Project description:A critical problem in biology is understanding how cells choose between self-renewal and differentiation. To generate a comprehensive view of the mechanisms controlling early hematopoietic precursor self-renewal and differentiation, we used systems-based approaches and murine EML multipotential hematopoietic precursor cells as a primary model. EML cells give rise to a mixture of self-renewing Lin-SCA+CD34+ cells and partially differentiated non-renewing Lin-SCA-CD34- cells in a cell autonomous fashion. We identified and validated the HMG box protein TCF7 as a key regulator in this self-renewal/differentiation switch, and it operates in the absence of canonical Wnt signaling. We found that TCF7 is the most downregulated transcription factor when CD34+ cells switch into CD34- cells using RNA-Seq. We subsequently identified the target genes bound by TCF7 using ChIP-Seq. We show that TCF7 binds to Runx1 (Aml1) promoter region, and RUNX1 and TCF7 co-regulate. Gene Set Enrichment Analysis suggests that TCF7 primarily acts as a positive regulator of genes preferentially expressed in CD34+ cells. Consistent with this possibility, knocking-down TCF7 represses many up-regulated genes in Lin-CD34+ cells. Finally a network of up-regulated transcription factors of CD34+ cells which defines the self-renewing state was constructed. These studies in EML cells demonstrate fundamental cell-intrinsic properties of the switch between self-renewal and differentiation, and yield valuable insights for manipulating HSCs and other differentiating systems. Examining the transcription factor binding targets of TCF7 and RUNX1.

Project description:A critical problem in biology is understanding how cells choose between self-renewal and differentiation. To generate a comprehensive view of the mechanisms controlling early hematopoietic precursor self-renewal and differentiation, we used systems-based approaches and murine EML multipotential hematopoietic precursor cells as a primary model. EML cells give rise to a mixture of self-renewing Lin-SCA+CD34+ cells and partially differentiated non-renewing Lin-SCA-CD34- cells in a cell autonomous fashion. We identified and validated the HMG box protein TCF7 as a key regulator in this self-renewal/differentiation switch, and it operates in the absence of canonical Wnt signaling. We found that TCF7 is the most downregulated transcription factor when CD34+ cells switch into CD34- cells using RNA-Seq. We subsequently identified the target genes bound by TCF7 using ChIP-Seq. We show that TCF7 binds to Runx1 (Aml1) promoter region, and RUNX1 and TCF7 co-regulate. Gene Set Enrichment Analysis suggests that TCF7 primarily acts as a positive regulator of genes preferentially expressed in CD34+ cells. Consistent with this possibility, knocking-down TCF7 represses many up-regulated genes in Lin-CD34+ cells. Finally a network of up-regulated transcription factors of CD34+ cells which defines the self-renewing state was constructed. These studies in EML cells demonstrate fundamental cell-intrinsic properties of the switch between self-renewal and differentiation, and yield valuable insights for manipulating HSCs and other differentiating systems.

Project description:A critical problem in biology is understanding how cells choose between self-renewal and differentiation. To generate a comprehensive view of the mechanisms controlling early hematopoietic precursor self-renewal and differentiation, we used systems-based approaches and murine EML multipotential hematopoietic precursor cells as a primary model. EML cells give rise to a mixture of self-renewing Lin-SCA+CD34+ cells and partially differentiated non-renewing Lin-SCA-CD34- cells in a cell autonomous fashion. We identified and validated the HMG box protein TCF7 as a key regulator in this self-renewal/differentiation switch, and it operates in the absence of canonical Wnt signaling. We found that TCF7 is the most downregulated transcription factor when CD34+ cells switch into CD34- cells using RNA-Seq. We subsequently identified the target genes bound by TCF7 using ChIP-Seq. We show that TCF7 binds to Runx1 (Aml1) promoter region, and RUNX1 and TCF7 co-regulate. Gene Set Enrichment Analysis suggests that TCF7 primarily acts as a positive regulator of genes preferentially expressed in CD34+ cells. Consistent with this possibility, knocking-down TCF7 represses many up-regulated genes in Lin-CD34+ cells. Finally a network of up-regulated transcription factors of CD34+ cells which defines the self-renewing state was constructed. These studies in EML cells demonstrate fundamental cell-intrinsic properties of the switch between self-renewal and differentiation, and yield valuable insights for manipulating HSCs and other differentiating systems.

Project description:Enforced expression of the homeobox transcription factor HOXB4 has been shown to enhance hematopoietic stem cell (HSC) self-renewal and expansion ex vivo and in vivo. In order to investigate the largely unknown downstream targets of HOXB4 in hematopoietic progenitor cells, HOXB4 was constitutively overexpressed in the primitive hematopoietic progenitor cell line, EML. Gene expression differences were compared between KLS (c-Kit+, Lin-, Sca-1+)-EML cells that overexpressed HOXB4 (KLS-EML-HOXB4) to control KLS-EML cells that were transduced with vector alone. ChIP-chip was used to identify promoter regions bound by HOXB4. We overexpressed HOXB4 in EML cells. We isolated 3 separate single cell clones as assessed by Southern Blot Analysis (3 clones for EML-HOXB4 and 3 clones for control EML-GFP cells). RNA was isolated from the KLS (c-Kit+, Lin-, Sca-1+) fraction of each single cell clone population and processed for hybridization to array chips using established lab protocols. Chip-Chip analysis of the three HOXB4 overexpressing clones was performed to identify HOXB4 bound promoters.

Project description:Fractionation of EML cells isolated based on surface expression of immunophenotypic markers reveals the existence of a subpopulation that has undergone spontaneous commitment to an erythroid fate. Uncommitted fractions were compared to committed cells, derived from both spontaneous (EryCP) and cytokine-driven (Ediff) commitment. EML cells were separated by flow cytometry based on their expression of the markers Sca1, CD34 and cKit as described.

Project description:We sequenced mRNA from mouse EML cell line under Kai1 knockdown or Kai1 overexpressing condition. KAI1 belongs to tetraspanin superfamily and is known as suppressor of tumor metastasis. Examination of mRNA levels in wildtype (WT) and KAI1 knockdown EML cells were generated by deep sequencing, in duplicate, using Illumina GAIIx. Examination of mRNA levels in wildtype (WT) and KAI1 overexpressing EML cells were also generated in single set.

Project description:We used microarrays to examine the impact of AF1q/MLLT11 on the gene expression profile of CD34+CD45RA-Lin- and CD34+CD45RA+Lin- HPCs isolated from umbilical cord blood CD34+CD45RA-Lin- and CD34+CD45RA+Lin- HPCs correspond respectively to early multipotent and lympho-granulo-macrophagic precursors. A2M is a nuclear mutant-derivative of AF1q/MLLT11 CD34+CD45RA-Lin- and CD34+CD45RA+Lin- HPCs were FACS-sorted, exposed to A2M or control vectors, sorted based on GFP expression, and subjected to global gene expression analysis 72 hrs later.

Project description:ASXL1 is the obligate regulatory subunit of a deubiquitinase complex whose catalytic subunit is BAP1. Heterozygous mutations of ASXL1 that result in premature truncations are frequent in myeloid leukemias and Bohring-Opitz syndrome. Here, we demonstrate that truncated ASXL1 proteins confer enhanced activity on the ASXL1-BAP1 complex. Stable expression of truncated, hyperactive ASXL1-BAP1 complexes in a hematopoietic precursor cell line resulted in global erasure of H2AK119Ub, striking depletion of H3K27me3, selective upregulation of a subset of genes whose promoters bore both H2AK119Ub and H3K4me3, and spontaneous differentiation to the mast cell lineage. These outcomes required the catalytic activity of BAP1, indicating these events were downstream consequences of H2AK119Ub erasure. In bone marrow precursors, truncated ASXL1-BAP1 expression cooperated with TET2 loss-of-function to increase differentiation to the myeloid lineage in vivo. We propose that pathological ASXL1 mutations confer gain-of-function on the ASXL-BAP1 complex. ChIP-Seq for H2AK119Ub, H3K4me3, H3K27me3 on EML cells. RNA-Seq on EML cells expressing ASXL1(1-479)+BAP1 and control.

Project description:Most adult patients have a D816V mutation in phosphotransferase domain (PTD), we have described that half of the children carry mutations in extracellular domain (ECD). KIT-ECD versus IT-PTD-mutants were introduced into rodent Ba/F3, EML, Rat2 and human TF1 cells to investigate their biological effect. ECD- and PTD-mutants also displayed distinct whole-genome transcriptional profiles in EML cells. We observed differences in their signaling properties: they both activated STAT pathways, whereas AKT pathway was only activated by ECD-mutants. Consistently, AKT inhibitor suppressed ECD-mutant-dependent proliferation, clonogenicity and erythroid differentiation. Expression of myristoylated AKT restored erythroid differentiation in EMLPTD cells, suggesting the differential role of AKT in those mutants. Overall, our study implied different pathogenesis of pediatric versus adult mastocytosis, which might explain their diverse phenotypes. Each EML cell line (Del417-419insY mutant and D816V mutant) was cultured with or without 250 ng/mL SCF for 48h. Gene expression profile analysis was performed using whole-genome microarrays. RNA expression profiling of cell lines was done with Affymetrix M430 2.0 mouse oligonucleotide microarrays containing 45.101 probe sets, representing 21.408 transcripts and variants including 17.482 well-characterized mouse genes. Preparation of cRNA, hybridizations, washes, detection and quantification were done as recommended by the supplier. For each sample, synthesis of the first-strand cDNA was done from 3 μg total RNA by T7-oligo(dT) priming, followed by second-strand cDNA synthesis. After purification, in vitro transcription associated with amplification generated cRNA-containing biotinylated pseudouridine. Biotinylated cRNA was purified, quantified and chemically fragmented (95°C for 35 min), then hybridized to microarrays in 200 μL hybridization buffer at 45°C for 16 h. Automated washes and staining with streptavidin-phycoerythrin were done as recommended. Signal amplification was done by biotinylated antistreptavidin antibody with goat-IgG blocking antibody. Scanning was done with Affymetrix GeneArray scanner and quantification with Affymetrix GCOS software.

Project description:We applied a novel approach of parallel transcriptional analysis of multiple, highly fractionated stem and progenitor populations from patients with acute myeloid leukemia (AML) and a normal karyotype. We isolated phenotypic long-term HSC (LT-HSC), short-term HSC (ST-HSC), and committed granulocyte-monocyte progenitors (GMP) from individual patients, and measured gene expression profiles of each population, and in comparison to their phenotypic counterparts from age-matched healthy controls. Bone marrow samples from AML patients with normal karyotype and age-matched healthy controls were used in this study. Hematopoietic stem and progenitor compartments were purified by multiparameter-high speed fluorescence-activated cell sorting (FACS) from CD34+ enriched bone marrow to isolate LT-HSC (Lin-/CD34+/CD38-/CD90+), ST-HSC (Lin-/CD34+/CD38-/CD90-), and GMP (Lin-/CD34+/CD38+/CD123+/CD45R+).