Project description:MicroRNAs are small non-coding RNAs that regulate cellular development by interfering with mRNA stability and translation. We defined the kinetics of global microRNA expression during the differentiation of murine hematopoietic progenitors into megakaryocytes. Of 435 miRNAs analyzed, 13 were upregulated and 81 were downregulated. Many of these changes are consistent with miRNA profiling studies of human megakaryocytes and platelets, although new patterns also emerged. Among 7 conserved miRNAs that were upregulated most strongly in megakaryocytes, 6 were also induced in the related erythroid lineage. MiR-146a was strongly upregulated during mouse and human megakaryopoiesis, but not erythropoiesis. However, overexpression of miR-146a in mouse bone marrow hematopoietic progenitor populations produced no detectable alterations in megakaryocyte development or platelet production in vivo or in colony assays. Our findings extend the repertoire of differentially regulated miRNAs during murine megakaryopoiesis and provide a useful new dataset for hematopoiesis research. In addition, we show that enforced hematopoietic expression of miR-146a has minimal effects on megakaryopoiesis. These results are compatible with prior studies indicating that miR-146a inhibits megakaryocyte production indirectly by suppressing cytokine production from innate immune cells, but cast doubt on a different study, which suggests that this miRNA inhibits megakaryopoiesis cell-autonomously.

Project description:Embryonic stem (ES) and induced pluripotent stem (iPS) cells represent a potential source of megakaryocytes and platelets for transfusion therapies. However, most current ES/iPS cell differentiation protocols are limited by low yields of hematopoietic progeny. Mutations in the mouse and human genes encoding transcription factor GATA1 cause accumulation of proliferating, developmentally arrested megakaryocytes. To exploit this clinical observation, we engineered wildtype (WT) murine ES cells to express doxycycline (dox)-regulated Gata1 short hairpin (sh) RNAs. In vitro differentiation with dox and thrombopoietin (Tpo) resulted in approximately 1013-fold expansion of immature hematopoietic progenitors. Upon dox withdrawal with multilineage cytokines, GATA1 expression was restored and the cells differentiated into erythroblasts and megakaryocytes. With Tpo alone, dox-deprived progenitors formed mainly mature megakaryocytes that generated functional platelets in vivo. Our findings provide a novel, readily reproducible strategy to expand ES-cell derived megakaryocyte-erythroid progenitors and direct their differentiation into megakaryocytes producing functional platelets in clinically relevant numbers. 3 classes of samples were compared 1) fetal liver derived megkaryocytes 2) G1ME (Gata1– megakaryocyte-erythroid) 3) G1ME2 (engineered wildtype (WT) murine ES cells to express doxycycline (dox)-regulated Gata1 short hairpin (sh) RNAs)

Project description:Background: Children with Down syndrome (DS) are predisposed to acute megakaryoblastic leukemia (AMKL, or AML M7) and a related myeloid disorder, referred to as transient myeloproliferative disorder (TMD), or transient leukemia (TL). Recently, acquired mutations in the erythroid/megakaryocytic lineage-specific transcription factor GATA-1 have been identified in megakaryoblasts from virtually all DS patients with AMKL (DS-AMKL), as well as in nearly all DS neonates with TMD. These mutations prevent synthesis of full-length GATA-1, but lead to synthesis of a truncated GATA-1 protein (GATA-1s) that lacks the N-terminal transactivation domain. To determine the in vivo requirement of GATA-1 N-terminal domain in hematopoiesis and to model DS megakaryocytic leukemia initiated by GATA-1 mutation, we generated a GATA-1 knockin allele with a truncation at this domain (GATA-1deltaN). ES cells bearing this mutant allele generated a unique type of large Thrombopoietin (Tpo)-dependent megakaryocytes-containing colonies, when differentiated in vitro. Fetal livers from mice carrying this mutant allele contained elevated numbers of CD41+ cells throughout embryonic development, especially during mid-gestation. In in vitro hematopoietic colony assays, mutant cells from yolk sacs and mid-gestation fetal livers gave rise to a large number of macroscopic hyperproliferative megakaryocytic colonies (CFU-MKs). Consistent with that, when mutant fetal liver progenitors were cultured in liquid medium in the presence of Tpo, the derived megakaryocytes displayed marked hyperproliferation and grew for longer period of time than WTs. Specific aims: To understand the molecular basis for the megakaryocytic hyperproliferation phenotype of the GATA-1deltaN mutants, we plan to profile gene expression patterns of fetal liver-derived primary megakaryocytes and megakaryocytic progenitors from the GATA-1deltaN mutants and compare them with WTs, as well as GATA-1deltaNeodeltaHS mutants (GATA-1megakaryocytes). Experimental design: E12.5 fetal livers were harvested from either GATA-1 WT and mutant embryos. Single cell suspensions were made from these livers and the cells were cultured in liquid medium in the presence of Tpo for 3 days. On day 3, primary megakaryocytes were enriched by a BSA gradient, and further enriched by anti-CD41 antibody and magnetic microbeads. Megakaryocytic progenitors were collected by FACS sorting for small cells in the same culture that express low level of CD41. Total RNAs were then prepared from these two populations and submitted for microarray profiling. Conclusions: When examining genes that are normally upregulated upon megakaryocyte differentiation (many of this class are megakaryocyte-specific genes), we found in GATA-1deltaN megakaryocytes, the majority of these genes are upregulated, although not to the full extent as seen in WTs. In contrast, this class of genes is largely not upregulated in GATA-1deltaNeodeltaHS megakaryocytes, which are blocked at an immature stage of differentiation. Genes that are downregulated during megakaryocyte differentiation include those that are normally repressed by GATA-1. Among genes that are not properly downregulated in GATA-1deltaN megakaryocytes, five transcription factors (Myc, Myb, GATA-2, PU.1, Ikaros) are of particular interest. Inadequate GATA-1s-mediated repression of transcription factors required for proliferation of hematopoietic progenitors (Myc, Myb and GATA-2) and for specifying lineage choices other than megakaryocyte/erythrocyte (PU.1 and Ikaros) may contribute to hyperproliferation of GATA-1deltaN megakaryocytes.

Project description:Hematopoietic progenitor cells were isolated from 13.5 day mouse fetal livers by lineage depletion and expanded for three days. Fetal livers were isolated from both wild type and Gata-1 knock embryos. Gata-1 knock embryos contain a deletion of the Gata-1 promoter sequence that results in undetectable levels of Gata-1 protein specifically in the megakaryocyte lineage. Following progenitor outgrowth megakaryocytes were enriched in a differentiation media for three days and isolated on a discontinuous BSA gradient. The resulting megakaryocytes were >90% pure as determined by acetylcholinesterase staining. These cells were lysed in Trizol and the resulting RNA was used for hybridization.

Project description:We newly identified prospectively-isolatable unipotent megakaryocyte progenitor population (MegP) as the major source of megakaryocytes, which emerges directly from early stage of hematopoiesis bypassing megakaryocyte-erythroid lineage bifurcation and contributes to physiological and pathological human megakaryopoiesis. To explore gene expression signature of hematopoietic stem/progenitor populrations miroarry-based whole transcriptome analysis was performed. As a result, gene expression signature of MegP clearly reflected its differentiation potential.

Project description:Thioredoxin-interacting protein (TXNIP) is ubiquitously expressed in blood cells, including hematopoietic stem cells (HSCs), monocytes, and platelets. Here we report a novel finding that TXNIP plays a crucial role in megakaryopoiesis and platelet biogenesis via interacting with GATA1, a transcription factor for megakaryocyte-erythroid differentiation. Txnip-/- mice displayed immature megakaryocytes in the bone marrow with thrombocytopenia, which had gotten worse as the mice aged. Transcriptome analysis revealed that the transcriptional activity of GATA1 was significantly enhanced in the Txnip-/- megakaryocyte precursors (MkPs) than wild type (WT) cells. During megakaryopoiesis in ex vivo, Txnip-/- MkPs remained small in cell size with less mitochondrial mass, and more glycolysis for ATP production, as opposed to the normal megakaryocyte maturation. The effects of TXNIP in megakaryocytes were recapitulated in human cord blood CD34+ HSC-derived differentiation. Taken together, this study demonstrates the importance of spatiotemporal expression of TXNIP in platelet biogenesis. We propose for the first time that TXNIP might play a critical role in determining a lineage between megakaryocytes and erythroid cells from a common megakaryocyte-erythroid progenitor via regulation of transcriptional activity of GATA1.

Project description:This study aims to identify all genes expressed in primary mouse megakaryocytes Keywords: Megakaryocyte, SAGE, transcriptome analysis Mouse megakaryocytes were grown in vitro from bone marrow progenitors. Mature, polyploid (approximately 95% 64n and 128n) differentiated megakaryocytes were used to generate RNA for SAGE library construction.

Project description:During megakaryopoiesis and consecutive platelet production, megakaryocytes undergo robust cellular morphological changes which are associated with the reprogramming of signaling pathways. Moreover, it can be assumed that lipid membrane composition and signaling are strongly modified. However, the knowledge of lipid alteration during megakaryopoiesis and which pathways are involved is still lacking. Here, we use a lipid-centric multiomics approach to create a quantitative map of the megakaryocyte lipidome during maturation and proplatelet formation. Our data reveal that megakaryocyte differentiation is driven by an increased fatty acyl import and de novo lipid synthesis, resulting in the modulation towards an anionic membrane phenotype. This phenotype and the upregulation of diacylglycerols highly correlate with the activation of lipid-dependent kinases such as PKC and BTK. Using inhibitors of fatty acid import and phospholipid synthesis proved to block membrane remodeling and kinase activation and directly reduced proplatelet formation. Altogether, this study provides a framework for understanding how membrane lipid remodeling during megakaryocyte differentiation impacts kinase signaling and proplatelet formation while providing a knowledge base to exploit megakaryopoiesis.

Project description:The transcription factor cMyb plays a key role in human primary CD34+ hematopoietic progenitor cells (HPCs) lineage choice, by enhancing erythropoiesis at the expense of megakaryopoiesis. We previously demonstrated that cMyb affects erythroid versus megakaryocyte lineage decision in part by transactivating KLF1 and LMO2 expression. To further unravel the molecular mechanisms through which cmyb affects lineage fate decision, we profiled the miRNA and mRNA changes in myb-silenced CD34+ HPCs. mRNA and miRNA expression for each sample were profiled by Affymetrix GeneAtlas U219 strip array and Exiqon Human miRNome PCR Panel, respectively. miRNA/mRNA data were integrated by Ingenuity Pathway Analysis. The integrative analysis of miRNA/mRNA expression changes upon c-myb silencing in human CD34+ HPCs highlighted a set of 19 miRNA with 150 anticorrelated putative target mRNAs. Among the miRNAs downregulated in myb-silenced progenitors with the highest number of predicted target mRNAs, we selected hsa-miR-486-3p based on the in vitro effects of its overexpression on HPCs commitment. Indeed, morphological and flow cytometric analyses after liquid culture showed that hsa-miR-486-3p overexpression in HPCs enhanced erythroid and granulocyte differentiation while restraining megakaryocyte and macrophage differentiation. Moreover, collagen-based clonogenic assay demonstrated a strong impairement megakaryocyte commitment upon hsa-miR-486-3p overexpression in CD34+ cells. Gene expression profiling of hsa-miR-486-3p overexpressing CD34+ cells enabled us to identify a set of 8 genes downregulated and computationally predicted, putative hsa-miR-486-3p targets. Among them, we selected c-maf transcript as upregulated upon myb silencing. Worth of note, c-maf silencing in CD34+ progenitor cells was able to reverse the affects of myb silencing on erythroid versus megakaryocyte lineage choice. Integrative miRNA/mRNA analysis highlighted a set of miRNAs and anticorrelated putative target mRNAs modulated upon myb silencing, therefore potential players in myb-driven HPCs lineage choice. Among them, we demonstrated the hsa-miR-486-3p/c-maf pair as partially contributing to the effects of myb on HPCs commitment. Therefore, our data collectively identified myb-driven hsa-miR-486-3p upregulation and subsequent c-maf downregulation as a new molecular mechanism through which cMyb favours erythropoiesis while restraining megakaryopoiesis. RNA from CD34+ HPCs transfected with c-myb-targeting/non targeting control (NegCTR) synthetic siRNAs was collected 24 hours post-Nucleofection for a set of 5 independent experiments.

Project description:The transcription factor cMyb plays a key role in human primary CD34+ hematopoietic progenitor cells (HPCs) lineage choice, by enhancing erythropoiesis at the expense of megakaryopoiesis. We previously demonstrated that cMyb affects erythroid versus megakaryocyte lineage decision in part by transactivating KLF1 and LMO2 expression. To further unravel the molecular mechanisms through which cmyb affects lineage fate decision, we profiled the miRNA and mRNA changes in myb-silenced CD34+ HPCs. mRNA and miRNA expression for each sample were profiled by Affymetrix GeneAtlas U219 strip array and Exiqon Human miRNome PCR Panel, respectively. miRNA/mRNA data were integrated by Ingenuity Pathway Analysis. The integrative analysis of miRNA/mRNA expression changes upon c-myb silencing in human CD34+ HPCs highlighted a set of 19 miRNA with 150 anticorrelated putative target mRNAs. Among the miRNAs downregulated in myb-silenced progenitors with the highest number of predicted target mRNAs, we selected hsa-miR-486-3p based on the in vitro effects of its overexpression on HPCs commitment. Indeed, morphological and flow cytometric analyses after liquid culture showed that hsa-miR-486-3p overexpression in HPCs enhanced erythroid and granulocyte differentiation while restraining megakaryocyte and macrophage differentiation. Moreover, collagen-based clonogenic assay demonstrated a strong impairement megakaryocyte commitment upon hsa-miR-486-3p overexpression in CD34+ cells. Gene expression profiling of hsa-miR-486-3p overexpressing CD34+ cells enabled us to identify a set of 8 genes downregulated and computationally predicted, putative hsa-miR-486-3p targets. Among them, we selected c-maf transcript as upregulated upon myb silencing. Worth of note, c-maf silencing in CD34+ progenitor cells was able to reverse the affects of myb silencing on erythroid versus megakaryocyte lineage choice. Integrative miRNA/mRNA analysis highlighted a set of miRNAs and anticorrelated putative target mRNAs modulated upon myb silencing, therefore potential players in myb-driven HPCs lineage choice. Among them, we demonstrated the hsa-miR-486-3p/c-maf pair as partially contributing to the effects of myb on HPCs commitment. Therefore, our data collectively identified myb-driven hsa-miR-486-3p upregulation and subsequent c-maf downregulation as a new molecular mechanism through which cMyb favours erythropoiesis while restraining megakaryopoiesis. RNA from CD34+ HPCs transfected once/twice/3 times with c-myb-targeting/non targeting control siRNAs was collected for a set of 5 independent experiments.