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.     

Contact relationships between chick embryo cells growing in monolayer culture after infection with Rous sarcoma virus

An electron microscopic examination was made of cell contacts and associated microfilament arrays in subconfluent cultures of chick embryo fibroblasts (CEF) and chick embryo retinal pigmented epithelium cells (RPE) transformed by strains of Rous sarcoma virus (RSV) imparting a rounded (Morph r) or fusiform (Morph f) transformed morphology. A few cell substrate contact specializations were found in Morph r-transformed CEF and RPE cells. These resembled cell/substrate plaques of uninfected fibroblasts, but lacked associated microfilament tracts. In contrast Morph f-transformed CEF and RPE resembled untransformed fibroblasts having well developed cell/substrate and cell/cell contact specializations with extensive associated microfilament arrays. Morph r- and Morph f-transformed RPE cells had lost the junctional complex typical of untransformed RPE cultures and additionally no melanosomes were found. SEM and TEM demonstrated differences in adhesive properties of CEF and RPE cell surfaces, few virions adhering to the free cell surface of RPE cells but being found in clumps and singly on CEF cells.     

Isolation of focal contact membrane using saponin

The fragments of lower cell surface remained attached to the substrate after incubation of mouse or chick fibroblasts in 0.2% saponin solution and subsequent removal of cells under the action of shearing force. These fragments corresponded exactly to the cellular focal contacts seen by interference reflection microscopy. Ultrastructurally they were membrane fragments with typical three-layered structure. No cytoskeletal components were found in saponin-isolated focal contact membranes either by immunofluorescence or electron microscopy. Only one major cell-derived protein with an apparent molecular weight (MW) of 51 kD (chick embryo fibroblasts) or 47 kD (mouse embryo fibroblasts) remained on the substrate after saponin treatment and removal of cells.     

Heavy meromyosin binding to microfilaments involved in cell and morphogenetic movements

Certain microfilaments found in migratory single cells and in morphogenetically-active epithelial cells are shown to bind heavy meromyosin prepared from skeletal muscle. This ‘actin-like’ feature of the filaments is compatible with the hypothesis that such filaments are components of contractile systems in these cells.     

Is there a role for actin in virus budding?

Electrophoretic data from both sodium dodecyl sulfate-polyacrylamide gels (SDS-PAGE) and acid-urea gels reveal a protein in purified murine mammary tumor virus (MuMTV) which co-migrates with purified chick skeletal muscle actin. 125I-labeling of intact and disrupted virus preparations shows that the actin-like protein is not artifactually adsorbed to the outside of virions during isolation. Quantitative SDS- PAGE and examination of negatively stained preparations show that the actin cannot be accounted for by a contaminating population of virus- free vesicles. The ultrastructure of mammary epithelial cells and of Rous sarcoma virus-transformed chick embryo fibroblasts shows that virus extrusion is associated with filament-containing cellular processes. In particular, MuMTV is released from the ends of long microvilli which contain a bundle of 6-8-nm microfilaments and share other structural features with intestinal microvilli. We suggest that virus nucleoids require an interaction with host cell contractile proteins for their extrusion from the cell.     

Actin-like filaments in the myoid cell of the testis

Microfilaments in the myoid cells of the peritubular tissue in the mouse, swine and human testis bind heavy meromyosin (HMM) and form arrowhead complexes. The periodicity of the arrowhead complexes is about 35 nm. Individual filaments show arrowheads that point in the same direction. Opposing polarity of the HMM-bound filaments is also observed. The microfilaments do not bind HMM in the presence of 10 mM ATP. After treatment with the contraction medium of Hoffmann-Berling, the filaments appear to be undulated. These observations indicate that the microfilaments in the myoid cell are actin-like in nature. A small number of thicker filaments (about 10 nm in diameter) which do not bind HMM is also observed in the cell. Microfibrils which have been reported around the human myoid cell are also found in the swine.     

An integral glycoprotein associated with the membrane attachment sites of actin microfilaments

An integral membrane protein associated with sites of microfilament-membrane attachment has been identified by a newly developed IgG1 monoclonal antibody. This antibody, MAb 30B6, was derived from hybridoma fusion experiments using intact mitotic cells of chick embryo fibroblasts as the immunization vehicle as well as the screening probe for cell surface antigens. In immunofluorescent experiments with fixed cells, MAb 30B6 surface labeling is uniquely correlated with microfilament distributions in the cleavage furrow region of dividing chick embryo fibroblasts and cardiac myocytes in culture. The MAb 30B6 antigen in addition is associated with microfilament-membrane attachment sites in interphase fibroblasts at the dorsal surface, the adhesion plaque region at the ventral surface, and at junction-like regions of cell-cell contact. It is also found co-localized with the membrane-dense plaques of smooth muscle. The MAb 30B6 antigen is expressed in a wide number of chicken cell types (particularly smooth muscle cells, platelets, and endothelial cells), but not in erythrocytes. Some of the molecular characteristics of the MAb 30B6 antigen have been determined from immunoblotting, immunoaffinity chromatography, immunoprecipitation, cell extraction, and charge shift electrophoresis experiments. It is an integral sialoglycoprotein with an apparent molecular mass of 130 kD (reduced form)/107 kD (nonreduced form) in SDS PAGE. Another prominent glycoprotein species with an apparent molecular mass of 175 kD (reduced form)/165 kD (nonreduced form) in SDS PAGE is co-isolated on MAb 30B6 affinity columns, but appears to be antigenically distinct since it is not recognized by MAb 30B6 in immunoblotting or immunoprecipitation experiments. By virtue of its surface distributions relative to actin microfilaments and its integral protein character, we propose that the MAb 30B6 antigen is an excellent candidate for the function of directly or indirectly anchoring microfilaments to the membrane.     

Cytoskeletal elements of chick embryo fibroblasts revealed by detergent extraction

Treatment of chick embryo fibroblasts with 0.5% Triton® X-100 extracts most of the cell protein, leaving an organized part of the cell structure attached to the tissue culture dish. This “Triton cytoskeleton” consists largely of intermediate-sized filaments and bundles of microfilaments. SDS polyacrylamide gel electrophoresis reveals that this cytoskeleton is made up of three main proteins. One protein component is 42,000 daltons and co-migrates with muscle actin. The other two components are 52,000 and 230,000 daltons and remain quantitatively associated with the cytoskeleton during the detergent extraction. The possible identity of these three protein components and their organization into a supramolecular structure is discussed.     

pH-dependent function, purification, and intracellular location of a major collagen-binding glycoprotein

A major collagen-binding heat shock protein of molecular mass 47,000 D was found to bind to collagen by a pH-dependent interaction; binding was abolished at pH 6.3. Native 47-kD protein could therefore be purified from chick embryo homogenates in milligram quantities by gelatin-affinity chromatography and gentle acidic elution. Rat monoclonal and rabbit polyclonal antibodies were generated against the purified 47-kD protein. Immunofluorescence microscopy of cultured chick embryo fibroblasts with these antibodies revealed bright, granular perinuclear staining as well as a weaker reticular network structure towards the cell periphery, suggesting that this protein was located in the endoplasmic reticulum. No immunofluorescence staining was detected on the cell surface. Double-staining experiments with these antibodies and fluorescently labeled wheat-germ agglutinin suggested that the 47-kD protein was absent from the Golgi apparatus. Localization of the 47-kD protein in the endoplasmic reticulum but not in the Golgi complex was confirmed by immunoelectron microscopy. In vivo localization studies using immunohistochemistry of cryostat sections of chick liver revealed that the 47-kD protein was present in fibrocytes, Kupffer cells, and smooth muscle cells. It was absent from hepatocytes and the epithelia of bile ducts or sinusoidal endothelium. This major transformation- and heat shock-regulated glycoprotein is thus localized intracellularly, is expressed in only certain cells, and functions in a pH-regulated manner. These findings suggest that this glycoprotein is not likely to be a general cell-surface collagen receptor, but may instead play roles in intracellular protein processing or translocation.     

Cell surface protein decreases microvilli and ruffles on transformed mouse and chick cells.

Transformation of cultured fibroblasts usually results in a decrease in a high molecular weight cell surface glycoprotein (LETS protein) and often in increased numbers of surface microvilli and ruffles. We have isolated such a major cell surface glycoprotein from chick embryo fibroblasts; this protein, CSP, is decreased after transformation. Treatment of a mouse tumor cell line (SV1), L929 cells, and transformed chick fibroblasts with CSP results in a decrease in the number of microvilli and marginal ruffles, accompanied by restoration of a more normal morphology.     

Early contacts between fibroblasts. An ultrastructural study

Pairs of chick heart fibroblasts have been studied with the light microscope and then fixed in situ for electron microscopy at varying times after they have been seen to make contact with each other. The resultant electron micrographs show that areas of specialisation begin to develop within 20 sec of the contact being made. These specialisations resemble those seen in isolated chick heart fibroblasts where the cell comes close to the substrate and are thought to be areas of adhesion. The development of these areas and their associated microfilaments is described and an attempt is made to correlate this with the stages of the contact inhibition phenomenon.     

Colocalization of single ribosomes with intermediate filaments in puromycin-treated and serum-starved mouse embryo fibroblasts*

Previous experiments have revealed a relatively weak electrostatic binding capacity of in vitro reconstituted intermediate filaments (IFs) as well as of natural IFs of whole cell mount preparations for purified ribosomal particles of mammalian origin. In order to demonstrate that such associations also occur in vivo, intact cells were subjected to double immunofluorescence microscopy using antibodies directed against vimentin and ribosomal protein S17. Since in proliferating cells the majority of the ribosomal particles are assembled into polyribosomes and these are to a great extent associated with microfilaments, in vitro cultured mouse embryo skin fibroblasts (MSF cells) were treated with puromycin to allow the formation of single ribosomes. Employing confocal laser scanning microscopy, the ribosomes were detected in colocalization with vimentin IFs. Disassembly of polyribosomes was also achieved by serum starvation of cultured cells. In this case, MSF cells of a low passage attained an extended and flattened appearance with the vimentin IFs being directly associated with the cell nuclei, radiating into the peripheral areas of the cells or showing a stress fiber-like distribution. In both cases, considerable quantities of ribosomal material were seen in close neighborhood to vimentin IFs. Frequently, these ribosome-IF associations were coaligned with microtubules and they also surrounded myosin I-decorated stress fibers. Double labeling with the vital, RNA-specific fluorochrome SYTO 14 produced a fluorescence pattern largely super-imposable on that of ribosomal protein S17. Treatment of the starved cells with either demecolcine or cytochalasin D had an only moderately disturbing effect on vimentin IF distribution and the ribosomes stayed in contact with the vimentin IFs. On the basis of these results, it is conceivable that IFs play a role in the storage of ribonucleoprotein particles in general and non-translating ribosomes in particular in the cytoplasm of animal cells. In addition, the often seen coalignment of IFs with microtubules and microfilaments might serve facilitated and directional transport of ribonucleoprotein particles from the nucleus to peripheral areas of the cell.     

Microfilaments and tropomyosin of cultured mammalian cells: isolation and characterization

Microfilaments were isolated from cultured mammalian cells, utilizing procedures similar to those for isolation of "native" thin filaments from muscle. Isolated microfilaments from rat embryo, baby hamster kidney (BHK- 21), and Swiss mouse 3T3 cells appeared structurally similar to muscle thin filaments, exhibiting long, 6 nm Diam profiles with a beaded, helical substructure. An arrowhead pattern was observed after reaction of isolated microfilaments with rabbit skeletal muscle myosin subfragment 1. Under appropriate conditions, isolated microfilaments will aggregate into a form that resembles microfilament bundles seen in situ cultured cells. Isolated microfilaments represent a complex of proteins including actin. Some of these components have been tentatively identified, based on coelectrophoresis with purified proteins, as myosin, tropomyosin, and a high molecular weight actin-binding protein. The tropomyosin components of isolated microfilaments were unexpected; polypeptides comigrated on SDS-polyacrylamide gels with both muscle and nonmuscle types of tropomyosin. In order to identify more specifically these subunits, we isolated and partially characterized tropomyosin from three cell types. BHK-21 cell tropomyosin was similar to other nonmuscle tropomyosins, as judged by several criteria. However, tropomyosin isolated from rate embryo and 3T3 cells contained subunits that comigrated with both skeletal muscle and nonmuscle types of myosin, whereas the BHK cell protein consistently contained a minor muscle-like subunit. The array of tropomyosin subunits present in a cell culture was reflected in the polypeptide chain pattern seen on SDS-polyacrylamide gels of microfilaments isolated from that culture. These studies provide a starting point for correlating changes in the ultrastructural organization of microfilaments with alterations in their protein composition.     

Cytochalasin B-induced depolymerization of F-actin in chick embryo fibroblasts is dependent on cell density and anchorage to substratum

The effect of cytochalasin B on F-actin amount and organization was measured in chick embryo fibroblasts (CEF) grown on solid substratum at low density, at high density, and suspended in a fluid medium. It was found that: 1) Cytochalasin B induced decrease in F-actin content only in cells growing at low density, in density-inhibited or suspended cells cytochalasin B had no effect on F-actin amount. 2) In cells grown at low density F-actin filaments organized in stress fibers are more resistant to cytochalasin B than F-actin which is not organized in fibrils. In cell density-inhibited or suspended in a fluid medium F-actin filaments are insensitive to the action of cytochalasin B, although they are not organized in stress fibers. These results are interpreted to reflect the influence of contact reactions on treadmilling in F-actin filaments.     

Alteration of insulin binding and cytoskeletal organization in cultured fibroblasts by tertiary amine local anesthetics

Tertiary amine local anesthetics cause a time- and dose-dependent, reversible increase in insulin binding sites in cultured chick embryo fibroblasts. Incubation of fibroblasts with 0.2 mM dibucaine for 3 h at 37°C results in a twofold to threefold increase in insulin binding, with an increase in average number of binding sites (K_a = 3.0 × 10⁷M^?1) from 9 × 10³ to 29 × 10³ per cell. Trypsin or ethylenegly coltetraacetic acid (EGTA) alone increases insulin binding twofold to threefold, but fails to further increase ¹²⁵I-insulin binding in cells pretreated with dibucaine. Transformation of chick embryo fibroblasts with Rous sarcoma virus causes a threefold to fivefold increase in insulin binding, which is not further increased by incubation with dibucaine. As demonstrated by transmission electron microscopy, dibucaine and trypsin also induce changes in the cytoskeleton of chick embryo fibroblasts, characterized by disorganization and disappearance of microfilament and microtubule bundles. These alterations are accompanied by gross morphologic changes, including rounding of cells and appearance of numerous ruffles and blebs on the cell surface. These observations are consistent with the hypothesis that expression of surface receptors in cultured chick embryo fibroblasts is related to the organization and disorganization of cytoskeletal structures.     

Changes in the surface morphology of normal and transformed mouse fibroblasts following disruption of cell-substrate adhesion]

By means of scanning electron microscopy surface morphology of cultured normal mouse embryo fibroblasts (MEF) and transformed mouse fibroblasts of L strain was studied in the course of alteration of cell-substrate adhesion with proteases, EDTA and urea. The morphology of cell rounding induced by the above agents in MEF and L cells was almost independent on the type of the agent. The rounding of MEF proceeded through three stages and was accompanied by substantial changes of cell surface relief. L cells lacked the intermediate stage (formation of thick processes) during their rounding which proceeded without any changes of cell surface relief. It is suggested that the observed differences are related to the poorer development of the lamelloplasm and microfilaments bundles in the transformed cells ascompared to the normal ones.     

Filament arrangements in negatively stained cultured cells: the organization of actin

Treatment of spread, cultured cells with Triton X-100 followed by negative staining reveals the organization of the unextracted intracellular filamentous elements: actin, microtubules and the 100 angstrom filaments. The present report describes the organization of the actin-like filaments in human skin fibroblasts and mouse 3 T 3 cells. As shown in earlier studies, the cytoplasmic stress fibres were seen to be composed of bundles of colinear actin-like filaments. In addition to these large stress fibres much smaller bundles of thin filaments as well as randomly oriented thin filaments were also observed. A thick bundle of thin filaments, 0.2 microm to 0.5 microm in diameter, was found to delimit the concave cell edges most prominent in well-spread stationary cells. The leading edge and ruffled border of human skin fibroblasts appeared as a broad web, of meshwork of diagonally oriented thin filaments interconnecting radiating, linear bundles of thin filaments about 0.1 microm in diameter. These bundles corresponding to the microspikes described earlier ranged from about 1.5 microm in length and were separated by 1 microm to 3 microm laterally. The leading edge of 3 T 3 cells showed a similar organization but with fewer radiating thin filament bundles. Both the filaments in the bundles and in the meshwork formed arrowhead complexes with smooth muscle myosin subfragment - 1 which were unipolar and directed towards the main body of the cell. The findings are discussed in relation to the mechanisms of non-muscle cell motility.     

Effect of microinjected amine and diamine oxidases on the ultrastructure of eukaryotic cultured cells

Diamine oxide and serum amine oxidase, which catalyse the oxidation of diamines and polyamines, respectively, were trapped within reconstituted Sendai virus envelopes. These loaded envelopes were incubated with cultured normal chick fibroblasts or with fibroblasts transformed by Rous sarcoma viruses. The binding of the reconstituted envelopes to the cultured cells was confirmed by scanning electron microscopy. It has been shown that the reconstituted envelopes (1-3 microns diameter) were attached to the eukaryotic cells. No significant changes in the morphology of the normal chick embryo fibroblasts were noted upon treatment with enzyme-loaded envelopes. On the other hand, chick embryo fibroblasts transformed by Rous sarcoma virus were affected by the microinjected amine oxidases. Scanning electron microscopy demonstrated the formation of holes in the microinjected cells. Similar morphological changes were also observed when diamine oxidase was microinjected into cultured glioma cells. These holes may be the result of the ejection of the nucleus. These findings are in line with the observed effect of the injected amine oxidases on macromolecular synthesis in normal and transformed chick embryo fibroblasts.     

Immunocytochemical localization of 140 kD cell adhesion molecules in cultured chicken fibroblasts, and in chicken smooth muscle and intestinal epithelial tissues

A monoclonal antibody (JG22 MAb) that was previously raised to a chick embryo myogenic cell preparation had been shown to produce rounding and other morphological changes in myogenic cells in culture, and, in some cases, their detachment from the substratum. In other studies it was shown that the epitope recognized by JG22 was associated with a set of 140 kD cell surface glycoproteins. It is shown that this antigen occurs in a wide variety of cell types; in cultured fibroblasts, it is distributed equally between the dorsal and ventral cell surfaces shortly after plating, but appears to become concentrated on the ventral surface as cell spreading proceeds; by immunoelectron microscopic labeling experiments, it is absent from the focal adhesion contact sites formed by fibroblasts with their substrata and with one another, but is present in clusters at the edge of focal adhesions, and within the close contact sites and extracellular matrix contact sites; in smooth muscle cells, it is absent from the membrane-associated dense plaques, but is located in clusters at adjacent membrane sites; in intestinal epithelium, it is present in clusters at the basolateral membranes, but not at the microvilli or within junctional complexes of the brush border of the cell layers. These and other results are consistent with the suggestion that the antigen recognized by JG22 MAb is important cell adhesion molecules, and performs a characteristic function in a variety of cell-cell contacts and cell adhesions.     

Effects of lectins on cytoskeleton and morphology or cultured chick embryo fibroblasts

The microfilaments and microtubules of cultured chick embryo skin fibroblasts were studied in the presence of exogenous lectins by an indirect immunofluorescence technique. Lectin treatment induced modifications in the arrangement of myosin, actin and tubulin, determined depolymerization of the proteins and caused changes in cell shape and size. The results suggest that the interaction between lectins and their specific membrane receptors triggers a series of changes in the cytoskeletal pattern via transmembrana as yet unknown mechanisms and that these are responsible for the alterations in cell shape and size.