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  • 1
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    Artificial thymic organoid cultures: In vitro human T-cell differentiation from hematopoietic stem and progenitor cells
    Springer Science and Business Media LLC ; 2017
    In:  Protocol Exchange ( 2017-4-3)
    Details
    In: Protocol Exchange, Springer Science and Business Media LLC, ( 2017-4-3)
    Type of Medium: Online Resource
    ISSN: 2043-0116
    URL: Article
    DOI: 10.1038/protex.2017.062
    Language: Unknown
    Publisher: Springer Science and Business Media LLC
    Publication Date: 2017
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  • 2
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    Mef2C protects B lymphoid progenitor homeostasis by enhancing DNA repair and V(D)J recombination
    Elsevier BV ; 2014
    In:  Experimental Hematology Vol. 42, No. 8 ( 2014-08), p. S65-
    Details
    In: Experimental Hematology, Elsevier BV, Vol. 42, No. 8 ( 2014-08), p. S65-
    Type of Medium: Online Resource
    ISSN: 0301-472X
    URL: Article
    DOI: 10.1016/j.exphem.2014.07.248
    RVK:
    XA 42470
    Language: English
    Publisher: Elsevier BV
    Publication Date: 2014
    detail.hit.zdb_id: 2005403-8
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  • 3
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    Strength of CAR signaling determines T cell versus ILC differentiation from pluripotent stem cells
    Elsevier BV ; 2023
    In:  Cell Reports Vol. 42, No. 3 ( 2023-03), p. 112241-
    Details
    In: Cell Reports, Elsevier BV, Vol. 42, No. 3 ( 2023-03), p. 112241-
    Type of Medium: Online Resource
    ISSN: 2211-1247
    URL: Article
    DOI: 10.1016/j.celrep.2023.112241
    Language: English
    Publisher: Elsevier BV
    Publication Date: 2023
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  • 4
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    Unveiling ZAP-70's plan B
    American Society of Hematology ; 2008
    In:  Blood Vol. 111, No. 5 ( 2008-03-01), p. 2501-2502
    Details
    In: Blood, American Society of Hematology, Vol. 111, No. 5 ( 2008-03-01), p. 2501-2502
    Abstract: In this issue of Blood, Chen and colleagues demonstrate that ZAP-70 enhances BCR signaling in B-CLL cells by promoting phosphorylation of the ITAMs in the Ig signaling subunit independently of its kinase activity.
    Type of Medium: Online Resource
    ISSN: 0006-4971 , 1528-0020
    URL: Article
    DOI: 10.1182/blood-2007-12-128348
    RVK:
    XA 33000
    RVK:
    XA 10000
    Language: English
    Publisher: American Society of Hematology
    Publication Date: 2008
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  • 5
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    In Vitro Generation of Human Pluripotent Stem Cell-Derived T Cells for Immunotherapy
    American Society of Hematology ; 2017
    In:  Blood Vol. 130, No. Suppl_1 ( 2017-12-07), p. 691-691
    Details
    In: Blood, American Society of Hematology, Vol. 130, No. Suppl_1 ( 2017-12-07), p. 691-691
    Abstract: Adoptive cell therapy using T cells engineered to express antigen-specific T cell receptors (TCR-T) or chimeric antigen receptors (CAR-T) offer targeted and potentially curative treatments for malignancy. Current approaches rely on the genetic modification and expansion of mature circulating T-cells. Such processes are limited to autologous T cells due to the risk of graft-versus-host (GvHD) disease from allogeneic T cells through endogenous TCR expression as well as rejection through MHC incompatibility. Furthermore, prolonged ex-vivo expansion of T cells may reduce in vivo efficacy and harvesting sufficient T cells from lymphopenic patients is challenging. Direct in vitro differentiation of engineered T cells from human pluripotent stem cells (HSPCs) may overcome these problems by providing an unlimited source of cells that can be genetically edited, permitting the suppression of endogenous TCR expression through allelic exclusion, and the de novo generation of naïve antigen-specific T cells. We have developed an in vitro Artificial Thymic Organoid (ATO) system that induces highly efficient and reproducible production of mature naïve T cells from human hematopoietic stem cells and progenitor cells (HSPC). Here, we report the preclinical development of a modified ATO system that supports highly efficient in vitro differentiation and positive selection of naive human T cells from at least 5 different lines of human pluripotent stem cells (PSC), including Embryonic stem cells (ESC) and induced Pluripotent Stem Cells (iPSC). T cell differentiation from PSC was very similar phenotypically to that from HSPC. As in normal human thymopoiesis, the first evidence for T cell commitment was expression of CD7 and CD5, followed by the CD3-CD8lo "ISP8" stage, then CD4+CD8+ "DP" stage and finally production of CD3+CD8+CD4- "CD8SP" and Cd3+CD4+CD8- "CD4SP". As is typical with both monolayer cultures and ATOs (and opposite to normal thymus), CD8SP predominated over CD4SP. Surprisingly, differentiation occurred more rapidly from PSC than with HSPC. As with HSPC-ATOs, CD8SP from PSC ATOs showed a mature naïve conventional T cell phenotype i.e. CD3+TCRab+CD4- CD45RA+CD62L+CD27+ and exhibited a diverse, thymic-like TCR repertoire, and robust TCR-dependent cytokine release and proliferation. The differentiation in ATOs of an ESC line that expresses an HLA-A*02:01-restricted αβ TCR specific for NY-ESO-1 resulted in a markedly increased cell yield with an enhanced generation of naïve CD3+TCRαβ+CD8αβ+ conventional T cells, the majority of which were antigen-specific by tetramer staining. TCR-engineered T cells produced from PSC in ATOs displayed a near complete lack of endogenous TCR Vβ expression, consistent with induction of allelic exclusion by the exogenous TCR during T cell development. The TCR engineered T cells underwent polyfunctional cytokine release, and proliferation in response to artificial APCs. Moreover, the differentiation in ATOs of an ESC line that expresses a CD19-specific 2nd generation (CD28/CD3zeta) CAR construct resulted in the production of CD5+CD7+ CD45RA+ CAR T cells. As reported previously, the ESC-derived CAR T cells did not express CD4, CD8 or CD3; however, they responded to PMA/ionomycin and underwent specific cytokine release and degranulation in response to target cells expressing CD19. PSC-derivedATOs thus present a highly efficient platform for the generation of clinically relevant mature naïve and potentially non-alloreactive TCR and CAR engineered T cells for adoptive immunotherapy. Disclosures Montel-Hagen: Kite Pharma: Research Funding. Seet: Kite Pharma: Research Funding. Crooks: Kite Pharma: Research Funding.
    Type of Medium: Online Resource
    ISSN: 0006-4971 , 1528-0020
    URL: Article
    DOI: 10.1182/blood.V130.Suppl_1.691.691
    RVK:
    XA 33000
    RVK:
    XA 10000
    Language: English
    Publisher: American Society of Hematology
    Publication Date: 2017
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  • 6
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    Induction of GLUT1 during Erythropoiesis Triggers a Switch from Glucose to DHA Uptake in Vitamin C-Defective Mammals.
    American Society of Hematology ; 2007
    In:  Blood Vol. 110, No. 11 ( 2007-11-16), p. 1705-1705
    Details
    In: Blood, American Society of Hematology, Vol. 110, No. 11 ( 2007-11-16), p. 1705-1705
    Abstract: Glucose provides a key supply of energy and carbon and its transport is achieved via multimembrane-spanning glucose transporters (GLUTs). The human erythrocyte is the cell type expressing the highest level of the GLUT1 glucose transporter, harboring greater than 200,000 molecules per cell. We now demonstrate that GLUT1 transcripts increase by 3-logs during erythropoiesis and high GLUT1 surface expression is observed following passage through the basophilic erythroblast stage. Paradoxically though, glucose transport significantly decreases. As GLUT1 also transports L-dehydroascorbic acid (DHA), the oxidized form of ascorbic acid (AA), transport of this molecule was assessed and indeed, it increases dramatically during erythropoiesis. The switch from glucose to DHA transport is coupled to the physical association of GLUT1 with stomatin, an integral erythrocyte membrane protein. We find that stomatin inversely regulates the relative transports of glucose and DHA by GLUT1. Moreover, in a patient with overhydrated hereditary stomatocytosis, a rare genetic disorder of red cell membrane permeability wherein stomatin is absent, glucose uptake is significantly higher but there is a concomitant 50% reduction in DHA transport. Intriguingly, erythrocyte-specific DHA transport is not conserved amongst all mammalian species; we did not detect GLUT1 on mature murine erythrocytes where DHA uptake is minimal. Notably though, humans differ from the vast majority of the greater than 5,000 mammalian species in that they are unable to synthesize ascorbic acid from glucose. This trait is shared only with other higher primates, guinea pigs and and fruit bats. We have determined that erythrocyte GLUT1 expression and associated DHA transport are specific features of these diverse ascorbic acid-deficient mammals. Within the primate order, defective ascorbic acid synthesis is due to an inactivation of the L-gulonolactone oxidase (GLO) enzyme at the Haplorrhini-Strespsirrhini split. In accord with the data presented above, we find that erythrocyte GLUT1 expression and associated DHA transport are characteristic of erythrocytes from primates within the Haplorrhini suborder but not Strepsirrhini lemurs. Thus, the erythrocyte-specific co-expression of GLUT1 and stomatin constitutes a compensatory mechanism in mammals that are unable to synthesize the essential ascorbic acid metabolite.
    Type of Medium: Online Resource
    ISSN: 0006-4971 , 1528-0020
    URL: Article
    DOI: 10.1182/blood.V110.11.1705.1705
    RVK:
    XA 33000
    RVK:
    XA 10000
    Language: English
    Publisher: American Society of Hematology
    Publication Date: 2007
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  • 7
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    Artificial Thymic Organoids Permit Allelic Exclusion and Efficient Generation of Naïve TCR-Engineered T-Cells from Human Hematopoietic Stem Cells In Vitro
    American Society of Hematology ; 2016
    In:  Blood Vol. 128, No. 22 ( 2016-12-02), p. 4553-4553
    Details
    In: Blood, American Society of Hematology, Vol. 128, No. 22 ( 2016-12-02), p. 4553-4553
    Abstract: Engineered adoptive immunotherapies have shown unprecedented activity in the treatment of cancer and chronic viral infections. Current approaches rely on individualized ex vivo genetic modification of autologous T cells due to the risk of graft-versus-host disease from allogeneic T cells. These processes furthermore require activation and prolonged expansion of T cells, which may reduce in vivo efficacy and persistence. Direct in vitro differentiation of engineered T cells from hematopoietic stem and progenitor cells (HSPCs) may overcome these problems by permitting the suppression of endogenous TCR expression through allelic exclusion, and the de novo generation of naïve antigen-specific T cells. Existing methods of in vitro human T cell differentiation are subject to wide experimental variability and do not adequately support the positive selection of immature T cell precursors to mature T cells, and thus have not been suitable for clinical-scale production of engineered T cells. We report here the preclinical development of an artificial thymic organoid (ATO) system using off-the-shelf, serum-free components and a standardized stromal cell line that supports highly efficient in vitro differentiation and positive selection of native and TCR-engineered human T cells from cord blood (CB), bone marrow, and mobilized peripheral blood CD34+ HSPCs, and purified CD34+CD38- hematopoietic stem cells. ATOs closely recapitulated thymic T cell commitment and differentiation, resulting in greater than 80% CD7+CD5+ T-lineage cells and 50% CD4+CD8+ double positive (DP) T cell precursors by 4 weeks. By 6 weeks, 30-40% of ATO cells were CD3+TCRαβ+ T cells, of which 20-30% were mature CD8 single positive (SP) T cells. CD4SP cells were generated at a lower frequency and later in culture (2-14% of CD3+TCRαβ+ cells). ATO-derived T cells exhibited a naïve CD45RA+CD27+CCR7+CD62L+ phenotype, a diverse, thymic-like TCR repertoire, and robust TCR-dependent cytokine release and proliferation. Transduction of CB CD34+ HSPCs with an HLA-A*02:01-restricted αβ TCR specific for NY-ESO-1 resulted in a markedly increased cell output per ATO ( 〉 400-fold, relative to input HSPCs) and enhanced generation of naïve CD3+TCRαβ+CD8αβ+ conventional T cells, the majority of which were antigen-specific by tetramer staining. Positive selection of TCR-engineered naïve T cells could be further enhanced by expression of cognate HLA-A*02:01 in ATO stromal cells. ATO-derived TCR-engineered T cells exhibited a near complete lack of endogenous TCR Vβ expression, consistent with induction of allelic exclusion by the exogenous TCR during T cell development. ATO-derived engineered T cells underwent antigen-specific cytotoxic priming, polyfunctional cytokine release, and proliferation in response to artificial APCs; and exhibited antigen-specific killing of NY-ESO-1+ tumor cells in vitro and in vivo. ATOs thus present a highly efficient off-the-shelf platform for the generation of clinically relevant numbers of naïve and potentially non-alloreactive engineered T cells for adoptive immunotherapy. Clinical translation of the ATO system will be aided by its simplicity, scalability, use of serum-free components, and compatibility with irradiated stromal cells. In addition, genetic manipulation of stem or stromal cell components can be easily incorporated into the system to further enhance downstream T cell engraftment or function. Disclosures Seet: Kite Pharma: Patents & Royalties: Kite Pharma holds an exclusive license to certain intellectual property. Montel-Hagen:Kite Pharma: Patents & Royalties: Kite Pharma holds an exclusive license to certain intellectual property. Crooks:Kite Pharma: Patents & Royalties: Kite Pharma holds an exclusive license to certain intellectual property, Research Funding.
    Type of Medium: Online Resource
    ISSN: 0006-4971 , 1528-0020
    URL: Article
    DOI: 10.1182/blood.V128.22.4553.4553
    RVK:
    XA 33000
    RVK:
    XA 10000
    Language: English
    Publisher: American Society of Hematology
    Publication Date: 2016
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  • 8
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    Latent Cardiogenic Potential in Endocardium and Hemogenic Endothelium Revealed in the Absence of Scl/tal1
    American Society of Hematology ; 2011
    In:  Blood Vol. 118, No. 21 ( 2011-11-18), p. 2362-2362
    Details
    In: Blood, American Society of Hematology, Vol. 118, No. 21 ( 2011-11-18), p. 2362-2362
    Abstract: Abstract 2362 The endothelium in embryonic and extraembryonic hematopoietic tissues has the capacity to generate hematopoietic stem and progenitor cells (HS/PC). However, it is unknown how this unique endothelium is specified. Microarray analysis of endothelial cells from hematopoietic tissues of embryos deficient for the bHLH transcription factor Scl/tal1 revealed that Scl establishes a robust hematopoietic transcriptional program in the endothelium. Surprisingly, lack of Scl also induced an unexpected fate switching of the prospective hemogenic endothelium to the cardiac lineage. Scl deficient embryos displayed a dramatic upregulation of cardiac transcription factors and structural proteins within the yolk sac vasculature, resulting in the generation of spontaneously beating cardiomyocytes. Ectopic cardiac potential in Scl deficient embryos arose from endothelial-derived CD31+Pdgfrα+ cardiogenic progenitor cells (CPCs), which were present in all sites of HS/PC generation. Analysis of Runx1-deficient embryos revealed, that although Runx1 acts downstream of Scl during the emergence of definitive HS/PCs, it is not required for the suppression of the cardiac fate in the endothelium. The only wild type tissue that contained CD31+Pdgfrα+ putative CPCs was the heart, and this population was greatly expanded in Scl deficient embryos. Strikingly, endocardium in Scl−/− hearts also activated a robust cardiomyogenic transcriptional program and generated Troponin T+ cardiomyocytes both in vivo and in vitro. Although CD31+Pdgfrα+ CPCs from wild type hearts did not generate readily beating cells in culture, they produced cells expressing endothelial, smooth muscle and cardiomyocyte specific genes, implying multipotentiality of this novel CPC population. Furthermore, CD31+Pdgfrα+ CPCs were greatly reduced in Isl1−/− hearts, which fail to generate functional, multipotential CPCs. Lineage tracing using VE-cadherin Cre Rosa-YFP mouse strain demonstrated that, in addition to generating HS/PCs in hematopoietic tissues, endothelial cells are also the cell of origin for CD31+Pdgfrα+ CPCs in the heart. Together, these data suggest a broader role for embryonic endothelium as a potential source of tissue-specific stem and progenitor cells and implicate Scl/tal1 as an important regulator of endothelial fate choice. Disclosures: No relevant conflicts of interest to declare.
    Type of Medium: Online Resource
    ISSN: 0006-4971 , 1528-0020
    URL: Article
    DOI: 10.1182/blood.V118.21.2362.2362
    RVK:
    XA 33000
    RVK:
    XA 10000
    Language: English
    Publisher: American Society of Hematology
    Publication Date: 2011
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  • 9
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    Scl/Tal1 Directly Activates Hematopoiesis and Represses Cardiogenesis During Mesodermal Diversification
    American Society of Hematology ; 2012
    In:  Blood Vol. 120, No. 21 ( 2012-11-16), p. 3446-3446
    Details
    In: Blood, American Society of Hematology, Vol. 120, No. 21 ( 2012-11-16), p. 3446-3446
    Abstract: Abstract 3446 Understanding the mechanisms of mesoderm specification into the different lineages during embryogenesis holds a great potential to advance the development of cell-based regenerative therapies for cardiovascular and blood disorders. The divergence of the developmental fates is dictated by transcription factors that induce lineage-specific gene expression programs. The basic helix-loop-helix transcription factor Scl is known as the master regulator for the specification of the hematopoietic fate. We recently discovered that, in addition to positive effects of Scl in promoting the establishment of hemogenic endothelium and hematopoietic stem/progenitor cells development, it is also required to repress cardiogenesis in hematopoietic tissues during developmentally defined window (Van Handel, Montel-Hagen, et al, Cell, 2012). However, how Scl regulates hematopoiesis and cardiogenesis remains unknown. To identify Scl's direct target genes during mesoderm diversification, we determined the genome-wide Scl binding sites in Flk+ mesoderm from embryoid bodies using ChIP-sequencing. This analysis identified ∼4600 Scl binding sites throughout the genome, with predominance in inter-genic regions. Comparison with previously published Scl ChIP-seq datasets during later stages of development (HPC7 hematopoietic progenitor cell-line, Wilson et al. 2010, and red blood cells from fetal liver, Kassouf et al. 2010) revealed that the majority of the binding sites are developmental stage specific. Using nearest gene approach to intersect ChIP-seq data with gene expression data showed that the regulating regions of about 35% of Scl activated and 20% of repressed genes in Flk+ mesoderm were bound by Scl. Similar to later stages of hematopoietic development, robust binding of Scl to key hematopoietic transcription factors downstream of Scl, such as Runx1, Gata1, Gata2, Lyl1, Eto2, Erg, Fli1, Hhex, Gfi1, Gfi1b and Myb was observed during mesoderm specification. Interestingly, genomic regions enrichment analysis of Scl binding sites unique to Flk+ mesoderm showed enrichment for genes implicated in mesoderm formation and heart development, such as Gata4, Gata6, Msx1, Myocd, Nkx2–5 and Tbx5 indicating Scl functions as a direct repressor for cardiogenic transcriptional program. We then went on to investigate the mechanism of how Scl distinguishes between cardiac and hematopoietic genes to repress or activate them. Previous studies have shown that Scl forms complex with Gata1/2 transcription factors to activate red cell transcriptional program in erythroid cells. To clarify whether Gata1/2 are required in Scl binding and functional distinction between activation and repression during mesoderm specification, we performed Scl ChIP sequencing on Flk+ mesoderm from embryoid bodies induced from Gata1/2 double KO ES cells. Unexpectedly, Scl still bound to most hematopoietic as well as cardiac sites. However, some specific binding sites around key hematopoietic genes were completely lost or significantly reduced, such as ∼+300kb Runx1, ∼+30kb Myb and ∼TSS of Pu.1, and the expression of these genes was also down regulated in agreement with the loss of CD41+ hematopoietic progenitors in Day4.5 embryonic bodies. This suggests that Gata1/2 are required for Scl binding to the regulatory regions of a subset of crucial hematopoietic genes. These studies show that Scl has a direct critical function both as an activator of hematopoietic fate and a repressor of cardiac fate during mesoderm diversification, and only a fraction of Scl binding sites are Gata1 and/or Gata2 dependent. Disclosures: No relevant conflicts of interest to declare.
    Type of Medium: Online Resource
    ISSN: 0006-4971 , 1528-0020
    URL: Article
    DOI: 10.1182/blood.V120.21.3446.3446
    RVK:
    XA 33000
    RVK:
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    Language: English
    Publisher: American Society of Hematology
    Publication Date: 2012
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  • 10
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    Specification and Maintenance of the Scl Induced Hematopoietic Stem Cell Fate.
    American Society of Hematology ; 2009
    In:  Blood Vol. 114, No. 22 ( 2009-11-20), p. 1504-1504
    Details
    In: Blood, American Society of Hematology, Vol. 114, No. 22 ( 2009-11-20), p. 1504-1504
    Abstract: Abstract 1504 Poster Board I-527 The hematopoietic program is initiated in the embryo by the basic helix-loop-helix (bHLH) transcription factor Scl/Tal1 (stem cell leukemia gene). In the absence of Scl, mesodermal precursors are unable to commit to the hematopoietic fate and the embryo dies due to lack of blood formation. However, Scl becomes dispensable for hematopoietic stem cell(HSC) function shortly after hematopoietic specification, suggesting that once specified by Scl, the hematopoietic fate is maintained by alternative regulatory mechanisms. Scl is required again later for the proper maturation of erythrocytes and megakaryocytes. Despite Scl's pivotal role in initiating hematopoiesis, how Scl dictates HSC development at a molecular level remains unknown. To define how the hematopoietic fate is established by Scl, we performed genome-wide gene expression and ChIP-chip Scl binding analysis on in vitro differentiated hemangioblasts isolated from Scl−/− and control ES cells. Analysis of the 655 Scl-dependent genes and Scl binding revealed that Scl acts both as an activator and a repressor. The group of genes activated by Scl included major hematopoietic transcription factors such as Tel/Etv6, Gfi1, Fli1, cMyb, Gata2, Hhex, Sox17, Lyl1, and JunB, as well as regulators of embryonic vasculogenesis/angiogenesis and/or arterio-venous specification such as Ets1, Ets2, Elk3, Foxo1, Hoxb5, Smarca2, and Sox18. The group of genes repressed by Scl included regulators of alternative mesodermal fates such as Gata4, Tbx20 and Isl1, Foxf1a, and Snail1. These data show that Scl induces the hematopoietic program both by directly activating the major transcriptional networks required for the formation of the hemogenic endothelium and the emergence, self-renewal and survival of HSCs, as well as repressing alternative mesodermal fates. Considering the large number of transcription factors that Scl regulates during specification, we sought to determine at the molecular level how the hematopoietic fate is maintained independently of Scl. Gene expression analysis on Lin−cKit+ HSCs/progenitors isolated from Sclfl/flVavCre+ mice revealed that only 41 genes were Scl dependent, none of which were major hematopoietic factors. Notably, the key hematopoietic transcription factors remained expressed in both control and Scl deficient HSCs/progenitors indicating that the Scl induced program is maintained. Regulators of alternative mesodermal fates remained silenced during adult hematopoiesis. These molecular data were in agreement with the functional data showing that the bone marrow HSC/progenitor pool is maintained stably in the absence of Scl. To test whether Lyl1, a bHLH family member and Scl target gene, has an active role in maintaining the Scl induced hematopoietic fate, we generated HSCs/progenitors that do not express either Scl, or Lyl1, or both, by knocking down Lyl1 in Scl-deficient and control HSCs/progenitors via lentiviral shRNA. Analysis of colony forming capacity of transduced Lin−cKit+ HSCs/progenitors revealed that removing either Lyl1 or Scl alone did not have major impact on the clonogenic progenitor pool, whereas loss of both Lyl1 and Scl abrogated colony formation completely. Furthermore, ChIP-chip data revealed that Lyl1 is recruited to the promoters of the majority of Scl's target genes, and can maintain the hematopoietic program in the absence of Scl. In summary, these data show that Scl is critical in inducing the major transcriptional network of HSC genes while repressing alternative mesodermal fates during hematopoietic specification, after which the program is stabilized by Scl's target gene Lyl1. During adult hematopoiesis, relative redundancy between Scl and Lyl1 ensures stability of the HSC fate, while both factors retain unique functions in lineage differentiation. Disclosures: No relevant conflicts of interest to declare.
    Type of Medium: Online Resource
    ISSN: 0006-4971 , 1528-0020
    URL: Article
    DOI: 10.1182/blood.V114.22.1504.1504
    RVK:
    XA 33000
    RVK:
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    Language: English
    Publisher: American Society of Hematology
    Publication Date: 2009
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