The covalent structure of cartilage collagen. Amino acid sequence of the NH2-terminal helical portion of the alpha 1 (II) chain

Early cathepsin K degradation of type II collagen in vitro and in vivo in articular cartilage

OBJECTIVE

To characterize the initial events in the cleavage of type II collagen mediated by cathepsin K and demonstrate the presence of the resulting products in human and equine articular osteoarthritic cartilage.

DESIGN

Equine type II collagen was digested with cathepsin K and the cleavage products characterized by mass spectrometry. Anti-neoepitope antibodies were raised against the most N-terminal cleavage products and used to investigate the progress of collagen cleavage, in vitro, and the presence of cathepsin K-derived products in equine and human osteoarthritic cartilage.

RESULTS

Six cathepsin K cleavage sites distributed throughout the triple helical region were identified in equine type II collagen. Most of the cleavages occurred following a hydroxyproline residue. The most N-terminal site was within three residues of the previously identified site in bovine type II collagen. Western blotting using anti-neoepitope antibodies showed that the initial cleavages occurred at the N-terminal sites and this was followed by more extensive degradation resulting in products too small to be resolved by SDS gel electrophoresis. Immunohistochemical staining of cartilage sections from equine or human osteoarthritic joints showed staining in lesional areas which was not observed in non-arthritic sites.

CONCLUSIONS

Cathepsin K cleaves triple helical collagen by erosion from the N-terminus and with subsequent progressive cleavages. The liberated fragments can be detected in osteoarthritic cartilage and may represent useful biomarkers for disease activity.

LC-MS/MS identification of the O-glycosylation and hydroxylation of amino acid residues of collagen α-1 (II) chain from bovine cartilage

O-Glycosylation of collagen is a unique type of posttranslational modifications (PTMs) involving the attachment of galactose (Gal) or glucose-galactose (Glc-Gal) moieties to hydroxylysine (HyK). Also, hydroxyproline (HyP) result from the posttranslational hydroxylation of some proline residues in collagen. Here, LC-MS/MS was effectively employed to identify 23 O-glycosylation sites and a large number of HyP residues associated with bovine type II collagen α-1 chain (CO2A1). The modifications of the 23 O-glycosylation sites varied qualitatively and quantitatively. Both Gal and Glc-Gal moieties occupied 22 of the identified glycosylation sites, while K773 was observed as unmodified. A large number of HyP residues at Yaa positions of Gly-Xaa-Yaa motif were detected. HyP residues at Xaa positions of Gly-HyP-HyP, Gly-HyP-Ala, and Gly-HyP-Val motifs were also observed. Notably, HyP residue of Gly-HyP-Gln motif was detected, which has not been previously reported. Moreover, the deamidation of 8 Asn residues was identified, of which 2 Asp residues were observed at different retention times because of isomerization (Asp vs isoAsp). Partial macroheterogeneities of some CO2A1 glycosylation sites were revealed by LC-MS/MS analysis. ETD experiments revealed partial macroheterogeneities associated with K299-K308, K452-K464, K464-K470, and K857-K884 glycosylation sites. Semiquantitative data suggest that the glycosylation of hydroxylysine residues is site-specific.

Development of a novel method for analyzing collagen O-glycosylations by hydrazide chemistry

In recent years, glycopeptide purification by hydrazide chemistry has become popular in structural studies of glycoconjugates; however, applications of this method have been almost completely restricted to analysis of the N-glycoproteome. Here we report a novel method for analyzing O-glycosylations unique to collagen, which are attached to hydroxylysine and include galactosyl-hydroxylysine and glucosyl-galactosyl-hydroxylysine. We established a hydrazide chemistry-based glycopeptide purification method using (1) galactose oxidase to introduce an aldehyde into glycopeptides and (2) formic acid with heating to elute the bound glycopeptides by cleaving the hydrazone bond. This method allows not only identification of O-glycosylation sites in collagen but also concurrent discrimination of two types of carbohydrate substitutions. In bovine type I and type II collagens, galactosyl-hydroxylysine /glucosyl-galactosyl-hydroxylysine -containing peptides were specifically detected on subsequent comprehensive liquid chromatography (LC)/MS analysis, and many O-glycosylation sites, including unreported ones, were identified. The position of glycosylated hydroxylysine, which is determined by our unambiguous and simple method, could provide insight into the physiological role of the modifications.

Biochemical and immunological characterization of collagen molecules from echinothurioid sea urchin Asthenosoma ijimai

Collagens collected from the test (the external hard covering of invertebrates) of the sea urchin, Asthenosoma ijimai, were characterized biochemically and immunologically. The amino-acid composition was typical of that of mammalian collagens. Crystals of segment-long-spacing showed that the molecules of sea urchin collagen were 300 nm long. Selective salt precipitation revealed that the collagen has the same solubility characteristics as type I collagen. The collagen was denatured at 23.1 degrees C. Anti-sea urchin collagen antisera were immunologically cross-reacted with collagens of the same species and the starfish Asterina pectinifera. However, the antisera showed no or slight responses to collagens of bovine type I, II, III, IV and V. The collagen molecules contained four alpha-chains, named alpha 1(SU), alpha 2(SU), alpha 3(SU) and alpha 4(SU), respectively. All of the four alpha-chains were eluted in the same fraction on gel filtration chromatography. Chains of alpha 1(SU) and alpha 2(SU) were extracted earlier than alpha 3(SU) and alpha 4(SU) during pepsin digestion. Other biochemical and immunological analyses clearly demonstrated that test of sea urchins contains two genetically different, but biochemically similar, species of collagens, one of which is composed of alpha 1(SU) and alpha 2(SU) chains, and the other of alpha 3(SU) and alpha 4(SU).

Collagenous structures present in brain contain epitopes shared by collagen and microtubule-associated protein tau

A novel type of collagenous fibers has been isolated from human brain and characterized by electron microscopy and optical diffraction. It was found that the morphology of the fibers is similar, but not identical, to that of skin collagen. Also, the collagenous fibers show some similarities with the paracrystals that could be assembled in vitro from purified microtubule-associated protein tau. Immunological analyses indicated the presence of epitopes in these collagenous fibers which react with antibodies against collagen and tau.

Structure of cDNA clones coding for human type II procollagen. The alpha 1(II) chain is more similar to the alpha 1(I) chain than two other alpha chains of fibrillar collagens

Overlapping cDNA clones were isolated for human type II procollagen. Nucleotide sequencing of the clones provided over 2.5 kb of new coding sequences for the human pro alpha 1(II) gene and the first complete amino acid sequence of type II procollagen from any species. Comparison with published data for cDNA clones covering the entire lengths of the human type I and type III procollagens made it possible to compare in detail the coding sequences and primary structures of the three most abundant human fibrillar collagens. The results indicated that the marked preference in the third base codons for glycine, proline and alanine previously seen in other fibrillar collagens was maintained in type II procollagen. The domains of the pro alpha 1(II) chain are about the same size as the same domains of the pro alpha chains of type I and type III procollagens. However, the major triple-helical domain is 15 amino acid residues less than the triple-helical domain of type III procollagen. Comparison of hydropathy profiles indicated that the alpha chain domain of type II procollagen is more similar to the alpha chain domain of the pro alpha 1(I) chain than to the pro alpha 2(I) chain or the pro alpha 1(III) chain. The results therefore suggest that selective pressure in the evolution of the pro alpha 1(II) and pro alpha 1(I) genes is more similar than the selective pressure in the evolution of the pro alpha 2(I) and pro alpha 1(III) genes.

Covalent structure of collagen. Amino acid sequence of an arthritogenic cyanogen bromide peptide from type II collagen of bovine cartilage

Bovine articular type II collagen was prepared by limited pepsin digestion, differential salt fractionation and carboxymethylcellulose chromatography. Cyanogen bromide digestion of purified type II collagen alpha chains yielded twelve distinct peptides designated CB1-12. The peptide alpha 1(II)-CB11 was isolated by carboxymethylcellulose chromatography and Sephadex G-75S gel filtration. Automated Edman degradation together with chymotrypsin, thermolysin and trypsin digestion enabled identification of its complete amino acid sequence. Compared with type I and type III collagen, the data show similarity with alpha 1(I)-CB8 and alpha 1(III)-CB6-1-8-10-2 peptides, respectively. The peptide is located within residues 124-402 of the alpha 1(II) collagen chain and with its identification, now extends the known amino acid sequence of bovine type II cartilage collagen to 660 amino acid residues including alpha 1(II)-CB1-2-6-12-11-8-10 (partial). This corresponds to alpha 1(I)-CB0-1-2-4-5-8-3-7 (partial; 1-660) and alpha 1(III)-CB3A-3B-3C-7-6-1-8-10-2-4-5 (partial; 1-660) of bovine alpha 1(I) and alpha 1(III) collagen chains.

The structure of fibril-forming collagens

Although collagen molecules are designed primarily to serve as constituents of supporting aggregates in various tissues, they are present as a relatively large family of proteins that exhibit a wide diversity in structural and chemical features. Molecular diversity is, of course, specified primarily by the different genes for synthesis of the various collagen chains. However, intracellular post-translational modifications of the nascent chains as well as extracellular processing of newly assembled molecules contribute to, and considerably amplify, the diversity specified by the genome. Moreover, the nature of the aggregates derived from various molecular species of collagen reflects this diversity. In this fashion, a great deal of chemical and biological variation is created in otherwise highly similar molecules such as those classified here as belonging to group 1. It is anticipated that further developments regarding these and other molecular species of collagen will considerably refine our understanding of the spectrum of structure and function associated with this unique family of proteins.

A [3H]lysine-containing synthetic peptide substrate for human protocollagen lysyl hydroxylase

A tridecapeptide containing tritium-labelled lysine and corresponding closely to residues 98 to 110 of the alpha chain of type I collagen was synthesized by the solid-phase method. Gly-Leu-Hyp-Gly-Nle-[4,5-3H]Lys-Gly-His-Arg-Gly-Phe-Ser-Gly was used as a substrate of human protocollagen lysyl hydroxylase (peptidyllysine, 2-oxoglutarate: oxygen 5-oxidoreductase, EC 1.14.11.4) obtained from dermal fibroblasts. L-[4,5-3H]Lysine was converted to N alpha-t-butyloxycarbonyl-N epsilon-o-chlorobenzyloxycarbonyl [3H]lysine which was incorporated during stepwise synthesis of the peptide. The chemical and radiochemical purities and specific activity of the completed peptide were characterized. A non-radiolabelled analogue of the peptide inhibited the hydroxylation of [3H]lysine-containing protocollagen by human lysyl hydroxylase, indicating that the synthetic peptide interacted with the enzyme. The peptide containing [3H]lysine was a substrate for lysyl hydroxylase and permitted direct measurement of enzyme activity in relatively crude cell extracts by a tritium-release assay. Extracts of cultured fibroblasts from a patient with an autosomal recessive pattern of inheritance for Ehlers-Danlos syndrome type VI had activities for tritium release from either the radiolabelled synthetic peptide or from [3H]lysine-containing protocollagen that were only 30% of those from control cells. These data indicate that a stable, well-defined synthetic peptide containing [3H]lysine is a useful substrate for studies of genetically variant lysyl hydroxylase from cultured human cells.

The cell attachment determinant in fibronectin

Fibronectin possesses a domain that interacts with cell surfaces. The ability of fibronectin to promote cell attachment can be duplicated with a short amino acid sequence, glycyl-L-arginyl-glycyl-L-aspartyl-L-serine, taken from that domain. The tripeptide Arg-Gly-Asp appears to be irreplaceable for maintenance of the activity of this peptide, whereas the serine residue can be replaced with some, but apparently not all, possible residues. This recognition sequence, or a closely related sequence, is present in a number of proteins other than fibronectin that interact with cells. These proteins include collagens, fibrinogen, thrombin, a bacterial surface protein, and two viral proteins, as well as discoidin-I, a protein implicated in the aggregation of Dictyostelium discoideum. A similar sequence is also repeated in some, but not all, fibronectin molecules, making it possible that some fibronectin molecules have more than a single cell attachment site. Synthetic peptides constructed from sequences taken from several of these other proteins have also been shown to promote cell attachment. The tripeptide sequence may, therefore, constitute an ancient cellular recognition mechanism common to many proteins.

Variants of the cell recognition site of fibronectin that retain attachment-promoting activity

A tetrapeptide sequence, Arg-Gly-Asp-Ser, is the minimal structure recognized by cells in the large, adhesive glycoprotein fibronectin. We now have defined the structural requirements for this cell recognition site by testing several synthetic variants of the active tetrapeptide sequence. The conservative substitutions of lysine for arginine, alanine for glycine, or glutamic acid for aspartic acid each resulted in abrogation of the cell attachment-promoting activity characteristic of the natural sequence. However, in the position of the serine residue, some alterations were compatible with activity. Assay of peptides containing the structure Arg-Gly-Asp-X (where X = another amino acid residue) showed that an Arg-Gly-Asp-Val sequence predicted to be present in some, but not all, fibronectin molecules as a result of alternative RNA splicings could potentially create a second cell attachment site in those fibronectin polypeptide chains carrying that sequence. Other proteins with potentially active Arg-Gly-Asp-X sequences include several proteins that are known to interact with the cell surface. Among these are various types of collagens, thrombin, and discoidin, a slime-mold protein that may be involved in cell aggregation. The result presented here show that the arginine, glycine, and aspartic acid residues are absolutely required for the cell recognition, and that the surrounding amino acids may play a role in the expression of cell attachment activity in fibronectin and other proteins having this sequence. We suggest, based on these data, that this recognition mechanism may be common to a number of biological systems.

Different levels of glycosylation contribute to the heterogeneity of alpha 1(II) collagen chains derived from a transplantable rat chondrosarcoma

Three collagen fractions, each of which contain molecules composed of alpha 1(II) chains, have been isolated from pepsin-solubilized rat chondrosarcoma collagen. One fraction could be selectively precipitated from the pepsin digest at 0.7 M NaCl. Two additional fractions were obtained on chromatography of the collagen precipitating at 1.2 M NaCl on carboxymethyl cellulose under nondenaturing conditions. When chromatographed on carboxymethyl cellulose under denaturing conditions, each fraction contained components eluting in the position expected for alpha 1(II) chains. One of the fractions precipitating at 1.2 M NaCl contained the recently described 1 alpha and 2 alpha chains in addition to material eluting as alpha 1(II) chains. Comparison of the chains eluting as alpha 1(II) chains in the various fractions with respect to amino acid composition, carbohydrate content, and cyanogen bromide-cleavage products showed that they differed only in the number of glycosylated hydroxylysyl residues. In this regard, alpha 1(II) chains obtained from collagens precipitated at 1.2 M NaCl exhibited significantly higher levels of glucosylgalactosylhydroxylysyl residues than alpha 1(II) chains precipitated at 0.7 M NaCl. These results indicate that molecules composed of alpha 1(II) chains are heterogeneous with respect to levels of hydroxylysine-linked carbohydrate moieties and that the more highly glycosylated molecules require higher salt concentrations for precipitation from acidic solutions. The data also indicate that a proportion of the more highly glycosylated alpha 1(II) chains are involved in the formation of one or more molecular species with 1 alpha and 2 alpha chains.

Cross-linking of collagen. Location of pyridinoline in bovine articular cartilage at two sites of the molecule

The location of pyridinoline in 18-month-old bovine articular cartilage was investigated by fractionation of CNBr-derived peptides by ion-exchange chromatography and gel filtration. Two peptides, PCP1 and PCP2, were isolated and were shown to contain stoichiometric amounts of pyridinoline. From its amino acid composition and sequence studies, peptide PCP1 was shown to comprise two C-terminal non-helical chains (CB14) linked through pyridinoline to the alpha 1(II)-CB12 portion of the helix. The CB14 chains appeared to be labile at their C-terminal ends, resulting in lower-than-expected amounts of homoserine, and only the N-terminal portion of the peptide was sequenced. Similar studies of peptide PCP2 showed that it contained two N-terminal non-helical chains (CB4) linked to the alpha 1(II)-CB9,7 portion of the helix. The isolated peptides therefore confirmed the function of pyridinoline in stabilizing the 4D stagger of adjacent molecules. The possibility that the cross-link could act both as an intra- and an inter-microfibrillar cross-link was considered. A mechanism of formation of pyridinoline was postulated that, together with other evidence, appears to support the view that, in cartilage, pyridinoline acts primarily as an intramicrofibrillar cross-link and does not contribute to increased stability during maturation through lateral aggregation and bonding of filaments.

Type II collagen from lathyritic rat chondrosarcoma: preparation and in vitro fibril formation

Intact type II collagen monomer was isolated in 10-20% yield from lathyritic rat chondrosarcoma and purified to homogeneity. On warming in neutral solution, the collagen formed a mixture of D-periodic native fibrils and thin filaments with no apparent structure. There were characteristic lag and growth phases in the turbidity profile. cooling dispersed or dissolved the fibrils leaving thin filaments. The fibrils were very wide, up to 2.0 micrometers compared to the 10 to 40 nm fibrils present in situ. They had the appearance of stiff tactoids compared to the very long and flexible fibrils obtained from type I collagen under similar conditions. Type II collagen also required higher temperatures and concentrations than type I to form fibrils. The continued presence of thin filaments when type II fibril formation was complete suggests either that filaments are in slow equilibrium with fibrils or that they may not be intermediates but rather a separate product.

The covalent structure of cartilage collagen. Amino acid sequence of residues 552-661 of bovine alpha1(II) chains

The covalent structure of the first 111 residues from the N-terminus of peptide alpha1(II)-CB10 from bovine nasal-cartilage collagen is presented. This region comprises residues 552-661 of the alpha1(II) chain. The sequence was determined by automated Edman degradation of peptide alpha1(II)-CB10 and of peptides produced by cleavage with trypsin and hydroxylamine. Comparison of this region of the alpha1(II) chain with the homologous segment of the alpha1(I) chain indicated a homology level of 85%, slightly higher than that of 81% reported for the N-terminal region of the alpha1(II) chain (Butler, Miller & Finch (1976) Biochemistry15, 3000-3006). The occurrence of two residues of glycosylated hydroxylysine was established at positions 564 and 603, the first present exclusively as galactosylhydroxylysine and the latter as a mixture of galactosylhydroxylysine and glucosylgalactosylhydroxylysine. Also, two residues at positions 648 and 657 were tentatively identified as glycosylated hydroxylysines. The amino acid sequences adjacent to the hydroxylysine residues so far identified in the alpha1(II) chain were compared with the homologous regions of the alpha1(I) and alpha2 chains, but no obvious prerequisite for hydroxylation could be seen. From comparison with the homologous sequence of the alpha1(I) chain, it appears that the alpha1(II)-chain sequence presented here contains three more amino acids than that reported for the alpha1(I) chain. This triplet would be interposed between residues 63 and 64 of the reported sequence of peptide alpha1(I)-CB7 from calf skin collagen. Data on the purification of the subpeptides and their amino acid compositions have been deposited as Supplementary Publication SUP 50087 (7 pages) at the British Library Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1978) 169, 5.

Covalent structure of collagen: amino-acid sequence of chymotryptic peptides from the carboxyl-terminal region of alpha2-CB3 of chick-skin collagen

The amino acid sequence of chymotryptic peptides C4 and C5 which together make up 206 COOH-terminal residues of alpha2-CB3 of chick skin collagen is described. This in combination with the sequence of 132 residues from the amino-terminal region published earlier [Dixit, Seyer, and Kang (1977) Eur. J. Biochem. 73, 213-221] completes the total amino acid sequence of the large CNBr peptide, alpha2-CB3 of chick skin collagen. The amino acid sequence was determined by automated Edman degradation of intact peptides C4 and C5 and their respective tryptic and maleylated tryptic peptides, and thermolytic peptides of C4. The comparison of the sequence with the homologous segment of alpha1(I) chain showed striking variance of over 51% within the same species.