Immunomorphological research on the formation of the extracellular matrix in epithelial cell cultures

Formation of extracellular matrix structures in cultures of rat liver epithelial nontransformed cell line IAR2 was studied with antisera to fibronectin, laminin and type IV collagen by immunofluorescence and immunoelectron microscopy of platinum replicas. Fibronectin formed peripheral spots of variable size some of which outlined free cell edges, as well as fibrils located towards the center of single cells or of cellular islands. Similarly distributed structures were seen in isolated matrices. Codistribution of fibronectin and actin was observed only for the peripheral line of fibronectin spots and marginal circular actin bundle. Basement membrane components. laminin and type IV collagen, formed mainly spots of variable size predominantly beneath the cell or each cell in an island. Occasional fibrils were seen also. Essentially the same results were obtained by immunofluorescence and immunogold electron microscopy. Cytochalasin D treated cells displayed spots of both fibronectin and laminin. The relevance of previously postulated receptor-mediated assembly of extracellular matrix structures to the epithelial cells is discussed.     

Factor VIII-related antigen : A pericellular matrix component of cultured human endothelial cells

We studied the extracellular localization of factor VIII-related antigen (VIIIR: Ag) in cultures of human endothelial cells. The cells deposited both VIIIR: Ag and fibronectin already during their initial adhesion phase and in immunofluorescence microscopy of spread cells extracellular VIIIR: Ag was localized to fibrils coaligning with pericellular fibronectin. When human fibroblasts, which do not synthesize VIIIR: Ag, were cultured in endothelial cell post-culture medium, a fibrillar matrix localization of VIIIR: Ag was seen, comparable to that of endothelial cell cultures. A fibrillar VIIIR: Ag-specific staining was also seen in cell-free pericellular matrices of endothelial cells, produced by deoxycholate treatment. In immunoelectron microscopy, VIIIR: Ag was seen in fibrillar extracellular material between and underneath the cells and in cell-free matrices of endothelial cells as well.In immunofluorescence microscopy of cell-free matrices, VIIIR: Ag codistributed with both fibronectin and type III procollagen. Digestion of the matrices with purified bacterial collagenase abolished the type III procollagen-specific fluorescence, whereas the fibrillar VIIIR: Ag-specific staining, codistributing with fibronectin, remained unaffected. In electrophoresis of isolated, metabolically labelled endothelial cell matrices, major polypeptides with M_r 220–240; 180; 160; 80 and 45 kD and some minor polypeptides were resolved. In addition, immunoblotting revealed fibronectin, VIIIR: Ag and type III procollagen as components of cell-free matrices of endothelial cells. Direct overlay of iodinated cellular fibronectin on electrophoretically separated polypeptides of cultured endothelial cells, transferred to nitrocellulose, suggested that fibronectin binds directly to VIIIR: Ag. Our results indicate that VIIIR: Ag produced by human endothelial cells is a component of the pericellular matrix and is not bound to collagen but may directly associate with fibronectin.     

Extracellular matrix fibers containing fibronectin and basement membrane heparan sulfate proteoglycan coalign with focal contacts and microfilament bundles in stationary fibroblasts

Double-label immunofluorescence microscopy and immunoelectron microscopy were performed on stationary cultures of Nil 8 fibroblasts to determine if fibronectin and basement membrane heparan sulfate proteoglycans play coordinated roles in cell-to-substrate adhesion. Relationships between subcellular matrix fibers containing fibronectin plus proteoglycan, and focal contacts associated with microfilament bundles, were studied simultaneously using interference reflection microscopy, differential interference contrast microscopy, and immunofluorescence microscopy. Cells maintained in 0.3% FBS were doubly stained with monospecific anti-fibronectin IgG and antibodies against a basement membrane proteoglycan purified from the EHS (Engelbreth-Holm-Swarm) tumor. Coincident patterns of fibronectin and proteoglycan-containing fibers were found to codistribute with focal contacts and microfilament bundles in both early (6-h) and late (24-h) cultures. The early cells showed doubly-stained fibers colinear with substrate adhesion sites in 43% of the sample, while 100% of the later cells exhibited these coaligned matrix-cytoskeletal attachment complexes. Immunoelectron microscopy showed that both of these antigens were situated in the same type of extracellular matrix fiber that appeared to be loosely associated with the cell surface membrane. We hypothesize that the appearance of proteoglycan in subcellular matrix fibers of these fibroblasts might stabilize fibronectin-containing cell-to-substrate contacts.     

Induction of fibronectin expression, actin cable formation, and entry into S phase following reexpression of T antigen in mouse macrophages transformed by the tsA640 mutant of SV40

Mouse macrophages transformed by a temperature-sensitive mutant (tsA640) of simian virus 40 (SV40) were examined by immunofluorescence microscopy for fibronectin expression and actin distribution. Resting cultures of tsA640 transformants incubated at a temperature nonpermissive for SV40 large T antigen (39.0 degrees C) exhibited phagocytic activity and did not exhibit cellular fibronectin and actin cables, like primary cultures of resident macrophages. When the resting cultures were sparsely seeded and shifted down to the permissive temperature of 33.0 degrees C, expression of large T antigen in the nucleus, expression of fibronectin in the cytoplasm, and cellular entry into S phase occurred in that temporal order, followed by actin cable formation, cellular proliferation, and diminishment of phagocytic activity. The expression of T antigen and fibronectin was sensitive to actinomycin D and cycloheximide. The expression of fibronectin was insensitive to inhibitors of DNA synthesis, whereas the expression of actin cables was sensitive. These results suggest that SV40 T antigen leads macrophages to express fibronectin and actin cables, as well as resumption of cell proliferation, and that entry into S phase is not required for fibronectin expression but may be required for actin cable formation.     

Rat hepatocytes in serum-free primary culture elaborate an extensive extracellular matrix containing fibrin and fibronectin

Adult rat hepatocytes cultured on type IV collagen, fibronectin, or laminin and maintained in serum-free medium were examined by indirect immunofluorescence using polyclonal antibodies against extracellular matrix proteins. An extensive fibrillar matrix containing fibronectin and fibrin was detected in all hepatocyte cultures irrespective of the exogenous matrix substratum used to support cell adhesion. Fibrils radiated from the cell periphery and covered the entire culture substratum. In addition, thicker fibers or bundles of fibers were localized on top of hepatocytes. This matrix did not contain laminin or the major types of collagen found in the liver biomatrix (types I, III, and IV). Isolation of the fibrillar matrix and analysis on polyacrylamide gels under reducing conditions demonstrated a major 58-kD polypeptide, derived from beta-fibrinogen as indicated by immunoblotting and two-dimensional peptide mapping. Plasmin rapidly dissolved the matrix. Deposition of the fibrin matrix in hepatocyte cultures was arrested by hirudin, by specific heparin oligosaccharides that potentiate thrombin inhibition by antithrombin III, and by dermatan sulfate, an activator of heparin cofactor II-mediated inhibition of thrombin. The results indicate that hepatocytes in culture synthesize and activate coagulation zymogens. In the absence of inhibitory and fibrinolytic mechanisms, a fibrin clot is formed by the action of thrombin on fibrinogen. Fibronectin attaches to this fibrin clot but fails to elaborate a fibrillar matrix on its own in the presence of coagulation inhibitors.     

Studies of fibronectin matrices in living cells with fluoresceinated gelatin

We have used fluorescein isosthiocyanate-conjugated gelatin (FITC- gelatin) (1 mg/ml) to localize cell surface fibronectin in unfixed live cells in cultures. FITC-gelatin stains the fibronectin matrix on primary cultures of rat and chick embryo fibroblasts as well as untransformed, established cell lines. In live cultured cells, fibronectin in many areas of the extracellular matrix is inaccessible to antibody and cannot be visualized by immunofluorescence staining. In contrast, fibronectin in these areas is fully stainable by FITC- gelatin. At a low concentration (20 micrograms/ml), FITC-gelatin stains the fibronectin matrix of primary cultured cells but not of "untransformed" established cell lines. SEM can detect only the matrix stainable with the low concentration of FITC-gelatin, such as that expressed by primary chick embryo fibroblasts. The binding of fibronectin to the extracellular matrix is very stable and FITC-gelatin remained bound to the matrix for at least 10 d in culture. Radioiodinated gelatin has been used to quantitate the level of cell surface fibronectin in living normal and transformed cells. FITC- gelatin appears to be a useful probe for studying the fibronectin of living cells in culture.     

Isolation of the pericellular matrix of human fibroblast cultures

The pericellular matrix of human fibroblast cultures was isolated, using sequential extraction with sodium deoxycholate and hypotonic buffer in the presence of protease inhibitor. The matrix attached to the growth substratum had a "sackcloth-like" structure as seen by phase contrast, immunofluorescence, and scanning electron microscopy, and it had a vaguely filamentous ultrastructure similar to that seen in intact cell layers. The matrix consisted of hyaluronic acid and heparan sulfate as the major glycosaminoglycan components and fibronectin and procollagen as major polypeptides as shown by metabolic labeling, gel electrophoresis, immunofluorescence, and collagenase digestion. This pericellular matrix can be regarded as an in vitro equivalent of the loose connective tissue matrix.     

Colocalization of laminin and fibronectin in bovinelens epithelial cells in vitro

Summary The distribution and organization of the extracellular matrix (ECM) proteins laminin, fibronectin, entactin, and type IV collagen were investigated in primary colonies and secondary cultures of bovine lens epithelial cells using species-specific antisera and indirect immunofluorescence microscopy. Primary cell colonies fixed in formaldehyde and permeabilized with Triton X-100 displayed diffuse clonies. In contrast, thick bundles of laminin and fibronectin were located on the basal cellsurfaces and in between cells in the densely packed center of the colonies, and as “adhesive plaques” and fine extracellular matrix cords in the sparsely populated (migratory) outer edge of the colonies. The distribution of ECM proteins observed in secondary lens epithelial cell cultures was similar to that observed at the periphery of the primary colony. Extraction of the secondary cell cultures with sodium deoxycholate confirmed that laminin and fibronectin were deposited on the basal cell surface. Indeed, the patterns of laminin and fibronectin deposition suggested that these proteins codistribute. These results establish that lens epithelial cells in culture can be used as a model system to study the synthesis and extracellular deposition of the basement membrane proteins, laminin and fibronectin. Supported by Public Health Service grant EY05570 from the National Eye Institute Bethesda, MD.     

Phagocytosis of gelatin-latex particles by a murine macrophage line is dependent on fibronectin and heparin

It has been suggested that fibronectin plays a role in clearing particles from the circulation by promoting binding to phagocytes of the reticuloendothelial system. By use of a well-defined system to investigate the possible opsonic role of fibronectin, we have studied the uptake of gelatin-coated latex particles by a murine macrophage cell line (P388D1). Fibronectin promotes binding of gelatin-coated beads to these cells in both suspension and monolayer cultures. In both cases there is a requirement for heparin as a cofactor. Other glycosaminoglycans (chondroitin sulfates A and C, dermatan sulfate, and keratan sulfate) were inactive, whereas heparan sulfate was somewhat active. Proof that beads were actually endocytosed was obtained by electron microscopy, which showed beads internalized in membrane- bounded vesicles, and by immunofluorescence analyses, using antibodies to fibronectin to stain external beads. Two rapid assays for the opsonic activity of fibronectin were developed based on differential centrifugation of cell-associated beads and on the immunofluorescence procedure. Binding and endocytosis were time- and temperature-dependent and varied with the amount of gelatin on the beads and with the concentrations of fibronectin and heparin added, and could be inhibited by F(ab')2 antifibronectin. These studies provide a sound basis for a detailed analysis of the interaction of fibronectin with the cell surface and of its involvement in endocytosis.     

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.     

Neuronal differentiation in F9 embryonal carcinoma cells

F9 line embryonal carcinoma cells were induced to differentiate into neural direction by long-term treatment of monolayer cultures with retinoic acid and dibutyryl cyclic AMP. Bi- and multi-polar cells appeared, expressing acetylcholinesterase and neurofilament proteins but not markers of glial differentiation including GFA-protein. Nerve growth factor combined with both retinoic acid and dibutyryl cyclic AMP greatly enhanced the development of neuron-like morphology and induced expression of immunoreactivity to tyrosine hydroxylase as well as to Leu-encephalin-like peptides. Similarly, serotonin-like immunofluorescence but not substance P-like immunoreactivity was demonstrable in such cultures. In addition, synaptic-like vesicles were often found in the processes. Analysis of matrix expression in neuronally differentiated F9 cells revealed marked increase in laminin production, as judged by immunofluorescence and immuno-electron microscopy, but no demonstrable intracellular staining for fibronectin or type IV collagen. The results with neuronal cells contrast with the expression of all the three matrix components in endodermally differentiating F9 cells in the same cultures.     

Plasma fibronectin is synthesized and secreted by hepatocytes

Primary cultures of hepatocytes of rats and hamsters were established and examined for the synthesis and secretion of fibronectin. Hepatocytes of both species secreted fibronectin as a soluble dimeric protein which could be purified by its affinity for gelatin and using specific antisera. Plasma and cellular fibronectins could be clearly resolved on two-dimensional gels. In both species, the majority of the fibronectin secreted by hepatocytes was of the plasma type, as shown by analyses on one- and two-dimensional gels. The secretion of plasma fibronectin increased with time in culture, both in absolute terms and relative to the secretion of albumin. Even during the first day of culture, the secretion of fibronectin relative to that of albumin appeared to be sufficient to account for the relative levels of these two proteins in plasma. Hepatocytes of both species secreted preferentially the chain of plasma fibronectin with higher apparent molecular weight, although the faster migrating chain was also secreted. In addition, hamster hepatocytes cultured for 2 or more days appeared to secrete a cellular form of fibronectin. Possible origins for the different chain types of cellular and plasma fibronectins are discussed.     

Distribution of a major surface-associated glycoprotein,fibronectin, in cultures of adherent cells

Fibronectin was present in media and cell layers of cultures of adherent cells from human skin, kidney, lung, chest wall, liver, and heart. Cell-surface fibronectin, visualized by immunofluorescence, was in dense fibrillar (cultures from lung), discrete fibrillar (e.g., cultures from skin), or punctate (some cultures from kidney) structures. The subunit sizes of cell-surface fibronectin and fibronectin soluble in medium appeared identical in sodium dodecyl sulfate-polyacrylamide gels. To explain the polymorphism of cell-surface fibronectin, there must be chemical differences among the fibronectins synthesized by different cell strains or factors in the cell layer which influence fibronectin binding and aggregation.     

Growth and functional activities of neonatal and adult rat hepatocytes cultured on fibronectin coated substratum in serum-free medium

Hepatocytes isolated from neonatal (NN) and adult (AD) rats were seeded on fibronectin coated substratum and cultured in arginine-free medium supplemented with various combinations of insulin, dexamethasone, triiodothyronine (T3), albumin, and transferrin, in presence or absence of fibronectin depleted serum (FDS). The main finding is that in response to certain hormone mixtures, both NN and AD hepatocytes can be stimulated to proliferate, as revealed by an increase in cell number, a [3H]thymidine incorporation into nuclei, and extractable DNA as well as the appearance of mitotic figures. Moreover, this proliferative activity is associated with changes in hepatocyte ploidy. However, the proliferative response of NN hepatocytes to hormone action is much different from that of AD hepatocytes, and the addition of FDS amplifies this activity in NN but inhibits it in AD hepatocyte cultures. Measurements of tyrosine aminotransferase and lactate dehydrogenase activities indicate a good preservation of NN and AD hepatocyte functional integrity under certain culture conditions. A good maintenance of albumin production in NN and AD hepatocyte cultures requires the presence of dexamethasone, whereas the alpha-fetoprotein production in NN hepatocyte cultures is reduced quite rapidly under most conditions. No alpha-fetoprotein is detectable in AD hepatocyte cultures.     

Formation of bile canaliculi in long-term primary cultures of adult rat hepatocytes on permeable membrane: an ultrastructural study

Adult rat hepatocytes were cultured for 15 days on type I collagen-coated permeable membranes in a hormonally defined Waxman's modified medium supplemented with very low concentrations of insulin, glucagon and dexamethasone. Phase contrast examination showed that 15-day-old cultures still formed a regular monolayer of polygonal cells. In similarly aged cultures, intracellular glycogen was abundant and evenly distributed, while steatosis remained very limited. Scanning and transmission electron microscopy showed that well developed bile canaliculi could be observed on the lateral side of the hepatocyte membrane after 4 days of incubation and persisted for 2 weeks. These canalicular structures probably originated from coalescence of membrane invaginations observed in 1-day-old cultures. Transmission electron microscopy showed that the ultrastructure of the cells was very close to that of normal rat hepatocytes in the intact liver. These results suggest that rat hepatocytes cultured under these experimental conditions are able to develop and maintain tissue-specific cytochemical and morphological properties for at least 15 days.     

Extracellular matrix microfibrils are composed of core proteins coated with fibronectin

Extracellular proteins of cultured calf aortic smooth muscle cells consist predominantly of microfibrils 10-20 nm in diameter typical of "elastin-associated" microfibrils described in many tissues. Chemical and immunochemical evidence is presented that microfibrils consist of at least two proteins: core protein and fibronectin. Insoluble proteins of the microfibrils were obtained in the form of a pellet and antibodies raised in rabbits against these components. The antisera reacted with the insoluble microfibrillar proteins and with soluble fibronectin in enzyme-linked immunosorbent assay, and immunostained the extracellular microfibrils in cultured cells. An immunoglobulin (Ig) fraction was prepared and absorbed with fibronectin. The absorbed IgG retained its reactivity with the microfibrillar proteins but was no longer reactive with soluble fibronectin. Immunofluorescence studies were carried out using the absorbed IgG and IgG to soluble fibronectin. Both antibodies showed immunoreactive microfibrils in the extracellular matrix of cells in log phase. However, with increasing time in culture, as the cells reached confluence, the immunofluorescence of microfibrils reacting with the absorbed IgG became less intense, whereas that of microfibrils reacting with IgG to fibronectin increased; in confluent cells, essentially no staining was detected with the absorbed IgG, and a dense network of intensely stained microfibrils was seen with IgG to fibronectin. Treatment of these cultures with urea led to partial dissociation of the fibronectin and increased visualization of the microfibrils with the absorbed IgG; double-label immunofluorescence showed that both proteins occurred on the same microfibrils. The localization of immunoreactive sites to the extracellular microfibrils was confirmed by immunoelectron microscopy. Nearly quantitative cleavage with CNBr failed to dissociate the antigenically active fragments of fibronectin from the CNBr fragments of the core proteins of the microfibrils. It was concluded that microfibrils contain core proteins and fibronectin that are codistributed in insoluble, possibly covalently cross-linked, aggregates. The core proteins are first deposited by the cell and, as a function of time in culture, fibronectin gradually coats their surface.     

Rapid isolation of metaphase chromosomes containing high molecular weight DNA

Normal rat kidney cells were cultured in medium supplemented with normal fetal bovine serum (FBS) or FBS depleted of fibronectin. The cell surface fibronectin of these cultures was visualized by indirect immunofluorescence using species-specific antisera for either rat fibronectin or bovine fibronectin. Anti-rat-fibronectin revealed fibrillar structures on the cells grown in either normal medium or fibronectin-depleted medium. Anti-bovine fibronectin revealed similar fibrillar networks, but only on the cells grown in medium containing bovine fibronectin. Staining in each case was abolished by absorption with the homologous antigen. It appears that exogenous fibronectin was incorporated into the same structures as endogenous fibronectin. This finding suggests that circulating fibronectin may serve as a building block for the assembly of extracellular matrix, possibly by cells which are incapable of synthesizing it.     

Fibronectin associated with the glial component of embryonic brain cell cultures

In a basic approach to investigations of neuronal–glial interactions during both normal brain development and its pathogenesis, embryonic brain cell populations were fractionated into purified neuronal and glial components. Using separation procedures based on differential adhesion and cytotoxicity, the isolated neuronal and glial phenotypes could be identified by distinct morphological and biochemical characteristics, including the visualization of glial fibrillary acid protein (GFA) within glial cells in immunohistochemical assays with monospecific anti-GFA serum. When unfractionated cerebrum cells dissociated from 10-day chick or 14-day mouse embryos were plated as monolayers and cultured for 1-14 days, monospecific antiserum against fibronectin (LETS glycoprotein) was found to react with many, but not all, of the cells as revealed by indirect immunofluorescence microscopy. The isolated neuronal and glial components of these populations were used to determine whether the appearance of membrane-associated fibronectin was characteristic of one cell type or the other, or both, and if neuronal–glial cell interaction was required for its expression. It was found that the surfaces of glial cells, completely isolated from neurons, showed an intense fluorescent reaction to the anti-fibronectin serum. In contrast, the purified neuronal cultures showed no fluorescence with either the anti-GFA or anti-fibronectin sera. These results demonstrate fibronectin as a cell surface protein associated primarily with glial cells and independent of neuronal–glial cell interaction for its expression. Furthermore, the results indicate that the fibronectin observed on glial cell surfaces in these cultures is produced endogenously and is not due to the preferential binding of fibronectin present in the culture medium. The role of fibronectin as an adhesive molecule in neuronal–glial interactions is discussed.