Project description:Epigenetic modifications must underlie lineage-specific differentiation since terminally differentiated cells express tissue-specific genes, but their DNA sequence is unchanged. Hematopoiesis provides a well-defined model of progressive differentiation in which to study the role of epigenetic modifications in cell fate decisions. Multi-potent progenitors (MPPs) can differentiate into all blood cell lineages, while downstream progenitors commit to either myeloerythroid or lymphoid lineages. While DNA methylation is critical for myeloid versus lymphoid differentiation, as demonstrated by the myeloerythroid bias in Dnmt1 hypomorphs {Broske, 2009 #6}, a comprehensive DNA methylation map of hematopoietic progenitors, or of any cell lineage, does not exist. Here we have generated a mouse DNA methylation map, examining 4.6 million CpG sites throughout the genome including all CpG islands and shores, examining MPPs, all lymphoid progenitors (ALPs), common myeloid progenitors (CMPs), granulocyte/macrophage progenitors (GMPs), and thymocyte progenitors (DN1, DN2, DN3). Interestingly, differentiation towards the myeloid lineage corresponds with a net decrease in DNA methylation, while lymphoid commitment involves a net increase in DNA methylation, but both show substantial dynamic changes consistent with epigenetic plasticity during development. By comparing lineage-specific DNA methylation to gene expression array data, we find many examples of genes and pathways not previously known to be involved in lymphoid/myeloid differentiation, such as Gcnt2, Arl4c, Gadd45α, and Jdp2. Several transcription factors, including Meis1 and Prdm16 were methylated and silenced during differentiation, suggesting a role in maintaining an undifferentiated state. Additionally, epigenetic modification of modifiers of the epigenome appears to be important in hematopoietic differentiation. Our results directly demonstrate that modulation of DNA methylation occurs during lineage-specific differentiation, often correlating with gene expression changes, and define a comprehensive map of the methylation and transcriptional changes that accompany myeloid versus lymphoid fate decisions. mRNA expression of 8 hematopoietic progenitor populations [MPPFL-(5), MPPFL+(3), CMP(3), GMP(3), CLP(3), DN1(3), DN2(3), DN3(3)] were compared

Project description:Despite recent advances in the identification of lymphoid-restricted progenitors, the transcription factors essential for their generation remain to be identified. Here we describe an unexpected role for the myeloid oncogene Mef2c in multipotent progenitors (MPPs), where it is required for pan-lymphoid differentiation. Mef2c deficiency was associated with profound defects in B, T, NK cell and common lymphoid progenitor production and an enhanced myeloid output. Mef2c deficiency in MPPs leads to downregulation of several key lymphoid regulators and the upregulation of the myeloid factor C/EBPa. Our studies also show that Mef2c is a critical transcriptional target of PU.1 during lymphopoiesis. Thus, Mef2c is a crucial component of the transcriptional network that regulates lymphoid specification and cell fate choice in MPPs.

Project description:The commitment of hematopoietic stem cells and multipotent progenitors (MPPs) can be tuned to reprogram their differentiation capacity to be biased toward myeloid cells in response to an infection. Bach2, which inhibits myeloid differentiation in common lymphoid progenitors, repressed a cohort of genes of myeloid function (myeloid genes) and activated those for lymphoid function (lymphoid genes) in MPPs. In addition, Bach2 repressed both Cebpb and its target Csf1, encoding C/EBPβ and macrophage colony-stimulating factor (M-CSF), respectively, whereas C/EBPβ repressed Bach2 and activated the M-CSF receptor gene Csf1r. Bach2 and C/EBPβ bound to overlapping regulatory regions of their myeloid target genes, suggesting the presence of a gene regulatory network (GRN) with mutual repression and antagonistic, feed-forward regulation of myeloid genes. Lipopolysaccharide reduced the expression of Bach2, resulting in enhanced myeloid differentiation. Bach2 tunes the commitment of multipotent progenitors to myeloid and lymphoid lineages under both normal and infectious conditions.

Project description:Collombet2016 - Lymphoid and myeloid cell specification and transdifferentiation This model is described in the article: Logical modeling of lymphoid and myeloid cell specification and transdifferentiation Samuel Collombet, Chris van Oevelen, Jose Luis Sardina Ortega, Wassim Abou-Jaoudé, Bruno Di Stefano, Morgane Thomas-Chollier, Thomas Graf, and Denis Thieffry Proceedings of the National Academy of Sciences of the United States of America Abstract: Blood cells are derived from a common set of hematopoietic stem cells, which differentiate into more specific progenitors of the myeloid and lymphoid lineages, ultimately leading to differentiated cells. This developmental process is controlled by a complex regulatory network involving cytokines and their receptors, transcription factors, and chromatin remodelers. Using public data and data from our own molecular genetic experiments (quantitative PCR, Western blot, EMSA) or genome-wide assays (RNA-sequencing, ChIP-sequencing), we have assembled a comprehensive regulatory network encompassing the main transcription factors and signaling components involved in myeloid and lymphoid development. Focusing on B-cell and macrophage development, we defined a qualitative dynamical model recapitulating cytokine-induced differentiation of common progenitors, the effect of various reported gene knockdowns, and the reprogramming of pre-B cells into macrophages induced by the ectopic expression of specific transcription factors. The resulting network model can be used as a template for the integration of new hematopoietic differentiation and transdifferentiation data to foster our understanding of lymphoid/myeloid cell-fate decisions. This model is hosted on BioModels Database and identified by: MODEL1610240000. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:Mature lymphoid cells express the transcriptional repressor Bach2, which imposes regulation on humoral and cellular immunity. Here we found critical roles for Bach2 in the development of cells of the B lineage, commencing from the common lymphoid progenitor (CLP) stage, with Bach1 as an auxiliary. Overexpression of Bach2 in pre-pro-B cells deficient in the transcription factor EBF1 and single-cell analysis of CLPs revealed that Bach2 and Bach1 repressed the expression of genes important for myeloid cells (M-bM-^@M-^Xmyeloid genesM-bM-^@M-^Y). Bach2 and Bach1 bound to presumptive regulatory regions of the myeloid genes. Bach2hi CLPs showed resistance to myeloid differentiation even when cultured under myeloid conditions. Our results suggest that Bach2 functions with Bach1 and EBF1 to promote B cell development by repressing myeloid genes in CLPs. WT and Bach1 and Bach2 double deficient (DD) CLPs. Multipotent progenitors (MPPs) infected with control-GFP and Bach2-GFP and cultured several condition. Follicular B cells (Fo B) stimulated with IgM. Three expreriments was performed in this paper.

Project description:Hematopoietic stem cells and multipotent progenitors (MPPs) commitment can be tuned in response to an infection so that their differentiation is biased toward myeloid cells. Here we find that Bach2, which inhibits myeloid differentiation in common lymphoid progenitors, represses a cohort of myeloid genes and activates those linked to lymphoid function. Bach2 repressed both Cebpb and its target Csf1r, encoding C/EBPβ and macrophage colony-stimulating factor receptor (M-CSFr), respectively, whereas C/EBPβ repressed Bach2 and activated Csf1r. Bach2 and C/EBPβ further bound to overlapping regulatory regions at their myeloid target genes, suggesting the presence of a gene regulatory network (GRN) with mutual repression and antagonistic, feed-forward myeloid gene regulations. Lipopolysaccharide reduced the expression of Bach2, resulting in enhanced myeloid differentiation. The Bach2-C/EBPβ GRN pathway thus tunes MPP commitment to myeloid and lymphoid lineages under both normal conditions and after infection.  

Project description:DNA methylation is essential for mammalian development and plays crucial roles in a variety of biological processes. The DNA methyltransferase Dnmt1 serves to maintain parental cell methylation patterns on daughter DNA strands in mitotic cells, however, the precise role of Dnmt1 in regulation of quiescent adult stem cells is not known. To examine the role of Dnmt1 in adult hematopoietic stem cells (HSCs), we conditionally disrupted Dnmt1 in the hematopoietic system. We used microarrays to profile the global gene expression program in hematopoietic stem and progenitor cells following deletion of Dnmt1. Dnmt1 was conditionally deleted in the hematopoietic system by injections of poly(I)poly(C) to induce Cre expression from the Mx-Cre transgene. Control mice were also injected with poly(I)poly(C) but do not carry the Mx-Cre transgene. Four days after completion of poly(I)poly(C) injections, bone marrow was harvested from the mice, antibody-mediated magnetic bead selection was used to remove cells expressing mature lineage markers, and the resulting lineage-depleted cells were stained with fluorochrome-conjugated antibodies against the surface receptors c-Kit, Sca-1 and CD34. Populations of LT-HSCs, MPPs and myeloid progenitors were FACS sorted, RNA was extracted and amplified from these sorted populations and hybridized to Affymetrix microarrays to compare changes in gene expression induced by conditional knockout of Dnmt1 compared to control in each of the three cell populations. There are 2 biological replicates for the LT-HSCs and MPPs and 3 biological replicates for the myeloid progenitors.

Project description:Epigenetic mechanisms regulate the multilineage differentiation capacity of hematopoietic stem cells (HSCs) into a variety of blood and immune cells. Our recent work revealed evidence of multilineage gene priming in HSCs, where open cis-regulatory elements (CREs) exclusively shared between HSCs and unipotent lineage cells were enriched for DNA binding motifs of known lineage-specific transcription factors. To test the hypothesis that HSC-primed lineage-specific CREs remain accessible throughout differentiation, we used ATAC-seq to map the temporal dynamics of chromatin remodeling during blood cell differentiation. We observed epigenetic-driven clustering of oligopotent and unipotent progenitors into distinct erythromyeloid and lymphoid branches, with multipotent HSCs and MPPs associating with the erythromyeloid lineage. We mapped the dynamics of lineage-primed CREs throughout hematopoiesis and identified both unique and shared CREs as potential lineage reinforcement mechanisms at fate branch points in hematopoiesis. These findings provide insight into the regulation of stem cell multipotency and lineage commitment throughout hematopoiesis and serve as a resource to test functional drivers of hematopoietic lineage fate.

Project description:Allogenic hematopoietic stem cell (HSC) transplantation is widely used for treatment of blood disorders to re-establish long-term multi-lineage hematopoiesis. Enhance self-renewal potential of progenitor population to support hematopoiesis offer an alternative and complementary approach to achieve similar or enhance therapeutic effects. Nup98-Hoxa10hd fusion gene (NA) has been shown to confer expansion, anti-stress response and engraftment competitiveness on HSC. However, whether the ectopic expression of NA in multipotent progenitors (MPPs) could enhance their self-renewal potential and confer long-term multi-lineage hematopoiesis remains unknown. In this study, we showed that ectopic expression in MPPs confer long-term multi-lineage hematopoiesis in recipient mice. We further showed that NA upregulated pathways of cell cycle regulation, epigenetic regulation and response to stress in MPPs. These molecular traits increased the self-renewal potential of NA MPPs, which resulting in production of lineage-maintaining committed progenitor cells. Transcriptome analysis of NA myeloid progenitors identified genes regulating hematopoiesis, homeostasis, phosphorylation. In summary, we show that ectopic expression of Nup98-Hoxa10hd fusion gene enhance self-renewal potential of MPPs thus confer long-term multi-lineage repopulating capacity on MPPs, offering promising means to involve MPPs to augment cell source in clinical transplantation settings.

Project description:Allogenic hematopoietic stem cell (HSC) transplantation is widely used for treatment of blood disorders to re-establish long-term multi-lineage hematopoiesis. Enhance self-renewal potential of progenitor population to support hematopoiesis offer an alternative and complementary approach to achieve similar therapeutic effects. Nup98-Hoxa10hd fusion gene (NA) has been shown to confer expansion, anti-stress response and engraftment competitiveness on HSC. However, whether the ectopic expression of NA in multipotent progenitors (MPPs) could enhance their self-renewal potential and confer long-term multi-lineage hematopoiesis remains unknown. In this study, we showed that ectopic expression in MPPs confer long-term multi-lineage hematopoiesis in recipient mice. We further showed that NA upregulated pathways of cell cycle regulation, epigenetic regulation and response to stress in MPPs. These molecular traits increased the self-renewal potential of NA MPPs, which resulting in production of lineage-maintaining committed progenitor cells. Transcriptome analysis of NA myeloid progenitors identified genes regulating hematopoiesis, homeostasis, phosphorylation. In summary, we show that ectopic expression of Nup98-Hoxa10hd fusion gene enhance self-renwal potential of MPPs thus confer long-term multilineage repopulating capacity on MPPs, offering promising means to involve MPPs to augment cell source in clinical transplantation settings.