Spreading and orientation of epithelial cells on grooved substrata

The spreading and orientation of epithelial (E) cells was studied on titanium-coated grooved substrata by light, transmission (TEM) and scanning electron microscopy (SEM). Vertical-walled grooves and V-shaped grooves, 3-60 microns deep, were produced in silicon wafers by micromachining, a process which was developed for the fabrication of micro-electronic components, and the grooved substrata were replicated in Epon. Photolithography was used to prepare photoresist-based and silicon dioxide-silicon substrata with grooves of approximately 2 and approximately 0.5 micron deep, respectively. Cell clusters were markedly oriented by all the grooved substrata examined, with the orientation index being highest for substrata with grooves of the smallest repeat spacing. Time-lapse cinemicrography showed that the grooves directed the migration of E cells, but the control was not absolute, as some cells crossed over the ridges and descended into the grooves. The 0.5 micron grooves appeared less effective than the deeper grooves in directing cell locomotion. SEM and TEM of E cells spreading on the grooved substrata demonstrated that cell processes, including lamellae and filopodia, were capable of bending around and closely adapting to groove edges. E cells did not flatten as extensively on a substratum with 22 microns deep V-shaped grooves as on a smooth surface, although some cells were markedly elongated. One mechanism proposed to explain contact guidance of fibroblasts is that linear elements of the locomotory system, such as microfilament bundles, are unable to operate when bent. The observed flexibility of epithelial cell processes and the ability of substrata with shallow grooves to orient E cells indicate that contact guidance of E cells on micromachined substrata cannot be explained by the mechanical stiffness of long linear cytoskeletal elements.     

Morphogenetic guidance cues can interact synergistically and hierarchically in steering nerve cell growth

Nerve cell growth is influenced by guiding properties of its substratum. Microfabricated cell culture substrata were used to determine whether rat dorsal root ganglia (DRG) nerve cells could detect and integrate simultaneous model adhesive and topographic guidance cues. Interference reflection microscopy demonstrated strips of surface contact under the marginal zone of growth cones on planar surfaces which were coincident with actin immunostaining at the periphery of the C-domain. Clusters of focal contacts below the growth cone C-domain delineated the track edges on adhesive gratings. Neurite extension was guided most effectively by adhesive gratings of 25-μm period where highly aligned cells were typically bipolar. Nanometric steps and differences in surface texture between the adhesive tracks was detected using atomic force microscopy (AFM). Neurites did not align to 12- to 100-μm pitch grooves which were less than 1 μm deep. The proportion of aligned neurites increased with groove depth. Maximum neurite alignment was seen when 6-μm-deep, 25-μm-wide grooves contained superimposed parallel adhesive tracks of matched pitch. Neurites aligned preferentially to adhesive tracks superimposed orthogonally over shallow grooves (1 μm deep). Primary neurites aligned increasingly to grooves with orthogonal adhesive tracks as their depth increased. These neurites frequently had highly branched terminal arbours aligned to the orthogonal adhesive tracks. We conclude that morphogenetic guidance cues can interact synergistically and hierarchically to steer nerve cell growth.     

Guidance and Activation of Murine Macrophages by Nanometric Scale Topography

We studied the guidance and activation of macrophages from the P388D1 cell line and rat peritoneum by topographic features on a nanometric scale. Cells were plated on plain fused silica substrata or substrata with microfabricated grooves and steps, 30–282 nm deep. The contact of cells with the patterned surface activated cell spreading and adhesion and increased the number of protrusions of the cell membrane. These changes were accompanied by an increase in the amount of F-actin in cells. The accumulation of F-actin and vinculin in cells was observed along the edges of single steps or grooves. Formation of focal contacts along discontinuities in the substratum was accompanied by the phosphorylation of tyrosine colocalized with F-actin and vinculin. A similar pattern of staining was seen in cells stained for vitronectin receptor, αV integrin, but not for integrins α5β1 or α3β1. Cells cultured on nanogrooves showed a higher phagocytotic activity than cells cultured on plain substrata. We show that macrophages can react to ultrafine features of topography of a size comparable to that of a single collagen fiber and become activated by the contact with topographic features.     

Fibroblasts on micromachined substrata orient hierarchically to grooves of different dimensions

Contact guidance was studied by light, scanning (SEM) and transmission electron microscopy (TEM) in cultures of human gingival fibroblasts cultured on grooved surfaces. The grooves were originally produced in silicon wafers by micromachining, a process which is based on the methods used to fabricate microelectronic components, and the grooved surfaces were then replicated in Epon. Micromachining enables precise control of groove depth, groove spacing, and groove shape to be obtained. In silicon wafers with appropriate crystal orientation, a second smaller set of grooves, called the minor grooves, is found on the floor of the major grooves. The minor grooves are oriented at a 54 degree angle to the major grooves, so that cells cultured on such surfaces are concurrently exposed to grooves of different dimensions which direct cell migration in different directions. Marked fibroblast alignment with the major grooves was observed both within the grooves and in the intervening flat ridges between the grooves. In addition, shallow and closely spaced grooves in epon or titanium-coated polymer or silicon were also capable of orienting fibroblasts. Although the minor grooves were able to orient fibroblasts in the absence of any other orienting influence, when fibroblasts were concurrently exposed to major and minor grooves the cells aligned themselves with the major grooves. TEM showed that the cellular filamentous cytoskeletal elements reflected the orientation of the cell as a whole. Fibroblasts on grooved substrata appeared to have more filopodia and to round up more frequently than fibroblasts cultured on flat substrata. It is suggested that both the mechanical properties of the cytoskeleton as well as the durability of the cellular attachment to groove edges may play a role in the contact guidance effected by grooved surfaces produced by micromachining.     

Topographic modulation of the orientation and shape of cell nuclei and their influence on the measured elastic modulus of epithelial cells

The influence of nucleus shape and orientation on the elastic modulus of epithelial cells was investigated with atomic force microscopy. The shape and orientation were controlled by presenting the epithelial cells with anisotropic parallel ridges and grooves of varying pitch at the cell substratum. As the cells oriented to the underlying topography, the volume of the nucleus increased as the pitch of the topography increased from 400 nm to 2000 nm. The increase in nucleus volume was reflected by an increase in the measured elastic modulus of the topographically aligned cells. Significant alterations in the shape of the nucleus, by intimate contact with the topographic ridge and grooves of the underlying cell, were also observed via confocal microscopy, indicating that the nucleus may also act as a direct mechanosensor of substratum topography.     

Activation of macrophage-like cells by multiple grooved substrata. Topographical control of cell behaviour.

We studied the influence of substrata topography on the behaviour of murine P388D1 macrophage cell line. Cells were plated on plain fused silica substrata or substrata with microfabricated grooves of varying depth and width. Cell spread area, elongation, orientation and F-actin content were measured on plain substratum and 6 sets of gratings. The speed and persistence of cell movement were also studied. We found that patterned substrata substantially activated cell spreading and elongation and significantly increased the persistence and speed of cell movement, shallow grooves being more effective than deep ones. The contact of cells with micropatterned substrata significantly increased the F-actin content in cells. The sensitivity of LPS (lipopolisaccharide) stimulated and unstimulated macrophages to topographical cues was also compared.     

Sensitivity of Fibroblasts and Their Cytoskeletons to Substratum Topographies: Topographic Guidance and Topographic Compensation by Micromachined Grooves of Different Dimensions

Fibroblasts alter their shape, orientation, and direction of movement to align with the direction of micromachined grooves, exhibiting a phenomenon termed topographic guidance. In this study we examined the ability of the microtubule and actin microfilament bundle systems, either in combination with or independently from each other, to affect alignment of human gingival fibroblasts on sets of micromachined grooves of different dimensions. To assess specifically the role of microtubules and actin microfilament bundles, we examined cell alignment, over time, in the presence or absence of specific inhibitors of microtubules (colcemid) and actin microfilament bundles (cytochalasin B). Using time-lapse videomicroscopy, computer-assisted morphometry and confocal microscopy of the cytoskeleton we found that the dimensions of the grooves influenced the kinetics of cell alignment irrespective of whether cytoskeletons were intact or disturbed. Either an intact microtubule or an intact actin microfilament-bundle system could produce cell alignment with an appropriate substratum. Cells with intact microtubules aligned to smaller topographic features than cells deficient in microtubules. Moreover, cells deficient in microtubules required significantly more time to become aligned. An unexpected finding was that very narrow 0.5-μm-wide and 0.5-μm-deep grooves aligned cells deficient in actin microfilament bundles (cytochalasin B-treated) better than untreated control cells but failed to align cells deficient in microtubules yet containing microfilament bundles (colcemid treated). Thus, the microtubule system appeared to be the principal but not sole cytoskeletal substratum-response mechanism affecting topographic guidance of human gingival fibroblasts. This study also demonstrated that micromachined substrata can be useful in dissecting the role of microtubules and actin microfilament bundles in cell behaviors such as contact guidance and cell migration without the use of drugs such as cytochalasin and colcemid.     

Contact formation by fibroblasts adhering to heparan sulfate-binding substrata (fibronectin or platelet factor 4)

The process of cell-substratum adhesion of BALB/c 3T3 fibroblasts on fibronectin (FN)-coated substrata was compared with that of cells adhering to substrata coated with the heparan sulfate (HS)-binding protein, platelet factor four (PF4). FN has binding domains for HS and an unidentified cell surface receptor, whereas PF4 binds to only HS on the surface of the cell. The attachment and early spreading sequences of cells on either substratum were similar as shown by scanning electron microscopy (SEM). Within 2 h of spreading, cells on FN developed typical fibroblastic morphologies, whereas those on PF4 lacked polygonal orientations and formed numerous broadly spread lamellae. Interference reflection microscopic analysis indicated that PF4-adherent cells formed only close adhesive contacts, whereas FN-adherent cells formed both close contacts and tight focal contacts. Cells on either substratum responded to Ca2+ chelation with EGTA by rounding up, but remained adherent to the substratum by relatively EGTA-resistant regions of the cell's undersurface, demonstrating that cell surface HS by binding to an appropriate substratum is capable of initiating a Ca2+-dependent spreading response. The EGTA-resistant substratum-attached material on PF4 was morphologically similar to that on FN, the latter of which was derived from both tight focal contacts and discrete specializations within certain close contacts. These studies show that heparan sulfate proteoglycans on the surface of these cells can participate in the formation of close contact adhesions by binding to an appropriate substratum and suggest that sub-specializations within close contact adhesions may evolve into tight focal contacts by the participation of an unidentified cell surface receptor which binds specifically to fibronectin but not to PF4. In addition, the functional role of FN in tight focal contact formation is demonstrated.     

Locomotion of sponges and its physical mechanism

Active locomotion by individual marine and freshwater sponges across glass, plastic and rubber substrata has been studied in relation to the behavior of the sponges' component cells. Sequential tracing of sponge outlines on aquarium walls shows that sponges can crawl up to 160 microns/hr (4 mm/day). Time-lapse cinemicrography and scanning electron microscopy reveal that moving sponges possess distinctive leading edges composed of motile cells. Sponge locomotion was found to be mechanically similar to the spreading of cell sheets in tissue culture both with respect to exertion of traction (which causes the wrinkling of rubber substrata) and with respect to the patterns of adhesive contacts formed with the substratum (as observed by interference reflection microscopy). Other similarities include the orientation of sponge locomotion along grooves and the preferential extension onto more adhesive substrata. Neither the patterns of wrinkling produced in rubber substrata nor the distributions of adhesive contacts seen by interference reflection microscopy show evidence of periodic, propagating waves of surface contractions, such as would be expected if the sponges' mechanism of locomotion were by peristalsis or locomotory waves. Our observations suggest that the displacement of sponges is achieved by the cumulative crawling locomotion of the cells that compose the sponge's lower surface. This mode of organismal locomotion suggests new explanations for the plasticity of sponge morphology, seems not to have been reported from other metazoans, and has significant ecological implications.     

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.     

Adhesion of cells to protein carpets: do cells' feet have to be black?

In most physiological situations, cell contact with a substratum is mediated by proteins of extracellular matrix. Therefore, an increasing number of cell-substratum adhesion studies employ substrata covered with one or more proteins of extracellular matrix. To visualize the most adhesive cell structures, focal contacts and focal adhesions, the interference reflection microscopy has been widely used. It has been generally accepted that these strongly adhesive structures can be seen as black streaks in interference reflection microscopy. Calculations are presented herein, which although simplified, suggest that when cells are plated on protein-covered substrata, their focal contacts may not always appear black in interference reflection microscopy.     

Regulation of integrin-mediated adhesion at focal contacts by cyclic AMP

Cyclic AMP (cAMP) elevation causes diverse types of cultured cells to round partially and develop arborized cell processes. Renal glomerular mesangial cells are smooth, muscle-like cells and in culture contain abundant actin microfilament cables that insert into substratum focal contacts. cAMP elevation causes adhesion loss, microfilament cable fragmentation, and shape change in cultured mesangial cells. We investigated the roles of the classical vitronectin (αVβ3 integrin) and fibronectin (α5β1 integrin) receptors in these changes. Mesangial cells on vitronectin-rich substrata contained microfilament cables that terminated in focal contacts that stained with antibodies to vitronectin receptor. cAMP elevation caused loss of focal contact and associated vitronectin receptor. Both fibronectin and its receptor stained in a fibrillary pattern at the cell surface under control conditions but appeared aggregated along the cell processes after cAMP elevation. This suggested that cAMP elevation caused loss of adhesion mediated by vitronectin receptor but not by fibronectin receptor. We plated cells onto fibronectin-coated slides to test the effect of ligand immobilization on the cellular response to cAMP. On fibronectin-coated slides fibronectin receptor was observed in peripheral focal contacts where actin filaments terminated, as seen with vitronectin receptor on vitronectin-coated substrata, and in abundant linear arrays distributed along microfilaments as well. Substratum contacts mediated by fibronectin receptor along the length of actin filaments have been termed fibronexus contacts. After cAMP elevation, microfilaments fragmented and fibronectin receptor disappeared from peripheral focal contacts, but the more central contacts along residual microfilament fragments appeared intact. Also, substratum adhesion was maintained after cAMP elevation on fibronectin—but not on vitronectincoated surfaces. Although other types of extracellular matrix receptors may also be involved, our observations suggest that cAMP regulates adhesion at focal contacts but not at fibronexus-type extracellular matrix contacts. © 1993 Wiley-Liss, Inc.     

Collagen modulates cell shape and cytoskeleton of embryonic corneal and fibroma fibroblasts: Distribution of actin, α-actinin,and myosin

In the embryo, fibroblasts migrating through extracellular matrices (ECM) are generally elongate in shape, exhibiting a leading pseudopodium with filopodial extensions, and a trailing cell process. Little is known about the mechanism of movement of embryonic cells in ECM, for studies of fibroblast locomotion in the past have been largely confined to observations of flattened cells grown on planar substrata. We confirm here that embryonic avian corneal fibroblasts migrating within hydrated collagen gels in vitro have the bipolar morphology of fibroblasts in vivo, and we show for the first time that highly flattened gerbil fibroma fibroblasts, grown as cell lines on planar substrata, can also respond to hydrated collagen gels by becoming elongate in shape. We demonstrate that the collagen-mediated change in cell shape is accompanied by dramatic rearrangement of the actin, α-actinin, and myosin components of the cytoskeleton. By immunofluorescence, the stress fibers of the flattened corneal fibroblasts grown on glass are seen to stain with antiactin, anti-α-actinin, and antimyosin, as has been reported for fibroma and other fibroblasts grown on glass. Stress fibers, adhesion plaques, and ruffles do not develop when the corneal or fibroma fibroblast is grown in ECM; these features seem to be a response to strong attachment of the cell underside to a planar substratum. When the fibroblasts are grown in ECM, antimyosin staining is distributed diffusely through the cytoplasm. Antiactin and anti-α-actinin stain the microfilamentous cell cortex strongly. We suggest that locomotion of the fibroblast in ECM is accompanied by adhesion of the cell to the collagen fibrils and may involve an interaction of the myosin-rich cytosol with the actin-rich filamentous cell cortex. Interestingly, the numerous filopodia that characterize the tips of motile pseudopodia of cells in ECM are very rich in actin and α-actinin, but seem to lack myosin; if filopodia use myosin to move, the interaction must be at a distance. Soluble collagen does not convert flattened fibroblasts on planar substrata to bipolar cells. Thus, the effect of collagen on the fibroblast cytoskeleton seems to depend on the presence of collagen fibrils in a gel surrounding the cell.     

Microspike-mediated particle transport towards the cell body during early spreading of 3T3 cells

Freshly trypsinized 3T3 cells send out microspikes of 0.2 μm diameter and up to 10 μm length within 20 min after attachment to a glass substratum. The microspikes move actively and eventually attach to the substratum. Subsequently, lamellae flow out between lines of attached microspikes. If, however, colloidal gold particles of 0.2–0.4 μm diameter and clusters of gold particles up to 4 μm in diameter are placed on the substratum and a microspike attaches to them, we observed two reactions of the microspikes to this contact. They either retract upon contact, transporting the attached particles to the cell surface at a speed of 0.2 μm/sec, or the particles flow toward the cell body while the microspike stays in place. This action results in the clearing of a circular area around each spreading cell before lamellae flow out. “Clearing” proceeds at serum concentrations between 1 and 20% and in concentrations of colchicine up to 20 μm/ml. In concentrations of cytochalasin B higher than 5 μg/ml, however, particle removal is completely inhibited, although the microspikes are still produced by the cell. Transmission electron microscopy shows that the microspikes contain mostly longitudinally oriented microfilaments and only a few microtubules, if any.     

Development of the major pathways for neurite outgrowth in the chick hindlimb

To elucidate mechanisms that may control development of the gross anatomical nerve pattern, motoneuron outgrowth into the chick hindlimb was examined using orthograde labeling, scanning and transmission electron microscopy, and Alcian blue staining. Results show that growth cones are not guided by contact with oriented extracellular fibrils, aligned mesenchyme cells, the myotome, or the vasculature. Pathways are not delineated by cell-free space or channels of lower cell density; however, densely packed mesenchyme may form barriers that channel outgrowth. In addition, abundant mesenchymal cell death was seen at the nerve front. This cell death may provide space that encourages growth cone advancement. Pathways often lie along interfaces between areas that stain darkly and lightly with Alcian blue, which specifically stains glycosaminoglycans, and growth cones never penetrate areas that stain intensely, such as the pelvic girdle, which is known to be a barrier to outgrowth. Leading growth cones form specialized contacts with mesenchyme cells, but the predominant contacts are interneuronal. It is proposed that the anatomical pattern of outgrowth is determined by the distribution of preferred substrata, the most preferred substratum being other neurites. Further, neurites tend to prefer loose mesenchyme to dense mesenchyme or areas rich in glycosaminoglycans.     

Modulation of protein synthesis and secretion by substratum in primary cultures of rat hepatocytes

Hepatocytes isolated by perfusion of adult rat liver and cultured on substrata consisting of one or more of the major components of the liver biomatrix (fibronectin, laminin, type IV collagen) have been examined for the synthesis of defined proteins. Under these conditions, tyrosine amino transferase, a marker of hepatocyte function, is maintained at similar levels in response to dexamethasone over 5 days in culture on each substratum, and total cellular protein synthesis remains constant. By contrast, there is a rapid decrease in synthesis and secretion of albumin and a 3-7-fold increase in synthesis and secretion of alpha-fetoprotein which are most marked on a laminin substratum, but least evident on type IV collagen, and an increased synthesis of fibronectin and type IV collagen. The newly synthesized matrix proteins are present in the cell layer as well as in cell secretions. The enhanced synthesis of fibronectin is less in cells seeded onto a fibronectin substratum than on laminin or type IV collagen substrata, and its synthesis by hepatocytes seeded onto a mixed substratum of laminin and fibronectin is down-regulated by fibronectin in a dose-related manner. Similarly, type IV collagen synthesis is less when the cells are seeded on the homologous matrix protein substratum than on heterologous substrata. These results indicate that hepatocytes cultured in serum-free medium on substrata composed of components of the liver biomatrix maintain certain functions of the differentiated state (tyrosine amino transferase), lose others (albumin secretion) and switch to increased synthesis of matrix components as well as fetal markers such as alpha-fetoprotein. The magnitude of these effects depends on the substratum on which the hepatocytes are cultured.     

Stimulation of corneal differentiation by interaction between cell surface and extracellular matrix. I. Morphometric analysis of transfilter "induction".

The present study was undertaken to determine whether or not physical contact with the substratum is essential for the stimulatory effect of extracellular matrix (ECM) on corneal epithelial collagen synthesis. Previous studies showed that collagenous substrata stimulate isolated epithelia to produce three times as much collagen as they produce on noncollagenous substrate; killed collagenous substrata (e.g., lens capsule) are just as effective as living substrata (e.g., living lens) in promoting the production of new corneal stroma in vitro. In the experiments to be reported here, corneal epithelia were placed on one side of Nucleopore filters of different pore sizes and killed lens capsule on the other, with the expectation that contact of the reacting cells with the lens ECM should be limited by the number and size of the cell processes that can tranverse the pores. Transfilter cultures were grown for 24 h in [3H]proline-containing median and incorporation of isotope into hot trichloroacetic acid-soluble protein was used to measure corneal epithelial collagen production. Epithelial collagen synthesis increases directly as the size of the pores in the interposed filter increases and decreases as the thickness of the filter layer increases. Cell processes within Nucleopore filters were identified with the transmission electron microscope with difficulty; with the scanning electron microscope, however, the processes could easily be seen emerging from the undersurface of even 0.1-mum pore size filters. Morphometric techniques were used to show that cell surface area thus exposed to the underlying ECM is linearly correlated with enhancement of collagen synthesis. Epithelial cell processes did not pass through ultrathin (25-mum thick) 0.45-mum pore size Millipore filters nor did "induction" occur across them. The results are discussed in relation to current theories of embryonic tissue interaction.     

Expression of the differentiated phenotype by epithelial cells in vitro is regulated by both biochemistry and mechanics of the substratum

In this paper I sought to determine how the expression of differentiated traits of chick retinal pigmented epithelial (RPE) cells in vitro can be modulated by varying both the biochemical and the spatial complexity, and the mechanical properties, of the growth substratum. I have used glass derivatized with proteins of a basement membrane extract (nondeformable, two-dimensional substratum) and gels of reconstituted basement membrane extract (viscoelastic, three-dimensional substratum). These two biochemically similar substrata were compared to an inert substratum (untreated glass) and to the native basement membrane of the RPE, i.e., Bruch's Membrane. With immunofluorescence microscopy, I have shown that RPE cells, given space, will spread on their native basement membrane and form stress fibres and focal contacts, analogous to the stress fibres and integrin-, talin-, and vinculin-containing focal contacts of the cells grown on glass. Therefore, the stress fibres and focal contacts present in cultured cells are not artifacts of growth in vitro, but are a natural cellular response to the nondeformability of commonly used tissue culture substrata. The proteins of the basement membrane promote expression of some of the differentiated traits by RPE cells in vitro: however, the fully differentiated phenotype is expressed by RPE cells only when their spreading is prevented by low resilience of a substratum. Basement membrane gels generally are not resilient enough to support RPE cell spreading; however, the cells spread and form stress fibres, and integrin-, talin-, and vinculin-containing focal contacts when they are presented with areas of the gel which locally acquired higher resilience. The extent of cell spreading is determined by the deformability of substratum, hence elastic forces operating within the substratum determine the maximal cell traction allowable and, indirectly, the cytoarchitecture. Therefore, in addition to biochemical composition, the mechanical properties of substrata play important role in regulation of expression of the differentiated phenotype of cells in vitro and, possibly, in vivo.     

Proteolytic activity of specialized surface protrusions formed at rosette contact sites of transformed cells

Surface protrusions at the leading edge of a moving cell that make contact with the surrounding extracellular matrix (ECM) are its main motor for locomotion and invasion. Chicken embryonic fibroblasts transformed by Rous sarcoma virus (RSV-CEF) form specialized membrane rosette-shaped contact sites on planar substrata as shown by interference reflection microscopy (IRM). Such activity is lacking in normal cells. These rosette contacts are more labile than other adhesion sites, such as focal and close contacts. Ultrastructural studies demonstrate that rosettes are sites at which membrane protrusions from the ventral cell surface contact the substratum. These protrusions are filled with meshworks of microfilaments and contain the pp60src oncogene product, actin, vinculin, and alpha-actinin. However, unlike focal contacts, at the rosettes these proteins interact to extend a highly motile membrane. Rosettes have the biological activity of degrading ECM components, as demonstrated by (1) local degradation of fibronectin substrata at sites of rosette contacts, but not focal and close contacts; (2) localization of putative antiprotease antibody at sites of rosette contacts, but not at focal an close contacts; and (3) local disruption of fibronectin matrix at sites of protrusive activity seen by transmission electron microscopy (TEM). In addition, formation of the rosette contact is insensitive to the ionophore monensin, and to inhibitors of proteolytic enzymes, while local fibronectin degradation at rosette contacts is inhibited by inhibitors of metalloproteases, 1,10-phenanthroline and NP-20. I consider these membrane protrusions of the rosette contacts in RSV-transformed cells specialized structural entities--invadopodia--that are involved in the local degradation of the ECM.