Microfilament Bundles In Cells Research Articles

Ultraviolet light-irradiated collagen III modulates expression of cytoskeletal and surface adhesion molecules in rat aortic smooth muscle cells in vitro.

Systemic and pulmonary hypertension is characterised by structural reconstruction of the vascular wall which includes hypertrophy and hyperplasia of vascular smooth muscle cells (VSMCs) and fibroproduction. We hypothesise that these changes are stimulated by non-enzymatic modification of collagen molecules in the injured vascular wall by radicals. We exposed collagen III to ultraviolet (UV) light irradiation which, as indicated by fluorescence and electrophoretic analyses, resulted in its fragmentation. Both irradiated and control unmodified collagen were adsorbed on culture dishes and seeded with VSMCs derived from the rat thoracic aorta. During the first week after seeding, the cells on the modified collagen attained significantly higher population density (by 15-83%), higher mitotic index (by 31-135%) and higher BrdU labelling index (by 32%). However, these cells were less resistant to spontaneous and trypsin-mediated detachment from the growth support. As revealed using enzyme-linked immunosorbent assay in 3-day-old cultures, the cells growing on the irradiated collagen exhibited a lower concentration of beta-1 integrins (-10%, measured per milligram of protein), vinculin (-18%), talin (-6%) and vimentin (-15%). Immunofluorescence staining showed that these molecules were distributed more diffusely and less organised into focal adhesion plaques or cytoskeletal fibres. The concentration of two adhesion molecules of immunoglobulin type, ICAM-1 and VCAM-1, was increased by 11% and 16%, respectively. The concentration of alpha-v integrins and alpha-actin was unchanged; the latter, however, formed fewer distinct microfilament bundles in cells on the modified collagen. Our results suggest that the VSMCs growing on UV-modified collagen are more prone to escape the growth control mediated by cell-extracellular matrix contact and can bind the cells of the immune system.

The distribution of microfilament bundles in rabbit endothelial cells in the intact aorta and during wound healing in situ.

The distribution of microfilament (MF) bundles in rabbit thoracic aortic endothelial cells (EC) fixed in situ was examined using en face preparations and the fluorescent probe 7-nitrobenz-2-oxa-1,3-diazole-phallacidin. In the normal aorta, prominent peripheral MF bundles are seen near the cell borders running the full length of each cell, parallel to the direction of blood flow, while shorter less prominent bundles are seen in the more central regions. In EC covering the flow dividers at intercostal ostia, the central MF bundles are more prominent, longer, and more numerous than in the other regions of the aorta examined. This increase in the number, size, and length of central MF bundles may result from the response of the cells to the higher shear forces present in this region of the vessel wall. Following denudation of the endothelium from a segment of the aorta with a balloon catheter, there is an initial reduction in the size of all of the MF bundles in cells near the wound edge. This is followed by an increase in the number and size of the central MF bundles. At 48 h after wounding, strongly stained central MF bundles could be detected in EC up to 0.75 mm from the wound edge. Adjacent to the wounds that had failed to reendothelialize 10 months after denudation, some regions had EC with prominent peripheral MF bundles and others, EC with prominent central MF bundles. At the very edge of the wound, the EC and their MF bundles were oriented with their long axes parallel to the wound edge and perpendicular to the direction of blood flow. The failure of the wounded vessel wall to become fully reendothelialized may be related to the orientation of EC at the wound edge. These results show that EC migration in situ is accompanied by a dramatic change in the organization of MF in which different stages can be identified. Microfilament bundles in rapidly migrating cells in vivo, 24 and 48 h after wounding, resemble stress fibers seen in EC migrating in vitro and in slowly migrating fibroblasts and epithelial cells.

Visualization of the same PtK2 cytoskeletons by both immunofluorescence and low power electron microscopy

A procedure is described which allows the examination of the cytoskeleton of a single PtK2 cell first by immunofluorescence and then by electron microscopy after staining with uranyl acetate. The immunofluorescent patterns of these detergent resistant cytoskeletons elicited with various monospecific antibodies closely resemble the patterns found in whole cells. Comparison of the immunofluorescence and electron micrographs directly supports the previous assignments of actin, myosin, filamin, α-actinin and tropomyosin as proteins associated with microfilament bundles in non-muscle cells. Actin is also found associated with a fine lattice-like structure present both in the ruffles and lying above the microfilament bundles in the cell body. The tonofilament bundles present in PtK2 cytoskeletons are not decorated by antibodies directed against the proteins associated with microfilament bundles. Antibodies directed against tonofilaments decorate specifically this system and not the microfilament bundles.

Microfilament bundles and cell shape are related to adhesiveness to substratum and are dissociable from growth control in cultured fibroblasts

The distribution of microfilament bundles in cells was examined using antibodies to fibroblast myosin and indirect immunofluorescence microscopy. There is no correlation between the presence of bundles of microfilaments and normal growth control. A normal cell line (Balb/c 3T3) cultured on a poorly adhesive substratum showed no microfilament bundles. Similarly, a mutant cell line (AD6) with normal growth, but a rounded shape due to defective adhesiveness to substratum, showed no bundle formation. On the other hand, two transformed cell lines with a flat morphology (Swiss SV3T3 and Balb MSV-85) showed extensive bundle formation. When a transformed cell line with poor adhesiveness (MC5-5) was treated with CSP (a major surface glycoprotein of normal cells) which increases adhesiveness to substratum, the cells formed extensive microfilament bundles without any decrease in growth. We conclude that the distribution of microfilament bundles is related to adhesiveness to substratum and cell shape but not to growth properties.