[Cytoskeletal changes in A-431 cells under the action of epidermal growth factor].
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By the use of rhodamine-phalloidin, the distribution of actin in A-431 cells during the action of epidermal growth factor (EGF) has been studied. Changes in the pattern of staining are observed in 30-60 s after addition of the EGF. Microvilli and wrinkles are created on the cell surface. Following a 5-10 min action of EGF, rhodamine-phalloidin stained intensely ruffles and cell borders. After 60 min, the ruffling of cell surface disappeared, and actin was seen concentrating on the cell borders only. Electron microscopy of the EGF-treated A-431 cells lysed by Triton X-100 also revealed some vigorous fibrillar bunches on the cell edges.Keywords:
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Abstract We compared, on lysed polymorphonuclear leukocytes (PMNs), the spatial distributions of sites that nucleate actin polymerization with the spatial distribution of endogenous F‐actin. Sites nucleating polymerization of exogenous actin were detected by incubating lysed cells with rhodamine‐labeled G‐actin under polymerizing conditions. Endogenous F‐actin was stabilized and stained by lysis of cells into fluorescein‐labeled (FITC) phalloidin. We found the distributions of rhodamine and fluorescein intensities in a given cell, resting or stimulated with chemoattractant, to be similar. Thus, after lysis the number of sites able to nucleate actin polymerization is proportional to the local F‐actin concentration. Quantitative fluorescence microscopic analysis also demonstrated that (1) if cells were stimulated with chemoattractant shortly before lysis, the total fluorescence per cell of both fluorophors went up; (2) if peptide was diluted shortly before lysis, the endogenous F‐actin in the lamellae was dramatically reduced, but nucleation sites persisted, giving a high rhodamine to fluorescein ratio; and (3) there was a small increase in the ratio of rhodamine (exogenously grown actin) to fluorescein (endogenous F‐actin) in a region near the lamellar/endoplasm border, centripetal to regions of the highest concentration of endogenous F‐actin. The rhodamine signal appeared to be due to in situ actin polymerization probably nucleated by existing free barbed ends, since (1) the rhodamine signal increased linearly with time with no detectable lag if the actin concentration was above that of the critical concentration of the barbed end; (2) the rhodamine signal was dramatically reduced if lysates were incubated with gelsolin–actin complex (which stably caps barbed ends), then washed before the rhodamine G‐actin was added; and (3) the number of nucleation sites at the time of lysis is similar to the number of the barbed ends of actin filaments determined by the kinetics of depolymerization [Cano et al., 1991]. The fact that the distribution of exogenous actin polymerization paralleled the endogenous F‐actin suggests that the number of free barbed ends per F‐actin is roughly constant. If all filament ends were free, or if a constant fraction of the filaments ends were free, these data would suggest that the mean filament length is roughly constant throughout the cell. © 1993 Wiley‐Liss, Inc.
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By the use of rhodamine-phalloidin, the distribution of actin in A-431 cells during the action of epidermal growth factor (EGF) has been studied. Changes in the pattern of staining are observed in 30-60 s after addition of the EGF. Microvilli and wrinkles are created on the cell surface. Following a 5-10 min action of EGF, rhodamine-phalloidin stained intensely ruffles and cell borders. After 60 min, the ruffling of cell surface disappeared, and actin was seen concentrating on the cell borders only. Electron microscopy of the EGF-treated A-431 cells lysed by Triton X-100 also revealed some vigorous fibrillar bunches on the cell edges.
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Abstract Background Maintaining proper adhesion between neighboring cells depends on the ability of cells to mechanically respond to tension at cell-cell junctions through the actin cytoskeleton. Thus, identifying the molecules involved in responding to cell tension would provide insight into the maintenance, regulation, and breakdown of cell-cell junctions during various biological processes. Vinculin, an actin-binding protein that associates with the cadherin complex, is recruited to cell-cell contacts under increased tension in a myosin II-dependent manner. However, the precise role of vinculin at force-bearing cell-cell junctions and how myosin II activity alters the recruitment of vinculin at quiescent cell-cell contacts have not been demonstrated. Results We generated vinculin knockdown cells using shRNA specific to vinculin and MDCK epithelial cells. These vinculin-deficient MDCK cells form smaller cell clusters in a suspension than wild-type cells. In wound healing assays, GFP-vinculin accumulated at cell-cell junctions along the wound edge while vinculin-deficient cells displayed a slower wound closure rate compared to vinculin-expressing cells. In the presence of blebbistatin (myosin II inhibitor), vinculin localization at quiescent cell-cell contacts was unaffected while in the presence of jasplakinolide (F-actin stabilizer), vinculin recruitment increased in mature MDCK cell monolayers. Conclusion These results demonstrate that vinculin plays an active role at adherens junctions under increased tension at cell-cell contacts where vinculin recruitment occurs in a myosin II activity-dependent manner, whereas vinculin recruitment to the quiescent cell-cell junctions depends on F-actin stabilization.
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ABSTRACT 7-Diethylamino-3-(4-isothiocyanotophenyl)-4-methylcoumarin (CPITC) was coupled to amino-methyldithiolanophalloidin to produce a new phalloidin derivative, coumarin–phalloidin, fluorescent in the blue region of the spectrum. Coumarin–phalloidin binds to actin with around 100-fold less affinity than unconjugated phalloidin, but with enough avidity to make it a useful stain for actin filaments. Appropriate filter combinations permit triple immunofluorescence microscopy of the cytoskeleton with fluorescein and rhodamine conjugates together with coumarin-phalloidin.
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Currently a central question that remains unresolved is the potential importance of phospholipase C (PLC)-gamma1 in cell mitogenesis. In this study, we introduced wild-type PLC-gamma1 plasmid and mutants Y771F and Y783F into CCL-39 fibroblasts and investigated their effect on host cell functions. To our surprise, Y771F and Y783F plasmids appeared to have opposite effects on CCL-39 cell actin-cytoskeleton organization and cell proliferation. Y771F transfectants increased cell proliferation by two-fold. Y783F transfectants showed much thicker actin filaments and decreased cell growth rate by 50%. These results suggest that PLC-gamma1 mutations have an essential impact on cell mitogenesis.
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Actin remodeling
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Treadmilling
Subtilisin
Actin-binding protein
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Cleavage (geology)
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Microtubules are long, proteinaceous filaments that perform structural functions in eukaryotic cells by defining cellular shape and serving as tracks for intracellular motor proteins. We report the first accurate measurements of the flexural rigidity of microtubules. By analyzing the thermally driven fluctuations in their shape, we estimated the mean flexural rigidity of taxol-stabilized microtubules to be 2.2 x 10(-23) Nm2 (with 6.4% uncertainty) for seven unlabeled microtubules and 2.1 x 10(-23) Nm2 (with 4.7% uncertainty) for eight rhodamine-labeled microtubules. These values are similar to earlier, less precise estimates of microtubule bending stiffness obtained by modeling flagellar motion. A similar analysis on seven rhodamine-phalloidin-labeled actin filaments gave a flexural rigidity of 7.3 x 10(-26) Nm2 (with 6% uncertainty), consistent with previously reported results. The flexural rigidity of these microtubules corresponds to a persistence length of 5,200 microns showing that a microtubule is rigid over cellular dimensions. By contrast, the persistence length of an actin filament is only approximately 17.7 microns, perhaps explaining why actin filaments within cells are usually cross-linked into bundles. The greater flexural rigidity of a microtubule compared to an actin filament mainly derives from the former's larger cross-section. If tubulin were homogeneous and isotropic, then the microtubule's Young's modulus would be approximately 1.2 GPa, similar to Plexiglas and rigid plastics. Microtubules are expected to be almost inextensible: the compliance of cells is due primarily to filament bending or sliding between filaments rather than the stretching of the filaments themselves.
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Persistence length
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Cytoplasmic streaming
Actina
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The eukaryotic cell has evolved to compartmentalize its functions and transport various metabolites among cellular compartments. Therefore, in cell biology, the study of organization and structure/function relationships is of great importance. The cytoskeleton is composed of a series of filamentous structures, including intermediate filaments, actin filaments, and microtubules. Immunofluorescent staining has been most frequently used to study cytoskeletal components. However, it is also possible to fluorescently label isolated cytoskeletal proteins and either microinject them back into the cell or add them to fixed, permeabilized cells. Alternatively, it is possible to use the mushroom-derived fluorescinated toxins, phalloidin or phallacidin, to label F-actin of the cytoskeleton, as is described in this article. Phalloidin is available labeled with different fluorophores. The choice of the specific fluorophore should depend on whether phalloidin labeling for actin is part of a double-label experiment. In most cells, the abundance of actin filaments should provide a very strong signal. In double-label experiments, the fluorophore should be chosen to take this into account. In general, rhodamine labels are more resistant to photobleaching and can be subjected to the longer exposures required for finer structures.
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