Amino acid sequence of the triple-helical domain of human collagen type VI

The complete amino acid sequence of the triple-helical domain of human collagen VI was deduced from sequences of appropriate cDNA clones and confirmed to about 50% by Edman degradation of tryptic peptides. This domain consists of three different peptide segments containing some 335-336 amino acid residues originating from central portions of the alpha 1 (VI), alpha 2(VI), and alpha 3(VI) chains, respectively. Sequence identity in the X/Y positions of the Gly-X-Y repeats is rather low (10-15%) between the chains. Peculiar features of these sequences include 3 cysteine residues about 50 (alpha 3(VI)) and 89 (alpha 1(VI), alpha 2(VI)) residues away from the N-terminus and several Gly-X-Y interruptions clustered in the C-terminal two-thirds of the triple helix. These structures are presumably required for cross-linking collagen VI oligomers and for super-coiling of triple helices in the dimers. Other features include 11 Arg-Gly-Asp sequences, some of which are likely to be used as cell-binding sites, and four Asn-X-Thr sequences, allowing N-linked glycosylation along the triple helix. Junctional areas close to the helix contain short, cysteine-rich segments which may seal the triple-helical domain through disulfide bond formation, endowing it with high stability. These features, together with a low sequence homology to fiber-forming and basement-membrane collagens, document the unique character of collagen VI, whose triple helix is specifically adjusted for forming microfibrils in tissues.     

Towards understanding the glycoprotein hormone receptors.

Lutropin (LH), follitropin (FSH) and thyrotropin (TSH), as well as choriogonadotropin (CG, which binds to the LH receptor) constitute the glycoprotein hormone family. Their 3 receptors have been cloned during the last few months. They belong to the large group of G-protein coupled membrane proteins, with their specific N-terminal domain likely to bind the hormone and the characteristic 7 membrane-spanning segments in their C-terminal moiety. The present review discusses the main results of amino acid sequence analysis performed on the glycoprotein hormone receptors. The putative extracellular head exhibits less than 45% homology over the 3 receptors, while approximately 70% residue conservation is found in the transmembrane moiety. Here only, limited sequence homologies (approximately 20%) can be found with other G-protein coupled receptors. The secondary structure predictions performed on the 3 receptors revealed that the polypeptide sequence predicted as ordered (either alpha-helix or beta-strand) were repeated evenly throughout the extracellular head with a period of approximately 25 amino acids. This analysis helped to define the intervening loops between this ordered stretches as potential candidates for bearing at least part of the binding site of the hormones. Some of the perspectives opened by the cloning of the receptors are described, like the production of the extracellular head of the porcine LH receptor in baculovirus-infected insect cells, and the exploration of the LH receptor's mechanism of functioning as a dimer.     

Analysis of Mutations in the Sqt-1 and Rol-6 Collagen Genes of Caenorhabditis Elegans

Different mutations in the sqt-1 and rol-6 collagen genes of Caenorhabditis elegans can cause diverse changes in body morphology and display different genetic attributes. We have determined the nucleotide alterations in 15 mutant alleles of these genes. Three mutations in sqt-1 and one in rol-6 that cause dominant right-handed helical twisting (RRol) of animals are arginine to cysteine replacements. These mutations are all within a short conserved sequence, on the amino terminal side of the Gly-X-Y repeats, that is found in all C. elegans cuticle collagens. A recessive RRol mutation of rol-6 is a replacement of one of the same conserved arginines by histidine. In contrast, three sqt-1 mutations that cause recessive left-handed helical twisting (LRol) are replacements of a conserved carboxyterminal cysteine residue with either tyrosine or serine. These results suggest that disulfide bonding is important in collagen organization and that a deficit or surplus of disulfides may cause cuticle alterations of opposite handedness. In contrast to other collagens, glycine replacement mutations in the Gly-X-Y repeats of sqt-1 cause very mild phenotypes. Nonsense mutations of both sqt-1 and rol-6 cause nearly, but not totally, wild-type phenotypes. A nonsense mutation in sqt-1 suppresses the phenotype of rol-6 RRol mutations, suggesting that rol-6 collagen function is dependent on the presence of sqt-1 collagen. Mutations of sqt-1 are not suppressed by a rol-6 nonsense mutation, however, indicating that sqt-1 collagen can function independently of rol-6.     

Laminin, a multidomain protein. The A chain has a unique globular domain and homology with the basement membrane proteoglycan and the laminin B chains

Laminin (Mr = 800,000) is a glycoprotein consisting of three chains, A, B1, and B2, and has diverse biological activities. Previously we reported the complete primary structure of the B1 and B2 chains of mouse laminin deduced from cDNA sequence (Sasaki, M., Kohno, K., Kato, S., Martin, G. R., and Yamada, Y. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 935-939; Sasaki, M., and Yamada, Y. (1988) J. Biol. Chem. 262, 17111-17117). Here we describe the isolation, characterization, and sequence of cDNA clones spanning 9,520 bases which encode the entire A chain of mouse laminin. The nucleotide sequence of the clones contains an open reading frame of 3,084 amino acids including 24 amino acids of a signal peptide. The A chain contains some eight distinct domains including alpha-helices, cysteine-rich repeats and globules. There is considerable sequence and structural homology between the A chain and the B1 and B2 chains. However, the A chain has a unique globular structure containing homologous repeats at the carboxyl terminus and constituting one third of the molecular mass of the chain. Furthermore, the A chain contains three globules and three cysteine-rich domains at the amino terminus, whereas the B1 and B2 chains have only two each of such domains. The A chain shows homology to the basement membrane heparan sulfate proteoglycan core protein and the extracellular domain of the Drosophila neurogenic protein Notch. There is an RGD (Arg-Gly-Asp) sequence in one of the cysteine-rich domains of the A chain. This potential cell binding sequence could be active as another adhesion signal in addition to the previously identified cell binding sequence YIGSR (Tyr-Ile-Gly-Ser-Arg) of the B1 chain.     

The globular domains of type VI collagen are related to the collagen-binding domains of cartilage matrix protein and von Willebrand factor.

Type VI collagen is a transformation-sensitive glycoprotein of the extracellular matrix of fibroblasts. We have isolated and sequenced several overlapping cDNA clones (4153 bp) which encode the entire alpha 2 subunit of chicken type VI collagen. The deduced amino acid sequence predicts that the alpha 2(VI) polypeptide consists of 1015 amino acid residues that are arranged in four domains: a hydrophobic signal peptide of 20 residues, an amino-terminal globular domain of 228 residues, a collagenous segment of 335 residues and a carboxy-terminal globular domain of 432 residues. The collagenous domain contains seven Arg-Gly-Asp tripeptide units, some of which are likely to be used as cell-binding sites. The globular domains contain three homologous repeats with an average length of 180 amino acid residues. These repeats show a striking similarity to the collagen-binding motifs found in von Willebrand factor and cartilage matrix protein. We therefore speculate that the globular domains of the alpha 2(VI) polypeptide may interact with collagenous structures.     

Appearance and distribution of collagens and laminin in the early mouse embryo

Appearance and distribution of the different collagen types and the noncollagenous glycoprotein laminin was studied during early mouse development from unfertilized ova to 8-day embryos using indirect immunofluorescence techniques. Laminin was first detected intracellularly in the 16-cell compacted morula and appeared also intercellularly along cell contours. Type IV collagen was first seen in the blastocyst mainly in the inner cell mass. After implantation intense fluorescence for both of these proteins was found in all the embryonic and extraembryonic basement membranes. The interstitial collagens type I and III were first detected in the 8-day embryo closely codistributed in tissues of mesodermal origin including the head and heart mesenchymes and in basement membranes bounded by mesodermal structures. The results establish a developmental sequence for the appearance of basement membrane and extracellular matrix glycoproteins in early mouse development. The distribution of laminin suggests the presence of extracellular matrix material already in compacted morulae. The appearance of type IV collagen coincides with differentiation of the primitive endoderm and assembly of the first embryonal basement membrane. The appearance of the interstitial collagens during mesoderm differentiation indicates a stage when mesoderm acquires connective tissue characteristics.     

Mammalian collagen receptors.

Collagen-rich extracellular matrices are abundant and ubiquitous in the mammalian body. Collagens are not only essential for the mechanical stability of tissues, but are also intimately involved in controlling cell behaviour. The hallmark of collagens is a triple helix made up of polypeptide chains containing glycine-X-Y repeats. A structurally and functionally diverse group of cell surface receptors mediates the recognition of triple-helical collagen: integrins, discoidin domain receptors, glycoprotein VI, leukocyte-associated IG-like receptor-1, and members of the mannose receptor family. In this review, we discuss the structure and function of these receptors, focussing on the principles involved in collagen recognition.     

The complete primary structure of type XII collagen shows a chimeric molecule with reiterated fibronectin type III motifs, von Willebrand factor A motifs, a domain homologous to a noncollagenous region of type IX collagen, and short collagenous domains with an Arg-Gly-Asp site

Extracellular matrix molecules are generally categorized as collagens, elastin, proteoglycans, or other noncollagenous structural/cell interaction proteins. Many of these extracellular proteins contain distinctive repetitive modules, which can sometimes be found in other proteins. We describe the complete primary structure of an alpha 1 chain of type XII collagen from chick embryonic fibroblasts. This large, structurally chimeric molecule identified by cDNA analysis combines previously unrelated molecular domains into a single large protein 3,124 residues long (approximately 340 kD). The deduced chicken type XII collagen sequence starts at the amino terminus with one unit of the type III motif of fibronectin, which is followed by one unit homologous to the von Willebrand factor A domain, then one more fibronectin type III module, a second A domain from von Willebrand factor, 6 units of type III motif and a third A domain, 10 consecutive units of type III motif and a fourth A domain, a domain homologous to the NC4 domain peptide of type IX collagen, and finally two short collagenous regions previously described as part of the partially sequenced collagen type XII molecule; an Arg-Gly-Asp potential cell adhesive recognition sequence is present in a hydrophilic region at the terminus of one collagenous domain. Antibodies raised to type XII collagen synthesized in a bacterial expression system recognized not only previously reported bands (220 kD et cetera) in tendons, but also bands with apparently different molecular sizes in fibroblasts and 4-d embryos. The antibodies stained a wide variety of extracellular matrices in embryos in patterns distinct from those of fibronectin or interstitial collagens. They prominently stained extracellular matrix associated with certain neuronal tissues, such as axons from dorsal root ganglia and neural tube. These studies identify a novel chimeric type of molecule that contains both adhesion molecule and collagen motifs in one protein. Its structure blurs current classification schemes for extracellular proteins and underscores the potentially large diversity possible in these molecules.     

Molecular characterization of cuticle and interstitial collagens from worms collected at deep sea hydrothermal vents

Two different collagens were isolated and characterized from the body walls of the vestimentiferan tube worm Riftia pachyptila and the annelid Alvinella pompejana, both living around hydrothermal vents at a depth of 2600 m. The acid-soluble cuticle collagens consisted of a long triple helix (2.4 microns for Alvinella, 1.5 microns for Riftia) terminating into a globular domain. Molecular masses of 2600 and 1700 kDa, respectively, were estimated from their dimensions. The two cuticle collagens were also quite different in amino acid composition, in agreement with their different supramolecular organizations within tissues. Interstitial collagens corresponding to cross-striated fibrils underneath the epidermal cells could be solubilized by digestion with pepsin and consisted of a single alpha-chain. They were similar in molecular mass (340 kDa) and length (280 nm) but differed in composition and banding patterns of segment-long-spacing fibrils. This implicates significant sequence differences also in comparison to fibril-forming vertebrate collagens, although all form typical quarter-staggered fibrils. The thermal stability of the worm collagens was, with one exception (interstitial collagen of Riftia), in the range of mammalian and bird collagens (37 to 46 degrees C), and thus distinctly above that of shallow sea water annelids. Yet, their 4-hydroxyproline contents were not directly correlated to this stability. About 20% of Riftia collagen alpha-chain sequence was elucidated by Edman degradation and showed typical Gly-X-Y repeats but only a limited homology (45 to 58% identity) to fibril-forming vertebrate collagens. A single triplet imperfection and the variable hydroxylation of proline in the X position were additional unique features. It suggests that this collagen represents an ancestral form of fibril-forming collagens not directly corresponding to an individual fibril-forming collagen type of vertebrates.     

Synergism between membrane gangliosides and Arg-Gly-Asp-directed glycoprotein receptors in attachment to matrix proteins by melanoma cells

The identification of specific cell surface glycoprotein receptors for Arg-Gly-Asp-containing extracellular matrix proteins such as fibronectin has focused attention on the role of gangliosides in this process. Is their involvement dependent or independent of the protein receptors? In attachment assays with cells from a human melanoma cell line, titration experiments with an antibody (Mel 3) with specificity for the disialogangliosides GD2 and GD3, used together with a synthetic peptide containing the cell binding sequence Arg-Gly-Asp, show that their joint effect is synergistic. Both the Mel 3 antibody and the synthetic peptide individually cause rapid detachment of melanoma cells from fibronectin substrate but, when used together, much smaller concentrations of both are required to achieve the same effect. The Mel 3 antibody was not nonspecifically reducing receptor binding to the Arg- Gly-Asp sequence since, in binding assays with radiolabeled peptide performed with cells in suspension, very little peptide is bound by the melanoma cells under these conditions but addition of Mel 3, an antibody of IgM isotype, causes a two- to threefold increase in specific binding. The simplest interpretation of these data is that the Mel 3 antibody is causing sufficient clustering of membrane gangliosides in local areas and producing a favorably charged environment to facilitate peptide binding by specific glycoprotein receptors.     

Molecular analysis of mutations in the Caenorhabditis elegans collagen gene dpy-7.

Collagens are a family of proteins contributing to the body structure of eukaryotes. They are encoded by a large and diverse gene family in the nematode Caenorhabditis elegans but by only a few genes in vertebrates. We have studied mutant alleles of the C. elegans dpy-7 gene, one of a large group of genes whose mutant phenotype is altered body form and several of which have previously been shown to encode cuticular collagens. We made use of the C. elegans physical map to screen specifically for collagen genes in the region of the X chromosome to which dpy-7 maps. This yielded a wild-type collagen gene clone which we showed, by micro-injection, could repair the dpy-7 mutant phenotype in transgenic animals. We cloned the homologous sequence from four dpy-7 mutant strains and by sequence analysis identified a single mutation in each case. All four mutations result in the substitution of a glycine with a larger residue in the conserved Gly-X-Y collagen domains. Similar substitutions in vertebrate collagens cause the heritable brittle bone disorder osteogenesis imperfecta. Whereas the human mutations are dominant, the dpy-7 mutations are recessive, and this may reflect different levels of complexity of collagenous macromolecular structures in the two organisms.     

Collagens support embryo attachment and outgrowth in vitro: effects of the Arg-Gly-Asp sequence

Collagen types I through VI support attachment and outgrowth of mouse blastocysts in vitro. We found that embryos acquire the ability to attach to collagens type II and VI relatively early in their developmental program. The time at which half of the embryos displayed outgrowth formation and the morphology of outgrowths formed on these two collagen types are similar to those observed for laminin, fibronectin, and hyaluronate. Embryos acquire the ability to outgrow on the other collagen types at a later time in culture. Both "native" and denatured collagens support embryo attachment and outgrowth, indicating that this activity is intrinsic to the primary collagens' structure. A synthetic peptide containing the sequence Arg-Gly-Asp inhibits embryo outgrowth on collagen type II and denatured collagen type IV, whereas a peptide containing the related sequence, Arg-Gly-Glu, has relatively little effect on embryo outgrowth. In contrast, embryo attachment to collagen types I, V, and VI was not inhibited specifically by the Arg-Gly-Asp peptide sequence. Consequently, it appears that embryos use multiple adhesion systems to attach to collagens. Among these are adhesion systems that have a peptide recognition specificity similar to that of fibronectin receptors. These studies indicate that embryo interactions with collagens may be one aspect of the tissue invasion processes that take place during implantation.     

The structure of the Cys-rich terminal domain of Hydra minicollagen, which is involved in disulfide networks of the nematocyst wall

The minicollagens found in the nematocysts of Hydra constitute a family of invertebrate collagens with unusual properties. They share a common modular architecture with a central collagen sequence ranging from 14 to 16 Gly-X-Y repeats flanked by polyproline/hydroxyproline stretches and short terminal domains that show a conserved cysteine pattern (CXXXCXXXCXXX-CXXXCC). The minicollagen cysteine-rich domains are believed to function in a switch of the disulfide connectivity from intra- to intermolecular bonds during maturation of the capsule wall. The solution structure of the C-terminal fragment including a minicollagen cysteine-rich domain of minicollagen-1 was determined in two independent groups by 1H NMR. The corresponding peptide comprising the last 24 residues of the molecule was produced synthetically and refolded by oxidation under low protein concentrations. Both presented structures are identical in their fold and disulfide connections (Cys2-Cys18, Cys6-Cys14, and Cys10-Cys19) revealing a robust structural motif that is supposed to serve as the polymerization module of the nematocyst capsule.     

Detecting distant homologies of mosaic proteins. Analysis of the sequences of thrombomodulin, thrombospondin complement components C9, C8 alpha and C8 beta, vitronectin and plasma cell membrane glycoprotein PC-1

Recognition of homologies may give hints about the structure and function of proteins; therefore, we are developing strategies to aid sequence comparisons. Detecting homology of mosaic proteins is especially difficult since the modules constituting these proteins are usually distantly related and their homology is not readily recognized by conventional computer programs. In the present work we show that the rules of the evolution of mosaic proteins can guide the identification of modules of mosaic proteins and can delineate the group of sequences in which the presence of homologous sequences may be expected. By this approach we can concentrate the search for homology to a limited group of sequences; thus ensuring a more intense and more fruitful search. The power of this approach is illustrated by the fact that it could detect homologies not identified by earlier methods of sequence comparison. In this paper we show that thrombomodulin contains a domain homologous with animal lectins, that complement components C9, C8 alpha and C8 beta have modules homologous with one of the repeat units of thrombospondin and that the somatomedin B module of vitronectin is homologous with the internal repeats of plasma cell membrane glycoprotein PC-1.     

The modular architecture of vertebrate collagens.

Collagens are typical mosaic proteins containing a number of shuffled domains. These domains have been classified by sequence similarity in order to characterize their structural and functional relationships to other proteins. This analysis provides an overview of homologies of collagen domains. It also reveals two new relationships: (i) a module common to type V, IX, XI, and XII collagens was found to be homologous to the heparin binding domain of thrombospondin; (ii) the modular architecture of a human type VII collagen fragment was identified. Its N-terminal globular domain contains fibronectin type III repeats located adjacent to a Von Willebrand factor type A module. The proposed structural similarities point to analogous subfunctions of the respective domains in otherwise distinct proteins.     

Primary structure of bovine conglutinin, a member of the C-type animal lectin family

We report the complete amino acid sequence of bovine conglutinin obtained by structural characterization of peptides derived from the protein by various chemical and enzymatic fragmentation methods. The protein consists of 351 amino acid residues including 55 apparent Gly-X-Y repeats with two interruptions. This 171-residue-long collagenous domain separates a short noncollagenous NH2-terminal region of 25 residues from the 155-residue-long globular COOH terminus revealing the structural relation of conglutinin with mannose-binding proteins, pulmonary surfactant-associated proteins, and a complement component C1q. Eight hydroxylysine residues were found in the collagenous domain. All of these hydroxylysine residues which occupy a Y position in a Gly-X-Y triplet are possible glycosylation sites since no phenylthiohydantoin amino acid was identified in automated Edman degradation cycles corresponding to these sites. The noncollagenous COOH domain of conglutinin, on the other hand, contains a carbohydrate recognition domain which shares substantial sequence homology with C-type animal lectins. Conglutinin has the greatest sequence similarity with mannose-binding proteins and pulmonary surfactant-associated proteins.     

Receptors for laminin on mammalian cells.

Early in development, cells produce an extracellular matrix that provides important cues that regulate gene expression, cell division, and morphogenesis. Interactions with the extracellular matrix are mediated by cell-surface receptors providing a transmembrane link between extracellular and intracellular compartments. Laminin, a large, multichain glycoprotein found in basement membranes, is involved in various biological activities, including promotion of cell adhesion, growth, migration, differentiation, neurite outgrowth, and tumor metastases. To date, several classes of binding proteins have been found to interact with laminin, including a high-affinity 67-kDa receptor, galactoside-binding lectins, galactosyltransferase, sulfatides, and integrins. This review will summarize our current understanding of some of these laminin-binding proteins, and where possible, integrate the biochemistry and cell biology of ligand and receptor expression.     

The collagen family members as cell adhesion proteins

The collagen family of extracellular matrix proteins has played a fundamental role in the evolution of multicellular animals. At the present, 28 triple helical proteins have been named as collagens and they can be divided into several subgroups based on their structural and functional properties. In tissues, the cells are anchored to collagenous structures. Often the interaction is indirect and mediated by matrix glycoproteins, but cells also express receptors, which have the ability to directly bind to the triple helical domains in collagens. Some receptors bind to sites that are abundant in all collagens. However, increasing evidence indicates that the coevolution of collagens and cell adhesion mechanisms has given rise to receptors that bind to specific motifs in collagens. These receptors may also recognize the different members of the large collagen family in a selective manner. This review summarizes the present knowledge about the properties of collagen subtypes as cell adhesion proteins.     

Molecular characterization of a new immunoglobulin superfamily protein with potential roles in opioid binding and cell contact.

A purified opioid-binding protein has been characterized by cDNA cloning. The cDNA sequence predicts an extracellularly located glycoprotein of 345 amino acids. This protein does not possess a membrane-spanning domain but contains a C-terminal hydrophobic sequence characteristic of membrane attachment by a phosphatidylinositol linkage. It displays homology to the immunoglobulin protein superfamily, featuring three domains that resemble disulfide-bonded constant regions. More specifically, the protein is most homologous to a subfamily of proteins which includes the neural cell adhesion molecule (NCAM) and myelin-associated glycoprotein (MAG) and one subgroup of the tyrosine kinase growth factor receptors comprising the platelet-derived growth factor receptor (PDGF R), the colony-stimulating factor 1 receptor (CSF-1 R) and the c-kit protooncogene. These sequence homologies suggest that the protein could be involved in either cell recognition and adhesion, peptidergic ligand binding or both.