We report the effect of Fab' (anti-60k) to a 60,000 mol wt gelatin binding domain of fibronectin (1981, J. Biol . Chem . 256:5583) on diploid fibroblast (IMR-90) extracellular fibronectin and collagen organization . Anti-60k Fab' did not inhibit IMR-90 attachment or proliferation in fibronectin-depleted medium . Fibroblasts cultured with preimmune Fab' deposited a dense extracellular network of fibronectin and collagen detectable by immunofluorescence, while anti-60k Fab' prevented extracellular collagen and fibronectin fibril deposition . Matrix fibronectin and collagen deposition remained decreased in cultures containing anti-60k Fab' until cells became bilayered or more dense, when fibronectin and collagen began to appear in lower cell layers . Anti-60k Fab' added to confluent cultures 24 h before fixation and staining had no effect on matrix fibronectin or collagen, so anti-60k Fab' did not simply block immunostaining . Confluent cultures grown in anti-60k Fab' and labeled for 24 h with [3H]proline incorporated identical amounts of [3H]proline and [3H]hydroxyproline, but [3H]hydroxyproline deposition in the cell layer was significantly decreased by anti-60k Fab' (P < 0.01) . Extracellular matrix collagen does not appear to form a scaffold for fibronectin deposition, as neither gelatin nor a gelatin-binding fragment of plasma fibronectin inhibited deposition of matrix fibronectin . Our results suggest that interstitial collagens and fibronectin interact to form a fibrillar component of the extracellular matrix, and that fibronectin is required for normal collagen organization and deposition by fibroblasts in vitro. Domain-specific antibodies to fibronectin are powerful tools to study the biological role of fibronectin in extracellular matrix organization and other processes.Fibronectin (FN) is a major synthetic product of diploid fibroblasts (1) organized in discrete extracellular matrix fibrils also containing procollagen types I and 111 (3,5,11,14,42). FN is associated with collagen or collagen precursors in extracellular matrix in vivo in human lung specimens (32), in implanted cellulose sponges (26), and during wound healing (13). The distribution of FN and its multiple binding to other matrix components and cells in vitro (36,39,45 ; and references therein) implicate FN in organization of glycosaminoglycans and collagens in extracellular matrix, and in the interaction of cells with these matrix components . However, direct demonstration of FN-mediated organization of other matrix components is lacking.
Abstract. Cells interact with extracellular fibronectin (FN) via adhesive fibronectin receptors (FNRs) that are members of the very late antigens (VLAs) subgroup of the integrin family. In stationary fibroblasts, the FNR is highly organized and distributed identically to extracellular FN fibrils. However, in highly migratory neural crest cells and embryonic somatic fibroblasts, this organization is lost and the FNR appears diffuse. Similarly, oncogenic transformation typically leads to disorganization of the FN receptor and loss of matrix FN. Two models can account for these observations. First, the FN matrix may organize the FN receptor at extracellular matrix contacts on the cell surface. Motile cells not depositing FN matrices thus lack organized receptors. Alternatively, as the FNR is required for optimal FN matrix assembly, (McDonald, J. A., B. J. Quade, T. J. Broekelmann, R. LaChance, K. Forseman, K. Hasegawa, and S. Akiyama. 1987. J. Biol. Chem. 272:2957-2967; Roman, J., R. M. LaChance, T. J. Broekelmann, C. J. R. Kennedy, E. A. Wayner, W. G. Carter, J. A. McDonald. 1989. J. Cell Biol. 108:2529-2543 and has putative cytoskeletal links, it could be organized from within the cell helping to position newly forming FN fibrils. To study this question, we developed peptide antibodies specifically recognizing the a5 subunit of the FNR.Using these antibodies, we examined the organization of FN and of the FNR in normal, matrix assembly inhibited, and SV40-transformed human fibroblasts. On FN-coated substrates, the FNR is found in focal contacts rather than diffusely on the basal cell surface, suggesting FNR interaction with intracellular components. However, when FN fibrils are deposited, the FNR is co-distributed with these fibrils. Preventing FN matrix assembly prevents organization of the FNR. Moreover, when fibroblasts with well established FN matrices and co-distributed FNR are incubated briefly with monoclonal antibodies that block FNR binding to FN, the FNR is no longer co-distributed with the FN matrix. Thus, the FN receptor is organized in fibrils on the cell surface in response to extracellular FN. Because exogenous FN restores a FN matrix and receptor organization to SV40-transformed cells, the diffuse FN receptor phenotype appears to be related to loss of the FN matrix rather than to impaired FNR function. These results explain diffusely distributed FNRs in migratory neural crest and embryonic fibroblasts lacking well organized FN matrices and emphasize the existence of separate but related systems controlling FN deposition and recognition by receptor-armed cells.
Excessive collagen deposition plays a critical role in the development of fibrosis, and early or active fibrosis may be more susceptible to therapeutic intervention than later stages of scarring. However, at present there is no simple method for assessing the collagen-synthesizing and secreting activity of fibroblasts in human tissues. Type I procollagen carboxyterminal domains are proteolytically removed during collagen secretion. Thus, antibodies to these domains should stain fibroblasts synthesizing type I collagen but not extracellular collagen fibrils which could mask the signal from the cells. We developed and characterized a monoclonal antibody (Anti-pC) specific for the carboxyterminal propeptide of type I procollagen.
Lung engineering is a promising technology, relying on re-seeding of either human or xenographic decellularized matrices with patient-derived pulmonary cells. Little is known about the species-specificity of decellularization in various models of lung regeneration, or if species dependent cell-matrix interactions exist within these systems. Therefore decellularized scaffolds were produced from rat, pig, primate and human lungs, and assessed by measuring residual DNA, mechanical properties, and key matrix proteins (collagen, elastin, glycosaminoglycans). To study intrinsic matrix biologic cues, human endothelial cells were seeded onto acellular slices and analyzed for markers of cell health and inflammation. Despite similar levels of collagen after decellularization, human and primate lungs were stiffer, contained more elastin, and retained fewer glycosaminoglycans than pig or rat lung scaffolds. Human endothelial cells seeded onto human and primate lung tissue demonstrated less expression of vascular cell adhesion molecule and activation of nuclear factor-κB compared to those seeded onto rodent or porcine tissue. Adhesion of endothelial cells was markedly enhanced on human and primate tissues. Our work suggests that species-dependent biologic cues intrinsic to lung extracellular matrix could have profound effects on attempts at lung regeneration.
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