Project description:CD4 T cells are thought to help promote anti-tumour responses by ‘licensing’ antigen presenting cells (APCs) that activate CD8 T cells. Conventional type 1 dendritic cells (cDC1s) are responsible for cross-presentation of tumour-derived antigens to CD8 T cells. Prevailing models presume that the cDC1 is licensed by CD4 T cells that are themselves activated by a distinct cDC subset, the cDC2. The recent finding that neoantigens presented by major histocompatibility complex (MHC) class II molecules can promote rejection of tumours that lack MHC class II (MHC-II) surface expression is consistent with an indirect action of CD4 T cells, such as cDC1 licensing. However, no study has directly identified the APC that primes the CD4 T cells responsible for licensing or clearly identified the target of CD4 licensing in vivo. Here, we generated cDC1-specific Cre expressing mouse strain to inactivate or induce expression of MHC-I, MHC-II, or CD40 specifically within the cDC1 lineage. Using a tumour model that relies on CD8 T cells and CD4 T cells for rejection, we discovered that early priming of CD4 T cells against tumour-derived antigens, in contrast to soluble antigens, relied overwhelmingly on the cDC1 and not the cDC2. cDC1 do not simply transport antigen to lymph nodes for processing by cDC2, since lack of MHC-II expression on cDC1 prevented CD4 T cell priming. We also found that CD40 signaling not only affects licensing of cDC1 for CD8 T cell priming, but is also critical for the activation of CD4 T cells. Thus, in the setting of tumour-derived antigens, cDC1 can function as an autonomous platform, capable of priming both CD4 and CD8 T cells and orchestrating their cross-talk required for optimal anti-tumour immunity.

Project description:Stimulatory type 1 conventional dendritic cells (cDC1s) engage in productive interactions with CD8+ effectors along tumor-stroma boundaries. The paradoxical accumulation of “poised” cDC1s within stromal sheets is unlikely to simply reflect passive exclusion from tumor cores. Drawing parallels with embryonic morphogenesis, we hypothesized that invasive margin stromal remodeling generates developmentally conserved cell fate cues that regulate cDC1 behavior. We find that, in human T cell-inflamed tumors, CD8+ T cells penetrate tumor nests, whereas cDC1s are confined within adjacent stroma that recurrently displays site-specific proteolysis of the matrix proteoglycan versican (VCAN), an essential organ-sculpting modification in development. VCAN is necessary, and its proteolytic fragment (matrikine) versikine is sufficient for cDC1 accumulation. Versikine does not influence tumor-seeding pre-DC differentiation; rather, it orchestrates a distinctive cDC1 activation program conferring exquisite sensitivity to DNA sensing, supported by atypical innate lymphoid cells. Thus, peritumoral stroma mimicking embryonic provisional matrix remodeling regulates cDC1 abundance and activity to elicit T cell-inflamed tumor microenvironments.

Project description:Type 1 conventional dendritic cells (cDC1s) are unique in their efferocytosis and cross-presenting abilities, resulting in T cell-mediated immunity or tolerance. However, the factors that dictate whether cDC1s induce a tolerogenic or immunogenic response remain largely unknown. Here, we show that the erythropoietin receptor (EpoR) acts as a critical switch that determines the tolerogenic function of cDC1s and the threshold of Ag-specific T cell responses. In total lymphoid irradiation and anti-thymocyte serum (TLI/ATS)-induced allograft tolerance, cDC1s upregulate EpoR expression, and conditional knockout of EpoR in cDC1s diminishes antigen (Ag)-specific FOXP3+ Treg induction and expansion, resulting in allograft rejection. Mechanistically, EpoR promotes efferocytosis-induced tolerogenic maturation of splenic cDC1s towards late-stage CCR7⁺ cDC1s characterized by elevated integrin β8 gene (Itgb8) expression, and conditional knockout of Itgb8 in cDC1s impairs TLI/ATS-induced tolerance. Migratory cDC1s in peripheral lymph nodes preferentially express EpoR, and their capacity to induce FOXP3⁺ Tregs is enhanced by EPO. Reciprocally, EpoR deficiency enables immunogenic maturation of both pLN migratory and splenic CCR7⁺ cDC1s by upregulating genes essential for MHC class II-mediated Ag presentation, cross-presentation and costimulation. Loss of cDC1 EpoR reduces tumor growth by enhancing anti tumor CD8⁺ T cell immunity, particularly by promoting tumor Ag specific CD8⁺ T cell priming in tumor draining lymph nodes to generate more precursor exhausted T cells (Tpex) and by sustaining intratumoral Tpexs while decreasing Tregs. Targeting EpoR on cDC1s to either induce or inhibit immune tolerance could pave the way for novel treatments of a variety of diseases.

Project description:Cancer cells evade T-cell-mediated killing through poorly understood mechanisms of tumour–immune interactions. Dendritic cells (DCs), especially type-1 conventional DCs (cDC1), mediate T-cell priming and therapeutic efficacy against tumours. Besides pattern recognition receptors (PRRs), how DC functions are shaped by other environmental cues remains incompletely defined. Nutrients are emerging mediators of adaptive immunity, but whether nutrients impact DC function or innate–adaptive cell communication is largely unresolved. Here, we establish glutamine as an intercellular metabolic checkpoint to mediate tumour–cDC1 crosstalk and license cDC1 functionality for activating cytotoxic T cells. Intratumoral glutamine supplementation inhibits tumour growth by augmenting cDC1-mediated CD8+ T-cell immunity, and also overcomes therapeutic resistance to checkpoint blockade and T-cell-mediated immunotherapies. Mechanistically, tumour cells and cDC1 compete for glutamine uptake via transporter SLC38A2 to tune anti-tumour immunity. Nutrient screening and integrative analyses show that glutamine is the dominant amino acid for promoting cDC1 function, by signalling via FLCN to impinge upon TFEB function. Loss of FLCN in DCs selectively impairs cDC1 function in vivo in a TFEB-dependent manner, and phenocopies SLC38A2 deficiency by abrogating anti-tumour therapeutic effect of glutamine supplementation. Our findings establish glutamine-mediated intercellular metabolic crosstalk between tumour cells and cDC1 that underpins tumour immunoevasion, and reveal glutamine acquisition and signalling in cDC1 as limiting events for DC activation and putative targets for cancer treatment.

Project description:Cancer cells evade T-cell-mediated killing through poorly understood mechanisms of tumour–immune interactions. Dendritic cells (DCs), especially type-1 conventional DCs (cDC1), mediate T-cell priming and therapeutic efficacy against tumours. Besides pattern recognition receptors (PRRs), how DC functions are shaped by other environmental cues remains incompletely defined. Nutrients are emerging mediators of adaptive immunity, but whether nutrients impact DC function or innate–adaptive cell communication is largely unresolved. Here, we establish glutamine as an intercellular metabolic checkpoint to mediate tumour–cDC1 crosstalk and license cDC1 functionality for activating cytotoxic T cells. Intratumoral glutamine supplementation inhibits tumour growth by augmenting cDC1-mediated CD8+ T-cell immunity, and also overcomes therapeutic resistance to checkpoint blockade and T-cell-mediated immunotherapies. Mechanistically, tumour cells and cDC1 compete for glutamine uptake via transporter SLC38A2 to tune anti-tumour immunity. Nutrient screening and integrative analyses show that glutamine is the dominant amino acid for promoting cDC1 function, by signalling via FLCN to impinge upon TFEB function. Loss of FLCN in DCs selectively impairs cDC1 function in vivo in a TFEB-dependent manner, and phenocopies SLC38A2 deficiency by abrogating anti-tumour therapeutic effect of glutamine supplementation. Our findings establish glutamine-mediated intercellular metabolic crosstalk between tumour cells and cDC1 that underpins tumour immunoevasion, and reveal glutamine acquisition and signalling in cDC1 as limiting events for DC activation and putative targets for cancer treatment.

Project description:Cancer cells evade T-cell-mediated killing through poorly understood mechanisms of tumour–immune interactions. Dendritic cells (DCs), especially type-1 conventional DCs (cDC1), mediate T-cell priming and therapeutic efficacy against tumours. Besides pattern recognition receptors (PRRs), how DC functions are shaped by other environmental cues remains incompletely defined. Nutrients are emerging mediators of adaptive immunity, but whether nutrients impact DC function or innate–adaptive cell communication is largely unresolved. Here, we establish glutamine as an intercellular metabolic checkpoint to mediate tumour–cDC1 crosstalk and license cDC1 functionality for activating cytotoxic T cells. Intratumoral glutamine supplementation inhibits tumour growth by augmenting cDC1-mediated CD8+ T-cell immunity, and also overcomes therapeutic resistance to checkpoint blockade and T-cell-mediated immunotherapies. Mechanistically, tumour cells and cDC1 compete for glutamine uptake via transporter SLC38A2 to tune anti-tumour immunity. Nutrient screening and integrative analyses show that glutamine is the dominant amino acid for promoting cDC1 function, by signalling via FLCN to impinge upon TFEB function. Loss of FLCN in DCs selectively impairs cDC1 function in vivo in a TFEB-dependent manner, and phenocopies SLC38A2 deficiency by abrogating anti-tumour therapeutic effect of glutamine supplementation. Our findings establish glutamine-mediated intercellular metabolic crosstalk between tumour cells and cDC1 that underpins tumour immunoevasion, and reveal glutamine acquisition and signalling in cDC1 as limiting events for DC activation and putative targets for cancer treatment.

Project description:Cancer cells evade T-cell-mediated killing through poorly understood mechanisms of tumour–immune interactions. Dendritic cells (DCs), especially type-1 conventional DCs (cDC1), mediate T-cell priming and therapeutic efficacy against tumours. Besides pattern recognition receptors (PRRs), how DC functions are shaped by other environmental cues remains incompletely defined. Nutrients are emerging mediators of adaptive immunity, but whether nutrients impact DC function or innate–adaptive cell communication is largely unresolved. Here, we establish glutamine as an intercellular metabolic checkpoint to mediate tumour–cDC1 crosstalk and license cDC1 functionality for activating cytotoxic T cells. Intratumoral glutamine supplementation inhibits tumour growth by augmenting cDC1-mediated CD8+ T-cell immunity, and also overcomes therapeutic resistance to checkpoint blockade and T-cell-mediated immunotherapies. Mechanistically, tumour cells and cDC1 compete for glutamine uptake via transporter SLC38A2 to tune anti-tumour immunity. Nutrient screening and integrative analyses show that glutamine is the dominant amino acid for promoting cDC1 function, by signalling via FLCN to impinge upon TFEB function. Loss of FLCN in DCs selectively impairs cDC1 function in vivo in a TFEB-dependent manner, and phenocopies SLC38A2 deficiency by abrogating anti-tumour therapeutic effect of glutamine supplementation. Our findings establish glutamine-mediated intercellular metabolic crosstalk between tumour cells and cDC1 that underpins tumour immunoevasion, and reveal glutamine acquisition and signalling in cDC1 as limiting events for DC activation and putative targets for cancer treatment.

Project description:Agonistic αCD40 therapy has been shown to inhibit cancer progression in only a fraction of patients. Understanding the cancer cell-intrinsic and microenvironmental determinants of αCD40 therapy response is therefore crucial to identify responsive patient populations and design efficient combinatorial treatments. Here, we show that the therapeutic efficacy of αCD40 in subcutaneous melanoma relies on pre-existing, type 1 classical dendritic cell (cDC1)-primed CD8+ T cells. However, after administration of αCD40, cDC1s were dispensable for anti-tumour efficacy. Instead, the abundance of activated cDCs, potentially derived from cDC2 cells, increased and further activated antitumour CD8+ T cells. Hence, distinct cDC subsets contributed to the induction of αCD40 responses. By contrast, lung carcinomas, characterized by a high abundance of macrophages, were resistant to αCD40 therapy. Combining αCD40 therapy with macrophage depletion led to tumour growth inhibition only in the presence of strong neoantigens. Accordingly, treatment with immunogenic cell death-inducing chemotherapy sensitized lung tumours to αCD40 therapy in subcutaneous and orthotopic settings. These insights into the microenvironmental regulators of response to αCD40 suggest that different tumour types would benefit from different combinations of therapies to optimize the clinical application of CD40 agonists.

Project description:XCR1+ dendritic cells (DC) have been shown to excel in antigen cross-presentation for the activation of naïve CD8 T cells. This property was reported to be associated to the subset of the XCR1+ DC expressing IL-12b upon ex vivo stimulation for 24 h with a mixture of CpG, IFN-γ, and GM-CSF (Lin ML et al. Proc Natl Acad Sci USA. 2008. PMID: 18272486). DC found in the steady-state non-lymphoid tissues undergo an homeostatic, tolerogenic, maturation and migrate to the draining lymph nodes to interact with naive autoreactive T cells and induction their peripheral tolerance. In contrast, spleen DC are thought to exist solely in an immature state. The aim of this study was to re-examine heterogeneity within steady state spleen XCR1+ DC, in particular examining whether this population encompass a fraction of mature DCs as assessed through their expression of CCR7 and/or the Il12b gene. Indeed, we show that a small fraction of XCR1+ spleen DC constitutively mature into two distinct but likely successive activation stages characterized as CCR7+ and CCR7+Il12b+ respectively, and correlated with increasing ability to cross-present antigen to naïve CD8 T cells. Transcriptomic analysis of the subsets of XCR1+ DC found in steady state spleen unexpectedly showed that their homeostatic maturation was unexpectedly associated with up-regulated of many genes thought to drive pro-inflammatory T-cell responses and previously found to be commonly induced upon maturation of distinct DC subsets in response to stimulation by various microbial-type stimuli (Vu Manh TP et al. Eur J Immunol. 2013. PMID: 23553052). Thus, our results reveal that spleen XCR1+ DC undergo constitutive maturation and emphasize the common mechanisms operating upon homeostatic, tolerogenic, DC maturation versus microbial-type stimuli-induced, immunogenic, DC maturation. DC were isolated from the spleen of untreated Il12b-EYFP reporter mice (Reinhardt RL et al. J Immunol. 2006. PMID:16849470) mice as previously described (Robbins SH et al. Genome Biol. 2008. PMID: 18218067; Baranek T et al. Cell Host Microbe. 2012. PMID: 23084923). DC subsets were sorted by flow cytometry according to the marker combinations described in the “characteristics: phenotype” field for each sample.

Project description:Conventional type 1 dendritic cells (cDC1s) are critical for anti-tumor immunity. They acquire antigens from dying tumor cells and cross-present them to CD8+ T cells, promoting the expansion of tumor-specific cytotoxic T cells. However, the signaling pathways that govern the anti -tumor functions of cDC1s are poorly understood. We mapped the molecular pathways regulating intratumoral cDC1 maturation using single cell RNA sequencing. We identified NF κB and IFN pathways as being highly enriched in a subset of functionally mature cDC1s. The specific targeting of NF-κB or IFN pathways in cDC1s prevented the recruitment and activation of CD8+ T cells and the control of tumor growth. We identified an NF-κB-dependent IFN-γ-regulated gene network in cDC1s, including cytokines and chemokines specialized in the recruitment and activation of cytotoxic T cells. We used single cell transcriptomes to map the trajectory of intra-tumoral cDC1 maturation which revealed the dynamic reprogramming of tumor-infiltrating cDC1s by NF-κB and IFN signaling pathways. This maturation process was perturbed by specific inactivation of either NF-κB or IRF1 in cDC1s, resulting in impaired expression of IFN-γ-responsive genes and consequently a failure to efficiently recruit and activate anti-tumoral CD8+ T cells. Finally, we demonstrate the relevance of these findings to cancer patients, showing that activation of the NF-κB/IRF1 axis in association with cDC1s is linked with improved clinical outcome. The NF-κB/IRF1 axis in cDC1s may therefore represent an important focal point for the development new diagnostic and therapeutic approaches to improve cancer immunotherapy.