ß-Catenin is required for T-cell leukemia initiation and MYC transcription downstream of Notch1.

Notch activation is instrumental in the development of most T-cell acute lymphoblastic leukemia (T-ALL) cases, yet Notch mutations alone are not sufficient to recapitulate the full human disease in animal models. We here found that Notch1 activation at the fetal liver (FL) stage expanded the hematopoietic progenitor population and conferred it transplantable leukemic-initiating capacity. However, leukemogenesis and leukemic-initiating cell capacity induced by Notch1 was critically dependent on the levels of ß-Catenin in both FL and adult bone marrow contexts. In addition, inhibition of ß-Catenin compromised survival and proliferation of human T-ALL cell lines carrying activated Notch1. By transcriptome analyses, we identified the MYC pathway as a crucial element downstream of ß-Catenin in these T-ALL cells and demonstrate that the MYC 3' enhancer required ß-Catenin and Notch1 recruitment to induce transcription. Finally, PKF115-584 treatment prevented and partially reverted leukemogenesis induced by active Notch1.

The Notch ligand DLL4 specifically marks human hematoendothelial progenitors and regulates their hematopoietic fate.

Notch signaling is essential for definitive hematopoiesis, but its role in human embryonic hematopoiesis is largely unknown. We show that in hESCs the expression of the Notch ligand DLL4 is induced during hematopoietic differentiation. We found that DLL4 is only expressed in a sub-population of bipotent hematoendothelial progenitors (HEPs) and segregates their hematopoietic versus endothelial potential. We demonstrate at the clonal level and through transcriptome analyses that DLL4(high) HEPs are enriched in endothelial potential, whereas DLL4(low/-) HEPs are committed to the hematopoietic lineage, albeit both populations still contain bipotent cells. Moreover, DLL4 stimulation enhances hematopoietic differentiation of HEPs and increases the amount of clonogenic hematopoietic progenitors. Confocal microscopy analysis of whole differentiating embryoid bodies revealed that DLL4(high) HEPs are located close to DLL4(low/-) HEPs, and at the base of clusters of CD45+ cells, resembling intra-aortic hematopoietic clusters found in mouse embryos. We propose a model for human embryonic hematopoiesis in which DLL4(low/-) cells within hemogenic endothelium receive Notch-activating signals from DLL4(high) cells, resulting in an endothelial-to-hematopoietic transition and their differentiation into CD45+ hematopoietic cells.

Non-conventional functions for NF-κB members: the dark side of NF-κB.

NF-κB pathway exerts an essential function in the regulation of the immune response, which has been the nucleus of numerous studies for the past 25 years. Both activation of the pathway and termination of the NF-κB response are tightly regulated events, which is essential to prevent exacerbated inflammatory responses. Thus, alterations in NF-κB regulatory elements might result in tissue damage and cancer in different systems. In addition, several of the proteins involved in NF-κB regulation display additional, and much less studied, functions that connect with specific NF-κB-unrelated pathways. Many of these pathways are in turn regulators of particular physiologic and/or pathologic responses. Which are the principal non-conventional functions that have been identified for specific NF-κB elements, how they connect with other signaling pathways and what is their potential impact on cancer is the focus of this review.

Novel functions of chromatin-bound IκBα in oncogenic transformation.

The nuclear factor-κB (NF-κB) signalling pathway participates in a multitude of biological processes, which imply the requirement of a complex and precise regulation. IκB (for Inhibitor of kappaB) proteins, which bind and retain NF-κB dimers in the cytoplasm, are the main contributors to negative regulation of NF-κB under non-stimulation conditions. Nevertheless, increasing evidences indicate that IκB proteins exert specific nuclear roles that directly contribute to the control of gene transcription. In particular, hypophosphorylated IκBß can bind the promoter region of TNFα leading to persistent gene transcription in macrophages and contributing to the regulation of the inflammatory response. Recently, we demonstrated that phosphorylated and SUMOylated IκBα reside in the nucleus of the cells where it binds to chromatin leading to specific transcriptional repression. Mechanistically, IκBα associates and regulates Polycomb Repressor Complex activity, a function that is evolutionary conserved from flies to mammals, as indicate the homeotic phenotype of Drosophila mutants. Here we discuss the implications of chromatin-bound IκBα function in the context of tumorigenesis.

p27Kip1 represses transcription by direct interaction with p130/E2F4 at the promoters of target genes.

The cyclin-cdk (cyclin-dependent kinase) inhibitor p27Kip1 (p27) has a crucial negative role on cell cycle progression. In addition to its classical role as a cyclin-cdk inhibitor, it also performs cyclin-cdk-independent functions as the regulation of cytoskeleton rearrangements and cell motility. p27 deficiency has been associated with tumor aggressiveness and poor clinical outcome, although the mechanisms underlying this participation still remain elusive. We report here a new cellular function of p27 as a transcriptional regulator in association with p130/E2F4 complexes that could be relevant for tumorigenesis. We observed that p27 associates with specific promoters of genes involved in important cellular functions as processing and splicing of RNA, mitochondrial organization and respiration, translation and cell cycle. On these promoters p27 co-localizes with p130, E2F4 and co-repressors as histone deacetylases (HDACs) and mSIN3A. p27 co-immunoprecipitates with these proteins and by affinity chromatography, we demonstrated a direct interaction of p27 with p130 and E2F4 through its carboxyl-half. We have also shown that p130 recruits p27 on the promoters, and there p27 is needed for the subsequent recruitment of HDACs and mSIN3A. Expression microarrays and luciferase assays revealed that p27 behaves as transcriptional repressor of these p27-target genes (p27-TGs). Finally, in human tumors, we established a correlation with overexpression of p27-TGs and poor survival. Thus, this new function of p27 as a transcriptional repressor could have a role in the major aggressiveness of tumors with low levels of p27.

The notch pathway positively regulates programmed cell death during erythroid differentiation.

Programmed cell death plays an important role in erythropoiesis under physiological and pathological conditions. In this study, we show that the Notch/RBPjkappa signaling pathway induces erythroid apoptosis in different hematopoietic tissues, including yolk sac and bone marrow as well as in murine erythroleukemia cells. In RBPjkappa(-/-) yolk sacs, erythroid cells have a decreased rate of cell death that results in increased number of Ter119(+) cells. A similar effect is observed when Notch activity is abrogated by incubation with the gamma-secretase inhibitors, DAPT or L685,458. We demonstrate that incubation with Jagged1-expressing cells has a proapoptotic effect in erythroid cells from adult bone marrow that is prevented by blocking Notch activity. Finally, we show that the sole expression of the activated Notch1 protein is sufficient to induce apoptosis in hexametilene-bisacetamide-differentiating murine erythroleukemia cells. Together these results demonstrate that Notch regulates erythroid homeostasis by inducing apoptosis.

Nuclear IKK activity leads to dysregulated notch-dependent gene expression in colorectal cancer.

Nuclear functions for IkappaB kinase (IKK), including phosphorylation of histone H3 and nuclear corepressors, have been recently described. Here, we show that IKK is activated in colorectal tumors concomitant with the presence of phosphorylated SMRT (silencing mediator of retinoic acid and thyroid hormone receptor) corepressor that is aberrantly localized in the cytoplasm. In these tumors, IKKalpha associates to the chromatin of specific Notch targets, leading to the release of SMRT. Abrogation of IKK activity by BAY11-7082 or by expressing dominant negative IKKalpha restores the association of SMRT with Notch target genes, resulting in specific gene repression. Finally, BAY11-7082 significantly reduces tumor size in colorectal cancer xenografts (CRC-Xs) implanted in nude mice.

Phosphorylation of Ser2078 modulates the Notch2 function in 32D cell differentiation.

Notch signaling is involved in the regulation of many cell fate determination events in both embryonic development and adult tissue homeostasis. We previously demonstrated that Notch1 and Notch2 molecules inhibit myeloid differentiation in a cytokine-specific manner and that the Notch cytokine response domain is necessary for this functional specificity. We have now investigated the putative role of phosphorylation in the activity of Notch in response to cytokine signals. Our results show that the granulocyte colony-stimulating factor (G-CSF) stimulation of 32D cells expressing the intracellular Notch2 protein induces phosphorylation at specific sites of this molecule, rendering the molecule inactive and permitting differentiation of these cells. In contrast, when cells are stimulated with granulocyte macrophage colony-stimulating factor (GM-CSF), intracellular notch2 is not phosphorylated at these residues and differentiation is inhibited. We also show that deletion of the Ser/Thr-rich region between amino acids 2067 and 2099 abrogates G-CSF-induced phosphorylation and results in a molecule that inhibits differentiation in response to either G-CSF or GM-CSF. Our results further indicate that Ser(2078) is a critical residue for phosphorylation and modulation of Notch2 activity in the context of G-CSF-induced differentiation of 32D cells.

Differential expression and phosphorylation of CTCF, a c-myc transcriptional regulator, during differentiation of human myeloid cells.

CTCF is a transcriptional repressor of the c-myc gene. Although CTCF has been characterized in some detail, there is very little information about the regulation of CTCF activity. Therefore we investigated CTCF expression and phosphorylation during induced differentiation of human myeloid leukemia cells. We found that: (i) both CTCF mRNA and protein are down-regulated during terminal differentiation in most cell lines tested; (ii) CTCF down-regulation is retarded and less pronounced than that of c-myc; (iii) CTCF protein is differentially phosphorylated and the phosphorylation profiles depend on the differentiation pathway. We concluded that CTCF expression and activity is controlled at transcriptional and post-transcriptional levels.

Notch1 and Notch2 inhibit myeloid differentiation in response to different cytokines.

We have compared the ability of two mammalian Notch homologs, mouse Notchl and Notch2, to inhibit the granulocytic differentiation of 32D myeloid progenitor cells. 32D cells undergo granulocytic differentiation when stimulated with either granulocyte colony-stimulating factor (G-CSF) or granulocyte-macrophage colony-stimulating factor (GM-CSF). Expression of the activated intracellular domain of Notch1 inhibits the differentiation induced by G-CSF but not by GM-CSF; conversely, the corresponding domain of Notch2 inhibits differentiation in response to GM-CSF but not to G-CSF. The region immediately C-terminal to the cdc10 domain of Notch confers cytokine specificity on the cdc10 domain. The cytokine response patterns of Notch1 and Notch2 are transferred with this region, which we have termed the Notch cytokine response (NCR) region. The NCR region is also associated with differences in posttranslational modification and subcellular localization of the different Notch molecules. These findings suggest that the multiple forms of Notch found in mammals have structural differences that allow their function to be modulated by specific differentiation signals.

Inhibition of granulocytic differentiation by mNotch1.

Effective hematopoiesis requires the commitment of pluripotent and multipotent stem cells to distinct differentiation pathways, proliferation and maturation of cells in the various lineages, and preservation of pluripotent progenitors to provide continuous renewal of mature blood cells. While the importance of positive and negative cytokines in regulating proliferation and maturation of hematopoietic cells has been well documented, the factors and molecular processes involved in lineage commitment and self-renewal of multipotent progenitors have not yet been defined. In other developmental systems, cellular interactions mediated by members of the Notch gene family have been shown to influence cell fate determination by multipotent progenitors. We previously described the expression of the human Notch1 homolog, TAN-1, in immature hematopoietic precursors. We now demonstrate that constitutive expression of the activated intracellular domain of mouse Notch1 in 32D myeloid progenitors inhibits granulocytic differentiation and permits expansion of undifferentiated cells, findings consistent with the known function of Notch in other systems.

Generation of hematopoietic colony-forming cells from embryonic stem cells: synergy between a soluble factor from NIH-3T3 cells and hematopoietic growth factors.

Murine embryonic stem cells are able to differentiate into embryoid bodies (EBs) in vitro in the absence of leukemia-inhibitory factor with the formation of different types of hematopoietic precursors within these EBs. With the aim of determining the in vitro requirements for the continued development of hematopoietic colony-forming cells (CFCs) and their progeny from embryonic stem-derived cells, cells from EBs disrupted after 9 days of formation in the absence of leukemia-inhibitor factor were cultured under different conditions. Low numbers of day-9 EB cells (5 x 10(5) or less) cultured in the presence of several growth factors (interleukin-3 [IL-3], IL-1, c-kit ligand, basic fibroblast growth factor, insulin growth factor-1, IL-6, granulocyte colony-stimulating factor, fetal liver kinase-2 ligand) develop few or no CFCs after 1 week of culture. When these cells are plated on irradiated NIH-3T3 with IL-3 or c-kit ligand or combinations containing these and other growth factors, they are able to generate CFCs for at least 3 weeks. These cultures were found to include granulocytic, monocytic, erythrocytic, and megakaryocytic cells. Transwell cultures in which NIH-3T3 cells were separated from the EB cells and cultures in which cells were replaced by NIH-3T3 conditioned medium showed that the interaction between EB-derived cells and NIH-3T3 is via a soluble factor(s). These studies show that maximal generation of hematopoietic CFCs from precursors present in day-9 EBs is stimulated by a combination of known hematopoietic growth factors and a soluble factor(s) produced by NIH-3T3 cells.

A single dose of granulocyte colony-stimulating factor modifies radiation-induced death in B6D2F1 mice.

Granulocyte colony stimulating factor (G-CSF) stimulates the proliferation of progenitor cells committed to myeloid differentiation. In animal models, G-CSF is able to stimulate granulocyte recovery and promote survival after lethal or sublethal irradiation when administered as daily injections, suggesting an influence on the residual hematopoietic primitive precursors surviving irradiation. In this study, we clearly demonstrate that a single dose of G-CSF (1 mg/kg) administered to B6D2F1 mice 2 hours after a lethal dose 95/30 irradiation achieves a 78% survival at day +30 after irradiation. Survival of G-CSF treated mice compares favourably with that of syngenic bone marrow transplantation recipients (78% vs 90%, ns).