While many individual transcription factors are known to regulate hematopoietic differentiation, major aspects of the global architecture of hematopoiesis remain unknown. Here, we profiled gene expression in 38 distinct purified populations of human hematopoietic cells and used probabilistic models of gene expression and analysis of cis-elements in gene promoters to decipher the general organization of their regulatory circuitry. We identified modules of highly co-expressed genes, some of which are restricted to a single lineage, but most are expressed at variable levels across multiple lineages. We found densely interconnected cis-regulatory circuits and a large number of transcription factors that are differentially expressed across hematopoietic states. These findings suggest a more complex regulatory system for hematopoiesis than previously assumed.
In certain human cancers, the expression of critical oncogenes is driven from large regulatory elements, called super-enhancers, which recruit much of the cell’s transcriptional apparatus and are defined by extensive acetylation of histone H3 lysine 27 (H3K27ac). In a subset of T-cell acute lymphoblastic leukemia (T-ALL) cases, we found that heterozygous somatic mutations are acquired that introduce binding motifs for the MYB transcription factor in a precise noncoding site, which creates a super-enhancer upstream of the TAL1 oncogene. MYB binds to this new site and recruits it’s H3K27 acetylase binding partner CBP, as well as core components of a major leukemogenic transcriptional complex that contains RUNX1, GATA-3, and TAL1 itself. Additionally, most endogenous super-enhancers found in T-ALL cells are occupied by MYB and CBP, suggesting a general role for MYB in super-enhancer initiation. Thus, this study identifies a genetic mechanism responsible for the generation of oncogenic super-enhancers in malignant cells.
SUMMARY The oncogenic transcription factor TAL1/SCL is aberrantly expressed in over 40% of cases of human T-cell acute lymphoblastic leukemia (T-ALL), emphasizing its importance in the molecular pathogenesis of T-ALL. Here we identify the core transcriptional regulatory circuit controlled by TAL1 and its regulatory partners HEB, E2A, LMO1/2, GATA3 and RUNX1. We show that TAL1 forms a positive interconnected auto-regulatory loop with GATA3 and RUNX1, and that the TAL1 complex directly activates the MYB oncogene, forming a positive feed-forward regulatory loop that reinforces and stabilizes the TAL1-regulated oncogenic program. One of the critical downstream targets in this circuitry is the TRIB2 gene, which is oppositely regulated by TAL1 and E2A/HEB and is essential for the survival of T-ALL cells.
Summary BMP and Wnt signaling pathways control essential cellular responses through activation of the transcription factors SMAD (BMP) and TCF (Wnt). Here, we show that regeneration of hematopoietic lineages following acute injury depends on the activation of each of these signaling pathways to induce expression of key blood genes. Both SMAD1 and TCF7L2 co-occupy sites with master regulators adjacent to hematopoietic genes. In addition, both SMAD1 and TCF7L2 follow the binding of the predominant lineage regulator during differentiation from multipotent hematopoietic progenitor cells to erythroid cells. Furthermore, induction of the myeloid lineage regulator C/EBPα in erythroid cells shifts binding of SMAD1 to sites newly occupied by C/EBPα, while expression of the erythroid regulator GATA1 directs SMAD1 loss on non-erythroid targets. We conclude that the regenerative response mediated by BMP and Wnt signaling pathways is coupled with the lineage master regulators to control the gene programs defining cellular identity.
Mixed-lineage leukemia (MLL) fusion proteins are potent inducers of leukemia, but how these proteins generate aberrant gene expression programs is poorly understood. Here we show that the MLL-AF4 fusion protein occupies developmental regulatory genes important for hematopoietic stem cell identity and self-renewal in human leukemia cells. These MLL-AF4-bound regions have grossly altered chromatin structure, with histone modifications catalyzed by trithorax group proteins and DOT1 extending across large domains. Our results define direct targets of the MLL fusion protein, reveal the global role of epigenetic misregulation in leukemia, and identify new targets for therapeutic intervention in cancer.Supplemental material is available at http://www.genesdev.org.Received September 16, 2008; revised version accepted November 4, 2008. Chromosomal translocations involving the mixed-lineage leukemia gene (MLL) are a frequent occurrence in human acute leukemias of both children and adults (Eguchi et al. 2005). In over half of all infant acute leukemias, the MLL protein fuses to one of >50 identified partner genes, resulting in a MLL fusion protein that acts as a potent oncogene (Krivtsov and Armstrong 2007). While extensive gene expression signatures have been determined for primary human leukemia samples (Armstrong et al. 2002;Yeoh et al. 2002;Ferrando et al. 2003;Ross et al. 2003;Rozovskaia et al. 2003;Haferlach et al. 2005), the direct genomic targets of MLL fusion proteins remain unknown. This information is essential to determine how MLL fusion proteins impose oncogenic transcriptional programs and to identify targets for therapeutic intervention in human disease.Distinct chromatin-modifying complexes and histone modifications are associated with distinct phases of transcription (Li et al. 2007). The trithorax group proteins, including MLL, catalyze histone H3-Lys-4 trimethyl (H3K4me3) modifications at the start sites of transcriptionally engaged genes (Ruthenburg et al. 2007). These H3K4me3-modified regions are largely constrained to the transcription start site regions of genes that are transcriptionally initiated, but not necessarily fully transcribed (Bernstein et al. 2006;Barski et al. 2007;Guenther et al. 2007). As a gene becomes fully transcribed, elongating RNA Polymerase II (Pol II) molecules proceed through gene coding regions along with associated elongation factors including DOT1, which catalyzes dimethylation of histone H3-Lys-79 (H3K79me2) (Li et al. 2007). Physical interactions between the most common MLL partner proteins and transcriptional elongation components suggest that defects in H3K4 and H3K79 methylation might be a key factor in MLL leukemogenesis In order to define the portion of gene regulatory circuitry that is controlled directly by MLL fusion proteins in human leukemia, we determined the binding patterns of an MLL fusion protein and chromatin modifications across the entire human genome. We performed this mapping in leukemic cells harboring the MLL-AF4 fusion gene, because this rearran...
Summary Using mouse skin, where bountiful reservoirs of synchronized hair follicle stem cells (HF-SCs) fuel cycles of regeneration, we explore how adult SCs remodel chromatin in response to activating cues. By profiling global mRNA and chromatin changes in quiescent and activated HF-SCs and their committed, transit-amplifying (TA) progeny, we show that polycomb-group(PcG)-mediated H3K27-trimethylation features prominently in HF-lineage progression by mechanisms distinct from embryonic-SCs. In HF-SCs, PcG represses non-skin lineages and HF-differentiation. In TA-progeny, non-skin regulators remain PcG-repressed, HF-SC regulators acquire H3K27me3-marks and HF-lineage regulators lose them. Interestingly, genes poised in embryonic-SCs, active in HF-SCs and PcGrepressed in TA-progeny, encode not only key transcription factors, but also signaling regulators. We document their importance in balancing HF-SC quiescence, underscoring the power of chromatin mapping in dissecting SC behavior. Our findings explain how HF-SCs cycle through quiescent and activated states without losing stemness, and define roles for PcG-mediated repression in governing a fate switch irreversibly.
We have developed a simple procedure based on reassociation kinetics that can reduce effectively the high variation in abundance among the clones of a cDNA library that represent individual mRNA species. For this normalization, we used as a model system a library of human infant brain cDNAs that were cloned directionally into a phagemid vector and, thus, could be easily converted into single-stranded circles. After controlled primer extension to synthesize a short complementary strand on each circular template, melting and reannealing of the partial duplexes at relatively low Cot, and hydroxyapatite column chromatography, unreassodated circles were recovered from the flow through fraction and electroporated into bacteria, to propagate a normalized library without a requirement for subcloning steps. An evaluation of the extent of normalization has indicated that, from an extreme range of abundance of 4 orders of magnitude in the original library, the frequency of occurrence of any done exmned in the normalized library was brought within the narrow range of only 1 order of magnitude. feasible task). Finally, by increasing the frequency of occurrence of rare cDNA clones while decreasing simultaneously the percentage of abundant cDNAs, normalization can expedite significantly the development of expressed sequence databases by random sequencing of cDNAs.Although cDNA library normalization could be achieved by saturation hybridization to genomic DNA (6), this approach is impractical, since it would be extremely difficult to provide saturating amounts of the rarer cDNA species to the hybridization reaction. The alternative is the use of reassociation kinetics: assuming that cDNA reannealing follows second-order kinetics, rarer species will anneal less rapidly and the remaining single-stranded fraction of cDNA will become progressively normalized during the course of the reaction (6-8). As we report here, we have used this kinetic principle to develop a method for normalization of a directionally cloned cDNA library that has significant advantages over two previously reported similar procedures (refs. 7 and 8; see Results and Discussion).
The role of the chromatin remodeler Mi-2β in hematopoietic stem cell self-renewal and multilineage differentiation
The ability of somatic stem cells to self-renew and differentiate into downstream lineages is dependent on specialized chromatin environments that keep stem cell-specific genes active and key differentiation factors repressed but poised for activation. The epigenetic factors that provide this type of regulation remain ill-defined. Here we provide the first evidence that the SNF2-like ATPase Mi-2 of the Nucleosome Remodeling Deacetylase (NuRD) complex is required for maintenance of and multilineage differentiation in the early hematopoietic hierarchy. Shortly after conditional inactivation of Mi-2, there is an increase in cycling and a decrease in quiescence in an HSC (hematopoietic stem cell)-enriched bone marrow population. These cycling mutant cells readily differentiate into the erythroid lineage but not into the myeloid and lymphoid lineages. Together, these effects result in an initial expansion of mutant HSC and erythroid progenitors that are later depleted as more differentiated proerythroblasts accumulate at hematopoietic sites exhibiting features of erythroid leukemia. Examination of gene expression in the mutant HSC reveals changes in the expression of genes associated with self-renewal and lineage priming and a pivotal role of Mi-2 in their regulation. Thus, Mi-2 provides the hematopoietic system with immune cell capabilities as well as with an extensive regenerative capacity.[Keywords: Mi-2; chromatin; HSC; multipotency; self-renewal; lineage priming] Supplemental material is available at http://www.genesdev.org. Received December 13, 2007; revised version accepted March 4, 2008. The defining properties of somatic stem cells, their ability to self-renew and to progress through available differentiation pathways, are critical for the life-long tissue integrity of multicellular organisms (Weissman 2000;Lemischka and Moore 2003). A balance between stem cell quiescence and activation is required to sustain the stem cell pool and to provide adequate numbers of mature cells to meet normal homeostatic conditions. Both the self-renewal and differentiation properties of stem cells can be altered dramatically in order to meet demands imposed by stress conditions.In hematopoietic tissue, the most primitive stem cells are thought to be in a comparatively quiescent state. They cycle with slow kinetics that strongly correlate with their long-term self-renewing potential (LT-HSC) (Morrison and Weissman 1994;Cheshier et al. 1999). Thus, maintenance of hematopoietic stem cell (HSC) activity can be compromised in two ways. On the one hand, a cell cycle block can prevent self-renewing divisions. On the other hand, prolonged cell cycle activation can lead to HSC exhaustion. This has been corroborated by studies on components of the cell cycle machinery and on signaling pathways that modulate their activity. An increase in expression of the cell cycle inhibitors p16 Ink4A, p19Ink4D/Arf , or p18Ink4C has an adverse effect on the HSC's self-renewal, presumably by restricting its entry into the cell cycle (Park et a...
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