Transforming growth factor beta responsiveness is modulated by the extracellular collagen matrix during hepatic ito cell culture

Hepatic sinusoidal Ito cells have the capacity to produce interstitial collagen types I and III as well as other matrix proteins and may be involved in hepatic fibrogenesis. Transforming growth factor beta (TGF beta) responsiveness was evaluated during in vitro cell culture, since increasing evidence suggests that this ubiquitous polypeptide can stimulate the production of collagenous proteins in a variety of cell types. TGF beta induced marked inhibition of Ito cell proliferation for cells grown on either a type I or a type IV collagen matrix. In marked contrast, the collagen synthetic response was considerably different for cells grown on a type I versus a type IV collagen matrix. When cells were grown on a type I collagen matrix, TGF beta caused a significant increase in the accumulation of collagen type I and III. When Ito cells were grown on a type IV collagen matrix, there was no stimulation of collagen production. TGF beta responsiveness was also evaluated in the setting of altered vitamin A concentrations. Freshly isolated Ito cells are engorged with vitamin A, the usual physiologic storage site for hepatic vitamin A. During in vitro culture and during in vivo fibrogenesis, Ito cells lose their vitamin A stores coincident with a transformation to a collagen-producing myofibroblast-like cell. When cultured Ito cells were grown on a type I collagen matrix and re-exposed to an increased concentration of vitamin A, the production of interstitial collagen was reduced. However, when the vitamin A-enriched Ito cells were exposed to TGF beta, the production of interstitial collagen was increased, similar to cells that had not received vitamin A.     

Analysis of the collagen types synthesized by bovine corneal endothelial cells in culture.

Bovine corneal endothelial cells synthesize in culture predominantly type III collagen, with lesser amounts of types I and V and apparently little if any type IV. This pattern of synthesis is observed in both dividing and post-confluent cultures and irrespective of whether cells are attached to plastic or collagen-coated surface.     

The effect of a native collagen gel substratum on the synthesis of collagen by bovine brain capillary endothelial cells

Cultured capillary endothelial cells, derived from bovine brain, and maintained on a plastic substratum synthesized predominantly interstitial collagens of which approximately 75 per cent were secreted into the medium. When grown on a native hydrated collagen type I gel, although no marked alteration in the 'collagen synthetic pattern' was observed, the overall level of collagen synthesis was increased by approximately 100 per cent. More dramatic, however, was the alteration in the distribution of these molecules between medium and cell layer. Interstitial collagens produced by cells grown on collagen gels were almost exclusively associated with the cell layer or collagenous gel. These studies, thus, demonstrate that an extracellular matrix may exert a considerable influence on the cellular synthetic activities and possibly cellular polarity of capillary endothelial cells.     

Type I collagen preparations inhibit DNA synthesis in glial cells of the peripheral nervous system

The mechanisms underlying cessation of glial proliferation in the developing peripheral nervous system are obscure. One possibility, as yet little explored, is that mitotic inhibitory signals play a part in regulating glial cell numbers. In this study we demonstrate that type I collagen preparations from several different sources can inhibit the rate of DNA synthesis in purified populations of enteric glia and both short-term and long-term secondary Schwann cells in dissociated cell cultures. When these cells are grown on gelled or dried type I collagen substrata, they proliferate at substantially lower rates than on polylysine substrata. In contrast, type III or V collagen preparations do not inhibit glial DNA synthesis and laminin, fibronectin, type IV collagen, and secreted matrix from bovine corneal endothelial cells all stimulate thymidine incorporation. The inhibitory effect is not observed with heat denatured type I collagen preparations, but is seen equally in serum-containing medium, in medium containing fibronectin-free serum, or in serum-free medium, suggesting that the interaction of collagen with the cells requires structurally intact collagen molecules and does not occur via intermediary linkage to fibronectin. The inhibition on collagen is accompanied by a shape change from a more flattened morphology to a narrow spindle form. The labeling index of a rat Schwannoma cell line, 33B, is not inhibited on type I collagen substrata. These results demonstrate that type I collagen preparations inhibit the DNA synthesis levels of early postnatal peripheral glial cells in vitro. It remains to be determined whether this effect occurs via direct collagen-cell membrane interactions or whether it depends on accessory molecules, perhaps present in the collagen preparations themselves, since these are not purified to absolute homogeneity.     

Comparison of the collagenous products synthesized in culture by pig aortic endothelial and smooth-muscle cells. Variability in endothelial-cell cultures.

In contrast with smooth-muscle cells from the same tissue, endothelial cells from pig aorta were found to exhibit in culture considerable variability in the pattern of collagen synthesis between one isolation of cells and the next. Synthesis varied from largely collagen type I to virtually all type III in the absence of type I but with small amounts still of collagens types IV and V, to, in one instance, synthesis basically of only type V. Synthesis usually by these cells of collagen predominantly of the interstitial type (I and III) rather than, as might be expected, that from basement membrane (type IV) was not attributable to the influence of subculture. All four collagen types were deposited in the cell layer to an increased extent in primary compared with secondary cultures of either smooth muscle or endothelial origin. Endothelial cells appeared sometimes to synthesize a large-Mr collagenous entity that might conceivably be related to 'short-chain' collagen. In addition, small-Mr hydroxyproline-containing peptides were detected that might reflect rapid collagen(s) turnover in endothelial cultures.     

Retinol and extracellular collagen matrices modulate hepatic Ito cell collagen phenotype and cellular retinol binding protein levels

The hepatic vitamin A-storing Ito cell has been implicated as a causative cell in hepatic fibrogenesis. Using a modification of a recent method (Friedman, S. L., Roll, F. J., Boyles, J., and Bissell, D. M. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 8681-8685), rat Ito cells were isolated and passaged in vitro on collagen-coated plastic dishes through cell generation 40-50. The collagen synthetic phenotype for Ito cells grown on various extracellular matrices was demonstrated by immunofluorescence and quantitated by competition enzyme-linked immunosorbent assays. When grown on a type I collagen matrix, Ito cells produced type IV greater than type III greater than type I collagen. When grown on a type IV collagen matrix, the cells produced relatively equal amounts of types I and III collagen. The absolute amounts of type I collagen produced were greater when cells were grown on type IV versus type I matrix. When 10(-5) M retinol was added to cell cultures, there was a uniform increase in type III collagen regardless of matrix type but a decrease in type I collagen when cells were grown on a type IV matrix and a large increase in type I collagen when cells were grown on a type I collagen matrix. The levels of cellular retinol binding protein, a key cytosolic retinol transport protein, were quantitated by high performance liquid chromatography and compared for cells grown on type I versus type IV collagen matrices. It was found that cells on a type I matrix contain 4.96 +/- 2.8 times more cellular retinol binding protein than do cells grown on a type IV matrix. In conclusion, Ito cell collagen synthesis may be altered by underlying extracellular matrix and exogenous retinol. This in vitro culture system should allow the study of regulatory factors and possible therapeutic anti-fibrogenic mediators.     

Phenotypic differences in subclones and long-term cultures of clonally derived rat bone cell lines

Previous studies with clonally derived populations of cells have shown that cells released from embryonic rat calvaria by enzymatic digestion are heterogeneous with respect to their hormone responsiveness, morphology, and production of matrix components [Aubin JE et al; J. Cell Biol 92:452, 1982]. Several of these clonal populations have been used to study the effects of long-term culture and inter- and intraclonal cell heterogeneity. During continuous subculture, marked changes in collagen synthesis were observed in two clonal populations. Both of these clones were originally responsive to parathyroid hormone (PTH) and synthesized primarily type I collagen with small amounts of type III and V collagens, although one clone (RCJ 3.2) had a fibroblastic morphology whereas the second clone (RCB 2.2) displayed a more polygonal shape. Following routine subculture over 3 yr, clone RCB 2.2 was found to synthesize exclusively alpha 1(I)-trimer and not other interstitial collagens. When the same cells were maintained at confluence for 1-2 wk, however, they also synthesized type III collagen. Whereas RCJ 3.2 did not show such dramatic changes in collagen synthesis after long-term subculture, two subclones derived from RCJ 3.2 were found to synthesize almost exclusively either type III collagen (RCJ 3.2.4.1) or type V collagen (RCJ 3.2.4.4). Immunocytochemical staining indicated that both subpopulations also produced type IV collagen, laminin, and basement membrane proteoglycan, proteins that are typically synthesized by epithelial cells. The differences in collagen expression by the various clonal cell populations were accompanied by qualitative and quantitative differences in other secreted proteins and differences in cell morphology. The results demonstrate both the inter- and intraclonal heterogeneity of connective tissue cells and their diverse potentiality with respect to extracellular matrix synthesis.     

Inhibition of TGF-β Signaling Enables Human Corneal Endothelial Cell Expansion In Vitro for Use in Regenerative Medicine

Corneal endothelial dysfunctions occurring in patients with Fuchs'' endothelial corneal dystrophy, pseudoexfoliation syndrome, corneal endotheliitis, and surgically induced corneal endothelial damage cause blindness due to the loss of endothelial function that maintains corneal transparency. Transplantation of cultivated corneal endothelial cells (CECs) has been researched to repair endothelial dysfunction in animal models, though the in vitro expansion of human CECs (HCECs) is a pivotal practical issue. In this study we established an optimum condition for the cultivation of HCECs. When exposed to culture conditions, both primate and human CECs showed two distinct phenotypes: contact-inhibited polygonal monolayer and fibroblastic phenotypes. The use of SB431542, a selective inhibitor of the transforming growth factor-beta (TGF-β) receptor, counteracted the fibroblastic phenotypes to the normal contact-inhibited monolayer, and these polygonal cells maintained endothelial physiological functions. Expression of ZO-1 and Na⁺/K⁺-ATPase maintained their subcellular localization at the plasma membrane. Furthermore, expression of type I collagen and fibronectin was greatly reduced. This present study may prove to be the substantial protocol to provide the efficient in vitro expansion of HCECs with an inhibitor to the TGF-β receptor, and may ultimately provide clinicians with a new therapeutic modality in regenerative medicine for the treatment of corneal endothelial dysfunctions.     

The different effects of type I and IV collagens on the survival and proliferation of cultured BSC-1 cells

The effects of type I and IV collagens on the survival and proliferation of cells were investigated to clarify a possible involvement of the substratum in the regulation of cell function. BSC-1 cells attached, spread and sustained their viability in the absence of calf serum on culture dishes coated with type IV collagen, but were unable to spread and survive on untreated culture dishes. The effects of adding type IV collagen in solution were similar to those of type IV coating. The fraction of the solution of type IV collagen with molecular mass of more than 100 kDa enhanced spreading and survival of cells, but the fraction of less than 100 kDa did not. Type I collagen did not support cell viability in the absence of calf serum. Moreover, coating of culture dishes with type I collagen, but not with type IV collagen, inhibited DNA synthesis and cell proliferation in the presence of calf serum. The cells grown on type I collagen were long, thin and spindle-shaped, and their stress fibers were not well developed, but the cells grown on type IV collagen, as well as those grown on untreated culture dishes, were polygonal in shape with well-developed stress fibers. These results indicate that the interactions of BSC-1 cells with the substratum, when it is derived from type I and IV collagens, differentially modulate the survival and proliferation of BSC-1 cells.     

The biosynthesis of extracellular-matrix components by bovine retinal endothelial cells displaying distinctive morphological phenotypes.

Previous studies have indicated that the morphology and behaviour of bovine retinal microvessel endothelial cells are influenced by culture conditions in vitro. Data are presented here concerning the biosynthesis of matrix macromolecules by bovine retinal endothelial cells cultured under conditions in which the cells display either the 'cobblestone' or the 'sprouting' phenotype. Newly synthesized matrix proteins were identified by their characteristic electrophoretic mobilities, immunoprecipitation with specific antibodies, susceptibilities to enzymic digestions and chromatographic behaviour. Type IV procollagen was the major collagenous species synthesized by early-passage cells forming a 'cobblestone' monolayer. In contrast, cells displaying the 'sprouting' morphology switched to the predominant synthesis of interstitial fibrillar collagens (types I and III). Fibronectin was synthesized by retinal endothelial cells under all the experimental conditions studied. A non-collagenous glycoprotein of Mr approx. 47,000 was also a major biosynthetic product of these cells. The synthesis of thrombospondin was very much dependent on the nature of the substratum on which the cells were cultured. This glycoprotein was synthesized in large amounts by 'cobblestone' endothelial cells cultured on gelatin-coated dishes, whereas its synthesis was markedly decreased by culturing the cells on collagen gels, and the protein appeared to be absent when the cells were plated within collagen gels ('sprouting' cells). Late-passage retinal cells synthesized predominantly type I procollagen, variable amounts of type III procollagen and only traces of type IV procollagen, irrespective of whether the cells displayed a 'cobblestone' or 'sprouting' morphology.     

Identification of collagens synthesized by cultures of normal human corneal and keratoconus stromal cells

We have examined the collagens synthesized by cultures of normal human corneal stromal cells. Radioactively labeled products, accumulated in the culture medium during a 24-h labeling period, were treated with pepsin and analyzed by SDS-polyacrylamide gel electrophoresis. The cell layer collagen was characterized by 2.6 M and 4.4 M salt fractionation at neutral pH. CM-cellulose column chromatography, SDS-gel electrophoresis, and cyanogen bromide peptide mapping. Type I alpha 1 and alpha 2 chains were the predominant components in both the cell layer and the medium fractions of normal human stromal cultures; type III collagen was found mostly in the culture medium; and type V collagen was associated with the cell layer. Immunofluorescent techniques used to visualize collagen deposition in the cell layer confirmed the presence of these collagen types. Keratoconus is a disease characterized by thinning and scarring of the central cornea. Stromal cells grown from keratoconus corneas produced similar types of collagen (types I, III, and V) as normal human controls. Cells from keratoconus patients, however, contained more type V collagen in the cell layer than did normal cells. The difference was seen only in the 4.4 M salt precipitates. Since type V collagen is one component of cell surfaces, the primary defect in cultures from keratoconus corneas could involve cell membrane and cell surface components.     

Extracellular matrix components synthesized by human amniotic epithelial cells in culture

Epithelial cells from human post-partal amniotic membrane in primary culture secreted two major matrix proteins, fibronectin and procollagen type III, and small amounts of laminin and basement membrane collagens (types IV and AB). Identified in the culture medium by immunoprecipitation, these components were located by immunofluorescence to a pericellular matrix beneath the cell monolayer. Deposition of fibronectin, laminin and procollagen type III occurred under freshly seeded spreading cells. In the matrix of confluent cultures, fibronectin and procollagen type III had a moss-like distribution. Matrix laminin had predominantly a punctate pattern and was sometimes superimposed on the fibronectin-procollagen type III matrix. In the human amniotic membrane in vivo, laminin, type IV collagen and fibronectin were located to a narrow basement membrane directly beneath the epithelial cells. Fibronectin and procollagen type III were detected in the underlying thick acellular compact layer. Fibronectin secreted by amniotic epithelial cells is a disulfide-bonded dimer of slightly higher apparent molecular weight (240 kilodaltons) than fibronectins isolated from human plasma or fibroblast cultures. Laminin was detected in small amounts in the culture medium. Laminin antibodies precipitated a polypeptide of about 400 kilodaltons, and two polypeptides with slightly faster mobility in electrophoresis under reducing conditions than fibronectin. Procollagen type III was by far the major collagenous protein whereas little or no production of procollagen type I could be observed. Basement membrane collagens were identified as minor components in the medium by immunoprecipitation (type IV) or chemical methods (αA and αB chains).     

Interstitial collagen synthesis by somatic testicular cells in culture

The synthesis, distribution and types of collagen produced by somatic testicular cells in culture was studied. To investigate whether changes in collagen synthesis correlate with the age of the animal, cultures derived from immature and pubertal rats were established. Immature rats synthesize 40 per cent more collagen than pubertal rats. Both groups of animals synthesize procollagen types I and III. Pro-collagen type I is present in the culture medium as well as in the cell fraction, while type III is only detected in the culture medium. In the transition from immature to pubertal rat, the ratio of procollagen type III to procollagen type I diminishes from 5.7 to 1.7. These results indicate that the synthesis, distribution and molecular characteristics of interstitial collagens changes with the age of the animal. Since, the content of other extracellular matrix components such as proteoglycans and collagen type IV also varies with age, we postulate that the composition of the extracellular matrix in the testes is not constant but changes with sexual development.     

Immunohistochemical and biochemical studies on the collagenous proteins of human osteosarcomas

The distribution of type I, II, III, IV, V and VI collagens in 20 cases of osteosarcoma was demonstrated immunohistochemically using monospecific antibodies to different collagen types. In addition, biochemical analysis was made on collagenous proteins synthesized by tumor cells in short-term cultures obtained from seven representative cases and compared with dermal fibroblasts. In osteoblastic areas, most of the tumor osteoid consisted exclusively of type I collagen. Type V collagen was associated in some of them. Type III and type VI collagens were mainly localized in the perivascular fibrous stroma. Cultured tumor cells from osteoblastic osteosarcomas produced type I collagen exclusively and small amount of type V collagen constantly, while the synthetic activity of type III collagen was extremely low. In contrast, fibroblastic areas were characterized by the codistribution of type I, III, VI collagens and chondroblastic areas by type I, V, VI collagens as well as type II. Furthermore, type IV collagen was demonstrated in the stroma, other than the basement membrane region of blood vessels, in fibroblastic, intramedullary well-differentiated and telangiectatic osteosarcomas. In vitro, the production of variable amounts of type IV collagen, which was not detected in cultured dermal fibroblasts, was also recognized in the osteoblastic, fibroblastic, undifferentiated and intramedullary well-differentiated osteosarcomas examined. These findings suggest that the immunohistochemical approach using monospecific antibodies to different collagen types is useful not only in identifying some specific organoid components, such as tumor osteoid, but also in disclosing the biological properties of osteosarcoma cells with diverse differentiation.     

Synthesis of type III collagen by fibroblasts from the embryonic chick cornea

Synthesis of collagen types I, II, III, and IV in cells from the embryonic chick cornea was studied using specific antibodies and immunofluorescence. Synthesis of radioactively labeled collagen types I and III was followed by fluorographic detection of cyanogen bromide peptides on polyacrylamide slab gels and by carboxymethylcellulose chromatography followed by disc gel electrophoresis. Type III collagen had been detected previously by indirect immunofluorescence in the corneal epithelial cells at Hamburger-Hamilton stages 20--30 but not in the stroma at any age. Intact corneas from embryos older than stage 30 contain and synthesize type I collagen but no detectable type III collagen. However, whole stromata subjected to collagenase treatment and scraping (to remove epithelium and endothelium) and stromal fibroblasts from such corneas inoculated in vitro begin synthesis of type III collagen within a few hours while continuing to synthesize type I collagen. As demonstrated by double-antibody staining, most corneal fibroblasts contain collagen types I and III simultaneously. Collagen type III was identified biochemically in cell layers and media after chromatography on carboxymethylcellulose be detection of disulfide-linked alpha l (III)3 by SDS gel electrophoresis. The conditions under which the corneal fibroblasts gain the ability to synthesize type III collagen are the same as those under which they lose the ability to synthesize the specific proteoglycan of the cornea: the presence of corneal-type keratan sulfate.     

Fibroblast growth factor modulates synthesis of collagen in cultured vascular endothelial cells

Vascular endothelial cells derived from adult bovine aortic arch can be grown in two ways, either in the presence or absence of fibroblast growth factor. The types of collagen produced by cultures under these two conditions have been compared. In the presence of fibroblast growth factor, cells grow in an orderly fashion, express their normal phenotype and synthesize primarily type III collagen plus collagens types IV and V at a ratio of 10:1:3. Cultures grown in the absence of the factor lose their orderly pattern of growth, lose polarity and normal phenotypic expression. They devote twice the proportion of total protein-synthesizing capacity to collagen, and now synthesize type I in addition to the other collagen types. The ratio of collagen types I:III:IV:V is approximately 30:70:1:13. The kinds of type V collagen chains expressed are also altered. Fibroblast growth factor appears to modulate collagen synthesis, the major component of the extracellular matrix, and indirectly modulates the phenotypic expression of cultured vascular endothelial cells. In atherosclerosis, type I collagen is found in association with the intimal layer. The disorderly growth and the abnormal production of type I collagen by these vascular endothelial cells cultured in the absence of fibroblast growth factor is a model for a number of pathological situations including atherosclerotic plaque formation.     

Progressive modulation of endothelial phenotype during in vitro blood vessel formation.

"Sprouting" vascular endothelial cells were used as an in vitro model system to study the progressive morphologic and biosynthetic changes associated with the formation of tubular structures. In vitro, sprouting endothelial cells formed spontaneously without the addition of any exogenous factors from cultures of cloned endothelium exhibiting a polygonal/cobblestone phenotype. These phenotypically variant endothelial cells differentiated to form associated cell networks or nodules which gradually reorganized into tubular structures. Concomitant with these morphologic changes, the biosynthesis of extracellular matrix proteins was modulated, as determined by Northern blot analysis, metabolic labeling, and immunocytochemistry. The initial sprouting phase was characterized by the induction of type I collagen synthesis and the appearance of fibronectin containing the ED-A domain, in comparison to their absence in cloned cultures displaying a stable polygonal/cobblestone phenotype. The organizational stage, where the sprouting endothelial cells assembled into tubular structures, was additionally characterized by the expression of type IV collagen. These studies demonstrate that the progression from polygonal/cobblestone to sprouting cultures, and subsequent tubular organization, involves major alterations in extracellular matrix protein expression. This developmental phenomenon, although not completely analogous to blood vessel formation in vivo, nevertheless may be helpful in understanding the role of matrix macromolecules in the angiogenic process.     

An ultrastructural and immunohistochemical study of extracellular matrix in meningiomas

Extracellular matrix of meningiomas was studied by light and electron microscopy with the aid of immunohistochemical techniques. Special attention was paid to the distribution of type I, III, IV, V collagens and laminin with a comparison between meningothelial and fibroblastic types. Connective tissue fibers and basement membrane were not found among the tumor cells in the meningothelial type, but were found in the fibroblastic type. The immunolocalizations were consistently demonstrated extracellularly, but were not within the cytoplasm. Type I, III and V collagens were usually demonstrated in the fibrous septum in the meningothelial type, while they were localized among the tumor cells in the fibroblastic type. Furthermore, type IV collagen and laminin were demonstrated within the vascular walls or around the syncytium in the meningothelial type, while they were localized among the tumor cells in the fibroblastic type. In both types the expression of type IV collagen and laminin was closely related to the distribution of basement membrane. Although meningothelial and fibroblastic meningiomas showed quite different distribution of extracellular matrices, the profile of collagen types expressed by these two basic types was essentially the same. The cellular derivation of meningiomas was discussed with particular attention to the structure of human arachnoid villi and meninges.     

Heterogeneity in collagen biosynthesis by sprouting retinal endothelial cells

Bovine retinal microvascular endothelial cells can display two distinct and reversible morphologies in culture: ‘cobblestone’ and ‘sprouting’. The cobblestone morphology resembles the resting cells lining the lumen of mature vessels while the sprouting morphology resembles the angiogenic cells involved in the formation of new vessels. Retinal cells displayed some heterogeneity in the shape of the cells making up the cobblestone monolayer. In contrast, all cell lines displayed an identical sprouting morphology. We have investigated the synthesis of matrix macromolecules by retinal endothelial cells displaying either the cobblestone or the sprouting morphology. Type IV was the only collagen synthesised by eight different lines of early-passage (between one and six) cobblestone endothelial cells. Collagen types I and III were not detected in these cultures. In contrast, heterogeneity was observed in the types of collagen synthesised by four lines of early-passage cells displaying the sprouting morphology. That is, two lines synthesised collagen types I, III and IV, whereas two other lines continued to synthesise only type IV collagen. Both cobblestone and sprouting cells synthesised fibronectin and thrombospondin, although the relative amounts of these macromolecules varied with culture conditions. The pattern of collagen synthesis by cobblestone cells was also affected by in vitro ?ageing”?: 4/5 lines examined above passage eight synthesised collagen types I, III and IV. Our results indicate that there is heterogeneity in the sprouting phenotype displayed by retinal endothelial cells, and that this phenotype is not necessarily associated with the synthesis of type I collagen. We suggest that differences in the spectrum of matrix macromolecules synthesised by sprouting endothelial cells may play a role in the control of angiogenesis. © 1994 wiley-Liss, Inc.