Relationship between intermediate filaments and microfilaments in cultured fibroblasts: evidence for common foci during cell spreading

Spreading and fully spread chick embryo fibroblasts (CEF) were examined by double-label fluorescence microscopy using the actin-specific probe rhodamine-phalloidin and an antibody directed against CEF intermediate filaments (IF). During midspreading, a striking relationship became discernible: statistical analysis showed that approximately half of the cell population exhibited one or more phase-dense, phalloidin-binding nodules that appeared to act as foci from which IF diverged. Coincidence between actin-containing structures and IF was not limited to these centers; IF could also frequently be seen running in close parallel arrays with stress fibers. Ultrastructural analysis confirmed the presence of non-membrane-bound out-pocketings along the length of stress fibers from which 10-nm IF diverged. These structures varied in size and shape, and displayed a dense, fine fibrillar appearance. IF and microfilaments (MF) were distinguished by size and by decoration of MF with myosin subfragment-1. Other IF-MF interactions were seen in cells of all stages: IF were observed to loop through stress fibers, most frequently at the cell margins. In colchicine-treated cells, IF became redistributed into cables that often ran parallel and appeared to merge with stress fibers. Cytochalasin D-treated CEF exhibited loose aggregates of actin-containing material that appeared to be associated with IF. These results suggest the possibility of an interaction between actin-containing structures and IF, particularly during cell spreading in cultured fibroblasts.     

The arrangement of microfilaments and microtubules in the periphery of spreading fibroblasts and glial cells

Studies of spreading fibroblasts and glial cells showed that the initial phase of the spreading process on a solid substratum proceeds by sequential development of different kinds of protrusions. Initially there is a high blebbing activity which is followed by development of small lamellipodia and somewhat later microspikes are formed. In the periphery of the spreading cells several types of microfilament organizations are displayed, these seem to be related to different stages in the cycles of extensions and retractions performed by the lamellipodia. The presence of microtubules and their relation to the different microfilament organizations are also shown.     

Circular distribution of microfilaments in cells spreading in vitro

In the peripheral cytoplasm of spreading epithelial cells (JTC-12), circular bundles of microfilaments appear running in parallel to the cell outline at the level of the cell-substratum contact.     

The fibronexus: a transmembrane association of fibronectin-containing fibers and bundles of 5 nm microfilaments in hamster and human fibroblasts.

A possible connection between external fibronectin-containing fibers and cytoplasmic 5 nm actin microfilaments within dense submembranous plaques has been observed by transmission electron microscopy. We refer to this transmembranous association as the fibronexus. Hamster embryo fibroblasts, transformed by wild-type or temperature-sensitive mutant (A28) SV40 virus, and human lung fibroblasts (WI-38, MRC-5) were studied using the tannic acid method of Simionescu and Simionescu (1976), which preferentially stained external carbohydrates. Fibronectin antigens were also localized on the extracellular fibers of the fibronexus with fibronectin antibody and immunoferritin staining. Goniometric studies of sections cut parallel to the plasmalemma demonstrated that the actin- and fibronectin-containing fibers of the fibronexus remained colinear when the specimen was tilted through a 40 degree angle about the fibrillar long axis. Sections cut perpendicular to the cell surface also showed that these fibers were apparently colinear. Our results suggest that the fibronectin and actin fibers of the fibronexus are closely associated (maximum separation distances of 8--22 nm), if not co-axial. Fibronexuses remained after expression of SV40-induced transformation, despite alteration of microfilament bundles and reduction in the amount of fibronectin (observed by immunofluorescence microscopy). The possible roles of fibronectin and the fibronexus in regulating actin polymerization are discussed.     

The role of microfilaments in the spreading process of JTC-12 cells

In 5 μg/ml cytochalasin B (CB), spreading of JTC-12 cells over the substratum occurred to some extent, but an almost complete inhibition was seen in 10 μg/ml CB, except for extrusion of thin processes. Formation of microfilament bundles beneath the adhesive surface was correlated with the grade of spreading. Treatment of spreading cells with 10 μg/ml CB caused a retraction of the peripheral cytoplasm or inhibited further spreading and concurrently disintegrated the microfilament bundles. Thus, the circular bundles of the microfilaments inside the cell outline probably enable the concentrical spreading of JTC-12 cells by advancing and consolidating the peripheral cytoplasm.     

Changes in the mechanical properties of fibroblasts during spreading: a micromanipulation study

Cell morphology is controlled in part by physical forces. If the main mechanical properties of cells have been identified and quantitated, the question remains of how the cell structure specifically contributes to these properties. In this context, we addressed the issue of whether cell rheology was altered during cell spreading, taken as a fundamental morphological change. On the experimental side, we used a novel dual micromanipulation system. Individual chick fibroblasts were allowed to spread for varying amounts of time on glass microplates, then their free extremity was aspirated into a micropipet at given pressure levels. Control experiments were also done on suspended cells. On the theoretical side, the cell was modeled as a fluid drop of viscosity μ, bounded by a contractile cortex whose tension above a resting value was taken to be linearly dependent on surface area expansion. The pipet negative pressure was first adjusted to an equilibrium value, corresponding to formation of a static hemispherical cap into the pipet. This allowed computation, through Laplace's law, of the resting tension (τ ₀), on the order of 3×10^–4 N/m. No difference in τ ₀ was found between the different groups of cells studied (suspended, adherent for 5 min, spread for 0.5 h, and spread for 3 h). However, τ ₀ was significantly decreased upon treatment of fibroblasts with inhibitors of actin polymerization or myosin function. Then, the pressure was set at 30 mmH₂O above the equilibrium pressure. All cells showed a biphasic behavior: (1) a rapid initial entrance corresponding to an increase in surface area, which was used to extract an area expansion elastic modulus (K), in the range of 10^–2 N/m; this coefficient was found to increase up to 40% with cell spreading; (2) a more progressive penetration into the pipet, linear with time; this phase, attributed to viscous behavior of the cytoplasm, was used to compute the apparent viscosity (μ, in the range of 2–5×10⁴ Pa s) which was found to increase by as much as twofold with cell spreading. In some experiments the basal force at the cell-microplate interface was quantitated with flexible microplates and found to be around 1 nN, in agreement with values calculated from the model. Taken together, our results indicate a stiffening of fibroblasts upon spreading, possibly correlated with structural organization of the cytoskeleton during this process. This study may help understand better the morphology of fibroblasts and their mechanical role in connective tissue integrity. Received: 22 June 1998 / Revised version: 14 October 1998 / Accepted: 15 October 1998     

Effect of colcemid on the spreading of fibroblasts in culture

The effect of colcemid upon the spreading of mouse embryo fibroblast-like cells on substrates was studied with the aid of time-lapse microcinematography and scanning electron microscopy. Two types of substrates were used: flat glass and narrow strips of glass surrounded by non-adhesive lipid film; on the latter, spreading and polarization of cells proceeded simultaneously. On glass, colcemid did not prevent transition of cells into a well-attached state; however, the time required for this transition increased considerably as compared with control cultures. Similar effects were caused by two other drugs inhibiting the formation of microtubules: colchicine and vinblastine. The intermediate stages of spreading on flat glass had several abnormal features in the colcemid-containing medium: (a) the shape of cytoplasmatic outgrowths formed by the cell was altered and their distribution became less regular; (b) partial detachment of the attached parts of the cells was very frequent; (c) the spreading of various parts of the cell was not well correlated: the central part of the cell could remain unspread long after the spreading of the peripheral part. Similar effects of colcemid were observed in experiments with cells spreading on the narrow strips of the glass. In addition, colcemid prevented stabilization of the cell surface, i.e., differentiation of the cellular edge into active and stable parts. About two-thirds of the cells attached to the narrow strips of glass were completely detached from the substrate in the course of spreading in colcemid-containing medium. The possible mechanisms of the action of colcemid on spreading are discussed and it is suggested that intracellular structures sensitive to colcemid are essential for the coordination of the reactions in various parts of the cell in the course of spreading.     

Evaluation of L-929 postmitotic daughter cell spreading during their migration on a substrate

Spreading of postmitotic daughter cells was examined using time-lapse microscopy. The work was performed on unsynchronized cells of a permanent L-929 cell line. The study aimed at formalizing the comparison of the moving cell area and estimating whether the area of migrating cells was changed randomly or nonrandomly. Two new parameters are proposed for comparison of cell morphology: the identity indicator and the synchronism indicator. To calculate these parameters, time-dependent changes of the area in cell pairs were measured. The first indicator shows the degree of coincidence between the absolute area values in the cell pairs, whereas the second indicator shows synchronism in the changes of cell areas and does not depend on their absolute values. The low indicators were a high similarity in the time-dependent changes of the cell area. The indicators were shown to be approximately 1.5-fold lower for the pairs of the postmitotic daughter cells than those for any other pair of the cells. The results point to a nonrandom character of the changes of cultured cell morphology.     

Effect of colcemid on the radial spreading of fibroblasts in culture

Effect of colcemide upon the spreading of mouse embryo fibroblast-like cells on the substrate was studied with the aid of time-lapse microcinematography and scanning electron microscopy. On the glass, colcemide did not prevent the transition of cells into a well-attached state, however, the time needed for this transition was seen considerably increased as compared with the control cultures. Intermediate stages of spreading on flat glass had the following abnormal features in colcemide-containing medium: a) shapes of cytoplasmic outgrowths formed by the cell were altered and their distribution along the cell border appeared less regular; b) partial detachments of the attached parts of cells occurred very frequently; c) the spreading of various parts of the cells was not correlated. Possible mechanisms of colcemide action on the cell spreading are discussed, and it is suggested that intracellular structures sensitive to colcemide are essential for coordination of reactions that occur in various parts of the cell in the course of spreading.     

Reorganization of actin filament bundles in living fibroblasts

We investigated how actin bundles assemble, disassemble, and reorganize during cell movement. Living chick embryonic fibroblasts were microinjected with actin molecules that had been fluorescently labeled with tetramethylrhodamine. We found that the fluorescent analogue of actin can be used successfully by both existing and newly formed cellular structures. Using time-lapse photography coupled to image- intensified fluorescence microscopy, we were able to detect various patterns of reorganization in motile cells. Assembly of stress fibers occurred near both the leading and the trailing ends of the cell. The initial structure appeared as discrete spots that subsequently extended into stress fibers. The extension occurred unidirectionally. The site of initiation near the leading edge remained stationary relative to the substrate during subsequent cell advancement. However, the orientation of the fiber could change according to the direction of cell movement. In addition, existing stress fibers could merge or fragment. The shortening of stress fibers can occur from either end of the fiber. Shortening from the proximal end (centrifugal shortening) was accompanied by a decrease in fluorescence intensity, as if the bundle were disassembling, and usually led to the total disappearance of the bundle. Shortening from the distal end (centripetal shortening), on the other hand, is usually accompanied by an increase in fluorescence intensity at the distal end of the bundle, as if this end had pulled loose from its attachment and retracted toward the center of the cell. Besides stress fibers, arc-like actin bundles have also been detected in spreading cells. These observations can explain how the organization of actin bundles coordinates with cell movement, and how stress fibers reach a highly regular pattern in static cells.     

Formation of an actin cytoskeleton and adhesive structures during the spreading of cultured cells

Fibroblast spreading was studied using immunofluorescent method that provided visualization of actin structures and adhesion contacts in the same cell. Four stages of actin system formation were observed. 1. Actin concentration in ruffles at the cell periphery. Formation of numerous dot-like contacts along the whole perimeter of the cell. 2. Formation of a circumferential actin bundle. Focal contacts are located at the outer edge of the bundle. 3. Gradual transformation of the circumferential bundle into actin network with triangular meshes. Peripheral (rather than internal) filaments of the network are associated with the focal contacts. 4. Appearance of the system of long straight actin bundles (stress fibers) associated with dash-like focal contacts. The stress fibers are supposed to arise from the triangular actin network which in its turn arises from the circumferential bundle. It is suggested that the formation of actin cytoskeleton is a process driven by the development of tensions in actin structures attached to the focal contacts at the cell periphery.     

Cell spreading on laminin substrate involves Con A-binding proteins

Concanavalin A (Con A), a tetravalent lectin, was shown to impair 8 chick embryo fibroblast (8 d CEF) spreading on a laminin (LM) substrate but not on a fibronectin substrate (FN), suggesting that cell surface Con A binding proteins could be involved in 8 d CEF spreading on a LM substrate. The interaction of Con A-binding proteins with Con A is dependent upon the carbohydrate moieties of the isolated glycoproteins; since they interact strongly with Con A-Sepharose and are eluted with 0.3 Mol/l alpha-methylmannopyranoside, the isolated Con A binding-proteins inhibit 8 d CEF adhesion to a Con A substrate to the same extent as alpha-methylmannopyranoside. Furthermore, the isolated Con A binding proteins specifically inhibit in a dose-dependent manner 8 d CEF spreading on LM but not on FN.     

Early events during substrate adhesion of normal and virus-transformed mouse fibroblasts.

The relationship between attachment of Balb/c3T3 cells and their SV40 transformants to glass or plastic substrates and deposition of substrate-attached material (SAM-proteoglycans implicated in substrate adhesion) has been examined very early after inoculation of cells subcultured with ethylenebis (oxyethylenenitrilo) tetra-acetic acid (EGTA). The metabolic inhibitors cycloheximide and colchicine minimally affected the kinetics or short-term stability of attachment of cells or deposition of SAM. SAM deposition on to the substrate began immediately after inoculation of cells and was maximal prior to the highest cell attachment level (30-40 min after inoculation). At 4 degrees C, there was no attachment of cells to the substrate and no deposition of leucine- or glucosamine-radiolabelled SAM on to the substrate. 3T3 cells deposited SAM to a maximal level earlier during the attachment process than SV40-transformed cells. SVT2 cells deposited much smaller amounts of SAM (measured on a per-cell basis) to 3T3 SAM-coated substrates during attachment processes, whereas 3T3 cells and concanavalin A (con A) revertant variants of SVT2 cells, which have regained density-dependent inhibition of growth, deposited identical amounts of SAM (per-cell) on untreated or SAM-coated substrates. Serial attachment experiments with SVT2 cells indicated that all SVT2 cells reduced their deposition amounts on SAM-coated substrates, rather than there being an ability of a small proportion of cells to attach preferentially to SAM-coated substrates while being unable to deposit SAM themselves. The data are consistent with the presence of a sizeable pool of SAM-like proteoglycans being present on the surface of EGTA-removed cells whose deposition may be a requirement for, but may not necessarily be sufficient for, stable adhesion of cells to the substrate.     

Spreading of mouse fibroblasts on the substrate with multiple spikes

Mouse embryo fibroblasts were cultivated on special substrates with discontinuous surfaces. The substrates were silicon plates with multiple vertical (65-90 microns height) spike-like silicon microcrystals evenly distributed on the plate surfaces. It was shown that the cells were successfully spread and flattened on these substrates. The spread cells formed several discrete attachment zones at the tops and side surfaces of the spikes; these zones were separated from one another by distances considerably greater than the diameter of the unspread cell. At early stages of spreading the unspread cells attached to the tops of single spikes and extended long filopodia attached to the distant spikes. At later stages the lamellae were formed between the filopodia: probably these filopodia served as guidelines for extension of lamellae and progressive cell spreading. These experiments demonstrated that continuity of substrate surface is not a necessary condition for advanced cell spreading.     

Molecular requirements for the adhesion and spreading of hamster fibroblasts

Hamster plasma fibronectin adsorbs rapidly to a plastic surface to form a monolayer that promotes attachment and spreading of baby hamster kidney (BHK) fibroblasts. Maximal spreading requires a minimum surface density of about 1.8 × 10¹⁰ fibronectin molecules/cm² indicating a maximum of 45 000 contacts between a well-spread cell and the adsorbed fibronectin lattice. Surfaces coated with other antibodies or lectins reactive with the BHK cell surface also promote rapid cell flattening.     

Long-term growth of chicken fibroblasts on a collagen substrate

In 3 separate experiments, cells derived from chick embryo muscle explants have been grown in either Waymouth's medium or Ling's (AN.54) medium with 20% human placental cord serum. Continuous transfer and new outgrowth from a succession of 2 × 2 mm fragments has continued for periods of 24 to 44 months. Continuous growth was achieved only on a collagen substrate, and no continuous growth was obtained when cells were transferred to glass. When incubator temperature was raised to 43 °C over a period of 1 month, new cell types developed and had the capacity to both survive and grow directly on glass for several months.