Number Of Stress Fibers Research Articles

Endocardial endothelium in the rat: cell shape and organization of the cytoskeleton

The cytoskeleton in endocardial endothelium of rat heart was examined by en face confocal scanning laser microscopy. In the ventricular cavity, endocardial endothelial cells had a polygonal shape and F-actin staining was generally restricted to the peripheral junctional actin band. Central F-actin bundles, or stress fibers, in endocardial endothelial cells were found on the tendon end of papillary muscles, especially in the right ventricle, and frequently in the outflow tract of both ventricles; elsewhere, stress fibers were scarce. Many endocardial endothelial cells were elongated in areas of endothelium with stress fibers, but no correlation was found between cell elongation and the number of stress fibers. An inverse correlation was found between the number of stress fibers and the surface area of endocardial endothelial cells. Shear stress as well as mechanical deformation of the surface of the ventricular wall during the cardiac cycle may affect cell shape and the organization of actin filaments in endocardial endothelial cells. Vimentin in endocardial endothelial cells formed a filamentous network with some distinct cytoplasmic and juxtanuclear vimentin bundles. No perinuclear ring of vimentin filaments was observed in endocardial endothelium. Microtubules in endocardial endothelial cells were, in contrast to endothelial cells of rat aorta, not aligned, less closely packed and originated from randomly distributed centriolar regions. The cytoskeleton has been suggested to play an important role in cellular functions of vascular endothelial cells. Accordingly, differences in the cytoskeletal organization between endocardial and vascular endothelial cells may relate to differences in functional properties.

Dynamics of shear-induced redistribution of F-actin in endothelial cells in vivo.

The steady-state responses of endothelial cell F-actin distribution to changes in in vivo shear stress have been well documented. The purpose of the current work was to define the dynamics of redistribution of F-actin in the period immediately after experimental changes in shear. We used abdominal aortic coarctation in rabbits to experimentally increase shear stress downstream from the coarctation by approximately twofold. In situ staining was employed to track subsequent F-actin redistribution. Within 12-15 hours, the number of stress fibers in the central regions of the cells decreased, and some separation of junctional actin in adjacent cells occurred. Long, central stress fibers of variable thickness were evident at 24 hours, but the band of actin normally seen at the periphery of the cells could no longer be distinguished. The redistribution of F-actin was completed over the next 24 hours by an increase in thickness of central stress fibers. Restoration of normal F-actin distribution after coarctations were removed proceeded more slowly. The long, thick stress fibers that were induced by high shear were replaced by thinner or shorter microfilament bundles 48 hours after the coarctations were removed. At 72 hours, central stress fibers were primarily long, thin structures. Peripheral F-actin was not fully restored at this time. Peripheral F-actin was restored at 1 week after removal of the coarctation, but there were still more and longer stress fibers at this time than were observed in control aortas.(ABSTRACT TRUNCATED AT 250 WORDS)

Scatter factor affects major changes in the cytoskeletal organization of epithelial cells

The effects of scatter factor on the cytoskeleton of MDCK and PtK2 cells are described. During the first 6 h after the addition of scatter factor, MDCK cells were found to increase their projected areas twofold, as well as the number and size of their F-actin stress fibers. In contrast PtK2 cells showed no change in their projected areas or in their stress fiber content. However, when both MDCK and PtK2 cells began to separate and scatter after approximately 6 h, the size and number of stress fibers was found to decrease considerably. Unscattered PtK2 cells and cells treated with scatter factor which had yet to scatter showed focal contacts present over the whole ventral surface, as judged by staining for both vinculin and talin. After treated cells separated, both vinculin and talin staining were mainly present in focal contacts on the ventral surfaces of the cell bodies and the distal ends of the processes. However, the cell processes showed few focal contacts along their lengths. The distribution of microtubules and vimentin and keratin intermediate filaments also did not change significantly until scattering had occurred. After cell separation, the processes were always packed with microtubules which were often, but not always, rich in detyrosinated α-tubulin and often, but not always, packed with intermediate filaments. All these changes in cytoskeletal organization are consistent with the adoption of a much more motile phenotype. The changes found are compared with those brought about by transformation.

Cadmium (Cd 2+) disrupts intercellular junctions and actin filaments in LLC-PK 1 cells

Studies reported in the literature suggest that cadmium (Cd 2+) may disrupt the junctions between cells in some tissues and cell culture systems. In order to examine this possibility in more detail, we have studied the effects of Cd 2+ on the integrity of intercellular junctions in the established porcine renal epithelial cell line, LLC-PK 1. Junctional integrity was assessed by monitoring the collapse of domes and by measuring changes in the transepithelial electrical resistance in confluent cell monolayers. Exposure to Cd 2+ caused a rapid decrease in transepithelial resistance and the concomitant collapse of domes. These effects occurred at Cd 2+ concentrations (20–60 μ m) and durations of exposure (as little as 1 hr) that did not alter levels of ATP or kill the cells. Electron microscopic studies showed that Cd 2+ caused time-dependent changes in adhering and occluding junctional complexes, which eventually resulted in the complete separation of the cells. Additional studies, in which rhodamine-coupled phalloidin was used to visualize F-actin, showed that Cd 2+ altered the structure of actin filaments in the cells; there was a significant reduction in the amount of junction-associated F-actin and in the number of stress fibers. These results indicate that Cd 2+ has relatively specific damaging effects on the adhering and occluding junctions between LLC-PK 1 cells and that these effects may involve the disruption of cytoskeletal actin filaments.

Protein kinase inhibitor prevents pulmonary edema in response to H2O2.

We investigated the effect of H2O2 (92 microM) in isolated guinea pig lungs perfused with a buffered Ringer solution. Pulmonary arterial pressure (Ppa), pulmonary capillary pressure (Ppc), and change in lung weight (delta W) were recorded at 0 min and at 15, 30, and 60 min after the H2O2. The capillary filtration coefficient (Kfc) was measured at 0 and 30 min. The perfusion of H2O2 increased the Ppa, Ppc, delta W, and Kfc. The thromboxane synthetase inhibitor Dazoxiben, or the vasodilator papaverine, prevented the increases in Ppa and Ppc. The protein kinase C (PKC) inhibitor H7 [1-(5-isoquinolinesulfonyl)-2-methylpiperazine dihydrochloride] prevented the increases in Ppa, Ppc, delta W, and Kfc, whereas the inactive isoquinoline HA1004 [N-(2-guanidinoethyl)-5-isoquinolinesulfonamide hydrochloride] had little effect on the H2O2 response. H2O2 increased the number of stress fibers and disrupted the peripheral band of cultured confluent endothelial cells, changes that were prevented with pretreatment with H7. PKC may mediate the increases in vascular permeability and pulmonary edema that occur in response to H2O2.

Butyrate effects on growth, morphology, and fibronectin production in PC‐3 prostatic carcinoma cells

Sodium butyrate (NaBT) induces differentiation in several transformed cell lines. The present paper describes the effects of NaBT on some transformation-associated parameters in PC-3, a human prostatic carcinoma cell line. NaBT produces a reversible inhibition of cell proliferation, but anchorage-independent growth is more sensitive than monolayer growth. Soft agarose colonies are reduced by over 50% at 0.1 mM, a concentration that hardly affects growth on solid substrata. Monolayer cells respond to NaBT by spreading and flattening, as demonstrated by a combined light and electron microscopic, morphometric technique. After 4 days' exposure to 2 mM NaBT, the average cell covers an area of substratum that is approximately double that covered by control cells. The average cell volume, however, remains unchanged. This flattening is paralleled by an increase in the number of stress fibers, as seen by fluorescence microscopy. Only minor changes are observed in the microtubule and intermediate filament patterns. While control cells contain very little antifibronectin reactive material, substantial amounts of such material appear upon NaBT treatment. The amount of fibronectin increases up to 100-fold in cells exposed to NaBT. The changes observed correspond to a suppression of properties that are generally associated with the malignant phenotype.

Heat shock gene expression and cytoskeletal alterations in mouse neuroblastoma cells

The cytoskeleton of neuroblastoma cells, clone Neuro 2A, is altered by two stress conditions: heat shock and arsenite treatment. Microtubules are reorganized, intermediate filaments are aggregated around the nucleus, and the number of stress fibers is reduced. Since both stress modalities induce similar cytoskeletal alterations, no thermic denaturation of one or more cytoskeletal components can be involved in this process. Heat shock proteins are induced both by heat and by arsenite. However, cells treated with arsenite synthesize hsp28 which is not detected in heat-treated cells. Synthesis of all hsps is prevented by addition of actinomycin D or cycloheximide. Under these conditions no alterations are observed in the organization of microtubules and intermediate filaments during heat or arsenite treatment. However, these drugs are not able to prevent the rapid loss of stress fibers. A re-formation of the cytoskeleton during the recovery period proceeds within 3 h and is also found to occur in the presence of a protein synthesis inhibitor. These data suggest that reorganization of microtubules and intermediate filaments during a stress treatment requires the synthesis of a new protein(s), probably hsp(s).

Extracellular matrix modulation of endothelial cell shape and motility following injury in vitro.

We utilized fluorescence microscopy and affinity-purified antibodies to probe the form and function of cytoplasmic actin in endothelial cells (EC) recovering from injury and grown on extracellular matrices in vitro. Bovine aortic EC were seeded onto glass microscope coverslips that had been coated with either BSA, fibronectin, type I and III (interstitial) collagens, type IV (basement membrane) collagen or gelatin. After EC that had been grown on glass, glass-BSA or extracellular matrix-coated coverslips reached confluence, a 300-400 micron zone of cells was mechanically removed to stimulate EC migration and proliferation. Post-injury EC movements were monitored with time-lapse, phase-contrast videomicrography before fixation for actin localization with fluorescence microscopy using affinity-purified antibodies. We found that the number of stress fibres within EC was inversely proportional to the rate of movement; and, the rates of movement for EC grown on glass or glass-BSA were approximately eight times faster than EC grown on gelatin or type IV collagen (X velocity = 0.5 micron/min versus 0.06 micron/min). EC movements on fibronectin and interstitial collagens were similar (X velocity = 0.2 micron/min). These results suggest that extracellular matrix molecules modulate EC stress fibre expression, thereby producing alterations in the cytoskeleton and the resultant EC movements that follow injury in vitro. Moreover, the induction of stress fibres in the presence of basement membrane (type IV) collagen may explain the failure of aortic EC to migrate and repopulate wounded regions of intima during atherogenesis in vivo.

Microtubules, microfilaments and adhesion patterns in differentiating chick retinal pigment epithelial (RPE) cells in vitro

The distribution of microtubules (MT), microfilaments (MF), and patterns of cell-to-substratum adhesion were studied by tubulin antibody labeling, NBD-phallacidin staining and by reflection interference contrast (RIC) microscopy respectively in colonies of differentiating RPE cells obtained from explants after 10 days in culture. In each colony three zones could be identified: a central zone of packed well-differentiated cuboidal cells (zone 1), an intermediate zone of more flattened, pleomorphic cells (zone 2) and a peripheral zone of very spread cells at the edge of the colony (zone 3). As visualized with antibodies to tubulin, the MT distribution in cells of each zone was distinctly different and correlated well with differences in cell shape. Changes in the distribution of MF were more striking. In the cuboidal well-differentiated cells of zone 1, prominent cortical bands but no stress fibers were observed after staining with NBD-phallacidin and RIC microscopy showed that the cells lacked strong adhesion to the substratum. Stress fibers, in addition to cortical bands of MF, were seen in the more spread, less differentiated cells of zone 2 and focal contacts were observed when these cells were examined by RIC microscopy. The flattened least differentiated cells in zone 3 lacked cortical bands but had prominent stress fibers. These cells displayed a variety of adhesion forms ranging from a mosaic of far and close contacts to numerous focal contacts and broad focal adhesions. Our results show that as the RPE cells display less differentiated morphologies, i.e. are more flattened and less densely packed towards the edge of the colony, there is a gradual decrease in the cortical bands of MF and an increase in the number and prominence of stress fibers. This increase in numbers of stress fibers is correlated with an increase in the cell adhesiveness to the substratum, as estimated by RIC microscopy. These results strongly support the general observation that normal epithelial cells in colonies tend to adhere to the substratum more strongly by marginal cells than by the more differentiated centrally located cuboidal cells which have well developed intercellular contacts.