Role of fibronectin in collagen deposition: Fab' to the gelatin-binding domain of fibronectin inhibits both fibronectin and collagen organization in fibroblast extracellular matrix

We report the effect of Fab' (anti-60k) to a 60,000 mol wt gelatin binding domain of fibronectin (1981, J. Biol. Chem. 256:5583) on diploid fibroblast (IMR-90) extracellular fibronectin and collagen organization. Anti-60k Fab' did not inhibit IMR-90 attachment or proliferation in fibronectin-depleted medium. Fibroblasts cultured with preimmune Fab' deposited a dense extracellular network of fibronectin and collagen detectable by immunofluorescence, while anti-60k Fab' prevented extracellular collagen and fibronectin fibril deposition. Matrix fibronectin and collagen deposition remained decreased in cultures containing anti-60k Fab' until cells became bilayered or more dense, when fibronectin and collagen began to appear in lower cell layers. Anti-60k Fab' added to confluent cultures 24 h before fixation and staining had no effect on matrix fibronectin or collagen, so anti- 60k Fab' did not simply block immunostaining. Confluent cultures grown in anti-60k Fab' and labeled for 24 h with [3H]proline incorporated identical amounts of [3H]proline and [3H]hydroxyproline, but [3H]hydroxyproline deposition in the cell layer was significantly decreased by anti-60k Fab' (P less than 0.01). Extracellular matrix collagen does not appear to form a scaffold for fibronectin deposition, as neither gelatin nor a gelatin-binding fragment of plasma fibronectin inhibited deposition of matrix fibronectin. Our results suggest that interstitial collagens and fibronectin interact to form a fibrillar component of the extracellular matrix, and that fibronectin is required for normal collagen organization and deposition by fibroblasts in vitro. Domain-specific antibodies to fibronectin are powerful tools to study the biological role of fibronectin in extracellular matrix organization and other processes.     

Endothelial Matrix Assembly during Capillary Morphogenesis: Insights from Chimeric TagRFP-Fibronectin Matrix

Biologically relevant, three-dimensional extracellular matrix is an essential component of in vitro vasculogenesis models. WI-38 fibroblasts assemble a 3D matrix that induces endothelial tubulogenesis, but this model is challenged by fibroblast senescence and the inability to distinguish endothelial cell-derived matrix from matrix made by WI-38 fibroblasts. Matrices produced by hTERT-immortalized WI-38 recapitulated those produced by wild type fibroblasts. ECM fibrils were heavily populated by tenascin-C, fibronectin, and type VI collagen. Nearly half of the total type I collagen, but only a small fraction of the type IV collagen, were incorporated into ECM. Stable hTERT-WI-38 transfectants expressing TagRFP-fibronectin incorporated TagRFP into ~90% of the fibronectin in 3D matrices. TagRFP-fibronectin colocalized with tenascin-C and with type I collagen in a pattern that was similar to that seen in matrices from wild type WI-38. Human Umbilical Vein Endothelial Cells (HUVEC) formed 3D adhesions and tubes on WI38-hTERT-TagRFP-FN-derived matrices, and the TagRFP-fibronectin component of this new 3D human fibroblast matrix model facilitated the demonstration of concentrated membrane type 1 metalloprotease and new HUVEC FN and collagen type IV fibrils during EC tubulogenesis. These findings indicate that WI-38-hTERT- and WI-38-hTERT-TagRFP-FN-derived matrices provide platforms for the definition of new matrix assembly and remodeling events during vasculogenesis.     

Cartilage oligomeric matrix protein is overexpressed by scleroderma dermal fibroblasts.

Cartilage oligomeric matrix protein (COMP) is an extracellular glycoprotein that belongs to the thrombospondin gene family. It is found predominantly in cartilage, tendon, ligament, and bone. Mutations in the COMP gene have been linked to the development of pseudoachondroplasia and multiple epiphysial dysplasia. COMP influences the organization of collagen fibrils by interacting with collagens I, II and IX. Gene expression profiling of cultured skin fibroblasts suggested that COMP mRNA levels were elevated in scleroderma. We therefore examined COMP expression in SSc and normal skin biopsies. Immunohistochemistry confirmed that COMP protein accumulates in SSc but not normal skin, with SSc skin showing striking deposition in the papillary and deeper dermis. Significant staining was also seen in non-lesional skin from patients. Due to its involvement in the development of fibrosis, TGFbeta was examined for a possible role in regulating COMP expression. Cultured SSc fibroblasts demonstrated greater staining for COMP compared to normal controls prior to stimulation, and TGFbeta-1 induced a large increase in mRNA and protein. Murine fibroblasts engineered to overexpress human COMP demonstrated increased levels of fibronectin and collagen in the extracellular matrix. Taken together, these data demonstrate that COMP is overexpressed in SSc skin and cultured fibroblasts possibly due to autocrine TGFbeta stimulation, and COMP overexpression is sufficient to stimulate excess matrix deposition. By interactions with other matrix proteins and cells, COMP may play a role in pathogenic matrix deposition.     

Extracellular matrix regulates induction of alkaline phosphatase expression by ascorbic acid in human fibroblasts

During wound healing and inflammation, fibroblasts express elevated alkaline phosphatase (ALP), but are not in contact with collagen fibrils in the fibronectin (FN)-rich granulation tissue. We hypothesized that the extracellular matrix (ECM) environment might influence the induction of ALP in fibroblasts. Here we tested this hypothesis by studying the ALP-inductive response of normal human gingival fibroblasts to ascorbic acid (AsA). AsA induced ALP activity and protein in cells in conventional monolayer culture. This induction was inhibited by blocking-antibodies to the FN receptor alpha 5 beta 1 integrin and by the proline analog 3,4-dehydroproline (DHP). DHP prevented cells from arranging FN fibrils into a pericellular network and reduced the activity of cell spreading on FN. Plating of cells on FN facilitated the up-regulation by AsA of ALP expression, but did not substitute for AsA. In contrast, AsA did not cause ALP induction in cells cultured on and in polymerized type I collagen gels. Collagen fibrils inhibited the up-regulation by AsA of ALP expression in cells plated on FN. These results indicate that the ECM regulates the induction of ALP expression by AsA in fibroblasts: FN enables them to express ALP in response to AsA through interaction with integrin alpha 5 beta 1, whereas type I collagen fibrils cause the suppression of ALP expression and overcome FN.     

Regulation of collagen VI expression in fibroblasts. Effects of cell density, cell-matrix interactions, and chemical transformation

Collagen VI expression was studied in cultured human skin fibroblasts and mouse 3T3 cells using cDNA probes specific for alpha 1(VI), alpha 2(VI), and alpha 3(VI) chains. A 2-3-fold increase of these mRNAs was observed when fibroblasts were grown at increasing densities while only minimal changes occurred for the mRNA levels of collagens I and III, fibronectin, and beta-actin. Changes in mRNA correlated well with an increased production of corresponding proteins as determined by immunological assays. A comparable increase of alpha 1(VI) and alpha 2(VI) but not of alpha 3(VI) chain mRNAs was found for fibroblasts grown in a three-dimensional collagen gel after gel contraction. These conditions resulted, however, in a decrease of steady-state levels of collagens I and III and actin mRNAs. Transformation of 3T3 cells by phorbol ester did not change collagen VI mRNAs but caused a 3-5-fold reduction in mRNA levels for the other extracellular matrix proteins. These data strongly imply different regulatory mechanisms for the expression of collagen VI compared with collagens I and III and fibronectin. The differences may be correlated to changes in cell shape and reflect the requirement for collagen VI as a cell-binding protein.     

Ultrastructural defects of collagen VI filaments in an Ullrich syndrome patient with loss of the alpha3(VI) N10-N7 domains

Ultrastructural alterations of collagen VI in cultured fibroblasts and reduced collagen VI immunostaining in the papillary dermis and endomysium were detected in a patient with a mild form of Ullrich congenital muscular dystrophy caused by a COL6A3 gene mutation. The patient had been previously demonstrated to express an alpha3(VI) chain shorter than normal due to skipping of the mutated exon. We show that collagen VI filaments are not organized in a normal network in the extracellular matrix secreted by patient's cultured fibroblasts. Moreover, we demonstrate that in this patient the alpha3(VI) chain is produced in lower amounts and it is almost exclusively represented by the shorter, alternatively spliced N6-C5 isoform. These results suggest that different alpha3(VI) chain isoforms, containing also domains of the N10-N7 region, are required for assembling a proper collagen VI network in the extracellular matrix.     

Interactions of Human Skin Fibroblasts with Monomeric or Fibrillar Collagens Induce Different Organization of the Cytoskeleton

Fibrillar collagens represent the most abundant extracellular matrix components surrounding fibroblasts. Although there is a large heterogeneity in the collagen composition and in the physiological functions of different tissues, interactions between cells and native collagens monomers are mediated by only two integrins, the α1β1 and α2β1 integrins. In tissue, fibroblasts are exposed to collagen polymers, supramolecular assemblies which might play a role on the availability of the cell-binding sites at the surface of the fibrils. We have addressed this issue by investigating the patterns of adhesion structures in normal human skin fibroblasts exposed to collagen monomers or polymers. Our results showed that cell morphology, cell adhesion pattern, actin organization, and distribution of integrin subunits, talin, vinculin, and phosphotyrosine-containing proteins are dependent on the supramolecular organization of the collagens. In particular, compared to monomers, collagen polymers induced a looser organization of the actin network and a linear clustering of integrins, talin, vinculin, and phosphotyrosine-containing proteins. These results emphasize the role of the physical state of collagen on cellular interactions and underline the role of the extracellular matrix in the phenotypic modulation of fibroblasts. Furthermore, our studies suggest the existence of a local heterogeneity in the biological activity of collagen fibrils.     

Co-assembly of plasma and cellular fibronectins into fibrils in human fibroblast cultures

Exogenous plasma and endogenous cellular fibronectins on the surface of cultured fibroblasts and in extracellular matrix fibrils were colocalized by fluorescent and high voltage immunoelectron microscopy. Fibroblast cultures grown in the presence or absence of cycloheximide were incubated with exogenous plasma fibronectin labeled with fluorescein isothiocyanate. A monoclonal antibody specific for the EIIIA sequence of cellular fibronectin was used to detect cellular fibronectin. A rabbit antifluorescein antibody identified fluoresceinated plasma fibronectin. In cultures incubated in the presence of cycloheximide, plasma fibronectin was bound to the cell surface and was assembled into extracellular fibrils. In cultures grown in the absence of cycloheximide, plasma and cellular fibronectins were observed in the same matrix fibrils and in the same locations on the cell surface. There was not, however, random admixture of the two proteins.     

Deposition and ultrastructural organization of collagen and proteoglycans in the extracellular matrix of gel-cultured fibroblasts

Human skin fibroblasts were cultivated within the three-dimensional space of polymerized alginate and collagen, respectively. The in vitro synthesis of collagens and proteoglycans was measured during the first 3 days of culture, and the deposition as well as the ultrastructural organization of newly synthesized extracellular matrix components were examined by electron microscopy. The amount of collagens and proteoglycans synthesized by fibroblasts, embedded in calcium alginate gels as well as in collagen lattices, was lowered as compared to monolayer cultures. Furthermore, it was found that collagen synthesis was reduced to a greater extent in alginate gels than in collagen lattices. On the contrary, total proteoglycan biosynthesis was similarly reduced either in alginate gels or in collagen lattices. At the end of a 3-day-culture period, filamentous material as well as cross-striated banded structures were found extracellularly in the alginate gel. According to their periodicity, their banding pattern, their association with polyanionic matrix components and their sensitivity towards glycosaminoglycan-degrading enzymes we could distinguish (1) sheets of amorphous non-banded material consisting of irregularly arranged filaments and containing dermatan sulfate-rich proteoglycans (type I structures), (2) sheets of long-spacing fibrils consisting of parallel orientated filaments and containing chondroitin sulfate-rich proteoglycans (= zebra bodies; type II structures), and (3) fibrillar structures with a complex banding pattern different from that of native collagen fibrils (type III structures). In fibroblasts cultured in collagen lattices, we only sporadically found depositions which are identified as type I structures. Using indirect immunoelectron microscopy and monospecific polyclonal antibodies, we localized type VI collagen in type I structures and type II structures. Type III structures can be identified as type I collagen derived as becomes obvious by comparison with segment long spacing crystallites of type I collagen.     

An axial periodic fibrillar arrangement of antigenic determinants for fibronectin and procollagen on ascorbate treated human fibroblasts

Fibronectin and collagens are major constituents of the cell matrix of fibroblasts. Fibronectin is a 220,000 dalton glycoprotein that mediates a variety of adhesive functions of cells examined in vitro. Fibronectin is secreted in a soluble form and interacts with collagen to form extracellular filaments. Fibronectin and procollage type I were localized using the peroxidase anti-peroxidase method. Under standard culture conditions, fibronectin and procollagen were localized to non-periodic 10 nm extracellular fibrils, the cell membrane and plasma membrane vesicles. Ascorbate treatment of cells leads to a new larger fibril with a diameter of approximately 40 nm. Antibodies to fibronectin and procollagen I react to these native collagen fibrils with an axial periodicity of approximately 70 nm. Fibronectin is clearly associated with native collagen fibrils produced by ascorbate treated cells and there is an asymetric distribution or segregation of fibronectin on these collagen fibrils with a 70 nm axial repeat.     

Isolation and characteristics of the extracellular matrix of cultured cells

Sodium deoxycholate extraction was used to isolate extracellular matrix from various cultured cells: human and murine embryonic fibroblasts, epithelial lines of mouse (MPTR), rat (IAR 2 and IAR 20), pig (SPEV) and cow (FBT). Protein composition of the matrix was studied by sodium dodecyl sulfate polyacrylamide gel electrophoresis and immunofluorescence. The matrix morphology was investigated by scanning electron microscopy. In cell lines FBT and MPTR the major component of the matrix was laminin, whereas in other lines and fibroblasts it was fibronectin. The matrix of the majority of lines had a fibrillar structure, and the fibrils usually formed networks. MPTR cells had a punctate matrix composed of laminin and collagen type IV, densely covering the substratum. The treatment of the matrix by hyaluronidase and/or DNAase I did not influence its protein composition. The isolated matrix of different structure and composition may serve a biological substratum in studies of normal tumor cell behavior in tissue culture.     

Opposing effects of collagen I and vitronectin on fibronectin fibril structure and function

Extracellular matrix fibronectin fibrils serve as passive structural supports for the organization of cells into tissues, yet can also actively stimulate a variety of cell and tissue functions, including cell proliferation. Factors that control and coordinate the functional activities of fibronectin fibrils are not known. Here, we compared effects of cell adhesion to vitronectin versus type I collagen on the assembly of and response to, extracellular matrix fibronectin fibrils. The amount of insoluble fibronectin matrix fibrils assembled by fibronectin-null mouse embryonic fibroblasts adherent to collagen- or vitronectin-coated substrates was not significantly different 20 h after fibronectin addition. However, the fibronectin matrix produced by vitronectin-adherent cells was ~ 10-fold less effective at enhancing cell proliferation than that of collagen-adherent cells. Increasing insoluble fibronectin levels with the fibronectin fragment, anastellin did not increase cell proliferation. Rather, native fibronectin fibrils polymerized by collagen- and vitronectin-adherent cells exhibited conformational differences in the growth-promoting, III-1 region of fibronectin, with collagen-adherent cells producing fibronectin fibrils in a more extended conformation. Fibronectin matrix assembly on either substrate was mediated by α5β1 integrins. However, on vitronectin-adherent cells, α5β1 integrins functioned in a lower activation state, characterized by reduced 9EG7 binding and decreased talin association. The inhibitory effect of vitronectin on fibronectin-mediated cell proliferation was localized to the cell-binding domain, but was not a general property of αvβ3 integrin-binding substrates. These data suggest that adhesion to vitronectin allows for the uncoupling of fibronectin fibril formation from downstream signaling events by reducing α5β1 integrin activation and fibronectin fibril extension.     

Collagen fibril assembly by corneal fibroblasts in three-dimensional collagen gel cultures: small-diameter heterotypic fibrils are deposited in the absence of keratan sulfate proteoglycan.

Extracellular matrix assembly is a multistep process and the various steps in collagen fibrillogenesis are thought to be influenced by a number of factors, including other noncollagenous matrix molecules. The synthesis and deposition of extracellular matrix by corneal fibroblasts grown within three-dimensional collagen gel cultures were examined to elucidate the factors important in the establishment of tissue-specific matrix architecture. Corneal fibroblasts in collagen gel cultures form layers and deposit small-diameter collagen fibrils (approximately 25 nm) typical of the mature corneal stroma. The matrix synthesized contains type VI collagen in a filamentous network and type I and type V collagen assembled as heterotypic fibrils. The amount of type V collagen synthesized is relatively high and comparable to that seen in the corneal stroma. This matrix is deposited between cell layers in a manner reminiscent of the secondary corneal stroma, but is not deposited as densely or as organized as would be found in situ. No keratan sulfate proteoglycan, a proteoglycan found only in the corneal stroma, was synthesized by the fibroblasts in the collagen gel cultures. The assembly and deposition of small-diameter fibrils with a collagen composition and structure identical to that seen in the corneal stroma in the absence of proteoglycans typical of the secondary corneal stroma imply that although proteoglycan-collagen interactions may function in the establishment of interfibrillar spacing and lamellar organization, collagen-collagen interactions are the major parameter in the regulation of fibril diameter.     

Micro-heterogenous expression of peanut agglutinin-binding sites in the extracellular matrix of cultured cells

Using double-label techniques with fluorochrome-conjugated peanut agglutinin (PNA) and indirect immunofluorescence with rabbit species-specific anti-fibronectin antibodies and a mouse monoclonal anti-fibronectin, the extracellular matrix (ECM) of cultured human and mouse fibroblasts (Hell7 and 3T3K) and human bladder epithelial cells (T24) was studied. The antibodies and PNA co-localized extensively. However, a small but consistent degree of micro-heterogeneity was revealed insofar as both PNA-positive fibronectin-negative fibrils as well as PNA-negative fibronectin-positive fibrils were observed. Fibronectin production by T24 cells (but not fibroblasts) was influenced by the growth medium, but this did not affect the heterogeneity. Trypsin removed most cell-surface fibronectin and all PNA-binding sites, but did not account for the observed phenomenon. Intracellular fibronectin, whether present naturally or induced to accumulate by culture in presence of Monensin, was PNA-negative. These data suggest that PNA-binding sites appear on fibronectin as a consequence of incorporation into the extracellular matrix, and that the resultant heterogeneity of spatial expression of beta-galactose-like residues may offer a mechanism whereby mesenchymal cells could modulate the behaviour of overlying cell-types.     

The Effects of Age and the Expression of SPARC on Extracellular Matrix Production by Cardiac Fibroblasts in 3-D Cultures

Fibrillar collagen is the primary component of the cardiac interstitial extracellular matrix. This extracellular matrix undergoes dramatic changes from birth to adulthood and then into advanced age. As evidence, fibrillar collagen content was compared in sections from neonates, adult, and old hearts and was found to increase at each respective age. Cardiac fibroblasts are the principle cell type that produce and control fibrillar collagen content. To determine whether fibroblast production, processing, and deposition of collagen differed with age, primary cardiac fibroblasts from neonate, adult, and old mice were isolated and cultured in 3-dimensional (3D) fibrin gels. Fibroblasts from each age aligned in fibrin gels along points of tension and deposited extracellular matrix. By confocal microscopy, wild-type neonate fibroblasts appeared to deposit less collagen into fibrillar structures than fibroblasts from adults. However, by immunoblot analysis, differences in procollagen production and processing of collagen I were not detected in neonate versus adult fibroblasts. In contrast, fibroblasts from old mice demonstrated increased efficiency of procollagen processing coupled with decreased production of total collagen. SPARC is a collagen-binding protein previously shown to affect cardiac collagen deposition. Accordingly, in the absence of SPARC, less collagen appeared to be associated with fibroblasts of each age grown in fibrin gels. In addition, the increased efficiency of procollagen alpha 1(I) processing in old wild-type fibroblasts was not detected in old SPARC-null fibroblasts. Increased levels of fibronectin were detected in wild-type neonate fibroblasts over that of adult and old fibroblasts but not in SPARC-null neonate fibroblasts versus older ages. Immunostaining of SPARC overlapped with that of collagen I but not to that of fibronectin in 3D cultures. Hence, whereas increases in procollagen processing, influenced by SPARC expression, plausibly contribute to increased collagen deposition in old hearts, other cellular mechanisms likely affect differential collagen deposition by neonate fibroblasts.     

Corneal cell-matrix interactions: type VI collagen promotes adhesion and spreading of corneal fibroblasts.

Type VI collagen is a nonfibrillar collagen present as a network throughout the chick secondary stroma. Immunolocalization of type VI collagen both in the chick corneal stroma and in other systems demonstrates that type VI collagen is present associated with cells and between striated fibrils. We hypothesize that type VI collagen may function in cell-matrix interactions important in corneal development. To examine this possibility, we have isolated and characterized bovine corneal type VI collagen and determined that the chain composition and morphology of type VI collagen isolated from cornea is similar to that isolated from other sources. The tissue form of type VI collagen was localized to filaments forming a network around fibrils and close to corneal fibroblasts. We then analyzed relative attachment and spreading on type VI collagen as compared to the other collagens present in the secondary stroma, and found that although corneal fibroblasts attach equally well to type VI and type I collagen, cells spread to a much greater extent on type VI collagen. Although corneal fibroblasts do have an RGD-dependent receptor which functions during adhesion to fibronectin, attachment to type VI collagen is RGD-independent unless the molecule is denatured. Blocking of the RGD-dependent receptor with soluble RGD peptides results in no change in attachment or spreading. These data imply a role for type VI collagen in cell-matrix interactions during corneal stroma development.     

A Role for Topographic Cues in the Organization of Collagenous Matrix by Corneal Fibroblasts and Stem Cells

Human corneal fibroblasts (HCF) and corneal stromal stem cells (CSSC) each secrete and organize a thick stroma-like extracellular matrix in response to different substrata, but neither cell type organizes matrix on tissue-culture polystyrene. This study compared cell differentiation and extracellular matrix secreted by these two cell types when they were cultured on identical substrata, polycarbonate Transwell filters. After 4 weeks in culture, both cell types upregulated expression of genes marking differentiated keratocytes (KERA, CHST6, AQP1, B3GNT7). Absolute expression levels of these genes and secretion of keratan sulfate proteoglycans were significantly greater in CSSC than HCF. Both cultures produced extensive extracellular matrix of aligned collagen fibrils types I and V, exhibiting cornea-like lamellar structure. Unlike HCF, CSSC produced little matrix in the presence of serum. Construct thickness and collagen organization was enhanced by TGF-ß3. Scanning electron microscopic examination of the polycarbonate membrane revealed shallow parallel grooves with spacing of 200–300 nm, similar to the topography of aligned nanofiber substratum which we previously showed to induce matrix organization by CSSC. These results demonstrate that both corneal fibroblasts and stromal stem cells respond to a specific pattern of topographical cues by secreting highly organized extracellular matrix typical of corneal stroma. The data also suggest that the potential for matrix secretion and organization may not be directly related to the expression of molecular markers used to identify differentiated keratocytes.     

Extracellular matrix organization modulates fibroblast growth and growth factor responsiveness

To learn more about the relationship between extracellular matrix organization, cell shape, and cell growth control, we studied DNA synthesis by fibroblasts in collagen gels that were either attached to culture dishes or floating in culture medium during gel contraction. After 4 days of contraction, the collagen density (initially 1.5 mg/ml) reached 22 mg/ml in attached gels and 55 mg/ml in floating gels. After contraction, attached collagen gels were well organized; collagen fibrils were aligned in the plane of cell spreading; and fibroblasts had an elongated, bipolar morphology. Floating collagen gels, however, were unorganized; collagen fibrils were arranged randomly; and fibroblasts had a stellate morphology. DNA synthesis by fibroblasts in contracted collagen gels was suppressed if the gels were floating in medium but not if the gels were attached, and inhibition was independent of the extent of gel contraction. Therefore, growth of fibroblasts in contracted collagen gels could be regulated by differences in extracellular matrix organization and cell shape independently of extracellular matrix density. We also compared the responses of fibroblasts in contracted collagen gels and monolayer culture to peptide growth factors including fibroblast growth factor, platelet-derived growth factor, transforming growth factor-beta, and interleukin 1. Cells in floating collagen gels were generally unresponsive to any of the growth factors. Cells in attached collagen gels and monolayer culture were affected similarly by fibroblast growth factor but not by the others. Our results indicate that extracellular matrix organization influenced not only cell growth, but also fibroblast responsiveness to peptide growth factors.