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Cell locomotion

Actin filaments are dynamic polymers whose assembly and disassembly in the cell cytoplasm drives shape changes (Small, 1989), cell locomotion (Theriot et al, 1992), and chemotactic migration (Theriot et al., 1992)Devreotes and... [Pg.46]

Cells make use of many different types of membranes. All cells have a cytoplasmic membrane, or plasma membrane, that functions (in part) to separate the cytoplasm from the surroundings. In the early days of biochemistry, the plasma membrane was not accorded many functions other than this one of partition. We now know that the plasma membrane is also responsible for (1) the exclusion of certain toxic ions and molecules from the cell, (2) the accumulation of cell nutrients, and (3) energy transduction. It functions in (4) cell locomotion, (5) reproduction, (6) signal transduction processes, and (7) interactions with molecules or other cells in the vicinity. [Pg.260]

Microtubules are universally present in eukaryotes from protozoa to the cells of higher animals and plants (Porter, 1966 Hardham and Gunning, 1978 Lloyd, 1987), but they are absent in mammalian erythrocytes and in prokaryotes. Microtubules participate in a number of cellular functions including the maintenance of cell shape and polarity, mitosis, cytokinesis, the positioning of organelles, intracellular transport to specific domains, axoplasmic transport, and cell locomotion. The diversity of microtubule fimctions suggests that not all microtubules are identical and that different classes of microtubules are present in different cell types or are localized in distinct domains in the same cell type (Ginzburg et al., 1989). [Pg.4]

Tubulins arose very early during the course of evolution of unicellular eukaryotes and provide the machinery for the equipartitioning of chromosomes in mitosis, cell locomotion, and the maintenance of cell shape. The primordial genes that coded for tubulins likely were few in number. As metazoan evolution progressed, natural selection processes conserved multiple and mutant tubulin genes in response to the requirements for differentiated cell types (Sullivan, 1988). [Pg.4]

The Locomotion of Amoeba The Locomotion of Fibroblastic Cell Types The Locomotion of Leukocytes The Behavior of Locomoting Cells The Role of the Cytoskeleton in Cell Locomotion The Microtubule-Based Cytoskeleton The Intermediate Filament-Based Cytoskeleton The Microfilament-Based Cytoskeleton The Organization of Microfilaments in Cells Microfilament Dynamics and Cell Locomotion Sites of Lamellar Protrusion May Be Determined by the Nucleation of Actin Polymerization... [Pg.77]

Listeria, an Unlikely Key to Understanding Cellular Actin Nucleation and Possibly Cell Locomotion ... [Pg.77]

The Role of Myosins in Cell Locomotion The Role of Actin-Binding Proteins in Cell Locomotion The Transduction of Extracellular Motility Signals to the Cytoskeleton Lipid Flow and Cell Locomotion The Role of Cell Locomotion in Metastasis Intracellular Motility Microtubule-Based Intracellular Motility... [Pg.77]

Protein Cell Type/Organism Expression Level Effect on Cell Locomotion Reference... [Pg.94]

There is a substantial weight of evidence for the cytoskeleton being responsible for the force production and control of cell locomotion. This view has not yet been accepted unanimously. However, an alternative hypothesis continues to be argued which states that membrane cycling is the motive force driving cell locomotion (Bretscher, 1987). One of the predictions of the membrane flow hypothesis is that there should be a discernible flow of lipid from the front to the rear of the cell. Lipid flow has proven very difficult to study, because of the lack of suitable methods to label single lipid molecules and the heterogenous behavior of membrane-associated proteins. The observation that particles were transported rearward when they bound... [Pg.95]

Grimstad, l.A. (1987). Direct evidence that cell locomotion contributes importantly to invasion. Expt. Cell Res. 173,515-523. [Pg.103]

Heath, J.P., Holifield, B.F. (1991). Cell locomotion New research tests old ideas on membrane and cytoskeletal flow. Cell Mot. Cytoskel. 18, 245-257. [Pg.103]

Sinard, J.H., Pollard, T.D. (1989). Microinjection into Acanthamoeba castellanii of monoclonal antibodies to mysoin II slows but does not stop cell locomotion. Cell Mot. Cytoskel. 12,42-52. [Pg.105]

Zigmond, S.H. (1993). Recent quantitative studies of actin filament turnover during cell locomotion. Cell Mot. Cytoskel. 25,309-316. [Pg.106]

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See also in sourсe #XX -- [ Pg.79 , Pg.80 , Pg.81 , Pg.82 , Pg.83 , Pg.84 ]

See also in sourсe #XX -- [ Pg.319 ]



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Cell locomotion actin polymerization/depolymerization

Cell locomotion cytoskeleton, role

Cell locomotion myosins

Cell locomotion types

Locomotion

Locomotion of cells

Locomotives

Microfilaments cell locomotion

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