Cytoskeletal Mechanisms of the Formation of Heterocellular Contacts

We studied the interaction of two main cell types, epitheliocytes and fibroblasts, in a mixed culture. Heterotypic cells had a different cytoskeleton organization and expressed different cell adhesion molecules, cadherins. In spite of this, when the cells contacted in the mixed cultures, a heterophilic contact was formed and the actin cytoskeleton of an epitheliocyte at the site of contact was reorganized: the marginal actin bundle was decomposed and actin structures were formed in its place, that were typical for the fibroblast lamella. No changes were observed in the actin organization of the fibroblast. In architecture, the heterophilic adhesion contacts resembled the contacts between fibroblasts. Both heterophilic and homophilic contacts were transient, rather than constant structures. The formation of heterophilic contacts in mixed cultures can serve as a model of formation of a tissue system consisting of epithelium and mesenchyme.     

Multiple effects of electroporation on the adhesive behaviour of breast cancer cells and fibroblasts

Background

Recently electroporation using biphasic pulses was successfully applied in clinical developments for treating tumours in humans and animals. We evaluated the effects of electrical treatment on cell adhesion behaviour of breast cancer cells and fibroblasts. By applying bipolar electrical pulses we studied short- and long-lived effects on cell adhesion and survival, actin cytoskeleton and cell adhesion contacts in adherent cancer cells and fibroblasts.

Methods

Two cancer cell lines (MDA-MB-231 and MCF-7) and one fibroblast cell line 3T3 were used. Cells were exposed to high field intensity (200 - 1000 V/cm). Cell adhesion and survival after electrical exposure were studied by crystal violet assay and MTS assay. Cytoskeleton rearrangement and cell adhesion contacts were visualized by actin staining and fluorescent microscope.

Results

The degree of electropermeabilization of the adherent cells elevated steadily with the increasing of the field intensity. Adhesion behaviour of fibroblasts and MCF-7 was not significantly affected by electrotreatment. Interestingly, treating the loosely adhesive cancer cell line MDA-MB-231 with 200 V/cm and 500 V/cm resulted in increased cell adhesion. Cell replication of both studied cancer cell lines was disturbed after electropermeabilization. Electroporation influenced the actin cytoskeleton in cancer cells and fibroblasts in different ways. Since it disturbed temporarily the actin cytoskeleton in 3T3 cells, in cancer cells treated with lower and middle field intensity actin cytoskeleton was well presented in stress fibers, filopodia and lamellipodia. The electrotreatment for cancer cells provoked preferentially cell-cell adhesion contacts for MCF-7 and cell-ECM contacts for MDA-MB- 231.

Conclusions

Cell adhesion and survival as well as the type of cell adhesion (cell-ECM or cell-cell adhesion) induced by the electroporation process is cell specific. The application of suitable electric pulses can provoke changes in the cytoskeleton organization and cell adhesiveness, which could contribute to the restriction of tumour invasion and thus leads to the amplification of anti-tumour effect of electroporation-based tumour therapy.     

The characteristics of actin cytoskeleton structure and its rearrangements by extracellular matrix proteins in normal, immortalized and transformed rat fibroblasts

Comparative analysis of actin cytoskeleton structure in rat embryonic fibroblasts, E1A-immortalized and E1A + cHa-ras-transformed cells has been carried out. A decrease in adhesiveness and the rate of changes in actin cytoskeleton structures was shown to correlate with the level of morphological transformation of cells. E1A + cHa-ras-transformants show the lowest adhesiveness and complete disorganization of actin structures. Cultivation on serum-free media promoted disassembling of actin cytoskeleton structures in a small part of normal fibroblast population, only in a few immortalized cells, but exerted no influence on transformed cells. The influence of immobilized extracellular matrix proteins fibronectin, laminin and collagens type I and III on actin cytoskeleton structure in normal, immortalized and transformed fibroblasts was studied. Transformed cells spread on fibronectin completely restored highly organized actin structures, displayed a lot of stress fibers and focal contacts. The use of laminin revealed differences in locomotion between normal and transformed cells. Normal, immortalized and transformed fibroblasts spread on fibronectin and laminin demonstrate some peculiarities in actin cytoskeleton structures as a result of specificity of ligand-receptor interaction. Cells spread on fibronectin have polygonal shapes, many stress fibers and focal contacts, whereas cells spread on laminin are highly polarized and develop broad lamellae filled with actin microfilament meshwork. Collagens type I and III can affect adhesive properties and actin cytoskeleton structure in all cell lines studied only slightly, in comparison with fibronectin and laminin.     

The Small GTPases Rho and Rac Are Required for the Establishment of Cadherin-dependent Cell–Cell Contacts

Cadherins are calcium-dependent cell–cell adhesion molecules that require the interaction of the cytoplasmic tail with the actin cytoskeleton for adhesive activity. Because of the functional relationship between cadherin receptors and actin filament organization, we investigated whether members of the Rho family of small GTPases are necessary for cadherin adhesion. In fibroblasts, the Rho family members Rho and Rac regulate actin polymerization to produce stress fibers and lamellipodia, respectively. In epithelial cells, we demonstrate that Rho and Rac are required for the establishment of cadherin-mediated cell–cell adhesion and the actin reorganization necessary to stabilize the receptors at sites of intercellular junctions. Blocking endogenous Rho or Rac selectively removed cadherin complexes from junctions induced for up to 3 h, while desmosomes were not perturbed. In addition, withdrawal of cadherins from intercellular junctions temporally precedes the removal of CD44 and integrins, other microfilament-associated receptors. Our data showed that the concerted action of Rho and Rac modulate the establishment of cadherin adhesion: a constitutively active form of Rac was not sufficient to stabilize cadherindependent cell–cell contacts when endogenous Rho was inhibited. Upon induction of calcium-dependent intercellular adhesion, there was a rapid accumulation of actin at sites of cell–cell contacts, which was prevented by blocking cadherin function, Rho or Rac activity. However, if cadherin complexes are clustered by specific antibodies attached to beads, actin recruitment to the receptors was perturbed by inhibiting Rac but not Rho. Our results provide new insights into the role of the small GTPases in the cadherin-dependent cell– cell contact formation and the remodelling of actin filaments in epithelial cells.     

Cytoskeleton organization of normal,scar, and embryonic human fibroblasts spread on extracellular matrix proteins

We assayed the cytoskeleton organization of normal, scar, and embryonic human fibroblasts spread on major proteins of the extracellular matrix (ECM), type-I and-IV collagens, laminin 2/4, and fibronectin. Confocal fluorescent microscopy showed that fibroblasts of different origins were distinguished by their organization of actin structures and focal contacts visualized with antibodies to vinculin. It was found that different fibroblasts spread on identical ECM proteins had a common spatial organization of their cytoskeletons and some modifications of their actin structures and focal contacts. Variations in the organization of actin microfilaments indicate differences in cell interactions with various ECM proteins. The difference may be dependent on the integrin combination exposed on the cell membrane. It is suggested that fibroblasts of different origins differ in their morphogenetic functions.     

Initiation of attachment and generation of mature focal adhesions by integrin-containing filopodia in cell spreading

Integrin receptors, and associated cytoplasmic proteins mediate adhesion, cell signaling and connections to the cytoskeleton. Using fluorescent protein chimeras, we analyzed initial integrin adhesion in spreading fibroblasts with Total Internal Reflection Fluorescence (TIRF) microscopy. Surprisingly, sequential radial projection of integrin and actin containing filopodia formed the initial cell-matrix contacts. These Cdc42-dependent, integrin-containing projections recruited cytoplasmic focal adhesion (FA) proteins in a hierarchical manner; initially talin with integrin and subsequently FAK and paxillin. Radial FA structures then anchored cortical actin bridges between them and subsequently cells reorganized their actin, a process promoted by Src, and characterized by lateral FA reorientation to provide anchor points for actin stress fibers. Finally, the nascent adhesions coalesced until they formed mature FAs.     

The fibronectin cell attachment sequence Arg-Gly-Asp-Ser promotes focal contact formation during early fibroblast attachment and spreading

Cultured fibroblasts form focal contacts (FCs) associated with actin microfilament bundles (MFBs) during attachment and spreading on serum- or fibronectin (FN)-coated substrates. To determine if the minimum cellular adhesion receptor recognition signal Arg-Gly-Asp-Ser (RGDS) is sufficient to promote FC and MFB formation, rat (NRK), hamster (Nil 8), and mouse (Balb/c 3T3) fibroblasts in serum-free media were plated on substrates derivatized with small synthetic peptides containing RGDS. These cultures were studied with interference reflection microscopy to detect FCs, Normarski optics to identify MFBs, and immunofluorescence microscopy to observe endogenous FN fiber formation. By 1 h, 72-78% of the NRK and Nil 8 cells plated on RGDS-containing peptide had focal contacts without accompanying FN fibers, while these fibroblasts lacked FCs on control peptide. This early FC formation was followed by the appearance of coincident MFBs and colinear FN fibers forming fibronexuses at 4 h. NRK and Nil 8 cultures on substrates coated with native FN or 75,000-D FN-cell binding fragment showed similar kinetics of FC and MFB formation. In contrast, the Balb/c 3T3 mouse fibroblasts plated on Gly-Arg-Gly-Asp-Ser peptide-derivatized substrates, or on coverslips coated with 75,000-D FN cell-binding fragment, were defective in FC formation. These results demonstrate that the apparent binding of substrate-linked RGDS sequences to cell surface adhesion receptors is sufficient to promote early focal contact formation followed by the appearance of fibronexuses in some, but not all, fibroblast lines.     

Role of feeder cells in spreading and cytoskeleton organization of newborn rat keratinocytes.

We studied the effect of feeder cells (fibroblasts) and a mixture of the extracellular matrix components, Matrigel, on spreading and cytoskeleton organization of newborn rat keratinocytes (REK). REK formed lamellipodia on being plated together with feeder cells and on the Matrigel as a substrate whereas the same REK plated alone on a plastic surface formed filopodia. REK lamellipodia formation in co-cultures depended on the fibroblast addition time. Although conditioned medium from fibroblast cultures was not enough to induce lamellipodia, the extracellular matrix left after fibroblast removal was as effective as Matrigel. Our results indicate that lamellipodia formation seems to depend on the factor(s) secreted by fibroblasts and associated with the extracellular matrix.     

Focal contacts and the cytoskeleton

Cultured cells attach to the substratum by means of specialized domains of cell surface, called focal contacts. The inner side of the cell membrane is associated in these structures with cytoskeletal elements, while the outer side is connected with extracellular matrix. The present review describes both light and electron microscopic methods of studying the focal contacts and ultrastructure of adhesion plaque, that is the cytoskeletal domain of focal contact. The proteins of adhesion plaque and focal contact membranes are also characterized. The processes of the formation of focal contacts and their association with the bundles of actin microfilaments in normal cultured fibroblasts are described in detail. Association of focal contacts with other cytoskeletal elements microtubules and intermediate filaments is discussed. The neoplastic transformation induced changes of focal contact system and cytoskeletal structures associated with contact sites are described.     

Early molecular events in the assembly of the focal adhesion-stress fiber complex during fibroblast spreading

Cell adhesion to the extracellular matrix triggers the formation of integrin-mediated contact and reorganization of the actin cytoskeleton. Examination of nascent adhesions, formed during early stages of fibroblast spreading, reveals a variety of forms of actin-associated matrix adhesions. These include: (1). small ( approximately 1 microm), dot-like, integrin-, vinculin-, paxillin-, and phosphotyrosine-rich structures, with an F-actin core, broadly distributed over the ventral surfaces of the cells; (2). integrin-, vinculin-, and paxillin-containing "doublets" interconnected by short actin bundles; (3). arrays of actin-vinculin complexes. Such structures were formed by freshly plated cells, as well as by cells recovering from latrunculin treatment. Time-lapse video microscopy of such cells, expressing GFP-actin, indicated that long actin cables are formed by an end-to-end lining-up and apparent fusion of short actin bundles. All these structures were prominent during cell spreading, and persisted for up to 30-60 min after plating. Upon longer incubation, they were gradually replaced by stress fibers, associated with focal adhesions at the cell periphery. Direct examination of paxillin and actin reorganization in live cells revealed alignment of paxillin doublets, forming long and highly dynamic actin bundles, undergoing translocation, shortening, splitting, and convergence. The mechanisms underlying the assembly and reorganization of actin-associated focal adhesions and the involvement of mechanical forces in regulating their dynamic properties are discussed.     

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.     

Structural and functional associations of apical junctions with cytoskeleton

Actin dynamics play multiple roles in promoting cell movement, changing cell shapes, and establishing intercellular adhesion. Cell contact events are involved in tissue morphogenesis, immune responses, and cancer cell invasion. In epithelial cells, cell-cell contacts mature to form apical junctions with which the actin cytoskeleton physically associates. Living cell imaging shows, however, that the apical junctional complex is less dynamically regulated than the actin cytoskeleton, indicating that their interaction does not remain stable. Given that several cell adhesion modules are clustered at apical junctions, the sum of weak or transient interactions may create linkages that can be strong yet easily remodeled. Here we describe how subcellular protein interactions are coordinated to induce changes in actin organization and dynamics, in response to the status of apical junctions.     

Structural and functional associations of apical junctions with cytoskeleton

Actin dynamics play multiple roles in promoting cell movement, changing cell shapes, and establishing intercellular adhesion. Cell contact events are involved in tissue morphogenesis, immune responses, and cancer cell invasion. In epithelial cells, cell-cell contacts mature to form apical junctions with which the actin cytoskeleton physically associates. Living cell imaging shows, however, that the apical junctional complex is less dynamically regulated than the actin cytoskeleton, indicating that their interaction does not remain stable. Given that several cell adhesion modules are clustered at apical junctions, the sum of weak or transient interactions may create linkages that can be strong yet easily remodeled. Here we describe how subcellular protein interactions are coordinated to induce changes in actin organization and dynamics, in response to the status of apical junctions.     

Influence of intercellular contacts in epithelial sheets on the capacity of the cell surface for adhesion and phagocytosis of particles]

The influence of intercellular contacts on the ability of the upper cell surface to adsorb and to phagocytose particles was studied in different types of cultured cells of mouse origin. In cultures of the MPTR strain, cells formed firm contacts which remained unbroken during the epithelial sheet migration into the wound. The contact inhibition of phagocytosis was found in these cultures. The phenomenon involved a low phagocytic activity of the sheet cells which made intercellular contacts in all directions, and of high phagocytic activity of marginal cells which had activity moving free edges. Other epithelial cultures, such as explants of normal kidney and hepatoma 60, behaved similarly. Cultured embryo fibroblasts and hepatoma 22a cells did not form firm intercellular contacts and migrated into the wound one by one. In these cultures most cells had high phagocytic activity. It is suggested that the formation of intercellular contacts alters the upper cell surface ability to adhesion and phagocytosis of particles.     

Aggregatibacter actinomycetemcomitans lipopolysaccharide affects human gingival fibroblast cytoskeletal organization

The cytoskeleton is a dynamic structure that plays a key role in maintaining cell morphology and function. This study investigates the effect of bacterial wall lipopolysaccharide (LPS), a strong inflammatory agent, on the dynamics and organization of actin, tubulin, vimentin, and vinculin proteins in human gingival fibroblasts (HGF). A time-dependent study showed a noticeable change in actin architecture after 1.5 h of incubation with LPS (1 microg/ml) with the formation of orthogonal fibers and further accumulation of actin filament at the cell periphery by 24 h. When 0.01-10 microg/ml of LPS was added to human gingival fibroblast cultures, cells acquired a round, flat shape and gradually developed cytoplasmic ruffling. Lipopolysaccharides extracted from Aggregatibacter actinomycetemcomitans periodontopathogenic bacteria promoted alterations in F-actin stress fibres of human gingival cells. Normally, human gingival cells have F-actin fibres that are organized in linear distribution throughout the cells, extending along the cell's length. LPS-treated cells exhibited changes in cytoskeletal protein organization, and F-actin was reorganized by the formation of bundles underneath and parallel to the cell membrane. We also found the reorganization of the vimentin network into vimentin bundling after 1.5 h of treatment. HGF cells exhibited diffuse and granular gamma-tubulin stain. There was no change in LPS-treated HGF. However, vinculin plaques distributed in the cell body diminished after LPS treatment. We conclude that the dynamic and structured organization of cytoskeletal filaments and actin assembly in human gingival fibroblasts is altered by LPS treatment and is accompanied by a decrease in F-actin pools.     

Mode of epithelium-fibroblast interaction in mixed heterotypic cell cultures

The interaction between epithelium (dog kidney epithelium MDCJ/clone 20) and fibroblasts (diploid human fibroblasts M19 and AG-1523) was studied in mixed heterotypic cell cultures. The mode of cell interaction depends on the manner of their collision. At collision of the epithelium lamella and the lateral side of fibroblast, the lamella was seen to creep under the lateral side to force back the fibroblast. At the frontal collision of epithelium and fibroblast lamellae, the mode of interaction depends on the local situation. With the presence of a free substratum around, the fibroblast formed a new lamella and moved aside from the place of collision. In the case, when the neighboring cells prevented fibroblast from moving, it migrated under the epithelium. In this work, we have first demonstrated the formation of specialized intercellular adhesions between epithelium and fibroblasts. The cultures were studied by phase contrast, interference reflection or video tape recording, using an image processing system (Hamamatsu). For studying adhesion, immuno-fluorescent methods were performed.     

Cytoskeletal changes in mouse embryonic fibroblasts exposed to colcemid. Electron microscopic research on platinum replicas

Cytoskeletons of colcemid-treated mouse embryo fibroblasts were studied using platinum replica technique. In the control cells, cytoskeletal components were oriented along direction of cell polarization. Structure of the control cytoskeleton changed regularly from the cell active edge to its centre forming several zones. Distribution of microtubules by colcemid led to significant changes in the organization of actin cytoskeleton. Both orientation and zonal differentiation of cytoskeleton disappeared in colcemid-treated fibroblasts. Changes in the fine structure of microfilament sheath were most prominent. Control sheath was composed of stretched tightly packed microfilaments. Colcemid treatment transformed it into fine microfilament meshwork, normally characteristic only for ruffle zone. Alterations of the fine structure of focal contacts and ruffles were also observed in treated cells. The role of microtubules in the organization of intracellular tensions and in the distribution of sites of actin polymerization is discussed.     

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.     

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.     

RNA interference elucidates the role of focal adhesion kinase in HLA class I-mediated focal adhesion complex formation and proliferation in human endothelial cells

Ligation of class I molecules by anti-HLA Ab stimulates an intracellular signaling cascade resulting in endothelial cell (EC) survival and proliferation, and has been implicated in the process of chronic allograft rejection and transplant-associated vasculopathy. In this study, we used small interfering RNA blockade of focal adhesion kinase (FAK) protein to determine its role in class I-mediated organization of the actin cytoskeleton, cell survival, and cell proliferation in primary cultures of human aortic EC. Knockdown of FAK appreciably inhibited class I-mediated phosphorylation of Src at Tyr(418), p85 PI3K, and Akt at both Thr(308) and Ser(473) sites. FAK knockdown also reduced class I-mediated phosphorylation of paxillin at Try(118) and blocked class I-induced paxillin assembly into focal contacts. FAK small interfering RNA completely abrogated class I-mediated formation of actin stress fibers. Interestingly, FAK knockdown did not modify fibroblast growth factor receptor expression induced by class I ligation. However, FAK knockdown blocked HLA class I-stimulated cell cycle proliferation in the presence and absence of basic fibroblast growth factor. This study shows that FAK plays a critical role in class I-induced cell proliferation, cell survival, and focal adhesion assembly in EC and may promote the development of transplant-associated vasculopathy.