Mechanisms Of Notch Signaling Research Articles

Examining the contribution of Notch signaling to lung disease development.

Notch pathway is a widely observed signaling system that holds pivotal functions in regulating various developmental cellular functions and operations. The Notch signaling mechanism is crucial for lung homeostasis, damage, and restoration. Based on increasing evidence, the Notch pathway has been identified, as critical for fibrosis and subsequently, the development of chronic fibroproliferative conditions in various organs and tissues. Recent research indicates that deregulation of Notch signaling correlates with the pathogenesis of significant pulmonary conditions, particularly chronic obstructive pulmonary disease (COPD), pulmonary fibrosis, asthma, pulmonary arterial hypertension (PAH), lung carcinoma, and pulmonary abnormalities in some hereditary disorders. In various cellular and tissue environments, and across both physiological and pathological conditions, multiple consequences of Notch activation have been observed. Studies have ascertained that the Notch signaling cascade exhibits close associations with various other signaling systems. This study provides an updated overview of Notch signaling's role, especially its link to fibrosis and its potential therapeutic implications. This study sheds light on the latest findings regarding the mechanisms and outcomes of irregular or lacking Notch activity in the onset and development of pulmonary diseases. As our insight into this signaling mechanism suggests that modulating Notch signaling might hold potential as a valuable additional therapeutic approach in upcoming research.

Aberrant activated Notch1 promotes prostate enlargement driven by androgen signaling via disrupting mitochondrial function in mouse

The prostate is a vital accessory gonad in the mammalian male reproductive system. With the ever-increasing proportion of the population over 60 years of age worldwide, the incidence of prostate diseases, such as benign prostatic hyperplasia (BPH) and prostate cancer (PCa), is on the rise and is gradually becoming a significant medical problem globally. The notch signaling pathway is essential in regulating prostate early development. However, the potential regulatory mechanism of Notch signaling in prostatic enlargement and hyperplasia remains unclear. In this study, we proved that overactivation of Notch1 signaling in mouse prostatic epithelial cells (OEx) led to prostatic enlargement via enhancing proliferation and inhibiting apoptosis of prostatic epithelial cells. Further study showed that N1ICD/RBPJ directly up-regulated the androgen receptor (AR) and enhanced prostatic sensitivity to androgens. Hyper-proliferation was not found in orchidectomized OEx mice without androgen supply but was observed after Dihydrotestosterone (DHT) supplementation. Our data showed that the number of mitochondrion in prostatic epithelial cells of OEx mice was increased, but the mitochondrial function was impaired, and the essential activity of the mitochondrial respiratory electron transport chain was significantly weakened. Disordered mitochondrial number and metabolic function further resulted in excessive accumulation of reactive oxygen species (ROS). Importantly, anti-oxidant N-Acetyl-L-Cysteine (NAC) therapy could alleviate prostatic hyperplasia caused by the over-activation of Notch1 signaling. Furthermore, we observed the incremental Notch signaling activity in progenitor-like club cells in the scRNA-seq data set of human BPH patients. Moreover, the increased number of TROP2+ progenitors and Club cells was also confirmed in our OEx mice. In conclusion, our study revealed that over-activated Notch1 signaling induces prostatic enlargement by increasing androgen receptor sensitivity, disrupting cellular mitochondrial metabolism, increasing ROS, and a higher number of progenitor cells, all of which can be effectively rescued by NAC treatment.

Sacubitril/valsartan inhibits the proliferation of vascular smooth muscle cells through notch signaling and ERK1/2 pathway

AimsTo explore the role and mechanism of Notch signaling and ERK1/2 pathway in the inhibitory effect of sacubitril/valsartan on the proliferation of vascular smooth muscle cells (VSMCs).Main methodsHuman aortic vascular smooth muscle cells (HA-VSMCs) were cultured in vitro. The proliferating VSMCs were divided into three groups as control group, Ang II group and Ang II + sacubitril/valsartan group. Cell proliferation and migration were detected by CCK8 and scratch test respectively. The mRNA and protein expression of PCNA, MMP-9, Notch1 and Jagged-1 were detected by qRT-PCR and Western blot respectively. The p-ERK1/2 expression was detected by Western blot.Key findingsCompared with the control group, proliferation and migration of VSMCs and the expression of PCNA, MMP-9, Notch1, Jagged-1 and p-ERK1/2 was increased in Ang II group. Sacubitril/valsartan significantly reduced the proliferation and migration. Additionally, pretreatment with sacubitril/valsartan reduced the PCNA, MMP-9, Notch1, Jagged-1 and p-ERK1/2 expression.

Notch intracellular domains form transcriptionally active heterodimeric complexes on sequence-paired sites

Notch signaling is universally conserved in metazoans where it is important for a wide variety of both normal and abnormal physiology. All four mammalian Notch receptors are activated by a conserved mechanism that releases Notch intracellular domains (NICDs) from the plasma membrane to translocate to the nucleus. Once there, NICDs interact through highly conserved ankyrin domains to form head-to-head homodimers on Notch sensitive promoters and stimulate transcription. Due to the highly conserved nature of these Notch ankyrin domains in all four mammalian Notch proteins, we hypothesized that NICDs may also engage in heterodimerization. Our results reveal the presence of two NICD dimerization states that can both engage in homo and heterodimerization. Using a Co-IP approach, we show that all NICD’s can form non-transcriptionally active dimers and that the N4ICD appears to perform this function better than the other NICDs. Using a combination of ChIP analysis and transcriptional reporter assays, we also demonstrate the formation of transcriptionally active heterodimers that form on DNA. In particular, we demonstrate heterodimerization between the N2ICD and N4ICD and show that this heterodimer pair appears to exhibit differential activity on various Notch sensitive promoters. These results illustrate a new diversification of Notch signaling mechanisms which will help us better understand basic Notch function.

Notch Signaling Is Required for Extramedullary Hematopoiesis in the Adult Liver

During embryonic development, hematopoietic stem cells (HSC) in the fetal liver undergo expansion and self-renewal. Fetal HSCs migrate to the bone marrow (BM) niche towards birth and remain there during adulthood. Extramedullary hematopoiesis (EMH), or hematopoiesis outside of the BM, predominantly occurs in the fetal liver or when the adult BM niche ceases to be a site for functional hematopoiesis. The mechanism by which the adult liver becomes reactivated as a site of EMH for itinerant HSCs is unknown. Our project is investigating EMH in the adult liver by inducing acute hemolytic anemia in adult mice that induces egress and homing of hematopoietic progenitors to the liver and spleen. Our work demonstrates that long-term HSCs isolated from the portal vein in the adult liver can serially reconstitute lethally irradiated mice. Thus, the adult liver serves as a potential reservoir for long-term, functional HSCs in the presence of a damaged BM niche. In pursuit of a mechanism, we focused on Notch-signaling which is an evolutionarily conserved pathway that has been shown to play a critical role in HSC emergence and fetal liver development. When comparing WT liver donors to Notch-deficient (Notch1 +/ΔTAD) or Notch knockout (Notch1 ffVavCre +) liver donors, hematopoietic transplants reveal that Notch mutant progenitors fail to efficiently reconstitute irradiated recipients. Using an HSC-specific a-catulin-GFPmouse model, we are able to track the expression of GFP + liver-originating HSCs after hematopoietic reconstitution. We show that mice reconstituted by EMH-activated a-catulin-GFP liver HSCs are able to provide long-term reconstitution in lethally irradiated recipients and resume residence in the bone marrow niche of recipients. Additionally, we see distinct localization of GFP + HSCs localized near sinusoids throughout the EMH liver niche using whole-mount imaging. We have validated receptor-ligand binding interactions of the Notch1 receptor with ligand-expressing hematopoietic cells in the adult liver. Using intracellular flow cytometry after EMH in the adult liver, we see a 3-fold increase in mean fluorescent intensity of GATA2 in HSPCs (hematopoietic stem cell progenitors) when compared to our bone marrow and isotype control mice. We demonstrate that Notch-driven GATA2 expression is a crucial regulator of self-renewal and functional maintenance of stemness during EMH of HSCs in the adult liver. Our findings reveal a developmentally conserved Notch signaling mechanism is reactivated in the adult liver to retain the functional potential and maintenance of HSCs as they adapt to inhospitable conditions in the bone marrow niche.

Fucosyltransferase 9 promotes neuronal differentiation and functional recovery after spinal cord injury by suppressing the activation of Notch signaling.

Individuals with spinal cord injury (SCI) suffer from permanent disabilities such as severe motor, sensory and autonomic dysfunction. Neural stem cell transplantation has proven to be a potential strategy to promote regeneration of the spinal cord, since NSCs can produce neurotrophic growth factors and differentiate into mature neurons to reconstruct the injured site. However, it is necessary to optimize the differentiation of NSCs before transplantation to achieve a better regenerative outcome. Inhibition of Notch signaling leads to a transition from NSCs to neurons, while the underlying mechanism remains inadequately understood. Our results demonstrate that overexpression of fucosyltransferase 9 (Fut9), which is upregulated by Wnt4, promotes neuronal differentiation by suppressing the activation of Notch signaling through disruption of furin-like enzyme activity during S1 cleavage. In an in vivo study, Fut9-modified NSCs efficiently differentiates into neurons to promote functional and histological recovery after SCI. Our research provides insight into the mechanisms of Notch signaling and a potential treatment strategy for SCI.

Mechanism of Notch Signal Regulating Alveolar Epithelial Cell Autophagy after Infection with Klebsiella Pneumoniae.

The Notch signaling pathway regulates various cellular processes, including cell growth, inflammation response, and autophagy, thereby participating in the occurrence and development of various diseases. The present study aimed to investigate the molecular mechanism of Notch signaling in regulating alveolar type II epithelial cell viability and autophagy after Klebsiella pneumonia (KPN) infection. KPN-infected human alveolar type II epithelial cells A549 (ACEII) were constructed. The autophagy inhibitor 3-methyladenine (3-MA) and Notch1 signaling inhibitor (DAPT) were used to pretreat A549 cells for 24 hours, 48 hours, and 72 hours before KPN infection. Real-time fluorescent quantitative PCR (qRT-PCR) and western blot assays were applied to detect the mRNA and protein expressions of LC3 and Notch1, respectively. ELISA was used to detect the levels of INF-γ, TNF-α, and IL-1β in the cell supernatants. The results showed that KPN-infected A549 cells presented significantly upregulated Notch1 and autophagy-related protein LC3 levels, along with increased IL-1β, TNF-α, INF-γ levels in a time-dependent manner. Autophagy inhibitor 3-methyladenine (3-MA) counteracted the promotive effects of LC3 and inflammatory cytokine levels in KPN-infected A549 cells; however, 3-MA did not influence Notch1 level. Notch1 inhibitor DAPT could suppress Notch1 and LC3 levels, thereby inhibiting inflammation response in KPN-treated A549 cells in a time-dependent way. KPN infection can activate the Notch signaling pathway and induce autophagy in type Ⅱ alveolar epithelial cells. Inhibiting the Notch signaling pathway may restrain KPN-induced A549 cell autophagy and inflammation response, shedding new insights for the treatment of pneumonia.

Notch signaling regulates vessel structure and function via Hspg2

The abnormal structure of tumor blood vessels is an important reason for the low efficacy of anti-tumor drugs. Notch signaling is an evolutionarily highly conserved signaling pathway that plays an important role in vessel development. However, the role and mechanism of Notch signaling in the formation of vascular structure is not fully understood. In this study, we demonstrated that blocking Notch signaling in endothelial cells (ECs) leads to obstructed tumor blood vessel basement membrane formation and the reduction of blood perfusion, as well as blood-retinal barrier (BRB) and blood-brain barrier (BBB) destruction in healthy mice. Endothelial Notch overactivation exacerbates the increases in tumor blood vessel basement membrane and blood perfusion ratio, and promotes recruitment of retinal vascular smooth muscle cells in neonatal mice. Notch signaling also regulates the formation of adhesion junctions (AJs) in ECs. In addition, we confirmed that Notch signaling regulates the AJs of ECs by regulating the expression of downstream gene Hspg2. This research is of great theoretical and practical significance for understanding the mechanism of tumor vascular structure formation as well as the search for new targets for vascular-targeted therapy.

A narrative review of the role of the Notch signaling pathway in rheumatoid arthritis.

Background and ObjectiveRheumatoid arthritis (RA) is a chronic autoimmune disease affected by genetics and the environment factors. Its early diagnosis and treatment are difficult, and the infection risk is serious. The treatment effects for most patients were not significant, which has become a difficult challenge to overcome. Cell signals play an important role in regulating basic cellular activities such as immunity. Notch signaling is a near secretory signal that can affects many processes of cell normal morphogenesis, including the differentiation of pluripotent progenitor cells, apoptosis, cell proliferation and the formation of cell boundary. In addition, the expression and activation of Notch signaling are increased in the synovial cells and vascular endothelial cells of RA patients. The purpose of this review was to elucidate the related mechanisms of Notch signaling in RA progression, as well as the potential therapeutic value of Notch signaling in a variety of autoimmune diseases.MethodsLiteratures about Notch signaling and RA were extensively reviewed to analyze and discuss.Key Content and FindingsThis article briefly reviews the role of Notch signaling in RA. It also summarizes the functional role of Notch signaling in the treatment of RA, with the goal to provide a new treatment option for RA patients.ConclusionsIn this review, the approach we discussed focuses on Notch signaling as a potential therapeutic target against RA, enriching therapeutic strategies for inflammatory diseases including RA.

A Skin‐Mountable Hyperthermia Patch Based on Metal Nanofiber Network with High Transparency and Low Resistivity toward Subcutaneous Tumor Treatment

AbstractA wearable hyperthermia device that allows for tumor treatment without interfering with daily activities is of clinical and social significance. However, the wide adaptation of local hyperthermia from such wearable devices in clinical practice has been hindered mainly due to several critical challenges in existing hyperthermia devices, such as the contradiction of high electrical conductivity and high optical transparency of the device while in a thin, deformable format. Here a soft, skin‐mountable, hyperthermia patch (HTP) is reported with unusual optical and electrical characteristics based on unidirectional silver nanofibers (AgNFs) network with low‐voltage operation and uniform heating even under mechanical deformation. The patch presents both high electrical conductivity and highly optical transparency simultaneously thus allowing real time inspection of the subcutaneous tumor treatment and skin response during the treatment. The unidirectional nature of the AgNFs network renders the key features of high optical transparency, low electrical resistivity, excellent electrothermal performances, and mechanical deformability. Effective treatment of subcutaneous tumors in mice is demonstrated with the skin worn HTP while the skin response is visually tracked. Systematic studies reveal the physiological mechanisms of Notch signaling in inducing tumor cell apoptosis.

A new toolkit to visualize and perturb endogenous LIN-12/Notch signaling in C. elegans.

Notch signaling mediates cell-cell interactions during development and homeostasis. Methods for visualizing and manipulating Notch activity in vivo are essential to elucidate how the Notch pathway functions. Here, we provide new tools for use in C. elegans to visualize and perturb Notch signaling in vivo using endogenously tagged alleles of the Notch receptor lin-12 . Tagging the endogenous LIN-12 intracellular domain with the fluorescent protein mNeonGreen (mNG) allowed for visualization of both its membrane-localized state and translocation of the Notch intracellular domain into the nucleus upon ligand activation. LIN-12::mNG localized to the nucleus in cells where and when Notch signaling is known to be active and provided a real-time readout of Notch activity in vivo that complements existing biosensors and transcriptional reporters. We also report an allele of endogenous lin-12 that we tagged with both mNG and an auxin-inducible degron, to facilitate conditional LIN-12 protein degradation. This toolkit provides novel reagents for the C. elegans research community to investigate mechanisms of Notch signaling and its functions in vivo .

Notch Ligand Jagged1 Is a Fetal Liver Niche Factor for the Function of Embryonic Hematopoietic Stem Cells

Embryonic hematopoietic stem cells (HSC) expand rapidly during development in the fetal liver. Notch1 is required for emergence of the definitive hematopoietic stem cells (HSCs) from the hemogenic endothelium, and is essential for survival and function of HSCs in the fetal liver. The identity of the ligand and the ligand-presenting cell during hematopoietic development would provide valuable information of the Notch signaling mechanism in HSCs as well as the identity of key niche cells that drive the expansion and cell fate decisions of embryonic HSCs. In the present study, we have taken a comprehensive approach to determine the ligands and cells that initiate Notch signaling in the mouse fetal liver. To this end, we have performed single-cell analysis for all Notch signaling proteins and many known targets in E14.5 fetal HSCs and adult bone marrow HSCs as well as fetal liver endothelial cells. We determined that Jagged1 (Jag1) is highly expressed in both endothelial cells as well as in fetal HSCs but not in adult HSCs. We have performed conditional loss-of-function analysis of Jag1 in fetal endothelial cells as well as in fetal hematopoietic lineages, where both myeloid and megakaryocytic progenitors are shown to express high levels of Jag1. Our results indicate that while loss of endothelial Jag1 has severe effects in embryonic vascular development, loss of hematopoietic Jag1 allows for normal fetal morphology, yet severely impedes the functional ability of fetal liver HSCs to expand and differentiate. RNA-Sequencing analysis of long-term fetal HSCs in Jag1-mutant embryos (VavCreJag f/f) revealed reduced expression of Gata2, Mllt3, Hoxa7, Angpt1 and IL-12a genes in fetal HSCs, which are well-known regulators of self-renewal and expansion. Our findings indicate that Jag1 is an essential niche factor for development of HSCs in the fetal liver and for functional potential of fetal HSCs once in the bone marrow microenvironment. [Display omitted] DisclosuresNo relevant conflicts of interest to declare.

Hematopoietic Jagged1 Is Required for the Transition of Hematopoietic Stem Cells from the Fetal Liver to the Adult Bone Marrow Niche

Notch signaling is known to play important roles in hematopoietic development and differentiation. Notch1 is required for emergence of the definitive hematopoietic stem cells (HSCs) from the hemogenic endothelium, and we have previously shown that Notch signaling is essential for survival and function of HSCs in the fetal liver. Activation of canonical Notch signaling requires direct cellular contact; thus, the identity of the ligand and the ligand-presenting cell during hematopoietic development would provide valuable information of the Notch signaling mechanism in HSCs as well as the identity of key niche cells that drive the expansion and cell fate decisions of embryonic HSCs. In the present study, we have taken a comprehensive approach to determine the ligands and cells that initiate Notch signaling in the mouse fetal liver. To this end, we have performed single-cell PCR analysis for all Notch signaling proteins in E14.5 fetal HSCs and compared the findings to the adult bone marrow HSCs. We also have analyzed fetal liver endothelial cells for surface expression of all Notch ligands. We determined that Jagged1 (Jag1) is highly expressed in both endothelial cells as well as in fetal HSCs but not adult HSCs. We have performed conditional loss-of-function analysis of Jag1 in fetal endothelial cells using inducible Ve-cadherinCreERT2 as well as in fetal hematopoietic lineages using constitutive VavCre. Our results indicate that while loss of endothelial Jag1 has severe effects in embryonic vascular development, loss of hematopoietic Jag1 allows for normal fetal morphology, yet severely impedes the functional ability of fetal liver HSCs to expand and differentiate both in vitro and in vivo. Fetal to adult transplantation of VavCre+Jag1f/f HSCs indicated a defect in reconstitution potential of fetal HSCs that lack Jag1 expression. Our findings indicate that hematopoietic Jag1 is essential for maturation of HSCs in the fetal liver and for homing and reconstitution potential of HSCs into the post-natal bone marrow microenvironment. Disclosures No relevant conflicts of interest to declare.

Multifaceted regulation of Notch signaling by glycosylation.

To build a complex body composed of various cell types and tissues and to maintain tissue homeostasis in the postembryonic period, animals use a small number of highly conserved intercellular communication pathways. Among these is the Notch signaling pathway, which is mediated via the interaction of transmembrane Notch receptors and ligands usually expressed by neighboring cells. Maintaining optimal Notch pathway activity is essential for normal development, as evidenced by various human diseases caused by decreased and increased Notch signaling. It is therefore not surprising that multiple mechanisms are used to control the activation of this pathway in time and space. Over the last 20years, protein glycosylation has been recognized as a major regulatory mechanism for Notch signaling. In this review, we will provide a summary of the various types of glycan that have been shown to modulate Notch signaling. Building on recent advances in the biochemistry, structural biology, cell biology and genetics of Notch receptors and the glycosyltransferases that modify them, we will provide a detailed discussion on how various steps during Notch activation are regulated by glycans. Our hope is that the current review article will stimulate additional research in the field of Notch glycobiology and will potentially be of benefit to investigators examining the contribution of glycosylation to other developmental processes.

Notch Signaling and Tissue Patterning in Embryology: An Introduction.

The attention of science first turned to the gene that later earned the name Notch over a century ago, when the American scientist John S. Dexter discovered in his laboratory at Olivet College the characteristic notched-wing phenotype (a nick or notch in the wingtip) in mutant fruit flies Drosophila melanogaster. At present, it is generally accepted that the Notch pathway governs tissue patterning and many key cell fate decisions and other core processes during embryonic development and in adult tissues. Not surprisingly, a broad variety of independent inherited diseases (including CADASIL, Alagille, Adams-Oliver, and Hajdu-Cheney syndromes) have now convincingly been linked to defective Notch signaling. In the second edition of the book entitled Notch Signaling in Embryology and Cancer, leading researchers provide a comprehensive, highly readable overview on molecular mechanisms of Notch signaling (Volume I), and notch's roles in embryology (Vol. II) and cancer (Vol. III). In these introductory pages of Vol. II, we give a short overview on its individual chapters, which are intended to provide both basic scientists and clinicians who seek today's clearest understanding of the broad role of Notch signaling in embryology with an authoritative day-to-day source.

Overview of Basic Mechanisms of Notch Signaling in Development and Disease.

Notch signaling is an evolutionarily conserved pathway associated with the development and differentiation of all metazoans. It is needed for proper germ layer formation and segmentation of the embryo and controls the timing and duration of differentiation events in a dynamic manner. Perturbations of Notch signaling result in blockades of developmental cascades, developmental anomalies, and cancers. An in-depth understanding of Notch signaling is thus required to comprehend the basis of development and cancer, and can be further exploited to understand and direct the outcomes of targeted cellular differentiation into desired cell types and complex tissues from pluripotent or adult stem and progenitor cells. In this chapter, we briefly summarize the molecular, evolutionary, and developmental basis of Notch signaling. We will focus on understanding the basics of Notch signaling and its signaling control mechanisms, its developmental outcomes and perturbations leading to developmental defects, as well as have a brief look at mutations of the Notch signaling pathway causing human hereditary disorders or cancers.

Molecular Mechanisms of Notch Signaling in Lymphoid Cell Lineages Development: NF-κB and Beyond.

Notch is a ligand-receptor interaction-triggered signaling cascade highly conserved, that influences multiple lineage decisions within the hematopoietic and the immune system. It is a recognized model of intercellular communication that plays an essential role in embryonic as well as in adult immune cell development and homeostasis. Four members belong to the family of Notch receptors (Notch1-4), and each of them plays nonredundant functions at several developmental stages. Canonical and noncanonical pathways of Notch signaling are multifaceted drivers of immune cells biology. In fact, increasing evidence highlighted Notch as an important modulator of immune responses, also in cancer microenvironment. In these contexts, multiple transduction signals, including canonical and alternative NF-κB pathways, play a relevant role. In this chapter, we will first describe the critical role of Notch and NF-κB signals in lymphoid lineages developing in thymus: natural killer T cells, thymocytes, and thymic T regulatory cells. We will address also the role played by ligand expressing cells. Given the importance of Notch/NF-κB cross talk, its role in T-cell leukemia development and progression will be discussed.

Regulation of Notch signaling by the chromatin-modeling protein Hat-trick.

Notch signaling plays a pleiotropic role in a variety of cellular processes, including cell fate determination, differentiation, proliferation and apoptosis. The increasingly complex regulatory mechanisms of Notch signaling account for the many functions of Notch during development. Using a yeast two-hybrid screen, we identified the Drosophila DNA-binding protein Hat-trick (Htk) to be an interacting partner of Notch-intracellular domain (Notch-ICD); their physical interaction was further validated by co-immunoprecipitation experiments. htk genetically interacts with Notch pathway components in trans-heterozygous combinations. Loss of htk function in htk mutant somatic clones resulted in the downregulation of Notch targets, whereas its overexpression caused ectopic expression of Notch targets, without affecting the level of the Notch protein. In the present study, immunocytochemical analyses demonstrate that Htk and overexpressed Notch-ICD colocalize in the same nuclear compartment. Here, we also show that Htk cooperates with Notch-ICD and Suppressor of Hairless to form an activation complex and binds to the regulatory sequences of Notch downstream targets such as Enhancer of Split complex genes, to direct their expression. Together, our results suggest a novel mode of regulation of Notch signaling by the chromatin-modeling protein Htk.

Mechanisms of Notch signaling: a simple logic deployed in time and space.

Most cells in our body communicate during development and throughout life via Notch receptors and their ligands. Notch receptors relay information from the cell surface to the genome via a very simple mechanism, yet Notch plays multiple roles in development and disease. Recent studies suggest that this versatility in Notch function may not necessarily arise from complex and context-dependent integration of Notch signaling with other developmental signals, but instead arises, in part, from signaling dynamics. Here, we review recent findings on the core Notch signaling mechanism and discuss how spatial-temporal dynamics contribute to Notch signaling output.

A genetic mosaic screen identifies genes modulating Notch signaling in Drosophila.

Notch signaling is conserved in most multicellular organisms and plays critical roles during animal development. The core components and major signal transduction mechanism of Notch signaling have been extensively studied. However, our understanding of how Notch signaling activity is regulated in diverse developmental processes still remains incomplete. Here, we report a genetic mosaic screen in Drosophila melanogaster that leads to identification of Notch signali ng modulators during wing development. We discovered a group of genes required for the formation of the fly wing margin, a developmental process that is strictly dependent on the balanced Notch signaling activity. These genes encode transcription factors, protein phosphatases, vacuolar ATPases and factors required for RNA transport, stability, and translation. Our data support the view that Notch signaling is controlled through a wide range of molecular processes. These results also provide foundations for further study by showing that Me31B and Wdr62 function as two novel modulators of Notch signaling activity.