Notch promotes epithelial-mesenchymal transition during cardiac development and oncogenic transformation
Epithelial-to-mesenchymal transition (EMT) is fundamental to both embryogenesis and tumor metastasis. The Notch intercellular signaling pathway regulates cell fate determination throughout metazoan evolution, and overexpression of activating alleles is oncogenic in mammals. Here we demonstrate that Notch activity promotes EMT during both cardiac development and oncogenic transformation via transcriptional induction of the Snail repressor, a potent and evolutionarily conserved mediator of EMT in many tissues and tumor types. In the embryonic heart, Notch functions via lateral induction to promote a selective transforming growth factor- (TGF)-mediated EMT that leads to cellularization of developing cardiac valvular primordia. Embryos that lack Notch signaling elements exhibit severely attenuated cardiac snail expression, abnormal maintenance of intercellular endocardial adhesion complexes, and abortive endocardial EMT in vivo and in vitro. Accordingly, transient ectopic expression of activated Notch1 (N1IC) in zebrafish embryos leads to hypercellular cardiac valves, whereas Notch inhibition prevents valve development. Overexpression of N1IC in immortalized endothelial cells in vitro induces EMT accompanied by oncogenic transformation, with corresponding induction of snail and repression of VE-cadherin expression. Notch is expressed in embryonic regions where EMT occurs, suggesting an intimate and fundamental role for Notch, which may be reactivated during tumor metastasis.[Keywords: Notch; endocardium; lateral induction; EMT; snail; TGF] Supplemental material is available at http://www.genesdev.org. Epithelial-to-mesenchymal transition (EMT) is fundamental to both normal development and the progression of malignant epithelial tumors (for review, see Thiery 2002). During EMT, epithelial cells undergo sweeping alterations in gene expression to lose apical/basolateral polarity, sever intercellular adhesive junctions, degrade basement membrane components, and become migratory. Several signaling pathways seem to be common to EMT regulation during both development and tumor progression, leading to the notion that developmentally regulated EMT and tumor metastasis are under the control of common molecular mechanisms (Thiery 2002), and raising the hypothesis that tumor metastasis could be regarded as a reactivation of at least some aspects of the embryonic program of EMT.The snail family of Zinc-finger-containing transcriptional repressors is believed to play a pivotal role in the process of EMT (Nieto 2002). Expression of various snail family members has been tightly associated with cells undergoing both metastatic and developmental EMT (Nieto et al. 1992;Romano and Runyan 2000). One important target of Snail repression is the E-cadherin gene, the primary cadherin that is responsible for homotypic adhesion between members of an epithelial sheet (Batlle et al. 2000;Cano et al. 2000).A classical example of developmentally regulated EMT occurs during the initial stages of cardiac morphogenesis. At embryonic day 8.5 (E8.5...
(HE) S U M M A R Y The development of efficient, reproducible protocols for directed in vitro differentiation of human embryonic stem (hES) cells into insulin-producing b cells will benefit greatly from increased knowledge regarding the spatiotemporal expression profile of key instructive factors involved in human endocrine cell generation. Human fetal pancreases 7 to 21 weeks of gestational age, were collected following consent immediately after pregnancy termination and processed for immunostaining, in situ hybridization, and real-time RT-PCR expression analyses. Islet-like structures appear from approximately week 12 and, unlike the mixed architecture observed in adult islets, fetal islets are initially formed predominantly by aggregated insulin-or glucagon-expressing cells. The period studied (7-22 weeks) coincides with a decrease in the proliferation and an increase in the differentiation of the progenitor cells, the initiation of NGN3 expression, and the appearance of differentiated endocrine cells. The present study provides a detailed characterization of islet formation and expression profiles of key intrinsic and extrinsic factors during human pancreas development. This information is beneficial for the development of efficient protocols that will allow guided in vitro differentiation of hES cells into insulin-producing cells.
Self-antigen–presenting cells expressing diabetes-associated autoantigens exist in both thymus and peripheral lymphoid organs
Recent reports indicate that genes with tissue-restricted expression, including those encoding the type 1 diabetes autoantigens insulin, glutamic acid decarboxylase (GAD), and the tyrosine-phosphatase-like protein IA-2 (or ICA512), are transcribed in the thymus. The reported modulation of diabetes susceptibility by genetically determined differences in thymic insulin levels and studies in transgenic mice provide correlative and functional evidence that thymic expression of peripheral proteins is crucial for immunological self-tolerance. However, there are no specific data about the existence, tissue distribution, phenotype, and function of those cells that express insulin and other self-antigens in the human thymus. We find that the human thymus harbors specialized cells synthesizing (pro)insulin, GAD, and IA-2, mainly localized in the medulla, and we demonstrate such cells also in peripheral lymphoid organs (spleen and lymph nodes). Phenotypic analysis qualifies these cells as antigen-presenting cells (APCs), including both dendritic cells and macrophages. These cells often appear surrounded by apoptotic lymphocytes, both in thymus and spleen, and may therefore be involved in the deletion of autoreactive lymphocytes. Our findings demonstrate the existence of, and define the tissue distribution and phenotype of, a novel subset of APCs expressing self-antigens in human lymphoid organs that appear to be involved in the regulation of self-tolerance throughout life.
Extracellular ATP has been proposed as a paracrine signal in rodent islets, but it is unclear what role ATP plays in human islets. We now show the presence of an ATP signaling pathway that enhances the human β cell's sensitivity and responsiveness to glucose fluctuations. By using in situ hybridization, RT-PCR, immunohistochemistry, and Western blotting as well as recordings of cytoplasmic-free Ca 2+ concentration, [Ca 2+ ] i , and hormone release in vitro, we show that human β cells express ionotropic ATP receptors of the P2X 3 type and that activation of these receptors by ATP coreleased with insulin amplifies glucose-induced insulin secretion. Released ATP activates P2X 3 receptors in the β-cell plasma membrane, resulting in increased [Ca 2+ ] i and enhanced insulin secretion. Therefore, in human islets, released ATP forms a positive autocrine feedback loop that sensitizes the β cell's secretory machinery. This may explain how the human pancreatic β cell can respond so effectively to relatively modest changes in glucose concentration under physiological conditions in vivo.extracellular ATP | human pancreatic β cell | insulin secretion | P2X receptor | positive autocrine feedback G lucose homeostasis is tightly controlled by hormone secretion from the endocrine pancreas, the islets of Langerhans. Even small physiological deviations (e.g., 10%) in plasma glucose are effectively counteracted by sharp (e.g., 3-fold) increases in the secretion of the islet hormones insulin and glucagon (1). Intraislet autocrine and paracrine signaling are pivotal mechanisms for proper function of the islet, making islet cells extremely sensitive and responsive to plasma glucose fluctuations. The roles of different compounds such as GABA, glutamate, Zn 2+ , insulin, and ATP as autocrine and paracrine regulators of islet hormone release have been examined extensively (2-8). Extracellular ATP seems important because it is present in insulin-containing secretory granules and is released during glucose stimulation in sufficient amounts to stimulate ATP receptors (9-12).Extracellular ATP is an important neurotransmitter signal in the brain as well as in vascular, immune, and endocrine cells (13-15). The purinergic system comprises receptors for extracellular ATP and adenosine, the P2 and P1 receptors, respectively. P2 purinergic receptors can be divided into metabotropic P2Y receptors (G protein coupled) and ionotropic P2X receptors (ligand-gated ion channels) (16). The ionotropic P2X family comprises seven subtypes named P2X 1 -P2X 7 that regulate cell function by opening cation channels permeable to Na + , K + , and Ca 2+ (15,17). Activation of these channels regulates the release of neurotransmitters and hormones, either through direct Ca 2+ influx or by promoting membrane depolarization and thereby inducing action potentials (18-21).The role of ATP signaling in the physiology of pancreatic islets has been studied in rodent models, but the results in the literature are conflicting (22-28). In rat islets, purinergic agonists...
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