Project description:Genome-scale studies have revealed extensive co-localization of transcription factors in a given cell type as well as substantial differences in the binding patterns of specific transcription factors between cell types. Several mechanisms have been proposed to explain these observations, including targeting of transcription factors to accessible chromatin marked by lysine 4-monomethylated histone H3 (H3K4me1) and interactions between transcription factors that enable nucleosome displacement. Here we demonstrate that collaborative interactions of PU.1 with small sets of macrophage- or B cell-lineage-determining transcription factors establish common and cell-specific binding sites that are associated with the majority of promoter-distal H3K4me1-marked genomic regions in macrophages and B cells, respectively. PU.1 binding initiates nucleosome remodeling followed by H3K4 monomethylation at large numbers of genomic regions associated with both broadly and specifically expressed genes. These sites are representative of locations that serve as beacons for additional factors, exemplified by liver X receptors, which drive both cell-specific gene expression and signal-dependent responses. In concert with analysis of transcription factor binding and H3K4me1 patterns in other cell types, these studies suggest that simple combinations of lineage-determining transcription factors can specify the genomic sites ultimately responsible for both cell identity and cell type-specific responses to diverse signaling inputs. ChIP-Seq and gene expression profiling was performed in macrophages, B cells, and a variety of genetically modified primary cells and cell lines approximating developmental stages of macrophage and B cell development.

Project description:PU.1 is a key transcription factor for macrophage differentiation. Novel PU.1 target genes were identified by mRNA profiling of PU.1-deficient progenitor cells (PUER) before and after PU.1 activation. We used two different types of Affymetrix DNA-microarrays (430 2.0 arrays and ST 1.0 exon arrays) to characterize the global PU.1-regulated transcriptional program underlying the early processes of macrophage differentiation. Keywords: time course Uninduced and 24h 4-hydroxy-tamoxifen (OHT) induced PUER cells were cultured before RNA extraction and hybridization on Affymetrix Mouse Genome 430 2.0 and Mouse Exon ST 1.0 microarrays. Triplicates before (0h) and after (24h) induction of PU.1 were analyzed.

Project description:We have shown that β-catenin overexpression induced blockage of monocyte-macrophage differentiation by inhibiting PU.1-targeted gene transcription including Egr2 expression in myeloid progenitor cells. Our results suggest that compromised PU.1-targeted gene transcription induced by β-catenin overexpression, at least partially, may mediate a pathogenic role of β-catenin in myeloid leukemia. PUER cells were infected with retrovirus expressing beta-catenin-S33Y or control vector MIGR1. Five days after infection, the GFP positive cells were sorted by flow cytometry, and were treated with 4-OHT to induce the expression of PU.1. Total RNA was exacted from cell samples and purified by RNeasy Micro kit (Qiagen). cRNAs were generated and hybridized to the mouse whole genome 4×44K arrays according to manufacturer’s instructions (Agilent Technologies).

Project description:To understand better the mechanisms controlling the balance between proliferation and and differentiation during myelopoiesis we have utilized teh bi-potent FDB1 myeloid cell line which differentiates to granulocytes and macrophages in response to GM-CSF and thus provides a dissectable model to analyse the switch between growth and differentiation. This was further studied using this cell line in which a second site mutation Y577F had been generated. A factorial time-course design between the two cell lines and over time, combined with linear modelling and geneset enrichment analysis identified the expression changes associated with the switch between granulocyte differentiation and macrophage differentiation. We observed that a single intracellular tyrosine residue (Tyr577) mediates the granulocyte fate decision. The loss of granulocyte differentiation and enhanced macrophage differentiation observed in this second site mutant is associated with accumulation of Beta-Catenin and activation of Tcf4 and other Wnt Target genes. Factorial design. First Factor was cell type with levels FDB1 expressing FI-Delta receptor mutant and FDB1 expressing FI-Delta Y577F receptor mutant. Second factor is time with levels 0 and 72 hours. Two biological replicates wre prepared for each cell line and comparions were perfomed for each cell line and directly between cell lines at 0 and 72hs. Additional dye swaps were done with FI Delta and FIDelta Y577F at 0h and the FI Delta 0-72h comparison.

Project description:The nuclear receptor Peroxisome Proliferator Activator Receptor (PPAR ) is the target of antidiabetic thiazolidinedione drugs, which improve insulin resistance but have side-effects that limit widespread use. PPAR is required for adipocyte differentiation, but is also expressed in other cell types, notably macrophages, where it influences atherosclerosis, insulin resistance, and inflammation. A central question is whether PPAR binding in macrophages occurs at the same or different genomic locations compared to adipocytes. Here, utilizing chromatin immunoprecipitation and high throughput sequencing (ChIP-seq), we demonstrate that PPAR cistromes in adipocytes and macrophages are predominantly cell type specific. In macrophages, PPAR colocalizes with the hematopoietic transcription factor PU.1 in areas of open chromatin and histone acetylation, near a distinct set of immune genes in addition to a number of metabolic genes shared with adipocytes. In adipocytes, the macrophage-unique binding regions are marked with repressive histone modifications, typically associated with local chromatin compaction and gene silencing. PPAR , when introduced into cells that are neither macrophages nor adipocytes, bound only to regions depleted of repressive histone modifications, where it increased DNA accessibility, enhanced histone acetylation, and induced gene expression. Thus, the cell-specificity of PPAR function is regulated by cell-specific chromatin accessibility, histone marks, and transcription factors. Genomic occupancy profiled by high throughput sequencing (ChIP-seq) from mouse macrophages for PPARgamma, PU.1, C/EBPbeta, H3K9Ace; and from 3T3-L1 adipocytes for PPARgamma and H3K9Ace Masking file used to subtract input bias areas prior to generating final peak lists is linked below.

Project description:Analysis of alternative activation of macrophages at gene expression level. The study forms part of a wider study where we compare the effects of IL-4 in different human and mouse macrophages. Our results support the notion that in vitro culture conditions greatly affect the macrophage response to IL-4. Total RNA obtained from Thioglycollate and Biogel elicited peritoneal macrophages exposed to 20 ng/ml of IL-4 for 18 hours. Biogel and thioglycollate elicited macrophages were stimulated with the Th2 cytokine IL-4, for RNA extraction and hybridization on Affymetrix microarrays.

Project description:Despite major advances in the generation of genome-wide binding maps, the mechanisms by which transcription factors (TFs) regulate cell type identity have remained largely obscure. Through comparative analysis of 10 key haematopoietic TFs in both mast cells and blood progenitors, we demonstrate that the largely cell-type specific binding profiles are not opportunistic, but instead contribute to cell-type specific transcriptional control, because (1) mathematical modelling of differential binding of shared TFs can explain differential gene expression, (2) cell-type specific binding is largely mediated through consensus binding sites, and (3) knock-down of blood stem cell regulators Gata2 and Erg in mast cells reveals mast cell specific genes as direct targets. Finally we show that the known mast cell regulators Mitf and c-Fos likely contribute to the global reorganisation of TF binding profiles. Taken together therefore, our study elucidates how key regulatory TFs contribute to transcriptional programmes in several distinct mammalian cell types. Comparison of HPC7 cell line (haematopoietic multipotent progenitor) and primary mast cells. 10 key haematopoietic transcription factors and mRNA expression were profiled in both cell types.

Project description:This SuperSeries is composed of the following subset Series: GSE5099: Expression Data from Macrophage Maturation and Polarization Experiment GSE35433: Genome-wide analysis of human macrophages stimulated with IL-4 (20ng/ml) (Illumina) GSE35434: Genome-wide analysis of human macrophages stimulated with IL-4 (10ng/ml) (Illumina) GSE35435: Genome-wide analysis of mouse macrophages stimulated with IL-4 (bone marrow macrophages) (Affymetrix) GSE35436: Genome-wide analysis of mouse macrophages stimulated with IL-4 (Biogel and thioglycollate macrophages) (Affymetrix) Refer to individual Series

Project description:Transcription and pre-mRNA alternative splicing was analyzed by in isogenic human HEK293 cell lines that inducibly express a-amanitin resistant mutants of the RNA polymerase II large subunit with slow and fast elongation rates. Alternative splicing was analyzed by, RNA-seq and RASL-seq of polyA+ RNA from a-amanitin treated cells; transcription elongation rate was analyzed by BrUTP-labelled GRO-seq of a-amanitin treated cells at time points after release from a DRB (5,6-dichloro-1-bold beta-D-ribofuranosylbenzimidazole) block.

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series