• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 33
  • 8
  • 7
  • 6
  • 5
  • 2
  • 1
  • Tagged with
  • 69
  • 69
  • 24
  • 21
  • 19
  • 11
  • 11
  • 11
  • 11
  • 9
  • 9
  • 9
  • 9
  • 8
  • 8
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
41

The Structural, Biophysical, and Functional Characterization of the CSL-RITA Complex: Similarities and Differences in Notch Transcriptional Regulation

Tabaja, Nassif H. January 2016 (has links)
No description available.
42

Roles of immunoglobulin domain proteins echinoid and friend-of-echinoid in drosophila neurogenesis

Chandra, Shweta 20 July 2004 (has links)
No description available.
43

<b>A Cell Autonomous Function of Delta-Like 1 </b><b>Intracellular Domain In Skeletal Muscle</b>

Sara Brooke Scinto (19199458) 25 July 2024 (has links)
<p dir="ltr">Delta-like 1 (DLL1) is a protein on the surface of the cell that serves as a ligand for NOTCH receptors. Like NOTCH receptors, NOTCH ligands span the membrane of the cell and contain extracellular, transmembrane, and intracellular domains. NOTCH activation occurs through contact-dependent interactions between the NOTCH receptor on one cell and ligand on an adjacent cell. Previous studies have demonstrated that DLL1 predominantly functions cell non-autonomously to trigger NOTCH signaling in a neighbor cell but a cell-autonomous function of DLL1 has also been proposed in recent years. However, there is no direct evidence to support a cell-autonomous function of DLL1 in vivo. The overall goal of this thesis was to elucidate the cell-autonomous function of DLL1 by testing the hypothesis that the intracellular domain of DLL1 (DLL1ICD) can be cleaved and function in the DLL1-expressing cell in addition to triggering NOTCH signaling in a neighbor cell. The research strategy to test the hypothesis is by overexpression of full-length (FL) and cleaved Dll1 (Dll1ICD) in the murine myoblast cell line (C2C12). These plasmids utilize a tet-on system for inducible overexpression. Transfected myoblasts were used to analyze how overexpression of Dll1-FL and Dll1ICD affects proliferation, differentiation, fusion, and gene expression. The results show that Dll1-FL can be cleaved to generate an ICD. DLL1ICD overexpression promotes fusion without affecting proliferation. Further investigation reveals that overexpression of Dll1ICD affects the expression of NOTCH and myogenic-specific genes during differentiation, confirming the cell-autonomous role of DLL1ICD in myoblasts. These results together show that DLL1 can function cell autonomously through its intracellular domain to regulate myogenesis.</p>
44

ADAM10 overexpression dysregulates Notch signaling in favor of myeloid derived suppressor cell (MDSC) accumulation that deferentially modulates the host response depending on immune stimuli and interaction with mast cells.

Saleem, Sheinei 08 July 2013 (has links)
Although the physiological consequences of Notch signaling in hematopoiesis have been extensively studied, the differential effects of individual notch cleavage products remain to be elucidated. Given that a disintegrin and metalloproteinase 10 (ADAM10) is a critical regulator of Notch and that its deletion is embryonically lethal, we generated transgenic mice that overexpress ADAM10 at early stages of lymphoid and myeloid development (A10Tg). ADAM10 transgene expression alters hematopoiesis post-hematopoietic Lineage-Sca-1+c-kit+ (LSK) subset differentiation but prior to lineage commitment of progenitor populations. This results in delayed T cell development, abrogated B2 cell development, and dramatic expansion of functionally active myeloid derived suppressor cells (MDSCs) in A10Tg mice. Given ADAM10’s role in Notch signaling, we hypothesized that the observed hematopoietic alterations may be a consequence of perturbed Notch signaling. In fact, blockade of ADAM10 (S2) rescues B cell development and reduces myeloid cells in A10Tg LSKs. Inhibition of γ-secretase (S3) in wild type (WT) LSKs results in enhanced myelopoiesis, mimicking the phenotype of A10Tg mice. Collectively, these findings indicate that the differential cleavage of Notch into S2 and S3 products regulated by ADAM10 is critical for hematopoietic cell-fate determination. Albeit arising in a tumor-free host, A10Tg MDSCs are functionally and phenotypically analogous to tumor-derived MDSCs. A10Tg MDSCs inhibit T cell activation in vitro, and inhibit adoptive immunotherapy (AIT) of metastatic melanoma in vivo, which can be reversed with MDSC depletion. Intriguingly, A10Tg mice are resistant to parasitic infection upon inoculation of Nippostrongylus brasiliensis. However, depletion of MDSCs abrogates this response, while adoptive transfer (AT) of MDSCs into WT mice increases their resistance. This polarized activity of MDSCs is heavily dependent upon interaction with mast cells (MCs). In fact, B16 melanoma cells metastasize more rapidly in WT mice infused with MDSCs when compared to MC-deficient mice (Kit Wsh/Wsh), with or without MDSC AT. Parallel to B16 progression, the ability of MDSCs to promote anti-Nb immunity is significantly diminished in MC-deficient (Kit Wsh/Wsh) mice even with MDSC AT. This augmentation of MDSC activity in the presence of MCs is further corroborated by in vitro co-culture assays that demonstrate a synergistic increase in cytokine production. Furthermore, MDSCs preferentially migrate to the liver in a MC-dependent manner. This interaction is mediated by MC-released histamine. In fact, MDSCs express histamine receptors (HR) and histamine induces MDSC survival, proliferation, and activation. We demonstrate that MDSC activity is abrogated with histamine blockade. Moreover, in humans, allergic patients present with an increase in MDSC population, and MDSCs purified from a stage I breast cancer patient exhibit increased survival in the presence of histamine. Taken together, our studies indicate that MCs and MC-released histamine are critical for the observed functional duality of MDSCs, ranging from immunosuppressive to immunosupportive, depending on the disease state.
45

O papel da sinalização Notch na diferenciação do epitélio pulmonar. / The role of Notch signaling in lung epithelial differentiation.

Vasconcelos, Michelle 16 January 2012 (has links)
O epitélio pulmonar é formado por uma grande diversidade celular, que incluí: células secretoras, ciliadas, basais e neuroendócrinas (NE). A distribuição balanceada destes tipos celulares é crucial para a função pulmonar e pode ser dramaticamente alterada em doenças como a asma. Neste trabalho, estudamos o papel de Notch no pulmão em desenvolvimento ao inativar condicionalmente Rbpjk ou Pofut1, componentes críticos da sinalização Notch. Pulmões mutantes apresentaram-se superpopulados por células ciliadas e NE, além da ausência de células de Clara. Nossos dados sugeriram que Notch suprime os programas de diferenciação de células ciliadas e NE para permitir a diferenciação de células de Clara, através de um mecanismo de inibição lateral. Identificamos também genes associados com a diferenciação de células secretoras e ciliadas através de microarrays. A heterogeneidade no padrão de expressão gênica sugeriu que a via de sinalização Notch estabelece múltiplos subtipos de células ciliadas e secretoras no epitélio pulmonar em desenvolvimento. / The airway epithelium comprises a diverse population of secretory, ciliated, basal and neuroendocrine cells (NE). The proper balance of these cell types is critical for normal lung function and can be altered dramatically in conditions, such as asthma. We studied the role of Notch in airway progenitor cell fate by conditionally inactivating Rbpjk or Pofut1, two critical Notch pathway components in mouse mutants. This resulted in airways overpopulated with ciliated and NE cells and absence of secretory Clara cells. We found that Notch suppresses the ciliated and the NE cell programs to allow secretory cell differentiation through a lateral inhibition mechanism. We also identified genes associated with the differentiation of secretory and ciliated cells through a microarray gene profiling experiment. The great heterogeneity of gene expression patterns suggested that Notch plays a role in establishing multiple subsets of secretory and ciliated cells in the developing lung.
46

Interaction entre les voies de signalisation FGF et Notch lors de la migration de la parapineale dans le cerveau asymétrique du poisson zèbre / Crosstalk between FGF and Notch signaling pathways during the collective migration of parapineal cells in the left right asymmetric zebrafish brain

Wei, Lu 26 November 2018 (has links)
Lors du développement de l'asymétrie gauche droite dans le cerveau du poisson zèbre, un petit groupe de cellules, le parapinéale, migre collectivement depuis la ligne médiane vers la partie gauche de l'épithalamus. Cette migration est défectueuse dans des mutants pour le gène fgf8, indiquant que le facteur Fgf8 (Fibroblast Growth Factor 8), sécrété de part et d'autre de la ligne médiane, est requis pour la migration. Cependant, l'orientation gauche de la migration dépend de l'activation, plus précocement dans l'épithalamus gauche, de la voie de signalisation Nodal/TGFb (Transforming Growth Factor). Par conséquent, la parapinéale est un modèle de choix pour comprendre comment les cellules migrent collectivement en réponse aux Fgf et pour étudier comment d'autres voies de signalisation modulent ce processus. L'imagerie en temps réel d'un transgène rapporteur de la signalisation FGF a révélé que la voie FGF est activée préférentiellement dans quelques cellules de tête, c'est à dire localisées au front de migration. L'expression globale d'un récepteur aux Fgf activé de façon constitutive (CA-FgfR1) interfère avec la migration de la parapinéale en contexte sauvage mais est capable de restaurer à la fois la migration de la parapinéale et l'activation focale de la voie FGF au front de migration dans les mutants fgf8-/-. De plus, l'activation focale de la voie FGF dans seulement quelques cellules de parapinéale est suffisante pour restaurer la migration de tout le collectif dans les mutants fgf8-/-. Finalement, nos données montrent que la signalisation Nodal contribue à restreindre et à biaiser l'activation de la voie FGF afin d'orienter la migration de la parapinéale vers le côté gauche (Manuscript n°1). Par la suite, mes travaux de thèse ont visé à comprendre comment l'activation de la voie FGF est restreinte à quelques cellules, bien que toutes les cellules de parapinéale semblent compétentes pour activer la voie. Nos résultats montrent que la signalisation Notch est capable de restreindre l'activation de la voie FGF. La perte ou le gain de fonction de la voie Notch entrainent respectivement une augmentation ou une diminution de l'activité FGF, associés à des défauts de migration de la parapinéale dans les deux contextes. De plus, la diminution ou l'augmentation artificielle du niveau d'activation de la voie FGF peut respectivement restaurer la migration de la parapinéale ou aggraver les défauts de migration en absence d'activité Notch. Nos données indiquent que la signalisation Notch restreint l'activation de la voie FGF au sein des cellules de parapinéale pour permettre la migration du collectif (Manuscript n°2). La voie Notch est également requise pour la spécification d'un nombre correct de cellules de parapinéale, indépendamment de la voie FGF. En parallèle, nous avons analysé la fonction de MMP2 (Matrix Metalloprotease 2), une protéine exprimée mosaïquement dans la parapinéale et candidate pour moduler la signalisation FGF. Cependant, nous n'avons observé aucun défaut de spécification ou de migration de la parapinéale dans les embryons mutants pour le gène mmp2 -/- (Manuscript n°3). Mon travail de thèse révèle un rôle de la voie Notch pour restreindre l'activation de la signalisation FGF dans quelques cellules de parapinéale, un processus qui est biaisé par la voie Nodal afin d'orienter la migration du collectif vers la gauche. Ces données pourraient permettre de mieux comprendre les interactions entre les voies de signalisation FGF, Notch et Nodal dans d'autres modèles de migration cellulaire collective comme, par exemple, la migration des cellules cancéreuses. / During the establishment of left-right asymmetry in the zebrafish brain, a small group of cells, the parapineal, collectively migrates from the dorsal midline of the epithalamus to the left in most wild-type embryos. Parapineal migration requires Fibroblastic Growth Factor 8 (Fgf8), a secreted signal expressed bilaterally in epithalamic tissues surrounding the parapineal. The left bias in the orientation of parapineal migration depends on the activity of Cyclops, a secreted factor of the Nodal/TGFß family that is transiently expressed in the left epithalamus prior to parapineal migration. Therefore, the parapineal provides a powerful new model to understand FGF dependent collective cell migration and to study how other signaling pathways modulate this process. Live imaging of an FGF reporter transgene revealed that the FGF pathway is activated in only few parapineal cells that are usually located at the leading edge of migration. Global expression of a constitutively activated Fgf receptor (CA-FGFR) delays migration in wild-type, while it partially restores both parapineal migration and focal activation of the FGF reporter transgene in fgf8-/- mutant embryos. Importantly, focal activation of FGF signaling in few parapineal cells is sufficient to restore collective migration in fgf8-/- mutants. Finally, Nodal asymmetry contributes to restrict and left-bias the activation of the FGF pathway (Manuscript n°1). Following this work, my thesis project aimed at understanding how the activation of the FGF pathway is restricted to few cells, despite all parapineal cells apparently being competent to activate the pathway. We showed that Notch signaling is able to restrict FGF activity. Loss or gain of function of the Notch pathway respectively triggers an increase or decrease in FGF activity, which correlate with PP migration defects. Moreover, decreasing or increasing FGF activity levels respectively rescues or aggravates parapineal migration defects in Notch loss-of-function context. Our data indicate that Notch signaling restricts the activation of the FGF pathway within parapineal cells to promote their collective migration (Manuscript n°2). We also found that Notch pathway is required for the specification of a correct number of parapineal cells, independently of FGF pathway. In parallel, we analysed the function of MMP2 (Matrix Metalloprotease 2), a protein mosaïcally expressed in the parapineal and a candidate to modulate FGF signaling. However, we found no significant defects in the specification or migration of parapineal cells in mmp2-/- mutant embryos (Manuscript n°3). My PhD work reveals a role for Notch signaling in restricting the activation of FGF signaling within few parapineal cells, a process that is biased by Nodal pathway to the left and required for the migration of the entire parapineal. These data provide insights into the interaction of FGF, Notch and Nodal/TGFb signaling pathways that may be applicable to other models of collective cell migration, such as cancer cells migration for instance.
47

Identification d’un double rôle de l’E3-Ubiquitine ligase Mindbomb au cours de la morphogénèse du tube neural du poisson zèbre / Identification of a dual role of the E3-ubiquitin ligase Mindbomb in the zebrafish neural tube morphogenesis

Sharma, Priyanka 14 October 2015 (has links)
Au cours de ce projet de thèse, j’ai étudié le lien fonctionnel entre la morphogénèse épithéliale et la signalisation Delta-Notch, dans le cadre de la formation du tube neural chez le poisson-zèbre. La signalisation Delta-Notch est primordiale pour le développement embryonnaire et le maintien de l’homéostasie des tissus adultes. De façon inattendue, j’ai observé suite à la perte-de-fonction de Mib une perte de la polarité apico-basale dans le neuro-épithélium de la moelle épinière embryonnaire. L’analyse plus poussée de ce phénotype m’a ensuite permis de montrer que l’activité de l’intégralité de la signalisation Notch est requise pour l’établissement de la polarité apico-basale dans le tube neural de poisson-zèbre. En effet, l’inhibition des ligands de Notch et des activateurs transcriptionnels situés en aval, Rbpja et Rbpjb, résulte en l’interruption de la polarité apico-basale. De plus, l’activation ectopique de Notch entraîne un sauvetage complet de la polarité apico-basale dans les embryons déplétés pour Mib. Finalement, le mutant Mib échoue à activer la transcription de protéines de polarité apicale Crumbs1 et Crumbs2a au cours de la formation du tube neural, ce qui suggèrerait que la signalisation Notch agit en amont des complexes de polarité. De façon surprenante, nous avons également montré que le composant de la signalisation Notch, Mib, affecte les mouvements de convergence-extension et la division cellulaire orientée, appelée C-divisions, durant la neurulation et la gastrulation à travers la signalisation PCP. Cet effet de Mib sur la PCP est indépendant de son rôle sur la signalisation Notch. Généralement, cette étude révèle un double-rôle de Mib. / In this Ph.D. project, I study the functional link between epithelial polarity and Delta-Notch signaling in the context of zebrafish neural tube morphogenesis. Notch signaling, one of the major signaling pathways and of prime importance in neurogenesis, has been widely studied for its function in cell fate specifications. Surprisingly, I found that the Notch signaling component Mindbomb (Mib) loss-of-function led to a loss of apico-basal polarity in the neuroepithelium of the embryonic spinal cord. I further explored that the activity of the entire Notch signaling pathway is actually required for the earliest steps of establishment of apico-basal polarity in the zebrafish neural tube. Indeed, inhibition of Notch ligands and downstream transcriptional activators Rbpja and Rbpjb resulted in a disruption of apico-basal polarity. Moreover, ectopic activation of Notch ensued to a complete rescue of apico-basal polarity in Mib loss of function embryos. Furthermore, Mib mutant embryos fail to upregulate the transcription of the apical polarity proteins Crumbs1 and Crumbs2a in the course of neural tube formation, suggesting that Notch signalling might act upstream of polarity complexes. Moreover, I found that Mib affects convergent-extension movements and oriented cell divisions during neurulation and gastrulation through an effect on planar cell polarity. Remarkably, this effect of Mib on PCP is independent of its role in Notch signaling. These results indicate a novel role of Mib in the regulation of PCP signaling. Altogether, this study revealed a dual role of Mib in the epithelial morphogenesis of the zebrafish neural tube.
48

Régulation de la quiescence des cellules souches du muscle squelettique par la voie Notch / Regulation of adult muscle stem cell quiescence by Notch signalling

Baghdadi, Meryem 19 September 2017 (has links)
Le muscle squelettique adulte est capable de se régénérer à plusieurs reprises après blessure grâce à sa population de cellules souches résidentes: les cellules satellites. Cependant, les mécanismes impliquant les cellules satellite dans la recouvrement de l'homéostasie et de l'intégrité musculaire ne sont toujours pas clairs. Chez l'adulte, les cellules satellites sont quiescentes et localisées dans une niche entre la lame basale et la fibre musculaire. Après blessure, elles prolifèrent, se différencient et fusent afin de restaurer les fibres endommagées. Lorsque la niche des cellules satellite est altérée elles expriment rapidement le marqueur d'activation Myod puis prolifèrent. La lame basale des cellules souches est riche en collagène, glycoprotéines et de protéoglycan. Cependant, le mécanisme de fonction de ces protéines de la matrice extracellulaire (MEC) dans le maintien de la cellule satellite dans sa niche est toujours inconnu. De plus, l'interaction entre la MEC et des voies de signalisation cellulaire essentielles au maintien des cellules souches quiescentes sont toujours un mystère. Nous avons identifiés la voie Notch comme effecteur indispensable à la quiescence des cellules satellites. Un ChIP screening dans des cellules musculaires nous a permit d'identifier des microRNAs et collagènes spécifiques comme des gènes cibles de la voie Notch. L'utilisation d'outils génétiques permettant de moduler l'activité de la voie Notch démontrent que ces microRNAs et collagènes sont régulés transcriptionnellement par la voie Notch in vitro et in vivo. Nous proposons que le Collagène de type V et miR-708, induits par Notch, peuvent autoréguler la niche des cellules souches. / Adult skeletal muscles can regenerate after repeated trauma, yet our understanding of how adult muscle satellite (stem) cells (MuSCs) restore muscle integrity and homeostasis after regeneration is limited. In the adult mouse, MuSCs are quiescent and located between the basal lamina and the myofibre. After injury, they re-enter the cell cycle, proliferate, differentiate and fuse to restore the damaged fibre. A subpopulation of myogenic cells then self-renews and replenishes the stem cell pool for future repair. When MuSCs are removed from their niche, they rapidly express the commitment marker Myod and proliferate. The basal lamina that ensheaths MuSCs is rich in collagens, non-collagenous glycoproteins and proteoglycans. Whether these and other extracellular matrix (ECM) proteins constitute functional components of MuSCs niche remains unclear. Moreover, although signalling pathways that maintain MuSCs quiescence have been identified, how these regulate stem cell properties and niche composition remains largely unknown. Sustained, high activity of the Notch signalling pathway is critical for the maintenance of MuSCs in a quiescence state. Of interest, whole-genome ChIP for direct Notch/Rbpj transcriptional targets identified specific micro-RNAs and collagen genes in satellite cells. Using genetic tools to conditionally activate or abrogate Notch signalling, we demonstrate that the expression of these target genes is controlled by the Notch pathway in vitro and in vivo. Further, we propose that Collagen V and miR708 can contribute cell-autonomously to the generation of the MuSCs niche via a Notch signalling-regulated mechanism.
49

O papel da sinalização Notch na diferenciação do epitélio pulmonar. / The role of Notch signaling in lung epithelial differentiation.

Michelle Vasconcelos 16 January 2012 (has links)
O epitélio pulmonar é formado por uma grande diversidade celular, que incluí: células secretoras, ciliadas, basais e neuroendócrinas (NE). A distribuição balanceada destes tipos celulares é crucial para a função pulmonar e pode ser dramaticamente alterada em doenças como a asma. Neste trabalho, estudamos o papel de Notch no pulmão em desenvolvimento ao inativar condicionalmente Rbpjk ou Pofut1, componentes críticos da sinalização Notch. Pulmões mutantes apresentaram-se superpopulados por células ciliadas e NE, além da ausência de células de Clara. Nossos dados sugeriram que Notch suprime os programas de diferenciação de células ciliadas e NE para permitir a diferenciação de células de Clara, através de um mecanismo de inibição lateral. Identificamos também genes associados com a diferenciação de células secretoras e ciliadas através de microarrays. A heterogeneidade no padrão de expressão gênica sugeriu que a via de sinalização Notch estabelece múltiplos subtipos de células ciliadas e secretoras no epitélio pulmonar em desenvolvimento. / The airway epithelium comprises a diverse population of secretory, ciliated, basal and neuroendocrine cells (NE). The proper balance of these cell types is critical for normal lung function and can be altered dramatically in conditions, such as asthma. We studied the role of Notch in airway progenitor cell fate by conditionally inactivating Rbpjk or Pofut1, two critical Notch pathway components in mouse mutants. This resulted in airways overpopulated with ciliated and NE cells and absence of secretory Clara cells. We found that Notch suppresses the ciliated and the NE cell programs to allow secretory cell differentiation through a lateral inhibition mechanism. We also identified genes associated with the differentiation of secretory and ciliated cells through a microarray gene profiling experiment. The great heterogeneity of gene expression patterns suggested that Notch plays a role in establishing multiple subsets of secretory and ciliated cells in the developing lung.
50

B cells with aberrant activation of Notch1 signaling promote Treg and Th2 cell-dominant T cell responses via IL-33 / Notch1シグナルが異常活性化したB細胞はIL-33を介して制御性T細胞および2型ヘルパーT細胞優位のT細胞免疫応答を促進する

Arima, Hiroshi 23 January 2019 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第21451号 / 医博第4418号 / 新制||医||1032(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 生田 宏一, 教授 椛島 健治, 教授 河本 宏 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Page generated in 0.0886 seconds