Interactions Of Fibronectin Research Articles

Distinct Binding Interactions of α5β1-Integrin and Proteoglycans with Fibronectin

Dynamic single-molecule force spectroscopy was performed to monitor the unbinding of fibronectin with the proteoglycans syndecan-4 (SDC4) and decorin and to compare this with the unbinding characteristics of α5β1-integrin. A single energy barrier was sufficient to describe the unbinding of both SDC4 and decorin from fibronectin, whereas two barriers were observed for the dissociation of α5β1-integrin from fibronectin. The outer (high-affinity) barriers in the interactions of fibronectin with α5β1-integrin and SDC4 are characterized by larger barrier heights and widths and slower dissociation rates than those of the inner (low-affinity) barriers in the interactions of fibronectin with α5β1-integrin and decorin. These results indicate that SDC4 and (ultimately) α5β1-integrin have the ability to withstand deformation in their interactions with fibronectin, whereas the decorin-fibronectin interaction is considerably more brittle.

Mechanical forces regulate the interactions of fibronectin and collagen I in extracellular matrix.

Despite the crucial role of extracellular matrix (ECM) in directing cell fate in healthy and diseased tissues—particularly in development, wound healing, tissue regeneration and cancer—the mechanisms that direct the assembly and regulate hierarchical architectures of ECM are poorly understood. Collagen I matrix assembly in vivo requires active fibronectin (Fn) fibrillogenesis by cells. Here we exploit Fn-FRET probes as mechanical strain sensors and demonstrate that collagen I fibres preferentially co-localize with more-relaxed Fn fibrils in the ECM of fibroblasts in cell culture. Fibre stretch-assay studies reveal that collagen I's Fn-binding domain is responsible for the mechano-regulated interaction. Furthermore, we show that Fn-collagen interactions are reciprocal: relaxed Fn fibrils act as multivalent templates for collagen assembly, but once assembled, collagen fibres shield Fn fibres from being stretched by cellular traction forces. Thus, in addition to the well-recognized, force-regulated, cell-matrix interactions, forces also tune the interactions between different structural ECM components.

Quantifying fibronectin adhesion with nanoscale spatial resolution on glycosaminoglycan doped polypyrrole using Atomic Force Microscopy

BackgroundThe interaction of ECM proteins is critical in determining the performance of materials used in biomedical applications such as tissue regeneration, implantable bionics and biosensing. MethodsTo improve our understanding of ECM protein–conducting polymer interactions, we have used Atomic Force Microscopy (AFM) to elucidate the interactions of fibronectin (FN) on polypyrrole (PPy) doped with different glycosaminoglycans. ResultsWe were able to classify four main types of FN interactions, including those related to 1) non-specific adhesion, 2) protein unfolding and subsequent unbinding from the surface, 3) desorption and 4) interactions with no adhesion. FN adhesion on PPy/hyaluronic acid showed a significantly lower density of surface adhesion with the adhesion restricted to nodule structures, as opposed to their peripheries, of the polymer morphology. In contrast, PPy/chondroitin sulfate showed a significantly higher density of surface adhesion to the point where the distribution of adhesion effectively masked the topography. Through conductive AFM imaging, we found that the conductive regions correlated with regions of FN adhesion. ConclusionsGiven that the conductivity requires doping of the polymer, these findings suggest that FN adhesion is mediated by interactions with chondroitin sulfate and hyaluronic acid at the polymer surface and may be indicative of specific interactions due to contributions from electrostatic attraction between the FN and sulfate/anionic groups of the dopants. General significanceThis study demonstrates the ability of AFM to resolve the protein–conducting polymer interactions at the molecular and nanoscale level, which will be important for interfacing these polymer materials with biological systems. This article is part of a Special Issue entitled Organic Bioelectronics — Novel Applications in Biomedicine.

Abstract 19552: Exercise-Induced Changes in Mechanotransduction Improve Myocardial Function in a Porcine Model of Chronic Occlusion

Introduction: Exercise training has been shown to improve cardiac dysfunction both in patients and animal models of coronary artery disease; however, the underlying cellular and molecular mechanisms have not been completely understood. Transmembrane integrins that connect the extracellular matrix (ECM) and intracellular cytoskeleton are important for mechanotransduction in cardiomyocytes. Hypothesis: The binding probability and adhesion force between integrins-ECM, and their subsequent signaling that is cell stiffness will be increased in the myocytes from exercise-trained animals when compared to the sedentary group. Methods: Ameroid occluders were surgically placed around the proximal left circumflex coronary artery of adult female Yucatan pigs. Twenty-two weeks postoperatively, myocardium was isolated from non-occluded and collateral-dependent regions of sedentary and exercise trained (treadmill run; 5 days/wk for 14 wks) pigs. We used atomic force microscopy for measuring cell stiffness and adhesion force between integrin and fibronectin (FN) in pig cardiomyocytes. In addition, integrins and FN expression were determined. Results: While exercise-trained pigs showed an increase in β1 integrin expression, β3 integrin expression was detected at an increased level in the sedentary myocardium. An increase in the amount of total FN and its fragments were found in the myocardium from collateral-dependent regions of exercise-trained and sedentary pigs when compared to the non-occluded myocardium regions. The peak bond rupture force of FN-integrin (46.4±0.3 pN vs 34.8±0.2 pN), the probability of adhesion (72% vs 54%) and cell stiffness (67.9±4.7 kPa vs 29.0±1.8 kPa) were significantly increased (p<0.05; n=10) in myocytes from exercise-trained pigs when compared to sedentary hearts, which were prevented by function blocking α5 and αv integrin antibodies, respectively. Conclusion: Our data demonstrate that the differences seen in adhesion force, probability and stiffness between the sedentary and exercise-trained myocytes are due to interactions of FN to different integrins, e.g., αvβ3 in sedentary and α5β1 in exercise-trained cells, suggesting potential importance of mechanotransduction pathway for therapeutic development.

Cell Membrane–associated Heparan Sulfate Is a Receptor for Prototype Foamy Virus in Human, Monkey, and Rodent Cells

Foamy viruses (FVs) (spumaretroviruses) are good alternative to retroviruses as gene therapy vector. Despite four decades since the discovery of FV, its receptor molecule is still unknown. FV vector transduction of human CD34(+) cells was inhibited by culture with fibronectin. Because fibronectin contains heparin-binding domain, the interactions of fibronectin with heparan sulfate (HS) on cells might be inhibitory to FV transduction. These observations led us to investigate whether HS is a receptor for FV. Two mutant CHO cell lines (but not parental wild type) lacking cell surface HS but not chondroitin sulfate (CS) were largely resistant to FV attachment and transduction. Inhibition of HS expression using enzymes or chemicals greatly reduced FV transduction in human, monkey, and rodent cells. Raji cells, which lack HS and were largely resistant to FV, were rendered more permissive through ectopic expression of syndecan-1, which contains HS. In contrast, mutant syndecan-1-expressing cells were largely resistant to FV. Our findings indicate that cellular HS is a receptor for FV. Identifying FV receptor will enable better understanding of its entry process and optimal use as gene therapy vector to treat inherited and pathogenic diseases.

Revealing the selective interactions of fibronectin with lipid bilayers

The interaction of extracellular matrix proteins with lipid bilayers is fundamental to cell adhesion and related processes such as tissue formation. In this paper we use atomic force microscopy to examine the interaction between fibronectin and supported lipid bilayers. For binary lipid mixtures that display phase separation, atomic force microscopy shows that fibronectin preferentially and almost exclusively interacts with the gel phase domains, sitting on top of these raised regions. Single molecule force spectroscopy confirms the location of fibronectin on the bilayer and reveals that the mechanical properties of fibronectin are affected by aggregation of the protein on the lipid. We demonstrate that it is possible to measure the thickness of the protein aggregates by identifying a protein layer breakthrough event. Of particular interest are force–distance curves that exhibit a combination of three features, a protein layer breakthrough event, a lipid bilayer breakthrough event, and a sawtooth pattern attributed to fibronectin unfolding. The combination of lipid- and protein-related events on a single force–distance profile, characterizes in detail the lipid/protein interaction. Preferential interactions of fibronectin with lipids suggest that non-specific binding could be important in extracellular matrix protein-cell interactions and that the lateral organization of the cell membrane may play an even greater role in cell adhesion than previously thought.

Fibrillin Assembly Requires Fibronectin

Fibrillins constitute the major backbone of multifunctional microfibrils in elastic and nonelastic extracellular matrices. Proper assembly mechanisms are central to the formation and function of these microfibrils, and their properties are often compromised in pathological circumstances such as in Marfan syndrome and in other fibrillinopathies. Here, we have used human dermal fibroblasts to analyze the assembly of fibrillin-1 in dependence of other matrix-forming proteins. siRNA knockdown experiments demonstrated that the assembly of fibrillin-1 is strictly dependent on the presence of extracellular fibronectin fibrils. Immunolabeling performed at the light and electron microscopic level showed colocalization of fibrillin-1 with fibronectin fibrils at the early stages of the assembly process. Protein-binding assays demonstrated interactions of fibronectin with a C-terminal region of fibrillin-1, -2, and -3 and with an N-terminal region of fibrillin-1. The C-terminal half of fibrillin-2 and -3 had propensities to multimerize, as has been previously shown for fibrillin-1. The C-terminal of all three fibrillins interacted strongly with fibronectin as multimers, but not as monomers. Mapping studies revealed that the major binding interaction between fibrillins and fibronectin involves the collagen/gelatin-binding region between domains FNI(6) and FNI(9).

Fibronectin promotes cell proliferation of human pre-B cell line via its interactions with VLA-4 and VLA-5

Fibronectin (FN) is thought to play an important role in various aspects of hematopoiesis through binding to very late antigen (VLA)-4 and VLA-5. Little is known, however, about the effects of FN on the proliferation of B cell progenitors. In this study, we investigated the effects of immobilized FN on the proliferation of the pre-B cell line, Nalm-6, which expresses both VLA-4 and VLA-5. Immobilized FN significantly promoted the proliferation of Nalm-6 cells through the synergistic effects of VLA-4 and VLA-5. Furthermore, FN induced the phosphorylation of mitogen-activated protein kinases (MAPKs) of Nalm-6 cells. The MAPK kinase 1 (MEK1) inhibitor, PD98059, and Src family tyrosine kinase inhibitor, herbimycin A, inhibited the FN-promoted proliferation of Nalm-6 cells. These results demonstrate that the interactions of FN and VLA-4/VLA-5 transmit the growth signals that are mediated through Src family tyrosine kinases and the MAPK cascade in Nalm-6 cells. The precise mechanism of synergistic effect of VLA-4 and VLA-5 on FN-promoted proliferation of Nalm-6 cells should be further investigated.

Calcium indirectly regulates immunochemical reactivity and functional activities of the N-domain of thrombospondin-1

Conformational changes induced in thrombospondin-1 by removal of calcium regulate interactions with some ligands of its N-modules. Because calcium binds primarily to elements of the C-terminal signature domain of thrombospondin-1, which are distant from the N-modules, such regulation was unexpected. To clarify the mechanism for this regulation, we compared ligand binding to the N-modules of thrombospondin-1 in the full-length protein and recombinant trimeric thrombospondin-1 truncated prior to the signature domain. Three monoclonal antibodies were identified that recognize the N-modules, two of which exhibit calcium-dependent binding to native thrombospondin-1 but not to the truncated trimeric protein. These antibodies or calcium selectively modulate interactions of fibronectin, heparin, sulfatide, α3β1 integrin, tumor necrosis factor-α-stimulated gene-6 protein, and, to a lesser extent, α4β1 integrin with native thrombospondin-1 but not with the truncated protein. These results indicate connectivity between calcium binding sites in the C-terminal signature domain and the N-modules of thrombospondin-1 that regulates ligand binding and functional activities of the N-modules.

TSG-6 binds via its CUB_C domain to the cell-binding domain of fibronectin and increases fibronectin matrix assembly

Human plasma fibronectin binds with high affinity to the inflammation-induced secreted protein TSG-6. Fibronectin binds to the CUB_C domain of TSG-6 but not to its Link module. TSG-6 can thus act as a bridging molecule to facilitate fibronectin association with the TSG-6 Link module ligand thrombospondin-1. Fibronectin binding to TSG-6 is divalent cation-independent and is conserved in cellular fibronectins. Based on competition binding studies using recombinant and proteolytic fragments of fibronectin, TSG-6 binding localizes to type III repeats 9–14 of fibronectin. This region of fibronectin contains the Arg-Gly-Asp sequence recognized by α5β1 integrin, but deletion of that sequence does not prevent TSG-6 binding, and TSG-6 does not inhibit cell adhesion on fibronectin substrates mediated by this integrin. This region of fibronectin is also involved in fibronectin matrix assembly, and addition of TSG-6 enhances exogenous and endogenous fibronectin matrix assembly by human fibroblasts. Therefore, TSG-6 is a high affinity ligand that can mediate fibronectin interactions with other matrix components and modulate some interactions of fibronectin with cells.

Atomic force microscopy and surface plasmon resonance investigation of fibronectin interactions with group B streptococci

The interactions of fibronectin (Fn) with group B streptococci (GBS) were investigated using the atomic force microscope (AFM) and surface plasmon resonance (SPR) biosensing. Submonolayer amounts of Fn were immobilized onto the AFM tip by two different methods, using either a sulfosuccinimidyl-4-(N-maleimidomethyl) cycholhexane-1-carboxylate (SMCC) linker or a pyridyldithio poly(ethylene glycol) succinimidylpropionate (NHS-PEG-PDP) linker. Each step of both immobilization methods was characterized using x-ray photoelectron spectroscopy. Time-of-flight secondary ion mass spectrometry experiments indicated both methods produced Fn immobilized in a similar conformation. AFM force-distance curves from live GBS plated onto polystyrene exhibited several types of interactions between the Fn functionalized AFM tip and the surface of capsule-deficient GBS (no interactions, interactions with the cell wall, Fn unfolding, large specific unbinding events, and small specific unbinding events). From analysis of the force-distance curves that exhibited only a single specific unbinding event, the work of adhesion and rupture force for the SMCC immobilized Fn tips (11,131 pN nm and 213 pN) were larger than the corresponding values for the NHS-PEG-PDP immobilized Fn tips (8115 pN nm and 189 pN). The unbinding event occurred at distances approximately 100 nm further from the surface with the NHS-PEG-PDP immobilized Fn tip compared to SMCC immobilized Fn tip. The SPR experiments of soluble Fn with adsorbed serine protease C5a peptidase (Scp), the surface protein on GBS that binds Fn, showed that both low (millimolar) and high binding (nanomolar) affinity interactions were present. However, the low binding affinity interactions dominated the adsorption process and, with increasing Fn solution concentration, the amount of Scp bound to Fn via the high binding affinity interaction decreased. These data confirm that Scp binds only to adsorbed Fn at the Fn concentrations typically present in blood plasma.

Plasma Fibronectin Concentration

Accumulation and cohesion of platelets at sites of vascular injury are essential for the formation of the hemostatic plug but also result in thrombosis.1,2 Platelet plug or thrombus formation is initiated by interaction of platelet receptors with components of extracellular matrix (ECM) of injured vessels. Fibronectin is both an ECM component and moderately abundant 460-kDa glycoprotein in blood, present at 300 to 400 μg/mL (0.6 to 0.9 μmol/L) in plasma and 0.5 μg per 3×108 platelets in platelet α-granules.3–5 Plasma fibronectin is a dimer of nearly identical 230-kDa subunits (Figure) that can multimerize to the insoluble form found in ECM.6 Because it is a ligand of platelet surface receptors and an ECM component, fibronectin has long been suspected of playing a role in platelet biology.4,5 Interestingly, fibronectin and its type I module, of which there are 12 in fibronectin (Figure), are well characterized to date only in vertebrates.7,8 Therefore, fibronectin seems to be a recent addition to the armamentarium of proteins that function in the vertebrate vasculature. A, Diagram of dimeric plasma fibronectin. N termini are on the outsides, and C termini are in the middle. The bulk of each subunit consists of 12 type I, 2 type II, and 15 type III modules. One subunit contains the alternatively spliced V region. The N-terminal regions that bind to platelet surface sites of fibronectin assembly and RGD-containing module III-10 that binds to αIIbβ3 and other platelet integrins are indicated. Below is a simplified model in which the C-terminal region is represented as an oval and the III-10 modules as triangles. B, Depiction of interactions of fibronectin with platelets. Circulating soluble …

Fibronectin adsorption on Fe–Cr alloy studied by XPS

AbstractImproved knowledge of the chemical composition of biomaterial surfaces and a better understanding of interactions between biomolecules and material surfaces will allow a more rational design of biomaterials. Surface characterisation of alloys before and after their interaction with proteins is an essential aspect of this approach. In this work, the interactions of fibronectin with stainless steel surfaces (Fe–17Cr alloy) were studied by X‐ray photoelectron spectroscopy (XPS). Different solution concentrations of fibronectin were tested (0, 8, 60, 120 and 240 µg ml−1) in interaction with the stainless steel sample. N 1s, C 1s, Cr 2p and Fe 2p core level spectra were systematically recorded and compared. The results indicate that fibronectin is adsorbed on the stainless steel surface. The alloy surface composition and oxide thickness are almost unchanged (Fe2O3—Cr2O3 + Cr(OH)3) in presence of the protein, whatever the protein solution concentration. The isotherm of fibronectin adsorption at 37 °C was measured. A saturation is clearly reached for solution concentrations greater than 60 µg ml−1. On the plateau, the equivalent protein thickness is 6.3 nm, corresponding to one fibronectin monolayer. Copyright © 2006 John Wiley & Sons, Ltd.

Fibronectin Displacement at Polymer Surfaces

The interactions of fibronectin with thin polymer films are studied in displacement experiments using human serum albumin. Fibronectin adsorption and exchange on two different maleic anhydride copolymer surfaces differing in hydrophobicity and surface charge density have been analyzed by quartz crystal microbalance and laser scanning microscopy with respect to adsorbed amounts, viscoelastic properties, and conformation. Fibronectin is concluded to become attached onto hydrophilic surfaces as a "softer", less rigid protein layer, in contrast to the more rigid, densely packed layer on hydrophobic surfaces. As a result, the fibronectin conformation is more distorted on the hydrophobic substrates together with remarkably different displacement characteristics in dependence on the adsorbed fibronectin surface concentration and the displacing albumin solution concentration. While the displacement kinetic remains constant for the strongly interacting surface, an acceleration in fibronectin exchange is observed for the weakly interacting surface with increasing fibronectin coverage. For displaced amounts, no change is determined for the hydrophobic substrate, in contrast to the hydrophilic substrate with a decrease of fibronectin exchange with decreasing coverage leading finally to a constant nondisplaceable amount of adsorbed proteins. Furthermore, the variation of the albumin exchange concentration reveals a stronger dependence of the kinetic for the weakly interacting substrate with higher rates at higher albumin concentrations.

Binding and orientation of fibronectin on surfaces with collagen-related peptides. Student Research Award in the Masters Science Degree Candidate category, 27th annual meeting of the Society for Biomaterials, St. Paul, MN, April 24-29, 2001.

Although fibronectin (FN) has been used in a variety of in vitro studies to enhance cell and bacteria adhesion, relatively little is known about the molecular interactions of FN with surfaces, particularly the interactions that can control the binding, conformation, and functionality of FN on these surfaces. Even less is known about approaches needed to control binding, orientation, and functionality of FN bound on surfaces. To begin to fill this gap in our knowledge, we hypothesized that functional FN can be bound and specifically oriented on polystyrene surfaces with FN-specific collagen-related peptides (CRPs). We further hypothesized that monoclonal antibodies that react with specific epitopes on FN can be used to quantify both FN binding and orientation on these surfaces. On the basis of these hypotheses, we initiated a systematic investigation of the binding and orientation of FN on polystyrene surfaces with CRPs. To bind FN to surfaces, we used two different CRPs: CRP-I (TLQPVYEYMVGV) and CRP-II (TGLPVGVGYVVTVLT). The binding and orientation of the FN molecule to these immobilized CRPs was quantified with (125)I-FN and monoclonal antibodies. Monoclonal antibodies used for this study were reactive with specific regions of the FN molecule, that is, the amino (N) terminus (anti-N antibodies) and carboxyl (C) terminus (anti-C antibodies). The results of our studies demonstrated that although CRP-I and CRP-II could be bound directly to polystyrene, these directly immobilized CRPs failed to bind (125)I-FN . Thus, to facilitate FN binding to the CRPs, we used bovine serum albumin (BSA) as a spacer to physically elevate the CRPs away from the polystyrene surface. Thus, CRP-I and CRP-II were covalently linked to BSA via the N and C termini of each CRP (CRP-I-BSA and CRP-II-BSA). (125)I-CRP-BSAs were all found to bind to equivalent levels on polystyrene (1.60-2.60 microg/cm2). When CRP-BSAs were immobilized on polystyrene, they all successfully bound (125)I-FN in a range of 34-72 ng/cm2 (mean). Using monoclonal antibodies to FN to characterize the orientation of FN bound to the various CRP-BSAs, we demonstrated that (1) FN consistently bound to either CRP-I-BSA or CRP-II-BSA; (2) bound FN reacted significantly more with anti-C antibodies than with anti-N antibodies; and (3) the increased reactivity of bound FN to anti-C antibodies was consistent, whether FN was bound by CRP-I or CRP-II or the CRPs were bound to BSA by the C or N termini. These data demonstrated an enhanced binding of anti-C antibodies to immobilized CRP-BSA relative to anti-N antibodies. We interpreted the data to be the result of FN binding in an oriented fashion with N termini of FN bound tightly to the BSA-polystyrene surface. In this position, the C termini of FN are exposed and available for binding by the anti-C antibodies. Alternatively, in this orientation the N termini of the FN would not be available to bind the anti-N antibodies, thereby explaining the decreased reactivity of the CRP immobilized FN to the anti-N antibodies. These studies not only demonstrate the utility of peptides in binding and orienting large molecular weight proteins such as FN on surfaces but underscore the need for well-characterized reagents (e.g., monomeric/functional FN and antibodies) to specifically bind, orient, and characterize large molecular weight proteins immobilized on various surfaces.

Alteration of fibronectin affinity during differentiation modulates the in vitro migration velocities of Hydra nematocytes.

In the fresh water Cnidarian Hydra nematocytes differentiate from stem cells in the body column of the polyps and are functional in the tentacles to where they migrate as single cells in an amoeboid fashion. The fluorescent vital stain TROMI (tetramethyl-rhodamine-5/6-maleimide) allows to easily discriminate between cells located in the body column and cells mounted in the tentacles. The two cell populations were found to have different in vitro migration properties. These differences appear to be due largely to a differential attachment to fibronectin. Nematocytes from the tentacles show significantly lower in vitro migration velocities on isolated pieces of the organisms extracellular matrix (the mesoglea) and attach more firmly to fibronectin-coated substrates than cells from the body column. Pretreatment of the mesogleae with antibodies against the cell binding domain of fibronectin or addition of RGD-peptides results in an increase of the average migration velocity of cells from the tentacles and a decreased velocity of the cells from the body column. These findings suggest that (1) modulation of the attachment to fibronectin is decisive for the observed differential migration properties of the two cell populations and (2) the in vitro migration of nematocytes is dependent on subtle and transient interactions of cell surface receptors (most probably integrins) and fibronectin.

Developing blood vessels and associated extracellular matrix as substrates for neural crest migration in Japanese quail, Coturnix coturnix japonica.

Japanese quail embryos were used to examine paths of neural crest cell (NC) migration in relationship to the embryonic vasculature. Immunolabeling for NC, angioblasts and the extracellular matrix (ECM) glycoproteins fibronectin (FN), laminin (LN) and tenascin (TN) revealed several instances where spatiotemporal patterns of NC migration coincide with the embryonic vascular pattern and its associated ECM. An in vitro model for angiogenesis was modified to include NC, and associations with "capillary-like" endothelial cell structures were demonstrated. A working hypothesis is that the embryonic vasculature may, in specific instances, be used as a substratum for directed NC migration and that these interactions are mediated primarily through the adhesive interactions of FN. Some members of the TN family of glycoproteins, through their relatively non-adhesive properties, may act to help guide neural crest cells to the FN-rich blood vessel surface.

Functional Interactions of Fibronectin and TNFα: A Paradigm of Physiological Linkage Between Cytokines and Extracellular Matrix Moieties

The ECM is composed of various cell-adhesive glycoproteins, such as, fibronectin (FN), laminin (LN), and different types of glycosaminoglycans and proteoglycans. These building blocks of the ECM are linked together to form a dense and complex tissue that fills the interstitial spaces and comprises the boundaries between cells and tissues. The ECM is the major milieu in which immune cells function during inflammatory processes (Shimizu and Shaw, 1991; Yamada, 1991). Recognition of ECM-glycoproteins by immune cells is mediated by very late activation (VLA) receptors, also referred to as integrins of the β1-subfamily (Hynes, 1992). A prerequisite of lymphocyte-ECM interactions is activation of the cells by mitogens, or via their CD3-T cell receptor complex, either of these types of activation modulates the affinity of otherwise inactive β1-integrins (Shimizu, et al., 1990).

Interactions of complement fraction C1q, fibronectin, and immunoglobulin G with polyacrylic microparticles used as solid-phase in immunoassay.

A microparticle-enhanced nephelometric immunoassay was recently described, where polyacrylic, hydrophilic, and polyfunctional microparticles are used as the solid phase. It is a one-step immunoassay based on the nephelometric quantification of microparticle agglutination. In such assays, the measurement of analytes at low concentration may be impaired by the need of using undiluted biological samples. This leads to work with high concentrations of several proteins liable to interfere with the agglutination process. In this paper, we report on a study performed with human serum and purified proteins, which were assayed by classical analytical methods. This work identified three major components of human serum specifically involved in yielding polyacrylic microparticle instability: complement fraction C1q, fibronectin, and immunoglobulins G. In this order of importance, they all showed a marked ability to be adsorbed on the microparticle's surface. Pretreatment of human serum with microparticles decreased the concentrations in C1q (82%), fibronectin (16%), and immunoglobulin G (4%) very unequally. However, it allowed the elimination of microparticle instability, consequently providing the possible use of such polyacrylic microparticles in a one-step nephelometric immunoassay of analytes at low concentration in biological samples, without washes or phase separation.

Protein kinase C involvement in focal adhesion formation.

Matrix molecules such as fibronectin can promote cell attachment, spreading and focal adhesion formation. Although some interactions of fibronectin with cell surface receptors have now been identified, the consequent activation of intracellular messenger systems by cell/matrix interactions have still to be elucidated. We show here that the kinase inhibitors H7 and HA1004 reduce focal adhesion and stress fiber formation in response to fibronectin in a dose-dependent manner, and that activators of protein kinase C can promote their formation under conditions where they do not normally form. Fibroblasts spread within 1h on substrata composed of fibronectin and formed focal adhesions by 3h, as monitored by interference reflection microscopy (IRM) and by labeling for talin, vinculin and integrin beta 1 subunits. In addition, stress fibers were visible. When cells were allowed to spread for 1h and then treated with kinase inhibitors H7 and HA1004 for 2h, IRM indicated a reduction in focal adhesion formation at concentrations where protein kinase C (PKC) should be inhibited. In contrast, focal adhesions formed normally at concentrations of these inhibitors where cyclic AMP- or cyclic GMP-dependent kinases should be inactivated. Inhibition of PKC, but not that of cyclic AMP- or cyclic GMP-dependent kinases, also prevented the formation of stress fibers and induced a dispersal of talin and vinculin, but not integrin beta 1 subunits, from small condensations present at 1h. Consistent with the reduction in focal adhesion formation when PKC was inhibited, activation of PKC by 30 minutes of treatment with phorbol esters induced focal adhesion formation in cells spread for 3h on substrata composed of the cell-binding (RGD-containing) fragment of fibronectin, while untreated cells or those treated with inactive phorbol esters did not form these structures.