Procollagen VII self-assembly depends on site-specific interactions and is promoted by cleavage of the NC2 domain with procollagen C-proteinase

Procollagen VII is a homotrimer of 350-kDa proalpha1(VII) chains. Each chain has a central collagenous domain flanked by a noncollagenous amino-terminal NC1 domain and a carboxy-terminal NC2 domain. After secretion from cells, procollagen VII molecules form antiparallel dimers with a 60 nm overlap. These dimers are stabilized by disulfide bonds formed between cysteines present in the NC2 domain and cysteines present in the triple-helical domain. Electron microscopy has provided direct evidence for the existence of collagen VII dimers, but the dynamic process of dimer formation is not well understood. In the present study, we tested the hypothesis that, during dimer formation, the NC2 domain of one procollagen VII molecule specifically recognizes and binds to the triple-helical region adjacent to Cys-2625 of another procollagen VII molecule. We also investigated the role of processing of the NC2 domain by the procollagen C-proteinase/BMP-1 in dimer assembly. We engineered mini mouse procollagen VII variants consisting of intact NC1 and NC2 domains and a shortened triple helix in which the C-terminal region encompassing Cys-2625 was either preserved or substituted with the region encompassing Cys-1448 derived from the N-terminal part of the triple-helical domain. The results indicate that procollagen VII self-assembly depends on site-specific interactions between the NC2 domain and the triple-helical region adjacent to Cys-2625 and that this process is promoted by the cleavage of the NC2 by procollagen C-proteinase/BMP1.     

Biosynthesis of two subunits of type IV procollagen and of other basement membrane proteins by a human tumor cell line

The major collagenous component secreted into the medium of cultured HT-1080 tumor cells was identified as type IV procollagen by specific antibodies and characteristic ratios of incorporated labeled 3-hydroxyproline and 4-hydroxyproline. The disulfide-bonded molecules consisted of two subunits, pro-alpha 1(IV) and pro-alpha 2(IV) chains with apparent molecular weights of 180 000 and 165 000. No conversion of the procollagen to collagen or to procollagen intermediates was detected in the cell cultures. The two subunits apparently represent different gene products, since enzymatic digestion of the separated chains produced quite different peptide maps. Pepsin degraded native type IV procollagen successively into several fragments, some still disulfide-linked, giving rise to a complex set of polypeptide chains (Mr = 30 000-140 000). This agrees with similar diverse patterns produced by pepsin from authentic type IV collagens. The ratio between the pro-alpha 1(IV) and pro-alpha 2(IV) chains varied in several experiments between 1.3 and 1.8, suggesting that the two chains belong to different triple-helical molecules. The cells also produced distinct amounts of fibronectin (subunit Mr = 230 000) and of the basement membrane glycoprotein laminin. The latter showed three subunits with Mr = 220 000, 210 000, and 400 000. A further disulfide-bonded, non-collagenous polypeptide (Mr = 160 000) was detected but not yet identified. Immunofluorescence demonstrated these proteins within the cells but not in a pericellular matrix. The production of basement membrane components by HT-1080 cells and lack of interstitial collagens disagree with the original classification of the cell line as a fibrosarcoma.     

Single amino acid substitutions in procollagen VII affect early stages of assembly of anchoring fibrils

Procollagen VII is a homotrimer of 350-kDa pro-alpha1(VII) chains, each consisting of a central collagenous domain flanked by the noncollagenous N-terminal NC1 domain and the C-terminal NC2 domain. After secretion from cells, procollagen VII molecules form anti-parallel dimers with a C-terminal 60-nm overlap. Characteristic alignment of procollagen VII monomers forming a dimer depends on site-specific binding between the NC2 domain and the triple-helical region adjacent to Cys-2634 of the interacting procollagen VII molecules. Formation of the intermolecular disulfide bonds between Cys-2634 and either Cys-2802 or Cys-2804 is promoted by the cleavage of the NC2 domain by procollagen C-proteinase. By employing recombinant procollagen VII variants harboring G2575R, R2622Q, or G2623C substitutions previously disclosed in patients with dystrophic epidermolysis bullosa, we studied how these amino acid substitutions affect intermolecular interactions. Binding assays utilizing an optical biosensor demonstrated that the G2575R substitution increased affinity between mutant molecules. In contrast, homotypic binding between the R2622Q or G2623C molecules was not detected. In addition, kinetics of heterotypic binding of all analyzed mutants to wild type collagen VII were different from those for binding between wild type molecules. Moreover, solid-state binding assays demonstrated that R2622Q and G2623C substitutions prevent formation of stable assemblies of procollagen C-proteinase-processed mutants. These results indicate that single amino acid substitutions in procollagen VII alter its self-assembly and provide a basis for understanding the pathomechanisms leading from mutations in the COL7A1 gene to fragility of the dermal-epidermal junction seen in patients with dystrophic forms of epidermolysis bullosa.     

Multiexon deletion in the procollagen III gene is associated with mild Ehlers-Danlos syndrome type IV

We have characterized a deletion of approximately 9 kilobases which spans from intron 33 to exon 48 of one pro-alpha 1 (III) collagen allele in a patient with Ehlers-Danlos syndrome type IV. The mutation results in the production of an in-frame species of mRNA which lacks the sequences corresponding to residues 595-1,008 of the triple-helical domain. Thus, half of the pro-alpha 1 (III) chains synthesized by the patient's fibroblasts are nearly 30% shorter than normal. The procollagen III molecules composed of either three normal length or three shortened chains are thermally stable and efficiently secreted. In contrast, the procollagen III molecules that contain one or two shortened chains are unstable and are not secreted. Failure to secrete unstable molecules and a residual functional role of the shortened but stable homotrimers may explain the somewhat milder phenotype of this individual compared with that of another Ehlers-Danlos type IV patient bearing a deletion of similar size in the amino-terminal portion of the alpha 1 (III) collagen chain.     

Folding of collagen IV

Collagen IV dimers of two collagen IV molecules connected by their C-terminal globular NC1 domains were isolated by limited digestion with bacterial collagenase from mouse Engelbreth-Holm-Swarm (EHS) sarcoma tissue. The collagenous domains were only 300 nm long as compared to 400 nm of intact collagen IV but the disulfide bonds in the N-terminal region of the major triple helix were retained. Unfolding of the collagenous domains as monitored by circular dichroism occurred in a temperature range of 30 to 44 degrees C with a midpoint at 37 degrees C. The transition is significantly broader than that of the continuous triple helices in collagens I, II and III, a feature which can be explained by the frequent non-collagenous interruptions in the triple-helical domain of collagen IV. Refolding at 25 degrees C following complete unfolding at 50 degrees C was monitored by circular dichroism, selective proteolytic digestion of non-refolded segments and by a newly developed method in which the recovered triple-helical segments were visualized by electron microscopy. Triple-helix formation was found to proceed in a zipper-like fashion from the C-terminal NC1 domains towards the N-terminus, indicating that this domain is essential for nucleations. For collagen IV dimers with intact NC1 domains the rate of triple-helix growth was of comparable magnitude to that of collagen III, demonstrating that the non-collagenous interruptions do not slow down the refolding process where the rate-limiting step is the cis-trans isomerization of proline peptide bonds. Refolding was near to 100% and the refolding products were similar to the starting material as judged by thermal stability and electron microscopic appearance. Removal of the NC1 domains by pepsin or dissociation of their hexametric structures by acetic acid led to a loss of the refolding ability. Instead products with randomly dispersed short triple-helical segments were formed in a slow reaction. In no case, even when the disulfide bonds in the N-terminal region of the triple-helical domain were intact, was refolding from the N- towards the C-terminus observed. Taken together with results in other collagens, this suggests that C to N directionality might be an intrinsic property of triple-helix folding.     

The complete primary structure of mouse alpha 2(IV) collagen. Alignment with mouse alpha 1(IV) collagen

We have determined the nucleotide and amino acid sequences of mouse alpha 2(IV) collagen which is 1707 amino acids long. The primary structure includes a putative 28-residue signal peptide and contains three distinct domains: 1) the 7 S domain (residues 29-171), which contains 5 cysteine and 8 lysine residues, is involved in the cross-linking and assembly of four collagen IV molecules; 2) the triple-helical domain (residues 172-1480), which has 24 sequence interruptions in the Gly-X-Y repeat up to 24 residues in length; and 3) the NC1 domain (residues 1481-1707), which is involved in the end-to-end assembly of collagen IV and is the most highly conserved domain of the protein. Alignment of the primary structure of the alpha 2(IV) chain with that of the alpha 1(IV) chain reported in the accompanying paper (Muthukumaran, G., Blumberg, B., and Kurkinen, M. (1989) J. Biol. Chem. 264, 6310-6317) suggests that a heterotrimeric collagen IV molecule contains 26 imperfections in the triple-helical domain. The proposed alignment is consistent with the physical data on the length and flexibility of collagen IV.     

Mechanism of chain selection in the assembly of collagen IV: a prominent role for the alpha2 chain

Collagens comprise a large superfamily of extracellular matrix proteins that play diverse roles in tissue function. The mechanism by which newly synthesized collagen chains recognize each other and assemble into specific triple-helical molecules is a fundamental question that remains unanswered. Emerging evidence suggests a role for the non-collagenous domain (NC1) located at the C-terminal end of each chain. In this study, we have investigated the molecular mechanism underlying chain selection in the assembly of collagen IV. Using surface plasmon resonance, we have determined the kinetics of interaction and assembly of the alpha1(IV) and alpha2(IV) NC1 domains. We show that the differential affinity of alpha2(IV) NC1 domain for dimer formation underlies the driving force in the mechanism of chain discrimination. Given its characteristic domain recognition and affinity for the alpha1(IV) NC1 domain, we conclude that the alpha2(IV) chain plays a regulatory role in directing chain composition in the assembly of (alpha1)(2)alpha2 triple-helical molecule. Detailed crystal structure analysis of the [(alpha1)(2)alpha2](2) NC1 hexamer and sequence alignments of the NC1 domains of all six alpha-chains from mammalian species revealed the residues involved in the molecular recognition of NC1 domains. We further identified a hypervariable region of 15 residues and a beta-hairpin structural motif of 13 residues as two prominent regions that mediate chain selection in the assembly of collagen IV. To our knowledge, this report is the first to combine kinetics and structural data to describe molecular basis for chain selection in the assembly of a collagen molecule.     

A network model for the organization of type IV collagen molecules in basement membranes

Type IV collagen was solubilized from a tumor basement membrane either by acid extraction or by limited digestion with pepsin. The two forms were similar in composition and the size of the constituent chains but differed when examined by electron microscopy and in the fragment pattern produced by bacterial collagenase. The acid-soluble form showed after rotary shadowing strands mainly of a length of 320 nm which terminated in a globule, or two strands connected by a similar globule. The globule was identified as a non-collagenous domain (NC1) which under dissociating conditions could be separated into two peptides showing a monomer-dimer relationship. Higher aggregates of NC1 were visualized under non-dissociating conditions. Some of the acid-extracted molecules have retained the previously 7-S collagen domain. The pepsin-solubilized form lacked domain NC1 and consisted mainly of four triple-helical strands (length 356 nm) joined together at the 7-S domain (length 30 nm). Common to both forms of type IV collagen was a small collagenase-resistant domain NC2 which was composed of collagenous and non-collagenous elements and located between the 7-S domain and the major triple helix. These data indicate that the collagenous matrix of basement membranes consists of a regular network of type IV collagen molecules which is generated by two different interacting sites located at opposite ends of each molecule. The 7-S collagen domain connects four molecules while the NC1 domain connects two molecules. The maximal distance between identical cross-linking sites (7-S or NC1) was estimated to be about 800 nm comprising the length of two molecules.     

Identification of the Goodpasture antigen as the alpha 3(IV) chain of collagen IV

The organizational relationship between the recently identified alpha 3 chain of basement membrane collagen (Butkowski, R.J., Langeveld, J.P.M., Wieslander, J., Hamilton, J., and Hudson, B.G. (1987) J. Biol. Chem. 262, 7874-7877) and collagen IV was determined. This was accomplished by the identification of subunits in hexamers of the NC1 domain of collagen IV that were immunoprecipitated with antibodies prepared against subunits M1, corresponding to alpha 1(IV)NC1 and alpha 2(IV)NC1, and M2, corresponding to alpha 3NC1, and by amino acid sequence analysis. The presence of at least two distinct types of hexamers was revealed, one enriched in M1 and the other enriched in M2, but in both types, M1 and M2 coexist. Evidence was also obtained for the existence of heterodimers comprised of M1 and M2. These results indicate that M2 is an integral component of the NC1 hexamer of collagen IV. The amino acid sequence of the NH2-terminal region of M2 was found to be highly related to the collagenous-NC1 junctional region of the alpha 1 chain of collagen IV. Therefore, M2 is designated alpha 3(IV)NC1 and its parent chain alpha 3(IV). These findings lead to a new concept about the structure of collagen IV: namely, 1) collagen IV is comprised of a third chain (alpha 3) together with the two classical ones (alpha 1 and alpha 2); the alpha 3(IV) chain exists within the same triple-helical molecule together with the alpha 1(IV) and alpha 2(IV) chains and/or within a separate triple-helical molecule, exclusive of alpha 1(IV) and alpha 2(IV) chains, but connected through the NC1 domains to the classical triple-helical molecule comprised of alpha 1(IV) and alpha 2(IV) chains. Additionally, a portion of those triple-helical molecules exclusive of alpha 1(IV) and alpha 2(IV) chains may be connected to each other through their NC1 domains; and 3) the epitope to which the major reactivity of autoantibodies are targeted in glomerular basement membrane in patients with Goodpasture syndrome is localized to the NC1 domain of the alpha 3(IV) chain.     

The molecular defect in an autosomal dominant form of osteogenesis imperfecta. Synthesis of type I procollagen containing cysteine in the triple-helical domain of pro-alpha 1(I) chains

Synthesis of procollagen was examined in skin fibroblasts from a patient with a moderately severe autosomal dominant form of osteogenesis imperfecta. Proteolytic removal of the propeptide regions of newly synthesized procollagen, followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under nonreducing conditions, revealed the presence of type I collagen in which two alpha 1(I) chains were linked through interchain disulfide bonds. Fragmentation of the disulfide-bonded alpha 1(I) dimers with vertebrate collagenase and cyanogen bromide demonstrated the presence of a cysteine residue in alpha 1(I)CB8, a fragment containing amino acid residues 124-402 of the alpha 1(I) collagen chain. Cysteine residues are not normally found in the triple-helical domain of type I collagen chains. The heterozygous nature of the molecular defect resulted in the formation of three kinds of type I trimers: a normal type with normal pro-alpha(I) chains, a type I trimer with one mutant pro-alpha 1(I) chain and two normal chains, and a type I trimer containing two mutant pro-alpha 1(I) chains and one normal pro-alpha 2(I) chain. The presence of one or two mutant pro-alpha 1(I) chains in trimers of type I procollagen was found to reduce the thermal stability of the protein by 2.5 and 1 degree C, respectively. In addition to post-translational overmodification, procollagen containing one mutant pro-alpha 1(I) chain was also cleared more slowly from cultured fibroblasts. The most likely explanation for these disruptive changes in the physical stability and secretion of the mutant procollagen is that a cysteine residue is substituted for a glycine in half of the pro-alpha 1(I) chains synthesized by the patient's fibroblasts.     

Biosynthetic processing of the Pro-alpha1(V)Pro-alpha2(V)Pro-alpha3(V) procollagen heterotrimer

Type V collagen is a quantitatively minor fibrillar collagen comprised of different chain compositions in different tissues. The most widely distributed form, an alpha1(V)2alpha2(V) heterotrimer, regulates the physical properties of type I/V heterotypic collagen fibrils via partially processed NH2-terminal globular sequences. A less characterized alpha1(V)alpha2(V)alpha3(V) heterotrimer has a much more limited distribution of expression and unknown function(s). We characterized the biosynthetic processing of pro-alpha1(V)2pro-alpha2(V) procollagen previously and showed it to differ in important ways from biosynthetic processing of the major fibrillar procollagens I-III. Here we have successfully produced recombinant pro-alpha1(V)pro-alpha2(V)pro-alpha3(V) heterotrimers. We use these, and mouse embryo fibroblasts doubly homozygous null for the Bmp1 gene, which encodes the metalloproteinase bone morphogenetic protein-1 (BMP-1), and for a gene encoding the closely related metalloproteinase mammalian Tolloid-like 1, to characterize biosynthetic processing of pro-alpha1(V)pro-alpha2(V)pro-alpha3(V) heterotrimers, thus completing characterization of type V collagen biosynthetic processing. Whereas pro-alpha1(V) and pro-alpha2(V) processing in pro-alpha1(V)pro-alpha2(V)pro-alpha3(V) heterotrimers is similar to that which occurs in pro-alpha1(V)2pro-alpha2(V) heterotrimers, the processing of pro-alpha3(V) by BMP-1 occurs at an unexpected site within NH2-terminal globular sequences. We also demonstrate that, despite similarities in NH2-terminal domain structures, pro-alpha2(V) NH2-terminal globular sequences are not cleaved by ADAMTS-2, the metalloproteinase that cleaves the N-propeptides of the major fibrillar procollagen chains.     

Exon/intron structure of the human alpha 3(IV) gene encompassing the Goodpasture antigen (alpha 3(IV)NC1). Identification of a potentially antigenic region at the triple helix/NC1 domain junction.

The Goodpasture antigen has been identified as the non-collagenous (NC1) domain of alpha 3(IV), a novel collagen IV chain (Saus, J., Wieslander, J., Langeveld, J., Quinones, S., and Hudson, B.G. (1988) J. Biol. Chem. 263, 13374-13380). In the present study, the exon/intron structure and sequence for 285 amino acids of human alpha 3(IV), comprising 53 amino acids of the triple-helical domain and the complete NC1 domain (232 amino acids), were determined. Based on the comparison of the amino acid sequences of the alpha 1(IV), alpha 2(IV), alpha 3(IV), and alpha 5(IV) NC1 domains, a phylogenetic tree was constructed which indicates that alpha 2(IV) was the first chain to evolve, followed by alpha 3(IV), and then by alpha 1(IV) and alpha 5(IV). The exon/intron structure of these domains is consistent with this evolution model. In addition, it appears that alpha 3(IV) changed most after diverging from the parental gene. Analysis of its primary structure reveals that, at the junction between the triple-helical and NC1 domains, there exists a previously unrecognized, highly hydrophilic region (GLKGKRGDSGSPATWTTR) which is unique to the human alpha 3(IV) chain, containing a cell adhesion motif (RGD) as an integral part of a sequence (KRGDSGSP) conforming to a number of protein kinase recognition sites. Based on primary structure data, we outline new aspects to be explored concerning the molecular basis of collagen IV function and Goodpasture syndrome.     

Pro-alpha 1(XI) collagen. Structure of the amino-terminal propeptide and expression of the gene in tumor cell lines.

We have determined the nucleotide sequence of several overlapping cDNA clones encoding the amino-terminal portion of human alpha 1(XI) procollagen. These experiments have revealed that this domain of the pro-alpha(XI) chain displays structural features common to other fibrillar procollagen molecules, such as a putative amino-terminal proteinase cleavage site and an interrupted collagenous segment. In the latter, structural similarities were noted when alpha 1(XI) was compared with alpha 1(II) and alpha 2(V) procollagens. Overall, however, the amino-terminal region of pro-alpha 1(XI) differs greatly in composition and size from that of other fibrillar chains. Nearly three-fourths of this domain is in fact composed of a 383-amino acid globular region in which a 3-cysteine cluster signals the transition to a long and highly acidic carboxyl-terminal segment. Finally, the unrestricted expression of this cartilage-specific collagen gene has been confirmed by the finding of high levels of pro-alpha 1(XI) mRNA in two human rhabdomyosarcoma cell lines.     

The carboxyl terminus of type VII collagen mediates antiparallel dimer formation and constitutes a new antigenic epitope for epidermolysis Bullosa acquisita autoantibodies

Type VII collagen, the major component of anchoring fibrils, consists of a central collagenous triple-helical domain flanked by two noncollagenous domains, NC1 and NC2. The NC2 domain has been implicated in catalyzing the antiparallel dimer formation of type VII procollagen. In this study, we produced the entire 161 amino acids of the NC2 domain plus 186 amino acids of adjacent collagenous domain (NC2/COL) and purified large quantities of the recombinant NC2/COL protein. Recombinant NC2/COL readily formed disulfide-bonded hexamers, each representing one antiparallel dimer of collagen VII. Removal of the collagenous helical domain from NC2/COL by collagenase digestion abolished the antiparallel dimer formation. Using site-directed mutagenesis, we found that mutation of either cysteine 2802 or cysteine 2804 alone within the NC2 domain blocked antiparallel dimer formation. In contrast, a single cysteine mutation, 2634, within the collagenous helical domain had no effect. A generated methionine to lysine substitution, M2798K, that is associated with recessive dystrophic epidermolysis bullosa, was unable to form antiparallel dimers. Furthermore, autoantibodies from epidermolysis bullosa acquisita patients also reacted with NC2/COL. We conclude that NC2 and its adjacent collagenous segment mediate antiparallel dimer formation of collagen VII. Epidermolysis bullosa acquisita autoantibodies bound to this domain may destabilize anchoring fibrils by interfering with antiparallel dimer assembly leading to epidermal-dermal disadherence.     

The binding of heparin to type IV collagen: domain specificity with identification of peptide sequences from the alpha 1(IV) and alpha 2(IV) which preferentially bind heparin

Three distinctive heparin-binding sites were observed in type IV collagen by the use of rotary shadowing: in the NC1 domain and at distances 100 and 300 nm from the NC1 domain. Scatchard analysis indicated different affinities for these sites. Electron microscopic analysis of heparin-type IV collagen interaction with increasing salt concentrations showed the different affinities to be NC1 greater than 100 nm greater than 300 nm. The NC1 domain bound specifically to chondroitin/dermatan sulfate side chains as well. This binding was observed at the electron microscope and in solid-phase binding assays (where chondroitin sulfate could compete for the binding of [3H]heparin to NC1-coated substrata). The triple helix-rich, rod-like domain of type IV collagen did not bind to chondroitin/dermatan sulfate side chains. In solid-phase binding assays only heparin could compete for the binding of [3H]heparin to this domain. In order to more precisely map potential heparin-binding sites in type IV collagen, we chemically synthesized 17 arginine- and lysine-containing peptides from the alpha 1(IV) and alpha 2(IV) chains. Three peptides from the known sequence of the alpha 1(IV) and alpha 2(IV) chains were shown to specifically bind heparin: peptide Hep-I (TAGSCLRKFSTM), from the alpha 1(NC1) chain, peptide Hep-II (LAGSCLARFSTM), a peptide corresponding to the same sequence in peptide Hep-I from the alpha 2 (NC1) chain, and peptide Hep-III (GEFYFDLRLKGDK) which contained an interruption of the triple helical sequence of the alpha 1(IV) chain at about 300 nm from the NC1 domain, were demonstrated to bind heparin in solid-phase binding assays and compete for the binding of [3H]heparin to type IV collagen-coated substrata. Therefore, each of these peptides may represent a potential heparin-binding site in type IV collagen. The mapping of the binding of heparin or related structures, such as heparan sulfate proteoglycan, to specific sequences of type IV collagen could help the understanding of several structural and functional properties of this basement membrane protein as well as interactions with other basement membrane and/or cell surface-associated macromolecules.     

A heterozygous defect for structurally altered pro-alpha 2 chain of type I procollagen in a mild variant of osteogenesis imperfecta. The altered structure decreases the thermal stability of procollagen and makes it resistant to procollagen N-proteinase

Cultured skin fibroblasts from a proband with an autosomal dominant variant of osteogenesis inperfecta were found to synthesize approximately equal amounts of normal pro-alpha 2(I) chains of type I procollagen and pro-alpha 2(I) chains which migrated more rapidly when examined by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. The structural alteration was present in alpha 2(I)-CB4, a cyanogen bromide fragment containing amino acid residues 7-327 of the alpha 2 chain, and it appeared to be a deletion of about 30 amino acids. The pro-alpha 2(I) chains with the apparent deletion associated with normal pro-alpha 1(I) chains synthesized by the same fibroblasts and formed triple-helical type I procollagen. The presence of the altered pro-alpha 2 chains in trimers of procollagen had two consequences in terms of the physical properties of the molecule. One was to decrease the thermal stability of the protein as judged by resistance to proteolysis at 37 degrees C and by the helix to coil transition as assayed by circular dichroism. The second consequence was to make type I procollagen containing the shortened pro-alpha 2(I) chains resistant to digestion by procollagen N-proteinase. The simplest explanation for the data is that the apparent deletion in half the pro-alpha 2(I) chains produced a partial unfolding of the N-terminal region of type I procollagen which prevented processing of the protein by procollagen N-proteinase.     

Sequence determination and analysis of the 3' region of chicken pro-alpha 1(I) and pro-alpha 2(I) collagen messenger ribonucleic acids including the carboxy-terminal propeptide sequences

Three pro-alpha 1 collagen cDNA clones, pCg1, pCg26, and pCg54, and two pro-alpha 2 collagen cDNA clones, pCg 13 and pCg45, were subjected to extensive DNA sequence determination. The combined sequences specified the amino acid sequences for chicken pro-alpha 1 and pro-alpha 2 type I collagens starting at residue 814 in the collagen triple-helical region and continuing to the procollagen C-termini as determined by the first in-phase termination codon. Thus, the sequences of 272 pro-alpha 1 C-terminal, 260 pro-alpha 2 C-terminal, 201 pro-alpha 1 helical, and 201 pro-alpha 2 helical amino acids were established. In addition, the sequences of several hundred nucleotides corresponding to noncoding regions of both procollagen mRNAs were determined. In total, 1589 pro-alpha 1 base pairs and 1691 pro-alpha 2 base pairs were sequenced, corresponding to approximately one-third of the total length of each mRNA. Both procollagen mRNA sequences have a high G+C content. The pro-alpha 1 mRNA is 75% G+C in the helical coding region sequenced and 61% G&C in the C-terminal coding region while the pro-alpha 2 mRNA is 60% and 48% G+C, respectively, in these regions. The dinucleotide sequence pCG occurs at a higher frequence in both sequences than is normally found in vertebrate DNAs and is approximately 5 times more frequent in the pro-alpha 1 sequence than in the pro-alpha 2 sequence. Nucleotide homology in the helical coding regions is very limited given that these sequences code for the repeating Gly-X-Y tripeptide in a region where X and Y residues are 50% conserved. These differences are clearly reflected in the preferred codon usages of the two mRNAs.     

Identification and partial characterization of two type XII-like collagen molecules

We have identified two distinct collagenous macromolecules in extracts of fetal bovine skin. Each of the molecules appears to contain three identical alpha-chains with short triple-helical domains of approximately 25 kD, and nontriple-helical domains of approximately 190 kD. Consistent with these observations, extracted molecules contain a relatively short triple-helical domain (75 nm) and a large globular domain comprised of three similar arms. Despite these similarities, the purified collagenase-resistant domains are distinguished by a number of criteria. The globular domains can be chromatographically separated on the basis of charge distribution. Peptide profiles generated by V8 protease digestion are dissimilar. These molecules are immunologically unique and have distinct distributions in tissue. Finally, rotary shadow analysis of purified domains identifies size and conformation differences. Structurally, the molecules are very similar to type XII collagen, but differ in tissue distribution, since both these molecules are present in cartilage, while type XII is reported to be absent from that tissue.     

Ehlers-Danlos syndrome type IV: a multi-exon deletion in one of the two COL3A1 alleles affecting structure, stability, and processing of type III procollagen

We have studied a patient with severe, dominantly inherited Ehlers-Danlos syndrome type IV. The results indicate that this patient carries a deletion of 3.3 kilo-base pairs in the triple helical coding domain of one of the two alleles for the pro-alpha-chains of type III collagen (COL3A1). His cultured skin fibroblasts contain equal amounts of normal length mRNA and of mRNA shortened by approximately 600 bases, and synthesize both normal and shortened pro-alpha 1(III)-chains. In procollagen molecules containing one or more shortened chains, a triple helix is formed with a length of only about 780 amino acids. The mutant procollagen molecules have decreased thermal stability, are less efficiently secreted, and are not processed as their normal counterpart. The deletion in this family is the first mutation to be described in COL3A1.