Association of thrombospondin of endothelial cells with other matrix proteins and cell attachment sites and migration tracks

Different biochemical and cytochemical techniques were applied to characterize the sites of localization of thrombospondin in cultured endothelial cells. The results obtained by [35S]methionine labeling, immunoblotting, immunoprecipitation, fluorescence microscopy, ultracytochemistry, immunogold labeling, and silver enhancement experiments revealed that thrombospondin secreted by endothelial cells is structurally organized together with proteoheparan sulfate in spherical granules at the cell surface. These granules are about 100 to 300 nm in size. Heparin or enzymatic degradation with heparitinase, but not with ABC lyase, release thrombospondin from the cell surface. Fibronectin is expressed in the extracellular matrix of endothelial cells in a fibrillar organization, clearly distinct from the punctate pattern of thrombospondin on the cell surface. Furthermore, secreted thrombospondin is highly enriched together with fibronectin and proteoheparan sulfate in cell attachment sites and in cell migration tracks. In cell migration tracks proteoheparan sulfate more clearly resembles the fibrillar distribution pattern of fibronectin, whereas thrombospondin reveals a rather monodisperse pattern. The obtained data suggest preferential sites of interaction between thrombospondin and heparan sulfate proteoglycans on the cell surface and a participation of thrombospondin in cell adhesion and cell migration.     

Production and utilization of extracellular matrix components by human melanocytes

Normal human melanocytes were separated from keratinocytes and maintained in culture using KGM medium supplemented with 12-O-tetradecanoylphorbol acetate and cholera toxin. The melanocytes were examined for the production of extracellular matrix molecules including fibronectin, laminin, and thrombospondin and for the utilization of these molecules in adhesion and motility assays. Melanocytes produced significant amounts of fibronectin as indicated by biosynthetic labeling/immunoprecipitation and by enzyme-linked immunosorbent assay (ELISA). Fibronectin was expressed on the surface of these cells. Laminin was also produced by melanocytes and expressed on the cell surface. The amount of laminin produced was significantly less than the amount of fibronectin. In contrast, melanocytes did not produce measurable thrombospondin as indicated by biosynthetic labeling/immunoprecipitation. Only traces of thrombospondin were detected by ELISA and no surface fluorescence was observed. When examined in adhesion and motility assays, melanocytes were found to utilize fibronectin for both processes. Laminin also stimulated adhesion but it was much less effective than fibronectin. Thrombospondin did not stimulate either attachment and spreading or motility. The pattern of extracellular matrix molecule production and utilization by melanocytes is significantly different from that shown previously for human epidermal keratinocytes (J. Varani et al., 1988, J. Clin. Invest. 81, 1537). These differences may underlie the differences with which the two cell types interact with basement membranes in vivo.     

Amyloid precursor-like protein 2 promotes cell migration toward fibronectin and collagen IV.

Previous studies have established that in response to wounding, the expression of amyloid precursor-like protein 2 (APLP2) in the basal cells of migrating corneal epithelium is greatly up-regulated. To further our understanding of the functional significance of APLP2 in wound healing, we have measured the migratory response of transfected Chinese hamster ovary (CHO) cells expressing APLP2 isoforms to a variety of extracellular matrix components including laminin, collagen types I, IV, and VII, fibronectin, and heparan sulfate proteoglycans (HSPGs). CHO cells overexpressing either of two APLP2 variants, differing in chondroitin sulfate (CS) attachment, exhibit a marked increase in chemotaxis toward type IV collagen and fibronectin but not to laminin, collagen types I and VII, and HSPGs. Cells overexpressing APLP2-751 (CS-modified) exhibited a greater migratory response to fibronectin and type IV collagen than their non-CS-attached counterparts (APLP2-763), suggesting that CS modification enhanced APLP2 effects on cell migration. Moreover, in the presence of chondroitin sulfate, transfectants overexpressing APLP2-751 failed to exhibit this enhanced migration toward fibronectin. The APLP2-ECM interactions were also explored by solid phase adhesion assays. While overexpression of APLP2 isoforms moderately enhanced CHO adhesion to laminin, collagen types I and VII, and HSPGs lines, especially those overexpressing APLP2-751, exhibited greatly increased adhesion to type IV collagen and fibronectin. These observations suggest that APLP2 contributes to re-epithelialization during wound healing by supporting epithelial cell adhesion to fibronectin and collagen IV, thus influencing their capacity to migrate over the wound bed. Furthermore, APLP2 interactions with fibronectin and collagen IV appear to be potentiated by the addition of a CS chain to the core proteins.     

Interleukin 6 promotes epithelial migration by a fibronectin-dependent mechanism.

We investigated the effect of interleukin 6 (IL-6) on the migration of rabbit corneal epithelium in vitro and on the attachment of dissociated corneal epithelial cells to a fibronectin matrix. When corneal blocks were cultured with IL-6 for 24 hours, the length of the path of epithelial migration over exposed corneal stroma increased significantly (p less than 0.005 at the concentration of 10 ng/ml) in proportion to the concentrations of IL-6 (0.1-10.0 ng/ml). The addition of antiserum against fibronectin or of GRGDSP abolished the stimulatory effect of IL-6 on epithelial migration. When corneal epithelial cells were cultured with various concentrations of IL-6, suspended, and plated on wells coated with fibronectin (10 micrograms/ml), the number of cells attached to the wells increased in a dose-dependent manner. The presence of antibody against fibronectin or of GRGDSP during the attachment assay decreased the number of cells attached to the fibronectin matrix, regardless of the fact that the cells had been cultured with IL-6 or not. IL-6 stimulated the attachment of corneal epithelial cells to collagen type IV and to laminin matrices. However, the presence of GRGDSP did not affect the cell attachment to collagen type IV and to laminin. These findings strongly indicate that IL-6 stimulates epithelial migration in the cornea by a fibronectin-dependent mechanism, presumably the increased expression of fibronectin receptors.     

Perlecan inhibits smooth muscle cell adhesion to fibronectin: role of heparan sulfate

Smooth muscle cell migration, proliferation, and deposition of extracellular matrix are key events in atherogenesis and restenosis development. To explore the mechanisms that regulate smooth muscle cell function, we have investigated whether perlecan, a basement membrane heparan sulfate proteoglycan, modulates interaction between smooth muscle cells and other matrix components. A combined substrate of fibronectin and perlecan showed a reduced adhesion of rat aortic smooth muscle cells by 70-90% in comparison to fibronectin alone. In contrast, perlecan did not interfere with cell adhesion to laminin. Heparinase treated perlecan lost 60% of its anti-adhesive effect. Furthermore, heparan sulfate as well as heparin reduced smooth muscle cell adhesion when combined with fibronectin whereas neither hyaluronan nor chondroitin sulfate had any anti-adhesive effects. Addition of heparin as a second coating to a preformed fibronectin matrix did not affect cell adhesion. Cell adhesion to the 105- and 120 kDa cell-binding fragments of fibronectin, lacking the main heparin-binding domains, was also inhibited by heparin. In addition, co-coating of fibronectin and (3)H-heparin showed that heparin was not even incorporated in the substrate. Morphologically, smooth muscle cells adhering to a substrate prepared by co-coating of fibronectin and perlecan or heparin were small, rounded, lacked focal contacts, and showed poorly developed stress fibers of actin. The results show that the heparan sulfate chains of perlecan lead to altered interactions between smooth muscle cells and fibronectin, possibly due to conformational changes in the fibronectin molecule. Such interactions may influence smooth muscle cell function in atherogenesis and vascular repair processes.     

Deposition of extracellular matrix along the pathways of migrating fibroblasts

Summary Fibroblasts from rat, mouse and chick embryos cultured on poly-lysine/fibronectin- or poly-lysine/laminin-coated dishes were stained with antibodies directed to extracellular matrix molecules. The staining showed that cells had migrated during culture and deposited extracellular matrix components along their migration trails. Depending on the antigen, the staining of the matrix revealed fibrils, spots or a diffuse smear along the migration pathways. The major matrix components were fibronectin and heparan sulfate proteoglycan; however, laminin nidogen, tenascin, glia-derived nexin (GDN) and chondroitin-4-sulfate proteoglycan were also found. The migration trails were also detectable by scanning electron microscopy. Here, the fibrils were the prominent structures. The deposition of matrix was independent from the substratum: fibronectin was deposited on laminin, plain poly-lysine, basal lamina and even on fibronectin. Functional assays using anti-fibronectin or an antiserum to embryonic pigment epithelium basement membrane disturbed the formation of matrix fibrils, but did not inhibit cell attachment and translocation. Likewise, heparin in the culture medium only partially inhibited cell migration, despite the fact that it disturbed the formation of proper matrix fibrils. Our results suggest that the deposition of extracellular matrix by cells may not be mandatory for attachment and translocation. However, the deposition of matrix along defined trails might be important for the pathfinding of cells or nerve fibers that appear later in development.     

Syndecans in cell adhesion and differentiation

Syndecans are transmembrane proteoglycans expressed on adherent cells. They are a family of four proteins, which participate in cell-matrix adhesion, the regulation of growth factors (FGFs, VEGF, HGF) binding and signaling. The extracellular domain of syndecans contains heparan sulfate and chondroitin sulfate glycosaminoglycan chains. Syndecans have transmembrane region and a short cytoplasmic domain. The cytoplasmic domain attaches activated protein kinase Calpha, phosphatidyl-inositol-4,5-bisphosphate, syntenin, beta-catenin and many others molecules. Syndecans bind numerous ligands, which are present in extracellular matrix: growth factors, enzymes, extracellular matrix molecules (fibronectin, laminin). They form connections with actin cytoskeleton. The changes in syndecan expression influence on cell adhesion and migration, structure of focal contacts and cytoskeleton. Syndecans participate in cell differentiation and tissue regeneration.     

The production and localization of laminin in cultured vascular and corneal endothelial cells

The production and localization of laminin, as a function of cell density (sparse versus confluent cultures) and growth stage (actively growing versus resting cultures), has been compared on the cell surfaces of cultured vascular and corneal endothelial cells. Comparison of the abilities of the two types of cells to secrete laminin and fibronectin into their incubation medium reveals that vascular endothelial cells can secrete 20-fold as much laminin as can corneal endothelial cells. In contrast, both cell types produce comparable amounts of fibronectin. Furthermore, if one compares the secretion of laminin and fibronectin as a function of cell growth, it appears that the laminin released into the medium by either vascular or corneal endothelial cells, is a function of cell density and cell growth, since this release is most pronounced when the cells are sparse and actively growing, and decreases by 10- and 30-fold, respectively, when either vascular or corneal endothelial cell cultures become confluent. With regard to fibronectin secretion, no such variation can be seen with vascular endothelial cell cultures, regardless of whether they are sparse and actively growing or confluent and resting. Corneal endothelial cell cultures, demonstrated a twofold increase in fibronectin production when they were confluent and resting as compared to when they were sparse and actively growing. When the distribution of laminin versus fibronectin within the apical and basal cell surfaces of cultured corneal and vascular endothelial cells is compared, one can observe that unlike fibronectin, which in sparse and subconfluent cultures can be seen to be associated with both the apical cell surface. In confluent cultures, laminin can be found associated primarily with the extracellular matrix beneath the cell monolayer, where it codistributes with type IV collagen.     

Inhibition of fibronectin binding and fibronectin-mediated cell adhesion to collagen by a peptide from the second type I repeat of thrombospondin

The platelet and extracellular matrix glycoprotein thrombospondin interacts with various types of cells as both a positive and negative modulator of cell adhesion, motility, and proliferation. These effects may be mediated by binding of thrombospondin to cell surface receptors or indirectly by binding to other extracellular matrix components. The role of peptide sequences from the type I repeats of thrombospondin in its interaction with fibronectin were investigated. Fibronectin bound specifically to the peptide Gly-Gly-Trp-Ser-His-Trp from the second type I repeat of thrombospondin but not to the corresponding peptides from the first or third repeats or flanking sequences from the second repeat. The two Trp residues and the His residue were essential for binding, and the two Gly residues enhanced the affinity of binding. Binding of the peptide and intact thrombospondin to fibronectin were inhibited by the gelatin-binding domain of fibronectin. The peptide specifically inhibited binding of fibronectin to gelatin or type I collagen and inhibited fibronectin-mediated adhesion of breast carcinoma and melanoma cells to gelatin or type I collagen substrates but not direct adhesion of the cells to fibronectin, which was inhibited by the peptide Gly-Arg-Gly-Asp-Ser. Thus, the fibronectin- binding thrombospondin peptide Gly-Gly-Trp-Ser-His-Trp is a selective inhibitor of fibronectin-mediated interactions of cells with collagen in the extracellular matrix.     

Production of components of extracellular matrix by cultured rat Sertoli cells

Sertoli cells from rats aged 15, 20, and 25 days were cultured in plastic dishes and extracted with Triton X-100 (0.1 percent w/v) or sodium deoxycholate (2 percent w/v). Residues left after extraction were found to contain three proteins characteristic of extracellular matrix (fibronectin, collagen IV, and laminin). These proteins were identified by four methods: indirect immunofluorescence, co-migration with standard proteins on electrophoresis in polyacrylamide gels, immunoblotting (Western blots), and immunoprecipitation after incubating the Sertoli cells with [35S]methionine. In addition, fibronectin was identified by immunoelectron microscopy with a second antibody conjugated to colloidal gold. In the same cell residues, heparan sulfate was tentatively identified by the first of these methods. The cells used in these studies were shown, by electron microscopy, to be essentially pure cultures of Sertoli cells (greater than 95% pure). Since 100 percent of the cells examined showed positive and specific immunofluorescent staining with well-characterized antibodies to the four components of the extracellular matrix, and since studies with colloidal gold revealed the presence of fibronectin closely associated with and inside cells identified by electron microscopy as Sertoli cells, it must be concluded that Sertoli cells synthesize these four proteins and presumably heparan sulfate. Evidently, cultured Sertoli cells can synthesize and secrete some of the components of an extracellular matrix.     

Synthesis and effects of basement membrane components in cultured rat Schwann cells

Schwann cells, the myelin-forming cells of the peripheral nervous system, are surrounded by a basement membrane. Whether cultured rat Schwann cells synthesize the basement membrane-specific components, laminin and collagen type IV, and whether these components influence the adhesion, morphology, and growth of these cells have been investigated. Both laminin and collagen type IV were detected in the cytoplasm of Schwann cells by immunofluorescence. After ascorbate treatment, laminin and collagen type IV were both found in an extracellular fibrillar matrix bound to the Schwann cell surface. Laminin was further localized on the Schwann cell surface by electron microscopy using gold immunolabeling. Anti-laminin IgG-labeled gold particles were scattered over the cell surface, and linear rows of particles and small aggregates were found along the cell edges and at points of contact with other cells. When added to the culture medium, laminin acted as a potent adhesion factor, stimulating Schwann cell adhesion as much as eightfold above control levels on type IV collagen. In the presence of laminin, the cells became stellate and by 24 hr had extended long, thin processes. Laminin also stimulated cell growth in a dose-dependent manner and anti-laminin IgG completely inhibited cell attachment and growth in the absence of exogenous laminin. Thus, cultured Schwann cells synthesize laminin and collagen type IV, two major components of basement membrane, and laminin may trigger Schwann cell differentiation in vivo during early stages of axon-Schwann cell interaction before myelination.     

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.     

Response to fibronectin of mouse primordial germ cells before, during and after migration.

The adhesive extracellular matrix glycoprotein fibronectin is thought to play a central role in cell migration during embryogenesis. In order to define this role, we have examined the response to fibronectin in cell culture of mouse primordial germ cells (PGCs) before, during and after their migration from the hindgut into their target tissue, the genital ridges. Using an explant culture system, we show that PGCs will emigrate from tissue fragments containing hindgut, and that fibronectin stimulates this migration. Adhesion assays show that the start of PGC migration is associated with a fall in adhesion to fibronectin. Double-labelling studies using in situ hybridization and histochemistry demonstrate that migrating PGCs do not contain detectable fibronectin mRNA, suggesting that they do not synthesize and secrete the fibronectin within their migratory substratum. Taken together, these findings are consistent with an important role for fibronectin in stimulating PGC migration. In addition, however, they suggest that the interaction between PGCs and fibronectin may be important in timing the start of migration, with the fall in adhesion allowing the PGCs to commence their migration towards the genital ridges.     

Human keratinocytes that have not terminally differentiated synthesize laminin and fibronectin but deposit only fibronectin in the pericellular matrix

Fibronectin and laminin production by human keratinocytes cultured in serum-free, low-calcium medium without a fibroblast feeder layer were examined by several techniques. By indirect immunofluorescence, fibronectin but not laminin appeared as short radial fibrils between the cells and the substratum, and in the pericellular matrix. Synthesis of fibronectin and laminin by 7-day keratinocyte cultures was determined by 18 hr 35S-methionine metabolic labeling followed by sodium dodecyl sulfate polyacrylamide gel electrophoresis and autoradiography. Fibronectin accounted for 2.9% of total synthesized protein, 26.5% of fluid phase protein secretion, and 4.3% of deposited ECM protein. In contrast, only 0.1% of the total synthesized protein was laminin, little (6.3%) of this product was secreted, and none of this product was deposited in the ECM. Our results indicate that human keratinocytes under culture conditions that prevent terminal differentiation in vitro can synthesize, secrete, and deposit fibronectin in the extracellular matrix. Although these cells synthesize laminin, they secrete very little and deposit no detectable laminin in the matrix under these culture conditions. From these data we believe that fibronectin may play an important role in the interaction of epidermal cells with connective tissue matrix during wound healing or morphogenesis in in vivo situations in which the epidermis is not terminally differentiated.     

Analysis of fibronectin receptor function with monoclonal antibodies: roles in cell adhesion, migration, matrix assembly, and cytoskeletal organization

We have developed two rat mAbs that recognize different subunits of the human fibroblast fibronectin receptor complex and have used them to probe the function of this cell surface heterodimer. mAb 13 recognizes the integrin class 1 beta polypeptide and mAb 16 recognizes the fibronectin receptor alpha polypeptide. We tested these mAbs for their inhibitory activities in cell adhesion, spreading, migration, and matrix assembly assays using WI38 human lung fibroblasts. mAb 13 inhibited the initial attachment as well as the spreading of WI38 cells on fibronectin and laminin substrates but not on vitronectin. Laminin-mediated adhesion was particularly sensitive to mAb 13. In contrast, mAb 16 inhibited initial cell attachment to fibronectin substrates but had no effect on attachment to either laminin or vitronectin substrates. When coated on plastic, both mAbs promoted WI38 cell spreading. However, mAb 13 (but not mAb 16) inhibited the radial outgrowth of cells from an explant on fibronectin substrates. mAb 16 also did not inhibit the motility of individual fibroblasts on fibronectin in low density culture and, in fact, substantially accelerated migration rates. In assays of the assembly of an extracellular fibronectin matrix by WI38 fibroblasts, both mAbs produced substantial inhibition in a concentration-dependent manner. The inhibition of matrix assembly resulted from impaired retention of fibronectin on the cell surface. Treatment of cells with mAb 16 also resulted in a striking redistribution of cell surface fibronectin receptors from a streak-like pattern to a relatively diffuse distribution. Concomitant morphological changes included decreases in thick microfilament bundle formation and reduced adhesive contacts of the streak-like and focal contact type. Our results indicate that the fibroblast fibronectin receptor (a) functions in initial fibroblast attachment and in certain types of adhesive contact, but not in the later steps of cell spreading; (b) is not required for fibroblast motility but instead retards migration; and (c) is critically involved in fibronectin retention and matrix assembly. These findings suggest a central role for the fibronectin receptor in regulating cell adhesion and migration.     

Thrombospondin inhibits adhesion of endothelial cells

Adsorption of thrombospondin to a substratum inhibits adhesion of endothelial cells to that substratum. Four hours after plating of cells on glass covered with thrombospondin, the number of cells bound per unit area was only 8% of that bound to fibronectin, and 20% of that which could bind to albumin. While on fibronectin cells assumed a well-spread configuration with time in culture, on thrombospondin they stayed completely round. On surfaces constructed by sequential incubation of glass with thrombospondin and fibronectin or other proteins, thrombospondin retained its inhibitory effect on cell adhesion. Fibronectin surfaces treated with thrombospondin lost 50% of their capacity to adhere endothelial cells. Cell spreading was also greatly impaired. These observations indicate that thrombospondin, which is a component of the extracellular matrix, can modulate adhesion of endothelial cells to the matrix.     

Effects of heat shock on the expression of thrombospondin by endothelial cells in culture

Heat-shock proteins from confluent primary cultures of bovine aortic endothelial cells were analyzed by SDS-polyacrylamide gels. In addition to the increased synthesis of the classical heat-shock proteins, there is an increase of a 180,000-mol wt polypeptide in the growth media of heat-shocked cells. Immunoprecipitation with specific antiserum indicates that the 180,000-mol wt polypeptide is thrombospondin. Assay of mRNA levels coding for thrombospondin after brief hyperthermic treatment (45 degrees C, 10 min), followed by a recovery of 2 h at 37 degrees C, results in a twofold increase in mRNA abundance. In contrast, the activation level of the 71,000-mol wt heat-shock protein mRNA occurs at an earlier time than for thrombospondin mRNA. Immunofluorescence microscopy was used to study the intracellular and extracellular distribution of thrombospondin. Thrombospondin is localized to a prominent pattern of granules of intracellular fluorescence in a perinuclear distribution in cells not exposed to heat. Upon heat treatment, the pattern of granules of intracellular fluorescence appears more pronounced, and the fluorescence appears to be clustered more about the nucleus. There are at least three pools of extracellular forms of thrombospondin: (a) the fine fibrillar extracellular matrix thrombospondin; (b) the punctate granular thrombospondin; and (c) the thrombospondin found in the conditioned medium not associated with the extracellular matrix. When bovine aortic endothelial cells are exposed to heat, the extracellular matrix staining of a fibrillar nature is noticeably decreased, with an increase in the number and degree of fluorescence of focal areas where the punctate granule thrombospondin structures are highly localized. No gross morphological changes in extracellular matrix staining of fibronectin was noted. However, the intermediate filament network was very sensitive and collapsed around the nucleus after heat shock. We conclude that the expression of thrombospondin is heat-shock stimulated.     

Behavior of sea urchin primary mesenchyme cells in artificial extracellular matrices

The primary mesenchyme cells (PMCs) were separated from the mesenchyme blastulae of Pseudocentrotus depressus using differential adhesiveness of these cells to plastic Petri dishes. These cells were incubated in various artificial extracellular matrices (ECMs) including horse serum plasma fibronectin, mouse EHS sarcoma laminin, mouse EHS sarcoma type IV collagen, and porcine skin dermatan sulfate. The cell behavior was monitored by a time-lapse videomicrograph and analysed with a microcomputer. The ultrastructure of the artificial ECM was examined by transmission electron microscopy (TEM), while the ultrastructure of the PMCs was examined by scanning electron microscopy (SEM). The PMCs did not migrate in type IV collagen gel, laminin or dermatan sulfate matrix either with or without collagen gel, whereas PMCs in the matrix which was composed of fibronectin and collagen gel migrated considerably. However, the most active and extensive PMC migration was seen in the matrix which contained dermatan sulfate in addition to fibronectin and collagen gel. This PMC migration involved an increase not only of migration speed but also of proportion of migration-promoted cells. These results support the hypothesis that the mechanism of PMC migration involves fibronectin, collagen and sulfated proteoglycans which contain dermatan sulfate.     

Antagonistic effects of laminin and fibronectin in cell-to-cell and cell-to-matrix interactions in MCF-7 cultures

Summary During morphogenesis, tumor progression and metastasis, cell adhesion, dissociation, and migration result from a complex balance between cell-to-cell and cell-to-matrix interactions. Two different organization patterns of MCF-7 cells were induced by different extracellular matrix proteins. When plated on plastic or polymeric type I collagen gel used as a model of interstitial matrix, MCF-7 cells spread and grew in monolayer. When cultured on a solid gel of basement membrane (BM) proteins (85% laminin) used as a model of BM, cells formed clusters attached to the matrix. Matrix proteins regulated these two types of cell organization by preferentially promoting cell-to-cell or cell-support interactions. On plastic in the presence of soluble laminin or on laminin-coated dishes, cells also formed clusters. Addition of soluble fibronectin induced spreading of the cells, suggesting that laminin and fibronectin have competitive antagonistic effects on MCF-7 cell morphology. Antilaminin antibodies inhibited cluster formation and attachment, emphasizing the important role of this glycoprotein not only in promoting cluster attachment but also in cell-to-cell contact formation. Such effects of extracellular matrix proteins could play significant roles in tumor progression and metastasis. This work was supported by grants 3.4512.85 and 3.4514.85 from the Belgian Fonds de la Recherche Scientifique Médicale and the Fonds Cancérologique de la CGER.     

Fibrin-enhanced endothelial cell organization

We examined the synthesis of extracellular matrix macromolecules by human microvascular endothelial cells isolated from the dermis of neonatal (foreskin) and adult (abdominal) skin. Electron microscopy showed that both cell types produced an extracellular matrix that was strictly localized to the subendothelial space. The subendothelial matrices were initially deposited as a single discontinuous layer of filamentous, electron-dense material that progressively became multilayered. Biosynthetic studies indicated that 2-4% of the newly synthesized protein was deposited in the subendothelial matrices by both cell types. Approximately 15-20% of the radiolabeled protein was secreted into the culture medium, and the remainder was confined to the cellular compartment. Biochemical and immunochemical analyses demonstrated the extracellular secretion of type IV collagen, laminin, fibronectin, and thrombospondin by the newborn and adult cells. Whereas type IV collagen was the predominant constituent of the matrix, fibronectin was secreted into the medium, with only small amounts being deposited in the matrix. Thrombospondin was a major constituent of the matrix produced by the newborn foreskin cells but was virtually absent in the matrix elaborated by the adult cells. However, both cell types did release comparable amounts of thrombospondin into their medium. Immunoperoxidase staining for type IV collagen revealed a fibrillar network in the subendothelial matrices produced by both adult and neonatal cells. In contrast, thrombospondin, which was detected only in the matrix of newborn cells, exhibited a spotty and granular staining pattern. The results indicate that the extracellular matrices synthesized by cultured human microvascular endothelial cells isolated from anatomically distinct sites and different stages of development and age are similar in ultrastructure but differ in their macromolecular composition.