Role of fibronectin in the organisation of the cytoskeleton during the spreading of rat mammary epithelial cells.

The correlation between the extracellular deposition of fibronectin and the development of the actin-containing cytoskeleton was studied during the attachment and spreading of the rat mammary epithelial cell line Rama 25. During the initial phase of cell spreading, actin is localised in peripheral microfilament bundles. As cell spreading increases, the peripheral ring is displaced towards the perinuclear region. Fibronectin, deposited beneath the basal surface, co-localises with the actin-containing peripheral ring. The peripheral ring subsequently disappears and is replaced by a system of radial microfilaments that extend from the perinuclear region to the cell periphery. At this stage, there is no correlation between the distribution of fibronectin and actin. As cells form colonies, radial microfilament bundles are replaced by peripheral microfilament bundles which do not co-localise with fibronectin. Cells at the edges of colonies extend lamellae that contain microfilament stress fibres. In these structures there is co-localisation of actin, fibronectin and the a5 beta 1-integrin fibronectin receptor.     

Monoclonal antibodies to epitopes shared by actin and vimentin obtained by paramyxovirus immunization

Three hybridoma clones producing IgM antibodies against actin were obtained from mice immunized with purified virions of paramyxoviruses. When tested on growing lung fibroblasts, ascites fluids of all clones stained in immunofluorescence cytoplasmic bundles of microfilaments, but also fibrillar networks. On colchicine-treated cells, perinuclear coils were seen in addition to microfilament bundles. In addition, one clone gave a pronounced speckled staining to the nuclei. Absorption of the ascites fluids with purified actin abolished all staining patterns. Using the Western blotting technique the antibodies reacted with both actin and vimentin polypeptides. DNase I abolished the staining of the actin filaments and of the nuclei, but left the vimentin pattern unimpaired. Thus, the monoclonal antibodies evidently reacted with epitopes common to actin and vimentin.     

Decreased biosynthesis of actin and cellular fibronectin during adipose conversion of 3T3-F442A cells. Reorganization of the cytoarchitecture and extracellular matrix fibronectin

Differentiation of 3T3-F442A cells was accompanied by changes in cell morphology, decreased synthesis and assembly of actin and fibronectin. The network of microfilament stress fibers detected with NBD-phallacidin was altered during adipose conversion of 3T3-F442A cells. Parallel to this, the disappearance of fibrillar bundles of extracellular matrix fibronectin was observed by immunofluorescence staining. The pericellular fibronectin content, detected by immunoblotting, strongly diminished during the differentiation process. An altered rate of biosynthesis of both proteins was also measured by [35S]-methionine pulse-labeling and immunoprecipitation. A 4-5-fold decrease in cellular fibronectin synthesis was observed in adipocytes compared to control preadipocytes. Conversely, non-differentiating 3T3-C2 control cells did not reorganize either the cytoskeletal architecture or the extracellular matrix fibronectin in the resting state. These results suggest that the decreased rate of biosynthesis of cell-associated fibronectin is correlated with that of actin. Moreover, both events can essentially be ascribed to differentiation.     

The reorganization of microfilaments, centrosomes, and microtubules during in vitro small wound reendothelialization

The repair of small endothelial wounds is an important process by which endothelial cells maintain endothelial integrity. An in vitro wound model system was used in which precise wounds were made in a confluent endothelial monolayer. The repair process was observed by time-lapse cinemicrophotography. Using fluorescence and immunofluorescence microscopy, the cellular morphological events were correlated with the localization and distribution of actin microfilament bundles and vinculin plaques, and centrosomes and their associated microtubules. Single to four-cell wounds underwent closure by cell spreading while wounds seven to nine cells in size closed by initially spreading which was then followed at approximately 1 h after wounding by cell migration. These two processes showed different cytoskeletal patterns. Cell spreading occurred independent of centrosome location. However, centrosome redistribution to the front of the cell occurred as the cells began to elongate and migrate. While the peripheral actin microfilament bundles (i.e., the dense peripheral band) remained intact during cell spreading, they broke down during migration and were associated with a reduction in peripheral vinculin plaque staining. Thus, the major events characterizing the closure of endothelial wounds were precise in nature, followed a specific sequence, and were associated with specific cytoskeletal patterns which most likely were important in maintaining directionality of migration and reducing the adhesion of the cells to their neighbors within the monolayer.     

Changes in expression and organization of smooth-muscle-specific α-actin during fibronectin-mediated modulation of arterial smooth muscle cell phenotype

The spreading of freshly isolated arterial smooth muscle cells on a substrate of fibronectin is mediated by an integrin receptor on the cell surface. It is associated with organization of actin filaments in stress fibers and marked changes in cell morphology and function, collectively referred to as a transition from a contractile to a synthetic phenotype. To study further how extracellular matrix components affect smooth muscle phenotype, we have analyzed the expression and organization of smooth-muscle-specific alpha-actin in freshly isolated rat aortic smooth muscle cells cultured on a substrate of fibronectin under serum-free conditions. Northern-blot analysis showed that the expression of mRNA for smooth muscle alpha-actin, but not for nonmuscle actin, was strongly repressed during primary culture. On the other hand, the cellular content of alpha-actin was only moderately changed during the same period. Indirect immunofluorescence staining revealed that nonmuscle actin was rapidly organized in stress fibers, which did not stain with a monoclonal antibody against smooth muscle alpha-actin. Filament bundles containing alpha-actin were most prominent in the central parts of the cytoplasm and gradually disappeared as the spreading of the cells progressed. In contrast to the situation with nonmuscle actin, there was no apparent overlap in the staining for alpha-actin and the fibronectin receptor (alpha 5 beta 1), indicating that this receptor interacted with nonmuscle actin during the initial spreading process. Taken together, the results show that the expression and organization of smooth muscle alpha-actin are changed during interaction of the cells with fibronectin early in primary culture. They support the notion that integrin-mediated interactions between extracellular matrix components and arterial smooth muscle cells take part in the control of smooth muscle phenotype.     

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.     

Particle movement on microspikes : Absence of direct linkage with actin filaments

The addition of polystyrene latex spheres to the induced lamellae of Concanavalin A (ConA)-treated neuroblastoma cells results in a preferential association and inward movement of particles along the membrane surrounding and overlying the microfilament bundles. After extraction of cell monolayers with low concentrations of Triton X-100, followed by negative staining, both the actin filaments within the bundles and the peripheral membrane with attached particles could be visualized in the electron microscope. In such preparations, no direct association was detected between membrane-particle attachment sites and the actin filaments within the bundles.     

Stages in specialization of fibroblast adhesion and deposition of extracellular matrix

Fibroblast cells seeded on a serum glycoprotein shown previously to mediate a spread shape without focal adhesions or microfilament bundles (Stage 1 spread) are now shown to have substratum contacts in which coated pits are abundant and associated with small globular deposits of glycocalyx bridging to substratum and staining for fibronectin and acidic glycoconjugates. After stimulation with serum or fibronectin to form focal adhesions and microfilament bundles (Stage 2 spread), clathrin-based structures remain at the cell underside but no longer in conspicuously higher concentration than on the dorsal surface; extracellular material at adhesions is now as regular strands which stain for acidic glycoconjugates but (as reported earlier by Chen and Singer) not always for fibronectin. During these stages of adhesion, striking changes are seen in the cellular display of fibronectin monitored by immunofluorescence. In rounded cells this is granular and cytoplasmic, concentrated around the submembranous cortex; on spreading to Stage 1, it remains granular and intracellular but is now oriented strongly towards the lower cell surface; only in Stage 2 does externalisation proceed to deposit fibrillar fibronectin on the substratum. While cytoplasmic orientation of matrix precursors can be determined by cell contact, organised externalisation is therefore coupled to fully developed adhesion status.     

Microfilament bundles in cultured cells : Correlation with anchorage independence and tumorigenicity in nude mice

The distribution of actin microfilament bundles in cell lines 3T3B, CHO, HeLa and CLID extracted with 0.1% Triton X-100 was examined by indirect immunofluorescence using human actin antibodies and by electron microscopy of whole cells grown directly on support grids. Anchorage dependence as determined by growth in soft agar and tumorigenicity in nude mice was also investigated. Immunofluorescent staining showed that CHO and HeLa cells have normal numbers and distributions of actin microfilament bundles as compared with similarly spread control 3T3B cells. A significant fraction of the mouse CLID cells showed comparable numbers of microfilament bundles as 3T3B cells but their distribution was markedly different. In many cases the bundles radiated from a region close to the cell's centre or near its projections and usually penetrated the projections. The presence of diffuse staining in 4% of the cell population also indicated the existence in these cells of disorganized actin. Electron microscope studies of well spread regions of negatively-stained, Triton-extracted cells corroborated the observations made with the immunofluorescence technique. In 3T3B, CHO and CLID cells abundant microtubules were found, colinearly arranged with actin filaments in the thin cytoplasmic extensions. While CLID, CHO and HeLa cells showed the capacity to grow in soft agar, only CLID and HeLa cells produced tumours in athymic nude mice. The observations suggest that a reduction or disorganisation of the actin microfilament bundles may not in itself be essential at least for the non-virally transformed cells studied to show anchorage independence or to produce tumours in nude mice.     

Cytoskeletal dynamics in rabbit synovial fibroblasts: II. Reformation of stress fibers in cells rounded by treatment with collagenase-inducing agents

Modulation of the synthesis and secretion of extracellular matrix proteins and matrix-degrading metalloproteases by rabbit synovial fibroblasts is an important model system for studying the control of tissue-specific gene expression. Induction of collagenase expression is correlated with changes in cell shape and actin filament distribution, but the role of the cellular cytoskeleton in the sustained synthesis and secretion of metalloproteases has not been closely examined. When cells were allowed to respread after rounding by trypsin or cytochalasin, two known metalloprotease inducers, reformation of stress fibers was observed within 2 h in the presence of serum. In the absence of serum, trypsin-treated cells did not respread substantially, even after 24 h in culture. In contrast, cytochalasin-treated cells recovered almost as rapidly in the absence as in the presence of serum, showing reformation of well-formed microfilament bundles within 30 min of drug removal, especially at the spreading cell edges. High resolution electron-microscopic views of detergent-extracted cytoskeletons confirmed the rapid rebundling of peripheral microfilaments. Acrylamide-treated cells fell between these two extremes, spreading slowly in the absence of serum, but almost as rapidly as cytochalasin-treated cells in its presence. Reestablishment of normal intermediate filament distribution generally lagged slightly behind actin for all treatments, and intermediate filaments always appeared to spread back into the cellular cytoplasm within the confines of the reforming peripheral microfilament bundles. No obvious interaction between these two cytoskeletal elements was observed after any treatment, and no specific role for intermediate filaments in modulating gene expression in these cells is suggested by these results. The serum dependence displayed after trypsin or acrylamide treatment may be due to the disturbances in fibronectin synthesis observed in these cells and is consistent with evidence that both induction and sustained expression of matrix-degrading metalloprotease may involve signals transduced through plasma membrane matrix receptors (integrins).     

Distribution of microfilament bundles during rotation of the nucleus in 3T3 cells treated with monensin

Cytoskeletal aspects of monensin-treated 3T3 cells with rotating nuclei were studied by immunofluorescence. The pattern of intermediate filaments and microtubules appeared unchanged when compared with control cells having a stationary nucleus. In contrast, the actin microfilament bundles appeared to have a consistent distribution in cells with rotating nuclei. Typically, we did not find long microfilament bundles that traverse the length of the cytoplasm of cells that were fixed at the time of nuclear rotation. Instead, there was a local distribution of short microfilament bundles situated ventrally to the nucleus and oriented at various angles to one another and to the predominant distribution of microfilament bundles in the cell. The observations suggest that the actin cytoskeleton is reorganized locally before or during rotation of the nucleus.     

α-Actinin: Immunofluorescent localization of a muscle structural protein in nonmuscle cells

Antibodies specific for the skeletal muscle structural protein α-actinin are used to localize this protein by indirect immunofluorescence in nonmuscle cells. In cultured nonmuscle cells, α-actinin is localized along or between actin filament bundles producing an almost regular periodicity. The protein is also detected in the form of fluorescent plaques at some ends of actin filament bundles, as well as in a filamentous form in some overlap areas of cells. In spreading rat embryo cells, α-actinin assumes a focal distribution which corresponds to the vertices of a highly regular actin filament network. The results suggest that α-actinin may be involved in the organization of actin filament bundles, in the attachment of actin filaments to the plasma membrane, and in the assembly of actin filaments in areas of cell to cell contact.     

Acetylcholine receptor clusters of rat myotubes have at least three domains with distinctive cytoskeletal and membranous components

Cultured rat myotubes develop high concentrations of acetylcholine receptors (AChR) in specialized areas of attachment to their substrate. We examined the ultrastructure of identified AChR clusters by quick-freeze, deep-etch, rotary replication or by thin sectioning of whole myotubes fixed in the presence of saponin and tannic acid to preserve the cytoskeleton. Our findings show that AChR clusters are composed of at least three distinct domains, differing in their cytoskeletal, intramembrane, and external components. At contact domains, the myotube's ventral membrane lacked AChR and lay within 10-15 nm of the substrate; electron-dense strands connected the two. The overlying cytoplasm contained bundles of parallel microfilaments passing above and through an irregular network of globular material, resembling the relationship of microfilament bundles to focal contacts already described in fibroblasts. Coated-membrane domains lay between the microfilament bundles and were overlain by cytoplasmic plaques of a regular network of polygons having associated coated pits. These plaques closely resembled the network of polymerized clathrin described in fibroblasts and macrophages. Coated membrane also lacked AChR and adhered to the substrate by electron-dense strands, but did not anchor microfilament bundles. The cytoplasm overlying AChR domains contained a complex network composed of at least two layers. The layer closest to the membrane consisted of protrusions from the cytoplasmic surface, some connected by fine filaments less than 5 nm in diameter. An overlying layer contained larger diameter filaments, some forming an anastomotic network reminiscent of the cortical cytoskeleton of erythrocytes. Longer filaments inserting into this network appeared identical to members of nearby microfilament bundles. The morphology of AChR domains supports the idea that AChR are immobilized by a network containing actin and spectrin.     

A new protein of adhesion plaques and ruffling membranes

A protein with a molecular weight on SDS polyacrylamide gels of 215,000 (referred to here as 215K) was purified from chicken gizzard smooth muscle. Antibodies against this protein localized it in fibroblasts to adhesion plaques (focal contacts), to regions underlying cell surface fibronectin, and to ruffling membranes. In the first two distributions it was similar to vinculin in cellular location, and this was confirmed by double-label immunofluorescence microscopy, but the concentration of 215K in membrane ruffles distinguished it from vinculin. There was no cross-reaction of the antibody against 215K with vinculin, and immunoprecipitation and antibody staining of SDS gels of whole cells revealed a single cross-reactive component with a molecular weight of 215,000. Immunoprecipitation from cultures labeled with [32P]phosphate revealed 215K to be a phosphoprotein. Transformation of rat or chicken fibroblasts by Rous sarcoma virus resulted in a reorganization of 215K, in some cases into complex intracellular structures. The localization of 215K where microfilament bundles terminate as well as in close relation to cell surface fibronectin and in membrane ruffles suggests that the protein has some function in the organization of actin filaments at or close to regions of actin-membrane attachment.     

Fibronectin in cultured rat keratinocytes: distribution, synthesis, and relationship to cytoskeletal proteins

The aim of this study was to investigate whether epidermal cells can synthesise fibronectin and whether the distribution of this glycoprotein is related to the adhesion and cytoskeletal organisation of these cells. The production of fibronectin by newborn rat epidermal cells was shown by indirect immunofluorescence staining of cultures grown in the absence of a feeder layer using an antiserum which had been cross-adsorbed with foetal calf serum proteins to remove antibodies which recognised serum fibronectin. The distribution of fibronectin in areas of cell-cell and cell-substratum contact, characteristically in the form of short radial stitches, was examined in more detail using immunoelectron microscopy with colloidal gold as marker. This showed the close proximity of fibronectin to the cell membrane, with the ventral surface and fine cellular processes showing the heaviest labelling, and also revealed evidence of a relationship between external fibronectin and internal structure in epidermal cells. Immunofluorescence showed that tonofilaments (keratin) and microtubules were present as fibrillar arrays but were not related to fibronectin distribution. Vimentin and desmin were absent. Actin was distributed as a circumferential bundle of filaments, with finer stands running radially to the edge. The latter were reminiscent of the radial fibronectin stitches and a spatial correspondence between fibronectin and actin was confirmed by double-label immunofluorescence which revealed many instances of overlap and colinearity of actin and fibronectin filaments. The ability of keratinocytes to produce fibronectin suggests that these cells can contribute to the formation of the basement membrane in skin. The localisation of fibronectin and its close association with actin also suggests that it is involved in keratinocyte adhesion and is related to the internal organisation of these cells.     

Heterogeneous distribution of isoactins in cultured vascular smooth muscle cells does not reflect segregation of contractile and cytoskeletal domains.

We have previously demonstrated that alpha-smooth muscle (alpha-SM) actin is predominantly distributed in the central region and beta-non-muscle (beta-NM) actin in the periphery of cultured rabbit aortic smooth muscle cells (SMCs). To determine whether this reflects a special form of segregation of contractile and cytoskeletal components in SMCs, this study systematically investigated the distribution relationship of structural proteins using high-resolution confocal laser scanning fluorescent microscopy. Not only isoactins but also smooth muscle myosin heavy chain, alpha-actinin, vinculin, and vimentin were heterogeneously distributed in the cultured SMCs. The predominant distribution of beta-NM actin in the cell periphery was associated with densely distributed vinculin plaques and disrupted or striated myosin and alpha-actinin aggregates, which may reflect a process of stress fiber assembly during cell spreading and focal adhesion formation. The high-level labeling of alpha-SM actin in the central portion of stress fibers was related to continuous myosin and punctate alpha-actinin distribution, which may represent the maturation of the fibrillar structures. The findings also suggest that the stress fibers, in which actin and myosin filaments organize into sarcomere-like units with alpha-actinin-rich dense bodies analogous to Z-lines, are the contractile structures of cultured SMCs that link to the network of vimentin-containing intermediate filaments through the dense bodies and dense plaques.     

Relationship of heparan sulfate proteoglycans to the cytoskeleton and extracellular matrix of cultured fibroblasts

The distribution of heparan sulfate proteoglycans (HSPG) on cultured fibroblasts was monitored using an antiserum raised against cell surface HSPG from rat liver. After seeding, HSPG was detected by immunofluorescence first on cell surfaces and later in fibrillar deposits of an extracellular matrix. Cell surface HSPG aligned with microfilament bundles of rat embryo fibroblasts seen by phase-contrast microscopy but was diffuse on transformed rat dermal fibroblasts (16C cells) which lack obvious stress fibers. Focal adhesions isolated from either cell type and monitored by interference reflection microscopy showed a concentration of HSPG labeling with respect to the rest of the membrane. Increased labeling in these areas was also seen for fibronectin (FN) by using an antiserum that detects both plasma and cell-derived FN. Double immunofluorescent staining of fully adherent rat embryo fibroblast cells showed some co-distribution of HSPG and FN, and this was confirmed by immunoelectron microscopy, which detected HSPG at localized areas of dorsal and ventral cell membranes, overlapping cell margins, and in the extracellular matrix. During cell shape changes on rounding and spreading, HSPG and FN may not co- distribute. Double labeling for actin and either HSPG or FN showed a closer correlation of actin with HSPG than with FN. The studies are consistent with HSPG being closely involved in a transmembrane cytoskeletal-matrix interaction; the possibility that HSPG coordinates the deposition of FN and other matrix components with cytoskeletal organization is discussed.     

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.     

Some of eukaryotic elongation factor 2 is colocalized with actin microfilament bundles in mouse embryo fibroblasts

Indirect immunofluorescent microscopy was used to study the distribution of eukaryotic elongation factor 2 (EF-2) in cultured mouse embryo fibroblasts. The perinuclear area (endoplasm) of all the cells and many straight cables running along the whole cytoplasm were stained with monospecific goat or rabbit antibodies to rat liver EF-2. Double staining of the cells with antibodies to EF-2 and rhodaminyl-phalloidin (used for actin microfilament detection) showed that EF-2 containing cables coincided with bundles of actin microfilaments. Not all actin microfilament bundles contained EF-2: sometimes EF-2 was not observed in bundles running along the cell edges or in actin microfilament junctions. Triton X-100 extracted most of EF-2 from the cells and no actin microfilament bundles were stained with the EF-2 antibodies in the Triton-extracted cells. Thus, in mouse embryo fibroblasts EF-2 can be found along actin microfilament bundles, but it is unlikely to be their integral protein.