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Extracellular Fluid Systems in the Brain and the Pathogenesis of HydrocephalusNagra, Gurjit 22 February 2011 (has links)
Fundamental questions related to the locations of Cerebrospinal Spinal Fluid (CSF) absorption deficit and causes of the pressure gradients that expand the ventricles with hydrocephalus remain largely unanswered.
Work in the Johnston lab over a 15 year period has demonstrated that CSF moves through the cribriform plate foramina in association with the olfactory nerves and is absorbed by a network of lymphatic vessels located within the olfactory turbinates. A kaolin-based rat model of communicating hydrocephalus was developed as a collaborative effort with Drs. McAllister, Wagshul and Li. After developing a method to quantify lymphatic CSF uptake in rats, we examined and observed that the movement of a radioactive tracer into the nasal turbinates was significantly reduced in the kaolin-injected animals compared to saline injected controls. However, it was possible that while lymphatic CSF uptake was compromised, other CSF absorption pathways may have compensated. To answer this, we measured the CSF outflow resistance (Rout) and observed it to be significantly greater in the kaolin group compared with animals receiving saline and there was a significant positive correlation between CSF Rout and ventricular volume. Nonetheless, it is not clear how impaired CSF clearance could lead to a dilation of the ventricles since the ventricular and subarachnoid compartments are in communication with one another and pressure would likely increase equally in both.
At this point, we came across a theoretical paper that postulated that a drop in periventricular interstitial fluid pressure might provide an intraparenchymal pressure gradient favouring ventricular expansion. In addition, studies in non-CNS tissues indicated that a disruption of beta-1 (β1) integrin-matrix interactions could lower tissue pressure. Based on these suppositions and data, we examined if these concepts had relevance to the brain. For this, we measured pressure in the brain and observed a decline in periventricular pressures to values significantly below those monitored in the ventricular system following the injection of the anti integrin antibodies. Many of the animals developed hydrocephalus over 2 weeks post antibody injection. These data provide a novel mechanism for the generation of intraparenchymal pressure gradients that is likely contributing to ventricular expansion.
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Extracellular Fluid Systems in the Brain and the Pathogenesis of HydrocephalusNagra, Gurjit 22 February 2011 (has links)
Fundamental questions related to the locations of Cerebrospinal Spinal Fluid (CSF) absorption deficit and causes of the pressure gradients that expand the ventricles with hydrocephalus remain largely unanswered.
Work in the Johnston lab over a 15 year period has demonstrated that CSF moves through the cribriform plate foramina in association with the olfactory nerves and is absorbed by a network of lymphatic vessels located within the olfactory turbinates. A kaolin-based rat model of communicating hydrocephalus was developed as a collaborative effort with Drs. McAllister, Wagshul and Li. After developing a method to quantify lymphatic CSF uptake in rats, we examined and observed that the movement of a radioactive tracer into the nasal turbinates was significantly reduced in the kaolin-injected animals compared to saline injected controls. However, it was possible that while lymphatic CSF uptake was compromised, other CSF absorption pathways may have compensated. To answer this, we measured the CSF outflow resistance (Rout) and observed it to be significantly greater in the kaolin group compared with animals receiving saline and there was a significant positive correlation between CSF Rout and ventricular volume. Nonetheless, it is not clear how impaired CSF clearance could lead to a dilation of the ventricles since the ventricular and subarachnoid compartments are in communication with one another and pressure would likely increase equally in both.
At this point, we came across a theoretical paper that postulated that a drop in periventricular interstitial fluid pressure might provide an intraparenchymal pressure gradient favouring ventricular expansion. In addition, studies in non-CNS tissues indicated that a disruption of beta-1 (β1) integrin-matrix interactions could lower tissue pressure. Based on these suppositions and data, we examined if these concepts had relevance to the brain. For this, we measured pressure in the brain and observed a decline in periventricular pressures to values significantly below those monitored in the ventricular system following the injection of the anti integrin antibodies. Many of the animals developed hydrocephalus over 2 weeks post antibody injection. These data provide a novel mechanism for the generation of intraparenchymal pressure gradients that is likely contributing to ventricular expansion.
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Functional Interactions between the Discoidin Domain Receptor 1 and Beta 1 IntegrinsStaudinger, Lisa Alexandra 19 March 2013 (has links)
The rate limiting step of phagocytosis is the binding of collagen to specific receptors, which include β1 integrins and the discoidin domain receptor 1 (DDR1). While these two receptors may interact, the functional nature of these interactions is not defined. We examined the effects of DDR1 over-expression on β1 integrin function and determined that DDR1 over-expression enhanced cell attachment through β1 integrins. These data are consistent with data showing that DDR1 over-expression enhanced cell-surface, but not total, β1 integrin expression and activation. As shown by experiments with endoglycosidase H, DDR1 over-expression increased glycosylation of the β1 integrin subunit. Collectively these data indicate that DDR1 enhances β1 integrin interactions with fibrillar collagen, possibly by affecting the processing and trafficking of β1 integrins to the cell surface. Our data provide insight into the mechanisms by which fibrotic conditions such as cyclosporine A-induced gingival overgrowth are regulated.
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Functional Interactions between the Discoidin Domain Receptor 1 and Beta 1 IntegrinsStaudinger, Lisa Alexandra 19 March 2013 (has links)
The rate limiting step of phagocytosis is the binding of collagen to specific receptors, which include β1 integrins and the discoidin domain receptor 1 (DDR1). While these two receptors may interact, the functional nature of these interactions is not defined. We examined the effects of DDR1 over-expression on β1 integrin function and determined that DDR1 over-expression enhanced cell attachment through β1 integrins. These data are consistent with data showing that DDR1 over-expression enhanced cell-surface, but not total, β1 integrin expression and activation. As shown by experiments with endoglycosidase H, DDR1 over-expression increased glycosylation of the β1 integrin subunit. Collectively these data indicate that DDR1 enhances β1 integrin interactions with fibrillar collagen, possibly by affecting the processing and trafficking of β1 integrins to the cell surface. Our data provide insight into the mechanisms by which fibrotic conditions such as cyclosporine A-induced gingival overgrowth are regulated.
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Etude des mécanismes moléculaires régulant la voie Hippo via les intégrines ß1 / Study of the molecular mechanisms regulating the Hippo pathway via the integrins b1Sabra, Hiba 29 June 2017 (has links)
L'adhérence cellulaire à la matrice extracellulaire joue un rôle clé dans leur prolifération,leur différenciation ou l'apoptose. Par conséquent ce processus est critique pour undéveloppement normal et pour l'homéostasie tissulaire. La dérégulation de ce mécanismecontribue souvent à des situations pathologiques. Ainsi, la dérégulation de nombreux gènesimpliqués dans les adhérences cellule-cellule ou cellule-matrice extracellulaire sont liés à despathologies conduisant à un défaut de développement, la progression tumorale, oul'inflammation.Les intégrines sont des récepteurs transmembranaires hétéro dimériques jouant un rôlemajeur dans les interactions cellule-matrice extracellulaire. Ce rôle n'est pas limité à unesimple interaction mécanique puisqu'elles permettent également la transduction dessignaux de la matrice extracellulaire à la cellule afin de permettre à cette dernière des'adapter à son micro environnement. Dans le but d’étudier le rôle des intégrines à chaîneβ1 dans le développement osseux, le laboratoire a mis en place un modèle murind'inactivation conditionnelle du gène Itgb1 basée sur l'expression de la recombinase Cre austade pré-ostéoblastique. Les souris mutées présentent un défaut de développementosseux, dû à une faible prolifération des ostéoblastes.Contrairement à ce qui était généralement admis, cette faible prolifération desostéoblastes est indépendante de la voie classique mettant en jeu la voie classique des MAPkinases. En revanche, elle est contrôlée par la voie Hippo: cette signalisation a étérécemment identifiée chez la Drosophile et les Mammifères comme un mécanismeinhibiteur majeur de la prolifération cellulaire. Le cofacteur de transcription YAP, effecteurfinal de cette voie, est une navette nucléo-cytoplasmique. Son expression est amplifiée dansdivers cancers dont l'ostéosarcome où cette surexpression associée à celle de l’Itgb1 est unfacteur de mauvais pronostique.Mes travaux consistent à comprendre comment les intégrines à chaîne β1 contrôlent lavoie Hippo, et donc la prolifération. Nous avons confirmé que la délétion des intégrines β16active la phosphorylation de YAP et sa séquestration dans le cytoplasme. En utilisant destechniques de Biologie Cellulaire et de Biochimie, nous avons montré que suite à la délétionde l’Itgb1, les cellules présentent un défaut de trafic vésiculaire réduisant la translocationmembranaire de Rac1. La séquestration cytoplasmique de Rac1 diminue l’activation de soneffecteur majeur la kinase PAK responsable de la dissociation d'un complexe membranaired'inactivation composé de la protéine adaptatrice NF2, la kinase LATS et de son effecteurprincipal YAP. Les intégrines en provocant la perte de ce complexe induisent ladéphosphorylation de YAP, sa translocation nucléaire et donc stimulent la proliférationcellulaire. / Cell adhesion to the extracellular matrix plays a key role in their proliferation,differentiation or apoptosis. Therefore, this process is critical for normal development andtissue homeostasis. The deregulation of this mechanism often contributes to pathologicalsituations. Thus, the deregulation of many genes involved in cell-cell or cell-extracellularmatrix adhesions are linked to pathologies leading to developmental defects, tumorprogression, or inflammation.Integrins are heterodimeric transmembrane receptors that play a major role in cellextracellularmatrix interactions. This role is not limited to a simple mechanical interactionsince integrins also allow the transduction of the signals from the extracellular matrix to thecell in order to permit the latter to adapt to its microenvironment. In order to study the roleof β1 integrins in bone development, the laboratory has implemented a mouse model withconditional inactivation of the Itgb1 gene based on the expression of recombinase Cre at thepre-osteoblastic stage. The mutated mice show a defect in bone development due to a lowproliferation rate of osteoblasts.Contrary to what was generally accepted, this reduced proliferation is independent of theclassical pathway involving the classical pathway of MAP kinases. On the other hand, it iscontrolled by Hippo: this signaling pathway has recently been identified in Drosophila andMammals as a major inhibitory mechanism of cell proliferation. The transcription cofactorYAP, the end effector of this pathway, is a nucleo-cytoplasmic shuttle. Its expression isamplified in various cancers including osteosarcoma where this overexpression associatedwith that of Itgb1 is a factor of poor prognosis.My work involves understanding how β1 integrins control the Hippo pathway, and thusproliferation. We confirmed that deletion of β1 integrins activates the phosphorylation ofYAP and its sequestration in the cytoplasm. Using Cell Biology and Biochemistry techniques,we showed that following the deletion of Itgb1, the cells exhibit a defect in vesicular trafficthat reduces the membrane translocation of Rac1. The cytoplasmic sequestration of Rac18decreases the activation of its major effector, the PAK kinase. PAK is responsible for thedissociation of an inactivating membrane complex composed of the adaptor protein NF2,the LATS kinase, and its main effector YAP. The integrins by provoking the loss of thiscomplex induce the dephosphorylation of YAP, its nuclear translocation, and thus stimulatecell proliferation.
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