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  • 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.
1

The role of alpha-catenin and ZO-1 in coupling tight junctions to adherens junctions

Maiers, Jessica Louise 01 December 2013 (has links)
Cell-cell junctions are essential for tissue homeostasis. Prominent among these junctions are adherens junctions and tight junctions. Adherens junctions mediate adhesion between adjacent cells while tight junctions are responsible for establishing apical-basolateral polarity and limiting paracellular permeability. Loss or disruption of either adherens junctions or tight junctions leads to a myriad of disease states, thus these junctions need to be tightly regulated to prevent dysfunction. A unique property of tight junctions is their dependence on adherens junctions for proper assembly and maintenance. Loss or disruption of adherens junction leads to abnormal tight junctions. Understanding the mechanisms that mediate tight junction coupling to adherens junctions is important for treating diseases that arise from disrupted cell-cell junctions. Currently, two controversial models exist for how tight junctions are coupled to adherens junctions. In the first model, the adherens junction protein α-catenin is critical for tight junction assembly. The second model suggests that a second adherens junction protein, nectin is critical for tight junction assembly through binding the tight junction protein ZO-1, and disruption of tight junction assembly is independent of E-cadherin. α-catenin also binds ZO-1, but the consequences of this interaction are unknown. I hypothesized that α-catenin binding to ZO-1 plays a critical role in coupling tight junctions to adherens junctions. To test this, I mapped the ZO-1 binding site on α-catenin and engineered a point mutant of α-catenin that failed to bind ZO-1. Expression of this point mutant in epithelial cells showed that ZO-1 binding to α-catenin is essential for tight junction assembly and maintenance, while adherens junctions were unaffected. These findings established a role for ZO-1 binding to α-catenin in coupling tight junctions to adherens junctions during junction assembly, as well as at steady-state conditions. After discovering the importance of ZO-1 binding to α-catenin in coupling tight junctions to adherens junctions, I wanted to study whether this interaction is critical in a physiological setting. Tight junctions and adherens junctions are both strengthened in response to mechanical force; however the mechanisms responsible for tight junction strengthening were unknown. Using the system I previously developed, I show that ZO-1 binding to α-catenin is essential for increased tight junction integrity in response to mechanical force, coupling changes in tight junctions to increased stability of adherens junctions. Together, these findings identify a novel interaction that is critical for coupling tight junctions to adherens junctions under several conditions, and provide mechanistic insight into the cellular response to mechanical force.
2

Die funktionelle Bedeutung des Coxsackie- und Adenovirus Rezeptors (CAR) im kolorektalen Karzinom / Functional role of the Coxsackie and Adenovirus Receptor (CAR) in colorectal carcinomas

Küster, Katrin January 2009 (has links)
Der Coxsackie- und Adenovirus Rezeptor (CAR) ist als Bestandteil von Tight Junctions (TJ) an interzellulären Adhäsionsprozessen beteiligt und scheint eine wichtige Rolle in der Karzinogenese zu spielen. Diese ist jedoch insbesondere bei Entstehung von Darmkrebs weitgehend unklar. Ziel der Arbeit war es daher, die funktionelle Bedeutung, mögliche Interaktionspartner sowie die Expressionsregulation von CAR im kolorektalen Karzinom zu analysieren. In den Zelllinien CaCo2, Colo205, DLD1, HCT116, HT29, SW480 und T84 konnte die Expression von CAR (mRNA und Protein) nachgewiesen werden. Nach stabiler CAR-Überexpression durch Transfektion von CARcDNA in DLD1, HCT116 und SW480 wurde das Zellwachstum gehemmt und eine Abnahme von Migration und Invasion induziert. Eine stabile CAR-Inhibition nach Transfektion von CARsiRNA führte in diesen Zelllinien zum Anstieg der Proliferation sowie zu verstärkter Migrations- und Invasionsaktivität, die in DLD1 mit morphologischen Änderungen einhergingen. Eine Genexpressionsanalyse der Zelllinie DLD1 mit CAR-Inhibition identifizierte α-Catenin als das am stärksten regulierte Gen. Obwohl keine direkte Interaktion beider Proteine detektiert werden konnte, führte eine stabile Re-Expression von α-Catenin in DLD1 mit stabiler CAR-Inhibition zu einer deutlichen Reduktion von Proliferation, Migration und Invasion sowie zu einem Rückgang der zellmorphologischen Änderungen. Um den Einfluss von Differenzierung auf die Regulation der CAR-Expression zu untersuchen, erfolgte eine Behandlung aller Zelllinien mit Natriumbutyrat. Dies führte in fünf der sieben Zelllinien zu einer Aktivierung des CAR-Promotors sowie zu einer gesteigerten Expression und Immunoreaktivität von CAR an der Zelloberfläche. Die Zelllinie CaCo2 zeigte nach spontaner Differenzierung durch 21-tägiges Wachstum post Konfluenz ebenfalls eine verstärkte CAR-mRNA-Expression sowie eine erhöhte CAR-Präsenz an der Zelloberfläche. Die gewonnenen Daten konnten die funktionelle Bedeutung von CAR für die Kolonkarzinogenese sowie den Einfluss von α-Catenin auf diese Funktion deutlich machen. Es wurde gezeigt, dass die Expressionsregulation sowie die subzelluläre Verteilung von CAR durch den zellulären Differenzierungsstatus beeinflusst werden kann. / The Coxsackie and Adenovirus Receptor (CAR) is a transmembrane compound of the tight junctions in polarized epithelial cells mediating cellular adhesion. CAR was suggested to play a functional role in the development of epithelial malignomas but detailed knowledge is still lacking, especially for the colorectal carcinoma. Therefore, the functional impact and regulation of CAR expression in human colorectal carcinoma cell models were investigated. CAR protein and mRNA was detectable in the cell lines CaCo2, Colo205, DLD1, HCT116, HT29, SW480 and T84. Stable CAR over expression by transfection of CARcDNA in DLD1, HCT116 and SW480 led to reduced proliferation in vitro and in vivo. Also reduced migration and invasion were observed. Stable CAR inhibition by transfection of CARsiRNA in the same cell lines resulted in increased migration and invasion. In DLD1 morphological changes were found after CAR inhibition. Differential gene expression was detected in DLD1 cells with stable CAR inhibition revealing an 18-fold decrease in α-Catenin gene expression. Loss of α-Catenin was obtained on protein level, too. Although no direct interaction between CAR and α-Catenin could be proven ectopic re-expression of α-Catenin in DLD1 with CAR inhibition reversed the determined functional and morphological effects of a CAR knock down. Then, the impact of differentiation on regulation of CAR expression was investigated. Sodium butyrate treatment induced differentiation in all cell lines (determined by alkaline phosphatase activity), which was paralleled by an increase of CAR immunoreactivity at the plasma membrane in all cell lines but CaCo2. However, CAR protein and mRNA expression, as well as CAR gene promoter activity increased in 5 cell lines only, whereas in SW480 and CaCo2 a down regulation was observed. Spontaneous differentiation of CaCo2 after a growth period of 21 days post confluence resulted in up regulation of CAR mRNA expression as well as increased CAR presence at the plasma membrane. The data suggest that CAR plays a crucial role in the carcinogenesis of colorectal carcinoma which could be influenced by α-Catenin interaction. Differentiation determines the regulation of CAR expression and the subcellular distribution of CAR in colon cancer cells.
3

Dynamique de la jonction adhérente : rôle d'EPLIN dans la stabilité des contacts intercellulaires de l'endothélium vasculaire / Dynamic of adherens junction : role of EPLIN in intercellular contacts stability of vascular endothelium

Pétinot, Adeline 07 October 2011 (has links)
L'endothelium vasculaire constitue la principale barrière entre le sang et les tissus régulant le passage de macromolécules et de cellules circulantes. Longtemps considéré comme une monocouche passive, l'endothélium joue d'importants rôles dans la régulation de la pression sanguine, de l'hémostase, des réponses immunitaires et inflammatoires. L'adhérence cellule/cellule est initiée dans l'endothélium vasculaire par des interactions homophiliques entre molécules de VE-cadhérine (= jonctions adhérentes). La dynamique de la jonction et du cytosquelette est importante pour le remodelage des jonctions intercellulaires qui a lieu au cours l'angiogenèse, de la vasculogenèse et lors de la réparation de l'endothélium. C'est pourquoi la détermination des mécanismes moléculaires sous-jacents est indispensable à la comprehension de phénomènes physiopathologiques (angiogenèse et progression tumorales, inflammation...). D'après la littérature, la protéine EPLIN intervient dans la formation du complexe E-cadhérine/alpha-caténine/EPLIN et stabilise l'actine corticale. Actuellement décrite comme spécifique des modèles épithéliaux, EPLIN peut-elle intervenir dans la liaison du complexe à base de VE-cadhérine au cytosquelette d'actine? De plus, il paraît essentiel de comprendre le rôle de cette protéine dans les cellules car son expression est fortement diminuée dans la plupart des cancers alors qu'à l'inverse sa surexpression bloque la prolifération cellulaire. / The endothelium forms the main barrier regulating the passage of macromolecules and circulating cells between the blood and tissue. Historically viewed as a passive vascular lining, vascular endothelium plays important roles in the regulation of vascular pressure, hemostasis, immune and inflammatory responses. In vascular endothelium, cell/cell adhesion is mediated by homophilic interactions of VE-cadherin molecules (= adherens junctions). Cytoskeleton and junction dynamics are important for intercellular junctions remodelling that occurs during angiogenesis, vasculogenesis and endothelium repair. So, determining the underlying molecular mechanisms is essential for the comprehension of pathologic phenomena such as angiogenesis, tumor progression or inflammation. We learn from the literature that EPLIN is involved in E-cadherin/α-catenin/EPLIN complex formation and cortical actin stabilization. Usually described as a protein specific of epithelial models, we wondered if EPLIN is able to link VE-cadherin complex to actin cytoskeleton. Furthermore, it seems essential to understand its cellular role since it is downregulated in many cancers while in contrast its overexpression blocks cell proliferation.
4

Functional Relationship between Merlin and the ERM Proteins

Hebert, Alan 05 October 2013 (has links)
The ability to spatially restrict specific activities across the cell cortex functionally defines individual cells and tissues. This is achieved, in part, via the assembly of protein complexes that link the plasma membrane to the underlying cortical actin cytoskeleton. The neurofibromatosis type 2 (NF2) tumor suppressor Merlin and closely related ERM proteins (Ezrin, Radixin and Moesin) are a special class of such membrane:cytoskeleton associated proteins that function to organize specialized cortical domains. In addition to their high degree of similarity, mounting evidence suggests that Merlin/ERMs share a functional relationship, which is largely unexplored. Unlike Merlin, the ERMs are not known to inhibit cell proliferation; in fact, Ezrin is thought to promote tumor metastasis. Defining the relationship between Merlin and the ERMs is essential to appreciating their respective roles in cancer development. Here I demonstrate a novel role for Merlin and the ERMs in generating cortical asymmetry in the absence of external cues. Our data reveal that Merlin functions to restrict the cortical distribution of Ezrin, which in turn positions the interphase centrosome in single epithelial cells and 3D organotypic cultures. In the absence of Merlin, ectopic cortical Ezrin yields mispositioned centrosomes, misoriented spindles and aberrant epithelial architecture. Furthermore, in tumor cells with centrosome amplification, the failure to restrict cortical Ezrin abolishes centrosome clustering, yielding multipolar mitoses. Consistent with a functional relationship, I observe a strong genetic interaction between Nf2 and Ezrin in the mouse intestine in vivo. Finally, I begin to address the basis of their functional interaction by testing whether they are coordinately regulated by the Ste-20 like kinase SLK. Altogether, these data uncover fundamental roles for Merlin/ERM proteins in spatiotemporally organizing the cell cortex in vitro and in vivo and suggest that Merlin’s role in promoting cortical heterogeneity may contribute to tumorigenesis by disrupting cell polarity, spindle orientation and potentially genome stability.

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