Isolation of bovine type X collagen and immunolocalization in growth-plate cartilage.

The accessibility of the cysteine residues of actin from rabbit muscles to the thiol-targeted reagent 7-dimethylamino-4-methyl-(N-maleimidyl)coumarin (DACM) was investigated. Under conditions where the actin is in the unpolymerized form (G-actin), the most reactive thiol group was Cys-257, suggesting that it was located on the surface of the actin molecule. The selective modification of Cys-374 for this reagent as reported by Sutoh [(1982) Biochemistry 21, 3654-3661] was not observed. Cys-10, Cys-217 and Cys-374 were much less reactive and only gradually became extensively modified when the concentration of DACM approached 5 molar equivalents of actin. Presumably these thiol groups were located further inward away from the surface or situated in a different environment that rendered them less reactive. On the other hand, Cys-285 was completely inaccessible and presumably was buried. The lack of preferential labelling of Cys-374 by DACM is incompatible with the finding with iodoacetic acid as the reagent as reported by Elzinga & Collins [(1975) J. Biol. Chem. 250, 5897-5905]. This discrepancy, however, might well be due to the different reagents employed. The DACM-G-actin largely retained its competence for polymerization. Upon polymerization of G-actin, practically all the thiol groups became inaccessible to DACM, suggesting that a drastic change occurred in the conformation of actin units in the transition of monomers to filamentous actin.     

Localization of collagen X in human fetal and juvenile articular cartilage and bone

The tissue localization was analysed of collagen X during human fetal and juvenile articular cartilagebone metamorphosis. This unique collagen type was found in the hypertrophic cartilage zone peri- and extracellularly and in cartilage residues within bone trabeculae. In addition, occasionally a slight intracellular staining reaction was found in prehypertrophic proliferating chondrocytes and in chondrocytes surrounding vascular channels. A slight staining was also seen in the zone of periosteal ossification and occasionally at the transition zone of the perichondrium to resting cartilage. Our data provide evidence that the appearance of collagen X is mainly associated with cartilage hypertrophy, analogous to the reported tissue distribution of this collagen type in animals. In addition, we observed an increased and often spotty distribution of collagen X with increasing cartilage degeneration associated with the closure of the growth plate. In basal hypertrophic cartilage areas, a co-distribution of collagens II and X was found with very little and spotty collagen III. In juvenile cartilage areas around single hypertrophic chondrocytes, co-localization of collagens X and I was also detected.     

Localization of collagen X in human fetal and juvenile articular cartilage and bone.

The tissue localization was analysed of collagen X during human fetal and juvenile articular cartilage-bone metamorphosis. This unique collagen type was found in the hypertrophic cartilage zone peri- and extracellularly and in cartilage residues within bone trabeculae. In addition, occasionally a slight intracellular staining reaction was found in prehypertrophic proliferating chondrocytes and in chondrocytes surrounding vascular channels. A slight staining was also seen in the zone of periosteal ossification and occasionally at the transition zone of the perichondrium to resting cartilage. Our data provide evidence that the appearance of collagen X is mainly associated with cartilage hypertrophy, analogous to the reported tissue distribution of this collagen type in animals. In addition, we observed an increased and often "spotty" distribution of collagen X with increasing cartilage "degeneration" associated with the closure of the growth plate. In basal hypertrophic cartilage areas, a co-distribution of collagens II and X was found with very little and "spotty" collagen III. In juvenile cartilage areas around single hypertrophic chondrocytes, co-localization of collagens X and I was also detected.     

Immunolocalization of type X collagen before and after mineralization of human thyroid cartilage

In this study the distribution of type X collagen in thyroid cartilages of various ages is described. Fetal and juvenile thyroid cartilage was negative for type X collagen, but showed a strong staining reaction for type II collagen. Type X collagen and calcium deposition were first detected in thyroid cartilage of 18-to 21-year-old adults. Type X collagen was restricted to large chondrocytes near or in mineralized cartilage, confirming the notion that type X collagen precedes mineralization. From these observations it was concluded that chondrocytes in thyroid cartilage undergo differentiation steps that are similar, but much slower, compared to cells in growth plate and sternal cartilage. Some type X collagen-positive areas also showed staining for type I collagen, suggesting that there is a further differentiation of chondrocytes to cells which are characterized by the simultaneous synthesis of type X and I collagen. However, a dedifferentiation process during aging of thyroid cartilage where cells switch from synthesis of type II to type I collagen cannot be excluded.     

Deposition of type X collagen in the cartilage extracellular matrix

In cultured chick embryo chondrocytes, type X collagen is preferentially deposited in the extracellular matrix, the ratio between type II and type X collagen being about 5 times higher in the culture medium than in the cell layer. When the newly synthesized collagens deposited in slices from the epiphyseal cartilage of 17-day-old embryo tibiae were isolated, type X collagen was always the major species. In agreement with this result the mRNA for type X collagen was the predominant mRNA species purified from the same tissue. When the total collagen (unlabeled) deposited in the epiphyseal cartilage was analyzed, it was observed that type X collagen represented only 1/15 of the type II collagen recovered in the same preparation. The possible explanations for these differences are discussed.     

The structure of human collagen type IX and its organization in fetal and infant cartilage fibrils

Human collagen type IX was isolated from the media of organ cultures of fetal or infant hyaline cartilage. It consisted of three distinct, disulfide-bonded polypeptides of 115, 84, and 72 kDa, respectively. Digestion with chondroitinase ABC reduced the apparent molecular mass of the 115-kDa chain to about 65 kDa demonstrating that also human collagen type IX is a proteoglycan. In the electron microscope, the molecule had a rigid rod-like structure with characteristic kinks and with a globular domain at one end. Digestion of human collagen type IX with pepsin leads to somewhat heterogeneous fragments. Affinity-purified antibodies to the mixture of fragments specifically reacted with the fragment HMW without cross-reaction with chicken HMW. LMW of both species were recognized to the same low extent. Mechanically generated fibril fragments from human fetal cartilage were heterogeneous in diameter. Significantly, they could be immunostained for collagen type IX in a D-periodic pattern and regardless of the fibril diameter. Some fibrils were poorly labeled, again independently of the diameter. Therefore, the role of collagen type IX in cartilage probably is not to control directly the lateral growth during fibrillogenesis but rather to stabilize the fibril network.     

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.     

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.     

Areas of asbestoid (amianthoid) fibers in human thyroid cartilage characterized by immunolocalization of collagen types I,II, IX,XI and X

The distribution of type I, II, IX, XI and X collagens in and close to areas of asbestoid (amianthoid) fibers in thyroid cartilages of various ages was investigated in this study. Asbestoid fibers were first detected in thyroid cartilage from a 3-year-old male child. Areas of asbestoid fibers functionally appear to serve as guide rails for vascularization of thyroid cartilage. Alcian blue staining in the presence of 0.3 M MgCl₂ revealed a loss of glycosaminoglycans in areas of asbestoid fibers. In addition, the fibers reacted positively with antibodies against collagen types II, IX and XI, but showed no staining with antibodies to collagen types I and X. Territorial matrix of adjacent chondrocytes showed the same staining pattern. In addition to staining for type II, IX and XI collagens, asbestoid fibers showed strong immunostaining for type I collagen after puberty but not for type X collagen. However, groups of chondrocytes within areas of asbestoid fibers reacted strongly with antibodies to type X collagen, suggesting that this collagen plays an important role in matrix of highly differentiated chondrocytes. The finding that these type X collagen-positive chondrocytes also revealed immunostaining for type I collagen confirms previous studies showing that hypertrophic chondrocytes can further differentiate into cells that are characterized by the synthesis of type X and I collagens.     

Two-dimensional peptide mapping of cross-linked type IX collagen in human cartilage

Type IX collagen is a quantitatively minor component of hyaline cartilage that is essential for the normal structural integrity of the tissue. Purification and analysis are difficult because the mature protein is insoluble as a cross-linked integral component of the fibrillar matrix. In order to view a peptide map of the total pool of type IX collagen in a cartilage sample, a selective method based on Western blot analysis was developed for displaying collagen IX peptides in a cyanogen bromide digest of tissue. Digests were partially resolved by reverse-phase HPLC, individual fractions were run on SDS-PAGE and then transblotted to membrane, and the collagen IX fragments were revealed using an anti-collagen IX rabbit antiserum. All major CB-peptides from alpha1(IX), alpha2(IX), and alpha3(IX) chains in the resulting two-dimensional display were identified by amino-terminal sequence analysis. Cross-linked peptides originating from sites of covalent interaction between collagen types IX and II and between IX and IX were also defined. By comparison with an analysis of soluble type IX collagen from chondrocyte culture medium, the results showed that the pool of type IX collagen molecules in fetal and adult human cartilage is extensively cross-linked intermolecularly at sites previously revealed by other methods using purified protein. This sensitive, direct method has the potential to screen for abnormalities in the content and properties of type IX collagen in tissue samples, for example, in the study of heritable chondrodysplasia syndromes and the pathogenesis of cartilage destruction in osteoarthritis.     

Expression of collagen type I,II, X and Ki-67 in osteochondroma compared to human growth plate cartilage

In order to characterize the consequences for the process of endochondral ossification we performed an immunohistochemical study and compared the expression of collagen type I, II and X as markers of cartilage differentiation and Ki-67 as a marker of cell proliferation in solitary (7-26 years, n=9) and multiple (11-42 years, n=6) osteochondromas with their expression in human fetal and postnatal growth plates. In fetal and young postnatal controls, we found a thin superficial layer of articular cartilage that stained positive for collagen type I while collagen II was expressed in the rest of the cartilage and collagen type X was restricted to the hypertrophic zone. Osteochondromas from children showed lobular collagen type II-positive areas surrounded by collagen type I. In adults, the separation of collagen type I- and type II-positive areas was more blurred, or the cartilaginous cap was missing. Collagen type X was detected in a pericellular distribution pattern within hypertrophic zones but also deeper between bone trabecula. The proliferative activity of osteochondromas from children younger than 14 years of age was comparable to postnatal growth plates, whereas in cartilage from individuals older than 14 years of age, we could not detect significant proliferative activity.     

Immunohistochemical localization of short chain cartilage collagen (type X) in avian tissues

Monoclonal antibodies were produced against the recently described short chain cartilage collagen (type X collagen), and one (AC9) was extensively characterized and used for immunohistochemical localization studies on chick tissues. By competition enzyme-linked immunosorbent assay, antibody AC9 was observed to bind to an epitope within the helical domain of type X collagen and did not react with the other collagen types tested, including the minor cartilage collagens 1 alpha, 2 alpha, 3 alpha, and HMW-LMW. Indirect immunofluorescence analyses with this antibody were performed on unfixed cryostat sections from various skeletal and nonskeletal tissues. Only those of skeletal origin showed detectable reactivity. Within the cartilage portion of the 13-d-old embryonic tibiotarsus (a developing long bone) fluorescence was observed only in that region of the diaphysis containing hypertrophic chondrocytes. None was detectable in adjacent regions or in the epiphysis. Slight fluorescence was also present within the surrounding sleeve of periosteal bone. Consistent with these results, the antibody did not react with the cartilages of the trachea and sclera, which do not undergo hypertrophy during the stages examined. It did, however, lightly react with the parietal bones of the head, which form by intramembranous ossification. These results are consistent with our earlier biochemical analyses, which showed type X collagen to be a product of that subpopulation of chondrocytes that have undergone hypertrophy. In addition, either it or an immunologically cross-reactive molecule is also present in bone, and exhibits a diminished fluorescent intensity as compared with hypertrophic cartilage.     

Immunoelectron microscopy of type X collagen: supramolecular forms within embryonic chick cartilage

To determine the supramolecular forms in which avian type X collagen molecules assemble within the matrix of hypertrophic cartilage, we performed immunoelectron microscopy with colloidal gold-labeled monoclonal antibodies. In addition double-labeled analyses were performed for the molecule and type II collagen, employing two monoclonal antibodies attached to different size gold particles. Both in situ limb cartilages and the extracellular matrix of chondrocyte cultures were examined. We observed in both systems that the type X collagen is present in two forms. One is as fine filaments (less than 5 nm in diameter) within mats which are found predominantly in the pericellular matrix of the hypertrophic chondrocytes. The second form is in association with the fibrils (10-20 nm in diameter) which also react with the antibody for type II collagen. It seems that the filamentous mats represent a form in which the type X collagen is initially secreted from the cell. The type X associated with the striated fibrils most likely represents a secondary association of the molecule with preexisting type II/IX/XI fibrils. The data are consistent with our previously proposed hypothesis that type X collagen is involved in, and perhaps even "targets," certain matrix components for degradation and removal.     

Cloning of the human and mouse type X collagen genes and mapping of the mouse type X collagen gene to chromosome 10.

Type X collagen, a homotrimer of alpha 1 (X) polypeptide chains, is specifically expressed by hypertrophic chondrocytes in regions of cartilage undergoing endochondral ossification. We have previously described the isolation of a small fragment of the human type X collagen gene (COL10A1) and its localization to the q21-q22 region of human chromosome 6 [Apte, S., Mattei, M.-G. & Olsen, B. R. (1991) FEBS Lett. 282, 393-396]. Using this fragment as a probe to screen genomic libraries, we report here the isolation of human and mouse genomic clones which contain the major part of the human and mouse type X collagen genes. In both species, the 14-kb genomic clones which were isolated contain a long open reading frame (greater than 2000 bp in length) which codes for the entire C-terminal non-collagenous (NC1) domain, the entire collagenous (COL) domain and part of the N-terminal non-collagenous (NC2) domain of the alpha 1(X) collagen chain. The human genomic clone contains the major part of the COL10A1 gene, in addition to the region we have previously cloned, and is highly similar to the corresponding portions of the mouse genomic clone (84.5% similarity at the nucleotide level, and 86.1% at the level of the conceptual translation product). The identification of the mouse genomic clone as the alpha 1(X) collagen gene (Col10a1) was confirmed by in situ hybridization of a fragment of the mouse genomic clone to sections from newborn mice. Hybridization was restricted to the hypertrophic chondrocytes of developing chondroepiphyses, being absent in small chondrocytes and in other tissues. Using interspecific backcross analysis, the locus for the mouse alpha 1 (X) collagen gene was assigned to chromosome 10. The cloning and chromosomal mapping of the human and mouse alpha 1 (X) collagen genes now permit the investigation of the possible role of type X collagen gene defects in the genesis of chondrodysplasias in both species and provide data essential for the generation of transgenic mice deficient in type X collagen.     

Purification and characterization of the low-molecular-mass (type X) collagen from chick-embryo tibial cartilage

Type X collagen, synthesized in large amount by cultured tibial chondrocytes, is deposited in vivo in the epiphyseal cartilages of 17-day-old chick embryo tibiae. Here we report the extraction of this collagen from these cartilages by limited pepsin digestion and its purification to electrophoretic homogeneity by salt precipitation followed by agarose gel filtration. Identity of the collagen purified from cartilage with the type X collagen synthesized by cultured chondrocytes is confirmed by comparison of the amino acid compositions. The high glycosylation extent of type X collagen is reminiscent of the glycosylation extent of pericellular collagens. The possible role of type X collagen is discussed.     

Type X collagen expression in osteoarthritic and rheumatoid articular cartilage

Type X collagen is a short chain, non-fibrilforming collagen synthesized primarily by hypertrophic chondrocytes in the growth plate of fetal cartilage. Previously, we have also identified type X collagen in the extracellular matrix of fibrillated, osteoarthritic but not in normal articular cartilage using biochemical and immunohistochemical techniques (von der Mark et al. 1992 a). Here we compare the expression of type X with types I and II collagen in normal and degenerate human articular cartilage by in situ hybridization. Signals for cytoplasmic α1(X) collagen mRNA were not detectable in sections of healthy adult articular cartilage, but few specimens of osteoarthritic articular cartilage showed moderate expression of type X collagen in deep zones, but not in the upper fibrillated zone where type X collagen was detected by immunofluorescence. This apparent discrepancy may be explained by the relatively short phases of type X collagen gene activity in osteoarthritis and the short mRNA half-life compared with the longer half-life of the type X collagen protein. At sites of newly formed osteophytic and repair cartilage, α1(X) mRNA was strongly expressed in hypertrophic cells, marking the areas of endochondral bone formation. As in hypertrophic chondrocytes in the proliferative zone of fetal cartilage, type X collagen expression was also associated with strong type II collagen expression.     

Uncalcified cartilage resorption in human fetal cartilage canals

In the human fetus, epiphyses appear as a solid avascular cartilaginous mass until the eleventh week of development. Around the third fetal month of development, vascular canals coming from the perichondrium are recognized in the mineralized epiphyseal cartilage. Whether cartilage canals develop by passive inclusion or active chondrolysis is still a matter of controversy. We studied the relationships between the intracanalar cells and the surrounding matrix on human fetal epiphyses embedded in glycol methacrylate. At the blind end of canals both stellate fibroblast-like cells and vacuolated macrophages are observed. These cellular foci show all characteristics of active chondrolysis (loss of metachromasia, lacunae containing cells intimately associated with matrix, and presence of granular debris). Similar resorptive foci have been observed in the pannus of rheumatoid joints and in the embryonic chick growth plate composed of uncalcified cartilage. A cellular cooperation (fibroblast/macrophage) is necessary for uncalcified cartilage breakdown. In the human fetus, monocytes/macrophages have been recognized in the peripheral blood as early as the twelfth week of gestation. Our observations support the view that chondrolysis due to both fibroblasts (of mesenchymal origin) and macrophages is the basic mechanism for cartilage canal development.     

Domains of type X collagen: alteration of cartilage matrix by fibril association and proteoglycan accumulation

During endochondral bone formation, hypertrophic cartilage is replaced by bone or by a marrow cavity. The matrix of hypertrophic cartilage contains at least one tissue-specific component, type X collagen. Structurally type X collagen contains both a collagenous domain and a COOH-terminal non-collagenous one. However, the function(s) of this molecule have remained largely speculative. To examine the behavior and functions of type X collagen within hypertrophic cartilage, we (Chen, Q., E. Gibney, J. M. Fitch, C. Linsenmayer, T. M. Schmid, and T. F. Linsenmayer. 1990. Proc. Natl. Acad. Sci. USA. 87:8046-8050) recently devised an in vitro system in which exogenous type X collagen rapidly (15 min to several hours) moves into non-hypertrophic cartilage. There the molecule becomes associated with preexisting cartilage collagen fibrils. In the present investigation, we find that the isolated collagenous domain of type X collagen is sufficient for its association with fibrils. Furthermore, when non-hypertrophic cartilage is incubated for a longer time (overnight) with "intact" type X collagen, the molecule is found both in the matrix and inside of the chondrocytes. The properties of the matrix of such type X collagen-infiltrated cartilage become altered. Such changes include: (a) antigenic masking of type X collagen by proteoglycans; (b) loss of the permissiveness for further infiltration by type X collagen; and (c) enhanced accumulation of proteoglycans. Some of these changes are dependent on the presence of the COOH-terminal non-collagenous domain of the molecule. In fact, the isolated collagenous domain of type X collagen appears to exert an opposite effect on proteoglycan accumulation, producing a net decrease in their accumulation, particularly of the light form(s) of proteoglycans. Certain of these matrix alterations are similar to ones that have been observed to occur in vivo. This suggests that within hypertrophic cartilage type X collagen has regulatory as well as structural functions, and that these functions are achieved specifically by its two different domains.