Contribution of intermediate filaments to cell stiffness, stiffening, and growth

It has been shown previously thatintermediate filament (IF) gels in vitro exhibit stiffening athigh-applied stress, and it was suggested that this stiffening propertyof IFs might be important for maintaining cell integrity at largedeformations (Janmey PA, Evtenever V, Traub P, and Schliwa M, JCell Biol 113: 155-160, 1991). In this study, the contribution ofIFs to cell mechanical behavior was investigated by measuring cellstiffness in response to applied stress in adherent wild-type andvimentin-deficient fibroblasts using magnetic twisting cytometry. Itwas found that vimentin-deficient cells were less stiff andexhibited less stiffening than wild-type cells, except at the lowestapplied stress (10 dyn/cm²) where the difference in thestiffness was not significant. Similar results were obtained frommeasurements on wild-type fibroblasts and endothelial cells aftervimentin IFs were disrupted by acrylamide. If, however, cells wereplated over an extended period of time (16 h), they exhibited asignificantly greater stiffness before than after acrylamide, even atthe lowest applied stress. A possible reason could be that theinitially slack IFs became fully extended due to a high degree of cellspreading and thus contributed to the transmission of mechanical stressacross the cell. Taken together, these findings were consistent withthe notion that IFs play important roles in the mechanical propertiesof the cell during large deformation. The experimental data also showedthat depleting or disrupting IFs reduced, but did not entirely abolish,cell stiffening. This residual stiffening might be attributed to theeffect of geometrical realignment of cytoskeletal filaments in thedirection of applied load. It was also found that vimentin-deficientcells exhibited a slower rate of proliferation and DNA synthesis thanwild-type cells. This could be a direct consequence of the absence ofthe intracellular IFs that may be necessary for efficient mediation ofmechanical signals within the cell. Taken together, results of thisstudy suggest that IFs play important roles in the mechanical properties of cells and in cell growth.