Global ETD Search

341	Effects of Cadmium on Actin Glutathionylation and Focal Adhesions Choong, Grace Mei Yee 21 November 2013 (has links) The toxic metal ion cadmium (Cd2+) is pro-oxidant and specifically disrupts the actin cytoskeleton in renal mesangial cells. This study investigated the role of Cd2+-mediated redox modulation of actin through protein S-glutathionylation and the effects of cytoskeletal changes on focal adhesions (FAs) through a Ca2+/calmodulin dependent-protein kinase II (CaMK-II) pathway. Only at low concentrations of Cd2+ (0.5-2 μM) was there an increase in actin glutathionylation, which was a reactive oxygen species-independent, total glutathione-dependent effect. Immunofluorescence of the cytoskeleton suggests that increases in glutathionylation levels occurring under low [Cd2+] are protective in vivo. Higher concentrations (>= 10 μM) of Cd2+ resulted in loss of vinculin and focal adhesion kinase (FAK) from FAs, concomitant with cytoskeletal disruption. Inhibition of CaMK-II preserved cytoskeletal integrity and focal contacts, while decreasing the migration of FAK-phosphoTyr925 to a membrane-associated compartment. This study adds further insight into the Cd2+-mediated effects on the cytoskeleton and FAs. cadmium toxicology glutathionylation ROS actin cytoskeleton focal adhesions CaMK-II 0383 0379
342	The Role of Substrate Stiffness on the Dynamics of Actin Rich Structures and Cell Behavior Zeng, Yukai 01 November 2014 (has links) Cell-substrate interactions influence various cellular processes such as morphology, motility, proliferation and differentiation. Actin dynamics within cells have been shown to be influenced by substrate stiffness, as NIH 3T3 fibroblasts grown on stiffer substrates tend to exhibit more prominent actin stress fiber formation. Circular dorsal ruffles (CDRs) are transient actin-rich ring-like structures within cells, induced by various growth factors, such as the platelet-derived growth factor (PDGF). CDRs grow and shrink in size after cells are stimulated with PDGF, eventually disappearing ten of minutes after stimulation. As substrate stiffness affect actin structures and cell motility, and CDRs are actin structures which have been previously linked to cell motility and macropinocytosis, the role of substrate stiffness on the properties of CDRs in NIH 3T3 fibroblasts and how they proceed to affect cell behavior is investigated. Cells were seeded on Poly-dimethylsiloxane (PDMS) substrates of various stiffnesses and stimulated with PDGF to induce CDR formation. It was found that an increase in substrate stiffness increases the lifetime of CDRs, but did not affect their size. A mathematical model of the signaling pathways involved in CDR formation is developed to provide insight into this lifetime and size dependence, and is linked to substrate stiffness via Rac-Rho antagonism. CDR formation did not affect the motility of cells seeded on 10 kPa stiff substrates, but is shown to increase localized lamellipodia formation in the cell via the diffusion of actin from the CDRs to the lamellipodia. To further probe the influence of cell-substrate interactions on cell behavior and actin dynamics, a two dimensional system which introduces a dynamically changing, reversible and localized substrate stiffness environment is constructed. Cells are seeded on top of thin PDMS nano-membranes, and are capable of feeling through the thin layer, experiencing the stiffness of the polyacrylamide substrates below the nano-membrane. The membranes are carefully re-transplanted on top of other polyacrylamide substrates with differing stiffnesses. This reversible dynamic stiffness system is a novel approach which would help in the investigation of the influence of reversible dynamic stiffness environments on cell morphology, motility, proliferation and differentiation in various cells types.
343	Cytoskeletal rearrangements in human umbilical vein endothelial cells in response to Staphylococcus aureus Rushing, Frances L. January 2006 (has links) Staphylococcus aureus are Gram-positive bacteria that adhere to the extracellular matrix of susceptible host cells to initiate infection and induce a signal transduction pathway that includes PI3K causing the disruption of cytoskeletal elements within the cytosol. Confocal microscopy was applied to visualize actin within human umbilical vein endothelial cells (HUVEC) to discern behavior during infection. HUVEC lysates were analyzed through immunoprecipitation and Western blot analysis to determine the isoforms of PI3K present in HUVECs. Infection experiments and confocal microscopy reveal a time dependent disruption of actin and a dose dependent decrease in infection when HUVECs are treated with the PI3K inhibitor LY294002. Results of Western blot analysis reveal a distinct band corresponding to the pl l0a isoform of PI3K in HUVECs. These studies taken together suggest that PI3K is involved in the signal transduction pathway induced by the infection of HUVECs by S. aureus, and that infection causes the disruption of cytoskeletal actin fibers. / Department of Biology Actin. Cytoskeleton -- Physiology.
344	On the mechanisms governing plasma membrane organization - a STED-FCS investigation Machado Andrade, Débora 06 January 2014 (has links) No description available. 571.4 STED-FCS plasma membrane organization lipid diffusion cortical actin cytoskeleton Biologie (PPN619462639)
345	Cellular and Molecular Mechanisms Underlying Congenital Myopathy-related Weakness Lindqvist, Johan January 2014 (has links) Congenital myopathies are a rare and heterogeneous group of diseases. They are primarily characterised by skeletal muscle weakness and disease-specific pathological features. They harshly limit ordinary life and in severe cases, these myopathies are associated with early death of the affected individuals. The congenital myopathies investigated in this thesis are nemaline myopathy and myofibrillar myopathy. These diseases are usually caused by missense mutations in genes encoding myofibrillar proteins, but the exact mechanisms by which the point mutations in these proteins cause the overall weakness remain mysterious. Hence, in this thesis two different nemaline myopathy-causing actin mutations and one myofibrillar myopathy-causing myosin-mutation found in both human patients and mouse models were used to investigate the cascades of molecular and cellular events leading to weakness. I performed a broad range of functional and structural experiments including skinned muscle fibre mechanics, small-angle X-ray scattering as well as immunoblotting and histochemical techniques. Interestingly, according to my results, point mutations in myosin and actin differently modify myosin binding to actin, cross-bridge formation and muscle fibre force production revealing divergent mechanisms, that is, gain versus loss of function (papers I, II and IV). In addition, one point mutation in actin appears to have muscle-specific effects. The presence of that mutant protein in respiratory muscles, i.e. diaphragm, has indeed more damaging consequences on myofibrillar structure than in limb muscles complexifying the pathophysiological mechanisms (paper II). As numerous atrophic muscle fibres can be seen in congenital myopathies, I also considered this phenomenon as a contributing factor to weakness and characterised the underlying causes in presence of one actin mutation. My results highlighted a direct muscle-specific up-regulation of the ubiquitin-proteasome system (paper III). All together, my research work demonstrates that mutation- and muscle-specific mechanisms trigger the muscle weakness in congenital myopathies. This gives important insights into the pathophysiology of congenital myopathies and will undoubtedly help in designing future therapies. skeletal muscle skeletal muscle contraction atrophy nemaline myopathy myofibrillar myopathy myosin actin
346	Analysis of <italic>crinkled</italic> Function in <italic>Drosophila melanogaster</italic> Hair and Bristle Morphogenesis Singh, Vinay January 2012 (has links) <p>Mutations in myosin VIIa (MyoVIIa), an unconventional myosin, have been shown to cause Usher Syndrome Type 1B in humans. Usher Syndrome Type 1B is characterized by congenital sensorineural deafness, vestibular dysfunction and pre-pubertal onset of <italic>retinitis pigmentosa</italic>. Mouse model studies show that sensorineural deafness and vestibular dysfunction in MyoVIIa mutants is caused by disruption in the structure of microvilli-like projections (stereocilia) of hair cells in the cochlea and vestibular organ. MyoVIIa has also been shown to affect adaptation of mechanoelectrical transduction channels in stereocilia. </p><p>In <italic>Drosophila melanogaster</italic> mutations in MyoVIIa encoded by <italic>crinkled (ck)</italic> cause defects in hair and bristle morphogenesis and deafness. Here we study the formation of bristles and hairs in <italic>Drosophila melanogaster</italic> to investigate the molecular basis of ck/MyoVIIa function and its regulation. We use live time-lapse confocal microscopy and genetic manipulations to investigate the requirement of ck/MyoVIIa function in various steps of morphogenesis of hairs and bristles. Here we show that null or near null mutations in ck/MyoVIIa lead to the formation of 8-10 short and thin hairs (split hairs) per epithelial cell that are likely the result of the failure of association of hair-actin bundles that in wild-type cells come together to form a single hair.</p><p>The myosin super family of motor proteins is divided into 17 classes by virtue of differences in the sequence of their motor domain, which presumably affect their physiological functions. In addition, substantial variety in the overall structure of their tail plays an important role in the differential regulation of myosin function. In this study we show that ck/MyoVIIa, that has two MyTH4 FERM domains in its tail separated by an SH3 domain, requires both MyTH4 FERM repeats for efficient association of hair-actin bundles to form hairs. We also show that the "multiple hair" phenotype of over-expression of ck/MyoVIIa requires both MyTH4 FERM domain function but not the tail-SH3 domain. We further demonstrate that the tail-SH3 domain of ck/MyoVIIa plays a role in keeping actin bundles, which run parallel to the length of the growing bristle, separate from each other. Our data also suggests that the tail-SH3 domain plays a role in the association of the actin filament bundles with the membrane and regulates F-actin levels in bristles.</p><p>We further demonstrate that over-expression of <italic>Quail</italic> (villin) can rescue the hair elongation defects seen in ck/MyoVIIa null or near null mutants but does not rescue the split hair defects. We show that over-expression of <italic>Alpha-actinin-GFP</italic>, another actin bundling protein, phenocopies the multiple hair phenotype of ck/MyoVIIa over-expression. Over-expression of <italic>Alpha-actinin-GFP</italic> in a ck/MyoVIIa null or near null background shows that <italic>Alpha-actinin-GFP</italic> cannot rescue the split or short hair phenotype of ck/MyoVIIa loss-of-function. However, cells over-expressing <italic>Alpha-actinin-GFP</italic> in a ck/MyoVIIa null or near null background have more than the normal 8-10 split hairs, suggesting that <italic>Alpha-actinin-GFP</italic> over-expression causes the formation of more than the normal complement of hair-actin bundles per cell, resulting in a multiple hair phenotype. We show that <italic>Twinfilin</italic>, an actin monomer sequestering protein implicated in negatively regulating F-actin bundle elongation in stereocilia in a MyoVIIa-dependent manner, is required for F-actin bundle stability. </p><p>In addition, we use yeast two-hybrid strategies to identify <italic>Slam</italic> as a protein that directly binds to ck/MyoVIIa. We show that <italic>Slam</italic>, a novel membrane-associated protein, likely functions to regulate ck/MyoVIIa function during hair and bristle morphogenesis. We show that over-expression of <italic>Slam</italic> and loss-of-function mutations in <italic>Slam</italic> phenocopy ck/MyoVIIa loss-of-function split and short hair phenotype. We also show that disruption of <italic>Slam</italic> and <italic>RhoGEF2</italic> association causes split hair defects similar to ck/MyoVIIa loss-of-function phenotype suggesting that Slam probably regulates ck/MyoVIIa function via <italic>RhoGEF2</italic>.</p><p>Together our results show that ck/MyoVIIa plays an important role in regulating the actin cytoskeleton that underlies actin-based cellular protrusions like hairs and bristles.</p> / Dissertation Developmental biology Cellular biology Biology Actin Bristle crinkled morphogenesis Myosin MyoVIIA
347	Characterization of New Players in Planar Polarity Establishment in Arabidopsis / Karakterisering av nya aktörer vid etablering av planpolaritet i Arabidopsis Pietra, Stefano January 2014 (has links) Coordinated polarity and differentiation of cells in the plane of a tissue layer are essential to the development of multicellular organisms. Arabidopsis thaliana root hairs and trichomes provide model systems to study the pathways that control planar polarity and cell fate specification in plants. A concentration gradient of the plant hormone auxin provides an instructive cue that coordinates polar assembly of signalling complexes at plasma membranes of root epidermal cells; however, knowledge about additional players and cytoskeletal effectors driving cell polarization prior to hair emergence remains limited. On the other hand, epidermal cell fate specification is controlled by a well-characterized gene network of transcription factors that translate positional signals and cell-to-cell communication into tissue-wide patterning. Yet, new components are continuously found to interact with the patterning pathway, shedding light on its connections with diverse developmental processes. This thesis presents the SABRE (SAB) gene as a novel player in planar polarity establishment and root epidermal patterning. SAB is a large protein with sequence similarity to proteins present in all eukaryotes and affects planar polarity as well as orientation of cell divisions and cortical microtubules. Genetic interaction with the microtubule-associated protein gene CLASP further supports involvement of SAB in microtubule arrangement, suggesting a role for this gene in cytoskeletal organisation. Strikingly, SAB also interacts genetically with ACTIN7 (ACT7), and both ACT7 and its modulator ACTIN INTERACTING PROTEIN 1-2 (AIP1-2) contribute to planar polarity of root hair positioning. Cell-file specific expression of AIP1-2 depends on the epidermal-patterning regulator WEREWOLF (WER), revealing a connection between actin organization, planar polarity and cell fate specification. Consistent with this finding, SAB also functions in patterning of the root epidermis by stabilizing cell fate acquisition upstream of the core patterning pathway. These results unveil new roles for SAB in planar polarity and epidermal patterning and suggest that organization of the microtubule and the actin cytoskeleton are important to both planar polarity establishment and cell fate specification. / Samordning av polaritet och differentiering av celler inom ett vävnadslager är avgörande för utvecklingen av multicellulära organismer. Rothår och bladhår hos Arabidopsis thaliana utgör modellsystem för att studera signalvägar som kontrollerar planpolaritet och specifikation av cellers öde hos växter. En koncentrationsgradient av växthormonet auxin ger en instruktiv signal som koordinerar polär hopsättning av signalkomplex vid plasmamembranet i rotepidermisceller; dock är kunskapen om ytterligare aktörer och hur cytoskelettets aktörer påverkar cellpolaritet innan rothår bildas begränsad. Vad gäller differentieringen av epidermala cellers öde kontrolleras dessa genom ett väl karakteriserat nätverk av transkriptionsfaktorer som överför positionssignaler och cell-till-cell kommunikation till vävnadsomfattande mönsterbildning. Fortfarande hittas dock nya komponenter som interagerar med signalvägarna för mönsterbildning, vilket ger nya insikter om dess förbindelser med diverse utvecklingsprocesser. Denna avhandling presenterar genen SABRE (SAB) som en ny aktör i etableringen av planpolaritet och mönsterbildning av rotepidermis. SAB är ett stort protein som har sekvenslikhet med proteiner som finns i alla eukaryoter och det påverkar planpolaritet, orientering av celldelning och kortikala mikrotubler. Genetisk interaktion med genen för det mikrotubuli-associerade proteinet CLASP stärker ytterligare inblandningen av SAB i organiserandet av mikrotubler och antyder att denna gen har en roll i organiserandet av cytoskelettet. Slående är att SAB även interagerar genetiskt med ACTIN7 (ACT7) och att både ACT7 och dess modulator ACTIN-INTERACTING PROTEIN1-2 (AIP1-2) bidrar till planpolaritet vid positionering av rothår. Cellfils-specifikt uttryck av AIP1-2 beror på den epidermala mönsterbildande genen WEREWOLF (WER), vilket påvisar ett samband mellan organisationen av aktin, planpolaritet och specifikationen av cellers öde. SAB fungerar även i mönsterbildning av rotens epidermis och stabiliserar förvärvet av cellöde uppströms av den centrala signalvägen för mönsterbildning. Dessa resultat visar på nya roller för SAB i planpolaritet och mönsterbildning av epidermis och indikerar att organiseringen av mikrotubler och aktin-cytoskelettet är viktiga både för etablerandet av planpolaritet och för specificeringen av cellers öde. SABRE planar polarity CLASP cell division orientation microtubule cytoskeleton actin AIP1 patterning
348	Regulation of Inverted Formin-1 (INF1) by Microtubule-Affinity Regulating Kinase 2 (MARK2) Kulacz, Wojciech 30 April 2012 (has links) The actin and microtubule cytoskeleton plays a critical role in the establishment of cell polarity. Cell processes like mitosis and migration rely on the reorganization of the cytoskeleton to properly function. One driver of cell polarity is the formin, Inverted Formin-1 (INF1). INF1 is able to induce F-actin formation, activate the Serum Response Factor (SRF) pathway, stabilize microtubules, associate with microtubules, and disperse the Golgi body. Regulation of INF1 is unique, since it does not possess conserved formin regulatory domains. However, INF1 does possess many potential phosphorylation sites. In this study, we demonstrate that INF1’s ability to induce F-actin stress fibers and activate SRF is inhibited by Microtubule-Affinity Regulating Kinase 2 (MARK2). Inhibition of INF1’s actin polymerization activity by MARK2 likely occurs near INF1’s C-terminus. However, MARK2 was unable to inhibit INF1’s ability to stabilize microtubules, associate with microtubules, and disperse the Golgi. Furthermore, we show that INF1 overexpression is associated with primary cilium absence and in some cases, the presence of long cilia, suggesting that INF1 plays a role in primary cilium formation. formins Inverted Formin-1 (INF1) actin microtubules primary cilium
349	Origin and Spatial Distribution of Forces in Motile Cells Brunner, Claudia 05 May 2011 (has links) (PDF) Die selbständige, gerichtete Bewegung von biologischen Zellen ist eine der grundlegendsten und komplexesten Erscheinungen der Natur. In höher entwickelten Lebewesen spielt die Zellbewegung eine wichtige Rolle, z.B. bei der Entwicklung des Organismus, bei der Funktion des Immunsystems aber auch bei der Metastase von Krebszellen. Die physikalischen Prozesse die dieser Fähigkeit zugrunde liegen, sind im Fokus dieser Arbeit. Um besser zu verstehen welche Prozesse im Einzelnen und in welcher Kombination den Zellen erlauben sich gerichtet fortzubewegen, wurde in der vorliegenden Arbeit ein representatives Modellsystem von motilen Zellen untersucht. Fischkeratozyten bewegen sich in vitro regelmäßig und gleichförmig, relativ schnell über die Substratfläche, und stellen aus physikalischer Sicht eine optimierte, sich selbständig bewegende Polymermaschine dar. Um Kräfte in der Bewegungsebene der Zellen zu untersuchen, wurde in der vorliegenden Arbeit eine neuartige, auf dem Rasterkraftmikroskop (RKM) basierende Methode entwickelt. Zusätzlich wurden hochaufgelöste, mit dem Phasenkontrastmikroskop aufgenommene Bilderserien analysiert und die Geschwindigkeitsverteilung in der Zelle durch Korrelationsalgorithmen bestimmt. Die Struktur des Polymernetzwerkes wurde in mit Fluoreszenzfarbstoff markierten Zellen untersucht, und elastische Eigenschaften wurden mit rheologischen RKM-Messungen bestimmt. Traktionskraftmessungen an elastischen Substraten runden das umfassende Bild ab. Durch Veränderung der molekularen Strukturen mit verschiedenen Chemikalien, die unterschiedliche Prozesse im Gesamtsystem stören, konnte nun ein Phasenraum der Kraftgenerierungsprozesse untersucht und unterschiedliche Effekte verschiedenen Prozessen eindeutig zugeordnet werden. Es wurde somit erstmalig experimentell bewiesen, dass die Polymerisation von Aktin die treibende Kraft am vorderen Rand der Zelle ist. Darüber hinaus wurde das Verhalten des Kraftaufbaus mit einem Model beschrieben, das Aufschluss über die Funktionsweise der darunterliegenden Aktinpolymerstrukturens gibt. Desweiteren wurde in der Mitte der Zelle, zwischen vorderem Rand und Zellkörper, erstmalig eine rückwärtsgerichtete Kraft gemessen, die wichtig ist um ein Kräftegleichgewicht zu erstellen. Ein Model das auf entropischen Kräften im Polymersystem basiert, beschreibt diese kontraktilen Kräfte und ordnet sie der Depolymerisation von Aktin zu. Die Bewegung des Zellkörpers wiederum basiert auf dem Zusammenspiel dieser beiden Mechanismen, sowie der Kontraktion von Aktin und Aktinbündeln durch molekulare Motoren. Eine umfassendes Charakterisierung über verschiedene lokale Mechanismen und ihrer Wechselwirkungen konnte somit erstellt werden, und damit das Verständnis der Kraftgenerierung zur Zellbewegung vertieft. Zellbewegung Rasterkraftmikroskop Zellbewegungskräfte cell motility scanning force microscope force measurements ddc:530
350	Plasma membrane order; the role of cholesterol and links to actin filaments : Dinic, Jelena January 2011 (has links) The connection between T cell activation, plasma membrane order and actin filament dynamics was the main focus of this study. Laurdan and di-4-ANEPPDHQ, membrane order sensing probes, were shown to report only on lipid packing rather than being influenced by the presence of membrane-inserted peptides justifying their use in membrane order studies. These dyes were used to follow plasma membrane order in live cells at 37°C. Disrupting actin filaments had a disordering effect while stabilizing actin filaments had an ordering effect on the plasma membrane, indicating there is a basal level of ordered domains in resting cells. Lowering PI(4,5)P2 levels decreased the proportion of ordered domains strongly suggesting that the connection of actin filaments to the plasma membrane is responsible for the maintaining the level of ordered membrane domains. Membrane blebs, which are detached from the underlying actin filaments, contained a low fraction of ordered domains. Aggregation of membrane components resulted in a higher proportion of ordered plasma membrane domains and an increase in cell peripheral actin polymerization. This strongly suggests that the attachment of actin filaments to the plasma membrane induces the formation of ordered domains. Limited cholesterol depletion with methyl-beta-cyclodextrin triggered peripheral actin polymerization. Cholesterol depleted cells showed an increase in plasma membrane order as a result of actin filament accumulation underneath the membrane. Moderate cholesterol depletion also induced membrane domain aggregation and activation of T cell signaling events. The T cell receptor (TCR) aggregation caused redistribution of domains resulting in TCR patches of higher order and the bulk membrane correspondingly depleted of ordered domains. This suggests the preexistence of small ordered membrane domains in resting T cells that aggregate upon cell activation. Increased actin polymerization at the TCR aggregation sites showed that actin polymerization is strongly correlated with the changes in the distribution of ordered domains. The distribution of the TCR in resting cells and its colocalization with actin filaments is cell cycle dependent. We conclude that actin filament attachment to the plasma membrane, which is regulated via PI(4,5)P2, plays a crucial role in the formation of ordered domains. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Submitted. Paper 4: Manuscript. Membrane Organization Lipid rafts Actin Laurdan di-4-ANEPPDHQ Cholesterol T cell signaling Colocalization Generalized Polarization

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