Human alpha 3(VI) collagen gene. Characterization of exons coding for the amino-terminal globular domain and alternative splicing in normal and tumor cells

We recently reported the isolation and sequencing of human cDNA clones corresponding to the alpha 3 chain of type VI collagen (Chu, M.-L., Zhang, R.-Z., Pan, T.-c., Stokes, D., Conway, D., Kuo, H.-J., Glanville, R., Mayer, U., Mann, K., Deutzmann, R., and Timpl, R. (1990) EMBO J. 9, 385-393). The study indicates that the amino-terminal globular domain of the alpha 3(VI) chain consists of nine repetitive subdomains of approximately 200 amino acid residues (N1-N9) and the gene appeared to undergo alternative splicing since some clones lacked regions encoding the N9 and part of the N3 subdomains. In the present study, we report the exon structure for the region encoding the amino-terminal globular domain of the human alpha 3(VI) chain. The nine repetitive subdomains are encoded by 10 exons spanning 26 kilobase pairs of genomic DNA. Eight of the repetitive subdomains (N2-N9) were found to be encoded by separate exons of approximately 600 base pairs each. The only exception is the N1 subdomain which is encoded by two exons of 417 and 146 base pairs. Characterization of the exon/intron structure showed that the cDNA variants were the result of splicing out of exon 9 (encoding the N9 subdomain) and part of exon 3 (encoding the N3 subdomain). Nuclease S1 analysis and the polymerase chain reaction demonstrated that exon 7 (N7 subdomain) was also subject to alternative splicing in normal skin fibroblasts. Examination of these splicing events by nuclease S1 analysis in normal fibroblasts, three different human tumor cell lines, and several human tissues showed that splicing out of exon 9 is much more efficient in normal as compared to tumor cells.     

The exon organization of the triple-helical coding regions of the human alpha 1(VI) and alpha 2(VI) collagen genes is highly similar.

The alpha 1(VI) and alpha 2(VI) chains, two of the three constituent chains of type VI collagen, are highly similar in size and domain structure. They are encoded by single-copy genes residing in close proximity on human chromosome 21. To study the evolution of the type VI collagen genes, we have isolated and characterized genomic clones coding for the triple-helical domains of the human alpha 1(VI) and alpha 2(VI) chains, which consist of 336 and 335 amino acid residues, respectively. Nucleotide sequencing indicates that, in both genes, the exons are multiples of 9 bp in length (including 27, 36, 45, 54, 63, and 90 bp) except for those encoding for regions with triple-helical interruptions. In addition, the introns are positioned between complete codons. The most predominant exon size is 63 bp, instead of 54 bp as seen in the fibrillar collagen genes. Of particular interest is the finding that the exon structures of the alpha 1(VI) and alpha 2(VI) genes are almost identical. A significant deviation is that a segment of 30 amino acid residues is encoded by two exons of 54 and 36 bp in the alpha 1(VI) gene, but by a single exon of 90 bp in the alpha 2(VI) gene. The exon arrangement therefore provides further evidence that the two genes have evolved from tandem gene duplication. Furthermore, comparison with the previously reported gene structure of the chick alpha 2(VI) chain indicates that the exon structure for the triple-helical domain of the alpha 2(VI) collagen is strictly conserved between human and chicken.     

A heterozygous splice site mutation in COL6A1 leading to an in-frame deletion of the alpha1(VI) collagen chain in an italian family affected by bethlem myopathy.

Bethlem myopathy is a mild neuromuscular disorder with proximal muscular weakness and early flexion contractures. It is an autosomal dominant disease due to mutations in type VI collagen genes. We found a T-->C substitution at the +2 position of COL6A1 intron 14 in a family, leading to skipping of exon 14 and an in-frame deletion of 18 amino acids in the triple-helical domain of the alpha1(VI) collagen chain. The deletion included a cysteine residue believed to be involved in the assembly of type VI collagen dimers intracellularly, prior to the protein secretion. Analysis of the affected fibroblasts showed that the shortened alpha1(VI) collagen chains were synthesized but not secreted by the cells and that the amount of type VI collagen microfibrils deposited by the cells was reduced. The results suggest that the clinical phenotype is due to a reduction in the level of type VI collagen in the extracellular matrix.     

Type II collagen mRNA containing an alternatively spliced exon predominates in the chick limb prior to chondrogenesis.

A series of cDNA clones corresponding to the 5' end of the chicken type II collagen mRNA were generated using a single-sided polymerase chain reaction technique. Analysis of these cDNAs showed that the second exon of the gene is alternatively spliced such that it is either present or absent in the mRNA. This exon encodes a 70-amino acid cysteine-rich globular domain which is present in the amino-terminal propeptides of alpha 1(I), alpha 1(III), and alpha 2(V) procollagen chains but which was previously thought to be absent from type II procollagen. Analysis of the expression of the two alternatively spliced forms of the chicken type II collagen mRNA showed that the mRNA without the second exon was the predominant form (approximately 90%) in sternal cartilage from 14-day embryos, but in precartilage limb mesenchyme only the form including the second exon was detected. This later form was also present in a number of non-cartilage tissues including embryonic calvaria, skin, heart, skeletal muscle, and brain; no type II collagen mRNA was detected in liver. Studies of developing limbs from progressive embryonic stages suggest that the appearance of the mRNA lacking the second exon is a relatively late event during chondrogenesis.     

Identification and partial purification of a large, variant form of type XII collagen.

A large, alternate form of type XII collagen has been identified in cultures of the human epidermoid cell line WISH. This form, designated XIIA, is comprised of alpha chains that are approximately 90 kDa larger than the 220-kDa alpha chain previously characterized in extracts of fetal chicken and bovine tissues. Results from both collagenase digestion and rotary shadow analysis of partially purified material show that the increase is due to a larger NC3 domain. While both the large (XIIA) and the small (XIIB) forms of type XII collagen are identified in pulse-chase radiolabeling of fetal bovine skin explant culture, they are not related in a precursor-product fashion. Inhibition studies with alpha, alpha'-dipyridyl indicate that proper folding of the collagen helix is required for complete assembly and secretion of type XIIA in WISH cell culture. The 310-kDa alpha 1A chain is likely to represent the bovine equivalent of a second translation product, estimated to be 340 kDa, predicted from analysis of one complete chick cDNA sequence. Additionally, the amino-terminal amino acid sequence of the 220-kDa bovine alpha 1B chain was determined. This sequence is very near a potential alternate splice site predicted from analysis of chicken type XII cDNA.     

Three novel collagen VI chains with high homology to the alpha3 chain

Here we describe three novel collagen VI chains, alpha4, alpha5, and alpha6. The corresponding genes are arranged in tandem on mouse chromosome 9. The new chains structurally resemble the collagen VI alpha3 chain. Each chain consists of seven von Willebrand factor A domains followed by a collagenous domain, two C-terminal von Willebrand factor A domains, and a unique domain. In addition, the collagen VI alpha4 chain carries a Kunitz domain at the C terminus, whereas the collagen VI alpha5 chain contains an additional von Willebrand factor A domain and a unique domain. The size of the collagenous domains and the position of the structurally important cysteine residues within these domains are identical between the collagen VI alpha3, alpha4, alpha5, and alpha6 chains. In mouse, the new chains are found in or close to basement membranes. Collagen VI alpha1 chain-deficient mice lack expression of the new collagen VI chains implicating that the new chains may substitute for the alpha3 chain, probably forming alpha1alpha2alpha4, alpha1alpha2alpha5, or alpha1alpha2alpha6 heterotrimers. Due to a large scale pericentric inversion, the human COL6A4 gene on chromosome 3 was broken into two pieces and became a non-processed pseudogene. Recently COL6A5 was linked to atopic dermatitis and designated COL29A1. The identification of novel collagen VI chains carries implications for the etiology of atopic dermatitis as well as Bethlem myopathy and Ullrich congenital muscular dystrophy.     

The effects of different cysteine for glycine substitutions within alpha 2(I) chains. Evidence of distinct structural domains within the type I collagen triple helix

Affected individuals from two apparently distinct, mild osteogenesis imperfecta families were heterozygous for a G to T transition in the COL1A2 gene that resulted in cysteine for glycine substitutions at position 646 in the alpha 2(I) chain of type I collagen. A child with a moderately severe form of osteogenesis imperfecta was heterozygous for a G to T transition that resulted in a substitution of cysteine for glycine at position 259 in the COL1A2 gene. Type I collagen molecules containing an alpha 2(I) chain with cysteine at position 259 denaturated at a lower temperature than molecules containing an alpha 2(I) chain with cysteine at position 646. In contrast to cysteine for glycine substitutions in the alpha 1(I) chain, the severity of the osteogenesis imperfecta phenotype is not directly proportional to the distance of the mutation from the amino-terminal end of the triple helix. These findings could be explained if the type I collagen triple helix contains discontinuous domains that differ in their contributions to maintaining helix stability.     

Bethlem myopathy and engineered collagen VI triple helical deletions prevent intracellular multimer assembly and protein secretion.

Mutations in the genes that code for collagen VI subunits, COL6A1, COL6A2, and COL6A3, are the cause of the autosomal dominant disorder, Bethlem myopathy. Although three different collagen VI structural mutations have previously been reported, the effect of these mutations on collagen VI assembly, structure, and function is currently unknown. We have characterized a new Bethlem myopathy mutation that results in skipping of COL6A1 exon 14 during pre-mRNA splicing and the deletion of 18 amino acids from the triple helical domain of the alpha1(VI) chain. Sequencing of genomic DNA identified a G to A transition in the +1 position of the splice donor site of intron 14 in one allele. The mutant alpha1(VI) chains associated intracellularly with alpha2(VI) and alpha3(VI) to form disulfide-bonded monomers, but further assembly into dimers and tetramers was prevented, and molecules containing the mutant chain were not secreted. This triple helical deletion thus resulted in production of half the normal amount of collagen VI. To further explore the biosynthetic consequences of collagen VI triple helical deletions, an alpha3(VI) cDNA expression construct containing a 202-amino acid deletion within the triple helix was produced and stably expressed in SaOS-2 cells. The transfected mutant alpha3(VI) chains associated with endogenous alpha1(VI) and alpha2(VI) to form collagen VI monomers, but dimers and tetramers did not form and the mutant-containing molecules were not secreted. Thus, deletions within the triple helical region of both the alpha1(VI) and alpha3(VI) chains can prevent intracellular dimer and tetramer assembly and secretion. These results provide the first evidence of the biosynthetic consequences of structural collagen VI mutations and suggest that functional protein haploinsufficiency may be a common pathogenic mechanism in Bethlem myopathy.     

Stable expression of chicken type-VI collagen alpha 1, alpha 2 and alpha 3 cDNAs in murine NIH/3T3 cells.

As a component of an extensive network of microfibrils interwoven with large collagen fibers and in close contact with cell surfaces, type VI collagen plays an important role in cell-matrix interactions. To investigate the behaviour of chicken type VI collagen chains in heterologous host cells as a means to understanding the pattern of assembly of this collagen, we transfected murine NIH/3T3 cells with cDNAs encoding chicken alpha 1(VI), alpha 2(VI) and alpha 3(VI) chains. Cell lines that constitutively expressed the individual chains were analyzed by metabolic labeling and immunoprecipitation with specific antibodies. No self-association was observed for either alpha 1(VI) or alpha 2(VI) chains which were secreted as monomeric polypeptides. Furthermore, neither the chicken alpha 1(VI) nor alpha 2(VI) chains associated with the endogenous murine chains to form chimeric chicken/murine heterotrimers. In contrast, chimeric chicken/murine heterotrimers were detected in cell lines transfected with chicken alpha 3(VI) cDNA. These chimeric forms appeared to be properly aligned since their triple helices were stable to pepsin digestion. In addition, the chimeric heterotrimers coassembled and gave rise to disulfide-linked type VI collagen molecules.     

A base substitution at the splice acceptor site of intron 5 of the COL1A2 gene activates a cryptic splice site within exon 6 and generates abnormal type I procollagen in a patient with Ehlers-Danlos syndrome type VII.

The dermal type I collagen of a patient with Ehlers-Danlos type VIIB (EDS-VIIB) contained normal alpha 2(I) chains and mutant pN-alpha 2(I)' chains in which the amino-terminal propeptide (N-propeptide) remained attached to the alpha 2(I) chain. Similar alpha 2(I) chains were produced by cultured dermal fibroblasts. Amino acid sequencing of tryptic peptides, prepared from the mutant amino-terminal pN-alpha 2(I) CB1' peptide, indicated that five amino acids, including the N-proteinase (the specific proteinase that cleaves the procollagen N-propeptide) cleavage site, had been deleted from the junction of the N-propeptide and the N-telopeptide (the nonhelical domain at the amino-terminus of the alpha chains of fully processed type I polypeptide chains) of the mutant pro-alpha 2(I)' chain. The corresponding 15 nucleotides, which were deleted from approximately half of the alpha 2(I) cDNA polymerase chain reaction products, of the alpha 2(I) cDNA polymerase chain reaction products, were encoded by the +1 to +15 nucleotides of exon 6 of the normal alpha 2(I) gene (COL1A2). These 15 nucleotides were deleted in the splicing of alpha 2(I) pre-mRNA to mRNA as a result of inactivation of the 3' splice site of intron 5 by an AG to AC mutation and the activation of a cryptic AG splice acceptor site corresponding to positions +14 and +15 of exon 6. Loss of the N-proteinase cleavage site explained the persistence of the pN-alpha 2(I)' chains in the dermis and in fibroblast cultures. Collagen production by cultured dermal fibroblasts was doubled, possibly due to reduced feedback inhibition by the N-propeptides. In contrast to previously reported cases of EDS-VIIB, Lys5 of the N-telopeptide was not deleted and appeared to take part in the formation of intramolecular cross-linkages. However, increased collagen solubility and abnormal extraction profiles of the mutant type I collagen molecules indicated that collagen cross-linking was abnormal in the dermis. The proband and her son were heterozygous for the mutation. It is likely that the heterozygous loss of the N-proteinase cleavage site, with persistence of a shortened N-propeptide, was the major factor responsible for the EDS-VIIB phenotype.     

Human COL6A1: Genomic characterization of the globular domains, structural and evolutionary comparison with COL6A2

The α1(VI) and α2(VI) chains of type VI collagen (nonfibrillar) are highly similar and are encoded by single-copy genes in close proximity on human Chromosome (Chr) 21q22.3, a gene-rich region that has proved refractory to cloning. For the α1(VI) chain, only the regions encoding the triple-helical and the promoter have been characterized hitherto. To facilitate our study of the role of this gene in the phenotype of Down syndrome, we have cloned and sequenced the amino- and carboxyl-terminal globular domains of COL6A1. The amino-terminal domain consists of seven exons and the carboxyl-terminal globular domain of nine exons. Together with the exons of the triple-helical domain, COL6A1 is encoded by a total of 36 exons spanning approximately 30 kb. Comparison of the genomic organization of COL6A1 and COL6A2 revealed that despite the similarity within their triple-helical domains, the intron-exon structures of their globular domains differ markedly. Conservation is limited to the exons encoding amino acids immediately adjacent to the triple-helical region, including the cysteine residues essential for the structure of mature collagen VI. The intron-exon structures of these two genes are highly similar to the collagen VI genes of chicken. These data suggest that COL6A1 and COL6A2 arose from a gene duplication before the divergence of the reptilian and mammalian lineages. Received: 9 November 1996 / Accepted: 28 December 1996     

The C5 domain of Col6A3 is cleaved off from the Col6 fibrils immediately after secretion.

In articular cartilage, type VI collagen is concentrated in the pericellular matrix compartment. During protein synthesis and processing at least the alpha3(VI) chain undergoes significant posttranslational modification and cleavage. In this study, we investigated the processing of type VI collagen in articular cartilage. Immunostaining with a specific polyclonal antiserum against the C5 domain of alpha3(VI) showed strong cellular staining seen in nearly all chondrocytes of articular cartilage. Confocal laser-scanning microscopy and immunoelectron microscopy allowed localization of this staining mainly to the cytoplasm and the immediate pericellular matrix. Double-labeling experiments showed a narrow overlap of the C5 domain and the pericellular mature type VI collagen. Our results suggest that at least in human adult articular cartilage the C5 domain of alpha3(VI) collagen is synthesized and initially incorporated into the newly formed type VI collagen fibrils, but immediately after secretion is cut off and is not present in the mature pericellular type VI matrix of articular cartilage.