Characterization of a highly soluble collagenous molecule isolated from chicken hyaline cartilage

Cartilage oligomeric matrix protein interacts with type IX collagen, and disruptions to these interactions identify a pathogenetic mechanism in a bone dysplasia family

Cartilage oligomeric matrix protein (COMP) and type IX collagen are key structural components of the cartilage extracellular matrix and have important roles in tissue development and homeostasis. Mutations in the genes encoding these glycoproteins result in two related human bone dysplasias, pseudoachondroplasia and multiple epiphyseal dysplasia, which together comprise a "bone dysplasia family." It has been proposed that these diseases have a similar pathophysiology, which is highlighted by the fact that mutations in either the COMP or the type IX collagen genes produce multiple epiphyseal dysplasia, suggesting that their gene products interact. To investigate the interactions between COMP and type IX collagen, we have used rotary shadowing electron microscopy and real time biomolecular (BIAcore) analysis. Analysis of COMP-type IX collagen complexes demonstrated that COMP interacts with type IX collagen through the noncollagenous domains of type IX collagen and the C-terminal domain of COMP. Furthermore, peptide mapping identified a putative collagen-binding site that is associated with known human mutations. These data provide evidence that disruptions to COMP-type IX collagen interactions define a pathogenetic mechanism in a bone dysplasia family.

Occurrence of a novel collagen with three distinct chains in the cranial cartilage of the squid Sepia officinalis: comparison with shark cartilage collagen

A unique collagen with three distinct chains, was purified from the cranial cartilage of the squid Sepia officinalis, by pepsinisation and salt precipitation and compared with shark cartilage collagen. These chains, which were different from the known cartilage collagen chains, were referred as C1, C2 and C3, had approximate molecular weights of 105 kDa, 115 kDa and 130 kDa, respectively, and were present in a ratio of 3:2:1, suggestive of two molecules of composition, [(C1)2C2] and [C1C2C3]. These collagens were purified by fractionation at acid and neutral pH, and by ammonium sulfate precipitation. Solubility data indicated that this collagen was more crosslinked than the type I collagen isolated from cartilage of shark, Carcharius acutus. In vitro fibrillogenesis revealed that the sepia collagen formed denser aggregates, as compared to shark collagen, and was stabilised by a higher degree of carbohydrate association. Polyclonal antisera raised against shark collagen was also reactive against the sepia collagens, while the converse was not true, indicating the high immunospecificity of the latter. These results demonstrate collagen polymorphism in an invertebrate cartilage and may hold significance in understanding tissue calcification and molecular evolution. Further, these collagens may represent ancestral forms of vertebrate minor collagens like typeV/XI.

Chondrocyte differentiation

Data obtained while investigating growth plate chondrocyte differentiation during endochondral bone formation both in vivo and in vitro indicate that initial chondrogenesis depends on positional signaling mediated by selected homeobox-containing genes and soluble mediators. Continuation of the process strongly relies on interactions of the differentiating cells with the microenvironment, that is, other cells and extracellular matrix. Production of and response to different hormones and growth factors are observed at all times and autocrine and paracrine cell stimulations are key elements of the process. Particularly relevant is the role of the TGF-beta superfamily, and more specifically of the BMP subfamily. Other factors include retinoids, FGFs, GH, and IGFs, and perhaps transferrin. The influence of local microenvironment might also offer an acceptable settlement to the debate about whether hypertrophic chondrocytes convert to bone cells and live, or remain chondrocytes and die. We suggest that the ultimate fate of hypertrophic chondrocytes may be different at different microanatomical sites.

Characterization of mammalian type IX collagen fragments from limited pepsin digests of a transplantable swarm rat chondrosarcoma

Collagenous fragments from type IX molecules have been solubilized by limited pepsin proteolysis of a transplantable rat chondrosarcoma and isolated by selective salt precipitation. Chromatography of the solubilized precipitate on CM-cellulose under nondenaturing conditions yielded three fractions. When examined by polarimetry, the material in all three fractions revealed native collagen helical structure with melting points which ranged from 31-37 degrees C. When the fractions were denatured and rechromatographed on a column of agarose beads, the most acidic fraction eluted as 13-kDa polypeptides with and without prior reduction and alkylation. In contrast, the second and third fractions eluted as 100-kDa and 30-kDa polypeptides prior to reduction, but on reduction and alkylation produced reducible products of 34 kDa and 10 kDa, respectively. The general compositional features of the three fractions closely resemble comparable collagenous fragments of type IX collagen from other species. The denaturation products of the 13-kDa nonreducible, the 30-kDa reducible, and the 100-kDa reducible fractions were sequentially purified by CM-cellulose and reversed-phase chromatography to resolve the chain constituents. The isolated 10-kDa, 13-kDa, and 34-kDa chains were cleaved with CNBr, and the cleavage products identified by gel-permeation chromatography. Two 13-kDa polypeptides, 13K2 and 13K3, which did not contain any methionyl residues and were not cleaved with CNBr, were digested with trypsin, and the peptide digests were resolved by reversed-phase chromatography. Comparisons of the CNBr and tryptic cleavage products demonstrate that the three major collagenous fragments are composed of three unique polypeptides. A partial amino acid sequence of an 8-kDa CNBr peptide derived from a purified 10-kDa peptide (10K1) matches identically the amino acid sequence derived from a cDNA sequence in the rat alpha 1(IX) chain (Kimura et al., 1989). These studies, then, present convenient procedures useful in the isolation of mammalian type IX collagen fragments and describe features of the rat molecule, indicating that it is similar to the avian counterpart with respect to chain composition and general molecular structure.

Separation of collagens by capillary zone electrophoresis

Collagen (types I, II, V, IX and XI) constituting polypeptide chains and their polymers and cyanogen bromide-cleaved peptides of collagen type I and type III were investigated by means of capillary zone electrophoresis. Separations were effected in 2.5 mM sodium tetraborate buffer in less than 15 min. A 50 cm x 0.1 mm I.D. fused-silica capillary was used. The separations were run at 18 kV per capillary. The results of the separation were monitored at 220 nm with an on-tube detection system. Using the Offord equation, relative retention times of cyanogen bromide cleavage fragments were plotted against M(2-3)/Z, where M is the molecular mass of a polypeptide and Z its valency. A linear relationship was observed. Collagen alpha-chains and their polymers were also satisfactorily resolved.

Problems in the immunolocalization of type IX collagen in fetal calf cartilage using a monoclonal antibody

Monoclonal antibodies were prepared against the pepsin-resistant fragments (X1-X3) of bovine type IX collagen. One of the five hybridomas that gave a positive reaction in an enzyme-linked immunosorbent assay was selected (H1a) for structural analysis and immunolocalization of type IX collagen. The location of the epitope for H1a was deducted from immunoblots and electron microscopic observations after rotary shadowing. The H1a antibody binds to one end of the longest X2, X3, X4 molecules, and preferentially 40-55nm from one end of X1 molecules thus, on or near the noncollagenous domain, NC2. Different immunolocalizations of type IX collagen in the superficial, middle and deep zones of fetal calf epiphyseal cartilage were observed depending on the thickness of the section and on hyaluronidase digestion conditions. In the middle and deep zones, staining with H1a throughout the matrix was obtained only with thin sections (5 microns) and digestion for 1 h at 37 degrees C. With thick sections (15 microns) or with digestion for 1 h at 24 degrees C, staining was restricted to the pericellular regions. Staining throughout the matrix was obtained in the superficial zone under all experimental conditions. Without hyaluronidase treatment, no immunofluorescent staining was seen with either H1a or polyclonal antibody to type II collagen, indicating that type IX collagen is present throughout the matrix in the different zones of fetal calf cartilage. This result is in good accordance with the recent demonstration of common cross-links between type II and type IX collagen in chicken and bovine cartilage. However, the preferential unmasking of type IX collagen antigenic sites in the pericellular regions of middle and deep zones of fetal calf cartilage does not preclude the presence in that region of a special pericellular organization of the collagenous network.

Vitreous humor of chicken contains two fibrillar systems: an analysis of their structure

An analysis of the structure of chicken vitreous humor after brief homogenization of the tissue was performed. Electron micrographs prepared after rotary shadowing with platinum showed the presence of two distinct fibrils. The collagen fibril was coated by glycosaminoglycan which could be removed by chondroitinase ABC digestion. In addition, individual molecules of tenascin were observed wrapped around some of the collagen fibrils. A second beaded fibril was present and several fine filaments were observed to extend from each bead. The beaded fibril is formed by the overlap of these filaments, and beaded fibrils were observed in either a "closed" or an "open" form dependent on whether all of the filaments are brought together to form the overlap. A schematic diagram is presented for the structure of the beaded fibril. The potential relationship of the beaded fibril to the zonular fibrils and the elastin microfibrils is briefly discussed.

Macromolecular organization of natural and recombinant lung surfactant protein SP 28-36. Structural homology with the complement factor C1q

The macromolecular structure of the pulmonary surfactant apolipoprotein SP 28-36 has been determined. For SP 28-36 isolated from dog lung lavage, a flower bouquet-like hexameric structure with six globular domains connected by short stalks to a common stem was revealed by electron microscopy, using the rotary shadowing technique. This structure is very similar to that published for the subcomponent C1q of the first component of complement C1. The lavage material was compared with the homologous human recombinant SP 28-36 by the same technique. Mostly smaller aggregates like di-, tri- and tetramers as well as very high aggregates were observed. Mild reduction of the recombinant material revealed the lollipop-shaped monomers composed of a globular domain and a tail with a discrete kink in the middle portion. The collagenous nature of the tail was demonstrated by circular dichroism spectroscopy. This implies that the mammalian expression system assembles the monomeric subunits correctly. Assembly into the hexameric structures, however, does not proceed quantitatively.

Structure of the glycosaminoglycan domain in the type IX collagen-proteoglycan

Type IX collagen represents 5-20% of the total collagen in hyaline cartilage. The molecules of this collagen are composed of three genetically distinct polypeptide subunits. One of these subunits, alpha 2(IX), contains covalently bound glycosaminoglycan (chondroitin sulfate or dermatan sulfate). We report here on the structure of the glycosaminoglycan attachment site of type IX collagen-proteoglycan. We show, by a combination of cDNA and peptide sequencing, that the attachment region contains the sequence Gly-Ser-Ala-Asp, located within the noncollagenous domain NC3 of the alpha 2(IX) chain. By comparing the exons encoding the NC3 domain in the alpha 2(IX) and alpha 1(IX) genes, we find that the exon coding for the glycosaminoglycan attachment site in the alpha 2(IX) gene is 48 base pairs long, whereas the homologous alpha 1(IX) exon is 33 base pairs. The NC3 domain is, therefore, five amino acid residues longer in alpha 2(IX) than in alpha 1(IX). The extra sequence in alpha 2(IX), Val-Glu-Gly-Ser-Ala, provides a simple explanation for the kink observed at the NC3 domain of type IX molecules when examined by electron microscopy. The inserted block of amino acid residues also provides the NC3 domain of alpha 2(IX) chains with a serine residue, not present in alpha 1(IX) that serves as attachment site for a glycosaminoglycan side chain. Our data show that the amino acid sequence that surrounds the glycosylated serine residue in type IX collagen-proteoglycan differs from glycosylated sequences in noncollagenous core proteins. The data also provide strong evidence that glycosylation of type IX collagen is not a chance glycosylation of a serine residue in a noncollagenous domain, but is a specific post-translational modification of this unusual collagen molecule.

Polypeptide composition of the mammalian tectorial membrane

The effects of the enzymes collagenase, pepsin, chondroitinase ABC and keratanase on the polypeptide composition of the mammalian tectorial membrane have been analysed using one dimensional SDS-polyacrylamide gel electrophoresis (SDS-PAGE). After reduction at least ten polypeptides can be consistently and clearly recognized in SDS gels with molecular weights relative to globular protein standards of 245, 235, 190, 165, 155, 145, 100, 93, 60-73 and 35-49 kDa. With the exception of the 60-73 and 35-49 kDa bands all these polypeptides are sensitive to digestion with bacterial collagenase. The 235, 165, 155, 145 and 93 kDa bands also resist degradation by cold, acidic pepsin. Amino acid analysis of whole tectorial membranes demonstrates that glycine accounts for nearly 25% of the total amino acid content, that proline, hydroxyproline and hydroxylysine are present and that amine sugars can be detected in fairly high concentrations. Estimates based on hydroxyproline content suggest that collagens account for 25-50% of the total tectorial membrane protein. Immunoblotting techniques demonstrate the presence of polypeptides cross reacting with antisera to Type II collagen, Type IX collagen and Type V collagen. Results from immunohistochemical studies confirm that these polypeptides are present in the tectorial membrane and are not contaminants of the isolation procedure. Collagenase treatment of tectorial membranes reveals the presence of an additional non-collagenous polypeptide with an apparent molecular weight of 173 kDa on 7.5% polyacrylamide gels, and polydisperse high molecular weight material spreading over a broad range at the top of the gels. This high molecular weight material and the 173, 60-73 and 35-49 kDa non-collagenous polypeptides are pepsin sensitive and all bind wheat germ agglutinin (WGA) suggesting that they contain N-acetyl glucosamine. The 173 kDa band also binds soybean agglutinin (SBA) suggesting the presence of N-acetyl galactosamine. In the absence of reducing agent the 173 and 60-73 kDa bands are no longer observed and high molecular weight material forming a broad band at the top of the separating gel is seen. The electrophoretic behaviour of this non-collagenous, glycosylated, disulphide bonded, high molecular weight material is altered by treatment with keratanase but not by chondroitinase ABC. The results of this study indicate the tectorial membrane contains at least three different collagen types and, in addition to these collagenous proteins, several non-collagenous, glycosylated polypeptides that may account for as much as 50% of the total tectorial membrane protein.

The immunoperoxidase localization of type X collagen in chick cartilage and lung

We have localized type X collagen in chick cartilage and lung by use of affinity-purified antibodies raised against the purified protein. Examination of the centers of primary endochondral development in the embryonic sternum, developing cartilage in the embryonic tubular bones and growth plate cartilages demonstrated the specific association of type X collagen with regions of hypertrophic chondrocytes in these tissues. Furthermore these studies revealed a tendency for type X collagen to accumulate adjacent to regions of active vascular invasion and an apparent lag between the initial intracellular accumulation and the matrix deposition of type X collagen. A lag in the matrix accumulation of type X collagen was also shown biochemically and immunohistochemically in chondrocytes in culture. In chick lung type X collagen was localized to the smooth muscle of the blood vessels and to smooth muscle surrounding alveolar ducts.

Type X collagen synthesis during in vitro development of chick embryo tibial chondrocytes

In the developing chick embryo tibia type X collagen is synthesized by chondrocytes from regions of hypertrophy and not by chondrocytes from other regions (Capasso, O., G. Tajana, and R. Cancedda, 1984, Mol. Cell. Biol. 4:1163-1168; Schmid, T. M., and T. F. Linsenmayer, 1985, Dev. Biol. 107:375-381). To investigate further the relationship between differentiation of endochondral chondrocytes and type X collagen synthesis we have developed a novel culture system for chondrocytes from 29-31-stage chick embryo tibiae. At the beginning of the culture these chondrocytes are small and synthesize type II and not type X collagen, but when grown on agarose-coated dishes they further differentiate into hypertrophic chondrocytes that synthesize type X collagen. The synthesis of type X collagen has been monitored in cultured cells by analysis of labeled collagens and in vitro translation of mRNAs. When the freshly dissociated chondrocytes are plated in anchorage-permissive dishes, most of the cells attach and dedifferentiate, as revealed by their fibroblastic morphology. Dedifferentiated chondrocytes, after several passages, can still reexpress the differentiated phenotype and continue their development to hypertrophic, type X collagen-synthesizing chondrocytes. Hypertrophic chondrocytes, when plated in anchorage permissive dishes, attach, maintaining the differentiated phenotype, and continue the synthesis of type X collagen.

On the role of type IX collagen in the extracellular matrix of cartilage: type IX collagen is localized to intersections of collagen fibrils

The tissue distribution of type II and type IX collagen in 17-d-old chicken embryo was studied by immunofluorescence using polyclonal antibodies against type II collagen and a peptic fragment of type IX collagen (HMW), respectively. Both proteins were found only in cartilage where they were co-distributed. They occurred uniformly throughout the extracellular matrix, i.e., without distinction between pericellular, territorial, and interterritorial matrices. Tissues that undergo endochondral bone formation contained type IX collagen, whereas periosteal and membranous bones were negative. The thin collagenous fibrils in cartilage consisted of type II collagen as determined by immunoelectron microscopy. Type IX collagen was associated with the fibrils but essentially was restricted to intersections of the fibrils. These observations suggested that type IX collagen contributes to the stabilization of the network of thin fibers of the extracellular matrix of cartilage by interactions of its triple helical domains with several fibrils at or close to their intersections.

Quantitative analysis of type X-collagen biosynthesis by embryonic-chick sternal cartilage

We have performed a quantitative analysis of the various collagens biosynthesized by organ cultures of whole embryonic-chick sternum and its separate anatomical regions corresponding to the zones of permanent hyaline and presumptive-calcification cartilages. Our studies demonstrated that embryonic-chick sternum devotes a large portion of its biosynthetic commitment towards production of Type X collagen, which represented approx. 18% of the total newly synthesized collagen. Comparison of the collagens biosynthesized by the permanent hyaline cartilage and by the cartilage from the presumptive-calcification zone demonstrated that Type X-collagen production was strictly confined to the presumptive-calcification region. Sequential extraction of the newly synthesized Type X collagen demonstrated the existence of two separate populations. One population (approx. 20%) was composed of easily extractable molecules that were solubilized with 1.0 m-NaCl/50 mM-Tris/HCI buffer, pH 7.4. The second population was composed of molecules that were not extractable even after repeated pepsin digestion, but became completely solubilized after treatment with 20 mM-dithiothreitol/0.15 M-NaCl buffer at neutral pH. These results suggest that most of the Type X collagen normally exists in the tissue as part of a pepsin-resistant molecular aggregate that may be stabilized by disulphide bonds. Quantitative analysis of the proportion of Type X collagen relative to the other collagens synthesized in the cultures indicated that this collagen was a major biosynthetic product of the presumptive-calcification cartilage, since it represented about 35% of the total collagen synthesized by this tissue. In contrast, the permanent hyaline cartilage did not display any detectable synthesis of Type X collagen. When compared on a per-cell basis, the chondrocytes from the presumptive-calcification zone synthesized approx. 33% more Type X collagen than the amount of Type II collagen synthesized by the chondrocytes from the permanent-hyaline-cartilage zone. Subsequently, it was demonstrated that Type X collagen is a structural component of chick sternum matrix, since quantitative amounts could be extracted from the region of presumptive calcification of 17-day-old chick-embryo sterna and from the calcified portion of adult-chick sterna. The strict topographic distribution in the expression of Type X collagen biosynthesis to the zone of presumptive calcification suggests that this collagen may play an important role in initiation or progression of tissue calcification.

Monoclonal antibody against chicken type IX collagen: preparation, characterization, and recognition of the intact form of type IX collagen secreted by chondrocytes

A series of monoclonal antibodies was prepared against the pepsin-resistant fragment of type IX collagen designated HMW. One of these antibodies (called 2C2) was selected for further analysis. Antibody 2C2 showed no cross-reactivity with other collagen types by inhibition enzyme-linked immunosorbent assays. It recognized an epitope present in native HMW, but failed to recognize any of the three chains of HMW fractionated after denaturation followed by reduction and alkylation of interchain disulfide bridges. Electron microscopic observations after rotary shadowing showed that the location of the epitope for antibody 2C2 was close to the carboxy-terminus of HMW. Immunofluorescent staining of sections of embryonic and adult cartilage with antibody 2C2 after removal of proteoglycans by testicular hyaluronidase digestion showed that type IX collagen is distributed throughout the cartilage matrix, and is not present in other connective tissues or skeletal muscle. The intact type IX collagen molecule, which was secreted by a suspension culture of freshly isolated embryonic chick chondrocytes, was recognized by rotary shadowing in the presence of antibody 2C2 after first precipitating the procollagens from the culture medium with ammonium sulfate (30%). Two different collagenous molecules were present in the precipitate: a longer molecule of type II procollagen (average length, 335 nm) with both amino- and carboxy-propeptides still remaining uncleaved, and a shorter molecule (average length, 190 nm) which was identified as type IX collagen. Antibody 2C2 consistently bound to the shorter molecules at a site located 136 nm from a distinctive knob at one end of the molecule, and did not bind to any specific site on the type II procollagen molecules. The structure of the intact type IX collagen molecule with the location of both collagenous and noncollagenous domains was as predicted after converting the nucleotide sequence of a cDNA clone encoding for one of the chains of type IX collagen to an amino acid sequence (Ninomiya, Y., and B. R. Olsen, 1984, Proc. Natl. Acad. Sci. USA, 81:3014-3018).

Type X collagen synthesis by chick sternal cartilage and its relationship to endochondral development

Our morphological studies have demonstrated that the appearance of localized, paired zones of primary calcification on either side of the midline of the 19-d embryonic chick sternum is heralded by the development of paired, translucent zones 2 d previously. Histological studies demonstrated that the majority of chondrocytes within these translucent zones are hypertrophic, and that the zones are surrounded by a margin of flattened nonhypertrophic cells. The discrete localization of these paired areas of hypertrophic chondrocytes and subsequent endochondral bone development allows for the direct correlation of the histological and biochemical characteristics of the zones sequentially during development and makes it possible to precisely match the synthetic activity to the cellular morphology, thereby eliminating possible minor but critical variations in developmental staging that could otherwise arise. Our studies have demonstrated that there is a direct spatial and temporal correlation between the degree of cellular maturation and the synthesis of type X collagen, and that the sudden and profound initiation of type X collagen synthesis on days 16-17 of development occurs concurrently with the attainment of hypertrophic characteristics by the majority of cells within the translucent zone. Before acquisition of these hypertrophic characteristics, the cells of this precalcification zone synthesize only type II and the minor cartilage collagens. Chondrocytes isolated from these regions in more immature sternae (i.e., 11+ d embryos) were found to synthesize high levels of type X collagen within 4 d of culture within collagen gels even though hypertrophic development and type X collagen synthesis by cells within this region would not normally have been apparent in ovo for several more days. These data indicate that there is a direct correlation between the development of hypertrophic characteristics and the synthesis of type X collagen, and that the maturation of chondrocytes in precalcification zones may be regulated by matrix components and/or stimulated by culture within collagen gels.

Isolation and partial characterization of precursors to minor cartilage collagens

Suspension cultures of cartilage cells were prepared from 17-day chick embryo sterna and radiolabeled with [14C]-proline under conditions which sought to minimize proteolytic conversion of procollagen to collagen. Collagenous proteins were isolated from the culture medium and cell fraction, were purified in their native state by (NH4)2SO4 precipitation and DEAE-cellulose chromatography, and were characterized by protease susceptibility, SDS-gel-filtration and SDS-polyacrylamide gel electrophoresis. Qualitatively, the precursor components present in the medium were similar to those in the cell extract; quantitatively, it appeared that the minor cartilage collagen precursor components derived from 1 alpha, 2 alpha, 3 alpha and type IX collagens were more prevalent in the cell extract. SDS-PAGE of unreduced samples showed that precursors to both of these collagens migrated as distinct high-molecular-weight aggregates. After chymotrypsin digestion, unreduced type IX collagen migrated as two disulfide-bonded aggregates--a large one (Mr approximately 210K) and a small one (Mr approximately 43K); whereas 1 alpha, 2 alpha, 3 alpha chains migrated identically whether reduced or unreduced. Reduction of undigested type IX aggregate yielded two components of Mr approximately 97K and 78K; whereas reduction of the chymotrypsin resistant 210K and 43 K aggregates gave a single component of Mr approximately 61K and a component which migrated at the dye front, respectively. The molecular origin of these components was confirmed by differential NaCl precipitation. It was concluded that this culture system synthesized precursors to 1 alpha, 2 alpha, 3 alpha and type IX collagens in addition to type II; type X collagen was not detected even though the 17-day sternum contained a population of cells morphologically similar to hypertrophic chondrocytes. The precursor chains to 1 alpha, 2 alpha, 3 alpha collagen had an apparent Mr greater than pro-alpha (II) and could be isolated as a disulfide-bonded aggregate(s); the precursor chains to type IX collagen had an apparent Mr less than pro alpha (II) and could also be isolated as a disulfide-bonded aggregate. All of the cartilage collagen precursors had protease-susceptible regions, but those in type IX appeared to be more sensitive to pepsin than to chymotrypsin.

Type IX collagen from sternal cartilage of chicken embryo contains covalently bound glycosaminoglycans

Type IX collagen was isolated as a native protein from chicken embryo sternal cartilages and purified to homogeneity. Chondroitin and/or dermatan sulfate were bound covalently to one of the three polypeptide chains present in this protein containing collagenous and noncollagenous domains. Type IX collagen could be metabolically labeled with both radioactive sulfate and glycine. The protein containing either of these labels was sensitive to digestion by bacterial collagenase as well as chondroitinase ABC. Besides the glycosaminoglycans, type IX collagen contains asparagine-linked carbohydrate chains because the protein could be labeled with radioactive mannose and no glycosaminoglycans other than those mentioned above were present. The melting curve indicated that, in contrast to interstitial collagens, this molecule contains at least two disulfide-bonded collagenous domains with distinct thermal stabilities.

Morphology of the pericellular capsule in articular cartilage revealed by hyaluronidase digestion

To allow a more valid comparison between our previous ultrastructural data and the immunolocalization of type IX and other minor collagen species in cryosectioned cartilage, we examined both normal and testicular hyaluronidase-digested canine tibial cartilage by electron microscopy. Removal of matrix proteoglycans caused the pericellular capsule to collapse against the cell surface, suggesting that its normal anatomical position is mediated by pericellular matrix hydration. Detailed examination of the pericellular capsule and pericellular channel revealed fine, faintly banded fibrils and an amorphous component somewhat similar in structure to basement membrane collagens. Matrix vesicles and the electron-dense material of the interterritorial matrix were only partially digested by hyaluronidase. We propose that the pericellular capsule is composed of a "felt-like" network of minor collagen species which act synergistically to maintain both the composition of the pericellular matrix and the integrity of the chondrocyte/pericellular matrix complex during compressive loading.

Further biochemical and physicochemical characterization of minor disulfide-bonded (type IX) collagen, extracted from foetal calf cartilage

Minor disulfide-bonded collagen (previously termed X1-X7 and now called type IX collagen) was isolated from foetal calf cartilage after pepsin treatment. At least three native fractions, containing, respectively, the X1X2X3, X4, and X5X6X7 chains, were separated; and from further biochemical and physicochemical experiments (differential scanning calorimetry, electrical birefringence, rotary shadowing), we propose a tentative model for their organization within a parent molecule. X1 and X2 are molecules composed of three chains of apparent Mr 62,000 and 50,000 linked by interchain disulfide bonds and containing pepsin-sensitive regions. The cleavage of at least three of these sites, present within X2, gives rise to the X3 and X5X6X7 fractions composed of molecules 80-100 nm and 40-55 nm in length, respectively. The X5X6X7 fraction is not digested by pepsin at 30 degrees C owing to its high thermal stability (certainly explained by its high hydroxyproline + proline content). This organization is in good accordance with that proposed for chicken cartilage type IX collagen; differences could only exist in the number and (or) the location of the pepsin-sensitive sites.

The structure of a small collagenous fragment isolated from chicken hyaline cartilage

In previous experiments, two collagenous fragments were isolated from pepsin digests of chicken hyaline cartilage and called the high molecular weight, (HMW) and low molecular weight (LMW) fractions [3]. In the present experiments, the chains of LMW were isolated after denaturation and subsequent reduction and alkylation of interchain disulfide bridges and were further fractionated by carboxymethyl-cellulose chromatography. Four peaks were resolved during chromatography and were designated LMW 1, 2A, 2B, and 3. Amino acid analyses and peptide mapping after cleavage with trypsin, V8 protease, and cyanogen bromide showed that three genetically distinct chains must be present in LMW. Fractions 2A and 2B were very similar, but not identical, in structure. LMW 1, 2A plus 2B, and 3 were consistently isolated in approximately equal proportions, suggesting that the probable chain organization of LMW is [1][2A + 2B][3]. This suggestion was supported further by experiments that attempted to fractionate LMW by carboxymethyl-cellulose chromatography after denaturation but without reduction and alkylation of interchain disulfide bridges. No fractionation of LMW was achieved, the single peak subsequently being shown to contain LMW 1, 2A plus 2B, and 3.

Biosynthesis of a disulphide-bonded short-chain collagen by calf growth-plate cartilage

Collagen biosynthesis by organ cultures of the hypertrophic zone of calf growth-plate cartilage was studied. It was found that this tissue devotes a large portion of its biosynthetic commitment towards production of a collagen molecule comprising short collagen chains. This collagen is similar to short-chain collagens synthesized by chick-embryo tibiotarsus, rabbit growth-plate cartilage and chick chondrocytes grown in three-dimensional gels. However, in contrast with the collagen synthesized in these three systems, the short-chain collagen synthesized by calf growth-plate hypertrophic cartilage is stabilized by disulphide bonds localized within the pepsin-resistant triple-helical collagenous domains of these molecules.

Localization of human type II procollagen gene (COL2A1) to chromosome 12

DNA was prepared from 39 human-mouse somatic cell hybrid lines, and mouse and human parental cell lines. The DNA was digested to completion with EcoRI and Southern filters were prepared. These filters were hybridized at high stringency conditions to the human genomic subclone phHCol(II) A which corresponds to the human alpha 1(type II) procollagen gene (COL2A1). The mouse DNA yielded a single band at greater than 10 kb, whereas the human DNA had the expected single band at 4.8kb. Analyses of these human-mouse cell hybrids demonstrated that the human alpha 1(type II) procollagen gene segregates with chromosome 12.

Cartilage type IX collagen is cross-linked by hydroxypyridinium residues

Type IX collagen, a recently discovered, unusual protein of cartilage, has a segmented triple-helical structure containing interchain disulfides. Its polymeric form and function are unknown. When prepared by pepsin from bovine articular cartilage, type IX collagen was found to contain a high concentration of hydroxypyridinium cross-links, similar to that in type II collagen. Fluorescence spectroscopy located the hydroxylysyl pyridinoline and lysyl pyridinoline cross-linking residues exclusively in the high-molecular-weight collagen fraction, from which they were recovered predominantly in a single CNBr-derived peptide. The results point to a structural role for type IX collagen in cartilage matrix, possibly as an adhesion material to type II collagen fibrils.

Isolation and characterization of the precursor of type M collagen

A 225000-Mr peptide has been purified from rat chondrosarcoma which is immunologically and biochemically related to type M collagen. Rotary shadowing shows this molecule to be twice the length of the type M molecule and has a prominent kink close to one end. We believe this molecule represents parent type M, the form of the molecule in vivo.

Synthesis of a low molecular weight collagen by chondrocytes from the presumptive calcification region of the embryonic chick sterna: the influence of culture with collagen gels

The mature chick sternum is divisible almost equally into cephalic calcified and caudal cartilagenous regions. Isolation and culture of cells derived from embryonic precursors of these regions has revealed two discrete populations of cells with distinct morphological features and synthetic capabilities. Both cell populations grew well in culture within or upon collagen gels or upon plastic and maintained morphologies similar to those observed in the parent tissue. Polyacrylamide gel electrophoresis of radiolabeled proteins synthesized by the cells in culture demonstrated large differences in the types of collagens synthesized. Both chondrocyte populations synthesized type II and minor cartilage collagens but only chondrocytes isolated from the presumptive calcification region synthesized the previously identified, low molecular weight collagen, termed G collagen. Synthesis of G collagen was stimulated by culture within or upon collagen gels such that it represented an average of 65% of the total collagen synthesized by presumptive calcification region chondrocytes after 7 d of culture within collagen gels. Light and scanning electron microscopy demonstrated that the two chondrocyte types exhibited distinct morphological features and accumulated different extracellular matrices in culture.

Analysis of collagen types synthesized by rabbit ear cartilage chondrocytes in vivo and in vitro

This study compares the collagen types present in rabbit ear cartilage with those synthesized by dissociated chondrocytes in cell culture. The cartilage was first extracted with 4M-guanidinium chloride to remove proteoglycans. This step also extracted type I collagen. After pepsin solubilization of the residue, three additional, genetically distinct collagen types could be separated by fractional salt precipitation. On SDS (sodium dodecyl sulphate)/polyacrylamide-gel electrophoresis they were identified as type II collagen, (1 alpha, 2 alpha, 3 alpha) collagen and M-collagen fragments, a collagen pattern identical with that found in hyaline cartilage. Types I, II, (1 alpha, 2 alpha, 3 alpha) and M-collagen fragments represent 20, 75, 3.5, and 1% respectively of the total collagen. In frozen sections of ear cartilage, type II collagen was located by immunofluorescence staining in the extracellular matrix, whereas type I collagen was closely associated with the chondrocytes. Within 24h after release from elastic cartilage by enzymic digestion, auricular chondrocytes began to synthesize type III collagen, in addition to the above-mentioned collagens. This was shown after labelling of freshly dissociated chondrocytes with [3H]proline 1 day after plating, fractionation of the pepsin-treated collagens from medium and cell layer by NaCl precipitation, and analysis of the fractions by CM(carboxymethyl)-cellulose chromatography and SDS/polyacrylamide-gel electrophoresis. The 0.8 M-NaCl precipitate of cell-layer extracts consisted predominantly of type II collagen. The 0.8 M-NaCl precipitate obtained from the medium contained type I, II, and III collagen. In the supernatant of the 0.8 M-NaCl precipitation remained, both in the cell extract and medium, predominantly 1 alpha-, 2 alpha-, and 3 alpha-chains and M-collagen fragments. These results indicate that auricular chondrocytes are similar to chondrocytes from hyaline cartilage in that they produce, with the exception of type I collagen, the same collagen types in vivo, but change their cellular phenotype more rapidly after transfer to monolayer culture, as indicated by the prompt onset of type III collagen synthesis.

Synthesis and characterization of cDNA encoding a cartilage-specific short collagen

Hyaline cartilage contains a unique set of collagenous proteins. Type II collagen is the most abundant, constituting about 85% of the total cartilage collagen. In addition, several minor collagenous components have been described. To study the structure and developmental regulation of chondrocyte-specific collagens, we have constructed a cDNA library from embryonic chicken sternal cartilage mRNA. We report here on the isolation and characterization of a 3200 base-pair-long cDNA that codes for a collagenous polypeptide of unusual structure in that the total length of the molecule is only about half of pro alpha 1(II) collagen chains. The mRNA for this polypeptide is considerably smaller than mRNA encoding the pro alpha chains of interstitial collagens. In addition, the peptide encoded by the cDNA appears to contain at least three domains with triple-helical potential separated by short, noncollagenous peptides. Between the three collagenous domains are several cysteinyl residues.

Embryonic chick cartilage collagens. Differences in the low-Mr species present in sternal cartilage and tibiotarsal articular cartilage

The collagenous polypeptides present in embryonic chick sternal and tibiotarsal cartilages have been solubilised by digestion with pepsin and separated by salt fractionation. Type II collagen, 1 alpha 2 alpha 3 alpha collagen, and two polypeptides (apparent molecular mass 150 and 42 kDa), which were reducible to a number of smaller peptides, were extracted from both tissues. However, also present in the peptic digests of tibiotarsal cartilages was a major non-reducible highly-soluble polypeptide of 45 kDa. This short-chain collagen is apparently identical to the pepsinized product of G collagen (Mr 59 000), a major low-Mr procollagen-like species previously detected in chick chondrocyte cultures.

A new look at vitreous-humour collagen

The collagens of bovine vitreous-humour and nasal-septum cartilage have been extracted, fractionated and compared. Both tissues show the same heterogeneity of collagen types, consisting of type II, 1 alpha, 2 alpha, 3 alpha and C-PS collagens. The type II collagen of the vitreous humour was significantly more hydroxylated both in the lysine and proline residues than was that of cartilage. C-PS1 collagen, together with higher-Mr forms were present in the vitreous humour, but the higher-Mr forms were not seen in cartilage. Both C-PS1 and C-PS2 were present in vitreous humour and cartilage, but vitreous humour contained three times more of these collagens than did cartilage. Despite the difference in amount, the molar ratio C-PS1/C-PS2 was approx. 1 in both tissues, suggesting that they are components of a larger molecule. The 1 alpha, 2 alpha, 3 alpha collagens were present in the same concentration in both tissues. These three chains co-precipitated on dialysis against phosphate-buffered saline, pH 7.2, in a manner analogous to type V collagen.

Changes in the synthesis of minor cartilage collagens after growth of chick chondrocytes in 5-bromo-2'-deoxyuridine or to senescence

Analyses were made of the minor collagens synthesized by cultures of chondrocytes derived from 14-day chick embryo sterna. Comparisons were made between control cultures, cultures grown for 9 days in 5-bromo-2'-deoxyuridine (BrdU) and clones of chondrocytes grown to senescence. Separation of minor collagens from interstitial collagens was achieved by differential salt precipitation in the presence of carrier collagens in acid conditions. The precipitate at 0.9 M NaCl 0.5 M acetic acid from control cultures was shown by CNBr peptide analysis to contain only the alpha 1(II) chain of type II collagen, whereas after BrdU treatment or growth to senescence synthesis of only alpha 1(I) and alpha 2(I) chains occurred. The synthesis of type III collagen was not detected. Analysis of the precipitate at 2.0 M NaCl, 0.5 M HAc from control cultures demonstrated the synthesis of 1 alpha, 2 alpha and 3 alpha chains together with the synthesis of short chain (SC) collagen of Mr 43000 after pepsin digestion. After BrdU treatment or growth to senescence alpha chains were isolated which possessed the migration positions on polyacrylamide gel electrophoresis (PAGE), or the elution positions on CM-cellulose chromatography, of the alpha 1(V) and alpha 2(V) chains of type V collagen. In addition, for BrdU-treated but not for control cultures, intracellular immunofluorescent staining was observed with a monoclonal antibody which specifically recognizes an epitope present in the triple helix of type V collagen. Synthesis of short chain (SC) collagen was not detected after BrdU treatment or growth to senescence. These results suggest that chick chondrocytes grown in conditions known to cause switching of collagen synthesis from type II to type I collagen also undergo a switch from the synthesis of 1 alpha, 2 alpha and 3 alpha chains to the synthesis of the alpha 1(V) and alpha 2(V) chains of type V collagen. It appears that there are several cartilage-specific collagens which together undergo a regulatory control to the synthesis of collagens typical of other connective tissues.

Isolation and characterization of a precursor form of M collagen from embryonic chicken cartilage

A disulfide-cross-linked collagen has been extracted with neutral salt solutions from organ cultures of embryonic chick sternal cartilage. This collagen, which we term pM collagen, is presumed to be the native extracellular precursor molecule to disulfide-cross-linked collagen fragments recently described. Cleavage of pM collagen under native conditions with pepsin gives rise to the collagen fragments M1 and M2, which had also been isolated from pepsin extracts of chick hyaline cartilage [K. von der Mark, M. van Menxel & H. Wiedemann (1982) Eur. J. Biochem. 124, 57-62]. Native pM collagen was purified by DEAE-cellulose chromatography and agarose gel filtration. On agarose and following polyacrylamide gel electrophoresis, the unreduced molecule migrates with an apparent Mr of 300 000. Reduction of disulfide bridges produces two subunits with Mr 80 000 (pMa) and 60 000 (pMb) when compared with collagen standards. Cyanogen bromide cleavage of pMa and pMb, excised from dodecyl sulfate gels, resulted in different peptide maps, indicating that both components are genetically distinct polypeptide chains. The occasional appearance of the unreduced pM collagen as a doublet band on dodecyl sulfate gels and the observation that pMa and pMb occur in non-stoichiometric ratios suggests that pMa and pMb form separate native molecules, although their incorporation into a single pM molecule cannot be excluded. Native pM collagen was completely digested with bacterial collagenase, and contained hydroxyproline and proline in a ratio of 1.15:1, indicating the absence of significant non-collagenous domains. Thus it represents, despite several pepsinlabile sites, more likely a largely triplehelical, processed form of collagen rather than a procollagen-like molecule containing globular domains. Processing of pM collagen to M1 and M2 fragments or other intermediate forms was not observed in cartilage organ culture or in chondrocyte cell cultures within 18 h.

Fetal calf ligament fibroblasts in culture secrete a low molecular weight collagen with a unique resistance to proteolytic degradation

A highly unusual collagen was secreted by fibroblasts cultured from 150- and 270-d-old fetal calf nuchal ligaments. Purification revealed that this protein (which may be synthesized in a higher molecular weight form) was precipitated at unusually high concentrations of ammonium sulfate and was also eluted from DEAE-cellulose at greater salt concentrations than were types I and III procollagens. On SDS PAGE, the collagenous protein exhibited an Mr of approximately 12,750 that was not altered in the presence of reducing agent. The low molecular weight collagen (FCL-1) was sensitive to bacterial collagenase and had a [3H]glycine content comparable to that found in type I procollagen, although the [3H]Hyp to [3H]Pro ratio was 0.43. FCL-1 was not cleaved by human skin collagenase, mast cell protease, trypsin, Staphylococcal V8 protease, or proteinase K at 37 degrees C. The collagen was susceptible to trypsin, but not to V8 protease, only after heating at 80 degrees C for 30 min. Preliminary structural studies indicate that FCL-1 was resistant to cleavage by CNBr but exhibited limited proteolysis with pepsin. Both 150- and 270-d-old fibroblasts produced comparable levels of interstitial (types I and III) procollagens, which comprised approximately 70% of the total protein secreted into the culture medium. However, 270-d-old (term) fibroblasts secreted approximately 50% more FCL-1, as percent of total culture medium protein, in comparison to the cells from the earlier gestational stage. This collagen may therefore play a role in the development of the nuchal ligament.