Project description:Analysis of gene signatures in WT+Ctrl vs WT+ETV6-RUNX1, Btg1-/- and Btg1-/-+ETV6-RUNX1 in cKit+Ter119- fetal liver-derived hematopoietic progenitor cells (FL-HPCs). The Btg1-/-+ETV6-RUNX1 FL-HPCs display a strong increase in proliferation compared to WT+ETV6-RUNX1. Total RNA otained from WT+Ctrl, WT+ETV6-RUNX1, Btg1-/-+Ctrl and Btg1-/-+ETV6-RUNX1 FL-HPCs cells that were cultured for 12 days in expansion medium.

Project description:Analysis of gene signatures in WT+Ctrl vs WT+ETV6-RUNX1, Btg1-/- and Btg1-/-+ETV6-RUNX1 in cKit+Ter119- fetal liver-derived hematopoietic progenitor cells (FL-HPCs). The Btg1-/-+ETV6-RUNX1 FL-HPCs display a strong increase in proliferation compared to WT+ETV6-RUNX1.

Project description:The Core Binding Factor (CBF) protein RUNX1 is a master regulator of definitive hematopoiesis, crucial for hematopoietic stem cell (HSC) emergence during ontogeny, which also plays vital roles in adult mice, in regulating the correct specification of numerous blood lineages. Akin to the other mammalian Runx genes, Runx1 has two promoters P1 (distal) and P2 (proximal) which generate distinct protein isoforms. The activities and specific relevance of these two promoters in adult hematopoiesis remain to be fully elucidated. Utilizing a dual reporter model we demonstrate here that the distal P1 promoter is broadly active in adult hematopoietic stem and progenitor cell (HSPC) populations. By contrast the activity of the proximal P2 promoter is more restricted and its upregulation, in both the immature Lineage- Sca1high cKithigh (LSK) and bipotential Pre-Megakaryocytic/Erythroid Progenitor (PreMegE) populations, coincides with a loss of erythroid specification. Accordingly the PreMegE population can be prospectively separated into “pro-erythroid” and “pro-megakaryocyte” populations based on Runx1 P2 activity. Comparative gene expression analyses between Runx1 P2+ and P2- populations indicated that the level of CD34 expression could substitute for P2 activity to distinguish these two cell populations in wild type (WT) bone marrow (BM). Prospective isolation of these two populations will provide the opportunity to further investigate and define the molecular mechanisms involved in megakaryocytic/erythroid (Mk/Ery) cell fate decisions. mRNA profiles of wild type (WT), Runx1 P2-hCD4+ (P2+) and Runx1 P2-hCD4- (P2-) Bone marrow Pre-Megakryocyte/Erythroid (PreMegE) progenitors were generated from young adult (12-16 weeks) mice by deep sequencing, in triplicate, using Illumina NextSeq 500.

Project description:The Core Binding Factor (CBF) protein RUNX1 is a master regulator of definitive hematopoiesis, crucial for hematopoietic stem cell (HSC) emergence during ontogeny, which also plays vital roles in adult mice, in regulating the correct specification of numerous blood lineages. Akin to the other mammalian Runx genes, Runx1 has two promoters P1 (distal) and P2 (proximal) which generate distinct protein isoforms. The activities and specific relevance of these two promoters in adult hematopoiesis remain to be fully elucidated. Utilizing a dual reporter model, we demonstrate here that the distal P1 promoter is broadly active in adult hematopoietic stem and progenitor cell (HSPC) populations. By contrast, the activity of the proximal P2 promoter is more restricted and its upregulation, in both the immature Lineage- Sca1high cKithigh (LSK) and bipotential Pre-Megakaryocytic/Erythroid Progenitor (PreMegE) populations, coincides with a loss of erythroid specification. Accordingly, the PreMegE population can be prospectively separated into "pro-erythroid" and "pro-megakaryocyte" populations based on Runx1 P2 activity. Comparative gene expression analyses between Runx1 P2+ and P2- populations indicated that the level of CD34 expression could substitute for P2 activity to distinguish these two cell populations in wild type (WT) bone marrow (BM). Prospective isolation of these two populations will provide the opportunity to further investigate and define the molecular mechanisms involved in megakaryocytic/erythroid (Mk/Ery) cell fate decisions. Moreover, comparison of a RUNX1C null (KO) PreMegE to its WT counterpart demonstrated considerably enhanced erythroid specification at the expense of megakaryopoiesis in the absence of P1-specified RUNX1C expression.

Project description:We have performed circular chromosome conformation capture sequencing (4C-seq) with six baits located at the Runx1 locus in the mouse hematopoietic progenitor cell line HPC-7. 4C baits were designed to the P1 and P2 promoters and to the previously characterised +24 hematopoietic enhancer (P1, P2 and 24), with secondary baits located at nearby cohesin/CTCF (cc) binding sites (P1cc, 24cc, P2cc).

Project description:Background: Down syndrome (DS) is associated with a wide range of phenotypes. To address the hypothesis that the genome-wide perturbation of gene regulation in DS is modulated by epigenetic changes, we performed an epigenome-wide association study (EWAS) on neonatal bloodspots comparing 196 newborns with DS and 439 newborns without DS. Results: We identified 652 epigenome-wide significant CpGs (P<7.67x10-8) and 1,052 differentially methylated regions (DMRs) across the genome. Differential methylation at promoters/enhancers correlated with gene expression changes in DS versus non-DS fetal liver hematopoietic stem/progenitor cells (HSPC) (P<0.0001). Two of the top 3 DS-associated CpGs overlapped RUNX1, and were highly significantly hypermethylated in DS newborns (P<1.0x10-21). The top two DMRs overlapped promoters of RUNX1 and FLI1, both important regulators of megakaryopoiesis. FLI1 expression was markedly reduced in DS fetal liver HSCs (P<0.0001) and myeloid progenitors (P<0.0001). By contrast, RUNX1 expression was increased in DS fetal liver myeloid progenitors (P<0.0001), consistent with selective hypermethylation of the RUNX1 P2 promoter, which dominates in embryonic development, but sparing the P1 promoter that drives definitive hematopoiesis. Targeted sequencing of GATA1 revealed somatic, preleukemic mutations in 16.3% DS newborns, consistent with the high frequency of these mutations in DS newborns. Removal of DS newborns with GATA1 mutations had minimal impact on the EWAS results. Conclusions: DS has profound, genome-wide effects on DNA methylation in hematopoietic cells in early life, which may contribute to the high frequency of hematological problems, including leukemia, in children with DS. Blood-detectable DS-related epigenetic changes may underlie an array of DS outcomes, including neurologic and immune-related morbidities.

Project description:Disrupting mutations of the RUNX1 gene are found in 10% of patients with myelodysplasia (MDS) and 30% of patients with acute myeloid leukemia (AML). Previous studies have revealed an increase in hematopoietic stem cells (HSCs) and multipotent progenitor (MPP) cells in conditional Runx1-knockout (KO) mice, but the molecular mechanism is unresolved. We investigated the myeloid progenitor (MP) compartment in KO mice, arguing that disruptions at the HSC/MPP level may be amplified in downstream cells. We demonstrate that the MP compartment is increased more than fivefold in Runx1 KO mice, with a prominent skewing toward megakaryocyte (Meg) progenitors. Runx1- deficient granulocyte-macrophage progenitors are characterized by increased cloning capacity, impaired development into mature cells, and HSC and Meg transcription signatures. An HSC/MPP subpopulation expressing Meg markers was also increased in Runx1-deficient mice. Rescue experiments coupled with transcriptome analysis and Runx1 DNA-binding assays demonstrated that commitment is marked by Runx1 suppression of genes encoding adherence and motility proteins (Tek, Jam3, Plxnc1, Pcdh7, and Selp) that support HSC–Meg interactions with the BM niche. In vitro assays confirmed that enforced Tek expression in HSCs/MPPs increases Meg output. Interestingly, besides this key repressor function of Runx1 to control lineage decisions and cell numbers in progenitors, our study also revealed a critical activating function in erythroblast differentiation, in addition to its known importance in Meg and granulocyte/monocyte (G/M) maturation. Thus both repressor and activator functions of Runx1 at multiple hematopoietic stages and lineages likely contribute to the tumor suppressor activity in MDS and AML. GMP were isolated either from Runx1+/+-Tg(vav-Cre) and Runx1fl/fl-Tg(vav-Cre) mice or from mice transplanted with Runx1fl/fl-Tg(vav-Cre) progenitors engineered to express GFP with RUNX1-ERt2 or ERt2. RUNX1-ERt2 activity was induced by i.p. injection of tamoxifen on 3 consecutive days prior to GMP isolation.

Project description:Hepatocyte Nuclear Factor 4α (HNF4α), master regulator of hepatocyte differentiation, is regulated by two promoters (P1 and P2). P1-HNF4α but not P2-HNF4α is expressed in normal adult liver in fed conditions. Both P1- and P2-HNF4α are expressed in fetal liver. P2-HNF4α expression is increased in fasted conditions, high fat diet, alcoholic liver and liver cancer. To determine the target genes of the P1- and P2-HNF4α isoforms, we compared P2-HNF4α-expressing exon swap mice (a7HMZ) to wildtype (WT) male mice. Liver ChIP-seq samples were taken at 10:30 AM (ZT 3.5)

Project description:Hepatocyte Nuclear Factor 4α (HNF4α), master regulator of hepatocyte differentiation, is regulated by two promoters (P1 and P2). P1-HNF4α but not P2-HNF4α is expressed in normal adult liver while both P1- and P2-HNF4α are expressed in fetal liver and liver cancer. To determine the physiological function of the HNF4α isoforms, we compared P2-HNF4α-expressing exon swap mice to wildtype (WT) using RNA-seq, ChIP-seq, proteomics, protein binding microarrays (PBMs) and metabolomics. P2-HNF4α orchestrates a distinct transcriptomic and metabolomic profile.

Project description:MiRNAs have the potential to regulate cellular differentiation programs. However, miRNA-deficiency in primary hematopoietic stem cells (HSCs) results in HSC depletion in mice, leaving the question of whether miRNAs play a role in early-lineage decisions unanswered. To address this issue, we deleted Dicer1, which encodes an essential RNaseIII enzyme for miRNA biogenesis, in murine CCAAT/enhancer-binding protein alpha (C/EBPA)-positive myeloid-committed progenitors in vivo. In contrast to the results in HSCs, we found that miRNA depletion affected neither the number of myeloid progenitors nor the percentage of C/EBPA-positive progenitor cells. Analysis of gene-expression profiles from wild type and Dicer1-deficient granulocyte-macrophage progenitors (GMPs) revealed that 20 miRNA families were active in GMPs. Of the derepressed miRNA targets in Dicer1-null GMPs, 27% are normally exclusively expressed in HSCs or are specific for multi-potent progenitors and erythropoiesis, indicating an altered gene-expression landscape. Dicer1-deficient GMPs were defective in myeloid development in vitro and exhibited an increased replating capacity, indicating a regained self-renewal potential of these cells. In mice, Dicer1 deletion blocked monocytic differentiation, depleted macrophages and caused myeloid dysplasia with morphological features of Pelger-Huët anomaly. These results provide evidence for a miRNA-controlled switch for a cellular program of self-renewal and expansion towards myeloid differentiation in GMPs. To generate Cebpa-Cre;R26-LSL-Eyfp;Dicer1wt/fl/Dicer1fl/fl mice, we crossed mice that contain floxed Dicer1 alleles (Dicer1fl) with Cebpa-Cre;R26-LSL-Eyfp reporter mice 2. Fetal livers were obtained on embryonic day (E) 13.5. Routine genotyping of Dicer1; Cebpa-Cre;R26-LSL-Eyfp mice was performed by PCR assays of DNA from tail or toe biopsies. For transplantation, 6 to 8-week-old recipient mice (C57Bl/6, Jackson Laboratories) were irradiated (8.5 Gy) and tail-vein injected with fetal liver single-cell suspensions. Typically, cells from each fetal liver were transplanted into two recipient mice. Hematopoietic tissues were analyzed 6-10 weeks post transplantation. EYFP positive GMPs from the bone marrow of Dicer wt control (n=3), Dicer -/wt (n=3 and Dicer fl/fl (n=3) were sorted and analyzed for gene expression profiles.