Project description:The basic-helix-loop-helix transcription factor Scl/Tal1 controls the development and subsequent differentiation of haematopoietic stem cells (HSCs). However, since few Scl target genes have been validated to date, the underlying mechanisms have remained largely unknown. Here we have employed ChIP-Seq technology to generate a genome-wide catalogue of Scl binding events in a stem/progenitor cell line followed by validation using primary fetal liver cells and comprehensive transgenic mouse assays. Transgenic analysis provided in vivo validation of multiple new direct Scl target genes and allowed us to reconstruct an in vivo validated network consisting of 17 factors and their respective regulatory elements. By coupling ChIP-Seq in model cell lines with in vivo transgenic validation and sophisticated bioinformatic analysis, we have identified a widely applicable strategy for the reconstruction of stem cell regulatory networks where biological material is otherwise limiting. Moreover, in addition to revealing multiple previously unrecognised links to known HSC regulators as well as novel links to genes not previously implicated in HSC function, comprehensive transgenic analysis of regulatory elements provided substantial new insights into the transcriptional control of several important haematopoietic regulators including Cbfa2t3h/Eto2, Cebpe, Nfe2, Zfpm1/Fog1, Erg, Mafk, Gfi1b and Myb. Keywords: Gene regulation study Examination of one transcription factor in a haematopoietic progenitor cell line The samples provided were all sourced from the same ChIP experiment. They were then split into three and sent for sequencing. The samples labelled Scl_lane7 and Scl_lane8 were sequenced in parallel using an Illumina Genome Analyzer and then aligned using Solexa alignment software. There only variation was that the Scl_lane8 sample contained twice as much of the DNA as Scl_lane7. The sample labelled Scl_vancouver was sent to an alternative site for sequencing, again on an Illumina Genome Analyzer, and was aligned using the Eland aligner software.

Project description:SCL/TAL1, a tissue-specific transcription factor of the basic helix-loop-helix (bHLH) family, and c-Kit, a tyrosine kinase receptor, control hematopoietic stem cell survival and quiescence. Here we report that SCL and c-Kit signaling control a common gene expression signature, of which 19 genes are associated with apoptosis. In vivo, SCL levels are limiting for the clonal expansion of Kit+ multipotent and erythroid progenitors. In addition, increased SCL expression specifically enhances the sensitivity of multipotent and megakaryocyte/erythroid progenitors to Steel factor (KIT ligand), whilst a DNA binding mutant antagonizes KIT function and induces apoptosis in progenitors. We conclude that Scl operates downstream of Kit to support the survival of megakaryocyte/erythroid progenitors. Finally, higher SCL expression upregulates Kit in normal bone marrow cells and increases chimerism after bone marrow transplantation, indicating that Scl is also upstream of Kit. We conclude that Scl and Kit establish a positive feedback loop in multipotent and megakaryocyte/erythroid progenitors.

Project description:Stem Cell Leukemia (Scl or Tal1) and Lymphoblastic Leukemia 1 (Lyl1) are highly related members of the basic helix-loop-helix (bHLH) family of transcription factors that are co- expressed in hematopoietic stem cells and the erythro-megakaryocytic lineages. Previous studies suggest that Scl is essential for hematopoietic development including primitive erythropoiesis. However, analysis of single-cell RNA-sequencing data of early embryos showed that primitive erythroid cells express both Scl and Lyl1. Therefore, to determine whether Lyl1 has a functional role in erythropoiesis, we crossed conditional Scl mice with transgenic mice expressing a Cre recombinase under the control of the Epo receptor, active in erythroid progenitors. Surprisingly, embryos with markedly reduced expression of Scl from E9.5 survived to adulthood. In contrast, mice with reduced expression of Scl and absence of Lyl1 (double knockout; DKO) died at E10.5 due to progressive loss of erythropoiesis. Consistent with a phenocopy of Gata1-null mice, gene expression profiling of DKO yolk sacs prior to the loss of erythrocytes (E9.5) revealed loss of Gata1 and many of the known target genes of the SCL-GATA1 complex. ChIP-seq analyses showed that LYL1 exclusively bound a small subset of SCL targets including GATA1. Together, these data show for the first time that Scl and Lyl1 share functional roles in primitive erythropoiesis.

Project description:SCL/TAL1, a tissue-specific transcription factor of the basic helix-loop-helix (bHLH) family, and c-Kit, a tyrosine kinase receptor, control hematopoietic stem cell survival and quiescence. Here we report that SCL and c-Kit signaling control a common gene expression signature, of which 19 genes are associated with apoptosis. In vivo, SCL levels are limiting for the clonal expansion of Kit+ multipotent and erythroid progenitors. In addition, increased SCL expression specifically enhances the sensitivity of multipotent and megakaryocyte/erythroid progenitors to Steel factor (KIT ligand), whilst a DNA binding mutant antagonizes KIT function and induces apoptosis in progenitors. We conclude that Scl operates downstream of Kit to support the survival of megakaryocyte/erythroid progenitors. Finally, higher SCL expression upregulates Kit in normal bone marrow cells and increases chimerism after bone marrow transplantation, indicating that Scl is also upstream of Kit. We conclude that Scl and Kit establish a positive feedback loop in multipotent and megakaryocyte/erythroid progenitors. c-Kit regulated genes were extrapolated from gene expression profiles of TF-1 erythroid progenitor cells (empty MSCV vector) stimulated with SF (Kit ligand), Epo or GM-CSF. Second, SCL-regulated genes were obtained by expressing a DNA binding-defective SCL mutant (DbSCL) and selecting genes that were differentially expressed in M-oM-^AM-^DbSCL cells versus control cells (MSCV) stimulated with the same cytokines.

Project description:Coordination of cellular processes through the establishment of tissue-specific gene expression programmes is essential for lineage maturation. The basic helix-loop-helix haemopoietic transcriptional regulator SCL/Tal1 is required for terminal differentiation of red blood cells. To gain insight into SCL function and mechanisms of action in erythropoiesis, we performed ChIP-sequencing and gene expression analyses from primary fetal liver erythroid cells. We show that SCL coordinates expression of genes in most known red cell-specific processes. The majority of SCL’s genomic targets require direct DNA-binding activity. However, one fifth of SCL’s target sequences, mainly amongst those showing high affinity for SCL, can recruit the factor independently of its DNA binding activity. An unbiased DNA motif search of sequences bound by SCL identified CAGNTG as SCL-preferred E-box motif in erythroid cells. Novel motifs were also characterised that may help distinguish activated from repressed genes and suggest a new mechanism by which SCL may be recruited to DNA. Finally, analysis of recruitment of GATA1, a protein partner of SCL, to sequences occupied by SCL suggests that SCL’s binding is necessary prior or simultaneous to that of GATA1. This work provides the framework to study regulatory networks leading to erythroid terminal maturation and to model mechanisms of action of tissue-specific transcription factors.

Project description:Combinatorial transcription factor (TF) interactions control cellular phenotypes and therefore underpin stem cell formation, maintenance and differentiation. Here we report the genome-wide binding patterns and combinatorial interactions for 10 key regulators of blood stem/progenitor cells (Scl/Tal1, Lyl1, Lmo2, Gata2, Runx1, Meis1, Pu.1, Erg, Fli-1, Gfi1b) thus providing the most comprehensive TF dataset for any adult stem/progenitor cell type to date. Genome-wide computational analysis of complex binding patterns followed by functional validation revealed the following: First, a previously unrecognized combinatorial interaction between a heptad of TFs (Scl, Lyl1, Lmo2, Gata2, Runx1, Erg, Fli-1). Second, we implicate direct protein-protein interactions between four key regulators (Runx1, Gata2, Scl, Erg) in stabilising complex binding to DNA. Third, Runx1+/-::Gata2+/- compound heterozygous mice are not viable with severe haematopoietic defects at midgestation. Taken together, this study demonstrates the power of genome-wide analysis in generating novel functional insights into the transcriptional control of stem and progenitor cells. 10 Samples (9 Transcription Factors and 1 Histone Modification) and 1 Control (IgG). All from the same cell line, a haematopoietic progenitor cell line (HPC-7).

Project description:Coordination of cellular processes through the establishment of tissue-specific gene expression programmes is essential for lineage maturation. The basic helix-loop-helix haemopoietic transcriptional regulator SCL/Tal1 is required for terminal differentiation of red blood cells. To gain insight into SCL function and mechanisms of action in erythropoiesis, we performed ChIP-sequencing and gene expression analyses from primary fetal liver erythroid cells. We show that SCL coordinates expression of genes in most known red cell-specific processes. The majority of SCL’s genomic targets require direct DNA-binding activity. However, one fifth of SCL’s target sequences, mainly amongst those showing high affinity for SCL, can recruit the factor independently of its DNA binding activity. An unbiased DNA motif search of sequences bound by SCL identified CAGNTG as SCL-preferred E-box motif in erythroid cells. Novel motifs were also characterised that may help distinguish activated from repressed genes and suggest a new mechanism by which SCL may be recruited to DNA. Finally, analysis of recruitment of GATA1, a protein partner of SCL, to sequences occupied by SCL suggests that SCL’s binding is necessary prior or simultaneous to that of GATA1. This work provides the framework to study regulatory networks leading to erythroid terminal maturation and to model mechanisms of action of tissue-specific transcription factors. Total RNA extracted from wild-type (WT) day E12.5 fetal liver Ter119- erythroid progenitor cells was compared to total RNA extracted from E12.5 fetal liver Ter119- cells expressing a DNA-binding mutant form of SCL (SclRER/RER).

Project description:Haematopoietic stem cells (HSC) reside in locations within the bone marrow microenvironment (BMM) featuring a slightly higher extracellular calcium ion concentration [eCa2+]. HSC respond to [eCa2+] via the G-protein coupled calcium-sensing receptor (CaSR), but the role of CaSR for leukaemia and leukaemia stem cells (LSC), the malignant counterpart to HSC, is poorly defined. Here we performed a proteomic analysis on Lin- MLL AF9+ cells, comparing WT cells to cells lacking CaSR using TMT-based proteomics.

Project description:Combinatorial transcription factor (TF) interactions control cellular phenotypes and therefore underpin stem cell formation, maintenance and differentiation. Here we report the genome-wide binding patterns and combinatorial interactions for 10 key regulators of blood stem/progenitor cells (Scl/Tal1, Lyl1, Lmo2, Gata2, Runx1, Meis1, Pu.1, Erg, Fli-1, Gfi1b) thus providing the most comprehensive TF dataset for any adult stem/progenitor cell type to date. Genome-wide computational analysis of complex binding patterns followed by functional validation revealed the following: First, a previously unrecognized combinatorial interaction between a heptad of TFs (Scl, Lyl1, Lmo2, Gata2, Runx1, Erg, Fli-1). Second, we implicate direct protein-protein interactions between four key regulators (Runx1, Gata2, Scl, Erg) in stabilising complex binding to DNA. Third, Runx1+/-::Gata2+/- compound heterozygous mice are not viable with severe haematopoietic defects at midgestation. Taken together, this study demonstrates the power of genome-wide analysis in generating novel functional insights into the transcriptional control of stem and progenitor cells.

Project description:Hematopoietic stem cells (HSC) rely on a unique regulatory machinery that facilitates life-long blood production and enables reconstitution of the entire hematopoietic system upon transplantation. However, the biological processes governing human HSC self-renewal and engraftment ability are poorly understood and challenging to recapitulate ex vivo to facilitate robust human HSC expansion. We discovered a novel HSC regulatory protein, MYCT1 (MYCT target 1), that is selectively expressed in endothelial cells (EC) and undifferentiated human HSPCs but becomes drastically downregulated during HSC culture. Lentiviral knockdown of MYCT1 in human foetal liver and cord blood HSPCs revealed a critical role for MYCT1 in governing human HSPC expansion and engraftment ability. Single cell RNAseq of human CB HSPCs after MYCT1 knockdown and overexpression revealed that MYCT1 governs HSC functional competence and modulates cellular properties essential for HSC stemness, such as low mitochondrial metabolic activity. Indeed, restoring the compromised MYCT1 expression in cultured human CB HSPCs improved ex vivo expansion of the most undifferentiated human HSPCs and enhanced their engraftment ability. We found that MYCT1 is localized in the endosomal membrane and interacts with vesicle trafficking regulators and signalling machinery essential for HSC and EC function. Loss of MYCT1 led to excessive endocytosis and hyperactive signalling responses to cytokines, whereas restoring MYCT1 expression in cultured CB HSPCs balanced the abnormal endocytosis associated with prolonged culture and fine-tuned signalling responses. Our work identifies MYCT1-moderated endocytosis and environmental sensing as an essential regulatory mechanism required to preserve human HSC stemness, and pinpoints silencing of MYCT1 as a critical contributor to the dysfunction of cultured human HSCs that needs to be addressed to improve human HSC culture strategies.