Dynamics and elasticity of the fibronectin matrix in living cell culture visualized by fibronectin-green fluorescent protein. (9/9343)

Fibronectin (FN) forms the primitive fibrillar matrix in both embryos and healing wounds. To study the matrix in living cell cultures, we have constructed a cell line that secretes FN molecules chimeric with green fluorescent protein. These FN-green fluorescent protein molecules were assembled into a typical matrix that was easily visualized by fluorescence over periods of several hours. FN fibrils remained mostly straight, and they were seen to extend and contract to accommodate movements of the cells, indicating that they are elastic. When fibrils were broken or detached from cells, they contracted to less than one-fourth of their extended length, demonstrating that they are highly stretched in the living culture. Previous work from other laboratories has suggested that cryptic sites for FN assembly may be exposed by tension on FN. Our results show directly that FN matrix fibrils are not only under tension but are also highly stretched. This stretched state of FN is an obvious candidate for exposing the cryptic assembly sites.  (+info)

Identification of protein-disulfide isomerase activity in fibronectin. (10/9343)

Assembly and degradation of fibronectin-containing extracellular matrices are dynamic processes that are up-regulated during wound healing, embryogenesis, and metastasis. Although several of the early steps leading to fibronectin deposition have been identified, the mechanisms leading to the accumulation of fibronectin in disulfide-stabilized multimers are largely unknown. Disulfide-stabilized fibronectin multimers are thought to arise through intra- or intermolecular disulfide exchange. Several proteins involved in disulfide exchange reactions contain the sequence Cys-X-X-Cys in their active sites, including thioredoxin and protein-disulfide isomerase. The twelfth type I module of fibronectin (I12) contains a Cys-X-X-Cys motif, suggesting that fibronectin may have the intrinsic ability to catalyze disulfide bond rearrangement. Using an established protein refolding assay, we demonstrate here that fibronectin has protein-disulfide isomerase activity and that this activity is localized to the carboxyl-terminal type I module I12. I12 was as active on an equal molar basis as intact fibronectin, indicating that most of the protein-disulfide isomerase activity of fibronectin is localized to I12. Moreover, the protein-disulfide isomerase activity of fibronectin appears to be partially cryptic since limited proteolysis of I10-I12 increased its isomerase activity and dramatically enhanced the rate of RNase refolding. This is the first demonstration that fibronectin contains protein-disulfide isomerase activity and suggests that cross-linking of fibronectin in the extracellular matrix may be catalyzed by a disulfide isomerase activity contained within the fibronectin molecule.  (+info)

Cortical bitufted, horizontal, and Martinotti cells preferentially express and secrete reelin into perineuronal nets, nonsynaptically modulating gene expression. (11/9343)

Reelin (Reln) is a protein with some structural analogies with other extracellular matrix proteins that functions in the regulation of neuronal migration during the development of cortical laminated structures. In the cortex of adult animals, Reln is expressed primarily in gamma-aminobutyric acid (GABA)ergic neurons and is secreted into perineuronal nets. However, only 50-60% of GABAergic interneurons express Reln. We have characterized this subpopulation of cortical GABAergic neurons that expresses Reln by using two strategies: (i) a double immunolabeling procedure to determine the colocalization of Reln with neuropeptides and Ca2+-binding proteins and (ii) a combination of Golgi staining and Reln immunolabeling to determine the morphology of the rat cortical cells that store Reln. Many interneurons that express Neuropeptide Y (NPY) or somatostatin (but none of those that express parvalbumin) are Reln-immunopositive. A small population of calbindin-positive interneurons and very few calretinin-positive cells express Reln immunopositivity. Golgi staining revealed that layer I horizontal cells, layer II-V bitufted neurons, and some deep cortical layer Martinotti cells express Reln. Basket and chandelier cells are often immunopositive to parvalbumin, but never to Reln. Although Reln is secreted by GABAergic neurons, its target are not the GABA receptors, but rather may be extrasynaptically located in perineuronal nets and concerned with the modulation of neuronal plasticity. Dab1, the target adapter protein that presumably mediates transcription regulation via the extrasynaptic actions of Reln, is expressed predominantly in pyramidal neurons, but it can also be detected in a small population of GABAergic neurons that are neither horizontal nor bitufted neurons.  (+info)

Connective tissues: matrix composition and its relevance to physical therapy. (12/9343)

In the last 2 decades, the understanding of CT structure and function has increased enormously. It is now clear that the cells of the various CTs synthesize a variety of ECM components that act not only to underpin the specific biomechanical and functional properties of tissues, but also to regulate a variety of cellular functions. Importantly for the physical therapist, and as discussed above, CTs are responsive to changes in the mechanical environment, both naturally occurring and applied. The relative proportions of collagens and PGs largely determine the mechanical properties of CTs. The relationship between the fibril-forming collagens and PG concentration is reciprocal. Connective tissues designed to resist high tensile forces are high in collagen and low in total PG content (mostly dermatan sulphate PGs), whereas CTs subjected to compressive forces have a greater PG content (mostly chondroitin sulphate PGs). Hyaluronan has multiple roles and not only provides tissue hydration and facilitation of gliding and sliding movements but also forms an integral component of large PG aggregates in pressure-resisting tissues. The smaller glycoproteins help to stabilize and link collagens and PGs to the cell surface. The result is a complex interacting network of matrix molecules, which determines both the mechanical properties and the metabolic responses of tissues. Patients with CT problems affecting movement are frequently examined and treated by physical therapists. A knowledge of the CT matrix composition and its relationship to the biomechanical properties of these tissues, particularly the predictable responses to changing mechanical forces, offers an opportunity to provide a rational basis for treatments. The complexity of the interplay among the components, however, requires that further research be undertaken to determine more precisely the effects of treatments on the structure and function of CTs.  (+info)

Role of extracellular matrix and Ras in regulation of glomerular epithelial cell proliferation. (13/9343)

Signals from extracellular matrix (ECM) to growth factor receptors regulate glomerular epithelial cell (GEC) proliferation. Epidermal growth factor (EGF), basic fibroblast growth factor, hepatocyte growth factor (HGF), or thrombin stimulated proliferation of GECs when the cells were adherent to collagen matrices, but not plastic substratum. Furthermore, EGF, HGF, or thrombin activated p42 mitogen-activated protein (MAP) kinase in collagen-adherent GECs, whereas activation was weak in GECs on plastic. To further examine the interaction of ECM with the Ras-MAP kinase cascade, GECs were stably transfected with a constitutively active Ras mutant (V12Ras). Low or moderate levels of V12Ras expression did not affect basal MAP kinase activity but, unlike parental GECs, in clones that express V12Ras, EGF was able to induce proliferation and activate MAP kinase when these cells were adherent to plastic. In parental and V12Ras-transfected GECs, MAP kinase activation was inhibited by cytochalasin D. Thus, adhesion of GECs to ECM facilitates proliferation and MAP kinase activation by mitogens acting via tyrosine kinase or non-tyrosine kinase receptors. Activation of pathway(s) downstream of V12Ras supplants signals from ECM that enable proliferation. These signals may involve the actin cytoskeleton.  (+info)

Echocardiography-derived left ventricular end-systolic regional wall stress and matrix remodeling after experimental myocardial infarction. (14/9343)

OBJECTIVES: We tested the hypothesis that regional end-systolic left ventricular (ESLV) wall stress is associated with extracellular matrix remodeling activity after myocardial infarction (MI). BACKGROUND: Increased left ventricular (LV) wall stress is a stimulus for LV enlargement, and echocardiography can be used to estimate regional wall stress. A powerful validation of a noninvasive method of estimating wall stress would be predicting cellular responses after a MI. METHODS: Echocardiographic images were obtained in rats 1, 7, 14 or 21 days after coronary ligation (n = 11) or sham surgery (n = 5). End-systolic left ventricular wall stress was calculated by finite element analysis in three regions (infarcted, noninfarcted and border) from short-axis images. Matrix metalloproteinase-9 (MMP-9) and macrophage density were determined by immunohistochemistry, and positive cells were counted in high power fields (hpf). RESULTS: Average ESLV wall stress was higher in rats with MI when compared to shams irrespective of time point (p < 0.01), and ESLV wall stress in the infarcted regions increased with time (25.1 +/- 5.9 vs. 69.9 +/- 4.4 kdyn/cm2, day 1 vs. 21; p < 0.01). Matrix metalloproteinase-9 expression was higher in infarcted and border regions when compared to noninfarcted regions (22.1 vs. 25.7 vs. 0.10 cells/hpf, respectively; p < 0.01). Over all regions, ESLV wall stress was associated with MMP-9 (r = 0.76; p < 0.001), macrophage density (r = 0.72; p < 0.001) and collagen content (r = 0.67; p < 0.001). End-systolic left ventricular wall stress was significantly higher when MMP-9 positive cell density was greater than 10 cells/hpf (45+/-20 vs. 14+/-10 kdyn/cm2; p < 0.001). CONCLUSIONS: Regional increases in ESLV wall stress determined by echocardiography-based structural analysis are associated with extracellular matrix degradation activity.  (+info)

Antibodies to CD18 influence neutrophil migration through extracellular matrix. (15/9343)

Mac-1 (CD11b/CD18) is known to be involved in neutrophil (PMN) adhesion to endothelial cells and extracellular matrix. Although antibodies to CD 18 are being tested for therapy in humans, their role in PMN migration through the extracellular matrix is unknown. We used direct visualization to quantify PMN motility through reconstituted, three-dimensional gels of collagen type I. Gels were prepared with different concentrations of collagen (ranging from 0.1 to 1.0 mg/mL) and PMN migration was examined in the presence and absence of antibodies to CD18 (anti-CD18), with and without stimulation by N-formyl peptides. In low-concentration gels (<0.6 mg/mL), anti-CD18 had a significant influence on PMN migration, increasing motility in unstimulated PMN by 90% at 0.3 mg/mL collagen, and decreasing motility in N-formyl-methionyl-leucyl-phenylalanine (fMLP)-stimulated PMN by 70% at 0.4 mg/mL collagen. But antiCD18 had no effect on the rate of cell migration through high-concentration collagen gels (>0.6 mg/mL). PMN migration through collagen gels is CD18-dependent but only under conditions of high hydration, suggesting that CD18-mediated effects (e.g., adhesion to gel fibers) are only important when the fiber density is relatively low. Anti-CD18 inhibited, but did not eliminate, the adhesion of fMLP-stimulated PMN to the surface of collagen gels, suggesting that cells use multiple mechanisms for gaining traction within the gel. Because of the multiple modes of interaction between motile cells and the deformable fiber matrix, blockade of one component, such as CD18, can enhance the rate of cell migration under one set of conditions, and inhibit under another.  (+info)

Development of cytotrophoblast columns from explanted first-trimester human placental villi: role of fibronectin and integrin alpha5beta1. (16/9343)

Human first-trimester floating mesenchymal villi explanted onto gels of collagen I or Matrigel were observed to undergo de novo development of anchoring sites. These consisted of cytotrophoblast columns that formed by proliferation of stem villous cytotrophoblast cells, as revealed by whole-mount and thin-section microscopy and incorporation of bromodeoxyuridine into DNA. Column formation occurred exclusively at the distal tips of the villi. No column formation was observed in tissue explanted onto agarose. On Matrigel, the developing columns penetrated downwards into the matrix, whereas on collagen I, cytotrophoblast sheets spread across the surface of the gel and merged to form a shell. The developing columnar cytotrophoblast up-regulated integrins alpha1beta1 and alpha5beta1 and produced an extracellular matrix containing oncofetal fibronectin, as in vivo. Function-blocking antibodies were used to investigate the role of the integrin-fibronectin interaction in anchoring villus development on collagen I. Antibodies to fibronectin and the integrin subunits alpha5 and beta1, added at 24 h, all changed the pattern of cytotrophoblast outgrowth. Anti-fibronectin caused cell rounding within the cytotrophoblast sheet and increased the population of single cells at its periphery. Anti-integrin alpha5 caused rounding and redistribution of cells within the outgrowth. In the presence of anti-integrin beta1, cell-collagen interactions within the sheet were destabilized, often leading to the appearance of an annulus of aggregated cells at the periphery. These results show that 1) mesenchymal villi retain the potential to form anchoring sites until at least the end of the first trimester, 2) adhesion to a permissive extracellular matrix stimulates cytotrophoblast proliferation and differentiation along the extravillous lineage, 3) integrin alpha5beta1-fibronectin interactions contribute significantly to anchorage of the placenta to uterine extracellular matrix. We suggest that as the developing placenta ramifies, new sites of anchorage form whenever peripheral villi contact decidua. This process is predicted to contribute to the stability of the placental-decidual interface.  (+info)