Project description:To identify the functional non-coding RNAs in human DC development, we explored the gene expression profiles during DC development from peripheral monocytes. Using RNA-seq, we identified many annotated lncRNAs with markedly altered expressions during human DC differentiation and maturation. RNA samples from human peripheral blood monocytes and monocyte-derived DCs were collected. RNAs from 3 donors were pooled together to form monocyte sample or DC sample and then these two samples were subjected to RNA-seq and analysis.

Project description:Expression profiles at different time points during dendritic cell differentiation (induced by specific culture conditions) including monocytes as well as expression profiles between monocytes and completely differentiated cells (macrophages at day7 and dendritic cells at day7, respectively) were compared. Monocyte-derived dendritic cells (DC) were obtained by culturing elutriated monocytes with 20U/ml IL-4, 280U/ml GM-CSF and 10% FCS; monocyte-derived macrophages (MAC) were obtained by culturing elutriated monocytes with 2% AB serum. Three to seven biological replicates that are derived from independent healthy donors were included. One-color based gene expression. 2 datasets: dendritic cell kinetic study and comparison of monocyte, macrophage, and dendritic cells

Project description:In mice, two restricted DC progenitors, macrophage-dendritic progenitor (MDP) and common dendritic cell progenitor (CDP) demonstrate increasing commitment of DC lineage as they sequentially lose granulocyte and monocyte potential respectively. Identifying these progenitors has enabled understanding of the role of DCs and monocytes in immunity and tolerance in mice. In humans, however, restricted monocyte and DC progenitors remain unknown. Progress in studying human DC development has been hampered by lack of an in vitro culture system that recapitulates in vivo DC hematopoiesis. Here we report a culture system that supports development of CD34+ hematopoietic stem cell progenitors into the three major human DC subsets, monocytes, granulocytes, NK and B cells. Using this culture system we defined the pathway for human DC development, and revealed the sequential origin of human DCs from increasingly restricted progenitors: a granulocyte-monocyte-DC progenitor (hGMDP) that develops into a monocyte-DC progenitor (hMDP) that develops into monocytes and a common DC progenitor (hCDP) that is restricted to produce the three major DC subsets. The phenotype of the DC progenitors partially overlaps with granulocyte monocyte progenitors (GMPs). These progenitors reside in human cord blood and bone marrow but not in the blood or lymphoid tissues in the steady state. We performed whole transcriptome expression analysis on monocytes and subsets of dendritic cells i.e. CD1c+ DCs, CD141+ DCs and CD303+ pDCs isolated from blood or differentiated in culture from cord blood CD34+ cells in presence of MS5 stromal cells and Flt3l, GM-CSF and SCF cytokines.

Project description:Monocytes can give rise to multiple highly specialized cell types to perform a wide array of functions, ranging from pathogen phagocytosis to bone resorption. This differentiation is induced by the binding of cytokines to dedicated receptors on the surface of monocytes, which results in the initiation of genetic programs that enable cells to perform their specialized functions. Given their common background, it is not surprising that monocyte-derived cells share abilities and cellular markers, yet their specialized functions require a dedicated set of proteins. In order to dissect the monocyte differentiation process and to define cell type-specific marker proteins, we differentiated circulating monocytes into dendritic cells, M1 and M2 macrophages, and osteoclasts, and assessed their proteomes by quantitative mass spectrometry throughout the differentiation process. Statistical analysis indicated that monocyte differentiation is a linear process characterized by a common core of proteins that is similarly affected among the distinct differentiation paths. Throughout the specialization process a cluster of RNA-binding and processing proteins was downregulated whereas proteins associated to metabolic processes were increased. Analysis of the specialized cells after 10 days of differentiation uncovered existing and putative novel dendritic cell markers. Combined, we here present a comprehensive proteomic analysis of monocyte differentiation uncovering shared and distinct proteomic features of differentiating monocytes and monocyte-derived cells.

Project description:The contribution of monocyte-derived dendritic cells (DC) to an immune response is essential for the elimination of pathogens. In vitro DC can be generated by treatment of monocytes with GM-CSF + IL-4 but it is unknown what stimuli induce the differentiation of monocytes to DC in vivo. CD137L-DC are human monocyte-derived DC that are generated by CD137 ligand (CD137L) signaling. Since CD137 is only expressed at sites of inflammation it would be a suitable signal for the induction of monocyte-derived DC. Here we report on gene expression analysis of CD137L-DC, immature and mature classical DC, monocytes and macrophages which indicates that CD137L-DC have a gene signature that is most similar to that of classical DC. Additionally, CD137L-DC signature genes are highly enriched in monocyte-derived DC which were isolated from sites of inflammation. Also cell surface marker expression and cytokine secretion of CD137L-DC are highly similar to that of inflammatory monocyte-derived DC. CD137L-DC express high levels of adhesion molecules, display strong attachment and employ the adhesion molecule ALCAM to stimulate T cell proliferation. This study identifies a physiological stimulus for the generation of monocyte-derived DC in vivo.

Project description:In order to gain insights into how PPARg regulates different facets of dendritic cell (DC) differentiation, we sought to identify PPARg regulated genes and gene networks in monocyte-derived dendritic cells using global gene expression profiling. We employed an exogenous ligand activation approach using a selective PPARg ligand (rosiglitazone abbreviated as RSG). In addition, we have defined culture conditions in which human serum (HS) induces PPARg activation via a yet uncharacterized endogenous mechanism. We also compared the gene expression profile of developing dendritic cells obtained from patients harboring dominant negative mutations of the PPARg receptor (C114R and C131Y). Experiment Overall Design: Monocytes were cultured for 6, 24 hours or 5 days with 500 U/ml IL-4 and 800 U/ml GM-CSF; cytokine treatment was repeated at day 3. Cells were obtained from 12 healthy individuals (6 biological replicates; the 6 and 24 hours samples were obtained from a single individual but the 5 days samples from a different one). Ligands were added at the beginning of differentiation. The 6 and 24 hours cells were treated with vehicle (DC) or 1 uM rosiglitazone (DC RSG), in the case of 5 day cultured cells 2.5 uM RSG was used. Cells were cultured in RPMI plus 10% FBS, in the case of DC4-DC6 cells were also cultured in human AB serum (DC HS). Finally we also obtained cells from patients harboring point mutations of the PPARg receptor (C114R and C131Y)

Project description:In order to detect the microRNA expression profile of in vitro generated dendritic cells , purified monocytes from PBMCs were used as dendritic cell (DCs) precursors and were cultured in medium with cocktail for differentiation and maturation to immature dendritic cells (iDCs) and mature dendritic cells (mDCs). microRNA samples were isolated from precursor, iDCs and mDCs and used for microarray-based microRNAs expression profiles. To generate enough amount of immature DC (iDCs) and mature DCs (mDCs), monocytes were differentiated with GM-CSF and rhIL-4 for 2 days and maturated in the presence of TNF-α, IL-1β, IL-6 and PGE2 for another 2 days. With the anticipation to insight developmental-stage-specific microRNAs with potential functions related to monocyte derived DCs, global microRNAs expression profiling was set using microarray technology.microRNA expression profiles were performed in triplicate independent experiments starting for 3 groups of precursor, iDC and mDC generated from different blood donors.

Project description:In order to detect the gene expression profile of in vitro generated dendritic cells , purified monocytes from PBMCs were used as dendritic cell (DCs) precursors and were cultured in medium with cocktail for differentiation and maturation to immature dendritic cells (iDCs) and mature dendritic cells (mDCs). Total RNA samples were isolated from precursor, iDCs and mDCs and used for microarray-based gene expression profiles. To generate enough amount of immature DC (iDCs) and mature DCs (mDCs), monocytes were differentiated with GM-CSF and rhIL-4 for 2 days and maturated in the presence of TNF-α, IL-1β, IL-6 and PGE2 for another 2 days. With the anticipation to insight developmental-stage-specific genes with potential functions related to monocyte derived DCs, global gene expression profiling was set using microarray technology.gene expression profiles were performed in triplicate independent experiments starting for 3 groups of precursor, iDC and mDC generated from different blood donors.

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