Adsorption of human plasma fibronectin (FN) on nonsulfonated and sulfonated polymer surfaces was studied, by using a polyclonal antiserum to FN and the ELISA method. ELISA signal was recorded as a function of FN concentration in solutions. The concentration dependence of FN binding shows the saturation effect in the range 5-10 microg/mL. ELISA data are discussed in the terms of a self-assembled monolayer and different conformations of the FN molecule. The early adhesion of L1210 cells to polymer surfaces after prior adsorption of FN on these surfaces was studied under static conditions. In the case of FN adsorbed on sulfonated surfaces, the relative number of adhering cells increased with the increase of the interfacial surface tension (i.e., the cell adhesion depends on the surface density of sulfonic groups). However, in the case of FN adsorbed on nonsulfonated surfaces, the relative number of adhering cells was low and independent on the interfacial surface tension. The alpha(5)beta(1)-integrin blocking by a monoclonal antibody resulted in a strong inhibition of the cell adhesion to FN adsorbed on sulfonated polymer surfaces. This indicates that cell adhesion to FN adsorbed on these surfaces is mostly mediated by the alpha(5)beta(1)-integrin. In contrast, in the case of FN adsorbed on nonsulfonated surfaces the cell adhesion was not inhibited by the alpha(5)beta(1)-integrin blocking.
The adsorption of fibronectin (FN) to (styrene/methyl methacrylate) copolymer surfaces, both sulfonated (hydrophilic) and nonsulfonated (hydrophobic), was studied by means of the radioisotope (125I-FN) and ELISA assays; the latter employed monoclonal antibodies. It was found that the radioiodination-derived isotherms did not follow the Langmuir-type adsorption law within the FN concentration range studied; rather, a quasi-linear FN surface density versus bulk concentration dependence was observed. These isotherms, and our recent ELISA measurements with polyclonal antibodies, allowed us to estimate saturative FN surface densities, which were, within the experimental error, similar on both types of surfaces. This suggested the amount of adsorbed FN to be not responsible for observed differences in leukaemia L1210 cell adhesion (FN-coated sulfonated surfaces are far more pro-adhesive than their nonsulfonated analogues). The presumption that these differences are induced by changes in the FN arrangement was confirmed by the use of monoclonal antibodies directed against distinct FN domains, and by the blocking of alpha5beta1 integrin receptor with the synthetic Gly-Arg-Gly-Asp-Ser-Pro (GRGDSP) peptide. The RGD sequence located within the FN cell-binding domain seems to be masked in the structure adopted on nonsulfonated surfaces, which hinders the integrin-ligand interaction.
The effect of polystyrene surface polarity on the conformation of adsorbed fibronectin (FN) has been studied with atomic force microscopy. We demonstrated that bare sulfonated and nonsulfonated polystyrene surfaces featured similar topographies. After the FN adsorption, direct comparison of both types of substrata revealed drastically different topographies, roughness values, and also cell-adhesive properties. This was interpreted in terms of FN conformational changes induced by the surface polarity. At high-solute FN concentrations the multilayer FN adsorption took place resulting, for the sulfonated substratum, in an increase of surface roughness, whereas for the nonsulfonated one the roughness was approximately stable. Conversely, the FN conformation characteristic for the first saturative layer tended to be conserved in the consecutive layers, as evidenced by height histograms. The height of individual FN molecules indicated, consonantly with the derived thickness of the adsorbed protein layer (the latter value being 1.4 nm and 0.6 nm, respectively, for an unmodified and sulfonated polystyrene surface), that molecules are flattened on polar surfaces and more compact on nonsulfonated ones. It was also demonstrated that the FN adsorption and conformation on polymeric substrata, and hence the resultant cell-adhesive properties, depended on the chemistry of the original surface rather than on its topography. Our results also demonstrated the ability of surface polarity to influence the protein conformation and its associated biological activity.
The process of human fibronectin (FN) adsorption on nonsulfonated and sulfonated polystyrene surfaces was studied in relation to mechanisms of L1210 cell adhesion. Radioisotope assays directed towards FN, as well as ELISA measurements of adsorbed FN and bovine serum albumin (BSA) were carried out. (125)I radioisotope assays led to linear FN adsorption isotherms. When combined to ELISA measurements for FN, they revealed the multilayer adsorption. Results indicated a large difference in the saturating first-layer surface density of FN adsorbed on sulfonated and nonsulfonated polystyrene surfaces: significantly (ca. factor of 5) less FN molecules are necessary to complete a monolayer on sulfonated than on nonsulfonated polystyrene. This suggests an unfolded conformation of FN on sulfonated polystyrene, and a more compact one on the nonsulfonated polymer. Significant conformational changes of FN are also indicated by the following: (1) early phase of cell adhesion to FN adsorbed on sulfonated polystyrene surfaces is significantly (ca. factor of 6) higher than to FN on nonsulfonated surfaces, and in the former case adhesion proceeds mostly via alpha(5)beta(1) integrins; (2) RGD, the crucial fragment within central cell binding domain, seems to be partially hidden in the protein structure adopted on nonsulfonated surfaces; (3) patterns of F-actin organization differ in cells adhering to FN on sulfonated and nonsulfonated surfaces. The ELISA study directed against BSA (this protein always present on the surface after the adsorption of FN), showed the importance of "free area," uncovered by both proteins, which influence the cell adhesion processes.
Interaction of cell integrins with the ECM (extracellular matrix) proteins is commonly assumed to be associated with cell dissemination and tumour metastases. Since these processes depend on the mechanism of cell—protein interaction, we have attempted to show the contribution of α5β1 and αvβ3 integrins of the prostate cancer PC‐3 cells in in vitro interaction with FN (fibronectin) adsorbed on defined polystyrene surfaces. Cell adhesion, spreading and cytoskeleton organization were studied using antibodies against integrins or a GRGDSP (Gly‐Arg‐Gly‐Asp‐Ser‐Pro) peptide. The results show that blocking the α5β1 integrin causes: (i) a decrease in the number of the adherent cells in the early phase of adhesion and (ii) a decrease in the dynamics of cell spreading and cell shape changes, and weaker reorganization of cytoskeletal proteins than in the control cells. Conversely, the blocking of the αvβ3 integrin: (i) causes no observable effect on the number of the adhered cells; however, (ii) causes an increase in the dynamics of cell spreading and cell shape changes, and stronger reorganization of cytoskeletal proteins than in the control cells. Interestingly, the blocking of integrins with a GRGDSP peptide strongly decreases the number of the adhered cells, and a complete inhibition of cell spreading. Our results strongly suggest that the α5β1 integrin plays the main role in the adhesion and spreading of PC‐3 cells interacting with FN, whereas the αvβ3 integrin seems to regulate other receptors in the spreading process. Moreover, integrin—FN interaction through the RGD sequence evidently curbed the cell adhesion and spreading.
The early phase of 3T3 fibroblast interaction with sulfonated styrene copolymer surfaces, of two sulfonic group densities and thus of differing wettability, was studied. The sulfonic groups present on copolymer surfaces affected the behaviour of cells, i.e. they stimulated cell adhesion, activated cell spreading and influenced cytoskeleton reorganization. The relative number of adhering cells correlated, while the number of spreading cells inversely correlated, with the surface density of sulfonic groups. Cell shape and the pattern of distribution of F-actin, alpha-actinin and vinculin in the interacting cells also depend on the surface density of sulfonic groups. On surfaces of high sulfonic group density, highly polarized cells were observed with F-actin bundles. On surfaces of low sulfonic group density, the cells spread with a square-like morphology with F-actin organized in stress fibres. In contrast, the cells spread poorly on nonsulfonated surfaces and cell adhesion was unaffected by surface wettability. The contribution of alpha(5)beta(1), alpha(4), and beta(5)integrins to the cell interaction with fibronectin (FN) and vitronectin (VN) adsorbed from serum-containing medium on polymer surfaces was examined. Our results suggest that surface sulfonic groups influence the conformation of FN and VN adsorbed on polymer surfaces and, in turn, determine the integrins that are involved in cell adhesion.
The static adhesion of living L1210 cells to sulfonated copolymer surfaces of different sulfonic group content and the actin cytoskeleton organization in the adhering cells were studied. The strength of the cell-substratum interaction was estimated by determining the relative number of cells remaining adherent despite experiencing a shearing force equal to 1.25 x 10(-11) N caused by the laminar flow of the medium. The cell-substratum interaction took place in a medium with or without serum. The distribution of F-actin and alpha-actinin in the adhering cells was determined in sequences of fluorescent images of cell optical slices with the use of a computer method of cell image analysis. It was shown that the surface sulfonic groups affect not only the rate and strength of cell-substratum adhesion but also the F-actin and alpha-actinin distribution (in the cell regions near the substratum surface) in cells adhering in the medium containing serum. These proteins, concentrated in the tips of microvilli, were observed as dots. The distinctness (discernibleness) and sizes of these dots depend on the surface content of sulfonic groups. F-actin is located at the periphery of the cells in cells adhering in the medium without serum and alpha-actinin is concentrated in small dots at the periphery and in the central part of the cells.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.