Suppression of synthesis of pro-alpha 1(I) and production of altered pro-alpha 2(I) procollagen subunits in 4-nitroquinoline-1-oxide-transformed fibroblasts

The collagen phenotype of a 4-nitroquinoline-1-oxide-transformed line of Syrian hamster embryo fibroblasts, NQT-SHE, was markedly altered from that of normal Syrian hamster embryo cells, which synthesized mainly type I procollagen [pro-alpha 1(I)]2 pro-alpha 2(I). Total collagen synthesis in the transformant was reduced to about 30% of the control level primarily because synthesis of the pro-alpha 1(I) subunit was completely suppressed. The major collagenous products synthesized consisted of two polypeptides, designated as N-33 and N-50, which could be completely separated by precipitation with ammonium sulfate at 33 and 50% saturation, respectively. N-33 migrated similarly to pro-alpha 2(I) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and N-50 migrated slightly more slowly. The collagenous regions of these chains were more sensitive to protease than the analogous region of procollagen I, but alpha-chains could be obtained by digestion for 2 h at 4 degrees C with high ratios of protein:pepsin. Staphylococcus V8 protease and cyanogen bromide peptide maps of N-33 alpha and N-50 alpha chains indicated that the chains were homologous with, but different than, alpha 2(I) chains and that they differed from each other. Considering their similarity to pro-alpha 2(I), it was surprising to find that the N-collagens were secreted to the same extent as was type I procollagen from Syrian hamster embryo cells and that there were no disulfide bonds between N-collagen chains. Intrachain disulfides were present. One possible explanation for the unusual collagen phenotype of NQT-SHE cells is that transformation induced one or more mutations in the pro-alpha 2(I) structural gene while suppression of synthesis of the pro-alpha 1(I) subunit may be due to a mutation in the regulatory region of its gene or in a general regulatory gene.     

Characterization of procollagen synthesized by matrix-free cells isolated from chick embryo tendons.

The genetic type and molecular structure of the precursor forms of collagen synthesized by matrix-free tendon cells isolated from 17-day old chick embryos were examined by chromatographic and electrophoretic techniques. The [14C]proline-labeled collagenous proteins secreted by the cells resolved on diethylaminoethylcellulose into two peaks, A and B. Both peaks contained type I collagenous proteins since on chromatography on carboxymethylcellulose, after limited pepsin proteolysis, both peaks contained alpha1 and alpha2 chains of collagen in a 2:1 ratio, and cyanogen bromide peptide maps of the 14C-labeled protein in both peaks were similar to cyanogen bromide peptide maps derived from authentic type I collagen. Enzymatic digestion with purified mammalian collagenase demonstrated that the collagen precursor in peak B contained noncollagenous peptide extensions at both the amino- and carboxy-terminal ends of the molecule, while peak A had only carboxy-terminal extension peptides. Although both the amino- and carboxy-terminal extensions incorporated radioactive cystine, only the carboxy-terminal extensions contained interchain disulfide bonds. The carboxy-terminal extensions were also shown to incorporate radioactive tryptophan. Since most of the precursor forms of collagen recovered in the incubation medium chromatographed in peak B, it is concluded that matrix-free tendon cells secrete only type I procollagen with extension peptides at both the amino- and carboxy-terminal ends of the molecule.     

The staining of type V collagen obtained from FBJ virus-induced osteosarcoma with concanavalin A

Type V collagen from FBJ virus-induced osteosarcoma of mice has a high content of saccharide as has been noted for type V collagens from different sources. In the present study, this collagen was found to contain significant amounts of mannose and hexosamine. Three alpha chains of this collagen were electrophoretically separated and cleaved by cyanogen bromide. The cyanogen bromide peptides, following their separation by SDS-polyacrylamide gel electrophoresis, were transferred onto nitrocellulose paper and stained with concanavalin A. Several bands derived only from alpha 3(V) stained positively, but this was inhibited by the presence of alpha-methylmannoside. Thus, at least one of these three chains appears to have an asparagine-linked oligosaccharide.     

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.     

Quantification and specific detection of collagenous proteins using an enzyme-linked immunosorbent assay and an immunoblotting for cyanogen bromide peptides

A method for the detection of collagenous proteins within cyanogen bromide digests of tissues has been devised. The peptides produced by digestion with cyanogen bromide were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transferred to a nitrocellulose filter. They were stained on the filter by incubation first with antibodies to collagen and then with a second antibody covalently linked to horseradish peroxidase, 4-chloro-1-naphthol was added, and the bound enzyme was assayed. This procedure is useful for the identification and characterization of collagens of types I, III, IV, and V in tissues. In addition, we have developed a sensitive and specific competitive enzyme-linked immunosorbent assay (ELISA) which is convenient for quantifying collagens (types I, III, and IV) in tissues. In this kind of assay, soluble cyanogen bromide peptides compete with cyanogen bromide peptides adsorbed onto a solid-phase support for rabbit anti-collagen antibodies. We determined the amount of bound antibody by using goat anti-rabbit immunoglobulin G covalently conjugated to horseradish peroxidase and then provided a substrate for the enzymatic reaction. The sensitivity range of the ELISA is 0.09 micrograms/ml in the region of 90 to 10% binding.     

Quantitation of type I and III collagens using electrophoresis of alpha chains and cyanogen bromide peptides

The methods of quantitating the relative amounts of type I and III collagens in samples containing crosslinked collagen chains were evaluated using electrophoresis of alpha chains and cyanogen bromide peptides. The densitometry areas of the alpha I(I) chains from type I collagen and the alpha I(III) chains from type III collagen were reduced because of the failure of the crosslinked chains to dissociate. However, the ratios of the unit densitometry areas of these chains (area of chain/micrograms type I or III collagen loaded) were constant for type I and III collagens prepared from the same samples of tissue. A calibration factor, which was the same for dermis and mitral valve, was derived to convert the densitometry area ratios to the weight ratios of type I to III collagens. In contrast, the densitometry areas of the alpha I(I) CB8 (type I collagen marker) and the alpha I(III) CB5 (type III collagen marker) were not reduced by crosslinked collagen chains. A calibration factor was also derived to convert the ratios of the densitometry areas of the marker peptides to weight ratios of type I to type III collagens. Almost identical results were obtained when electrophoresis of alpha chains and of cyanogen bromide peptides was used with these calibration factors to quantitate the relative amounts of type I and III collagens in tissue extracts which contained different amounts of crosslinked chains.     

The isolation and characterization of the cyanogen bromide peptides from the B chain of human collagen.

Cleavage of the collagen B chain with cyanogen bromide yields nine peptides which have been isolated and characterized with regard to molecular weight and amino acid composition. The peptides are recovered in equimolar quantities and account for the full amino acid complement of the chain as isolated following limited pepsin digestion of human placental tissue. These data thus confirm the unique composition of the chain and further indicate that the chain has been isolated in essentially pure form. The total number of amino acid residues (1018) observed in the cyanogen bromide peptides of the B chain indicate that it is comparable in length to the previously characterized collagen alpha chains. Thus, the apparent larger size of the B chain noted in previous studies may possibly be attributed to the relatively large quantities of hydroxylysine-linked carbohydrate, but more likely to the increased numbers of large hydrophobic amino acids in the B chain. Although the cyanogen bromide peptide pattern obtained in studies on the B chain serves to differentiate this chain from other known chains, some possible homologies between the B chain peptides and peptides derived from the alpha chains of type I, II, and III collagens are noted.     

High levels of expression of full length human pro-alpha 2(V) collagen cDNA in pro-alpha 2(V)-deficient hamster cells

A full length cDNA encoding human pro-alpha 2(V) collagen was constructed. Partial sequencing of the cDNA and primer extension analysis of mRNA from fibroblasts found that pro-alpha 2(V) mRNA differs from the mRNAs of other fibrillar collagens in the increased length of its 5'-untranslated region. The pro-alpha 2(V) cDNA was placed downstream of the human cytomegalovirus immediate early promoter/regulatory sequences for expression studies in cultured Chinese hamster lung cells. These cells have been shown previously to synthesize large quantities of pro-alpha 1(V) homotrimers as their only collagenous product. Transfection resulted in a number of clonal cell lines that express human alpha 2(V) RNA at levels comparable to, and in some cases greater than, levels found in normal human skin fibroblasts. Pro-alpha 2(V) chains produced in the majority of clonal lines were of sufficient quantity to complex all available endogenous pro-alpha 1(V) chains. Chimeric heterotrimers, composed of hamster alpha 1(V) and human alpha 2(V) chains in a 2:1 ratio, were stable to pepsin digestion and were found predominantly associated with the cell layer. Surprisingly, pro-alpha 2(V) chains, in excess to pro-alpha 1(V) chains, were found in the extracellular matrix and, in much greater abundance, in media. These chains were pepsin sensitive, indicating that pro-alpha 2(V) chains can be secreted as nonstable homotrimers or as free chains.     

Nonhelical,fibronectin-binding basement-membrane collagen from endodermal cell culture

A novel method of affinity chromatography on insolubilized collagen-binding fragments of fibronectin was utilized to isolate a random-coil collagenous protein from culture media of mouse teratocarcinoma-derived endodermal cells. These cells also produced another collagenous protein, which did not bind to fibronectin but could be isolated by differential salt precipitation. The affinity-purified collagen differs from its conventionally isolated counterpart in that it is not triple-helical in structure, its polypeptides are not disulfide-crosslinked and it has affinity for fibronectin in its native state. Both collagens resemble previously characterized type IV basement-membrane collagens with respect to their amino acid composition, cyanogen bromide peptides, chain size, immunological reactivity and tissue localization. The random-coil collagen is directly active in promoting the attachment of some lines of cells, but for attachment of the endodermal cells addition of fibronectin is required. This suggests that the presence of nonhelical, fibronectinbinding collagen may have biological significance in the interaction of cells with the extracellular matrix.     

A post-translational modification, unrelated to hydroxylation, in the collagenous domain of nonhelical pro-alpha 2(I) procollagen chains secreted by chemically transformed hamster fibroblasts.

Transformed Syrian hamster embryo (NQT-SHE) fibroblasts do not synthesize the pro-alpha 1 subunit of type I procollagen, but secrete two modified forms of the pro-alpha 2(I) subunit that migrate more slowly than the normal chain during gel electrophoresis (Peterkofsky, B., and Prather, W. (1986) J. Biol. Chem. 261, 16818-16826). By electrophoretic analysis of cyanogen bromide and V8 protease-derived peptides from the collagenous domains of intra- and extracellular pro-alpha 2(I) chains, we find that the modification occurs almost exclusively in secreted molecules, is located in the region spanned by the cyanogen bromide peptide CB3,5, and persists when hydroxylation is inhibited. Thus, modification is due to a post-translational reaction other than hydroxylation. The modified chains appear to be secreted in the denatured state since: 1) helical structures formed at 4 degrees C under acidic conditions were unstable under neutral conditions at 37 degrees C; 2) conditions that destabilize the type I procollagen helix and thus inhibit its secretion, i.e. inhibition of proline hydroxylation or incorporation of the proline analog cis-hydroxyproline, did not affect secretion of the modified chains. The time courses for secretion of nonhelical modified chains from NQT-SHE and of hydroxylated helical procollagen I from control cells, as a proportion of total collagen synthesized, were similar. Although cis-hydroxyproline did not inhibit the secretion of the modified chains, it induced their rapid intracellular degradation.     

Evidence that the collagen in the culture medium of Chinese hamster lung cells contains components related at the primary structural level to the alpha1(V) collagen chain

The collagenous protein synthesized by cultured Chinese hamster lung (CHL) cells and present in the culture medium has been isolated after limited pepsin digestion and differential salt precipitation. Molecular size analysis of this material indicates that the CHL cell medium collagen contains chains which exhibit an apparent molecular mass of approximately 85,000 Da. When chromatographed on CM-cellulose under denaturing conditions, the reduced and alkylated CHL cell medium collagen chains elute slightly after the human alpha1(I) chain but well before the pepsin-derived alpha1(V) chain, which is the constituent chain present in the CHL cell cellular matrix collagen. Analysis of the peptides derived by CNBr cleavage of the CHL medium collagen chains by chromatography on CM-cellulose reveals, however, that these chains contain peptides which correspond both in size and in chemical properties to those derived from the alpha1(V) collagen chain, but clearly lack two peptides (alpha1(V)-CB4 and alpha1(V)-CB5) which are normally present in pepsin-derived alpha1(V) chains. Furthermore, analysis of the CHL cell culture medium collagenous material obtained without pepsin digestion indicates the presence of collagenous chains that exhibit after reduction a molecular mass of approximately 160,000 Da, which is smaller than the proposed size of the pro alpha1(V) collagen chain. These results demonstrate that the collagenous protein present in the culture medium of CHL cells is directly related at the primary structural level to the alpha1(V) collagen chain, and it is postulated that this material represents the large fragment derived from a collagenase cleavage of the [pro alpha1(V)]3 molecules present in the cell layer. Furthermore, these results and previous reports indicate that the only identifiable genetic type of procollagen chain synthesized by this cloned cell line in culture corresponds to the pro alpha1(V) chain.     

Partial covalent structure of the human alpha 2 type V collagen chain

Human cDNA libraries were screened with a cDNA fragment presumably encoding the 3' terminus of a procollagen carboxyl propeptide not identifiable as types I, II, III, or IV by protein sequence or Northern blot hybridization. One clone contained a 1350-base pair insert coding in part for 55 uninterrupted Gly-X-Y triplets. Comparison with the amino acid composition of the COOH-terminal cyanogen bromide (CB) peptides of the alpha 1 and alpha 2 type V collagen chains showed similarity only to the alpha 2(V)CB fragment. To identify the NH2 terminus of the peptide designated by methionine, an additional isolate was sequenced and found to contain a Gly-Met-Pro triplet. Thirty-one amino acids from the NH2 terminus of the alpha 2(V)CB9 fragment were then determined by Edman degradation and found to be identical to those derived from the cDNA clone. The DNA sequence encoding part of the triple helical region establishes for the first time the partial structure of a type V collagen chain. Although comparison of residues 796-1020 of the alpha 2(V) collagenous region with alpha 1 (III), alpha 1(I), and alpha 2(I) shows strong conservation of charged positions, the latter three chains appear considerably more similar to each other than to alpha 2(V). A striking feature of the alpha 2(V) sequence between 918-944 is the absence of proline residues. In the analogous region of alpha 1(I) where this amino acid is also lacking, a flexible site in the rigid triple helical structure of type I collagen has been observed (Hofmann, H., Voss, T., Kuhn, K. and Engel, J. (1984) J. Mol. Biol. 172, 325-343).     

Procollagen and collagen produced by a teratocarcinoma-derived cell line,TSD4: Evidence for a new molecular form of collagen

Procollagen and collagen were isolated from the culture medium and cell layer of line TSD4 (obtained from mouse teratocarcinoma OTT6050). SDS-polyacrylamide gel electrophoresis of the highly purified procollagen fraction demonstrated that the fraction is composed of θ chains (150,000 daltons), pro α chains (130,000 daltons), and α chains (100,000 daltons). Limited pepsin digestion of this fraction yielded a single species of collagen molecules having a chain composition (α1)₃, as did collagen isolated from the cell layer. Each α1 chain appears to be slightly larger than α1 chains from calf or human type I and type III collagen. Amino acid analysis and cyanogen bromide peptide profiles of pepsin-treated TSD4 collagen demonstrated significant differences from those of other collagens (II, III, IV) of the type α1(X)₃, although similar to that of the α1 chain of type I collagen, [α1(I)]₂α2. Taken together, acrylamide gel electrophoresis, amino acid composition, electron microscopy, and cyanogen bromide peptide analysis indicate that this material represents a new molecular species of collagen not previously characterized, probably related to [α1(I)]₃.     

FBJ virus-induced osteosarcoma has type V collagen consisting of A, B and C-like chains in addition to type I collagen

A study was carried out on collagen chains of FBJ virus-induced osteosarcoma. Collagens were extracted from pepsin-digested tissues and fractionated by differential salt precipitation. An acidic 0.7 M NaCl precipitate contained type I, type I trimer and/or type III collagens. Collagen fractions precipitated at acidic 1.2 M NaCl showed features characteristic of type V collagen consisting of three chains (mol. weights of which were 120K, 110K and 100K daltons). None of these chains, however, was identical to any of the B, C or A chains reported by Sage et al. in 1979 (1), judging from amino acid composition, cyanogen bromide cleavage and phosphocellulose chromatography data.     

Characterization of notochord collagen as a cartilage-type collagen

Sturgeon notochord and cartilage collagens have been characterized with respect to chromatographic properties, amino acid composition, carbohydrate content, and cyanogen bromide cleavage products of the component α chains. The data show that the collagen of both tissues is comprised of a single type of α chain and that the notochord and cartilage chains are identical. Further, the sturgeon chains bear a striking resemblance to previously characterized α1(II) chains from avian and mammalian hyaline cartilages. These observations strongly suggest that the data may be extrapolated to higher organisms and indicate that during development, a cartilage-type collagen is synthesized by notochord cells prior to the appearance of tissues classically identified as cartilage on the basis of morphology.     

Synthesis of [pro alpha 1(IV)]3 collagen molecules by cultured embryo-derived parietal yolk sac cells

Electron immunohistochemical studies demonstrate that cultured embryo-derived parietal yolk sac (ED-PYS) carcinoma cells synthesize type IV collagen. This material has been isolated and characterized. The collagen obtained after limited pepsin digestion from the medium in which the cells are grown is composed of homogeneous components with a molecular mass of approximately 95 000 daltons. When chromatographed on (carboxymethyl)cellulose under denaturing conditions, the chains elute as acidic components slightly before the human alpha 1(I) chain and coincident with the position of elution of the pepsin-derived human alpha 1(IV) chain. This analysis indicates the presence of a single type of collagen chain in the pepsin-derived ED-PYS synthesized material. In addition, the profile of cyanogen bromide (CNBr) cleavage products obtained from the pepsin-derived ED-PYS cell collagen chains is essentially identical with that derived from the human alpha 1(IV) chain. Isolation of the medium collagen in the absence of pepsin digestion reveals the presence of two high molecular weight components equivalent in size to procollagen alpha chains. However, both high molecular weight products yield CNBr cleavage products that correspond to those obtained from the pepsin-derived alpha 1(IV) chain. The ED-PYS cell-associated collagens obtained with or without the use of pepsin contain components that are essentially identical with those isolated from the culture-medium collagen. These data provide definitive evidence for the existence of type IV collagen molecules composed solely of alpha 1(IV) procollagen chains and further document the usefulness of ED-PYS cells for investigating the biosynthesis of basement membrane components.     

Fibril-forming collagens in lamprey

Five types of collagen with triple-helical regions approximately 300 nm in length were found in lamprey tissues which show characteristic D-periodic collagen fibrils. These collagens are members of the fibril forming family of this primitive vertebrate. Lamprey collagens were characterized with respect to solubility, mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, carboxylmethyl-cellulose chromatography, peptide digestion patterns, composition, susceptibility to vertebrate collagenase, thermal stability, and segment long spacing-banding pattern. Comparison with fibril-forming collagens in higher vertebrates (types I, II, III, V, and XI) identified three lamprey collagens as types II, V, and XI. Both lamprey dermis and major body wall collagens had properties similar to type I but not the typical heterotrimer composition. Dermis molecules had only alpha 1(I)-like chains, while body wall molecules had alpha 2(I)-like chains combined with chains resembling lamprey type II. Neither collagen exhibited the interchain disulfide linkages or solubility properties of type III. The conservation of fibril organization in type II/type XI tissues in contrast to the major developments in type I and type III tissues after the divergence of lamprey and higher vertebrates is consistent with these results. The presence of type II and type I-like molecules as major collagens and types V and XI as minor collagens in the lamprey, and the differential susceptibility of these molecules to vertebrate collagenase is analogous to the findings in higher vertebrates.     

The cell adhesion domain of type XVII collagen promotes integrin-mediated cell spreading by a novel mechanism

Type XVII collagen (BP180) is a keratinocyte transmembrane protein that exists as the full-length protein in hemidesmosomes and as a 120-kDa shed ectodomain in the extracellular matrix. The largest collagenous domain of type XVII collagen, COL15, has been described previously as a cell adhesion domain (Tasanen, K., Eble, J. A., Aumailley, M., Schumann, H., Baetge, J, Tu, H., Bruckner, P., and Bruckner-Tuderman, L. (2000) J. Biol. Chem. 275, 3093-3099). In the present work, the integrin binding of triple helical, human recombinant COL15 was tested. Solid phase binding assays using recombinant integrin alpha(1)I, alpha(2)I, and alpha(10)I domains and cell spreading assays with alpha(1)beta(1)- and alpha(2)beta(1)-expressing Chinese hamster ovary cells showed that, unlike other collagens, COL15 was not recognized by the collagen receptors. Denaturation of the COL15 domain increased the spreading of human HaCaT keratinocytes, which could migrate on the denatured COL15 domain as effectively as on fibronectin. Spreading of HaCaT cells on the COL15 domain was mediated by alpha(5)beta(1) and alpha(V)beta(1) integrins, and it could be blocked by RGD peptides. The collagen alpha-chains in the COL15 domain do not contain RGD motifs but, instead, contain 12 closely related KGD motifs, four in each of the three alpha-chains. Twenty-two overlapping, synthetic peptides corresponding to the entire COL15 domain were tested; three peptides, all containing the KGD motif, inhibited the spreading of HaCaT cells on denatured COL15 domain. Furthermore, this effect was lost by mutation from D to E (KGE instead of KGD). We suggest that the COL15 domain of type XVII collagen represents a specific collagenous structure, unable to interact with the cellular receptors for other collagens. After being shed from the cell surface, it may support keratinocyte spreading and migration.     

Isolation and identification of basement membrane collagen purified from dissociated rabbit renal tubules

In the present study collagens were isolated and identified from morphologically pure basement membrane material. Preparations of rabbit renal tubules devoid of contaminating glomeruli were obtained by homogenization and sieving of kidney cortices. Cellular material was removed by sequential detergent solubilization and the purity of the resultant tubular basement membrane was verified by transmission electron microscopy. The collagenous component of this ultrastructurally pure starting material was isolated by limited pepsinization and salt precipitation. Polyacrylamide gel electrophoresis of this collagen under nonreducing conditions resulted in four major bands: 300,000 (γ component), 100,000 (100K), 80,000 (80K), and 50,000 (50K). Individual collagen fractions of each of these molecular weights were then isolated from preparative polyacrylamide gels. Identification by their electrophoretic properties and cyanogen bromide peptide patterns leads us to believe that: (i) the 100K is composed of the C chain of type IV collagen; (ii) the 80K and 50K are derived from the genetically distinct D chain of type IV collagen; (iii) the γ component is structurally related to the 100K, 80K, and 50K; and (iv) A and B chains (type V collagen) are not major components of rabbit renal tubular basement membranes.     

Binding of soluble type I collagen to fibroblasts: specificities for native collagen types, triple helical structure, telopeptides, propeptides, and cyanogen bromide-derived peptides

Unlabeled collagenous proteins were quantified as inhibitors of binding of native, soluble, radioiodinated type I collagen to the fibroblast surface. Collagen types IV, V a minor cartilage isotype (1 alpha 2 alpha 3 alpha), and the collagenlike tail of acetylcholinesterase did not inhibit binding. Collagen types II and III behaved as competitive inhibitors of type I binding. Denaturation of native collagenous molecules exposed cryptic inhibitory determinants in the separated constituent alpha chains. Inhibition of binding by unlabeled type I collagen was not changed by enzymatic removal of the telopeptides. Inhibitory determinants were detected in cyanogen bromide-derived peptides from various regions of helical alpha 1 (I) and alpha 1(III) chains. The aminoterminal propeptide of chick pro alpha 1(I) was inhibitory for binding, whereas the carboxyterminal three-chain propeptide fragment of human type I procollagen was not. The data are discussed in terms of the proposal that binding to surface receptors initiates the assembly of periodic collagen fibrils in vivo.