Isolation and characterization of genomic DNA coding for alpha 2 type I collagen.

We have isolated and characterized a segment of the chick alpha 2 collagen gene by screening a library of chick genomic fragments using as hybridization probe an alpha 2 collagen cDNA clone. Several clones were isolated and one of them, lambda gCOL 204, was used for further studies. The DNA of lambda gCOL 204 hybridizes to a unique species of mRNA the size of alpha 2 collagen mRNA. This mRNA can be translated into a unique polypeptide which comigrates in SDS-gel electrophoresis with pro-alpha 2 collagen. Electron microscopic analysis by R-loop technique indicates that lambda gCOL 204 contains 7Kb of the alpha 2 collagen gene. This 7 Kb piece constitutes the 3' end of the gene. The same clone also contains 9 Kb of DNA that is immediately adjacent to the 3' end of the alpha 2 collagen gene. The cloned segment of the alpha 2 collagen gene is interrupted by 8 intervening sequences of various lengths. The coding sequences for collagen in this clone add up to approximately 1,800 bp, which correspond to about 1/3 of alpha 2 collagen mRNA. DNA sequence analysis of a small coding segment of lambda g COL 204 reveals a characteristic collagen type sequence which encodes for an amino acid sequence identical to a sequence found in calf alpha 2 collagen. The sequence of this region of the protein has not yet been determined for the chick alpha 2 collagen.     

Isolation and characterization of a genomic sequence of maize coding for a zein gene

Summary An EcoRI restriction endonuclease fragment of maize DNA coding for the 19,000 dalton zein protein was cloned in phage gt WES. The zein gene was identified by the electron microscopic analysis of RNA-DNA hybrids (R-loops) and DNA-DNA hybrids (D-loops). The R-loops were formed with poly(rA)-containing RNA isolated from 18 days post-pollination maize endosperm and showed no intervening non-hybridizing sequences (introns) within their 800 base length. A cDNA clone specific for the 19,000 dalton zein protein formed D-loops in the same position and orientation as the R-loops. The cloned fragment measured 4.4 kilobases (kb), the same size as an EcoRI fragment of maize DNA revealed by Southern analysis.     

Analysis of cDNA and genomic clones coding for the pro alpha 1 chain of calf type II collagen.

A bovine cDNA library constructed from fetal cartilage RNA was screened with a pro alpha 1(II) collagen specific chicken cDNA. A recombinant clone (Bc 7), with an insert of 1 kb, was identified and shown to contain sequences exhibiting 85% homology with the chicken pro alpha 1(II) collagen C-propeptide. Interspecies comparison strongly suggested that one potential glycosylation site present in the avian C-propeptide is not utilized, since this site is absent in the bovine chain. In addition, two overlapping genomic clones (Pal 3 and Pal 4) were isolated and partially characterized. These clones span 23 kb of DNA and contain approximately 17 kb of the pro alpha 1(II) calf gene. Sequencing of exon 1 has determined the length of the 3' untranslated region and the exact location of the polyadenylation attachment site.     

Structural comparison of promoter and coding sequence of type I collagen alpha 1 chain gene duplicates between zebrafish and flounder/fugu lineages

Alpha 1 chain (Colα1(I)) and alpha 2 chain (Colα2(I)) are universal components of type I collagen in tetrapods, but rainbow trout (Oncorhynchus mykiss) and zebrafish (Danio rerio) have a third: alpha 3 chain (Colα3(I)). This study tests whether Colα3(I) is a duplicate of Colα1(I) by whole-genome duplication (WGD) that occurred early in the ray-fin fish lineage. We also examine how their promoter sequence was modified after WGD. We cloned Colα1(I), Colα2(I) and Colα3(I) cDNAs and their promoters from flounder (Paralichthys olivaceus) and obtained corresponding sequences from the genome databanks of two pufferfishes Takifugu rubripes and Tetraodon nigroviridis, by BLAST-Search using flounder sequences. Phylogenetic analysis of N-terminal sequences of ca. 100 amino acids, including signal peptide and N-propeptide sequences before short triple helical domain, indicates that Colα3(I), found only in teleosts, is a duplicate of Colα1(1) by WGD. Colα1(I) and Colα3(I) genes begin to be transcribed at different stages of Takifugu embryogenesis, suggesting that their structure of promoter is modified differently after WGD. In flounder, Takifugu and Tetraodon, the structure of proximal region of promoter is highly conserved within Colα1(I) and within Colα3(I); no homology is apparent except for the TATA element motif between Colα1(I) and Colα3(I) of each species. Unexpectedly, zebrafish Colα1(I) promoter is more homologous to Colα3(I) of flounder and fugu than Colα1(I) is. These results suggest that each duplicated Colα1(I) gene promoter inherited a unique structure after WGD, but the manner of modification differed between the phylogenetically separated zebrafish and flounder/pufferfish lineages.     

Construction and characterization of cDNA encoding the alpha 2 chain of chicken type IX collagen

We have isolated and characterized a cDNA encoding the carboxy-terminal half of one of the polypeptide subunits of a novel disulfide-bonded collagen found in hyaline cartilage. This collagen has been given the type assignment type IX, and it has several unusual characteristics. First, the polypeptide subunits are shorter than alpha-chains of the fibrillar collagens types I, II, and III. Second, type IX molecules are heterotrimers of three genetically distinct polypeptide subunits. Third, type IX molecules contain three triple-helical collagenous domains interspersed with noncollagenous domains. When chicken cartilage collagens are extracted with pepsin, type IX collagen is cleaved and gives rise to the triple-helical fragments HMW and LMW. The identification of the cDNA reported here is based on a comparison of the amino acid composition of tryptic peptides derived from LMW with the composition of tryptic peptides predicted from the nucleotide sequence of the cDNA. We also show that the amino-terminal sequence of one of the subunits of LMW is identical with the sequence predicted from the nucleotide sequence of the cDNA. Finally, we demonstrate that the amino-terminal amino acid sequence of a tryptic peptide isolated from one of the subunits of HMW is identical with a sequence predicted from the cDNA. We have given the polypeptide chain encoded by the cDNA reported here the name alpha 2(IX), and we show that it is homologous to the alpha 1(IX) chain previously characterized by us.     

Sheep elastin genes. Isolation and preliminary characterization of a 9.9-kilobase genomic clone

A sheep genomic library containing sheep DNA in the bacteriophage vector Charon 4A was screened for elastin-gene sequences with partially purified, 32P-labelled elastin mRNA (mRNAE). A recombinant containing a 9.9-kb (kilobase) insert was selected from several positive clones by secondary and tertiary screening for further characterization. Positive identification of this elastin clone, designated SE1, was made with radiolabelled mRNAE by hydridization-selected translation and Southern blotting of restriction-enzyme fragments of SE1 DNA. Hybridization of either mRNAE or elastin complementary DNA to restriction fragments of SE1 showed that most of these fragments of SE1 contained elastin-coding sequences. Orientation of the insert was established by preferential hybridization of a short complementary elastin DNA to restriction fragments adjacent to the right arm of Charon 4A. Reciprocal hybridizations of nick-translated SE1 and sheep genomic DNA on Southern blots showed that two restriction fragments of SE1 contained sequence elements which were repeated at high frequency in a restriction-endonuclease-EcoR1 digest of total sheep genomic DNA. In the accompanying paper [Davidson, Shibahara, Boyd, Mason, Tolstoshev & Crystal (1984) Biochem. J. 220, 653-663], it is shown that a subcloned fragment of this elastin gene quantitatively and specifically hybridized to mRNAE sequences in sheep tissue RNA. Electron microscopy of SE1-mRNAE hybrids indicated the presence of at least seven large R-loops. Measurements of these structures indicated that SE1 is likely to contain less than 2 kb of coding sequence and more than 8 kb of intervening sequence, with an average exon size of 120 base-pairs. Thus the elastin gene is distributed over an extended region of the sheep genome and contains numerous intervening and coding sequences.     

Completion of the amino acid sequence of the alpha 1 chain from type I calf skin collagen. Amino acid sequence of alpha 1(I)B8.

The complete amino acid sequence of the 279-residue CNBr peptide CB8 from the alpha 1 chain of type I calf skin collagen is presented. It was determined by sequencing overlapping fragments of CB8 produced by Staphylococcus aureus V8 proteinase, trypsin, Endoproteinase Arg-C and hydroxylamine. Tryptic cleavages were also made specific for lysine by blocking arginine residues with cyclohexane-1,2-dione. This completes the amino acid sequence analysis of the 1054-residues-long alpha (I) chain of calf skin collagen.     

Use of the polymerase chain reaction to clone and sequence a cDNA encoding the bovine alpha 3 chain of type IV collagen

A novel type IV collagen, alpha 3(IV), has previously been isolated from a collagenase digest of bovine and human glomerular and lens basement membranes. The cloning and sequencing of a cDNA encoding the alpha 3(IV) chain is described here. Using the polymerase chain reaction, with primers derived from the known 27-residue bovine alpha 3(IV) amino acid sequence, a 68-base pair bovine genomic fragment (KEM68) which encodes the known peptide sequence, was synthesized. KEM68 was then used to screen a bovine lens cDNA library and a 1.5-kilobase partial cDNA clone obtained, encoding 471 residues of the bovine alpha 3(IV) chain: 238 residues from the triple helical collagenous domain and all 233 residues of the noncollagenous domain. The collagenous repeat sequence has three interruptions, coinciding with those in the alpha 1(IV) chain. The noncollagenous domain has 12 cysteine residues in identical positions to those of other type IV collagens and 71, 61, and 70% overall similarity with the human alpha 1(IV), alpha 2(IV), and alpha 5(IV) chains. The noncollagenous domain of alpha 3(IV) is of particular interest as it appears to be the component of glomerular basement membrane that reacts maximally with the Goodpasture antibody. Furthermore, such antigenicity is absent from collagenase digests of the glomerular basement membrane of some patients with Alport syndrome. The alpha 3(IV) cDNA clone described here now permits study of the molecular pathology of COL4A3 in Alport syndrome.     

Isolation of multiple genomic sequences coding for chicken myosin heavy chain protein

A genomic bank has been constructed using DNA isolated from a dystrophic strain of chickens. The library was screened for myosin heavy chain (MHC) sequences using a cDNA probe and 11 positive recombinants isolated. Identity of the clones was confirmed by positive RNA selection via hybridization of the clones with muscle RNA and subsequent translation of the hybridizable RNA in vitro. Restriction maps indicate that the clones can be divided into 7 distinct groups; some of these groups do, however, share similar or homologous sequences. Hydridization of the clones to RNA derived from leg, breast, heart, and brain reveals that all of the clones code for the muscle-specific MHC isoforms. These experiments also show that there are at least 3 size classes of MHC mRNA sequences, whose relative amounts appear to be modulated in a tissue- and developmental stage-specific manner.     

Partial covalent structure of the human alpha 2 type V collagen chain

Human cDNA libraries were screened with a cDNA fragment presumably encoding the 3' terminus of a procollagen carboxyl propeptide not identifiable as types I, II, III, or IV by protein sequence or Northern blot hybridization. One clone contained a 1350-base pair insert coding in part for 55 uninterrupted Gly-X-Y triplets. Comparison with the amino acid composition of the COOH-terminal cyanogen bromide (CB) peptides of the alpha 1 and alpha 2 type V collagen chains showed similarity only to the alpha 2(V)CB fragment. To identify the NH2 terminus of the peptide designated by methionine, an additional isolate was sequenced and found to contain a Gly-Met-Pro triplet. Thirty-one amino acids from the NH2 terminus of the alpha 2(V)CB9 fragment were then determined by Edman degradation and found to be identical to those derived from the cDNA clone. The DNA sequence encoding part of the triple helical region establishes for the first time the partial structure of a type V collagen chain. Although comparison of residues 796-1020 of the alpha 2(V) collagenous region with alpha 1 (III), alpha 1(I), and alpha 2(I) shows strong conservation of charged positions, the latter three chains appear considerably more similar to each other than to alpha 2(V). A striking feature of the alpha 2(V) sequence between 918-944 is the absence of proline residues. In the analogous region of alpha 1(I) where this amino acid is also lacking, a flexible site in the rigid triple helical structure of type I collagen has been observed (Hofmann, H., Voss, T., Kuhn, K. and Engel, J. (1984) J. Mol. Biol. 172, 325-343).     

Characterization of the c-Myb-responsive region and regulation of the human type I collagen alpha 2 chain gene by c-Myb

We have characterized the role of c-Myb and B-Myb in the regulation of human type I collagen alpha2 chain gene expression in fibroblastic cells. We have identified four Myb-binding sites (MBSs) in the promoter. Transactivation assays on wild type and mutant promoter-reporter constructs demonstrated that c-Myb, but not B-Myb, can transactivate the human type I collagen alpha 2 chain gene promoter via the MBS-containing region. Electrophoretic mobility shift assay experiments showed that c-Myb specifically binds to each of the four MBS; however, the mutagenesis of site MBS-4 completely inhibited transactivation by c-Myb, at least in the full-length promoter. In agreement with these results, c-myb(-/-) mouse embryo fibroblasts (MEFs) showed a selective lack of expression of type I collagen alpha 2 chain gene but maintained the expression of fibronectin and type III collagen. Furthermore, transforming growth factor-beta induced type I collagen alpha 2 chain gene expression in c-myb(-/-) MEFs, implying that the transforming growth factor-beta signaling pathway is maintained and that the absence of COL1A2 gene expression in c-myb(-/-) MEFs is a direct consequence of the lack of c-Myb. The demonstration of the importance of c-Myb in the regulation of the type I collagen alpha 2 chain gene suggests that uncontrolled expression of c-Myb could be an underlying mechanism in the pathogenesis of several fibrotic disorders.     

Isolation and characterization of a cDNA-clone coding for potato type A phytochrome

We have isolated and sequenced a cDNA clone encoding the apoprotein of a potato phytochrome. Based on the deduced amino acid sequence, which shows 78% amino acid identity to the Arabidopsis phyA and 50% identity to the Arabidopsis phyB open reading frame, we have classified this cDNA clone as potato phyA phytochrome. The amino acid immediately preceding cysteine 323, which is the homologue of oat cystein 321, to which the chromophore has been shown to be attached, is a tyrosine residue. This contrasts with six other type A phytochrome sequences from both monocots and dicots that encode serine in this position. As already observed in three other cDNAs isolated from dicot species, the potato phyA clone encodes a short open reading frame (13 amino acids) preceding the phyA open reading frame (1123 amino acids), supporting the idea that this type of leader sequence might be involved in the regulated expression of the phytochrome apoprotein. Southern blot analysis revealed a single phyA gene as well as other related phytochrome sequences in the potato genome. phyA mRNA levels varied in different organs and were modulated by white light; in seedlings and sprouts, highest levels of mRNA were detected in the etiolated stage. Upon illumination with white light, mRNA levels decreased to the amount found in leaves of re-etiolated plants. Lowest expression was observed in leaves of plants grown in the light, in tubers irrespective of light treatment, and in roots of plants grown in the dark. In roots of plants grown in the light, elevated levels of phyA mRNA were detected. Using a monoclonal antibody generated against pea phytochrome as an immunochemical probe, the protein was only detectable in protein extracts from etiolated seedlings and sprouts.     

A type I collagen with substitution of a cysteine for glycine-748 in the alpha 1(I) chain copolymerizes with normal type I collagen and can generate fractallike structures

Type I procollagen was purified from cultured fibroblasts of a proband with a lethal variant of osteogenesis imperfecta. The protein was a mixture of normal procollagen and mutated procollagens containing a substitution of cysteine for glycine in either one pro alpha 1(I) chain or both pro alpha 1(I) chains, some or all of which were disulfide-linked through the cysteine at position alpha 1-748. The procollagen was then examined in a system for generating collagen fibrils de novo by cleavage of the pCcollagen to collagen with procollagen C-proteinase [Kadler et al. (1987) J. Biol. Chem. 262, 15696-15701]. The mutated collagens and normal collagens were found to form copolymers under a variety of experimental conditions. With two preparations of the protein that had a high content of alpha 1(I) chains disulfide-linked through the cysteine alpha 1-748, all the large structures formed had a distinctive, highly branched morphology that met one of the formal criteria for a fractal. Preparations with a lower content of disulfide-linked alpha 1(I) chains formed fibrils that were 4 times the diameter of control fibrils. The formation of copolymers was also demonstrated by the observation that the presence of mutated collagens decreased the rate of incorporation of normal collagen into fibrils. In addition, the solution-phase concentration at equilibrium of mixtures of mutated and normal collagens was 5-10-fold greater than that of normal collagen.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure and assembly of the heterotrimeric and homotrimeric C-propeptides of type I collagen: significance of the alpha2(I) chain

Assembly of the type I procollagen molecule begins with interactions among the C-pro alpha1(I) and C-pro alpha2(I) domains. The C-propeptide domains themselves have subdomains of distinct structures. The important questions are where chain association begins and the basis of the chain selectivity which leads to the preferential formation of the [C-pro alpha1(I)]2[C-pro alpha2(I)] heterotrimer. These questions are addressed by energy minimization modeling of the individual C-propeptide structures, study of their docking interactions, and comparison of the heterotrimeric and homotrimeric C-pro structures and stability. The comparisons show the remarkable impact of the C-pro alpha2 chain on the structure of the assembled trimeric C-propeptide. In the modeling, the three chains were anchored and registered by a short C-terminal collagen triple-helical segment followed by the C-telopeptides in their docked conformation, and then the remaining C-propeptide chains were allowed to interact and dock. Surprisingly, propeptide trimerization did not proceed through the previously proposed N-terminal "oligomerization domain" of the C-propeptide [McAlinden et al. (2003) J. Biol. Chem. 278, 42200] but rather in the most C-terminal domains of type I procollagen chains. Molecular dynamics showed heterotrimer assembly to begin with dimer formation between globular G2alpha2 and the G2alpha1(2) domains followed by trimerization at the G1 domains. Assembly initiation in the putative oligomerization coiled-coil domain is not possible because of the Pro residues at positions 3, 7, and 11 at the N-terminus of the alpha2 C-propeptide chain. To confirm the computations and proposed assembly pathway, the G2alpha1 and G2alpha2 domains were prepared recombinantly as the maltose binding protein constructs, and their interactions were studied by dynamic light scattering and gel filtration chromatography. Under the conditions examined MBP remained as monomer, MBP-G2alpha1 and MBP-G2alpha2 alone formed dimers, but a 2:1 mixture of MBP-G2alpha1 and MBP-G2alpha2 favored trimer formation. Thus, the C-terminal globular domains (G2) of the type I collagen C-propeptides play a crucial role in the initiation of intermolecular assembly and heterotrimer selectivity.     

The role of the alpha2 chain in the stabilization of the collagen type I heterotrimer: a study of the type I homotrimer in oim mouse tissues

We have previously reported that the fragility of skin, tendon and bone from the oim mouse is related to a significant reduction in the intermolecular cross-linking. The oim mutation is unlikely to affect the efficacy of the lysyl oxidase, suggesting that the defect is in the molecule and fibre. We have therefore investigated the integrity of both the oim collagen molecules and the fibre by differential scanning calorimetry.The denaturation temperature of the oim molecule in solution and the fibre from tail tendon were found to be higher than the wild-type by 2.6deg.C and 1.9deg.C, respectively. With the loss of the alpha2 chain, the hydroxyproline content of the homotrimer is higher than the heterotrimer, which may account for the increase.There is a small decrease in the enthalpy of the oim fibres but it is not significant, suggesting that the amount of disorder of the triple-helical molecules and of the fibres is small and involves only a small part of the total bond energy holding the helical structure together. The difference in denaturation temperature of the skin collagen molecules (t(m)) and fibres (t(d)) is significantly lower for the oim tissues, 19.9deg.C against 23.1deg.C, indicating reduced molecular interactions and hence packing of the molecules in the fibre. Computation of the volume fraction of the water revealed that the interaxial separation of the oim fibres was indeed greater, increasing from 19.6A to 21.0A. This difference of 1.4A, equivalent to a C-C bond, would certainly decrease the ability of the telopeptide aldehyde to interact with the epsilon -amino group from an adjacent molecule and form a cross-link. We suggest, therefore, that the reduction of the cross-linking is due to increased water content of the fibre rather than a distortion of the molecular structure.The higher hydrophobicity of the alpha2 chain appears to play a role in the stabilisation of heterotrimeric type I collagen, possibly by increasing the hydrophobic interactions between the heterotrimeric molecules, thereby reducing the water content and increasing the binding of the molecules in the fibre.     

Isolation and characterization of a human collagen alpha 1(I)-like gene from a cosmid library

We have isolated a human collagen alpha 1(I)-like gene from a cosmid library. The clone which contains 37kb of human DNA has been shown to contain this gene by DNA sequencing, hybrid arrest and hybrid selection assays and Northern blot hybridizations. The collagen gene sequence extends through most of the cloned DNA and must, therefore, be at least 35kb in length.     

Wide distribution of the skin type I collagen alpha 3 chain in bony fish.

1. Skin Type I collagens were isolated from the five species of non-teleostean fish and examined with respect to their subunit chains. 2. In addition to alpha 1(I) and alpha 2(I) chains, a fish-specific chain, alpha 3(I), was previously found only in teleostean fish. The present study, however, has revealed the occurrence of alpha 3(I) in a chondrostean fish, white sturgeon. 3. The alpha 3(I) gene appears to have arisen from a duplication of the alpha 1(I) gene near the time of the adaptive radiation of bony fish.