Comparative studies of type X collagen expression in normal and rachitic chicken epiphyseal cartilage.

The levels of type X collagen in mineralizing normal chicken epiphyses and nonmineralizing rachitic chicken tibial epiphyses were measured and compared. Qualitative immunoperoxidase studies with anti-chick type X collagen monoclonal antibodies on sections from normal and rachitic cartilage demonstrated that the type X collagen levels in rachitic growth plates are reduced. Northern hybridization of mRNA and biosynthetic studies have confirmed that type X collagen synthesis in rickets is also decreased. In hypocalcemic rickets, the level of type X collagen mRNA is reduced by 80% whereas the level of type X collagen mRNA is only reduced by 50% in normocalcemic rickets. These observations provide additional evidence that type X collagen is involved in the process of cartilage mineralization and also suggest that the partial recovery of type X collagen synthesis in normocalcemic rickets may be related to the elevated plasma concentration of calcium. Calcium concentration may therefore play an important role in the control of type X collagen synthesis.

Macromolecular organization of chicken type X collagen in vitro.

The macromolecular structure of type X collagen in the matrices of primary cultures of chick hypertrophic chondrocytes was initially investigated using immunoelectron microscopy. Type X collagen was observed to assemble into a matlike structure with-in the matrix elaborated by hypertrophic chondrocytes. The process of self assembly was investigated at the molecular level using purified chick type X collagen and rotary-shadowing EM. It was shown that under neutral conditions at 34 degrees C, individual type X collagen molecules associate rapidly into multimeric clusters via their carboxy-terminal globular domains forming structures with a central nodule of carboxy-terminal domains and the triple helices radiating outwards. Prolonged incubation resulted in the formation of a regular hexagonal lattice by lateral association of the juxtaposed triple-helical domains from adjacent multimeric clusters. This extended lattice may play an important role in modifying the cartilage matrix for subsequent events occurring in endochondral bone formation.

Characterization of collagens and proteoglycans at the insertion of the human Achilles tendon.

This study provides a unique correlation between a molecular biological and biochemical analysis of the extracellular matrix (ECM) macromolecules in one half of 28 human Achilles tendons with an immunohistochemical study of the other. Both the insertion site and the mid-tendon were studied. The insertion (enthesis) is characterized by three distinctive fibrocartilages, two in the tendon (enthesial and sesamoid) and one on the heel bone (periosteal). Thus, its structure contrasts markedly with the fibrous character of the mid-tendon. RT-PCR analyses were performed on RNA extracted from mid-tendon and from the tendon fibrocartilages to investigate transcription of collagens and proteoglycans. Western blotting was also used to identify and characterize these macromolecules, and immunohistochemistry to localize their distribution. The results demonstrate striking differences in the ECM between the mid-tendon and its insertion. Types I, III, V and VI collagens, decorin, biglycan, fibromodulin and lumican were found in both the mid-tendon and the fibrocartilages, although their precise distribution often differed with site. mRNA for type II collagen was constantly present in the fibrocartilages, but it was only found in the mid-tendon of one specimen. The patterns of distribution for versican and aggrecan mRNA were complimentary - versican mRNA was present in the mid-tendon and absent from the fibrocartilages, while aggrecan mRNA was present in the fibrocartilages and absent from the mid-tendon. The range and distribution of ECM molecules detected in the Achilles tendon reflect the differing forces acting on it - the mid-tendon largely transmits tension and is characterized by molecules typical of fibrous tissues, but the fibrocartilages must also resist compression and thus contain, in addition, molecules typical of cartilage.

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

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

Identification of disulphide-bonded type X procollagen polypeptides in embryonic chick chondrocyte cultures.

A high-Mr (Mr 120,000), disulphide-bonded collagenous polypeptide was observed to co-purify with the prox1(X) chain during isolation of cartilage collagens from culture medium of embryonic chick tibiotarsal chondrocytes. This high Mr polypeptide was subsequently shown by two-dimensions l SDS-PAGE and peptide mapping to represent a dimer of the prox1(X) chain of type X collagen linked by disulphide bonding in the non-collagenous domains.

Immunoperoxidase localization of type X collagen in chick tibiae.

Type X collagen was prepared from medium of long-term cultures of embryonic chick tibiotarsal chondrocytes. Antibodies to type X collagen were raised and used in immunoperoxidase localization studies with embryonic and growing chick tibiotarsus. Strong anti-type X collagen reactivity was detected mainly in the region of hypertrophic chondrocytes, and to a lesser extent in the zone of calcified cartilage. No reactivity was detected in the proliferative zone nor the superficial layer of the cartilage growth plate. These results suggest that type X collagen may play a key role in matrix calcification during growth and development of the skeletal system.

Partial characterization of the C-terminal non-collagenous domain (NC1) of collagen type X.

Collagen type X is composed of three identical alpha 1(X) chains of 59 kDa, each containing a triple-helical region of 45 kDa flanked by a short N-terminal sequence and a larger non-collagenous C-terminal (NC1) domain of approx. 15 kDa. Collagen type X molecules can associate via their C-termini to form a regular hexagonal lattice in vitro, which in vivo may provide a modified extracellular matrix for the events of endochondral ossification. The NC1 domain of chick collagen type X was isolated and purified from a highly purified bacterial collagenase digest of hypertrophic chondrocyte medium proteins. The structure and aggregation properties of the NC1 domain of collagen X were investigated, independently of the triple helix. A trimer, a dimer and a monomer of the individual alpha-chain NC1 polypeptides were identified from a bacterial collagenase digest of cartilage collagens using [14C]tyrosine labelling, N-chlorosuccinimide peptide mapping and N-terminal sequencing. The trimer (50 kDa) remained intact in Laemmli sample buffer unless boiled, upon which it dissociated into the dimer (38 kDa) and the monomer (20 kDa). The dimer persisted even after prolonged periods of heating or reduction with beta-mercaptoethanol, and in preparations obtained from chondrocyte cultures treated with beta-aminoproprionitrile, indicating the presence of non-reducible, non-lysine-derived, covalent cross-links. Hexamers of the individual C-termini were observed in rotary-shadowed preparations of purified NC1 domain, reflecting the ability of collagen type X to self-assemble via its C-termini under appropriate conditions.

The biochemical characterization of aggrecan from normal and tibial-dyschondroplastic chicken growth-plate cartilage.

Tibial dyschondroplasia (TD) is a disorder of endochondral ossification characterized by the presence of an avascular, non-mineralized cartilage lesion extending from the growth plate into the metaphysis. Cells within the TD growth plate fail to differentiate to full hypertrophy, and instead appear to maintain a 'pre-hypertrophic' or 'transitional' status. Studies of the expression and distribution of cartilage matrix macromolecules in the TD growth plate have shown a marked decrease in the levels of aggrecan in the TD matrix. In the present study we compared the biochemical characteristics of the aggrecan molecules extracted from normal epiphyseal and TD cartilage. We have shown three major differences between normal and TD cartilage aggrecan. These are: (1) increase in molecular mass; (2) increase in the number of keratan sulphate chains; and (3) difference in the pattern of sulphation in TD aggrecan. Such changes in biochemical characteristics of the aggrecan monomers in TD cartilage may be associated with the lack of mineralization of the diseased cartilage. The present study provides a basis for further investigations into the importance of proteoglycans in normal and pathological bone development.

Human articular surface chondrocytes initiate alkaline phosphatase and type X collagen synthesis in suspension culture.

The type X collagen is a short chain collagen associated with calcific cartilage and/or the expression of the hypertrophic chondrocyte phenotype. In articular cartilage, type X collagen is restricted to the basal zone of calcified cartilage adjacent to the subchondral bone. However, during pathological change such as in osteoarthritis, the synthesis of type X collagen becomes more widespread but never extends to the articular surface. Using immunocytochemistry and fluorography of newly synthesised collagens, we report that surface articular chondrocytes (which occupy the uppermost 10-15% of the tissue depth) from normal human cartilage initiate de novo synthesis of both type X collagen and alkaline phosphatase when maintained in suspension culture.

Expression of type X collagen, Indian hedgehog and parathyroid hormone related-protein in normal and tibial dyschondroplastic chick growth plates.

Tibial dyschondroplasia (TD) is a form of aberrant endochondral ossification in chickens, in that a plug of avascular cartilage (TD lesion) is formed within the growth plate. Histologically, the lesion is filled with apparently transitional chondrocytes that have been unable to differentiate to hypertrophic chondrocytes. We have examined the spatial expression of mRNAs for type X collagen, Indian hedgehog (Ihh) and Parathyroid Hormone-related protein (PTHrP) in the TD growth plate by in situ hybridization in order to ascertain at which stage chondrocyte differentiation is arrested in TD. In the normal growth plate, type X collagen mRNA was expressed by both prehypertrophic and hypertrophic chondrocytes. Indian Hedgehog mRNA was detected in a band of prehypertrophic chondrocytes and PTHrP expression was localized to a narrow band of prehypertrophic chondrocytes and in osteoblasts within the diaphysis. In TD sections, collagen X expression was seen within differentiating cells, within a small number of lesion cells, and within hypertrophic chondrocytes on the diaphyseal side of the lesion. Ihh expression was also seen within the differentiating cells and throughout the lesion. These data indicate that chondrocyte differentiation is arrested at the transitional stage just prior to hypertrophy. Contrary to the previously reported PTHrP expression patterns in TD chicks by immunohistochemistry, PTHrP mRNA was not detected in the TD lesion. This observation probably reflects the cessation of PTHrP gene expression by chondrocytes in the more severe TD lesions. The results from the present study also imply that the arrest of cell differentiation in TD is independent of PTHrP and that endochondral ossification in the post-hatch avian growth plate may involve additional regulatory pathways.

Expression and distribution of cartilage matrix macromolecules in avian tibial dyschondroplasia.

Tibial dyschondroplasia (TD) is a disorder of endochondral ossification characterized by the presence of an avascular, non-mineralized cartilage lesion extending from the growth plate into the metaphysis. Cells within the TD growth plate fail to differentiate to full hypertrophy, and instead appear to maintain a 'pre-hypertrophic' or 'transitional' status. The synthesis and distribution of aggrecan, biglycan, decorin, and collagen types II and X in the growth plates of normal and tibial dyschondroplastic chickens have been investigated using in situ hybridization and immunolocalization. Marked reductions in the amount of aggrecan and biglycan core protein mRNAs were observed in the tibial dyschondroplastic lesion by in situ hybridization. Reduction in mRNA production seemed to be specific to the extracellular matrix components since total mRNA expression showed no significant difference between normal and dyschondroplastic cartilage. In addition, expression of collagen type II and decorin did not differ significantly between normal and TD cartilage. Distribution of aggrecan biglycan, decorin, type II and X collagens were examined using immunohistochemistry. Normal hypertrophic cartilage showed a strong matrix labelling for aggrecan and biglycan. Type X collagen in the normal hypertrophic cartilage showed strong pericellular and matrix distribution, whereas in TD cartilage labelling for aggrecan, biglycan and collagen X was located intracellularly with a very low level of signal in the matrix. In contrast, collagen type II was found to be present throughout the extracellular matrix of both the normal growth plate and the TD lesion, suggesting that the differences observed in aggrecan, biglycan and type X collagen distribution are specific to these proteins and not a general disturbance of matrix macromolecular metabolism. The reduced deposition of these macromolecules may have implications in normal and pathological bone development.

Isolation of cDNAs encoding the complete sequence of bovine type X collagen. Evidence for the condensed nature of mammalian type X collagen genes.

The complete primary structure of the bovine alpha 1(X) collagen chain was determined by nucleotide sequencing of cDNA clones. The overlapping cDNA clones encode 3144 bp with a 5'-terminal untranslated region of 148 bp, a 2025 bp reading frame and a 3'-terminal untranslated region of 971 bp. This represents the first complete sequence of a mammalian type X collagen cDNA and has allowed a number of informative comparisons to be made with the previously published chick alpha 1(X) sequence. The primary translation products of both bovine and chick type X collagen are 674 amino acid residues in length and there is a 73.3% identity at the amino acid level (67.8% at the base level). Sequence analyses reveal that the greatest degree of identity between the two species occurs within the triple-helical domain and the C-terminal non-collagenous domain, whereas the identity within the N-terminal non-collagenous domain is markedly lower. The interchain disulphide-bonding observed previously within the triple helix of bovine type X collagen is explained by the presence of two cysteine residues within an imperfection of the triple-helical domain encoded by -Gly-Xaa-Cys-Xaa-Yaa-Cys-Xaa-Yaa-Gly-. Southern blot analyses of bovine genomic DNA demonstrate that the bovine type X collagen gene is likely to have a condensed structure, similar to that of the chick, with at least 1.3 kb of the coding sequence being contained within one exon.

The reactions of articular cartilage to experimental wounding: role of apoptosis.

OBJECTIVE: To determine the cellular and matrix responses to experimental wounding of articular cartilage. METHODS: Immature and mature bovine articular cartilage was used as an in vitro model system to study the cellular responses to cartilage wounding. Explant cultures were wounded centrally with a trephine and maintained for up to 10 days. TUNEL labeling together with ultrastructural analyses were used to assess the nature of the observed cell death. In vitro labeling with 3H-thymidine was used to detect cell proliferation, and 2 antibodies (COL2-3/4M and BC-13) were used to detect changes in matrix turnover. RESULTS: Cell death was observed as a response to wounding and was considered to be a combination of necrosis and apoptosis. In immature tissue, cell death was more pronounced, particularly in the articular surface region. Within the area of cell death, many cells that did not die subsequently underwent proliferation. The collagenous network showed evidence of denaturation in the area of the wound, but "aggrecanase" activity was not detected. CONCLUSION: There are 2 contrasting, but related, responses to cartilage wounding--apoptosis and proliferation. In order to improve cartilage repair, future studies need to elucidate the regulatory mechanisms that determine these responses.

Type X collagen, a product of hypertrophic chondrocytes.

The synthesis of collagen types IX and X by explants of chick-embryo cartilages was investigated. When sternal cartilage labelled for 24h with [3H]proline was extracted with 4M-guanidinium chloride, up to 20% of the 3H-labelled collagen laid down in the tissue could be accounted for by the low-Mr collagenous polypeptides (H and J chains) of type IX collagen; but no type X collagen could be detected. Explants of tibiotarsal and femoral cartilages were found to synthesize type IX collagen mainly in zones 1 and 2 of chondrocyte proliferation and elongation, whereas type X collagen was shown to be a product of the hypertrophic chondrocytes in zone 3. Pulse-chase experiments with tibiotarsal (zone-3) explants demonstrated a time-dependent conversion of type X procollagen into a smaller species whose polypeptides were of Mr 49 000. The processed chains [alpha 1(X) chains] were shown by peptide mapping techniques to share a common identity with the pro alpha 1(X) chains of Mr 59 000. No evidence for processing of type IX collagen was obtained in analogous pulse-chase experiments with sternal tissue. When chondrocytes from tibiotarsal cartilage (zone 3) were cultured on plastic under standard conditions for 4-10 weeks they released large amounts of type X procollagen into the medium. However, 2M-MgCl2 extracts of the cell layer were found to contain mainly the processed collagen comprising alpha 1(X) chains. The native type X procollagen purified from culture medium was shown by rotary shadowing to occur as a short rod-like molecule 148 nm in length with a terminal globular extension, whereas the processed species comprising alpha 1(X) chains of Mr 49 000 was detected by electron microscopy as the linear 148 nm segment.