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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

Structural Studies of Talin-mediated Integrin Activation

Bakhautdin, Esen January 2009 (has links)
No description available.
2

Molecular Basis of the Role of Kindlin 2 in Cell Adhesion

Perera, Hettiarachchige Dhanuja Deepamalee January 2010 (has links)
No description available.
3

Structural and Functional Aspects of β1 Integrin Signalling

Nilsson, Stina January 2006 (has links)
<p>Integrins are transmembrane glycoproteins primarily mediating interactions of cells with the extracellular matrix. Each receptor is a complex of one α- and one β-subunit with affinity for a diverse set of ligands. A prerequisite for ligand binding, and subsequent events, is the activation of integrins by cytoplasmic signals that confer a large conformational change to the extracellular domain.</p><p>In this thesis, the role of a cytoplasmic threonine-cluster, conserved in several β subunits, in β1-integrin activation was investigated. Phosphorylation of these residues is postulated to regulate β2 and β3 integrin affinity for ligands, but it has not been shown so far to occur for β1. Residue T788, but not T789, was established as a site of critical importance for inside-out activation of β1 integrins by mutagenesis to alanine. In contrast to β1-T788A, a phospho-mimicking mutation, β1-T788D, expressed the conformation sensitive 9EG7-epitope and mediated normal cell adhesion. In addition, the T788D mutation did not interfere with binding of the talin head domain, an interaction important for integrin activation. Thus, phosphorylation of T788 in integrin β1 was concluded to be compatible with inside-out receptor activation, in line with β2 and β3 integrin regulation. </p><p>Focal adhesion kinase (FAK) is activated after integrin ligation and is, together with Src, one of the central players in integrin-mediated events. Phosphatidylinositol 3-kinase (PI3K) is thought to be activated by binding to FAK. However, a novel, major β1-integrin signalling pathway to activate PI3K was identified, which is FAK- and Src-independent.</p><p>Growth factor induced stimulation of extracellular signal-regulated kinase (Erk) is largely dependent on signals from integrin mediated adhesion to pass checkpoints downstream of Ras. The mechanisms by which β1-integrins mediate Erk-activation were characterized by pin-pointing what phosphorylation sites on the mitogen-activated protein (MAP) kinases and their effector proteins were FAK-dependent. The results indicated that β1 integrins can promote Erk activation by FAK-dependent mechanisms at the levels of both cRaf and Mek, and in addition, a FAK-independent checkpoint at the level of Mek activation.</p>
4

Structural and Functional Aspects of β1 Integrin Signalling

Nilsson, Stina January 2006 (has links)
Integrins are transmembrane glycoproteins primarily mediating interactions of cells with the extracellular matrix. Each receptor is a complex of one α- and one β-subunit with affinity for a diverse set of ligands. A prerequisite for ligand binding, and subsequent events, is the activation of integrins by cytoplasmic signals that confer a large conformational change to the extracellular domain. In this thesis, the role of a cytoplasmic threonine-cluster, conserved in several β subunits, in β1-integrin activation was investigated. Phosphorylation of these residues is postulated to regulate β2 and β3 integrin affinity for ligands, but it has not been shown so far to occur for β1. Residue T788, but not T789, was established as a site of critical importance for inside-out activation of β1 integrins by mutagenesis to alanine. In contrast to β1-T788A, a phospho-mimicking mutation, β1-T788D, expressed the conformation sensitive 9EG7-epitope and mediated normal cell adhesion. In addition, the T788D mutation did not interfere with binding of the talin head domain, an interaction important for integrin activation. Thus, phosphorylation of T788 in integrin β1 was concluded to be compatible with inside-out receptor activation, in line with β2 and β3 integrin regulation. Focal adhesion kinase (FAK) is activated after integrin ligation and is, together with Src, one of the central players in integrin-mediated events. Phosphatidylinositol 3-kinase (PI3K) is thought to be activated by binding to FAK. However, a novel, major β1-integrin signalling pathway to activate PI3K was identified, which is FAK- and Src-independent. Growth factor induced stimulation of extracellular signal-regulated kinase (Erk) is largely dependent on signals from integrin mediated adhesion to pass checkpoints downstream of Ras. The mechanisms by which β1-integrins mediate Erk-activation were characterized by pin-pointing what phosphorylation sites on the mitogen-activated protein (MAP) kinases and their effector proteins were FAK-dependent. The results indicated that β1 integrins can promote Erk activation by FAK-dependent mechanisms at the levels of both cRaf and Mek, and in addition, a FAK-independent checkpoint at the level of Mek activation.
5

Mécanismes moléculaires d’activation des intégrines par la kindline-2 lors de l’adhésion cellulaire / Molecular mechanisms of integrin activation by kindlin-2 during cell adhesion

Orré, Thomas 29 November 2017 (has links)
Les adhérences focales (AF), structures adhésives reliant la cellule à la matrice extra-cellulaire (MEC), constituent de véritables plateformes de signalisation biochimique et mécanique qui contrôlent l'adhérence, la migration, la différenciation et la survie cellulaire. Les récepteurs transmembranaires intégrines sont au coeur des AF, où elles connectent la MEC au cytosquelette d'actine. Au début des années 2000, la protéine intracellulaire taline, qui se lie aux parties cytoplasmiques bêta des intégrines, était considérée comme le principal activateur des intégrines. Néanmoins, il a depuis été montré que la kindline, autre protéine intracellulaire se liant aux parties bêta cytoplasmiques, jouait également un rôle essentiel dans l'activation des intégrines. Ainsi,plusieurs études ont mis en évidence que la kindline et la taline étaient complémentaires et avaient une action synergique durant l'activation des intégrines. Les bases moléculaires de ces phénomènes restent à déterminer. De plus, la plupart des données sur lerôle de la kindline dans l'adhérence et l'activation des intégrines provient d'expériences menées sur des cellules en suspension et/ou avec l'intégrine plaquettaire αIIbβ3. Ainsi, la régulation de ces processus par la kindline dans les cellules adhérentes est encore peu comprise. Dans cette étude, nous combinons la microscopie PALM et le suivi de protéines individuelles pour révéler le rôle et le comportement de la kindline à l'intérieur et à l'extérieur des AF au cours des événements moléculaires clés se déroulant au niveau de la membrane plasmique, et qui mènent à l'activation des intégrines. Nous avons observé que les intégrines bêta1 etbêta3 portant une mutation ponctuelle inhibant l'interaction avec la kindline montrent un défaut d'immobilisation dans les AF. Nous avons également observé que la kindline-2, qui est enrichie dans les AF, diffusait librement au niveau de la membrane plasmique,à l'intérieur et à l'extérieur des AF. Ceci constitue une distinction majeure par rapport à la taline, qui, au niveau de la membrane plasmique, est essentiellement observée dans les AF où elle est immobile, montrant qu'elle est recrutée dans les AF directement depuis le cytosol sans diffusion latérale membranaire (Rossier et al. 2012). Afin d'identifier les bases moléculaires du recrutement et de la diffusion membranaire de la kindline, nous avons utilisé différents variants mutés de kindline précédemment décrits. Le mutant kindline-2-QW614/615AA (liaison aux intégrines inhibée) montre une diffusion membranaire accrue, ce qui suggère que la kindline peut diffuser au niveau de la membrane plasmique sans être associée aux intégrines. Par ailleurs, la baisse d'immobilisation au niveau des AF observée avec ce mutant montre qu'une partie de l'immobilisation de la kindline est due aux intégrines, suggérant l'existence d'un complexe intégrine-kindline immobile dans les AF. La délétion du domaine PleckstrinHomology (PH) de la kindline diminue considérablement son recrutement et sa diffusion membranaire. Nous avons évalué le rôle fonctionnel du recrutement et de la diffusion membranaire de la kindline en réexprimant ces mutants dans des cellules déplétéesen kindline-1 et -2 (cellules KO kindline-1 -/-, kindline-2 -/-). Ces expériences montrent que le recrutement et la diffusion membranaire de la kindline sont cruciaux pour l'activation des intégrines durant l'étalement cellulaire et favorisent la formation d’adhérences. Cela suggère que la kindline utilise un chemin différent de celui de la taline pour atteindre et activer les intégrines,ce qui pourrait expliquer au niveau moléculaire comment la kindline complémente la taline durant l'activation des intégrines. / Focal adhesions (FAs) are adhesive structures linking the cell to the extracellular matrix (ECM) and constitute molecular platforms for biochemical and mechanical signals controlling cell adhesion, migration, differentiation and survival. Integrin transmembrane receptors are core components of FAs, connecting the ECM to the actin cytoskeleton. During the early 2000s, the intracellular protein talin, which directly binds to the cytoplasmic tail of β-integrins, was considered as the main integrin activator. Nevertheless, it has been shown that kindlin, another intracellular protein that bind to β-integrin, is also a critical integrin activator. In fact, several studies have shown that kindlin and talin play complementary and synergistic roles during integrin activation. The molecular basis of these phenomena remains to determine. Moreover, most studies focusing on the role of kindlin during integrin activation and cell adhesion have been performed with suspended cells and/or with the platelet integrin αIIbβ3. Here we combined PALM microscopy with single protein tracking to decipher the role and behavior of kindlin during key molecular events occurring outside and inside FAs at the plasma membrane and leading to integrin activation, as we have done previously for talin (Rossier et al., 2012). We found that beta1 and beta3-integrins with a point mutation inhibiting binding to kindlin show reduced immobilization inside FAs. We also found that kindlin-2, which is enriched inside FAs, displayed free diffusion at the plasma membrane outside and inside FAs. This constitutes a major difference with talin, which, at the plasma membrane level, is observed almost exclusively in FAs, where it is immobile, which shows that talin is recruited into FAs directly from the cytosol without lateral diffusion along the plasma membrane (Rossier et al. 2012). To determine the molecular basis of kindlin membrane recruitment and diffusion, we used a kindlin variant known to decrease binding to integrins (kindlin-2- QW614/615AA). This mutant displayed increased membrane diffusion, suggesting that kindlin-2 can freely diffuse at the plasma membrane without interacting with integrins. Moreover, the kindlin-2-QW mutant showed decreased immobilization inside FA, showing that part of kindlin immobilization depends on interaction with integrins. This suggests that kindlin can form an immobile complex with integrins inside focal adhesions. Deletion of the kindlin pleckstrin homology (PH) domain strongly reduced the membrane recruitment and diffusion of kindlin. We assessed the functional role of kindlin membrane recruitment and diffusion by re-expressing different kindlin-2 mutants in kindlin-1/kindlin-2 double KO cells. Those experiments demonstrated that kindlin-2 membrane recruitment and diffusion are crucial for integrin activation during cell spreading and favor adhesion formation. This suggests that kindlin uses a different route from talin to reach integrins and trigger their activation, providing a possible molecular basis for their complementarity during integrin activation.

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