Project description:Dendritic cells (DCs) are essential regulators of immune responses; however, transcriptional mechanisms establishing DC lineage commitment are poorly defined. Here we report that the PU.1 transcription factor induces specific remodeling of the higher-order chromatin structure at the Interferon Regulatory Factor-8 (Irf8) gene to initiate DC fate choice. Generation of an Irf8 reporter mouse enabled us to pinpoint an initial progenitor stage at which DCs separate from other myeloid lineages in the bone marrow. In the absence of Irf8, this progenitor undergoes DC-to-neutrophil reprogramming, indicating that DC commitment requires an active, Irf8-dependent escape from alternative myeloid lineage potential. Mechanistically, myeloid Irf8 expression depends on high PU.1 levels, resulting in local chromosomal looping and activation of a lineage- and developmental stage-specific cis-enhancer. These data delineate PU.1 as a concentration-dependent rheostat of myeloid lineage selection by controlling long-distance contacts between regulatory elements, and suggest that specific higher-order chromatin remodeling at the Irf8 gene determines DC differentiation. Mature macrophages, Granulocytes and DCs were isolated from wildtype mouse spleens for successive RNA extraction and hybridization on Affymetrix microarrays. 3 different pools, each consisting of splenic cells from 5 mice were prepared. Cell populations were isolated by flow cytometry. MDPs were isolated from Wildtype and IRF8 deficient bonemarrow by flowcytometry, again creating 3 biological replicates, each consisting of pooled cells from 5 mice. Differential gene expression between wildtype and IRF8 deficient MDPs was subgrouped into macrophage, granuloctic and DC signatures, derived from expression data of these cell populations.

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:The transcription factors Batf3 and IRF8 are required for development of CD8α+ conventional dendritic cells (cDCs), but the basis for their actions was unclear. Here, we identify two novel Zbtb46+ progenitors that separately generate CD8α+ and CD4+ cDCs and arise directly from the common DC progenitor (CDP). Irf8 expression in the CDP depends on prior PU.1-dependent autoactivation, and specification of pre-CD8 DC progenitors requires IRF8 but not Batf3. However, upon pre-CD8 DC specification, Irf8 autoactivation becomes Batf3-dependent at a CD8α+ cDC-specific enhancer containing multiple AP1-IRF composite elements (AICEs) within the Irf8 superenhancer. CDPs from Batf3-/- mice that specify toward pre-CD8 DCs fail to complete CD8α+ cDC development due to decay of Irf8 autoactivation, and divert to the CD4+ cDC lineage. Examination of histone modifications (H3K27ac and H3K4me1) and 2 transcription factors (Batf3 and Irf8) and the p300 co-factor binding in 3 different dendritic cell subsets

Project description:While most blood lineages are assumed to mature through a single cellular and developmental route downstream of hematopoietic stem cells (HSCs), dendritic cells (DCs) can be derived from both myeloid and lymphoid progenitors in vivo. To determine how distinct progenitors can generate similar downstream lineages, we examined the transcriptional changes that accompany loss of in vivo myeloid potential as common myeloid progenitors (CMPs) differentiate into common dendritic cell progenitors (CDPs), and as lymphoid-primed multipotent progenitors (LMPPs) differentiate into all lymphoid progenitors (ALPs). Microarray studies revealed that Interferon regulatory factor 8 (IRF-8) expression increased during each of these transitions. Competitive reconstitutions using Irf8-/- bone marrow demonstrated cell-intrinsic defects in the formation of CDPs and all splenic dendritic cell subsets. Irf8-/- CMPs and, unexpectedly, Irf8-/- ALPs produced more neutrophils in vivo than their wild type counterparts at the expense of DCs. Retroviral expression of IRF-8 in multiple progenitors led to reduced neutrophil production and increased numbers of DCs, even in the granulocyte-macrophage progenitor (GMP), which does not normally possess conventional DC potential. These data suggest that IRF-8 represses a neutrophil module of development and promotes convergent DC development from multiple lymphoid and myeloid progenitors autonomously of cellular context. CMP (Lineage-c-kithiSca-1-CD11c- CD34+ Flk2+CD16/32-CD115- ) or CDP (Lin-c-kitintSca-1-CD34+Flk2+CD16/32-CD115+) were double sorted from the bone marrow of wild type C57BL/6 mice. RNA was extracted from 10,000-30,000 sorted cells using Trizol (Invitrogen) and linear acrylamide (Ambion), amplified using Affymetrix Two-Cycle Amplification and IVT kits (Affymetrix), and hybridized to Affymetrix Mouse Genome 430 2.0 chips.

Project description:While most blood lineages are assumed to mature through a single cellular and developmental route downstream of hematopoietic stem cells (HSCs), dendritic cells (DCs) can be derived from both myeloid and lymphoid progenitors in vivo. To determine how distinct progenitors can generate similar downstream lineages, we examined the transcriptional changes that accompany loss of in vivo myeloid potential as common myeloid progenitors (CMPs) differentiate into common dendritic cell progenitors (CDPs), and as lymphoid-primed multipotent progenitors (LMPPs) differentiate into all lymphoid progenitors (ALPs). Microarray studies revealed that Interferon regulatory factor 8 (IRF-8) expression increased during each of these transitions. Competitive reconstitutions using Irf8-/- bone marrow demonstrated cell-intrinsic defects in the formation of CDPs and all splenic dendritic cell subsets. Irf8-/- CMPs and, unexpectedly, Irf8-/- ALPs produced more neutrophils in vivo than their wild type counterparts at the expense of DCs. Retroviral expression of IRF-8 in multiple progenitors led to reduced neutrophil production and increased numbers of DCs, even in the granulocyte-macrophage progenitor (GMP), which does not normally possess conventional DC potential. These data suggest that IRF-8 represses a neutrophil module of development and promotes convergent DC development from multiple lymphoid and myeloid progenitors autonomously of cellular context. CMP (Lineage-c-kithiSca-1-CD11c- CD34+ Flk2+CD16/32-CD115- ) or ALP (Lin-Ly6D-B220-c-kit+Flk2+IL7R?+) were double sorted from the bone marrow of wild type C57BL/6 mice. RNA was extracted from 2,000-15,000 sorted cells using Qiagen RNeasy Mini kit, amplified using Nugen pico-amplification kit , and 750 ng of aRNA was hybridized to Illumina MouseRef-8 v 2.0 bead chips Amy,M,Becker

Project description:In the traditional model of hematopoiesis, blood lineages diversify from HSCs through a sequential process of hierarchical bifurcation. Each of these bifurcation nodes comprises multipotent progenitors that are assumed to be homogeneous and equipotent in terms of their potency. The isolation of dendritic cell (DC) progenitors with either myeloid or lymphoid potency has led to the notion of “convergent development”, and an ongoing debate on the origin of DCs and their relationship with myeloid and lymphoid lineages. We have used a clonal assay combining with statistical modeling to quantify the yield of granulocytes (G), monocytes (M), lymphocytes (L) and three subsets of DCs from single human CD34+ progenitor cells of nine different phenotypes, and traced the potency of their individual progeny. We show that multipotent progenitors are not in fact equipotent, but instead exhibit a bias toward one specific lineage; this lineage bias is established at the HSC stage and transmitted to most progeny, with bifurcation to other lineages only occurring infrequently. Critically, these lineage biases can be correlated to lineage-specific transcriptional programs that are reinforced during division. We performed computational analysis to correlate transcriptomes and lineage composition of individual phenotype-defined progenitor cells. This enabled us to identify 32 common transcription factor (TF) candidates that interact physically and form genetic regulatory networks, with lineage-specific developmental programs initiated and reinforced based on the distinct dosage combination of these common TFs. Our analysis reveals that early expression of high levels of IRF8 and intermediate levels of PU.1 protein correlates with a bias towards CD141+ DC and plasmacytoid DC lineages in vivo, and that this pattern is inheritable from progenitors to mature cells. We have therefore arrived at a coherent model of DC development driven by parallel and inheritable programs defined by distinct dosages of TFs including PU.1 and IRF8, a developmental model that may apply to other lineages as well.

Project description:The transcription factors Batf3 and IRF8 are required for development of CD8α+ conventional dendritic cells (cDCs), but the basis for their actions was unclear. Here, we identify two novel Zbtb46+ progenitors that separately generate CD8α+ and CD4+ cDCs and arise directly from the common DC progenitor (CDP). Irf8 expression in the CDP depends on prior PU.1-dependent autoactivation, and specification of pre-CD8 DC progenitors requires IRF8 but not Batf3. However, upon pre-CD8 DC specification, Irf8 autoactivation becomes Batf3-dependent at a CD8α+ cDC-specific enhancer containing multiple AP1-IRF composite elements (AICEs) within the Irf8 superenhancer. CDPs from Batf3-/- mice that specify toward pre-CD8 DCs fail to complete CD8α+ cDC development due to decay of Irf8 autoactivation, and divert to the CD4+ cDC lineage.

Project description:Dendritic cells (DCs) are key immune modulators, and are able to mount immune responses or tolerance. DC differentiation and activation imply a plethora of molecular and cellular responses, including transcriptional changes. PU.1 is a highly expressed transcription factor in DCs, and coordinates relevant aspects of DC biology. Due to their role as immune regulators, DCs pose as a promising immunotherapy tool. However, some of their functional features, such as survival, activation or migration, are compromised due to the limitations to simulate in vitro the physiological DC differentiation process. A better knowledge of transcriptional programs would allow the identification of potential targets for manipulation with the aim of obtaining “qualified” DCs for immunotherapy purposes. Most of the current knowledge regarding DC biology derives from studies using mouse models, which not always find a parallel in human. In the present study we dissect the PU.1 transcriptional regulome and interactome in mouse and human DCs, in the steady state (ST) or LPS-activated. The PU.1 transcriptional regulome was identified by performing PU.1 chromatin immunoprecipitation followed by high throughput sequencing, and pairing these data with RNA-sequencing data. The PU.1 interactome was identified by performing PU.1 immunoprecipitation followed by mass spectrometry analysis. Our results portray PU.1 as a pivotal factor that plays an important role in the regulation of genes required for proper DC activation and function, and assures the repression of non-lineage genes. The interspecies differences between human and mouse DCs are surprisingly substantial, highlighting the need to study the biology of human DCs.

Project description:Dendritic cells (DCs) are critical immune regulators involved in autoimmune diseases, but exploiting them clinically requires a detailed picture on the mechanisms orchestrating their development. DNA methylation is attractive in this regard because it is reversible and as such allows therapeutic manipulation. Combining single cell transplantation assays with whole-genome methylation assessment and with mice expressing reduced DNA methyltransferase 1 levels, we show that conventional and plasmacytoid DCs arise from myeloid-restricted hematopoietic stem cells (HSCs), suggesting that both subsets can develop independently of the lymphoid pathway. DC commitment by these HSCs requires an intrinsically high methylation threshold to establish expression of DC genes, particularly the Flt3 cytokine receptor. Reducing methylation depleted DCs and ameliorated systemic lupus erythematosus in mice. These studies shed novel light on the DC origin, show how lineage- and subset-specific methylation dynamics regulate DC fate and provide a potential rationale for targeting DCs in autoimmunity by hypomethylating agents.

Project description:Transcriptional profiling of mouse comparing in vitro-derived DC progenitors from control and Gata2 conditional knockout mice. Two-condition experiment, Control DCs vs. G2 Knockout DCs. Biological replicates: 4 control, 3 Gata2 knockout, independently grown and harvested. One replicate per array. Dendritic cells (DCs) are critical immune response regulators; however, the mechanism of DC differentiation is not fully understood. Heterozygous germline GATA2 mutations induce GATA2 deficiency syndrome, characterized by monocytopenia, a predisposition to myelodysplasia/acute myeloid leukemia, and a profoundly reduced DC population, which is associated with increased susceptibility to viral infections, impaired phagocytosis, and decreased cytokine production. To define the role of GATA2 in DC differentiation and function, we studied Gata2 conditional knockout and haploinsufficient mice. Gata2 conditional deficiency significantly reduced the DC count, whereas Gata2 haploinsufficiency did not affect this population. GATA2 was required for the in vitro generation of DCs from Linâ??Sca-1+Kit+ cells, common myeloid-restricted progenitors, and common dendritic cell precursors, but not common lymphoid-restricted progenitors or granulocyte-macrophage progenitors, suggesting that GATA2 functions in the myeloid pathway of DC differentiation. Moreover, expression profiling demonstrated reduced expression of myeloid-related genes, including mafb, and increased expression of T-lymphocyte-related genes, including Gata3 and Tcf7, in Gata2-deficient DC progenitors. In addition, GATA2 was found to bind an enhancer element 190-kb downstream region of Gata3, and a reporter assay exhibited significantly reduced luciferase activity after adding this enhancer region to the Gata3 promoter, which was recovered by GATA sequence deletion within Gata3 +190. These results suggest that GATA2 plays an important role in cell fate specification toward the myeloid versus T lymphocyte lineage by regulating lineage-specific transcription factors in DC progenitors, thereby contributing to DC differentiation.