A monoclonal antibody specific for the amino terminal cleavage site of procollagen type I

A monoclonal mouse IgG1 antibody was produced against the aminopropeptide of dermatosparactic sheep procollagen type I by using the hybridoma technique. Radioimmunoassays demonstrated an apparent affinity constant of 10(8) l X mol-1. The antibody reacted with a 19-amino-acid-long sequence spanning the procollagen N-proteinase cleavage site with stronger binding to structures contributed by the aminopropeptide. The antibody showed strong cross-reactions with similar antigens of bovine, human or chick origin but failed to react with the aminopropeptide of procollagen type III. Incubation of chick or sheep procollagen type I with stoichiometric amounts of antibody blocked the release from procollagen molecules of the aminopropeptide by procollagen N-proteinase. Thus, this antibody seems useful for studying various biological problems encountered in the conversion of procollagen.     

Subpopulations of rat lung fibroblasts with different amounts of type I and type III collagen mRNAs

A fluorescence-based method using the cell sorter has been devised to separate rat lung fibroblasts into subpopulations. Type I or type III collagen antiserum was used as the primary antibody to react with parent rat lung fibroblasts. This was followed by a fluorescein-conjugated secondary antibody. Specificity of the primary collagen antibody was determined using a monoclonal beta-actin antibody and purified IgG as the primary antibodies. The fluorescent shift of parent rat lung fibroblasts was optimized for the amount of primary collagen antibody and secondary fluorescein-conjugated antibody. An increase in slot blot intensity was observed for pro-alpha 1(I), pro-alpha 2(I), and pro-alpha 1(III) mRNAs with increasing amounts of cellular RNA. When precipitating with type I collagen antibodies, the total cellular steady-state levels of type I procollagen mRNAs were increased in the high intensity cells as compared with the low intensity cells. Alternately, when the type III collagen antibodies were used to precipitate the rat lung fibroblasts, the low intensity cells had increased type I procollagen mRNAs while the high intensity cells had increased type III procollagen mRNA. The subpopulations of rat lung fibroblasts after isolation using the fluorescent cell sorter were readily propagated for at least four passages.     

Anchoring fibrils contain the carboxyl-terminal globular domain of type VII procollagen, but lack the amino-terminal globular domain

Type VII procollagen has been characterized as a product of epithelial cell lines. As secreted, it contains a large triple-helical domain terminated by a multi-globular-domained carboxyl terminus (NC-1), and a smaller amino-terminal globule (NC-2). The triple helix and the NC-1 domain have previously been identified in anchoring fibril-containing tissues by biochemical and immunochemical means, leading to the conclusion that type VII collagen is a major component of anchoring fibrils. In order to better characterize the tissue form of type VII collagen, we have produced a panel of monoclonal antibodies which recognize the NC-1 domain. Peptide mapping of these epitopes indicate that they are independent and span approximately 125,000 kDa of the total 150,000 kDa of each alpha chain contained in NC-1. All these antibodies elicit immunofluorescent staining of the basement membrane zone in tissues. Type VII collagen has been extracted from tissues. As previously reported, it is smaller than type VII procollagen, (Woodley, D. T., Burgeson, R. E., Lunstrum, G. P., Bruckner-Tuderman, L., and Briggaman, R. A., submitted for publication), and we now find that it predominantly occurs as a dimer. Following clostridial collagenase digestion, intact NC-1 has been recognized, indicating that the difference in apparent Mr between the tissue form of the molecule and type VII procollagen results from modification of the amino terminus. The size of the amino-terminal globule has been determined to be between approximately 96 and 102 kDa. Rotary shadowing analyses of extracted molecules indicate that dimeric molecules contain the NC-1 domain, but are missing intact NC-2. We propose that the tissue form monomer, Mr = 960,000, be referred to as "type VII collagen." These studies strongly suggest that anchoring fibrils contain dimeric molecules with intact NC-1 domains. The data also support the previous suggestion that the NC-2 domain is involved in the formation of disulfide bond-stabilized type VII collagen dimers, and is subsequently removed by physiological proteolytic processing.     

Glucocorticoids coordinately regulate procollagens type I and type III synthesis

Antibodies to type I and type III procollagens were raised in rabbits and were made monospecific by chromatography on collagen and procollagen affinity columns. The antibodies were determined to be monospecific by the direct enzyme-linked immunosorbent assay and the enzyme-linked immunosorbent assay inhibition assay. Rats were treated with various doses of triamcinolone diacetate, pulse-labeled with radioactive proline for 20 min, and the procollagens were precipitated with procollagen antibodies. The degree of inhibition of procollagen type I and type III synthesis to corticosteroid treatment was the same. This coordinate effect of glucocorticoids on the synthesis of the two procollagens was reversible, dose-dependent, time-dependent, and observed in lung as well as in skin. These data indicate that glucocorticoids coordinately regulate the synthesis of type I and type III procollagen in skin and lung to the same extent.     

Incorporation of sulphate into type III procollagen by cultured human fibroblasts. Identification of tyrosine O-sulphate

Confluent cultures of normal human skin fibroblasts were labelled overnight with [35S]sulphate, and the incorporation of the isotope into type III procollagen, secreted into the medium, was verified by radioimmunoassay and immunoprecipitation after removing the heavily sulphated proteoglycans by anion-exchange chromatography. Type III procollagen and its pro and pN alpha chains were visualized in fluorographs of the immunoprecipitates. The labelled procollagen could be isolated by a combination of ion-exchange chromatography and gel filtration and was found to contain tyrosine O-sulphate, which was identified by thin-layer electrophoresis after Ba(OH)2 hydrolysis. The regions sulphated in the type III procollagen molecule were susceptible to pepsin digestion. Digestion with purified bacterial collagenase at +37 degrees C produced a labelled fragment that was recognized by antibodies against the aminoterminal propeptide of type III procollagen, indicating that the sulphated tyrosine residues are located either in this propeptide or in the non-helical telopeptide region of the type III collagen molecule proper. Sulphation of tyrosine residues is a new post-translational modification in procollagen, which could be involved in the regulation of the processing of type III procollagen into collagen and thus affect the formation of collagen fibres.     

Procollagen production by rat hepatocytes in primary culture

Hepatocytes were obtained from rat liver and maintained in primary culture for periods up to 14 days. Collagen synthesis was maximal after 3–5 days and declined thereafter. The rate of collagen production was appox. one-tenth that observed by the rat skin fibroblasts of the same animals after 3–5 passages. Type I procollagen, the major macromolecular collagenous species, was identified as a 450 000 dalton molecule which was converted to 120 000 dalton, denatured, reduced procollagen chains. Prior pepsin digestion of the native procollagen released 95 000 dalton collagen chains identified as α1(I) and α2(I) by co-migration with carrier rat skin type I collagen chains. The production of type III procollagen was also tentatively identified by DEAE-cellulose chromatography. This material was isolated and identified with type-specific antibodies developed against the amino-terminal extension peptide of bovine skin type III procollagen. The relative distribution of type I:type III procollagen was estimated at 7:3 similar to the ratio previously found in whole rat liver. No evidence of type IV or type V procollagen biosynthesis was observed. These results suggest that rat hepatocytes in primary culture are capable of interstitial type I and type III collagen biosynthesis in a ratio similar to that found in their parent hepatic tissue in situ. They also suggest that the less abundant type IV (basement membrane-associated) or type V are nor major collagenous products of these cells.     

Immunohistochemical localization of procollagens. I. Light microscopic distribution of procollagen I, III and IV antigenicity in the rat incisor tooth by the indirect peroxidase-anti-peroxidase method.

Frozen sections of the growing end of the rat incisor tooth were exposed to antisera or affinity prepared antibodies against partially purified type I, II, or IV procollagen in the hope of detecting the location of the corresponding antigens by the peroxidase-anti-peroxidase technique. The distribution of immunostaining was similar with antisera as with purified antibodies of a given type, but differed for each type; that is, predentin, odontoblasts, pulp and periodontal tissue were the sites of type I; blood vessel walls, pulp and periodontal tissue, of type III; and basement membranes, of type IV antigenicity. It was demonstrated, at least in cases of type I and III, that immunostaining detected the corresponding procollagens and related substances, but not the corresponding collagens. The interpretation of these observations is that: 1) odontoblasts elaborate procollagen I for release to predentin and subsequent transformation to dentinal collagen I; 2) pulp and periodontal cells produce procollagens I and III which presumably become collagens I and III respectively, while the adventitial cells of blood vessels give rise to collagen III; and 3) procollagen IV is associated with basement membranes and, occasionally, adjacent cells.     

Purification of human procollagen type III N-proteinase from placenta and preparation of antiserum.

Procollagen type III N-proteinase, of Mr about 70,000, was detected in human placental tissue and purified from this source more than 5800-fold. It was found to be a glycoprotein, which was bound to both concanavalin A-Ultrogel and heparin-Sepharose affinity columns. Binding to a type III pN-collagen-Sepharose affinity column was used as the final step in purification. The purified enzyme accepted only native type III procollagen or [14C]carboxymethylated type III pN-collagen as its substrate; type I, type II and type IV procollagen and heat-denatured type III pN-collagen were not cleaved by the enzyme. Antibodies against this purified enzyme protein raised in rabbits demonstrated a high inhibitory effect on the enzyme activity. Immunoblotting of the denatured protein and immunoelectrophoresis of the native enzyme showed only one major antigenic component, again with an Mr of about 70,000. The antibodies cross-reacted with the enzyme preparation from foetal-calf aorta smooth-muscle cells.     

Chain assembly intermediate in the biosynthesis of type III procollagen in chick embryo blood vessels

A general mechanism for the assembly of procollagens is proposed from a biosynthetic study of procollagen III. This was shown to proceed by a stepwise process punctuated by disulfide bond formation and an assembly intermediate was recovered. The biosynthesis of type III procollagen in excised chick embryo blood vessels was studied by radioactive labeling for 30 min. Velocity sedimentation under denaturing conditions and purified antibodies specific against bovine amino propeptide III were used to identify and characterize monomeric pro alpha 1 III chains and a type III procollagen intermediate which is interchain disulfide-linked only at the carboxyl end but not at the amino end. The monomeric chains presumably have intrachain disulfide bonds within the propeptides. The monomeric pro alpha 1 III chains were also found when alpha, alpha'-dipyridyl was present during incubation. Pulse-chase experiments show that the monomeric chains and the intermediate are biosynthetic precursors of type III procollagen. Furthermore, it is shown that monomeric pro alpha 1 chains are not triple helical when extracted under nondenaturing conditions. The results indicate that the assembly of pro alpha 1 III chains into type III procollagen starts with the association of the folded carboxyl propeptides and is followed by formation of disulfide bonds between carboxyl propeptides, folding of the triple helix, and formation of disulfide bonds between amino propeptides. All procollagens may follow a similar assembly sequence.     

Colocalization of cytokeratin 18 and villin in type III alveolar cells (brush cells) of the rat lung

Alveoli of the rat lung are lined by three different cell types, the flat type I cells and the cuboidal type II and type III cells. Type III cells differ from type II cells by the presence of an apical tuft of microvilli and the absence of lamellar type secretory granules. In the present study we show by double immunolabelling that type III cells of the rat lung can be identified at the light-and electron microscope level by antibodies against both cytokeratin 18 and the actin-crosslinking protein villin. At the ultrastructural level, microvilli and their rootlets in the apical cytoplasm were labelled by the anti-villin antibodies, whereas a monoclonal antibody against cytokeratin 18 (Ks18.04) labelled bundles of intermediate filaments. In conclusion, antibodies against villin and certain monoclonal antibodies specific for cytokeratin 18 can be used as tools for selective visualization of type III cells in the rat lung.     

Identification of the molecular recognition sequence which determines the type-specific assembly of procollagen.

A key question relating to procollagen biosynthesis is the way in which closely related procollagen chains discriminate between each other to assemble in a type-specific manner. Intracellular assembly of procollagen occurs via an initial interaction between the C-propeptides followed by vectorial propagation of the triple-helical domain in the C to N direction. Recognition signals within the C-propeptides must, therefore, determine the selective association of individual procollagen chains. We have used the pro alpha1 chain of type III procollagen [pro alpha1(III)] and the pro alpha2 chain of type I procollagen [pro alpha2(I)] as examples of procollagen chains that are either capable or incapable of self-assembly. When we exchanged the C-propeptides of the pro alpha1(III) chain and the pro alpha(I) chain we demonstrated that this domain is both necessary and sufficient to direct the assembly of homotrimers with correctly aligned triple-helices. To identify the sequences within this domain that determine selective association we constructed a series of chimeric procollagen chains in which we exchanged specific sequences from the pro alpha1(III) C-propeptide with the corresponding region within the pro alpha2(I) C-propeptide (and vice versa) and assayed for the ability of these molecules to form homotrimers. Using this approach we have identified a discontinuous sequence of 15 amino acids which directs procollagen self-association. By exchanging this sequence between different procollagen chains we can direct chain association and, potentially, assemble molecules with defined chain compositions.     

Predominance of type III over type I cell surface procollagens in rat lung fibroblasts

Binding assays of 125I-labeled affinity-purified monospecific type I and III procollagen antibodies to fibroblasts have revealed the presence of type I and III procollagens on the cell surface, and that the amount of type III procollagen is 10 times greater than that of type I procollagen. Analyses by flow cytometry and fluorescent microscopy after treatment with an isothiocyanate (FITC)-conjugated second antibody supported this finding.     

Type V collagen: molecular structure and fibrillar organization of the chicken alpha 1(V) NH2-terminal domain, a putative regulator of corneal fibrillogenesis

Previous work from our laboratories has demonstrated that: (a) the striated collagen fibrils of the corneal stroma are heterotypic structures composed of type V collagen molecules coassembled along with those of type I collagen, (b) the high content of type V collagen within the corneal collagen fibrils is one factor responsible for the small, uniform fibrillar diameter (25 nm) characteristic of this tissue, (c) the completely processed form of type V collagen found within tissues retains a large noncollagenous region, termed the NH2- terminal domain, at the amino end of its alpha 1 chain, and (d) the NH2- terminal domain may contain at least some of the information for the observed regulation of fibril diameters. In the present investigation we have employed polyclonal antibodies against the retained NH2- terminal domain of the alpha 1(V) chain for immunohistochemical studies of embryonic avian corneas and for immunoscreening a chicken cDNA library. When combined with cDNA sequencing and molecular rotary shadowing, these approaches provide information on the molecular structure of the retained NH2-terminal domain as well as how this domain might function in the regulation of fibrillar structure. In immunofluorescence and immunoelectron microscopy analyses, the antibodies against the NH2-terminal domain react with type V molecules present within mature heterotypic fibrils of the corneal stroma. Thus, epitopes within at least a portion of this domain are exposed on the fibril surface. This is in marked contrast to mAbs which we have previously characterized as being directed against epitopes located in the major triple helical domain of the type V molecule. The helical epitopes recognized by these antibodies are antigenically masked on type V molecules that have been assembled into fibrils. Sequencing of the isolated cDNA clones has provided the conceptual amino acid sequence of the entire amino end of the alpha 1(V) procollagen chain. The sequence shows the location of what appear to be potential propeptidase cleavage sites. One of these, if preferentially used during processing of the type V procollagen molecule, can provide an explanation for the retention of the NH2-terminal domain in the completely processed molecule. The sequencing data also suggest that the NH2-terminal domain consists of several regions, providing a structure which fits well with that of the completely processed type V molecule as visualized by rotary shadowing.     

Processing of procollagen types III and I in cultured bovine smooth muscle cells

The processing of type III and type I procollagen molecules in cultured bovine aortic smooth muscle cells was investigated. The molecular identities of the processing intermediates of type III and type I procollagen were characterized by analysis of the radioactive collagenous components using mammalian collagenase and pepsin digestions and cyanogen bromide peptide mapping. The results indicate that the processed intermediates for procollagen type III and type I are their respective pC components. Although the processing pathways for both collagen types are the same, data from pulse-chase experiments suggest that the rates at which the processing occurs are different. Type I procollagen is processed more rapidly to its intermediate than is type III procollagen. The type I pC intermediate is almost completely processed to alpha-chains and a significant portion of these fully processed molecules remains in a soluble form even after 11 h. In the same time period, the type III pC intermediate is slowly converted to alpha-chains. Since beta-aminopropionitrile was not employed in these studies, significant accumulation of collagen chains into the insoluble extracellular matrix was observed during the chase period.     

Heymann antigen GP330 demonstrates affinity for fibronectin, laminin, and type I collagen and mediates rat proximal tubule epithelial cell adherence to such matrices in vitro.

We have utilized monoclonal antibodies directed against glycoproteins on the surface of proximal tubule epithelial cells (PTEC) to study their interaction with matrix components. PTEC exposed to monoclonal antibodies directed against a 330-kDa cell surface glycoprotein exhibited a significant epitope-specific inhibition of attachment and proliferation on type I collagen-, fibronectin-, laminin-, and gelatin-coated tissue culture surfaces. This effect was not due to antibody toxicity since such cells did not exhibit metabolic dysfunction in suspension cultures and the inhibition could be reversed upon removal of the antibody from the cell surface. Furthermore, detergent-solubilized gp330 demonstrated specific affinity for fibronectin, laminin, and type I collagen which was not inhibited by Arg-Gly-Asp-containing peptides. A monoclonal antibody directed against the receptor epitope was capable of promoting PTEC adherence and growth when such an antibody was immobilized on cell culture dishes. Although gp330 acted as a receptor for matrix proteins in primary cultures of freshly isolated PTEC, this effect was not demonstrable in established cultures. These results suggest that freshly isolated PTEC depend on gp330 for their attachment to matrix molecules while in vitro-adapted PTEC rely on other receptors activated by culture conditions. The affinity of gp330 for matrix molecules may be of pathogenic relevance in the persistence of gp330-containing immune complexes formed in the glomerular capillary wall in experimental membranous nephropathy (Heymann nephritis).     

Idiotypic determinants of monoclonal antibodies that bind to 3-fucosyllactosamine

Many monoclonal antibodies that react with the lacto-N-fucopentaose III (LNF III) antigenic determinant, Gal beta 1-4(Fuc alpha 1-3)GlcNAc beta 1-3Gal beta 1-4Glc, have been described recently. The terminal trisaccharide of this determinant, fucosyllactosamine, is present on glycolipids and glycoproteins and on the surface of granulocytes, monocytes, and other cells. To study the structural and genetic diversity of these antibodies, syngeneic anti-idiotypic monoclonal antibodies were produced in BALB/c mice against PMN 6, a monoclonal antibody directed against this sequence. Anti-idiotypic antibodies 6B1 and 6C4 reacted with 50% of a panel of 20 anti-LNF III monoclonal antibodies, whereas 6A3 reacted strongly only with PMN 6. This indicates that the determinants recognized by 6C4 and 6B1 represent major cross-reactive idiotopes of this family of antibodies. The binding of idiotypic antibodies to a glycolipid bearing this antigenic determinant was completely inhibited by the three anti-idiotypic antibodies, 6A3, 6B1, and 6C4. The idiotopes could be demonstrated on the heavy chain of the monoclonal antibodies by an antibody transfer technique when mild reducing conditions were employed, but a high concentration of reducing agent destroyed the idiotypic determinants. This suggests that the anti-idiotypic antibodies recognize conformational structures expressed on the heavy chain molecules. The binding of 18 monoclonal antibodies to two glycolipid antigens and to a fucosyllactosamine-bovine serum albumin conjugate was compared. Antibodies that possessed the 6C4 cross-reactive idiotope bound to fucosyllactosamine-bovine serum albumin more weakly than idiotype-negative antibodies (p = 0.001). This suggests that the 6C4-positive antibodies might represent germline structures.     

Vascular Ehlers-Danlos syndrome

Vascular Ehlers-Danlos syndrome, also known as Ehlers-Danlos syndrome type IV, is a life-threatening inherited disorder of connective tissue, resulting from mutations in the COL3A1 gene coding for type III procollagen. Vascular EDS causes severe fragility of connective tissues with arterial and gastrointestinal rupture, and complications of surgical and radiological interventions. As for many rare orphan diseases, delay in diagnosis is common, even when the clinical features are typical, leading to inadequate or inappropriate treatment and management. In childhood many individuals with vascular EDS are first thought to have coagulation disorders. In adulthood, four main clinical findings, including a striking facial appearance, easy bruising, translucent skin with visible veins and rupture of vessels, gravid uterus or intestines, contribute to the diagnosis, which can be confirmed by SDS-PAGE studies of type III procollagen molecules synthesis by cultured fibroblasts or by the identification of a mutation in the COL3A1 gene coding for type III procollagen. Vascular EDS is inherited as an autosomal dominant trait. Varied molecular mechanisms have been observed and, of the mutations described to date, most have been unique to each family or "private", with no correlation between genotype and phenotype. Vascular EDS is of particular importance to surgeons, radiologists, obstetricians and geneticists since, although there is currently no specific treatment for the condition, knowledge of the diagnosis may help in the management of visceral complications, pregnancy and genetic counseling.     

Synthesis of an altered type III procollagen in a patient with type IV Ehlers-Danlos syndrome. A structural change in the alpha 1(III) chain which makes the protein more susceptible to proteinases

The synthesis of type III procollagen was examined in cultured fibroblasts from ten patients with type IV Ehlers-Danlos syndrome, a heritable disorder of connective tissue. With fibroblasts from nine patients, a decreased amount of labeled type III procollagen was recovered in the medium after the cells were incubated with radioactive amino acids for 24 h. The results were compatible with undefined defects in type III procollagen. The culture medium from one patient contained apparently normal amounts of type III procollagen after a 24-h labeling. However, the pro-alpha 1(III) chains from the medium of the patient's fibroblasts appeared as an abnormally broad band when examined by gel electrophoresis in sodium dodecyl sulfate. Analysis of fragments generated by vertebrate collagenase and cyanogen bromide located a structural defect between amino acid residues 555 and 775 in half of the alpha 1(III) chains. Most of the patient's type III procollagen was susceptible to digestion by pepsin or a mixture of chymotrypsin and trypsin at temperatures at which normal type III procollagen resisted digestion. Cyanogen bromide digestion of samples of the patient's skin revealed that the amount of type III was reduced more than 4-fold. The results support the hypothesis that both normal and structurally altered pro-alpha 1(III) chains are being incorporated into type III procollagen synthesized by the patient's fibroblasts and that type III procollagen molecules containing one, two, or three structurally altered pro-alpha 1(III) chains are rapidly degraded by proteinases in the tissues.     

Deposition of an intermediate form of procollagen type III (pN-collagen) into fibrils in the matrix of amniotic epithelial cells

We have followed the deposition and maturation of the pericellular matrix of amniotic epithelial cell cultures for up to eight weeks using metabolic labeling and immunoelectron microscopy. This matrix contains mainly collagen type III and fibronectin. Cleavage of the carboxypropeptide occurred after secretion of the procollagen molecules into the medium but was not accompanied by a significant release of the aminopropeptide. The early matrix, as isolated from the cultures by a deoxycholate procedure, contained collagenous proteins predominantly composed of pN alpha 1(III) chains, which still possessed the aminopropeptide, and only little material in the form of alpha 1(III) chains. The relative amount of alpha 1(III) chains increased during subsequent days of culture. Electron microscopy showed two types of structures in the matrix: thin fibrils, ranging from 10 to 30 nm in diameter, with no apparent cross-striation, and 50-500 nm thick bundles composed of filamentous and amorphous material. In the fibrils, immunoferritin electron microscopy showed a regular staining for the aminopropeptide of procollagen type III with a periodicity of 71 nm. These collagenous fibrils did not stain for fibronectin which was found in the bundles. Since most of the aminopropeptide in the matrix appeared covalently linked as pN-collagen, we conclude that the deposition of this intermediate form of procollagen is a general mechanism in collagen type III fibrillogenesis.     

Collagen synthesis by bovine aortic endothelial cells in culture.

Endothelial cells isolated from bovine aorta synthesize and secrete type III procollagen in culture. The procollagen, which represents the major collagenous protein in culture medium, was specifically precipitated by antibodies to bovine type III procollagen and was purified by diethyl-aminoethylcellulose chromatography. Unequivocal identification of the pepsin-treated collagen was made by direct comparison with type III collagen isolated by pepsin digestion of bovine skin, utilizing peptide cleavage patterns generated by vertebrate collagenase, CNBr, and mast cell protease. The type III collagen was hydroxylated to a high degree, having a hydroxyproline/proline ratio of 1.5:1.0. Pulse-chase studies indicated that the procollagen was not processed to procollagen intermediates or to collagen. Pepsin treatment of cell layers, followed by salt fractionation at acidic and neutral pH, produced several components which were sensitive to bacterial collagenase and which comigrated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with alpha A, alpha B, and type IV collagen chains purified from human placenta by similar techniques. Bovine aortic endothelial cells also secreted fibronectin and a bacterial collagenase-insensitive glycoprotein which, after reduction, had a molecular weight of 135,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (using procollagen molecular weight standards) and which was not precipitable by antibodies to cold-insoluble globulin or to alpha 2-macroglobulin. Collagen biosynthesis by these cells provides an interesting model system for studying the polarity of protein secretion and the attachment of cells to an extracellular matrix. The presence of type III collagen in the subendothelium and the specific interaction of this protein with fibronectin and platelets suggest the involvement of this collagen in thrombus formation following endothelial cell injury.