addition to decreased granzyme B production. Here, we identify the histone methyltransferase DOT1L as a critical regulator of NK cell lineage integrity in vitro and in vivo. NK cells from NKp46-conditional DOT1L knockout mice (DOT1L.Ncr1) show increased frequencies of ILC1-like cells (CD49b+ CD49a+), and also express more of the ILC1 markers CD200R, TRAIL, while showing reduced expression of Ly49H. We further identify that the increased ILC1-like phenotype is largely independent of TGFβ. Assessment of transcription factor (TF) availability in the absence of DOT1L shows that the Myocyte-specific enhancer factor (MEF)2C is the highest downregulated TF in the absence of DOT1L. CRISPRCas9-mediated deletion of MEF2C ultimately provides evidence that this TF is limiting NK cell plasticity in vivo. Our findings provide evidence for a previously unknown role of DOT1L and MEF2C in NK cell biology for maintaining NK cell lineage integrity and may ultimately result in improved therapies for patients with leukemia or other NK cell-lineage dependent malignancies.

Project description:Tumor escape mechanisms for immunotherapy include deficiencies in antigen presentation, diminishing adaptive CD8+ T cell antitumor activity. Although innate NK cells are triggered by loss of MHC class I, their response is often inadequate. To increase tumor susceptibility to both innate and adaptive immune elimination, we performed parallel genome-wide CRISPR-Cas9 screens. This identified all components, RNF31, RBCK1, and SHARPIN, of the linear ubiquitination chain assembly complex (LUBAC). Genetic and pharmacologic ablation of RNF31, an E3 ubiquitin ligase, strongly sensitized melanoma, breast and colorectal cancer cells to both NK and CD8+ T cell killing. This occurred in a TNF-dependent manner, causing loss of A20 and non-canonical IKK complexes from TNF Receptor Complex I. Corroborating this preclinically, a small molecule RNF31 inhibitor sensitized human colon carcinoma organoids to TNF and greatly enhanced immune bystander killing of antigen-loss and antigen presentation machinery-deficient tumor cells. These results merit exploration of RNF31 inhibition as a clinical pharmacological opportunity for immunotherapy-refractory cancers.

Project description:Tumors evade control by CD8+ T cells by losing MHC I expression, necessitating new approaches to improve immunotherapy. NK cells target MHC I-deficient cells but are insufficiently activated to control tumors without help. Here we uncovered a novel approach to control MHC I-deficient tumors by ablating Treg cells intratumorally, which incites potent antitumor NK cell responses without imparting lethal autoimmunity. IT-Treg ablation increased NK cell activation, maturation, expression of effector molecules, and anti-tumor cytotoxic activity. In this setting, conventional CD4+ T cells were required for NK cell activation, due to their production of IL-2 after interacting with conventional type 2 dendritic cells. These results demonstrate an opportunity to reinvigorate antitumor NK cell responses against tumors that evade CD8 T cell responses, by locally depleting Tregs. The findings also highlight the multicellular immunosuppression enforced by Tregs that extends beyond the control of CD8 T cell responses to tumors.