The intracellular domain of Jagged-1 interacts with Notch1 intracellular domain and promotes its degradation through Fbw7 E3 ligase

Notch signaling involves the proteolytic cleavage of the transmembrane Notch receptor after binding to its transmembrane ligands. Jagged-1 also undergoes proteolytic cleavage by gamma-secretase and releases an intracellular fragment. In this study, we have demonstrated that the Jagged-1 intracellular domain (JICD) inhibits Notch1 signaling via a reduction in the protein stability of the Notch1 intracellular domain (Notch1-IC). The formation of the Notch1-IC-RBP-Jk-Mastermind complex is prevented in the presence of JICD, via a physical interaction. Furthermore, JICD accelerates the protein degradation of Notch1-IC via Fbw7-dependent proteasomal pathway. These results indicate that JICD functions as a negative regulator in Notch1 signaling via the promotion of Notch1-IC degradation.     

RUNX3 directly interacts with intracellular domain of Notch1 and suppresses Notch signaling in hepatocellular carcinoma cells

RUNX3 takes a strong suppressive effect in many tumors including hepatocellular carcinoma (HCC). HES-1, a downstream target of Notch signaling, is shown to be decreased in human HCC cell line SMMC7721 with RUNX3 gene transfection. Since Notch signaling is oncogenic in HCC, RUNX3 might exert its inhibitory effect in HCC partly through the suppression on Notch signaling. To investigate the possible mechanism of the down-regulation of HES-1 by RUNX3, we performed Western blot and reporter assay and found that RUNX3 suppressed intracellular domain of Notch1 (ICN1)-mediated transactivation of Notch signaling while it did not alter the expression of ICN1 and recombination signal binding protein-Jκ (RBP-J) in SMMC7721 cells. Besides, confocal microscopy, co-immunoprecipitation and GST pull-down assays showed that RUNX3 could co-localize with ICN1 and RBP-J, forming a complex with these two molecules in nucleus of SMMC7721 cells by its direct interaction with ICN1. Furthermore, RUNX3 was recruited to RBP-J recognition motif of HES-1 promoter, which was identified by chromatin immunoprecipitation (ChIP) and electrophoretic mobility shift assay (EMSA). Taken together, these findings indicate that RUNX3 suppresses Notch signaling in HCC SMMC7721 cells by its interaction with ICN1 and thus recruitment to the RBP-J recognition motif of downstream genes of Notch signaling.     

Notch1 and the activated NOTCH1 intracellular domain are expressed in differentiated trophoblast cells

The Notch signalling pathway regulates proliferation, cell death and cell type specification that is critical for organogenesis. Mouse models carrying mutations in the Notch signalling pathway display defects in development of the placenta, suggesting that this pathway is required for placental development. In particular, Notch1 mutant embryos exhibit abnormal placental morphogenesis and arrest early in development. However, expression of Notch1 gene has not been detected during placental development. Trophoblast stem cells are derived from the precursor of the placenta and express Notch1. We report that Notch1 is also expressed in differentiated trophoblast cells. Under standard differentiation conditions, Notch1 expression ceases by day 6. Furthermore, the activated NOTCH1 intracellular domain is enriched at the nucleolus of trophoblast stem cells and differentiated trophoblast cells. Our results suggest that NOTCH1 is active in both trophoblast stem cells and differentiated trophoblast cells.     

Autophagy regulates biliary differentiation of hepatic progenitor cells through Notch1 signaling pathway

Autophagy plays important roles in self-renewal and differentiation of stem cells. Hepatic progenitor cells (HPCs) are thought to have the ability of self-renewal as well as possess a bipotential capacity, which allows them to differentiate into both hepatocytes and bile ductular cells. However, how autophagy contributes to self-renewal and differentiation of hepatic progenitor cells is not well understood. In this study, we use a well-established rat hepatic progenitor cell lines called WB-F344, which is treated with 3.75 mM sodium butyrate (SB) to promote the differentiation of WB-F344 along the biliary phenotype. We found that autophagy was decreased in the early stage of biliary differentiation, and maintained a low level at the late stage. Activation of autophagy by rapamycin or starvation suppressed the biliary differentiation of WB-F344. Further study reported that autophagy inhibited Notch1 signaling pathway, which contributed to biliary differentiation and morphogenesis. In conclusions, autophagy regulates biliary differentiation of hepatic progenitor cells through Notch1 signaling pathway.     

MT1-MMP cleaves Dll1 to negatively regulate Notch signalling to maintain normal B-cell development

Notch signalling controls the differentiation of haematopoietic progenitor cells (HPCs). Here, we show that loss of membrane-type 1 matrix metalloproteinase (MT1-MMP, MMP14), a cell surface protease expressed in bone marrow stromal cells (BMSCs), increases Notch signalling in HPCs and specifically impairs B-lymphocyte development. When co-cultured with BMSCs in vitro, HPCs differentiation towards B lymphocytes is significantly compromised on MT1-MMP-deficient BMSCs and this defect could be completely rescued by DAPT, a specific Notch signalling inhibitor. The defective B-lymphocyte development could also be largely rescued by DAPT in vivo. MT1-MMP interacts with Notch ligand Delta-like 1 (Dll1) and promotes its cleavage on cell surface in BMSCs. Ectopic MT1-MMP cleaves Dll1 and results in diminished Notch signalling in co-cultured cells. In addition, recombinant MT1-MMP cleaves a synthetic Dll1 peptide at the same site where MT1-MMP cleaves Dll1 on the cell surface. Our data suggest that MT1-MMP directly cleaves Dll1 on BMSCs to negatively regulate Notch signalling to specifically maintain normal B-cell development in bone marrow.     

Regulation of active and quiescent somatic stem cells by Notch signaling

Somatic stem/progenitor cells actively proliferate and give rise to different types of mature cells (active state) in embryonic tissues while they are mostly dormant (quiescent state) in many adult tissues. Notch signaling is known to regulate both active and quiescent states of somatic stem cells, but how it regulates these different states is unknown. Recent studies revealed that the Notch effector Hes1 is expressed differently during the active and quiescent states during neurogenesis and myogenesis: high in the quiescent state and oscillatory in the active state. When the Hes1 expression level is high, both Ascl1 and MyoD expression are continuously suppressed. By contrast, when Hes1 expression oscillates, it periodically represses expression of the neurogenic factor Ascl1 and the myogenic factor MyoD, thereby driving Ascl1 and MyoD oscillations. High levels of Hes1 and the resultant Ascl1 suppression promote the quiescent state of neural stem cells, while Hes1 oscillation-dependent Ascl1 oscillations regulate their active state. Similarly, in satellite cells of muscles, known adult muscle stem cells, high levels of Hes1 and the resultant MyoD suppression seem to promote their quiescent state, while Hes1 oscillation-dependent MyoD oscillations activate their proliferation and differentiation. Therefore, the expression dynamics of Hes1 is a key regulatory mechanism of generating and maintaining active/quiescent stem cell states.     

YTHDF2 Suppresses Notch Signaling through Post-transcriptional Regulation on Notch1

YTH domain family 2 (YTHDF2) is an N6-methyladenosine (m⁶A) binding protein promoting mRNA degradation in various biological processes. Despite its essential roles, the role of YTHDF2 in determining cell fates has not been fully elucidated. Notch signaling plays a vital role in determining cell fates, such as proliferation, differentiation, and apoptosis. We investigated the effect of YTHDF2 on Notch signaling. Our results show that YTHDF2 inhibits Notch signaling by downregulating the Notch1, HES1, and HES5 mRNA levels. Analyzing YTHDF2 deletion mutants indicates that the YTH domain is critical in regulating the Notch signal by directly binding m⁶A of Notch1 mRNA. Recently, YTHDF2 nuclear translocation was reported under heat shock conditions, but its physiological function is unknown. In our study, the YTH domain is required for YTHDF2 nuclear translocation. In addition, under heat shock stress, the Notch signal was significantly restored due to the increased expression of the Notch1 targets. These results suggest that YTHDF2 in the cytoplasm may act as an intrinsic suppressor in Notch signaling by promoting Notch1 mRNA degradation under normal cellular conditions. Conversely, upon the extracellular stress such as heat shock, YTHDF2 nuclear translocation resulting in reduced Notch1 mRNA decay may contribute to the increasing of Notch intracellular domain (NICD) regulating the survival-related target genes.     

Mutations at the P1' position of Notch1 decrease intracellular domain stability rather than cleavage by gamma-secretase

Gamma-secretase is a unique protease which cleaves within the transmembrane domain of several substrate proteins. Among gamma-secretase substrates are members of the Notch family of receptors and the amyloid precursor protein. In this study we used a cell-free Notch-cleavage assay and specific gamma-secretase inhibitors to study the cleavage of Notch by gamma-secretase. Using this assay, we found that, in contrast to previous reports, the presence of valine at the P1(') position of Notch1 is not required for gamma-secretase cleavage. Our results suggest that the presence of valine at the N-terminus of the Notch intracellular domain cleavage product is important for its stability. Thus it appears that Notch cleavage is very similar to APP cleavage with respect to the lack of sequence specificity.     

Regulation of skeletal myogenesis by Notch

Notch signaling has emerged as a key player in skeletal muscle development and regeneration. Simply stated, Notch signaling inhibits differentiation. Accordingly, fine-tuning the pathway is essential for proper muscle homeostasis. This review will address various aspects of Notch signaling, including our current views of the core pathway, its effects in muscle, its interactions with other signaling pathways, and its relationship with ageing.     

CADASIL-associated Notch3 mutations have differential effects both on ligand binding and ligand-induced Notch3 receptor signaling through RBP-Jk

Mutations in the NOTCH3 gene are the cause of cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL), a hereditary angiopathy leading to strokes and dementia. Pathogenic mutations remove or insert cysteine residues within epidermal growth factor (EGF) repeats in the extracellular domain of the Notch3 receptor (N3ECD). Vascular smooth muscle cells (VSMC) are the predominant site of Notch3 expression in adults. In CADASIL patients, VSMC degenerate and N3ECD is deposited within the vasculature. However, the mechanisms underlying VSMC degeneration and N3ECD accumulation are still unknown. In this study, we investigated the consequences of three pathogenic Notch3 mutations on the biological activity of the receptor by analyzing ligand (Delta-/Jagged-)-induced signaling via RBP-Jk. Two mutations (R133C and C183R) that are located outside the putative ligand binding domain (LBD) of the receptor were found to result in normal Jagged1-induced signaling in A7r5 VSMC, whereas the third mutation (C455R located within the putative LBD) showed strongly reduced signaling activity. Ligand binding assays with soluble Delta1 and Jagged1 revealed that C455R interferes with ligand binding through disruption of the LBD which, as we show here, is located in EGF repeats 10/11 of Notch3. All mutant receptors including Notch3C455R were targeted to the cell surface but showed an elevated ratio between the unprocessed full-length 280-kDa receptor and S1-cleaved receptor fragments. Taken together, these data indicate that CADASIL-associated Notch3 mutations differ with respect to their consequences both on ligand binding and ligand-induced signaling through RBP-Jk, whereas they have similar effects on receptor maturation. Moreover, the data suggest that ligand-induced receptor shedding may not be required for N3ECD deposition in CADASIL.     

Polycomb Ezh1 maintains murine muscle stem cell quiescence through non-canonical regulation of Notch signaling

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Dll4-selective Notch signaling induces ephrinB2 gene expression in endothelial cells

The Notch pathway is involved in multiple aspects of vascular development, including arterial-venous differentiation. Here, we show that Notch stimulation instructively induces arterial characteristics in endothelial cells (EC). Forced expression of Notch intracellular domain (NICD, activated form of Notch) induced mRNA expression for a subset of arterial-specific markers such as ephrinB2, connexin40, and HERP1 only in EC but not other cell lines. In co-culture experiments using EC and either Dll4- or Jagged1-expressing cells, we found that Dll4 stimulation but not Jagged1 markedly induced ephrinB2 expression. An inducible expression of HERP1 and HERP2 by NICD has no measurable effects on expression of ephrinB2 and venous marker EphB4 although either HERP1 or HERP2 overexpression exerts potent inhibitory effects on EphB4 expression without ephrinB2 induction. We also found no functional interaction between Notch and TGF-beta-ALK1 signalings in an induction of ephrinB2 expression. These results suggest that Dll4-stimulated Notch signaling induces a part of arterial characteristics only in EC via HERP-independent mechanism. Our data provide new insight into the molecular mechanism of ligand-selective Notch activation during differentiation of arterial EC.