Project description:Notch signaling plays a pivotal role in liver development and aberrant Notch signaling may lead to hepatocellular (HCC) or cholangiocellular carcinoma (CCA) development. Using whole exome sequencing of 54 human HCC samples, we discovered 19 somatic missense mutations in 15 different Notch pathway genes affecting 24.6% (14 of 57) of patients. Prediction of functional impact of these Notch pathway mutations revealed HES5-R31G to have high relevance. We found HES5 to be strongly activated by Notch signaling. In vitro, HES5 reduced cell migration and clonogenicity and in vivo, HES5 inhibited MYC-dependent liver tumor formation. But together with AKT, HES5 increased liver tumor formation in a mouse model. HES5 directly binds to AKT and AKT expression leads to increase HES5 protein levels. Furthermore, HES5 exhibits a negative feed-back loop by inhibiting NOTCH1 and HES1 gene expression. In contrast, HES5-R31G appears to be non-functional possibly by loss of nuclear translocation

Project description:Notch signaling plays a role in specifying a cardiac fate but the downstream effectors remain unknown. In this study we implicate the Notch downstream effector HES5 in cardiogenesis. We show transient Hes5 expression in early mesoderm of gastrulating embryos and demonstrate, by loss and gain-of-function experiments in mouse embryonic stem cells, that HES5 favors cardiac over primitive erythroid fate. Hes5 overexpression promotes upregulation of the cardiac gene Isl1, while the hematopoietic regulator Scl is downregulated. Moreover, whereas a pulse of Hes5 instructs cardiac commitment, sustained expression after lineage specification impairs progression of differentiation to contracting cardiomyocytes. These findings establish a role for HES5 in cardiogenesis and provide insights into the early cardiac molecular network.

Project description:Insufficient insulin secretion is a hallmark of type 2 diabetes and has been attributed to beta cell identity loss characterized by a decreased expression of several key beta cell genes. The pro-inflammatory factor BMP-2 is upregulated in islets of Langerhans from diabetic individuals and acts as an inhibitor of beta cell function and proliferation. Exposure to BMP-2 induces expression of Id1-4, Hes-1 and Hey-1, transcriptional regulators associated with loss of differentiation. The aim of this study was to investigate the mechanism of BMP-2 induced beta cell dysfunction and identity loss. Mouse islets exposed to BMP-2 for 10 days showed impaired insulin secretion and beta cell proliferation. BMP-2-induced beta cell dysfunction was associated with decreased expression of beta cell specific identity and proliferation markers such as Ins1, Ucn3 and Ki67 but increased expression of Id1-4, Hes-1 and Hey-1. BMP-2 regulated mRNA expression significantly correlated with corresponding protein expression. BMP-2 induced gene expression changes were associated with a predominant reduction in the H3K27ac mark and a decrease in NeuroD1 chromatin binding activity. These results show that BMP-2-induced beta cell dysfunction is associated with epigenetic changes, predominantly a reduction in H3K27ac and a decrease in NeuroD1 DNA binding resulting in altered beta cell gene expression.

Project description:Decoding heterogeneity of pluripotent stem cell (PSC)-derived neural progeny is fundamental for revealing the origin of diverse progenitors, for defining their lineages, and for identifying fate determinants driving transition through distinct potencies. Here we prospectively isolated consecutively appearing PSC-derived primary progenitors based on their Notch activation state. We first isolate early neuroepithelial cells and show their broad Notch-dependent developmental and proliferative potential. Neuroepithelial cells further yield successive Notch-dependent functional primary progenitors, from early and mid neurogenic radial glia and their derived basal progenitors, to gliogenic radial glia and adult-like neural progenitors, together recapitulating hallmarks of neural stem cell (NSC) ontogeny. Gene expression profiling reveals dynamic stage specific transcriptional patterns that may link development of distinct progenitor identities through Notch activation. Our observations provide a platform for characterization and manipulation of distinct progenitor cell types amenable for developing streamlined neural lineage specification paradigms for modeling development in health and disease. Human embryonic stem cells (hESCs) H9 were differentiated into 5 distinct populations of neural precursor cells (NPCs) over a time course of 200 days. Each neural precursor populations was then sorted for HES5 expression based on a GFP-HES5 reporter. Both the HES5 positive and HES5 negative populations were then subjected to microarray profiling in singlicate, as well as the hESCs using GeneChipPrimeView Human Gene Expression Array

Project description:NOTCH/RBPJ/MAML ternary transcriptional complex binds to regulatory element and drives gene expression. The complex can function as monomer and dimer. How dimeric complexes regulate gene expression in human cancer is not well studied. Here, we integrate genomic data sets and analyze Notch dimeric complexes-regulated transcriptome and cis-regulatory elements. A subset of coding and non-coding RNA is Notch dimeric complexes-associated. Dimeric complexes recognition sequence enriched in functional dynamic Notch sites and majority of dimer recognition sequence located in (super-)enhancers. Using CRISPR-Cas9-mediated genome editing, we evaluated the function of one dimer-responsive element located in the promoter region of a noncoding RNA NDANR1 and 5' end 16kb away from HES5. Mutation of SPS in this element reduced expression of HES5 and NDANR1. This finding indicates that dimer-responsive elements can function as enhancer for HES5 and at the same time can function as promoter for noncoding RNA NDANR1. Our study reveals the pervasive role of Notch dimeric complexes in transcriptional regulation in human cancer genome.

Project description:In T-cell acute lymphoblastic leukemia (T-ALL) NOTCH 1 receptors are frequently mutated. This leads to aberrantly high Notch signaling, but how this translates into deregulated cell cycle control and the transformed cell type is poorly understood. In this report, we analyze downstream responses resulting from the high level of NOTCH 1 signaling in T-ALL. Notch activity, measured immediately downstream of the NOTCH 1 receptor, is high, but expression of the canonical downstream Notch response genes HES 1 and HEY 2 is low both in primary cells from T-ALL patients and in T-ALL cell lines. This suggests that other immediate Notch downstream genes are activated, and we found that Notch signaling controls the levels of expression of the E3 ubiquitin ligase SKP2 and its target protein p27Kip1. We show that in T-ALL cell lines, recruitment of NOTCH 1 ICD to the SKP2 promoter was accompanied by high SKP2 and low p27Kip1 protein levels were low. In contrast, pharmacologically blocking Notch signaling reversed this picture and led to loss of NOTCH 1 ICD occupancy of the SKP2 promoter, decreased SKP2 and increased p27Kip1 expression. T-ALL cells show a rapid G1-S cell cycle transition, while blocked Notch signaling resulted in G0/G1 cell cycle arrest, also observed by transfection of p27Kip1 or, to a smaller extent, a dominant negative SKP2 allele. Collectively, our data suggest that the aberrantly high Notch signaling in T-ALL maintains SKP2 at a high level and reduces p27Kip1, which leads to more rapid cell cycle progression. Experiment Overall Design: Three independent cultures of the MOLT4 cell line before and 48 hours after addition of the gamma-secretase inhibitor DAPT (5 uM).

Project description:In T-cell acute lymphoblastic leukemia (T-ALL) NOTCH 1 receptors are frequently mutated. This leads to aberrantly high Notch signaling, but how this translates into deregulated cell cycle control and the transformed cell type is poorly understood. In this report, we analyze downstream responses resulting from the high level of NOTCH 1 signaling in T-ALL. Notch activity, measured immediately downstream of the NOTCH 1 receptor, is high, but expression of the canonical downstream Notch response genes HES 1 and HEY 2 is low both in primary cells from T-ALL patients and in T-ALL cell lines. This suggests that other immediate Notch downstream genes are activated, and we found that Notch signaling controls the levels of expression of the E3 ubiquitin ligase SKP2 and its target protein p27Kip1. We show that in T-ALL cell lines, recruitment of NOTCH 1 ICD to the SKP2 promoter was accompanied by high SKP2 and low p27Kip1 protein levels were low. In contrast, pharmacologically blocking Notch signaling reversed this picture and led to loss of NOTCH 1 ICD occupancy of the SKP2 promoter, decreased SKP2 and increased p27Kip1 expression. T-ALL cells show a rapid G1-S cell cycle transition, while blocked Notch signaling resulted in G0/G1 cell cycle arrest, also observed by transfection of p27Kip1 or, to a smaller extent, a dominant negative SKP2 allele. Collectively, our data suggest that the aberrantly high Notch signaling in T-ALL maintains SKP2 at a high level and reduces p27Kip1, which leads to more rapid cell cycle progression. Keywords: comparative genomic hybridization

Project description:Notch signaling plays a pivotal role in liver development and aberrant Notch signaling may lead to hepatocellular (HCC) or cholangiocellular carcinoma (CCA) development. Using whole exome sequencing of 54 human HCC samples, we discovered 19 somatic missense mutations in 15 different Notch pathway genes affecting 24.6% (14 of 57) of patients. Prediction of functional impact of these Notch pathway mutations revealed HES5-R31G to have high relevance.

Project description:The microarray gene expression analysis revealed that TCF-4 isoforms activate different downstream target genes in HCC. TCF-4J upregulated genes associated with Wnt/beta-catenin, Notch, and insulin/IGF-1/IRS1 signal transduction pathway. 1 HAK-1A HCC clone overexpressing TCF-4J, 1 HAK-1A HCC clone overexpressing TCF-4K

Project description:Excessive activation of Hes causes stem cell hyperplasia in larval CNS. Transcriptomics of Notch induced hyperplasia and Hes induced hyperplasia were compared Using affymetrix microarray, global gene expression analysis was performed.