Effects of Delta1 and Jagged1 on early human hematopoiesis: correlation with expression of notch signaling-related genes in CD34+ cells

It has been shown that Notch signaling mediated by ligands of both Jagged and Delta families expands the hematopoietic stem cell compartment while blocking or delaying terminal myeloid differentiation. Here we show that Delta1- and Jagged1-expressing stromal cells have distinct effects on the clonogenic and differentiation capacities of human CD34(+) CD38(+) cells. Jagged1 increases the number of bipotent colony-forming unit-granulocyte macrophage (CFU-GM) and unipotent progenitors (CFU-granulocytes and CFU-macrophages), without quantitatively affecting terminal cell differentiation, whereas Delta1 reduces the number of CFU-GM and differentiated monocytic cells. Expression analysis of genes coding for Notch receptors, Notch targets, and Notch signaling modulators in supernatant CD34(+) cells arising upon contact with Jagged1 and Delta1 shows dynamic and differential gene expression profiles over time. At early time points, modest upregulation of Notch1, Notch3, and Hes1 was observed in Jagged1-CD34(+) cells, whereas those in contact with Delta1 strikingly upregulated Notch3 and Hes1. Later, myeloid progenitors with strong clonogenic potential emerging upon contact with Jagged1 upregulated Notch1 and Deltex and downregulated Notch signaling modulators, whereas T/NK progenitors originated by Delta1 strikingly upregulated Notch3 and Deltex and, to a lesser extent, Hes1, Lunatic Fringe, and Numb. Together, the data unravel previously unrecognized expression patterns of Notch signaling-related genes in CD34(+) CD38(+) cells as they develop in Jagged1- or Delta1-stromal cell environments, which appear to reflect sequential maturational stages of CD34(+) cells into distinct cell lineages.     

Jagged1 is the major regulator of notch‐dependent cell fate in proximal airways

Background: The Notch signaling pathway plays complex roles in developing lungs, including regulation of proximodistal fates, airway cell specification and differentiation. However, the specific Notch‐mediated signals involved in lung development remain unclear. Results: Here we report that Jagged1 is expressed in a subset of bronchial and bronchiolar epithelial cells, where it controls proximal airway cell fate and differentiation. In agreement with previous studies involving disruption of all Notch signaling, we found that deletion of Jagged1 in airway epithelium increased the number of ciliated cells at the expense of Clara cells, a phenotype associated with downregulation of Hes1. Deletion of Jagged1 also led to an increased number of pulmonary neuroendocrine cells (PNEC), suggesting that Jagged1/Notch signaling inhibits PNEC cell fate. As expected, Jagged1 deletion did not affect alveolar cell differentiation, although alveolar septation was impaired, likely an indirect effect of proximal airway defects. Finally, in the postnatal lung, Jagged1 deletion induced mucous metaplasia, accompanied by downregulation of Hes1 and Hes5. Conclusions: Our results demonstrate that Jagged1‐mediated Notch signaling regulates multiple cell fate decisions as well as differentiation in the respiratory system to coordinate lung development and to maintain a balance of airway cell types in adult life. Developmental Dynamics 242:678–686, 2013. © 2013 Wiley Periodicals, Inc.     

Disappearance of centroacinar cells in the Notch ligand‐deficient pancreas

Notch signaling has been shown to contribute to murine pancreatic development at various stages. Delta‐like 1 (Dll1) or Jagged1 (Jag1) are the Notch ligands that solely function to trigger this signaling during the pancreatic bud stage (~e9.5) or after birth, respectively. However, it has not been elucidated whether these Notch ligands are required at the later stage (e10.5–18.5) when the particular pancreas structures form. Here, we detected the dual expression of Dll1 and Jag1 in the epithelium after e10.5, which was restricted to the ductal cell lineage, including centroacinar cells expressing Sox9, CD133 and Hes1 but not the ductal cell markers Hnf1β and DBA, at e18.5. To evaluate the significance of the Notch ligands during this period, we established double‐floxed mice of Dll1 and Jag1 genes with Ptf1a‐Cre knock‐in allele and examined the effects on development. The abrogation of both ligands but not a single one led to the loss of centroacinar cells, which was due to the decrease in cell proliferation and the increase in cell death, as well as to the reduction of Sox9. These results suggested that Dll1 and Jag1 function redundantly and are necessary to maintain the centroacinar cells as an environmental niche in the developing pancreas.     

Expression pattern of notch1, 2 and 3 and Jagged1 and 2 in lymphoid and stromal thymus components: distinct ligand-receptor interactions in intrathymic T cell development.

The suggested role of Notch1 or its mutants in thymocyte differentiation and T cell tumorigenesis raises the question of how the different members of the Notch family influence distinct steps in T cell development and the role played by Notch ligands in the thymus. We report here that different Notch receptor-ligand partnerships may occur inside the thymus, as we observed differential expression of Notch1, 2 and 3 receptors, their ligands Jagged1 and 2, and downstream intracellular effectors hairy and Enhancer of Split homolog 1 (HES-1) and hairy and Enhancer of Split homolog 5 (HES-5), depending on ontogenetic stage and thymic cell populations. Indeed, while Jagged2 is expressed in both stromal cells and thymocytes, Jagged1 expression is restricted to stromal cells. Moreover, a differential distribution of Notch3, with respect to Notch1, was observed in distinct age-related thymocyte subsets. Finally, Notch3 was preferentially up-regulated in thymocytes, following the induction of their differentiation by interaction with thymic epithelial cells expressing the cognate Jagged1 and 2 ligands, suggesting that, besides Notch1, Notch3 may also be involved in distinct steps of thymocyte development. Our results suggest that the Notch signaling pathway is involved in a complex interplay of T cell developmental stages, as a consequence of the heterogeneity and specific expression of members of the Notch receptor family and their cognate ligands, in distinct thymic cell compartments.     

Expression and function of X chromosome-linked inhibitor of apoptosis protein in Sjögren's syndrome

Apoptotic cell death in acinar and ductal epithelial cells is thought to play an important role in the development of salivary gland dysfunction in patients with Sjogren's syndrome (SS). We examined the expression of anti-apoptotic molecules in salivary glands from patients with SS. The labial salivary glands from six human T-cell leukemia virus (HTLV)-I-seronegative and eleven HTLV-I-seropositive SS patients were analyzed by immunohistochemistry. In vitro experiments were performed with a human salivary gland cell line (HSG cells). Immunohistologic analyses revealed that Bcl-2 and Bcl-x were preferentially expressed in salivary infiltrating mononuclear cells more than acinar and ductal epithelial cells. In contrast, strong X chromosome-linked inhibitor of apoptosis protein (XIAP) expression was evident in both acinar and ductal epithelial cells. The pattern of expression of these anti-apoptotic molecules was similar in both HTLV-I-seropositive and HTLV-I -seronegative SS patients. Western blot analysis confirmed expression of XIAP in cultured HSG cells. The expression of XIAP in HSG cells was increased by IL-1beta, TGF-beta1, or IL-10. However, XIAP expression was down-regulated by TNF-alpha, which induced apoptotic cell death of HSG cells with an increase in caspase-3 activity. These effects of TNF-alpha in HSG cells were antagonized by IL-1beta, TGF-beta1, or IL-10. Our results suggest that XIAP is important in regulating apoptotic cell death of acinar and ductal epithelial cells in patients with SS.     

DLK1 Promotes Neurogenesis of Human and Mouse Pluripotent Stem Cell-Derived Neural Progenitors Via Modulating Notch and BMP Signalling

A better understanding of the control of stem cell maintenance and differentiation fate choice is fundamental to effectively realising the potential of human pluripotent stem cells in disease modelling, drug screening and cell therapy. Dlk1 is a Notch related transmembrane protein that has been reportedly expressed in several neurogenic regions in the developing brain. In this study, we investigated the ability of Dlk1 in modulating the maintenance and differentiation of human and mouse ESC-derived neural progenitors. We found that DLK1, either employed as an extrinsic factor, or via transgene expression, consistently promoted the generation of neurons in both the mouse and human ESC-derived neural progenitors. DLK1 exerts this function by inducing cell cycle exit of the progenitors, as evidenced by an increase in the number of young neurons retaining BrdU labelling and cells expressing the cycling inhibitor P57Kip2. DLK1 antagonised the cell proliferation activity of Notch ligands Delta 1 and Jagged and inhibited Hes1-mediated Notch signaling as demonstrated by a luciferase reporter assay. Interestingly, we found that DLK1 promotes the neurogenic potential of human neural progenitor cells via suppression of Smad activation when they are challenged with BMP. Together, our data demonstrate for the first time a regulatory role for DLK1 in human and mouse neural progenitor differentiation and establish an interaction between DLK1 and Hes1-mediated Notch signaling in these cells. Furthermore, this study identifies DLK1 as a novel modulator of BMP/Smad signalling.     

The Notch pathway mediates expansion of a progenitor pool and neuronal differentiation in adult neural progenitor cells after stroke

Molecular mechanisms by which stroke increases neurogenesis have not been fully investigated. Using neural progenitor cells isolated from the subventricular zone (SVZ) of the adult rat subjected to focal cerebral ischemia, we investigated the Notch pathway in regulating proliferation and differentiation of adult neural progenitor cells after stroke. During proliferation of neural progenitor cells, ischemic neural progenitor cells exhibited substantially increased levels of Notch, Notch intracellular domain (NICD), and hairy enhancer of split (Hes) 1, which was associated with a significant increase of proliferating cells. Blockage of the Notch pathway by short interfering ribonucleic acid (siRNA) against Notch or a γ secretase inhibitor significantly reduced Notch, NICD and Hes1 expression and cell proliferation induced by stroke. During differentiation of neural progenitor cells, Notch and Hes1 expression was downregulated in ischemic neural progenitor cells, which was coincident with a significant increase of neuronal population. Inhibition of the Notch pathway with a γ secretase inhibitor further substantially increased neurons, but did not alter astrocyte population in ischemic neural progenitor cells. These data suggest that the Notch signaling pathway mediates adult SVZ neural progenitor cell proliferation and differentiation after stroke.     

Notch1/Hes1信号调控C/EBPα表达对AECII细胞增殖与分化的影响

目的:探讨Notch1/Hes1信号通路能否通过调控CCAAT/增强子结合蛋白α(C/EBPα)的表达从而影响肺泡Ⅱ型上皮细胞(AECⅡ)的增殖与分化功能。方法:体外培养人AECⅡ,将细胞随机分为对照组、激活剂组(加入Notch通路激活剂Jagged1蛋白500μg/L)和抑制剂组(加入Notch通路抑制剂DAPT 10μmol/L),于干预后24 h收获各组细胞。采用RT-qPCR和Western blot法分别检测Notch1、Hes1及C/EBPα的mRNA与蛋白表达水平;CCK-8法检测细胞活力;细胞计数检测细胞增殖;流式细胞术检测细胞周期及分化。结果:与对照组相比,激活剂组Notch1、Hes1和C/EBPα的mRNA和蛋白表达显著增加(P0.05),促进AECⅡ从S期进入G_2/M期,增殖增加而分化减少(P0.05);抑制剂组Notch1、Hes1和C/EBPαmRNA和蛋白表达水平明显降低(P0.05),AECⅡ被阻滞于G_0/G_1期,增殖减少而分化增加(P0.05)。结论:Notch1/Hes1信号可调控C/EBPα表达并能影响AECⅡ增殖与分化。     

Human ligands of the Notch receptor

During development, the Notch signaling pathway is essential for the appropriate differentiation of many cell types in organisms across the phylogenetic scale, including humans. Notch signaling is also implicated in human diseases, including a leukemia and two hereditary syndromes known as Alagille and CADASIL. To generate tools for pursuing the role of the Notch pathway in human disease and development, we have cloned and analyzed the expression of three human homologues of the Notch ligands Delta and Serrate, human Jagged1 (HJ1), human Jagged2 (HJ2), and human Delta1 (H-Delta-1), and determined their chromosomal localizations. We have also raised antibodies to HJ1, and used these antibodies in conjunction with in situ hybridization to examine the expression of these ligands in normal and cancerous cervical tissue. We find that, as reported previously for Notch, the ligands are up-regulated in certain neoplastic tissues. This observation is consistent with the notion that Notch signaling is an important element in these pathogenic conditions, raising the possibility that modulation of Notch activity could be used to influence the fate of the cells and offering a conceivable therapeutic avenue.     

Eosinophilic differentiation is promoted by blockage of Notch signaling with a gamma-secretase inhibitor

Although increasing evidence supports the inhibitory role of Notch in granulocyte differentiation, the direct effects of Notch on the differentiation and maturation of eosinophils, one type of granulocyte, have not yet been studied. We investigated whether a blockage of Notch signaling promoted the differentiation of eosinophils from umbilical cord blood (UCB) cells. Freshly isolated UCB cells were cultured with IL-3, IL-5 and GM-CSF in the presence or absence of a gamma-secretase inhibitor L-685,458, and examined for the expression of major basic protein (MBP). Freshly isolated UCB cells expressed mRNA and proteins for Notch 1, Notch 2, Delta 1, and Jagged 1. MBP expression in cultures with the inhibitor was significantly increased, as compared with the cultures in the absence of the inhibitor. Treatment with the inhibitor was accompanied by a decrease in Hes 1 mRNA expression, indicative of Notch-mediated signaling for the inhibitor effect. UCB cells cultured with the inhibitor for 28 days displayed similar levels of CCR3, a late marker of eosinophil development, as compared with the cells cultured without the inhibitor, but almost completely lost chemotaxis response to eotaxin. Our data suggest that Notch signaling may modulate eosinophil migration at the mature stage as well as inhibit eosinophil differentiation.     

Altered Notch ligand expression in human liver disease: further evidence for a role of the Notch signaling pathway in hepatic neovascularization and biliary ductular defects

The Jagged and Delta family of transmembrane proteins are ligands for Notch receptors, which control the proliferation and/or differentiation of many cell lineages. Expression and localization of these ligands in the adult human liver has not been fully elucidated, nor whether dysregulation of these proteins contributes to liver disease processes. We have examined expression of the five known Notch ligands in human liver. Expression of Jagged-1 and Delta-4 mRNA was seen in normal and diseased liver tissue, whereas Jagged-2, Delta-1, and Delta-3 mRNA was undetectable. In primary liver cell isolates, Jagged-1 expression was found in all cell types, whereas Delta-4 was present in biliary epithelial and liver endothelial cells, but absent in hepatocytes. Interestingly, Jagged-1 mRNA expression was significantly up-regulated in diseased liver tissue. By immunohistochemistry, Jagged-1 expression was present on most structures in normal tissue. However in disease, strikingly strong Jagged-1 immunoreactivity was observed on many small neovessels and bile ductules. The expression of downstream modulators and effectors of Notch signaling was also detectable in purified cell isolates. This, together with aberrant Jagged-1 expression suggests that the Notch signaling pathway may play a role in the neovascularization and biliary defects observed in the liver during the development of cirrhosis.     

Hes1 regulates embryonic stem cell differentiation by suppressing Notch signaling

Embryonic stem (ES) cells display heterogeneous responses upon induction of differentiation. Recent analysis has shown that Hes1 expression oscillates with a period of about 3–5 h in mouse ES cells and that this oscillating expression contributes to the heterogeneous responses: Hes1‐high ES cells are prone to the mesodermal fate, while Hes1‐low ES cells are prone to the neural fate. These outcomes of Hes1‐high and Hes1‐low ES cells are very similar to those of inactivation and activation of Notch signaling, respectively. These results suggest that Hes1 and Notch signaling lead to opposite outcomes in ES cell differentiation, although they work in the same direction in most other cell types. Here, we found that Hes1 acts as an inhibitor but not as an effector of Notch signaling in ES cell differentiation. Our results indicate that sustained Hes1 expression delays the differentiation of ES cells and promotes the preference for the mesodermal rather than the neural fate by suppression of Notch signaling.     

Calsenilin Contributes to Neuronal Cell Death in Ischemic Stroke

Calsenilin is a calcium sensor protein that interacts with presenilin and increases calcium‐triggered neuronal apoptosis, and γ‐secretase activity. Notch is a cell surface receptor that regulates cell‐fate decisions and synaptic plasticity in brain. The aim of the present study was to characterize the role of calsenilin as a regulator of the γ‐secretase cleavage of Notch in ischemic stroke. Here, we determined the modulation of expression level and cellular distribution of calsenilin in neurons subjected to ischemic‐like conditions. The levels of calsenilin and presenilin were increased in primary neurons after oxygen and glucose deprivation. Furthermore, calsenilin was found to enhance the γ‐secretase cleavage of Notch and to contribute to cell death under ischemia‐like conditions. The inhibition of γ‐secretase activity and a presenilin deficiency were both found to protect against calsenilin‐mediated ischemic neuronal death. The expression of calsenilin was found to be increased in brain following experimental ischemic stroke. These findings establish a specific molecular mechanism by which the induction of calsenilin enhances Notch activation in ischemic stroke, and identify calsenilin as an upstream of the γ‐secretase cleavage of Notch.     

Hes1 regulates corneal development and the function of corneal epithelial stem/progenitor cells

Hes1, a major target gene in Notch signaling, regulates the fate and differentiation of various cell types in many developmental systems. To gain a novel insight into the role of Hes1 in corneal tissue, we performed gain-of-function and loss-of-function studies. We show that corneal development was severely disturbed in Hes1-null mice. Hes1-null corneas manifested abnormal junctional specialization, cell differentiation, and less cell proliferation ability. Worthy of note, Hes1 is expressed mainly in the corneal epithelial stem/progenitor cells and is not detected in the differentiated corneal epithelial cells. Expression of Hes1 is closely linked with corneal epithelial stem/progenitor cell proliferation activity in vivo. Moreover, forced Hes1 expression inhibits the differentiation of corneal epithelial stem/progenitor cells and maintains these cells' undifferentiated state. Our data provide the first evidence that Hes1 regulates corneal development and the homeostatic function of corneal epithelial stem/progenitor cells.     

Liver sinusoidal endothelial cells induce immunosuppressive IL‐10‐producing Th1 cells via the Notch pathway

Under homeostasis, liver sinusoidal endothelial cells (LSECs) shift intrahepatic T‐cell responses towards tolerance. However, the role of LSECs in the regulation of T‐cell‐induced liver inflammation is less clear. Here, we studied the capacity of LSECs to modulate pro‐inflammatory Th1‐cell differentiation in mice. Using in vitro co‐culture systems and subsequent cytokine analysis, we showed that LSECs induced high amounts of the anti‐inflammatory cytokine IL‐10 in developing Th1 cells. These LSEC‐stimulated Th1 cells had no pro‐inflammatory capacity in vivo but instead actively suppressed an inflammatory Th1‐cell‐induced delayed‐type hypersensitivity reaction. Blockage of IL‐10 signaling in vivo inhibited immunosuppressive activity of LSEC‐stimulated Th1 cells. We identified the Notch pathway as a mechanism how LSECs trigger IL‐10 expression in Th1 cells. LSECs expressed high levels of the Delta‐like and Jagged family of Notch ligands and induced expression of the Notch target genes hes‐1 and deltex‐1 in Th1 cells. Blockade of Notch signaling selectively inhibited IL‐10 induction in Th1 cells by LSECs. Our findings suggest that LSEC‐induced IL‐10 expression in Th1 cells via the Notch pathway may contribute to the control of hepatic inflammatory immune responses by induction of a self‐regulatory mechanism in pro‐inflammatory Th1 cells.