1 |
An Atat1/Mec-17-Myosin II axis controls ciliogenesisRao, Yanhua January 2013 (has links)
<p>Primary cilia are evolutionarily conserved, acetylated microtubule-based organelles that transduce mechanical and chemical signals. Primary cilium assembly is tightly controlled and its deregulation causes a spectrum of human diseases. Formation of primary cilium is a collaborative effort of multiple cellular machineries, including microtubule, actin network and membrane trafficking. How cells coordinate these components to construct the primary cilia remains unclear. In this dissertation research, we utilized a combination of cell biology, biochemistry and light microscopy technologies to tackle the enigma of primary cilia formation, with particular focus on isoform-specific roles of non-muscle myosin II family members. We found that myosin IIB (Myh10) is required for cilium formation. In contrast, myosin IIA (Myh9) suppresses cilium formation. In Myh10 deficient cells, Myh9 inactivation significantly restores cilia formation. Myh10 antagonizes Myh9 and increases actin dynamics, permitting pericentrosomal preciliary complex formation required for cilium assembly. Importantly, Myh10 is upregulated upon serum starvation-induced ciliogenesis and this induction requires Atat1/Mec-17, the microtubule acetyltransferase. Our findings suggest that Atat1/Mec17-mediated microtubule acetylation is coupled to Myh10 induction, whose accumulation overcomes the Myh9-dependent actin cytoskeleton, thereby activating cilium formation. Thus, Atat1/Mec17 and myosin II coordinate microtubules and the actin cytoskeleton to control primary cilium biogenesis.</p> / Dissertation
|
2 |
Combined Experimental and Mathematical Approach for Development of a Microfabrication-Based Model to Investigate Cell-Cell Interaction during MigrationSarkar, Saheli 30 March 2011 (has links)
No description available.
|
3 |
Constrição celular apical durante a invaginação do placóide do cristalino em galinhas. / Apical cell constriction during chicken lens placode invagination.Borges, Ricardo Moraes 06 November 2008 (has links)
O cristalino de vertebrados se origina a partir da invaginação do ectoderme que recobre a vesícula óptica. A invaginação epitelial em diversos modelos é causada pela constrição celular apical, mediada pela contração apical de actina e miosina II e regulada pela GTPase RhoA. Neste trabalho nós investigamos se a invaginação do cristalino em embriões de galinha ocorre devido à constrição celular apical e se este evento é controlado por RhoA. Actina filamentosa e miosina II são expressas na porção apical do cristalino durante a invaginação. Quando a polimerização de actina é inibida por Citocalasina D, o cristalino não invagina, sugerindo que a constrição celular apical poderia contribuir para a invaginação do cristalino. RhoA também é expressa durante o desenvolvimento do cristalino, mas a inibição de RhoA, por eletroporação da forma dominante-negativo, não impediu a invaginação do placóide do cristalino, não alterou a distribuição de miosina II na porção apical do cristalino nem sua ativação, indicando que a invaginação do cristalino independe de RhoA. / Vertebrate lens derives from invagination of the ectoderm that overlies optic vesicles. Epithelial invagination in many model systems is driven by apical cell constriction, mediated by actin and myosin II contraction regulated by GTPase RhoA. Here we investigate the possibility that chick lens placode invagination could also be driven by apical cell constriction and controlled by RhoA. We show that actin and myosin II are expressed at lens apical side during lens invagination. Actin polymerization inhibition by in ovo Cytochalasin D treatment prevents lens placode invagination, suggesting that lens placode invagination could be driven by apical cell constriction. RhoA GTPase is also expressed at apical portion of lens placode and during lens invagination. However, when we overexpressed by electroporation the dominant-negative RhoA in the pre-lens ectoderm invagination was not affected. Furthermore, dominant-negative RhoA didnt affect myosin II apical localization nor myosin II phosphorilation, indicating that in lens invagination this process is not regulated by GTPase RhoA.
|
4 |
Constrição celular apical durante a invaginação do placóide do cristalino em galinhas. / Apical cell constriction during chicken lens placode invagination.Ricardo Moraes Borges 06 November 2008 (has links)
O cristalino de vertebrados se origina a partir da invaginação do ectoderme que recobre a vesícula óptica. A invaginação epitelial em diversos modelos é causada pela constrição celular apical, mediada pela contração apical de actina e miosina II e regulada pela GTPase RhoA. Neste trabalho nós investigamos se a invaginação do cristalino em embriões de galinha ocorre devido à constrição celular apical e se este evento é controlado por RhoA. Actina filamentosa e miosina II são expressas na porção apical do cristalino durante a invaginação. Quando a polimerização de actina é inibida por Citocalasina D, o cristalino não invagina, sugerindo que a constrição celular apical poderia contribuir para a invaginação do cristalino. RhoA também é expressa durante o desenvolvimento do cristalino, mas a inibição de RhoA, por eletroporação da forma dominante-negativo, não impediu a invaginação do placóide do cristalino, não alterou a distribuição de miosina II na porção apical do cristalino nem sua ativação, indicando que a invaginação do cristalino independe de RhoA. / Vertebrate lens derives from invagination of the ectoderm that overlies optic vesicles. Epithelial invagination in many model systems is driven by apical cell constriction, mediated by actin and myosin II contraction regulated by GTPase RhoA. Here we investigate the possibility that chick lens placode invagination could also be driven by apical cell constriction and controlled by RhoA. We show that actin and myosin II are expressed at lens apical side during lens invagination. Actin polymerization inhibition by in ovo Cytochalasin D treatment prevents lens placode invagination, suggesting that lens placode invagination could be driven by apical cell constriction. RhoA GTPase is also expressed at apical portion of lens placode and during lens invagination. However, when we overexpressed by electroporation the dominant-negative RhoA in the pre-lens ectoderm invagination was not affected. Furthermore, dominant-negative RhoA didnt affect myosin II apical localization nor myosin II phosphorilation, indicating that in lens invagination this process is not regulated by GTPase RhoA.
|
5 |
Characterizing cortical myosin mini-filament regulation, length and its macroscopic implications in cytokinetic dynamicsPatino Descovich, Carlos 09 1900 (has links)
No description available.
|
6 |
The Development and Regeneration of the Serotonergic SystemHawthorne, Alicia Lynn 06 July 2010 (has links)
No description available.
|
Page generated in 0.0156 seconds