Evolution of collagen IV genes from a 54-base pair exon: A role for introns in gene evolution

The exon structure of the collagen IV gene provides a striking example for collagen evolution and the role of introns in gene evolution. Collagen IV, a major component of basement membranes, differs from the fibrillar collagens in that it contains numerous interruptions in the triple helical Gly-X-Y repeat domain. We have characterized all 47 exons in the mouse alpha 2(IV) collagen gene and find two 36-, two 45-, and one 54-bp exons as well as one 99- and three 108-bp exons encoding the Gly-X-Y repeat sequence. All these exons sizes are also found in the fibrillar collagen genes. Strikingly, of the 24 interruption sequences present in the alpha 2-chain of mouse collagen IV, 11 are encoded at the exon/intron borders of the gene, part of one interruption sequence is encoded by an exon of its own, and the remaining interruptions are encoded within the body of exons. In such "fusion exons" the Gly-X-Y encoding domain is also derived from 36-, 45-, or 54-bp sequence elements. These data support the idea that collagen IV genes evolved from a primordial 54-bp coding unit. We furthermore interpret these data to suggest that the interruption sequences in collagen IV may have evolved from introns, presumably by inactivation of splice site signals, following which intronic sequences could have been recruited into exons. We speculated that this mechanism could provide a role for introns in gene evolution in general.     

Structural organization of the gene for the alpha 1 chain of human type IV collagen

The complete exon size and distribution pattern in the gene for the alpha 1 chain of human type IV collagen was determined. Clones covering 145 kilobases (kb) of genomic DNA including 100 kb of the gene itself as well as 25 kb upstream and 20 kb downstream of the gene sequences, respectively, were isolated from lambda phage and cosmid libraries. The overall gene structure was determined by endonuclease restriction mapping and R-loop analyses and all exon sizes by nucleotide sequencing. The characterized clones contained all the coding sequences except for exon 2 whose sequence was determined after its amplification by the polymerase chain reaction. There were four gaps in the intron sequences; the exact size of the gene is unknown. The entire gene is at least 100 kb in size and contains 52 exons whose size distribution is completely different from that of the genes for fibrillar collagens. In the -Gly-X-Y- coding region there are three exons of 99, 90, and 45 base pairs (bp) each and two exons of 27, 36, 42, 51, 54, 63, and 84 bp each. The rest of the exons have sizes between 71 and 192 bp in the collagenous region. About one-half of the -Gly-X-Y- repeat coding exons start with the second base for the codon of glycine, whereas the other half starts (with two exceptions) with a complete glycine codon. The distribution of split versus unsplit codons is uneven in that the first 19 exons of the gene start with a complete codon. The gene contains repetitive sequences in several regions. A 185-nucleotide segment containing 40 copies of CCT flanked by poly(C) and poly(T) sequences was shown to be located adjacent to an exon. The gene has previously been shown to be located head-to-head to the alpha 2(IV) collagen gene at the distal end of the long arm of chromosome 13, such that the first exons of the two genes are separated by as little as 42 bp (P?schl, E., Pollner, R., and Kühn, K. (1988) EMBOJ. 7,2687-2695; Soininen, R., Huotari, M., Hostikka, S. L., Prockop, D. J., and Tryggvason, K. (1988) J. Biol. Chem. 263, 17217-17220). The results demonstrate that the human alpha 1(IV) collagen gene has a structure distinctly different from the genes for fibrillar collagens and also that it is considerably larger than any collagen gene characterized to date.     

Complete primary structure of human collagen alpha 1 (V) chain

Several cDNA clones, encoding prepropeptide of human collagen alpha 1(V) chain, have been isolated. The prepropeptide (1838 amino acids length) of the alpha 1(V) chain was composed of a putative signal peptide, a large NH2-terminal noncollagenous region, a main collagenous region, and a COOH-terminal noncollagenous region. The signal peptide contained many leucine residues. The NH2-terminal noncollagenous region was much larger than those of the other collagens and had a region homologous to the COOH-terminal domain of laminin A chain, but it did not contain a cysteine-rich region that was maintained in the region of the other collagens. This region also contained probable tyrosine sulfation sites, and short collagenous sequences that were interrupted by three noncollagenous segments. The main collagenous region of the alpha 1(V) chain consisted of 338 repeats of Gly-X-Y-triplet. This region had a high degree (82%) of homology with the amino acids of the collagen alpha 1(XI) chain. The COOH-terminal noncollagenous region resembled that of the alpha 1(XI) chain, too, and 8 residues of cysteine that were important for the formation of the triple helix structure of collagens were observed. These results suggest that the alpha 1(V) chain belongs to the fibrillar collagen relative to the alpha 1(XI) chain, but codon usage of the alpha 1(V) cDNA was clearly different from those of the other fibrillar collagens including the alpha 1(XI), while it was similar to type IV collagen. This result supposes a different evolution of the alpha 1(V) gene from those of the other fibrillar collagens.     

Head-to-head arrangement of murine type IV collagen genes

The genes for the two dissimilar subunits of type IV collagen are organized in a head-to-head manner with their translation initiation codons within 874 base pairs. Murine genomic clones which contain portions of both genes have been isolated and characterized. These clones contain the first exon of the alpha 1(IV) chain and the first 3 exons for the alpha 2(IV) chain within a 1.7-kilobase HindIII fragment. The intergenic region appears not to resemble previously described bidirectional promoters. The HindIII fragment is present as a single copy in the mouse genome ruling out the presence of one of these gene fragments as a pseudogene. These findings agree with linkage studies of these two genes and differ from the known organization of human fibrillar collagen genes which have been found to be dispersed within the human genome.     

Genomic organization of the human COL3A1 and COL5A2 genes: COL5A2 has evolved differently than the other minor fibrillar collagen genes.

We report here on the complete structure of the human COL3A1 and COL5A2 genes. Collagens III and V, together with collagens I, II and XI make up the group of fibrillar collagens, all of which share a similar structure and function; however, despite the similar size of the major triple-helical domain, the number of exons coding for the domain differs between the genes for the major fibrillar collagens characterized so far (I, II, and III) and the minor ones (V and XI). The main triple-helical domain being encoded by 49-50 exons, including the junction exons, in the COL5A1, COL11A1 and COL11A2 genes, but by 43-44 exons in the genes for the major fibrillar collagens. Characterization of the genomic structure of the COL3A1 gene confirmed its association with the major fibrillar collagen genes, but surprisingly, the genomic organization of the COL5A2 gene was found to be similar to that of the COL3A1 gene. We also confirmed that the two genes are located in tail-to-tail orientation with an intergenic distance of approximately 22 kb. Phylogenetic analysis suggested that they have evolved from a common ancestor gene. Analysis of the genomic sequences identified a novel single nucleotide polymorphism and a novel dinucleotide repeat. These polymorphisms should be useful for linkage analysis of the Ehlers-Danlos syndrome and related disorders.     

The triple-helical domain of alpha 2(VI) collagen is encoded by 19 short exons that are multiples of 9 base pairs

We have analyzed the structure of the gene coding for the alpha 2(VI) subunit of chicken type VI collagen. The triple-helical domain of this polypeptide is encoded by 19 short exons distributed over 10 kilobase pairs of genomic DNA. These exons begin with the codon for glycine and end with the codon for the Y amino acid of the collagenous triplet Gly-X-Y. The sizes of the exons are integral multiples of 9 base pairs (bp) (27, 36, 45, 54, 63, and 90 bp), the predominant one being 63 bp. The organization of this type VI collagen gene is therefore quite different from that of the fibrillar collagen genes which have evolved by duplication of a primordial 54-bp unit. It also differs from that of the basement membrane collagen genes whose exon/intron boundaries often split the codons for amino acids.     

A novel and highly conserved collagen (pro(alpha)1(XXVII)) with a unique expression pattern and unusual molecular characteristics establishes a new clade within the vertebrate fibrillar collagen family

The type XXVII collagen gene codes for a novel vertebrate fibrillar collagen that is highly conserved in man, mouse, and fish (Fugu rubripes). The pro(alpha)1(XXVII) chain has a domain structure similar to that of the type B clade chains (alpha1(V), alpha3(V), alpha1(XI), and alpha2(XI)). However, compared with other vertebrate fibrillar collagens (types I, II, III, V, and XI), type XXVII collagen has unusual molecular features such as no minor helical domain, a major helical domain that is short and interrupted, and a short chain selection sequence within the NC1 domain. Pro(alpha)1(XXVII) mRNA is 9 kb and expressed by chondrocytes but also by a variety of epithelial cell layers in developing tissues including stomach, lung, gonad, skin, cochlear, and tooth. By Western blotting, type XXVII antisera recognized multiple bands of 240-110 kDa in tissue extracts and collagenous bands of 150-140 kDa in the conditioned medium of the differentiating chondrogenic ATDC5 cell line. Phylogenetic analyses revealed that type XXVII, together with the closely related type XXIV collagen gene, form a new, third clade (type C) within the vertebrate fibrillar collagen family. Furthermore, the exon structure of the type XXVII collagen gene is similar to, but distinct from, those of the genes coding for the type A or B clade pro(alpha) chains.     

Identification, characterization and expression analysis of a new fibrillar collagen gene, COL27A1.

The fibrillar collagens provide structural scaffolding and strength to the extracellular matrices of connective tissues. We identified a partial sequence of a new fibrillar collagen gene in the NCBI databases and completed the sequence with bioinformatic approaches and 5' RACE. This gene, designated COL27A1, is approximately 156 kbp long and has 61 exons located on chromosome 9q32-33. The homologous mouse gene is located on chromosome 4. The gene encodes amino- and carboxyl-terminal propeptides similar to those in the 'minor' fibrillar collagens. The triple-helical domain is, however, shorter and contains 994 amino acids with two imperfections of the Gly-Xaa-Yaa repeat pattern. There were three sites of alternative RNA splicing, only one of which led to the intact mRNA that encodes this full-length collagen proalpha chain. Phylogenetic analyses indicated that COL27A1 forms a clade with COL24A1 that is distinct from the two known lineages of fibrillar collagens. Expression analyses of the mouse col27a1 gene demonstrated high expression in cartilage, the eye and ear, but also in lung and colon. It is likely that the major protein product of COL27A1, proalpha1(XXVII), is a component of the extracellular matrices of cartilage and these other tissues. Study of this collagen should yield insights into normal chondrogenesis, and provide clues to the pathogenesis of some chondrodysplasias and disorders of other tissues in which this gene is expressed.     

The pro alpha 2(V) collagen gene is evolutionarily related to the major fibrillar-forming collagens.

A number of overlapping cDNA clones, covering 5.2 kb of sequences which code for the human pro alpha 2(V) collagen chain, have been isolated. Analysis of the structural data have indicated a close evolutionary kinship between the pro alpha 2(V) chain and the major fibrillar collagen types. Isolation and analysis of an 8 kb genomic fragment has further supported this notion by revealing a homologous arrangement of nine triple-helical domain exons. These studies have therefore provided conclusive evidence which categorizes the Type V collagen as a member of the Group 1 molecules, or fibrillar-forming collagens.     

The human alpha 2(XI) collagen (COL11A2) chain. Molecular cloning of cDNA and genomic DNA reveals characteristics of a fibrillar collagen with differences in genomic organization

We have isolated three overlapping cDNA clones encoding the pro alpha 2(XI) collagen chain from a human chondrocyte cDNA library. Together, the cDNAs code for 257 uninterrupted Gly-X-Y triplets (almost 80% of the triple helical domain) and about 200 amino acid residues of the carboxyl telopeptide and carboxyl propeptide. The identification of the clones as pro alpha 2(XI) cDNAs was based on the complete identity between the amino acid sequences of three tryptic peptides derived from human alpha 2(XI) collagen and the cDNA-derived sequence. We have also sequenced six exons within a human genomic alpha 2(XI) cosmid clone. This sequence shows that although type XI collagen belongs to the fibril-forming class of collagens, there are substantial differences in exon sizes at the 3' end of the gene when comparing the alpha 2(XI) gene with those of human types I, II, and III collagens. Finally, pro alpha 2(XI) cDNA has been used as a probe to determine the location of the gene by in situ hybridization of chromosome spreads. The results demonstrate that the gene is located close to the region p212 on chromosome 6. Northern blot analysis shows that the gene is expressed in cartilage but not in adult liver, skin, and tendon.     

Organization of the exons coding for pro alpha 1(II) collagen N-propeptide confirms a distinct evolutionary history of this domain of the fibrillar collagen genes

The organization of the exons coding for the N-terminal portion of human type II procollagen has been determined. Aside from inferring the previously unknown primary structure of type II N-propeptide, this study has revealed that this coding domain of the gene exhibits an organization uniquely distinct from those of type I and type III collagens. This finding substantiates the notion that the N-propeptide coding domains of the fibrillar collagen genes evolved under less stringent selection than those encoding the C-propeptide and triple helical regions.     

Collagen XXIV,a vertebrate fibrillar collagen with structural features of invertebrate collagens: selective expression in developing cornea and bone

Tissue-specific assembly of fibers composed of the major collagen types I and II depends in part on the formation of heterotypic fibrils, using the quantitatively minor collagens V and XI. Here we report the identification of a new fibrillar-like collagen chain that is related to the fibrillar alpha1(V), alpha1(XI), and alpha2(XI) collagen polypeptides and which is coexpressed with type I collagen in the developing bone and eye. The new collagen was designated the alpha1(XXIV) chain and consists of a long triple helical domain flanked by typical propeptide-like sequences. The carboxyl propeptide is classic, with 8 conserved cysteine residues. The amino-terminal peptide contains a thrombospodin-N-terminal-like (TSP) motif and a highly charged segment interspersed with several tyrosine residues, like the fibril diameter-regulating collagen chains alpha1(V) and alpha1(XI). However, a short imperfection in the triple helix makes alpha1(XXIV) unique from other chains of the vertebrate fibrillar collagen family. The triple helical interruption and additional select features in both terminal peptides are common to the fibrillar chains of invertebrate organisms. Based on these data, we propose that collagen XXIV is an ancient molecule that may contribute to the regulation of type I collagen fibrillogenesis at specific anatomical locations during fetal development.     

Interaction of osteogenin, a heparin binding bone morphogenetic protein, with type IV collagen

Osteogenin, an extracellular matrix component of bone, is a heparin binding differentiation factor that initiates endochondral bone formation in rats when implanted subcutaneously with an insoluble collagenous matrix. We have examined the interaction of osteogenin with various extracellular matrix components including basement membranes. Osteogenin, purified from bovine bone, binds avidly to type IV collagen and to a lesser extent to both type I and IX collagens. Osteogenin binds equally well to both native and denatured type IV collagen. Both alpha 1 and alpha 2 chains of type IV collagen are recognized by osteogenin. Osteogenin binds to a collagen IV affinity column, and is eluted by 6.0 M urea with 1 M NaCl, pH 7.4, and the eluate contained the osteogenic activity as demonstrated in vivo. Binding of osteogenin to collagen IV is not influenced by either laminin or fibronectin. These results imply that osteogenin binding to extracellular matrix components including collagens I and IV and heparin may have physiological relevance, and such interactions may modulate its local action.     

Biochemical and immunological characterization of collagen molecules from echinothurioid sea urchin Asthenosoma ijimai

Collagens collected from the test (the external hard covering of invertebrates) of the sea urchin, Asthenosoma ijimai, were characterized biochemically and immunologically. The amino-acid composition was typical of that of mammalian collagens. Crystals of segment-long-spacing showed that the molecules of sea urchin collagen were 300 nm long. Selective salt precipitation revealed that the collagen has the same solubility characteristics as type I collagen. The collagen was denatured at 23.1 degrees C. Anti-sea urchin collagen antisera were immunologically cross-reacted with collagens of the same species and the starfish Asterina pectinifera. However, the antisera showed no or slight responses to collagens of bovine type I, II, III, IV and V. The collagen molecules contained four alpha-chains, named alpha 1(SU), alpha 2(SU), alpha 3(SU) and alpha 4(SU), respectively. All of the four alpha-chains were eluted in the same fraction on gel filtration chromatography. Chains of alpha 1(SU) and alpha 2(SU) were extracted earlier than alpha 3(SU) and alpha 4(SU) during pepsin digestion. Other biochemical and immunological analyses clearly demonstrated that test of sea urchins contains two genetically different, but biochemically similar, species of collagens, one of which is composed of alpha 1(SU) and alpha 2(SU) chains, and the other of alpha 3(SU) and alpha 4(SU).     

Characterization of a novel collagen chain in human placenta and its relation to AB collagen.

A novel collagen chain, termed alpha C, has been isolated from human placenta by limited pepsin digestion. The collagen containing the alpha C chain copurifies with placental AB collagen during selective salt precipitation but is virtually absent from fetal birth membranes, which contain relatively larger amounts of AB. Both native AB and alpha C-containing collagens are resistant to human skin collagenase under conditions that support cleavage of type I by greater than 90%. The alpha C chain was separated from alpha B by phosphocellulose chromatography and subsequently from alpha P by chromatography on CM-cellulose. Its amino acid composition is distinct from alpha A and alha B although all three chains posses compositional features in common; the carbohydrate content of the alpha C chain was intermediate between those of alpha A and alpha B. Analysis by NaDodSO4-polyacrylamide gel electrophoresis of peptides produced by CNBr cleavage and by limited digestion with the enzyme mast cell protease indicated different and unique products for the alpha A, alpha B, and alpha C chains. The data support the existence of another collagen chain which is related to the alpha A and alpha B chains but which is structurally unique. The proteins containing these chains may in turn comprise a subfamily of collagen isotypes which represents a divergence from and/or specialization of the type IV basement membrane collagens.     

Isolation and partial characterization of the entire human pro alpha 1(II) collagen gene.

Using a cDNA probe specific for the bovine Type II procollagen, a series of overlapping genomic clones containing 45 kb of contiguous human DNA have been isolated. Sequencing of a 54 bp exon, number 29, provided direct evidence that the recombinant clones bear human Type II collagen sequences. Localization of the 5' and 3' ends of the gene indicated that the human Type II collagen gene is 30 kb in size. This value is significantly higher than that of the homologous avian gene. The segregation of a polymorphic restriction site in informative families conclusively demonstrated that the Type II gene is found in a single copy in the human haploid genome. Finally, sequencing of a triple helical domain exon has confirmed that a rearrangement leading to the fusion of two exons occurred in the pro alpha 1(I) gene, following the divergence of the fibrillar collagens.