Type VIII collagen from bovine Descemet's membrane: structural characterization of a triple-helical domain

Bovine corneal Descemet's membrane (DM) was subjected to limited pepsin digestion. Soluble native collagens were fractionated by differential salt precipitation, and a mixture of type V collagen and collagenous fragments with a chain Mr of 50,000 (50K) was obtained at a concentration of 1.5 M NaCl. Further purification of the 50K collagen by molecular sieve and high-performance liquid chromatography resulted in the isolation of two-non-disulfide-bonded polypeptides, 50K-A and 50K-B, which were susceptible to several neutral proteases, including bacterial collagenase. By the criteria of peptide mapping, amino acid composition, and N-terminal sequence analysis, 50K-A and 50K-B were structurally dissimilar, although both chains contained Gly-X-Y repeats. 50K-A and 50K-B were immunologically and structurally distinct from collagen type I, III, IV, V, and VI. Immunohistochemical studies of bovine ocular tissue showed preferential distribution of the collagen containing the 50K fragment in the DM, with a more disperse arrangement of apparently interconnecting fibrils in the corneal stroma. Type VIII collagen isolated from the culture medium of metabolically radiolabeled bovine corneal endothelial (BCE) cells and its pepsin-resistant Mr 50 000 domain(s) both cross-reacted with antisera to 50K polypeptides from the corneal DM. Additionally, the CNBr peptide maps of pepsin-resistant Mr 50 000 polypeptides of type VIII collagen isolated from BCE cells and bovine corneal DM were highly similar.(ABSTRACT TRUNCATED AT 250 WORDS)     

Biosynthesis of chick type VI collagen. I. Intracellular assembly and molecular structure

A monospecific rabbit antiserum to pepsin-extracted chick gizzard type VI collagen was used to characterize the intact forms of type VI collagen in tissues and cultured cells. Immunoblotting of gizzard extracts revealed polypeptides of Mr ranging from 260,000 to 140,000. Components of about Mr = 260,000, 150,000, and 140,000, each with a different peptide profile, were immunoprecipitated from labeled matrix-free chick embryo cells. Cleavage of the immunoprecipitated polypeptides with pepsin generated pepsin-resistant fragments of about Mr = 70,000, 55,000, and 45,000 that represent the alpha 1(VI), alpha 2(VI), and alpha 3 (VI) fragments. Immunoblotting with affinity-purified antibodies indicated that the Mr = 150,000 is the intact parent polypeptide of the alpha 1(VI) pepsin; the Mr = 140,000 of the alpha 2(VI) pepsin, and the Mr = 260,000 of the alpha 3(VI) pepsin. Association of the three parent chains was studied by pulse-chase experiments and sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis under nonreduced conditions. A complex of Mr = 500,000 is already present intracellularly at the end of a 7-min pulse and increases considerably with time while the three unassembled chains show a comparable decrease. After 5-15 min of chase larger forms appeared along with small amounts of aggregated material that did not enter the gel. Analysis of the immunoprecipitate by diagonal electrophoresis indicated that the component of Mr = 500,000 and the larger forms dissociated into the Mr = 260,000, 150,000, and 140,000 polypeptides. Sedimentation profile of a labeled cell extract on a 5-20% sucrose gradient under nondenaturing conditions confirmed the presence of three different peptides in the complex.     

Type VI collagen. Studies on its localization, structure, and biosynthetic form with monoclonal antibodies

Monoclonal antibodies were prepared by immunization with whole tissue and were selected for their reactivity with extracellular matrices in tissue immunofluorescence. Two such antibodies were used to isolate the corresponding antigen from pepsin extracts of human placental tissue by immunochromatography. In each case, polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate showed that the isolated material was composed of four polypeptides of Mr between 57,000 and 85,000 that were disulfide-bonded into a high molecular weight aggregate. Amino acid analyses showed that the isolated material was partly collagenous. The material was shown to be antigenically related to previously isolated peptic fragments of type VI collagen and it shared their unique structure as revealed by electron microscopy. Based on these findings, it was concluded that the isolated material was a form of type VI collagen. In immunofluorescence, the monoclonal antibodies localized type VI collagen throughout the connective tissue and in the extracellular matrix of cultured fibroblasts. Polypeptides presumably comprising the intact form of this collagen were isolated from cultures of metabolically radiolabeled fibroblast cell cultures using the two monoclonal antibodies. The isolated material consisted of two polypeptides of Mr 240,000 and 140,000 that were extensively disulfide cross-linked. Four additional monoclonal antibodies bound the same radioactive polypeptides from fibroblast cultures, but only one of them reacted with the fragments isolated from pepsin-digested placenta. Since all six antibodies were originally selected based on tissue immunofluorescence, and therefore react with the tissue form of the protein, the tissue form appears to be more similar to the polypeptides detected in fibroblast cultures than to the pepsin-resistant fragments. Since these monoclonal antibodies apparently recognize different parts of the molecule, they will be useful for further study of the structure and function of the intact form of type VI collagen.     

Partial characterization of type X collagen from bovine growth-plate cartilage. Evidence that type X collagen is processed in vivo

Sequential extraction of bovine growth-plate cartilage with 4 M guanidinium chloride and pepsin was used to identify the intact and pepsinized forms respectively of type X collagen. This collagen occurs predominantly as the processed [alpha 1(X)]3 form in vivo, although the procollagen [pro alpha 1(X)]3 form can also be detected. The bovine pro alpha 1(X) and alpha 1(X) chains have Mr values identical to the corresponding chick species (Mr 59,000 and 49,000). However, the pepsinized alpha 1(X)p chains (Mr 47,000) are larger than those of the chick (Mr 45,000), and the bovine collagen type X is further distinguished by being disulphide-bonded within the triple-helical domain.     

Circular-dichroism and electron-microscopy studies of human subcomponent C1q before and after limited proteolysis by pepsin.

1. A fragment of human subcomponent C1q was prepared by limited proteolysis with pepsin at 37 degrees C for 20 h, and at pH4.4, followed by gel filtration on Sephadex G-200. This fragment was shown to contain all the collagen-like features known to be present in the intact molecule [Reid (1976) Biochem. J. 155, 5-17]. 2. Circular-dichroism studies showed the presence of positive bands at 230 and 223 nm in the intact subcomponent C1q and pepsin fragment respectively, compared with a positive band at 220 nm obtained for lathyritic rat skin collagen. These bands were abolished by collagenase treatment, which suggested that there may some collagen-like triple-helical structure in subcomponent C1q and that this structure resides in the pepsin-resistant portion of the molecule. However, the 230 and 223 nm bands had a substantially lower magnitude than that obtained for the unaggregated single fibres of totally triple-helical collagen. 3. Thermal-transition temperatures obtained for subcomponent C1q, the pepsin fragment and the reduced and alkylated pepsin fragment were 48 degrees, 48 degrees and 39 degrees C respectively, compared with a value of 38 degrees C obtained for lathyritic rat skin collagen. 4. Only the unreduced pepsin fragment regained significant amounts (up to 60%) of collagen-like structure, after heat denaturation and cooling, as estimated by circular-dichroism measurements. 5. Electron-microscopy studies of subcomponent C1q and the collagen-like pepsin-resistant fragment of subcomponent C1q showed that the six peripheral globular regions of the molecule were fragmented by pepsin leaving the six collagen-like connecting strands and fibril-like central portion intact.     

Assembly of stable human type I and III collagen molecules from hydroxylated recombinant chains in the yeast Pichia pastoris. Effect of an engineered C-terminal oligomerization domain foldon

The C-propeptides of the pro alpha chains of type I and type III procollagens are believed to be essential for correct chain recognition and chain assembly in these molecules. We studied here whether the 30-kDa C-propeptides of the human pC alpha 1(I), pC alpha 2(I), and pC alpha 1(III) chains, i.e. pro alpha chains lacking their N-propeptides, can be replaced by foldon, a 29-amino acid sequence normally located at the C terminus of the polypeptide chains in the bacteriophage T4 fibritin. The alpha foldon chains were expressed in Pichia pastoris cells that also expressed the two types of subunit of human prolyl 4-hydroxylase; the foldon domain was subsequently removed by pepsin treatment, which also digests non-triple helical collagen chains, whereas triple helical collagen molecules are resistant to it. The foldon domain was found to be very effective in chain assembly, as expression of the alpha 1(I)foldon or alpha 1(III)foldon chains gave about 2.5-3-fold the amount of pepsin-resistant type I or type III collagen homotrimers relative to those obtained using the authentic C-propeptides. In contrast, expression of chains with no oligomerization domain led to very low levels of pepsin-resistant molecules. Expression of alpha 2(I)foldon chains gave no pepsin-resistant molecules at all, indicating that in addition to control at the level of the C-propeptide other restrictions at the level of the collagen domain exist that prevent the formation of stable [alpha 2(I)]3 molecules. Co-expression of alpha 1(I)foldon and alpha 2(I)foldon chains led to an efficient assembly of heterotrimeric molecules, their amounts being about 2-fold those obtained with the authentic C-propeptides and the alpha 1(I) to alpha 2(I) ratio being 1.91 +/- 0.31 (S.D.). As the foldon sequence contains no information for chain recognition, our data indicate that chain assembly is influenced not only by the C-terminal oligomerization domain but also by determinants present in the alpha chain domains.     

Biosynthetic and structural properties of endothelial cell type VIII collagen

A highly unusual endothelial cell collagen (Sage, H., Pritzl, P., and Bornstein, P., (1980) Biochemistry 19, 5747-5755) has been characterized in greater detail. Pulse-chase experiments with bovine aortic endothelial cells revealed two nondisulfide-bonded collagens, of apparent chain Mr = 177,000 and 125,000, with an estimated synthesis and secretion time of 75 min. Stepwise, quantitative processing to stable lower molecular weight forms as described for type I procollagen was not observed. Endothelial collagen was secreted over a temperature range of 24-37 degrees C and, prior to heat denaturation, did not display affinity for a gelatin-binding fragment of fibronectin coupled to Sepharose. The presence of a pepsin-resistant domain (Mr = 50,000) in both the soluble and cell layer-associated forms of this protein was shown by ion exchange chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Endothelial collagen was cleaved by vertebrate collagenase into several discrete fragments that differed in molecular weight from the characteristic alpha A and alpha B fragments generated from the interstitial collagens. Nontriple helical domains corresponding to the NH2- and COOH-terminal propeptides of other procollagen types were not found after incubation of endothelial collagen with bacterial collagenase. Additional evidence for the lack of extended noncollagenous sequences was provided by studies with mast cell proteases, which convert native procollagen to collagen but are unreactive toward native interstitial collagens. Endothelial collagen was not cleaved by these enzymes at 37 degrees C, but, as observed for interstitial collagen alpha chains, required prior heating at elevated temperatures for cleavage to occur. In view of this unique set of structural characteristics, and a distribution that is not restricted to the endothelium, we have designated this protein as type VIII collagen.     

Bovine cartilage types VI and IX collagens. Characterization of their forms in vivo.

1. Collagens were extracted from bovine cartilage by 4 M-guanidinium chloride in the presence of proteinase inhibitors and identified by immunoblotting with specific anti-collagen sera. 2. The collagens retained their native conformations (shown by the resistance of their triple-helical domains to pepsin digestion), and the molecular masses of their component alpha-chains indicated that the chains were intact. 3. Type VI collagen was extracted as a large-molecular-mass disulphide-bonded aggregate composed of components of molecular mass 140 kDa and 200-240 kDa, and was therefore similar to type VI collagen identified in noncartilaginous tissues. Immunoblotting established the 200-240 kDa components as intact forms of the alpha 3(VI) chain. 4. Type IX collagen consisted of three clearly separable components of molecular mass 84 kDa, 72 kDa and 66 kDa, which were assigned to the alpha 1(IX)-, alpha 3(IX)- and alpha 2(IX)-chains respectively, and a large proportion of this collagen had no covalently bound glycosaminoglycan attached to the alpha 2(IX)-chain. 5. Differences between the type IX collagen extracted from bovine cartilage and that identified in biosynthetic studies on chick cartilage are discussed.     

Sequence analysis of alpha 1(VI) and alpha 2(VI) chains of human type VI collagen reveals internal triplication of globular domains similar to the A domains of von Willebrand factor and two alpha 2(VI) chain variants that differ in the carboxy terminus.

Amino acid sequences of human collagen alpha 1(VI) and alpha 2(VI) chains were completed by cDNA sequencing and Edman degradation demonstrating that the mature polypeptides contain 1009 and 998 amino acid residues respectively. In addition, they contain small signal peptide sequences. Both chains show 31% identity in the N-terminal (approximately 235 residues) and C-terminal (approximately 430 residues) globular domains which are connected by a triple helical segment (335-336 residues). Internal alignment of the globular sequences indicates a repetitive 200-residue structure (15-23% identity) occurring three times (N1, C1, C2) in each chain. These repeating subdomains are connected to each other and to the triple helix by short (15-30 residues) cysteine-rich segments. The globular domains possess several N-glycosylation sites but no cell-binding RGD sequences, which are exclusively found in the triple helical segment. Sequencing of alpha 2(VI) cDNA clones revealed two variant chains with a distinct C2 subdomain and 3' non-coding region. The repetitive segments C1, C2 and, to a lesser extent, N1 show significant identity (15-18%) to the collagen-binding A domains of von Willebrand factor (vWF) and they are also similar to some integrin receptors, complement components and a cartilage matrix protein. Since the globular domains of collagen VI come into close contact with triple helical segments during the formation of tissue microfibrils it suggests that the globular domains bind to collagenous structures in a manner similar to the binding of vWF to collagen I.     

Type VIII collagen has a restricted distribution in specialized extracellular matrices

A pepsin-resistant triple helical domain (chain 50,000 Mr) of type VIII collagen was isolated from bovine corneal Descemet's membrane and used as an immunogen for the production of mAbs. An antibody was selected for biochemical and tissue immunofluorescence studies which reacted both with Descemet's membrane and with type VIII collagen 50,000-Mr polypeptides by competition ELISA and immunoblotting. This antibody exhibited no crossreactivity with collagen types I-VI by competition ELISA. The mAb specifically precipitated a high molecular mass component of type VIII collagen (EC2, of chain 125,000 Mr) from the culture medium of subconfluent bovine corneal endothelial cells metabolically labeled for 24 h. In contrast, confluent cells in the presence of FCS and isotope for 7 d secreted a collagenous component of chain 60,000 Mr that did not react with the anti-type VIII collagen IgG. Type VIII collagen therefore appears to be synthesized as a discontinuous triple helical molecule with a predominant chain 125,000 Mr by subconfluent, proliferating cells in culture. Immunofluorescence studies with the mAb showed that type VIII collagen was deposited as fibrils in the extracellular matrix of corneal endothelial cells. In the fetal calf, type VIII collagen was absent from basement membranes and was found in a limited number of tissues. In addition to the linear staining pattern observed in the Descemet's membrane, type VIII collagen was found in highly fibrillar arrays in the ocular sclera, in the meninges surrounding brain, spinal cord, and optic nerve, and in periosteum and perichondrium. Fine fibrils were evident in the white matter of spinal cord, whereas a more generalized staining was apparent in the matrices of cartilage and bone. Despite attempts to unmask the epitope, type VIII collagen was not found in aorta, kidney, lung, liver, skin, and ligament. We conclude that this unusual collagen is a component of certain specialized extracellular matrices, several of which are derived from the neural crest.     

Human type VI collagen: isolation and characterization of alpha 1 and alpha 2 chains by two-dimensional preparative gel electrophoresis

Two 140 kDa collagenous glycoproteins were isolated from 5 M guanidinium chloride extracts of human uterine leiomyoma by two-dimensional preparative gel electrophoresis. The glycoproteins represented the major concanavalin A binding fraction of the extract and were also present in adult human skin. On two-dimensional gel electrophoresis the glycoproteins appeared as elongated spots, indicating variations of their isoelectric points from 5 to 6. These glycoproteins were disulfide-bonded components of high molecular mass protein and, after reduction, became sensitive to collagenase treatment that generated peptides corresponding in size to those of the noncollagenous domains of type VI collagen. Antisera raised against these purified glycoproteins reacted with either pepsin-derived alpha 1(VI) or pepsin-derived alpha 2(VI) chains but not with alpha 3(VI) chain of human type VI collagen. Reciprocally, these glycoproteins reacted with monoclonal antibodies against type VI collagen. These results indicate that the glycoproteins represent the integral alpha 1 and alpha 2 chains of type VI collagen. The globular domains of alpha 1(VI) and alpha 2(VI) chains remaining after collagenase treatment appeared on two-dimensional gel electrophoresis as elongated spots, suggesting that the noncollagenous portions determine the well known microheterogeneity of the molecule. The differences in isoelectric points between and within alpha chains may facilitate the formation of microfibrillar network.     

Pepsin-generated type VI collagen is a degradation product of GP140

A major extracellular matrix glycoprotein, GP140 , synthesized by WI-38 human lung fibroblasts has previously been shown to be collagen-like. A form of GP140 that is related to extracellular matrix GP140 both antigenically and in apparent molecular mass was isolated from human placenta. Types I-VI collagen were isolated from human tissues by limited pepsin digestion, selective salt precipitation, and chromatography. Immunoblot analysis of the collagens and GP140 utilizing affinity-purified polyclonal antiserum directed against extracellular matrix GP140 demonstrated cross-reactivity of antibodies with type VI collagen. Both type VI collagen and matrix GP140 could be digested with bacterial collagenase following reduction with dithiothreitol but were collagenase insensitive under nonreducing conditions, unlike types I-V collagen. Placental and matrix GP140 and type VI collagen were shown to have receptors for 125I-labeled Lens culinaris lectin. Pepsin digestion of WI-38 extracellular matrix GP140 yielded a 64,000-dalton band which co-migrated with subunits of reduced type VI collagen on Coomassie-stained sodium dodecyl sulfate-polyacrylamide gel electrophoresis gels, reacted with anti- GP140 antiserum and 125I-labeled L. culinaris lectin, and was collagenase-sensitive only under reducing conditions. CNBr fragmentation of extracellular matrix GP140 , the 64,000-dalton pepsin-resistant peptide of GP140 and type VI collagen followed by immunoblot analysis using anti- GP140 revealed similarities in peptide maps of GP140 and type VI collagen. Our data strongly suggest that GP140 and type VI collagen share characteristics that differ from those of other collagen types and that intermolecular disulfide bonding appears to stabilize these molecules in their native unreduced form, thus conferring collagenase resistance. Finally, the SC1 and SC2 subunits of type VI collagen appear to be generated by pepsin digestion of GP140 .     

Type VI collagen is composed of a 200 kd subunit and two 140 kd subunits.

We have isolated type VI collagen, a transformation-sensitive glycoprotein of the extracellular matrix, in an intact, disulfide-bonded form. The protein contains a 200 kd subunit and two different 140 kd subunits in a stoichiometric ratio. Based on the amount of hydroxyproline and hydroxylysine, the sensitivity to bacterial collagenase and the cross-reactivity with antibodies to pepsin-extracted type VI collagen, we have identified the 200 kd subunit as the alpha 3(VI) chain and the two 140 kd subunits as the alpha 1(VI) and alpha 2(VI) chains. The alpha 3(VI) chain is synthesized by cells in culture as a precursor of 260 kd, while no precursor form of the other two chains could be detected.     

Properties of the globular domain of type IV collagen and its relationship to the Goodpasture antigen

The globular domain of type IV collagen from bovine glomerular basement membrane was solubilized by collagenase digestion. Components of this domain include several monomer-size and structurally related dimer-size polypeptides. The monomer-size polypeptides were resolved into three fractions (M1, M2, and M3) with slightly different mobilities upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis (nonreduced Mr = 24,500-28,300). Chemical and immunochemical studies indicate that each is a distinct component. M2 is reactive with antibodies from patients with Goodpasture syndrome. The molecular weight by sedimentation equilibrium was 32,000 for M2 and 28,000 for M1. The dimers were characterized as two classes, D1 and D2. D1 consists of two sets of nonreactive components (D1a-d and D1a,c) whereas D2 contains one set of four components (D2a-d), each of which is reactive with Goodpasture sera. Chemical and immunochemical studies indicate that a monomer-dimer relationship exists between M1 and D1 and between M2 and D2. The origin of M3 remains undetermined. Rabbit antibodies to type IV collagen alpha chains react with M1 and M2, and antibodies to M1 and M2 react with type IV collagen alpha chains, which provides additional evidence for the localization of the Goodpasture antigen to one of the chains of type IV collagen.     

Isolation from bovine elastic tissues of collagen type VI and characterization of its form in vivo.

Foetal-bovine nuchal ligament and aorta, together with adult-bovine aorta and pregnant uterus, were extracted under dissociative conditions in the absence and in the presence of a reducing agent. A collagenous glycoprotein of Mr 140000 [designated component 140K(VI)], identified in these extracts as the major periodate/Schiff-positive component, was shown to be related to collagen type VI. Digestion of non-reduced extracts with pepsin yielded periodate/Schiff-positive peptides that, on the basis of their electrophoretic mobilities, amino acid analyses and peptide 'maps', were identical with type VI collagen fragments prepared by standard procedures. It is concluded that collagen type VI occurs in vivo as molecule comprising three chains of Mr 140000 in which the helical domains account for about one-third of each polypeptide. Biosynthetic experiments with nuchal-ligament fibroblasts in culture demonstrated that a bacterial-collagenase-sensitive [3H]fucose-labelled glycoprotein, Mr 140000, was immunoprecipitated from culture medium by a specific antibody to the pepsin-derived form of collagen type VI. This result suggests that the collagenous polypeptides [140K(VI) components] represent the biosynthetic precursors of type VI collagen that do not undergo processing to smaller species before deposition in the extracellular matrix. Analyses of 5M-guanidinium chloride extracts of tissues with markedly different elastin contents and at different stages of development suggested that there was no relationship between collagen type VI and elastic-fibre microfibrils, a conclusion supported by the observation that the immunoprecipitated glycoprotein, Mr 140000, was distinct from the glycoprotein MFPI, Mr 150000, believed to be a constituent of these microfibrils [Sear, Grant & Jackson (1981) Biochem. J. 194, 587-598].     

Type VI collagen of the intervertebral disc. Biochemical and electron-microscopic characterization of the native protein.

The collagen framework of the intervertebral disc contains two major fibril-forming collagens, types I and II. Smaller amounts of other types of collagen are also present. On examination of the nature and distribution of these minor collagens within bovine disc tissue, type VI collagen was found to be unusually abundant. It accounted for about 20% of the total collagen in calf nucleus pulposus, and about 5% in the annulus fibrosus. It was discovered by serially digesting disc tissue with chondroitin ABC lyase and Streptomyces hyaluronidase that native covalent polymers of type VI collagen could be extracted. Electron micrographs of this material prepared by rotary shadowing revealed the characteristic dimensions of tetramers and double tetramers of type VI molecules, with their central rods and terminal globular domains. Molecular-sieve column chromatography on agarose under non-reducing non-denaturing conditions gave a series of protein peaks with molecular sizes equivalent to the tetramer, double tetramer and higher multimers. On SDS/polyacrylamide-gel electrophoresis after disulphide cleavage, these fractions of type VI collagen all showed a main band at Mr 140,000 and four lesser bands between Mr 180,000 and 240,000. On electrophoresis without disulphide cleavage in agarose/2.4% polyacrylamide only dimeric (six chains) and tetrameric (12 chains) forms of type VI molecules were present. The ability to extract all the type VI collagen of the tissue in 4 M-guanidinium chloride, and absence of aldehyde-mediated cross-linking residues on direct analysis, showed that, in contrast with most matrix collagens, type VI collagen does not function as a covalently cross-linked structural polymer.     

Biosynthesis and regulation of type V collagen in diploid human fibroblasts

The biosynthesis of type V collagen and its regulation were studied using diploid human gingival fibroblasts. Cells were metabolically labeled with radioactive amino acids and labeled proteins were subjected to limited pepsin digestion, DEAE-cellulose chromatography at 15 degrees C, and polyacrylamide gel electrophoresis. Proteins eluted from DEAE-cellulose columns by 0.25 M NaCl contained a collagen species which was resistant to mammalian collagenase and had alpha chains with hydroxylysine/lysine ratios and CNBr peptide patterns similar to alpha 1(V) and alpha 2(V). Procollagen(V) fractions obtained by DEAE-cellulose chromatography and immunoprecipitates of type V collagen antibody contained polypeptides with Mr = 239,000, 219,000, 198,000, 174,000, 157,000, and 132,000. By comparing the CNBr peptide maps of these proteins with those of standard alpha 1(V) and alpha 2(V) chains, the first three polypeptides were shown to be related to alpha 1(V) and the others to alpha 2(V). It was concluded that the gingival fibroblasts synthesize type V collagen, that the pro alpha 1(V) and the pro alpha 2(V) chains have Mr = 239,000 and 174,000, respectively, and that the alpha 1(V) and alpha 2(V) chains laid in the form of fibrils have Mr = 198,000 and 132,000, respectively. A detectable amount of type V collagen was synthesized only at high cell density, and it was associated with the cell layer. The amount and proportion of type V synthesized were increased when the cells were labeled in the presence of serum, and the increase was accompanied by a decrease in type III. This effect was dependent on serum concentration. Serum obtained from platelet-poor plasma failed to elicit this effect, and it was restored by the addition of platelet-derived growth factor. Platelet-derived growth factor was effective in medium with and without platelet-poor serum. Thus, it appears that platelet-derived growth factor may be an important regulatory factor in the synthesis of types V and III collagens.     

The C5 domain of the collagen VI alpha3(VI) chain is critical for extracellular microfibril formation and is present in the extracellular matrix of cultured cells

Collagen VI, a microfibrillar protein found in virtually all connective tissues, is composed of three distinct subunits, alpha1(VI), alpha2(VI), and alpha3(VI), which associate intracellularly to form triple helical heterotrimeric monomers then dimers and tetramers. The secreted tetramers associate end-to-end to form beaded microfibrils. Although the basic steps in assembly and the structure of the tetramers and microfibrils are well defined, details of the interacting protein domains involved in assembly are still poorly understood. To explore the role of the C-terminal globular regions in assembly, alpha3(VI) cDNA expression constructs with C-terminal truncations were stably transfected into SaOS-2 cells. Control alpha3(VI) N6-C5 chains with an intact C-terminal globular region (subdomains C1-C5), and truncated alpha3(VI) N6-C1, N6-C2, N6-C3, and N6-C4 chains, all associated with endogenous alpha1(VI) and alpha2(VI) to form collagen VI monomers, dimers and tetramers, which were secreted. These data demonstrate that subdomains C2-C5 are not required for monomer, dimer or tetramer assembly, and suggest that the important chain selection interactions involve the C1 subdomains. In contrast to tetramers containing control alpha3(VI) N6-C5 chains, tetramers containing truncated alpha3(VI) chains were unable to associate efficiently end-to-end in the medium and did not form a significant extracellular matrix, demonstrating that the alpha3(VI) C5 domain plays a crucial role in collagen VI microfibril assembly. The alpha3(VI) C5 domain is present in the extracellular matrix of SaOS-2 N6-C5 expressing cells and fibroblasts demonstrating that processing of the C-terminal region of the alpha3(VI) chain is not essential for microfibril formation.     

Structural basis of type VI collagen dimer formation

We have determined the interactive sites required for dimer formation in type VI collagen. Despite the fact that type VI collagen is a heterotrimer composed of alpha1(VI), alpha2(VI), and alpha3(VI) chains, the formation of dimers is determined principally by interactions of the alpha2(VI) chain. Key components of this interaction are the metal ion-dependent adhesion site (MIDAS) motif of the alpha2C2 A-domain and the GER sequence in the helical domain of another alpha2(VI) chain. Replacement of the alpha2(VI) C2 domain with the alpha3(VI) domain abolished dimer formation, whereas alterations in the alpha2(VI) C1 domain did not disrupt dimer formation. When the helical sequences were investigated, replacement of the alpha2(VI) sequence GSPGERGDQ with the alpha3(VI) sequence GEKGERGDV abolished dimer formation. Mutating the Pro-108 to a Lys-108 in this alpha2(VI) sequence did not influence dimer formation and suggests that, unlike the integrin I-domain/triple-helix interaction, hydroxyproline is not required in collagen VI A-domain/helix interaction. These results demonstrate that the alpha2(VI) chain position in the assembled triple-helical molecule is critical for antiparallel dimer formation and identify the interacting collagenous and MIDAS sequences involved. These interactions underpin the subsequent assembly of type VI collagen.