The shape of cells during interphase in sparse cultures often resembles that of fried eggs. XTH-2 cells, which have been derived from tadpole heart endothelia, provide a typical example of this type of shape. To understand the physical basis of this shape, the cytoskeleton of these cells has been investigated in detail. Subcellular elasticity data have been achieved by scanning acoustic microscopy (SAM). Their changes were observed during treatment of the cells with microtubule-disrupting agents (colcemid and low temperature), and shape generation in giant cells produced by electro-fusion was observed with SAM, revealing the role of the nucleus as a force centering organelle. From these observations combined with well-documented observations on cellular dynamics described in the literature, a model is developed explaining the fried-egg shape of cells by means of interacting forces and fluxes (cortical flow, bulk flow of cytoplasm, microtubule-mediated transport of cytoplasm) of cytoplasm. The model also allows the comprehension of the increase of tension in cells treated with colcemid.
Keratocytes derived from the epidermis of aquatic vertebrates are now widely used for investigation of the mechanism of cell locomotion. One of the main topics under discussion is the question of driving force development and concomitantly subcellular force distribution. Do cells move by actin polymerization-driven extension of the lamella, or is the lamella edge extended at regions of weakness by a flow of cytoplasm generated by hydrostatic pressure? Thus, elasticity changes were followed and the stiffness of the leading front of the lamella was manipulated by local application of phalloidin and cytochalasin D (CD). In scanning acoustic microscopy (SAM), elasticity is revealed from the propagation velocity of longitudinal sound waves (1 GHz). The lateral resolution of SAM is in the micrometer range. Using this method, subcellular tension fields with different stiffnesses (elasticity) can be determined. A typical pattern of subcellular stiffness distribution is related to the direction of migration. Cells forced to change their direction of movement by exposure to DC electric fields of varying polarity alter their pattern of subcellular stiffness in relationship to the new direction. The cells spread into the direction of low stiffness and retract at zones of high stiffness. The pattern of subcellular stiffness distribution reveals force distribution in migrating cells; i.e., if a cell moves exactly in a direction perpendicular to its long axis, then the contractile forces are largest along the long axis and decrease toward the short axis. Locomotion in any angle oblique to this axis requires an asymmetric stiffness distribution. Inhibition of actomyosin contractions by La3+ (2 mM), which inhibits Ca2+ influx, reduces cytoplasmic stiffness accompanied by an immediate cessation of locomotion and a change of cell shape. Local release of CD in front of a progressing lamella activates a cell to follow the CD gradient: The lamella thickens locally and is extended toward the tip of the microcapillary. Release of phalloidin stops extension of the lamella, and the cell turns away from the releasing microcapillary. The response to CD is assumed to be the result of local weakening of the cytoplasm due to severing of the actin fibrils. Phalloidin is supposed to stabilize the leading front by inhibition of F-actin depolymerization. These observations are in favor of the assumption that migration is due to an extension of the cell into the direction of minimum stiffness, and they are consistent with the hypothesis that local release of hydrostatic pressure provides the driving force for the flux of cytoplasm.
The scanning acoustic microscope (SAM) allows one to measure mechanical parameters of living cells with high lateral resolution. By analyzing single acoustic images' sound attenuation and sound velocity, the latter corresponding to stiffness (elasticity) of the cortical cytoplasm can be determined. In this study, measurements of stiffness distribution in XTH-2 cells were compared with the organization of F-actin and microtubules. Single XTH-2 cells exhibit relatively high stiffness at the free margins; toward the cell center this value decreases and reaches a sudden minimum where the slope of the surface topography enlargens at the margin of the dome-shaped cell center. The steepness of the increase in slope is linearly related to the decrease in sound velocity at this site. Thus, a significant determinant of cell shape is paralleled by an alteration of stiffness. In the most central parts, no interferences could be distinguished, therefore, this region had to be excluded from the calculations. Stiffness distribution roughly coincided with the distribution of F-actin, but no correlation to microtubule arrangement was found. Following the treatment of XTH-2 cells with ionomycin in the presence of calcium (in the culture medium), the cell cortex first contracted as indicated by shape changes and by a marked increase in stiffness (deduced from sound velocity). This contraction phase was followed by a phase of microtubule and F-actin disassembly. Concomittantly, sound velocity decreased considerably, indicating the loss of elasticity in the cell cortex. No structural equivalent to sound attenuation has been identified.
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