Project description:Langerhans cells (LCs) are a unique population of phagocytes programmed within embryonic skin to maintain tissue and immunological homeostasis at the epidermal barrier site. Unique amongst tissue-resident macrophages, LCs play roles in skin innervation and repair, while also functioning as migrating professional antigen presenting cells, a capability classically assigned to dendritic cells (DC). We current lack insight into the molecular pathways that determine this dichotomy, when they are established, and whether precursors recruited to the adult skin niche access the same instructive signals laid down in utero. Tracking differentiation of monocyte-derived (m)LCs after destruction of embryo-derived cells in murine adult skin, revealed intrinsic intra-epidermal heterogeneity and selection of MDP-monocytes to by-pass gene programmes specifying a macrophage fate. Adopting a process unique to adult skin, subsequent extrinsic specification of EpCAM+ precursors via follicular Notch ligands, and aryl hydrocarbon receptor (Ahr) signalling, combined to determine commitment to resident mLCs. Using a unique human LC dataset, we demonstrated that embryo-derived (e)LCs in newborn human skin retained transcriptional evidence of their macrophage origin, which was superseded by a distinct DC-like immune modules following proliferation in infant skin. Thus, convergent differentiation of monocytes within adult skin exploits novel molecular pathways to replicate conditioning of eLC towards more immunogenic DC-like cells within post-natal skin.

Project description:miRNA profiling of CD34+ derived, in vitro-generated Langerhans cells (LCs) and interstitial-type dendritic cells (intDCs). Epidermal Langerhans cells (LCs) form a network of dendritic cells (DCs) in basal/suprabasal layers of the skin and are characterized by a unique phenotype (CD207+ CD1abright CD324+ CD11b-). Due to their specific location at body surfaces, LCs are constantly exposed to environmental stimuli. Conversely, interstitial-type DCs (intDCs) are located in adjacent tissues and can be discriminated from LCs phenotypically (CD207- CD1adim CD324- CD11b+). These DCs constitute a second line of defense against pathogens that have crossed the epithelial barrier. During development both DC subsets originally arise from myeloid progenitor cells via monocyte-committed intermediates in response to specific microenvironmental signals. Additionally certain pools of DCs can be replenished by tissue resident cells or monocytes in response to specific microenvironmental signals (2, 4, 5). In vitro generated GM-CSF/IL-4-dependent DCs derived either from CD14+ monocytes or via CD14+CD11b+ monocyte intermediates from CD34+ progenitor cells share many characteristics with intDCs in vivo. On the other hand, LCs generated from CD34+ cells under serum-free TGF-beta1-dependent conditions phenotypically resemble epidermal-resident LCs. Since these two DC subsets are of considerable interest for clinical cell therapy studies, an improved understanding of their development and function is of substantial relevance. To identify differentially expressed miRNAs in DC subsets, we performed a miRNA screen. Therefore, we generated LCs or intDCs from human CD34+ cord blood haematopoietic progenitor cells as described. For intDCs, CD34+ cells (1 x 104 to 2 x 104/ml per well) were cultured in 24-well tissue culture plates in serum free CellGro® DC medium (CellGenix, Freiburg, Germany) supplemented with GM-CSF (100 ng/ml), SCF (20 ng/ml), FL (50 ng/ml) and TNFalpha (2.5 ng/ml) for 3-5 days and subsequently with GM-CSF (100 ng/ml) and IL-4 (2.5 ng/ml) for 4-5 days. For LCs, CD34+ cells (1 x 104 to 2 x 104/ml per well) were cultured in 24-well tissue culture plates in serum free CellGro® DC medium (CellGenix, Freiburg, Germany) supplemented with GM-CSF (100 ng/ml), SCF (20 ng/ml), FL (50 ng/ml), TNFalpha (2.5 ng/ml) and TGF-beta1 (0.5 ng/ml). The well-established immunophenotype of LCs (CD1ahi CD11b- CD207+ CD324+) and intDCs (CD1a+ CD11b+ CD207- CD324-) was confirmed by FACS. These two DC subsets were purified and submitted to differential miRNA profiling. Two conditioned experiment LCs vs. intDCs. Biological replicates: 3 LCs, 3 intDCs, independently differentiated, harvested and purified. 3 replicates each were pooled and hybridized on one array. Supplementary files linked below.

Project description:TGF-β family ligands are key regulators of dendritic cell (DC) differentiation and activation. Epidermal Langerhans cells (LCs) require TGF-β family signaling for their differentiation and canonical TGF-β1 signaling secures a non-activated LC state. LCs reportedly control skin inflammation and are replenished from peripheral blood monocytes, which also give rise to pro-inflammatory monocyte-derived DCs (moDCs). By studying mechanisms in inflammation, we previously screened LCs vs moDCs for differentially expressed miRNAs. miR-424/503 was the most strongly inversely regulated (moDCs > LCs). We found that miR-424/503 is induced during moDC differentiation and promotes moDC differentiation in human and mouse. Inversely, forced repression of miR-424 during moDC differentiation facilitated TGF-β1-dependent LC differentiation. Mechanistically, miR-424/503 deficiency in monocyte/DC precursors leads to the induction of TGF-β1-response genes critical for LC differentiation. Therefore, the miR-424/503 gene cluster plays a decisive role in anti-inflammatory LC vs pro-inflammatory moDC differentiation from monocytes.

Project description:miRNA profiling of CD34+ derived, in vitro-generated Langerhans cells (LCs) and interstitial-type dendritic cells (intDCs). Epidermal Langerhans cells (LCs) form a network of dendritic cells (DCs) in basal/suprabasal layers of the skin and are characterized by a unique phenotype (CD207+ CD1abright CD324+ CD11b-). Due to their specific location at body surfaces, LCs are constantly exposed to environmental stimuli. Conversely, interstitial-type DCs (intDCs) are located in adjacent tissues and can be discriminated from LCs phenotypically (CD207- CD1adim CD324- CD11b+). These DCs constitute a second line of defense against pathogens that have crossed the epithelial barrier. During development both DC subsets originally arise from myeloid progenitor cells via monocyte-committed intermediates in response to specific microenvironmental signals. Additionally certain pools of DCs can be replenished by tissue resident cells or monocytes in response to specific microenvironmental signals (2, 4, 5). In vitro generated GM-CSF/IL-4-dependent DCs derived either from CD14+ monocytes or via CD14+CD11b+ monocyte intermediates from CD34+ progenitor cells share many characteristics with intDCs in vivo. On the other hand, LCs generated from CD34+ cells under serum-free TGF-beta1-dependent conditions phenotypically resemble epidermal-resident LCs. Since these two DC subsets are of considerable interest for clinical cell therapy studies, an improved understanding of their development and function is of substantial relevance. To identify differentially expressed miRNAs in DC subsets, we performed a miRNA screen. Therefore, we generated LCs or intDCs from human CD34+ cord blood haematopoietic progenitor cells as described. For intDCs, CD34+ cells (1 x 104 to 2 x 104/ml per well) were cultured in 24-well tissue culture plates in serum free CellGro® DC medium (CellGenix, Freiburg, Germany) supplemented with GM-CSF (100 ng/ml), SCF (20 ng/ml), FL (50 ng/ml) and TNFalpha (2.5 ng/ml) for 3-5 days and subsequently with GM-CSF (100 ng/ml) and IL-4 (2.5 ng/ml) for 4-5 days. For LCs, CD34+ cells (1 x 104 to 2 x 104/ml per well) were cultured in 24-well tissue culture plates in serum free CellGro® DC medium (CellGenix, Freiburg, Germany) supplemented with GM-CSF (100 ng/ml), SCF (20 ng/ml), FL (50 ng/ml), TNFalpha (2.5 ng/ml) and TGF-beta1 (0.5 ng/ml). The well-established immunophenotype of LCs (CD1ahi CD11b- CD207+ CD324+) and intDCs (CD1a+ CD11b+ CD207- CD324-) was confirmed by FACS. These two DC subsets were purified and submitted to differential miRNA profiling.

Project description:Langerhans cells (LCs) populate the mucosal epithelium, a major entry portal for pathogens, yet their ontogeny remains unclear. In contrast to skin LCs originating from self-renewing radioresistant embryonic precursors, we found that oral mucosal LCs derive from circulating radiosensitive precursors. Mucosal LCs can be segregated into CD103+CD11blow (CD103+LCs) and CD11b+CD103- (CD11b+LCs) subsets. We further demonstrated that similar to non-lymphoid dendritic cells (DCs), CD103+LCs originate from pre-DCs, whereas CD11b+LCs differentiate from both pre-DCs and monocytic precursors. Despite this ontogenetic discrepancy between skin and mucosal LCs, transcriptomic signature and immunological function of oral LCs highly resemble those of skin LCs but not DCs. These findings, along with their epithelial position, morphology and expression of LC-associated phenotype strongly suggest that oral mucosal LCs are genuine LCs. Collectively, in a tissue-dependent manner, murine LCs differentiate from at least three distinct precursors (embryonic, pre-DCs and monocytic) in steady state The following cells were isolated from mice (2-4 replicates): Lung DCs, mucosal CD103+ LC, mucosal CD11b+ LC, Skin LC. Transcriptome analysis was performed.

Project description:The lineage relationships and fate of human blood and tissue dendritic cells (DC) has significance for a number of diseases including HIV where both blood and tissue DC may be infected. We used gene expression profiling of monocyte and DC sub-populations sorted directly from blood and skin and compared this to monocyte derived DC (MDDC) and MUTZ3 Langerhans cells (LCs) to define the lineage relationships. Hierarchical clustering analysis showed that plasmacytoid DCs formed the most discrete cluster. The ex vivo derived myeloid cells formed two separate clusters of cells derived from blood, and skin. Separate and specific DC populations could be determined within the sub-clusters. During overnight culture CD14+ dermal DCs (DDC) converted to CD1a+ expressing cells in situ consistent with origin of the CD1a+ DDC from a local precursor rather than from circulating blood DC or monocyte precursors. The in vitro derived MDDC and MUTZ3 populations grouped within the skin DC cluster and MDDCs clustered most closely to CD14+ DDC consistent with the proposed similarity between these two cell types. We identified differential expression of novel genes in particular DC subsets including genes related to DC surface receptors (including C-type lectin receptors, toll-like receptors and galectins). Total RNA was extracted and hybridised to 24 bead arrays. Dendritic cells and monocytes from human blood and skin using magnetic bead and flow cytometry based cell sorting both before and after culture for 24 hours

Project description:The lineage relationships and fate of human blood and tissue dendritic cells (DC) has significance for a number of diseases including HIV where both blood and tissue DC may be infected. We used gene expression profiling of monocyte and DC sub-populations sorted directly from blood and skin and compared this to monocyte derived DC (MDDC) and MUTZ3 Langerhans cells (LCs) to define the lineage relationships. Hierarchical clustering analysis showed that plasmacytoid DCs formed the most discrete cluster. The ex vivo derived myeloid cells formed two separate clusters of cells derived from blood, and skin. Separate and specific DC populations could be determined within the sub-clusters. During overnight culture CD14+ dermal DCs (DDC) converted to CD1a+ expressing cells in situ consistent with origin of the CD1a+ DDC from a local precursor rather than from circulating blood DC or monocyte precursors. The in vitro derived MDDC and MUTZ3 populations grouped within the skin DC cluster and MDDCs clustered most closely to CD14+ DDC consistent with the proposed similarity between these two cell types. We identified differential expression of novel genes in particular DC subsets including genes related to DC surface receptors (including C-type lectin receptors, toll-like receptors and galectins). Total RNA was extracted and hybridised to 62 cDNA arrays. Dendritic cells and monocytes from human blood and skin using magnetic bead and flow cytometry based cell sorting both before and after culture for 24 hours

Project description:Langerhans cells (LCs) populate the mucosal epithelium, a major entry portal for pathogens, yet their ontogeny remains unclear. In contrast to skin LCs originating from self-renewing radioresistant embryonic precursors, we found that oral mucosal LCs derive from circulating radiosensitive precursors. Mucosal LCs can be segregated into CD103+CD11blow (CD103+LCs) and CD11b+CD103- (CD11b+LCs) subsets. We further demonstrated that similar to non-lymphoid dendritic cells (DCs), CD103+LCs originate from pre-DCs, whereas CD11b+LCs differentiate from both pre-DCs and monocytic precursors. Despite this ontogenetic discrepancy between skin and mucosal LCs, transcriptomic signature and immunological function of oral LCs highly resemble those of skin LCs but not DCs. These findings, along with their epithelial position, morphology and expression of LC-associated phenotype strongly suggest that oral mucosal LCs are genuine LCs. Collectively, in a tissue-dependent manner, murine LCs differentiate from at least three distinct precursors (embryonic, pre-DCs and monocytic) in steady state

Project description:The ontogeny of human Langerhans cells (LCs) remains poorly characterized, in particular the nature of LC precursors and the factors that may drive LC differentiation. Through a systematic transcriptomic analysis of TSLP-activated dendritic cells (DCs), we unexpectedly identified markers that have been associated with a skin-homing potential as well as with a LC phenotype. We performed transcriptomic analysis of TSLP-activated blood DCs, as compared to freshly purified, Medium-, and TNF-activated DCs. Among TSLP up-regulated genes, we identified molecules associated with skin homing, LC phenotype, and LC function, as determined by a literature-based survey. Conversely, genes not expressed in LCs were not found among TSLP-induced genes. Further experiments showed that TGF-? synergized with TSLP leading to the differentiation of blood BDCA-1+ DCs into bona fide Birbeck granule-positive LCs. The ontogeny of human Langerhans cells (LCs) remains poorly characterized, in particular the nature of LC precursors and the factors that may drive LC differentiation. Through a systematic transcriptomic analysis of TSLP-activated dendritic cells (DCs), we unexpectedly identified markers that have been associated with a skin-homing potential as well as with a LC phenotype. We performed transcriptomic analysis of TSLP-activated blood DCs, as compared to freshly purified, Medium-, and TNF-activated DCs. Among TSLP up-regulated genes, we identified molecules associated with skin homing, LC phenotype, and LC function, as determined by a literature-based survey. Conversely, genes not expressed in LCs were not found among TSLP-induced genes. Further experiments showed that TGF-? synergized with TSLP leading to the differentiation of blood BDCA-1+ DCs into bona fide Birbeck granule-positive LCs. Dendritic cells (DC) were purified from the blood of healthy human donors. Each replicate comes from a different donor. There are 6 freshly purified samples (Control_0h), 4 DC samples cultured during 6h with no additional stimulus than the medium (Control_6h), 5 samples cultured during 6h with recombinant TSLP (Thymic Stromal Lymphopoietin at 20 ng/uL) (TSLP_6h) and 3 samples cultured during 6h with recombinant TNF (Tumor necrosis factor at 20 ng/mL) (TNF_6h).

Project description:The lineage relationships and fate of human blood and tissue dendritic cells (DC) has significance for a number of diseases including HIV where both blood and tissue DC may be infected. We used gene expression profiling of monocyte and DC sub-populations sorted directly from blood and skin and compared this to monocyte derived DC (MDDC) and MUTZ3 Langerhans cells (LCs) to define the lineage relationships. Hierarchical clustering analysis showed that plasmacytoid DCs formed the most discrete cluster. The ex vivo derived myeloid cells formed two separate clusters of cells derived from blood, and skin. Separate and specific DC populations could be determined within the sub-clusters. During overnight culture CD14+ dermal DCs (DDC) converted to CD1a+ expressing cells in situ consistent with origin of the CD1a+ DDC from a local precursor rather than from circulating blood DC or monocyte precursors. The in vitro derived MDDC and MUTZ3 populations grouped within the skin DC cluster and MDDCs clustered most closely to CD14+ DDC consistent with the proposed similarity between these two cell types. We identified differential expression of novel genes in particular DC subsets including genes related to DC surface receptors (including C-type lectin receptors, toll-like receptors and galectins).