Assembly and sequencing of a cDNA covering the entire mouse alpha 1(IX) collagen chain

Characterization of recombinant amino-terminal NC4 domain of human collagen IX: interaction with glycosaminoglycans and cartilage oligomeric matrix protein

The N-terminal NC4 domain of collagen IX is a globular structure projecting away from the surface of the cartilage collagen fibril. Several interactions have been suggested for this domain, reflecting its location and its characteristic high isoelectric point. In an attempt to characterize the NC4 domain in more detail, we set up a prokaryotic expression system to produce the domain. The purified 27.5-kDa product was analyzed for its glycosaminoglycan-binding potential by surface plasmon resonance and solid-state assays. The results show that the NC4 domain of collagen IX specifically binds heparin with a K(d) of 0.6 microm, and the full-length recombinant collagen IX has an even stronger interaction with heparin, with an apparent K(d) of 3.6 nm. The heparin-binding site of the NC4 domain was located in the extreme N terminus, containing a heparin-binding consensus sequence, whereas electron microscopy suggested the presence of at least three additional heparin-binding sites on full-length collagen IX. The NC4 domain was also shown to bind cartilage oligomeric matrix protein. This interaction and the association of cartilage oligomeric matrix protein with other regions of collagen IX were found to be heparin-competitive. Circular dichroism analyses of the NC4 domain indicated the presence of stabilizing disulfide bonds and a thermal denaturation point of about 80 degrees C. The pattern of disulfide bond formation within the NC4 domain was identified by tryptic peptide mass mapping of the NC4 in native and reduced states. A similar pattern was demonstrated for the NC4 domain of full-length recombinant collagen IX.

Characterization of recombinant human type IX collagen. Association of alpha chains into homotrimeric and heterotrimeric molecules

As type IX collagen is a minor cartilage component, it is difficult to purify sufficient amounts of it from tissues or cultured cells to study its structure and function. Also, the conventional pepsin digestion used for fibrillar collagens cannot be utilized for purifying type IX collagen, because it contains several interruptions in its collagenous triple helix. A baculovirus expression system was used here to produce recombinant human type IX collagen by coinfecting insect cells with three viruses containing full-length cDNAs for the alpha1(IX), alpha2(IX), and alpha3(IX) collagen chains together with a double promoter virus for the alpha and beta subunits of human prolyl 4-hydroxylase. Correctly folded recombinant type IX collagen was secreted, consisting of the three alpha chains in a 1:1:1 ratio and showing the expected biphasic thermal melting profile. When the individual alpha chains were expressed, disulfide-bonded homotrimers and homodimers of the alpha chains were observed. When the cells were coinfected with the viruses for all three alpha chains, heterotrimers of alpha1(IX), alpha2(IX), and alpha3(IX) were detected in cell culture medium, and the other possible combinations were less prominent. When any two of the alpha chains were co-expressed, in addition to the homodimers and homotrimers, only alpha1(IX) and alpha3(IX) chains were disulfide-bonded. The results thus suggest that the most favored molecular species is an alpha1(IX)alpha2(IX)alpha3(IX) heterotrimer, but the chains are also able to form disulfide-bonded heterotrimers of alpha1(IX) and alpha3(IX) chains and (alpha1(IX))(3), (alpha2(IX))(3), and (alpha3(IX))(3) homotrimers.

An allele of COL9A2 associated with intervertebral disc disease

Intervertebral disc disease is one of the most common musculoskeletal disorders. A number of environmental and anthropometric risk factors may contribute to it, and recent reports have suggested the importance of genetic factors as well. The COL9A2 gene, which codes for one of the polypeptide chains of collagen IX that is expressed in the intervertebral disc, was screened for sequence variations in individuals with intervertebral disc disease. The analysis identified a putative disease-causing sequence variation that converted a codon for glutamine to one for tryptophan in six out of the 157 individuals but in none of 174 controls. The tryptophan allele cosegregated with the disease phenotype in the four families studied, giving a lod score (logarithm of odds ratio) for linkage of 4.5, and subsequent linkage disequilibrium analysis conditional on linkage gave an additional lod score of 7.1.