Adhesion Complexes Formed by OVCAR-4 Cells on Laminin 1 Differ from Those Observed on Fibronectin

Cell adhesion to laminin 1 or to fibronectin is mediated by distinct sets of integrins and is differentially regulated by protein kinase C (PKC). It suggests that upon integrin ligation to laminin 1 or to fibronectin different intracellular signaling pathways could be activated. We have therefore investigated the formation of signaling complexes induced during cell adhesion to laminin 1 or to fibronectin. Following cell adhesion to laminin 1 the re-arrangement of the cytoskeleton was slower than that observed on fibronectin and it was activated by treating the cells with H-7, an inhibitor of PKC. Conversely, treatment of laminin-adhering cells with a PKC activator resulted in a rapid disorganization of the actin cytoskeleton while a similar treatment had no effect on fibronectin-adhering cells. These results suggested that the structural organization of the adhesion complexes might be substrate-specific and might correspond to a different arrangement of cytoskeletal and/or cytoplasmic proteins. Reflection interference contrast microscopy (RICM) images revealed that cell-substratum contacts formed on laminin 1 were not well differentiated in contrast to those developed on fibronectin. However, immunofluorescence staining revealed a similar organisation of actin microfilaments, talin and phosphotyrosyl-containing proteins on both substrates. In contrast, differences were observed for vinculin distribution within cells spread on fibronectin or on laminin I. Following cell adhesion to fibronectin most of the vinculin appeared as thick patches at the tips of the actin stress fibers while in laminin-adhering cells vinculin was recruited into thin streaks localized at the end of only some actin stress fibers.     

Relationships between fibronectin (LETS protein) and actin.

Double label immunofluorescence was used to study the distribution of fibronectin (LETS protein), actin and intermediate filaments in cultured cells. No relationship was observed between fibronectin and intermediated filaments, but fibronectin and actin showed coincident staining in a large proportion of cells during spreading or when fully spread. The distributions of actin and fibronectin staining during the course of cell spreading progressed through a series of patterns. Certain actin patterns correlated with certain fibronectin patterns. When fibrillar patterns developed, there was correspondence between the two fibrillar arrays in 80--100% of the cells. These results suggest a transmembrane relationship between microfilament bundles and fibronectin. We propose that fibronectin may participate in the formation of attachment plaques and discuss the interrelationship between plaques, microfilament bundles and fibronectin in cell-substratum and cell-cell contacts.     

Differential localisation of GFP fusions to cytoskeleton-binding proteins in animal,plant, and yeast cells. Green-fluorescent protein

The structure and functioning of the cytoskeleton is controlled and regulated by cytoskeleton-associated proteins. Fused to the green-fluorescent protein (GFP), these proteins can be used as tools to monitor changes in the organisation of the cytoskeleton in living cells and tissues in different organisms. Since the localisation of a specific cytoskeleton protein may indicate a particular function for the associated cytoskeletal element, studies of cytoskeleton-binding proteins fused to GFP may provide insight into the organisation and functioning of the cytoskeleton. In this article, we focused on two animal proteins, human T-plastin and bovine tau, and studied the distribution of their respective GFP fusions in animal COS cells, plant epidermal cells (Allium cepa), and yeast cells (Saccharomyces cerevisiae). Plastin-GFP localised preferentially to membrane ruffles, lamellipodia and focal adhesion points in COS cells, to the actin filament cytoskeleton within cytoplasmic strands in onion epidermal cells, and to cortical actin patches in yeast cells. Thus, in these 3 very different types of cells plastin-GFP associated with mobile structures in which there are high rates of actin turnover. Chemical fixation was found to drastically alter the distribution of plastin-GFP. Tau-GFP bound to microtubules in COS cells and onion epidermal cells but failed to bind to yeast microtubules. Thus, animal and plant microtubules appear to have a common tau binding site which is absent in yeast. We conclude that the study of the distribution patterns of microtubule- and actin-filament-binding proteins fused to GFP in heterologous systems should be a valuable tool in furthering our knowledge about cytoskeleton function in eukaryotic cells.     

Characterization and immunocytochemical localization of actin and fibronectin in haemocytes of the musselMytilus galloprovincialis

Summary Cell-extracellular matrix interactions are recognized to be important for human leucocyte functions, including chemotaxis and phagocytosis. These activities depend on a reorganization of the microfilament actin (F-actin) promoted by fibronectin, one of the major components of extracellular matrices. Although invertebrate haemocytes are, in many aspects, similar to the human granulocyte-monocyte-macrophage cell lineage, actin and fibronectin have not been well studied in these cells. Consequently, the characterization and structural organization of actin and fibronectin in mussel (Mytilus galloprovincialis) haemocytes was investigated using Western blotting analysis, indirect immunofluorescence and immunoelectron microscopy. Actin was immunocharacterized by an anti-total actin monoclonal antibody. Fibronectin was immunocharacterized by an autologous polyclonal antiserum directed against the protein of mussel haemolymph. Actin was mainly localized along the peripheral cytoplasm of the haemocyte. The distribution of the F-actin microfilaments was assayed with Rhodamine-labelled phalloidin. F-actin was associated mainly with stress-fibres of spreading haemocytes and with microspikes at the adhesion sites. The labelling by the anti-fibronectin antiserum of the haemocyte rough endoplasmic reticulum vesiles, revealed by immunoelectron microscopy, suggests that these cells are involved in fibronectin biosynthesis. Gold particles were also present along the outer surfaces of the cell plasma membrane and its protrusions. Mussel fibronectin was localized immunohistochemically at the adhesion sites and in the extracellular matrix fibrils. The relationships between fibronectin and the actin cystoskeleton inMytilus galloprovincialis haemocytes are discussed.     

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.     

Actin filaments during terminal differentiation of urothelial cells in the rat urinary bladder

The localisation of actin filaments was studied in rat urothelial cells during differentiation which accompanied regeneration after cell damage induced by cyclophosphamide (CP). By immunofluorescence it was established that actin filaments equally stained along the cell circumference in basal and intermediate cells, while basolateral cell membrane expression was found in terminally differentiated superficial cells. During regeneration, after CP treatment, simple urothelial hyperplasia developed with smaller cuboidal superficial cells, in which actin filaments were equally distributed under the apical and basolateral plasma membranes. As demonstrated by immunoelectron microscopy, the apical surface of these superficial cells was covered with microvilli containing bundles of actin filaments. Within 1 week, the urothelium reverted to its normal three-layer thickness. Superficial cells became larger and flattened and the unthickened apical plasma membrane matured into a thick asymmetric unit membrane. Concomitantly actin filaments disappeared from apical areas of superficial cells while remaining abundant at basolateral areas. Our results indicate that in the urothelium subcellular distribution of actin filaments can be considered as a marker of cell differentiation. Accepted: 16 September 1999     

Myosin in onion (Allium cepa) bulb scale epidermal cells: involvement in dynamics of organelles and endoplasmic reticulum

Studied with the fluorochrome 3,3-dihexyloxacarbocyanine iodide [(DIOC₆(3)], the dynamic system of the endoplasmic reticulum (ER) in epidermal cells of onion bulb scales consists of long, tubular strands moving together with organelles in the deeper cytoplasm, and of a less mobile network composed of tubular and lamellar elements at the cell periphery. Treatment with the sulfhydryl-reagent N-ethylmaleimide (NEM) inhibited organelle and ER movement, and caused the fusion of ER-tubules into flat sheets. Fixed, long, tubular ER strands were formed by lowering the cytosolic pH of NEM-treated cells. Both these observations indicate the involvement of myosin in the dynamics of organelles and ER. Using a monoclonal antibody against murine skeletal muscle myosin (known to cross-react with plant myosin; Tang et al. 1989, J. Cell Sci. 92: 569–574), myosin was identified by immunofluorescence microscopy. Mapping the distribution of myosin, actin filaments, ER, and organelles in different phases of recovery after centrifugation of epidermal cells, co-localization of myosin with ER and organelles but not with actin filaments was observed, supporting the hypothesis that a membrane bound motor protein exists in onion epidermal cells, which translocates organelles and the endoplasmic reticulum along actin filaments.     

Differential localisation of GFP fusions to cytoskeleton-binding proteins in animal, plant, and yeast cells

Summary.  The structure and functioning of the cytoskeleton is controlled and regulated by cytoskeleton-associated proteins. Fused to the green-fluorescent protein (GFP), these proteins can be used as tools to monitor changes in the organisation of the cytoskeleton in living cells and tissues in different organisms. Since the localisation of a specific cytoskeleton protein may indicate a particular function for the associated cytoskeletal element, studies of cytoskeleton-binding proteins fused to GFP may provide insight into the organisation and functioning of the cytoskeleton. In this article, we focused on two animal proteins, human T-plastin and bovine tau, and studied the distribution of their respective GFP fusions in animal COS cells, plant epidermal cells (Allium cepa), and yeast cells (Saccharomyces cerevisiae). Plastin-GFP localised preferentially to membrane ruffles, lamellipodia and focal adhesion points in COS cells, to the actin filament cytoskeleton within cytoplasmic strands in onion epidermal cells, and to cortical actin patches in yeast cells. Thus, in these 3 very different types of cells plastin-GFP associated with mobile structures in which there are high rates of actin turnover. Chemical fixation was found to drastically alter the distribution of plastin-GFP. Tau-GFP bound to microtubules in COS cells and onion epidermal cells but failed to bind to yeast microtubules. Thus, animal and plant microtubules appear to have a common tau binding site which is absent in yeast. We conclude that the study of the distribution patterns of microtubule- and actin-filament-binding proteins fused to GFP in heterologous systems should be a valuable tool in furthering our knowledge about cytoskeleton function in eukaryotic cells. Received January 12, 2002; accepted March 7, 2002; published online June 24, 2002 RID="*" ID="*" Correspondence and reprints (present address): Institute of Botany, University of Bonn, Kirschallee 1, 53115 Bonn, Federal Republic of Germany. Abbreviation: smRS-GFP soluble modified red-shifted GFP.     

Changes in cholesterol levels in the plasma membrane modulate cell signaling and regulate cell adhesion and migration on fibronectin

The number and distribution of lipid molecules, including cholesterol in particular, in the plasma membrane, may play a key role in regulating several physiological processes in cells. We investigated the role of membrane cholesterol in regulating cell shape, adhesion and motility. The acute depletion of cholesterol from the plasma membrane of cells that were well spread and motile on fibronectin caused the rounding of these cells and decreased their adhesion to and motility on fibronectin. These modifications were less pronounced in cells plated on laminin, vitronectin or plastic, indicating that cholesterol-mediated changes in adhesion and motility are more specific for adhesion mediated by fibronectin-specific integrins, such as alpha5beta1. These changes were accompanied by remodeling of the actin cytoskeleton, the spatial reorganization of paxillin in the membrane, and changes to the dynamics of alpha5 integrin and paxillin-rich focal adhesions. Levels of tyrosine phosphorylation at position 576/577 of FAK and Erk1/Erk2 MAP-kinase activity levels were both lower in cholesterol-depleted than in control cells. These levels normalized only on fibronectin when cholesterol was reincorporated into the cell membrane. Thus, membrane cholesterol content has a specific effect on certain signaling pathways specifically involved in regulating cell motility on fibronectin and organization of the actin cytoskeleton.     

Fluorescence-mediated visualization of actin and myosin filaments in the contractile membrane-cytoskeleton complex of Dictyostelium discoideum

An intact complex that consisted of the cell membrane and cytoskeleton was prepared from Dictyostelium amoebae by an improved version of the method previously used by CLARKE et al. (1975). Proc. Natl. Acad. Sci. USA., 72: 1758-1762. After cells had attached tightly to a polylysine-coated coverslip in the presence of a divalent cation, the upper portions of the cells were removed with a jet of microfilament-stabilizing solution squirted from a syringe. The cell membranes left on the coverslip were immediately stained with tetramethylrhodamine-conjugated phalloidin for staining of actin filaments, and with antibody against myosin from Dictyostelium and a fluorescein-conjugated second antibody for staining of myosin. Networks of actin filaments and numerous rod-like structures of myosin (myosin filaments) aligned along them were observed on the exposed cytoplasmic surfaces of the cell membranes. These networks were similar to those observed in the cortex of fixed whole cells. Addition of ATP to these intact complexes of cell membrane and cytoskeleton caused the aggregation of both actin and myosin into several dot-like structures of actin on the cell membrane. Similar dot-like structures were also seen in the cortex of fixed whole cells, and their changes in distribution correlated with the motile activity of the cells. Transmission electron microscopy showed that these dot-like structures were composed of an electron-dense structure at the center, from which numerous actin filaments radiated outwards. These observations suggest that these novel dot-like structures are organizing centers for cortical actin filaments and may possibly be related to the adhesion of cells to the substratum.     

On the relation between distinct components of the cytoskeleton: an epitope shared by intermediate filaments, microfilaments and cytoplasmic foci.

Monoclonal antibodies were generated against detergent-insoluble cytoskeletal proteins isolated from low-density membrane fractions of rat liver. By immunofluorescence, one of the antibodies stains three distinct structures in cultured rat fibroblast and hepatocyte lines as well as the PtK2 rat-kangaroo kidney epithelial line. These structures are: i) many tangled filaments similar to intermediate filaments (IFs), ii) fewer and variable numbers of straight filaments, and iii) punctate cytoplasmic foci, often most intense around the nucleus. All three of these structures are resistant to extraction by non-ionic detergent. Close examination reveals that the tangled and straight filaments are not stained uniformly, but as a series of bright patches. In cells treated with nocodazole, the antibody reacts strongly with a perinuclear filamentous cage. Very few tangled filaments are detected in these cells, however, the straight filaments and punctate cytoplasmic staining are resistant to nocodazole treatment. Double-label immunofluorescence shows that, even though tangled filament distribution and nocodazole sensitivity are similar to the behavior of vimentin IFs, there is only partial coincidence of staining with either vimentin or cytokeratin IFs. The straight filaments coincide with some actin stress fibers, but the punctate cytoplasmic staining is not related to IFs, actin, or tubulin. Thus, this monoclonal antibody stains a novel group of three seemingly unrelated cytoskeletal structures, including a previously undescribed insoluble nonfilamentous pool. Taken as a whole, two hypotheses are consistent with these data. i) The antigen recognized may be a protein which has a large insoluble cytoplasmic pool and binds both IFs and actin, but only binds to a subset of each class of filaments.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vivo co-distribution of fibronectin and actin fibers in granulation tissue: immunofluorescence and electron microscope studies of the fibronexus at the myofibroblast surface

The fibronexus ( FNX ), a very close transmembrane association of individual extracellular fibronectin fibers and actin microfilaments, was found previously at the substrate-binding surface of fibroblasts in tissue culture (Singer, 1. 1., 1979, Cell, 16:675-685). To determine whether the fibronexus might be involved in fibroblast adhesion during wound healing in vivo, we looked for co-localization of actin and fibronectin in granulation tissue formed within full-thickness guinea pig skin wounds. At 7-9 d, most of the actin fibers were observed to be coincident with congruent fibronectin fibers using double-label immunofluorescence microscopy. These fibronectin and actin fibers were co-localized at the myofibroblast surface surrounding the nucleus, and along attenuated myofibroblast processes which extended deeply into the extracellular matrix. This conspicuous co-distribution of fibronectin and actin fibers prompted us to look for fibronexuses at the myofibroblast surface with electron microscopy. We observed three kinds of FNXs : (a) tandem associations between the termini of individual extracellular fibronectin fibers and actin microfilament bundles at the tips of elongate myofibroblast processes, (b) plaque-like and, (c) track-like FNXs , in which parallel fibronectin and actin fibers were connected by perpendicular transmembranous fibrils. Goniometric studies on the external and internal components of these cross-linking fibrils showed that their membrane-associated ends are probably co-axial. Using immunoelectron microscopy on ultrathin cryosections, we confirmed that the densely staining external portion of these various FNXs does indeed contain fibronectin. The finding that these FNXs appear to connect collagen fibers to intracellular bundles of actin microfilaments is particularly significant. Our studies strongly suggest that the fibronexus is an important in vivo cell surface adhesion site functioning in wound repair, and perhaps within fibronectin-rich tissues during embryogenesis, tumor growth, and inflammation.     

An immunofluorescence study of the effects of ultraviolet radiation on the organization of microfilaments, keratin intermediate filaments, and microtubules in human keratinocytes.

Indirect immunofluorescence microscopy has been used to investigate the ultraviolet (UV) radiation induced disruption of the organization of microfilaments, keratin intermediate filaments, and microtubules in cultured human epidermal keratinocytes. Following irradiation, concurrent changes in the organization of the three major cytoskeletal components were observed in cells incubated under low Ca2+ (0.15 mM) conditions. UV irradiation induced a dose-dependent condensation of keratin filaments into the perinuclear region. This collapse of the keratin network was accompanied by the reorganization of microfilaments into rings and a restricted distribution of microtubules, responses normally elicited by exposure to high Ca2+ (1.05 mM) medium. The UV induced alteration of the keratin network appears to disrupt the interactions between keratin and actin, permitting the reorganization of actin filaments in the absence of Ca2+ stimulation. In addition to the perinuclear condensation of keratin filaments, UV irradiation inhibits the Ca2+ induced formation of keratin alignments at the membrane of apposed cells if UV treatment precedes exposure to high Ca2+ medium. Incubation of keratinocytes in high Ca2+ medium for 24 hours prior to irradiation results in the stabilization of membrane associated keratin alignments and a reduced susceptibility of cytoplasmic keratin filaments to UV induced disruption. Unlike results from investigations with isogenic skin fibroblasts, no UV induced disassembly of microtubules was discernible in irradiated human keratinocytes.     

Immunolocalization of the intermediate filament-associated protein plectin at focal contacts and actin stress fibers.

The distribution of plectin in the cytoplasm of Rat1 and glioma C6 cells was examined using a combination of double and triple immunofluorescence microscopy and interference reflection microscopy. In cells examined shortly after subcultivation (less than 48 h), filamentous networks of plectin structures, resembling and partially colocalizing with vimentin filaments, were observed as reported in previous studies. In cells kept attached to the substrate without growth for periods of 72 h to 8 days (stationary cultures), thick fibrillary plectin structures were observed. These structures were located at the end of actin filament bundles and showed co-distribution with adhesion plaques (focal contacts), vinculin, and vimentin. Only relatively large adhesion plaques (dash-like contacts) were decorated by antibodies to plectin, smaller dot-like contacts at the cell edges remained undecorated. Moreover, in stationary Rat1 cells plectin structures were found to be predominantly colocalized with actin stress fibers. However, after treatment of such cells with colcemid, plectin's distribution changed dramatically. The protein was no longer associated with actin structures, but was distributed diffusely throughout the cytoplasm. After a similar treatment with cytochalasin B, plectin's association with stress fibers again was completely abolished, although stress fibers were still present. The association of plectin with focal contact-associated intermediate filaments was demonstrated also by immunogold electron microscopy of quick-frozen, deep-etched replicas of rat embryo fibroblasts. These data confirm previous reports suggesting a relationship between intermediate filaments on the one hand, and actin stress fibers and their associated plasma membrane junctional complexes, on the other. Furthermore, the data establish plectin as a novel component of focal contact complexes and suggest that plectin plays a role as mediator between intermediate filaments and actin filaments.     

Distribution of actin microfilaments in frog skin epithelial granular cells

Summary— Microfilaments were localised by immunofluorescence and immunogold cytochemistry to examine their distribution in granular cells of the isolated frog skin epithelium. Strongly fluorescent bundles of actin were observed beneath the plasma membrane with little evidence for actin in the central regions. Higher resolution offered by cytochemistry revealed that bundles of actin filaments comprised a substantial portion of the cortical cytoskeleton. Quantitative analysis of the frequency of gold label revealed an extremely rich array of filaments beneath the apical membrane of granular cells, with markedly less babel along the basolateral membrane and in the central cytoplasm. Treating cells with cytochalasin B or arginine vasopressin caused an apparent disruption of the apical actin fibres, concurrent with a decrease in gold label density. Assumably these signs are indicative of depolymerization of the filaments. Although the significance of this distribution is unknown, the apical polarisation of actin is consistent with a role in regulating the Na⁺ permeability of the apical membrane. The data are discussed in relation to possible roles of the cytoskeleton in the regulation of transepithelial sodium transport by vasopressin.     

Actomyosin relationships with surface features in fibroblast adhesion

The relationships between internal and external structures in fibroblast adhesion to substratum have been examined in mammalian and avian cells by optical and electron microscopy with the use of antibody and lectin reagents to distinguish specific protein and carbohydrate features. Two external components previously shown between the membrane and substratum at focal adhesions are now demonstrated to have distinct distributions on whole cells. Under the culture conditions we used, most fibronectin structures are unrelated in their distribution to focal adhesions or stress fibres, but a class of ricin receptors on the cell undersides which is distinguishable from fibronectin by both immunochemical and biochemical criteria is seen to extend from each adhesion along part of the length of the associated actin fibre. Further evidence for a transmembrane relationship between these arrays of ricin receptors and the actin fibres is the parallel dispersal of both by trypsin, by EGTA, and by cytochalasin B. More detailed structural information regarding transmembrane complexes at the adhesions was obtained by conventional and immunoelectron microscopy. The data confirm and extend analogies with the Z-line structure of skeletal muscle.     

The epidermal growth factor receptor is associated with actin filaments.

In this paper we describe our investigations on the association of receptors for the epidermal growth factor (EGF) with the cytoskeleton of A431 cells. In order to determine which filamentous system the EGF receptors are associated to, the cytoskeletal fraction to which these receptors bind was isolated. Second, the possible colocalization of EGF receptors with different cytoskeletal elements was examined in A431 cells. By selective extractions of the A431 cytoskeletons, it is shown that more than 90% of the cytoskeleton-associated EGF receptors are removed from the cytoskeletons together with the actin filamentous system. During several cycles of poly- and depolymerization of actin isolated from A431 cells, the EGF receptor precipitates together with the actin containing filaments, indicating that EGF receptors are able to bind in vitro to actin filaments. With immunofluorescence studies we show that EGF receptors especially colocalize with actin filaments. These results demonstrate that the EGF receptor is associated specifically with actin filaments in A431 cells.     

Attachment of A-431 cells on immobilized antibodies to the EGF receptor promotes cell spreading and reorganization of the microfilament system

EGF-like sequences, inherent in a number of extracellular matrix proteins, participate in cell adhesion. It is possible that interactions of these sequences with EGF receptors (EGFR) affect actin filament organization. It was shown previously [Khrebtukova et al., 1991: Exp. Cell Res. 194:48-55] that antibodies specific to EGFR induce capping of these receptors and redistribution of cytoskeletal proteins in A-431 cells. Here we report that A-431 cells attach and spread on solid substrata coated with antibodies to EGFR, even in the absence of serum. Thus, EGFR can act as an adhesion protein and promote microfilament reorganization. Binding of the cells to the EGFR-antibody resulted in the formation of a unique cell shape characterized by numerous, actin-based filopodia radiating from the cell body, but without membrane ruffles. There was also a conspicuous circular belt of actin-containing fibers inside the cell margin, and many irregular actin aggregates in the perinuclear area. The morphologies and actin distributions in A-431 cells spread on fibronectin or laminin 2/4 were very different. On fibronectin, cells had polygonal shapes with numerous stress-fibers and thick actin-containing fibers along the cell edges. On laminin-covered substrata, the cells became fusiform and acquired broad leading lamellae with ruffles. In these cells, there were also a few bundles of filaments running the whole length of the cell body, and shorter bundles extending through the leading lamellae towards the membrane ruffles in the cell edge. These effects and those seen with immobilized EGF suggest that different ligand/receptor complexes induce specific reorganizations of the microfilament system.     

Confocal analysis of cytoskeletal organisation within isolated chondrocyte sub-populations cultured in agarose

This study reports the cytoskeletal organisation within chondrocytes, isolated from the superficial and deep zones of articular cartilage and seeded into agarose constructs. At day 0, marked organisation of actin microfilaments was not observed in cells from both zones. Partial or clearly organised microtubules and vimentin intermediate filaments cytoskeletal components were present, however, in a proportion of cells. Staining for microtubules and vimentin intermediate filaments was less marked after 1 day in culture however than on initial seeding. For all three cytoskeletal components there was a dramatic increase in organisation between days 3 and 14 and, in general, organisation was greater within deep zone cells. Clear organisation for actin microfilaments was characterised by a cortical network and punctate staining around the periphery of the cell, while microtubules and vimentin intermediate filaments formed an extensive fibrous network. Cytoskeletal organisation within chondrocytes in agarose appears, therefore, to be broadly similar to that described in situ. Variations in the organisation of actin microfilaments between chondrocytes cultured in agarose and in monolayer are consistent with a role in phenotypic modulation. Vimentin intermediate filaments and microtubules form a link between the plasma membrane and the nucleus and may play a role in the mechanotransduction process.     

Ultrastructural cytoskeleton alterations and modification of actin expression in the NIH/3T3 cell line after transformation with Ha-ras-activated oncogene.

Cytoskeleton alterations of NIH/3T3 fibroblast monolayers transfected with Ha-ras-activated oncogene were studied by immunofluorescence, immunoelectron microscopy, and immunoelectrophoretic analysis of actin isoforms. Transformation foci were found to consist of cells with a round shape and rare stress fibers that spread sparsely, forming rare focal contacts and fibronexuses. The loss of stress fibers in transformed cells was confirmed by staining with rhodamine-phalloidin and with a fluorescinated anti-non-muscle cell actin antibody. The transformed cells were anchored to the substrate prominently by filaments that contained fibronectin, as showed by immunoelectron microscopy. A down-regulation of alpha-actin isoform was observed by immunofluorescence and immunoblotting analysis using a specific monoclonal antibody. The diffuse distribution of alpha-actin, lacking a specific association with stress fibers, challenges the hypothesis of a connection between alpha-actin down-regulation and stress fiber loss.