Project description:High-dimensional approaches have revealed emerging heterogeneity within dendritic cells (DC), including a population of transitional DC (tDC) present in mouse and human. However, tDC origin and relationship to other DC subsets are not fully understood because their phenotype partially overlaps with previous definitions of conventional DC precursors (pre-cDC). Here, we show that tDC are distinct from other well-characterized DC and pre-cDC. By combining single-cell transcriptomics, high-dimensional immunophenotyping, lineage tracing and adoptive transfer experiments, we demonstrate that murine tDC originate from bone marrow progenitors shared with plasmacytoid DC (pDC) that are distinct from CD115-expressing conventional DC progenitors. In the periphery, tDC contribute to the pool of Esam+ type 2 DC (DC2), and these tDC-derived DC2 harbor pDC-related developmental features. tDC have lower turnover than pre-cDC2, capture antigen, respond to stimuli, and potently antigen-specific naïve T cells, all characteristics of differentiated DC. Different from pDC, viral sensing by tDC results in IL-1β secretion and fatal immune pathology in a model of murine coronavirus. Our findings suggest that tDC are a distinct pDC-related lineage with a DC2 differentiation potential and unique pro-inflammatory function during viral infections.  The objective of this experiment was to evaulate the transcriptional changes in various dendritic cell subpopulations

Project description:Dendritic cells (DC) form a collection of antigen-presenting cells that are distributed throughout the body. Conventional DC (cDC) which include the cDC1 and cDC2 subsets, and plasmacytoid DC (pDC) constitute the two major ontogenically distinct DC populations. The pDC complete their differentiation in bone-marrow (BM) while the cDC subsets derive from pre-committed bone-marrow (BM) precursors, the pre-cDC, that seed lymphoid and non-lymphoid tissues where they further differentiate into mature cDC1 and cDC2. Within different tissues, cDC express distinct phenotype and function. Notably cDC in the thymus are exquisitely efficient at processing and presenting antigens in the class II pathway, while in the spleen they do so only upon maturation induced by danger signals. To appraise this functional heterogeneity, we examined the regulation of the expression of distinct antigen-processing enzymes during DC ontogeny. We analyzed the expression of cathepsin S (CTSS), cathepsin L (CTSL) and thymus specific serine protease (TSSP), three major antigen-processing enzymes regulating class II presentation in cDC, by DC BM precursors and immature and mature cDC from spleen and thymus. We found that pre-cDC in the BM express relatively high levels of these different proteases. Then, their expression is modulated in a tissue-specific and subset–specific manner with immature and mature thymic cDC expressing overall higher levels than immature splenic cDC. On the other hand, TSSP expression level is selectively down-regulated in spleen pDC while CTSS and CTSL are both increased in thymic and splenic pDC. Hence tissue-specific factors program the expression levels of these different proteases during DC differentiation thus conferring tissue-specific function to the different DC subsets.

Project description:Dendritic cells (DC) are professional antigen presenting cells that develop from hematopoietic stem cells in bone marrow by successive steps of lineage commitment and differentiation. Different DC subsets were identified based on phenotype, localisation and function: (i) classical DC (cDC) and plasmacytoid DC (pDC) are found in lymphoid organs and (ii) migratory tissue DC are spread throughout peripheral organs, including Langerhans cells, the cutaneous contingent of DC. We have developed a two-step culture system that recapitulates DC development in vitro (Felker et al., J. Immunol. 185, 5326-5335, 2010). In this system multipotent hematopoietic progenitors (MPP) progress into DC-restricted common DC progenitors (CDP) and further into the two major DC subsets cDC and pDC. We employed chromatin immunoprecipitation (ChIP) with deep sequencing (ChIP-seq) to determine the dynamics of H3K27ac occupancy in MPP, CMP, cDC and pDC. Histone modification H3K27ac and RNA-Seq in MPP, CDP, cDC and pDC

Project description:Plasmacytoid dendritic cells (pDCs) have been shown to play an important role during immune responses, ranging from initial viral control through the production of type I interferons (IFNs) to antigen presentation. However, recent evidence uncovered unexpected heterogeneity among pDCs. Notably we identified a new subset, referred to as pDC-like cells, that resembles pDCs but shares cDC features. Here we show that this subset is a circulating progenitor distinct from common DC progenitors (CDP), with prominent cDC2 precursor potential. This precursor subset responds to homeostatic cytokines, such as macrophage colony stimulating factor (M-CSF) by expanding and differentiating into cDC2 that efficiently prime Th17 cell. Development of pDC-like cells into CX3CR1+ESAM- cDC2b but not CX3CR1- ESAM+ cDC2a requires the transcription factor KLF4. Finally, we show that under homeostatic conditions this developmental pathway regulates the immune threshold at barrier sites, by controlling the pool of Th17 cells within the skin draining lymph nodes.

Project description:Dendritic cells (DC) are professional antigen presenting cells that develop from hematopoietic stem cells in bone marrow by successive steps of lineage commitment and differentiation. Different DC subsets were identified based on phenotype, localisation and function: (i) classical DC (cDC) and plasmacytoid DC (pDC) are found in lymphoid organs and (ii) migratory tissue DC are spread throughout peripheral organs, including Langerhans cells, the cutaneous contingent of DC. We have developed a two-step culture system that recapitulates DC development in vitro (Felker et al., J. Immunol. 185, 5326-5335, 2010). In this system multipotent hematopoietic progenitors (MPP) progress into DC-restricted common DC progenitors (CDP) and further into the two major DC subsets cDC and pDC. We employed chromatin immunoprecipitation (ChIP) with deep sequencing (ChIP-seq) to determine the dynamics of H3K27ac occupancy in MPP, CDP, cDC and pDC. Additionally, we monitored changes in gene expression in MPP, CDP, cDC and pDC by RNA-seq.

Project description:Plasmacytoid dendritic cells (pDC) are the main source of type I interferon (IFN) during viral infections. Their other functions are debated, due to a lack of tools to identify and target them in vivo without affecting pDC-like cells and transitional DC (tDC), which harbor overlapping phenotypes and transcriptomes but a higher efficacy for T cell activation. To overcome this bottleneck, we designed, generated and validated a pDC-Tomato reporter mouse. We bred pDC-Tomato with Zbtb46 GFP mice to yield the he ZeST mouse strain that enabled transcriptomic profiling of all splenic DC types, by single cell RNA sequencing, both at steady state and during the course of the infection with mouse cytomegalovirus (MCMV). Analyses of the transcriptomic dataset unraveled diverging activation of pDC-like cells vs tDC during the infection. This dataset and the associated specific gene modules will be useful to delineate the physiological functions of pDC versus other DC types.

Project description:By combining single cell transcriptomics and proteomics approaches, with lineage tracing and adoptive transfer experiments, we next demonstrate that tDC originate from a bone marrow precursor shared with plasmacytoid DCs (pDCs). Using new lineage tracing mouse models, we evaluated tDC plasticity and reveal their acquisition of Esamhi conventional DC type 2 (cDC2) features. Finally, we present tDC capacity to quickly response to stimulation and potently activate antigen-specific naïve T cells, demonstrating that these cells harbor functions of differentiated DCs. Our findings clarify tDC nature and reveal these cells as a unique lineage of DCs related developmentally to pDCs. 

Project description:Dendritic cells (DC) are professional antigen presenting cells that develop from hematopoietic stem cells through successive steps of lineage commitment and differentiation. Multipotent progenitors (MPP) are committed to DC restricted common DC progenitors (CDP), which differentiate into specific DC subsets, classical DC (cDC) and plasmacytoid DC (pDC). To determine epigenetic states and regulatory circuitries during DC differentiation, we measured consecutive changes of genome-wide gene expression, histone modification and transcription factor occupancy during the sequel MPP-CDP-cDC/pDC. Specific histone marks in CDP reveal a DC-primed epigenetic signature, which is maintained and reinforced during DC differentiation. Epigenetic marks and transcription factor PU.1 occupancy increasingly coincide upon DC differentiation. By integrating PU.1 occupancy and gene expression we devised a transcription factor regulatory circuitry for DC commitment and subset specification. The circuitry provides the transcription factor hierarchy that drives the sequel MPP-CDP-cDC/pDC, including Irf4, Irf8, Tcf4, Spib and Stat factors. The circuitry also includes feedback loops inferred for individual or multiple factors, which stabilize distinct stages of DC development and DC subsets. In summary, here we describe the basic regulatory circuitry of transcription factors that drives DC development.

Project description:Committed precursors of conventional dendritic cells (pre-cDCs) derived from the common DC progenitor which differentiate into cDC subpopulations in peripheral tissues have been identified, but committed precursors for plasmacytoid DCs (pDCs) have not been found. Here we show that CDP-derived ‘CCR9- MHCIIlow BST2+ Siglec-H+ pDCs from murine bone marrow which enter the circulation and peripheral tissues have a common DC precursor function in vivo in the steady state. Upon adoptive transfer the fate of CCR9- pDC-like precursors is governed by the tissues they enter. In the bone marrow and liver most transferred CCR9- pDC-like precursors differentiate into CCR9+ pDCs, whereas in peripheral lymphoid organs, lung and intestine they can give rise to CCR9+ pDCs and cDCs. Thus, CCR9- pDC-like cells are novel CDP-derived circulating DC precursors with pDC and cDC potential, whose final differentiation depends on tissue-specific factors allowing adaptation to local requirements. Total RNA obtained from CCR9- pDC-like common DC progenitors and CCR9+ pDCs was compared for differential gene expression. 3 independent isolations were performed for the 2 samples. 6 arrays were run in total.

Project description:Committed precursors of conventional dendritic cells (pre-cDCs) derived from the common DC progenitor which differentiate into cDC subpopulations in peripheral tissues have been identified, but committed precursors for plasmacytoid DCs (pDCs) have not been found. Here we show that CDP-derived ‘CCR9- MHCIIlow BST2+ Siglec-H+ pDCs from murine bone marrow which enter the circulation and peripheral tissues have a common DC precursor function in vivo in the steady state. Upon adoptive transfer the fate of CCR9- pDC-like precursors is governed by the tissues they enter. In the bone marrow and liver most transferred CCR9- pDC-like precursors differentiate into CCR9+ pDCs, whereas in peripheral lymphoid organs, lung and intestine they can give rise to CCR9+ pDCs and cDCs. Thus, CCR9- pDC-like cells are novel CDP-derived circulating DC precursors with pDC and cDC potential, whose final differentiation depends on tissue-specific factors allowing adaptation to local requirements.