Fish skin type I collagen: wide distribution of an alpha 3 subunit in teleosts

1. Skin Type I collagen was isolated from 15 species of teleosts. 2. Chromatographic and electrophoretic analyses revealed that most of the teleost skin collagens possessed a unique subunit, alpha 3, which had not been detected in other vertebrate Type I collagens. 3. The skin collagen seems to exist as an alpha 1 alpha 2 alpha 3 heterotrimer in many teleosts and as an (alpha 1)2 alpha 2 heterotrimer in some teleosts.     

Scale and bone type I collagens of carp (Cyprinus carpio).

1. Soluble Type I collagens were isolated from the scale and bone (skull) of lathyritic carp. Each tissue collagen was assumed to consist of two different molecular forms, (alpha 1)2 alpha 2 as a main component and alpha 1 alpha 2 alpha 3 as a minor one. 2. The possible coexistence of these two forms in soluble Type I collagen of carp was previously observed for skin and muscle, but not for the swim bladder in which only the form of (alpha 1)2 alpha 2 was found. 3. These composite results suggest the wide distribution of alpha 1 alpha 2 alpha 3 heterotrimers in collagenous tissues of carp.     

Vertebrate skin type I collagen: comparison of bony fishes with lamprey and calf

1. Characterization of Type I collagen alpha chains, alpha 1 and alpha 2, in the skin tissues of carp and common mackerel revealed a marked interspecies difference in CNBr-peptide maps of the alpha 2 chains, suggesting the hypervariability during evolution of the alpha 2 chains relative to the alpha 1 chains. 2. When compared with calf Type I collagen, lower vertebrate Type I collagens derived from these bony fishes as well as from lamprey were found to exhibit a higher degree of structural similarity between their alpha 1 and alpha 2 chains.     

Collagen fibrils of an invertebrate (Sepia officinalis) are heterotypic: immunocytochemical demonstration

Collagen fibrils from the dermis of Sepia officinalis were processed for immunoelectron microscopy to reveal reactions to antibodies against mammalian types I, III, and V, teleost type I and cephalopod type I-like collagens, by single and double immunogold localization. The fibrils were observed: (a) in suspensions of prepared fibrils, (b) in ultrathin sections of embedded fibril preparations, and (c) in ultrathin sections of dermal tissue. Some samples were subjected to acetic acid or urea dissociation. It was found that collagen fibrils from Sepia dermis are heterotypic in that they are composed of type I-like and type V collagens. Type I-like collagen epitopes were present mainly at the periphery of the fibrils; type V collagen epitopes were present throughout the fibrils. This is the first demonstration that collagen fibrils from an invertebrate are heterotypic, suggesting that heterotypy may be an intrinsic characteristic of the fibrils of fibrillar collagens, independent of evolutionary or taxonomic status.     

Fibril-forming collagens in lamprey

Five types of collagen with triple-helical regions approximately 300 nm in length were found in lamprey tissues which show characteristic D-periodic collagen fibrils. These collagens are members of the fibril forming family of this primitive vertebrate. Lamprey collagens were characterized with respect to solubility, mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, carboxylmethyl-cellulose chromatography, peptide digestion patterns, composition, susceptibility to vertebrate collagenase, thermal stability, and segment long spacing-banding pattern. Comparison with fibril-forming collagens in higher vertebrates (types I, II, III, V, and XI) identified three lamprey collagens as types II, V, and XI. Both lamprey dermis and major body wall collagens had properties similar to type I but not the typical heterotrimer composition. Dermis molecules had only alpha 1(I)-like chains, while body wall molecules had alpha 2(I)-like chains combined with chains resembling lamprey type II. Neither collagen exhibited the interchain disulfide linkages or solubility properties of type III. The conservation of fibril organization in type II/type XI tissues in contrast to the major developments in type I and type III tissues after the divergence of lamprey and higher vertebrates is consistent with these results. The presence of type II and type I-like molecules as major collagens and types V and XI as minor collagens in the lamprey, and the differential susceptibility of these molecules to vertebrate collagenase is analogous to the findings in higher vertebrates.     

Identification and analysis of collagen alpha 1(XXI), a novel member of the FACIT collagen family.

The FACIT collagens bind to the surface of collagen fibrils linking them with other matrix molecules. Bioinformatics analysis of cDNA clone DKFZp564B052 showed that it resembled the FACIT collagens and was therefore designated collagen alpha 1(XXI). Phylogenetic analyses of the N-terminal NC3 domains of alpha 1(XXI) and other FACIT collagens showed that (i) alpha 1(XXI) clustered with the FACIT collagens; (ii) collagen alpha 1(XXI) arose before the divergence of alpha 1(XII), alpha 1(XIV) and alpha 1(XX); (iii) collagen alpha 1(XIV) derived from the C-terminal region of the NC3 domain of a collagen alpha 1(XII)-like molecule; and (iv) collagen alpha 1(XX) derived from a collagen alpha 1(XIV)-like molecule. This study provides a framework for the evolution of the FACIT collagens which will be of value in linking NC3 domains with their functions.     

Type II collagen of lamprey

The major collagen in lamprey notochord is type II, as determined by its amino acid composition and solubility properties. This collagen has a distribution of charged residues indistinguishable from higher vertebrate Type II collagens as judged by its SLS banding pattern. Lamprey type II collagen has a higher thermal stability than lamprey skin collagen, in contrast to the identical melting temperatures for these types in mammals. A minor collagen in lamprey notochord has solubility properties, amino acid composition, and electrophoretic mobility similar to that of 1 alpha, 2 alpha, 3 alpha collagen in human cartilage.     

Vitreous body collagen. Evidence for a dual origin from the neural retina and hyalocytes

Two different cells types have been shown to synthesize embryonic chick vitreous collagen (vitrosin) at different stages of development. Identification of vitrosin was established by labeling the embryos in ovo [3H]proline at stages 23 and 28 and separating the extracted vitreous collagen alpha-chains by carboxymethylcellulose chromatography. The labeled collagen consisted predominately of alpha 1 chains, indicating a molecule in the form of a trimer of identical chains designated (alpha 1)3. The molecular weight of the labeled chains measured approximately 95,000 daltons by molecular sieve chromatography, and contained 41% of their imino acid as 4- hydroxyproline. To establish which eye tissues synthesize vitrosine, the collagens produced in organ culture by the isolated neural retina, lens and vitreous body from stages 26-27, 29-30, and 40 were examined. At the two earlier stages, only the neural retina synthesized large quantities of (alpha 1)3 collagen whereas the lens and the cells within the vitreous body itself synthesized relatively small amounts of collagen characterized by an alpha 1:alpha 2 ratio of about 2:1. At stage 40, however, the cells of the vitreous body itself synthesized the greatest quantities of collagen, which now was predominantly an (alpha 1)3 type molecule. Stage 40 neural retina and lens synthesized lesser amounts of collagen with an alpha 1:alpha 2 ratio of 2 to 3:1. Chick vitrosin thus appears to be synthesized by the neural retina in early embryonic stages, whereas the major contribution derives from cells within the vitreous body in later development.     

Collagen composition of normal and myxomatous human mitral heart valves.

The collagens were studied in 13 normal and 19 myxomatous human mitral valves. The collagens of the valve were completely solubilized by using a method consisting of guanidinium chloride extraction, limited pepsin digestions and CNBr cleavage of the residue. The normal valves contained 74% type I, 24% type III and 2% type V collagen. The type I and type III collagens had similar solubility patterns, although only type I collagen was detected in the guanidinium chloride extract. Type V collagen was only detected in the first pepsin extract. The type I and III collagens had higher contents of hydroxylysine than did the same collagens from age-matched dermis. The two-dimensional electrophoretic 'maps' of CNBr-cleavage peptides showed low recoveries of the C-terminal alpha 1(I) CB6 and alpha 1(III) CB9 peptides, which are involved in forming intermolecular cross-linkages. Most of the reducible cross-linkages were present in large-Mr peptide complexes, and these complexes were shown by labelling with 125I to include the tyrosine-containing alpha 1(I) CB6 peptide. The myxomatous valves contained 67% type I, 31% type III and 2% type V collagens. There was a significant increase in the concentration of each type of collagen, which consisted of a 9% increase of type I collagen, a 53% increase of type III collagen and a 25% increase of type V collagen. The contents of hydroxylysine in type I and III collagens and the electrophoretic 'maps' of the CNBr-cleavage peptides involved in cross-linkages did not differ significantly from the results obtained from the normal valves. The biochemical findings suggest that there is an increased production of collagen, in particular type III collagen, and glycosaminoglycan as well as a proliferation of cells as part of a repair process in the myxomatous valves.     

Coordinate regulation of type IX and type II collagen synthesis during growth of chick chondrocytes in retinoic acid or 5-bromo-2'-deoxyuridine

Chondrocytes isolated from 15-day-old embryonic chick sterna were cultured as monolayers for 7 days in control medium or in medium supplemented with retinoic acid or 5-bromo-2'-deoxyuridine. Control cells exhibited characteristic polygonal morphology and maintained the synthesis of cartilage-specific collagens, i.e. type II, type IX, 1 alpha, 2 alpha, and 3 alpha chains, and 45 K (presumptive type X). Type IX was the second most prevalent collagen and represented 12-15% of the phenotype. When exposed to retinoic acid, chrondrocytes displayed a fibroblast-like morphology and decreased collagen synthesis by day 2. The synthesis of collagen types II and IX declined in parallel along with that of the other cartilage collagens and ceased by day 7. During the same period, the synthesis of collagen types I, III, and V and two unidentified collagen chains was initiated and stimulated. Similar changes in collagen expression were caused by 5-bromo-2'-deoxyuridine but were delayed, beginning after day 4. Type III collagen, however, was never detected in 5-bromo-2'-deoxyuridine or control cultures. Because two different agents and two rates of modulation produced parallel changes in the synthesis of collagen types II and IX, these collagens appear to be coordinately regulated.     

Isolation and characterization of CNBr peptides of human (alpha 1 (III) )3 collagen and tissue distribution of (alpha 1 (I) )2 alpha 2 and (alpha 1 (III) )3 collagens.

[Alpha 1(III)]3 collagen was solubilized by pepsin digestion of normal human placental membranes and was purified by differential salt precipitation and carboxymethylcellulose chromatography. This collagen was digested with CNBr, and the resultant nine peptides were isolated and characterized. The chains are cross-linked by cysteinyl residues in the COOH-terminal peptide. Isolation of peptides derived from CNBr digestion of insoluble tissues was used as an assay for the presence of [alpha 1(I)]2alpha 2 and [alpha 1(III)]3 collagens. Both types are present in human skin, intestine, liver, spleen, kidney, lung, aorta, umbilical cord, placental membranes, and myocardium. Bone and tendon contain [alpha 1(I)]2alpha 2 collagen but, unlike the other tissues, lack [alpha 1(III)]3 collagen. Both [alpha 1(I)]2alpha 2 and[alpha 1(III)]3 collagens are present in scars of human skin, myocardium, tendon, and liver and of rabbit skin. The degree of hydroxylation of proline was 4 to 5% lower in the same peptides in skin, bone, and tendon than in the other tissues. The degree of hydroxylation of lysine in the same peptides derived from different tissues varied more widely.     

The degradation rates of type I, II, and III collagens by tadpole collagenase

The degradation rates of type I, II, and III collagens by tadpole collagenase were studied by measuring the viscosity of the solution and the contents of alpha chains and alpha A chains of collagen, using SDS-polyacrylamide gel electrophoresis followed by densitometric analysis of the separated peptide bands. An empirical parameter was derived from the viscosity, and was shown to change in parallel with the content of alpha chains upon incubation with tadpole collagenase almost to the stage of complete digestion of collagen. Linear plots of parameters reflecting the concentration of intact collagen molecules against time were obtained, indicating the degradation to be pseudo-first order. The first-order rate constants for the degradation of Type I, II, and III collagens with tadpole collagenase at 30, 25, and 20 degrees C gave activation energies of 60 kcal/mol for Type III collagen and 40 kcal/mol for Type I and II collagens. There appeared to be a dependency of the degradation rates on the conformation of the collagen molecules (which is affected by temperature).     

Unfolding intermediates in the triple helix to coil transition of bovine type XI collagen and human type V collagens alpha 1(2) alpha 2 and alpha 1 alpha 2 alpha 3

The thermal triple helix to coil transitions of two human type V collagens (alpha 1(2) alpha 2 and alpha 1 alpha 2 alpha 3) and bovine type XI collagen differ from those of the interstitial collagens type I, II, and III by the presence of unfolding intermediates. The total transition enthalpy of these collagens is comparable to the transition enthalpy of the interstitial collagens with values of 17.9 kJ/mol tripeptide units for type XI collagen, 22.9 kJ/mol for type V (alpha 1(2) alpha 2), and 18.5 kJ/mol for type V (alpha 1 alpha 2 alpha 3). It is shown by optical rotatory dispersion and differential scanning calorimetry that complex transition curves with stable intermediates exist. Type XI collagen has two main transitions at 38.5 and 41.5 degrees C and a smaller transition at 40.1 degrees C. Type V (alpha 1(2) alpha 2) shows two main transitions at 38.2 and 42.9 degrees C and two smaller transitions at 40.1 and 41.3 degrees C. Compared to these two collagens type V (alpha 1 alpha 2 alpha 3) unfolds at a lower temperature with two main transitions at 36.4 and 38.1 degrees C and two minor transitions at 40.5 and 42.9 degrees C. The intermediates present at different temperatures are characterized by resistance to trypsin digestion, length measurements of the resistant fragments after rotary shadowing, and amino-terminal sequencing. One of the intermediate peptides has been identified as belonging to the alpha 2 type V chain, starting at position 430 and being about 380 residues long. (The residue numbering begins with the first residue of the first amino-terminal tripeptide unit of the main triple helix. The alpha 2(XI) chain was assumed to be the same length as the alpha 1(XI). One intermediate was identified from the alpha 2(XI) chain and with starting position at residue 495, and three from the alpha 3(XI) with starting positions at residues 519, 585, and 618.     

Cleavage of Type II and III collagens with mammalian collagenase: site of cleavage and primary structure at the NH2-terminal portion of the smaller fragment released from both collagens.

Collagenase cleavage of human Type II and III collagens has been studied using a highly purified preparation of rabbit tumor collagenase. Progress of the reactions in solution was followed by viscometry and the results indicated that under the conditions employed Type III collagen molecules were cleaved at approximately five times the rate of Type II molecules. Cleavage products of the reactions were isolated in denatured form by agarose molecular sieve chromatography. The molecular weights and amino acid compositions of the products demonstrated that Type II and III molecules had been cleaved at the characteristic three-quarter, one-quarter locus, giving rise to a large fragment derived from the NH2-terminal portion of the molecule and a smaller fragment representing the COOH-terminal region. The amino acid sequence at the NH2-terminal portion of the smaller fragment derived from Type II collagen was determined to be Ile-Ala-Gly-Gln-Arg, and the corresponding region from Type III collagen was found to have the sequence Leu-Ala Gly-Leu-Arg. These sequences for alpha1(II) and alpha1(III) chains adjacent to the site of collagenase cleavage along with previous data for alpha1(I) and alpha2 chains indicate that the minimum specific sequence required for collagenase cleavage is Gly-Ile-Ala or Gly-Leu-Ala. Inspection of the available sequence data for collagen alpha chains indicates that the latter sequences are found in at least three additional locations at which collagenase cleavage does not occur. Each of the sequences which are apparently not substrates for collagenase, however, are followed by a Gly-X-Hyp sequence. We suggest, then, that a minimum of five residues in collagen alpha chains COOH-terminal to the cleavage site comprise the substrate recognition site.     

Age-related variations in hydroxylation of lysine and proline in collagen

The effect of age on the extent of hydroxylation of lysine and proline both generally and at certain specific sites in collagens from bone, skin and tendon was examined in the chick from the 14-day embryo to the 18-month-old adult. For all collagens there was a marked fall in the overall extent of hydroxylation of lysine with increasing age in both alpha(1) and alpha(2) chains, this fall occurring mostly in a relatively short period immediately after hatching. Hydroxylation of lysine declined to a constant value which, as expected, differed appreciably for each collagen and was considered to be characteristic of the collagen according to its tissue of origin. Hydroxylation of lysine in the N-terminal, non-helical telopeptide region of both alpha(1) and alpha(2) chains, which is important with regard to cross-linking, was relatively high in embryonic collagens. There was, however, a rapid loss of hydroxylation at these sites in skin collagen, occurring both during development of the embryo and in the period immediately after hatching. In contrast some hydroxylation at these sites persisted in bone and tendon collagens and, as judged by examination of peptide alpha(1)-CB1, appeared to reach a constant value in time of about 33% in bone and about 15% in tendon collagen. The actual extent of hydroxylation of lysine in the N-terminal telopeptides and the size of the changes in these values with age appeared to be unrelated to the corresponding whole-chain values, and it is suggested therefore that hydroxylation of telopeptidyl lysine may be under separate enzymic control. The increased hydroxylation of lysine in the embryo was accompanied by only minimal changes in proline hydroxylation, which was very slightly increased in embryonic bone and tendon collagens. Increased hydroxylation of proline in the embryo was, however, readily observed in peptide alpha(1)-CB2 from the helical region of tendon collagen. This hydroxylation was close to the theoretical maximum, in contrast with that observed in post-embryonic tendon, where hydroxylation was incomplete, as in rat tendon (Bornstein, 1967), only four on average, of the six susceptible proline residues being hydroxylated.     

Characterization of the tissue form of type V collagen from chick bone

Type V collagen was prepared from acetic acid extracts of lathyritic chick bone. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the extracted material demonstrated two collagenous bands of slower mobility than pepsin-extracted alpha 1(V) and alpha 2(V) chains. Cyanogen bromide peptide maps of these protein bands identified them as forms of alpha 1(V) and alpha 2(V). Segment long spacing (SLS) crystallite banding patterns of the acid-extracted Type V were identical within the triple-helical domain to the SLS banding patterns of pepsin-extracted Type V collagen, supporting the identification of this material. A globular domain at one end of the triple helix of the acid-extracted Type V was visualized by both rotary shadowing and negative staining of SLS crystallites. The molecular weights of the globular terminal peptides were 18,000 and 29,000, respectively, for alpha 1(V) and alpha 2(V), as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis after bacterial collagenase digestion of the isolated alpha chains. The results presented here indicate that fully processed Type V collagen in chick bone exists as a higher molecular weight form than that from pepsin extracts and retains a globular domain at one end of the triple helix. This is in contrast to the interstitial collagens in which only very small non-triple-helical domains (telopeptides) are retained in the fully processed molecules. In vitro aggregation studies demonstrated the intact fully processed form of Type V collagen forms uniform small-diameter fibrous structures. These results suggest that Type V collagen may be present in fibrous structures within tissues.     

Biosynthesis of skin collagens in normal and diabetic mice.

Synthesis of collagens in vitro was studied on minced mouse skins incubated with [3H]-proline in organ-culture conditions. A comparative study was carried out on genetically diabetic mice (KK strain) and control mice (Swiss strain). After incubation, neutral-salt-soluble and acid-soluble collagens were extracted. The insoluble dermis was digested by pepsin and type I and type III collagens separated by differential precipitation in neutral salt solutions. Type I and Type III collagens were characterized by ion-exchange and molecular-sieve chromatography, amino acid analysis and by the characterization of CNBr peptides. In diabetic-mouse skin, the relative proportion of type III collagen was significantly higher than in control-mouse skin. The incorporation of radioactively labelled proline into hydroxyproline of type III collagen was significantly faster in diabetic-mouse skin than in control-mouse skin.No significant modifications in the total collagen content of the skin or of their rates of synthesis were observed between the two strains. Alteration in the ratio of type III to type I collagen in the diabetic-mouse skin can be interpreted as a sign of alteration of the regulation of collagen biosynthesis and may be related to the structural alterations observed in the diabetic intercellular matrix.     

The differentiation of teratocarcinoma stem cells is marked by the types of collagen which are synthesized.

A cloned line of undifferentiated teratocarcinoma cells (OC15S1) was either maintained as a homogeneous embryonal carcinoma (EC) cell population or was cultured under conditions where the cells differentiated into endoderm-like (END) cells. In this study we examine the synthesis of collagen in both EC and END cells. Cell cultures were incubated with tritiated proline and lysine, and the radioactive collagen secreted into the medium was extracted and purified or immunoprecipitated by antibodies to type IV collagen (Adamson and Ayers, 1979). Radioactive collagens were identified by electrophoretic mobility, by sensitivity to collagenase and to reduction, by insensitivity to pepsin, by cyanogen bromide peptides, and by aminoacid analyses of 3-hydroxyproline, 4-hydroxyproline and proline. OC15S1 EC cells were found to synthesize several collagenous polypeptides, of which 60–70% of the radioactivity was like that of basement membrane (type IV) collagen. Type I-like collagen was the main collagenous product of END cells, but a minor product of EC cells. We concluded that type IV collagen synthesis was suppressed during the differentiation of EC cells to END, while type I-like synthesis was increased. Similarly, other EC cell lines produced mainly type IV-like collagen polypeptides (PC13, F9, PSA1), and following the formation of END cells, two lines produced mainly type I-like collagen polypeptides (PC13, C145b). The type of endoderm formed on embryoid bodies, however, presents an alternate route of differentiation, since immunoperoxidase tests showed that it was synthesizing significant amounts of type IV collagen. We discuss the significance of these findings in relation to a similar change which occurs during normal development.     

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)