The collagenous protein with elastin crosslinks from Descemet's membrane is not related to type VIII collagen

A collagen-like insoluble protein containing the elastin cross-links (desmosine and isodesmosine) has been isolated from Descemet's membrane. Recently type VIII collagen (endothelial collagen) has been shown to be a major constituent of this membrane. Biochemical studies suggest that these two proteins are unrelated. The cyanogen bromide peptide maps show negligible similarity. Antiserum raised against oxalic acid digests of elastin (alpha-elastin) did not react against an oxalic acid digests of type VIII collagen but did show some reaction against the cross-linked preparation. Immunofluorescent localization has demonstrated the presence of type VIII collagen in trachea but a desmosine cross-linked collagen could not be isolated from this tissue.     

Human macrophages synthesize type VIII collagen in vitro and in the atherosclerotic plaque.

Type VIII collagen is a short-chain collagen that is present in increased amounts in atherosclerotic lesions. Although the physiological function of this matrix protein is unclear, recent data suggest an important role in tissue remodeling. Type VIII collagen in the atherosclerotic lesion is mainly derived from smooth muscle cells. We now show that macrophages in the atherosclerotic vessel wall and monocytes in adjacent mural thrombi also express type VIII collagen. We demonstrated this using a novel combined fluorescence technique that simultaneously stains, within the same tissue section, specific RNAs by in situ hybridization and proteins by indirect immunofluorescence. In culture, human monocyte/macrophages expressed type VIII collagen at all time points from 1 h to 3 wk after isolation. Western blotting and immunoprecipitation also revealed secretion of type VIII collagen into the medium of 14-day-old macrophages. Because this is the first report of secretion of a collagen by macrophages, we tested the effect of lipopolysaccharide (LPS) and interferon gamma, substances that stimulate macrophages to secrete lytic enzymes, on macrophage expression of type VIII collagen. LPS and interferon gamma decreased expression of type VIII collagen. By contrast, secretion of matrix metalloproteinase 1 (MMP 1) was increased, indicating a switch from a collagen-producing to a degradative phenotype. Double in situ hybridization studies of expression of type VIII collagen and MMP 1 in human coronary arteries showed that in regions important for plaque stability, the ratio of MMP 1 RNA to macrophage type VIII collagen RNA varies widely, indicating that the transition from one phenotype to the other that we observed in vitro may also occur in vivo.     

Astrocytes express type VIII collagen during the repair process of brain cold injury

We recognized for the first time upregulation of type VIII collagen gene expression during the repair process in the mouse brain cold injury model. Immunohistochemical staining showed that type VIII collagen expression was around the necrotic region, where reactive astrocytes are frequently observed. Cultured astrocytes demonstrated a high expression of type VIII collagen genes. TGF-beta1 enhanced the expression of both alpha1(VIII) and alpha2(VIII) genes by astrocytes in culture. Further, we tested selected biological activities of type VIII collagen, compared with those of type I, IV, and V collagens and fibronectin. Astrocytes adhered to type VIII collagen via receptors requiring metal ions. Astrocyte migration on type VIII collagen was more stimulated than that observed on the other ECM molecules. These data indicate that type VIII collagen plays an important role in glial scar formation during the repair process by astrocytes.     

Type VIII collagen has a restricted distribution in specialized extracellular matrices

A pepsin-resistant triple helical domain (chain 50,000 Mr) of type VIII collagen was isolated from bovine corneal Descemet's membrane and used as an immunogen for the production of mAbs. An antibody was selected for biochemical and tissue immunofluorescence studies which reacted both with Descemet's membrane and with type VIII collagen 50,000-Mr polypeptides by competition ELISA and immunoblotting. This antibody exhibited no crossreactivity with collagen types I-VI by competition ELISA. The mAb specifically precipitated a high molecular mass component of type VIII collagen (EC2, of chain 125,000 Mr) from the culture medium of subconfluent bovine corneal endothelial cells metabolically labeled for 24 h. In contrast, confluent cells in the presence of FCS and isotope for 7 d secreted a collagenous component of chain 60,000 Mr that did not react with the anti-type VIII collagen IgG. Type VIII collagen therefore appears to be synthesized as a discontinuous triple helical molecule with a predominant chain 125,000 Mr by subconfluent, proliferating cells in culture. Immunofluorescence studies with the mAb showed that type VIII collagen was deposited as fibrils in the extracellular matrix of corneal endothelial cells. In the fetal calf, type VIII collagen was absent from basement membranes and was found in a limited number of tissues. In addition to the linear staining pattern observed in the Descemet's membrane, type VIII collagen was found in highly fibrillar arrays in the ocular sclera, in the meninges surrounding brain, spinal cord, and optic nerve, and in periosteum and perichondrium. Fine fibrils were evident in the white matter of spinal cord, whereas a more generalized staining was apparent in the matrices of cartilage and bone. Despite attempts to unmask the epitope, type VIII collagen was not found in aorta, kidney, lung, liver, skin, and ligament. We conclude that this unusual collagen is a component of certain specialized extracellular matrices, several of which are derived from the neural crest.     

Characteristics and in vivo occurrence of type VIII collagen

Type VIII collagen was isolated from bovine Descemet's membranes by pepsin treatment and salt fractionation, as described by Kapoor et al. [(1986) Biochemistry 25, 3930-3937]. Contaminating type IV collagen was removed by ion-exchange chromatography. Purified type VIII collagen consisted of two different polypeptide chains and, compared to the fiber forming collagens, showed a higher thermal stability. Corresponding fractions isolated from pepsinized human Ewing's sarcoma and fetal calf aorta reacted immunologically with a protein of similar molecular mass. After extraction of Descemet's membranes with guanidine hydrochloride, a peptide of about 60 kDa was obtained. This seems to be the tissue form of type VIII collagen.     

Expression of type VIII collagen during morphogenesis of the chicken and mouse heart.

The expression of type VIII collagen is restricted, in adult mammals, to specialized extracellular matrices and to a select subset of blood vessels. We have examined the distribution of type VIII collagen in sequential stages of mouse and chicken embryos and found a temporal and spatially restricted pattern of expression during cardiogenesis. Type VIII collagen was first detected by immunocytochemistry on Day 11 in the developing mouse embryo and at stage 19 in the chicken embryo. The distribution of this protein was rapidly modulated during cardiac morphogenesis. Initially (Day 11 in the mouse embryo), type VIII collagen was associated with cardiac myoblasts. From Days 15 to 18, the immunoreactive component was progressively diminished in the myocardium; however, this collagen was observed in the subendocardial layer of the atrioventricular canal and later in the cardiac jelly (or the myocardial basement membrane, an area associated with the formation of cardiac valves). On Day 17, type VIII collagen was also detected in the subendothelium (intima) and tunica media of large vessels. Neonatal and adult hearts contained low to undetectable levels of type VIII collagen. The presence of type VIII collagen was confirmed by immunoblot analysis of heart extracts at different stages of development. A major 185-kDa component, as well as polypeptides of 68 and 15 kDa, reacted with anti-type VIII collagen IgG. Exposure of heart extracts to hyaluronidase or reducing agent eliminated immunoreactivity of the 185-kDa component but not that of the 68- and 15-kDa polypeptides. Type VIII collagen therefore appears to be associated with a hyaluronidase-sensitive component of the extracellular matrix during a temporally restricted stage of embryonic cardiogenesis. The contribution of this collagen to cardiac morphogenesis might reside, in part, in its ability to influence the differentiation of the myocardium and formation of the cardiac valves.     

Crystal structure of the collagen alpha1(VIII) NC1 trimer.

Collagen VIII is a major component of Descemet's membrane and is also found in vascular subendothelial matrices. The C-terminal non-collagenous domain (NC1) domain of collagen VIII, which is a member of the C1q-like protein family, forms a stable trimer and is thought to direct the assembly of the collagen triple helix, as well as polygonal supramolecular structures. We have solved the crystal structure of the mouse alpha1(VIII)(3) NC1 domain trimer at 1.9 A resolution. Each subunit of the intimate NC1 trimer consists of a ten-stranded beta-sandwich. The surface of the collagen VIII NC1 trimer presents three strips of partially exposed aromatic residues shown to interact with the non-ionic detergent CHAPS, which are likely to be involved in supramolecular assemblies. Equivalent strips exist in the NC1 domain of the closely related collagen X, suggesting a conserved assembly mechanism. Surprisingly, the collagen VIII NC1 trimer lacks the buried calcium cluster of the collagen X NC1 trimer. The mouse alpha1(VIII) and alpha2(VIII) NC1 domains are 71.5% identical in sequence, with the differences being concentrated on the NC1 trimer surface. A few non-conservative substitutions map to the subunit interfaces near the surface, but it is not obvious from the structure to what extent they determine the preferred assembly of collagen VIII alpha1 and alpha2 chains into homotrimers.     

The alpha 1 chain of type VIII collagen is associated with many but not all microfibrils of elastic fiber system.

The antigen of monoclonal antibodies which had labeled the hexagonal lattice of Descemet's membrane in a specific manner was shown to be the alpha 1 chain of type VIII collagen by immunoblotting followed by amino acid sequence analysis. With this antibody, the localization of alpha 1 (VIII) in various tissues was studied by several immunocytochemical methods. Under light microscopy, the alpha 1 (VIII) was found in a fine fibrillar form in various capsular tissues such as capsules of the liver, kidneys, adrenals, lungs and so on. It was also present in dense connective tissues such as the Achilles tendon, and periodontal and perivertebral ligaments. When some dense connective tissues which had been negative to the label including the intima of aorta, perimysium and Glisson's sheath of the liver, were subjected to pepsin digestion, epitopes were revealed which showed a specific immunofluorescence pattern. In many locations the pattern of localization coincided with that of elastic fiber components, and full or partial colocalization with tropoelastin or costaining with resorcin-fuchsin staining was observed. In immunoelectron microscopy, the antigen (alpha 1 (VIII)) was localized on the surface of, but not inside, elastic fibers. However, some tissues which are rich in elastic fibers or microfibrils remained unlabeled. These included elastic fibers of the aortic media and ligamentum nuchae as well as ciliary zonules. Therefore it is suggested that alpha 1 (VIII) is a collagen associated with microfibrils of some elastic fiber systems, but is not an intrinsic component of either elastic fibers or of microfibrils.     

The alpha 1 (VIII) collagen gene is homologous to the alpha 1 (X) collagen gene and contains a large exon encoding the entire triple helical and carboxyl-terminal non-triple helical domains of the alpha 1 (VIII) polypeptide

We recently cloned and sequenced alpha 1 (VIII) collagen cDNAs and demonstrated that type VIII collagen is a short-chain collagen that contains both triple helical and carboxyl-terminal non-triple helical domains similar to those of type X collagen (Yamaguchi, N., Benya, P., van der Rest, M., and Ninomiya, Y. (1989) J. Biol. Chem. 264, 16022-16029). We report here on the structural organization of the gene encoding the rabbit alpha 1 (VIII) collagen chain. The alpha 1 (VIII) gene contains four exons, whose sizes are 69, 120, 331, and 2278 base pairs. The first and second exons encode only 5'-untranslated sequences, whereas the third exon codes for a very short (3 nucleotides) stretch of 5'-untranslated sequence, the signal peptide, and almost the entire amino-terminal non-triple helical (NC2) domain (109 1/3 codons). Interestingly, the last exon encodes the rest of the translated region, including 7 2/3 codons of the NC2 domains, the complete triple helical domain (COL1, 454 amino acid residues), the entire carboxyl-terminal non-triple helical domain (NC1, 173 amino acid residues), and the 3'-untranslated region. This exon-intron structure is in stark contrast to the multi-exon structure of the fibrillar collagen (types I, II, III, V, and XI) genes, but it is remarkably similar to that of the type X collagen gene (LuValle, P., Ninomiya, Y., Rosenblum, N. D., and Olsen, B. R. (1988) J. Biol. Chem. 263, 18278-18385). The data suggest that the alpha 1 (VIII) and the alpha 1 (X) genes belong to the same subclass within the collagen family and that they arose from a common evolutionary precursor.     

The alpha 2(VIII) collagen gene. A novel member of the short chain collagen family located on the human chromosome 1

Type VIII collagen is a major component of Descemet's membrane, the specialized basement membrane of corneal endothelial cells. Sequence analysis of a cDNA isolated from a library made with mRNA from rabbit corneal endothelial cells has indicated that type VIII molecules contain a polypeptide chain, alpha 1(VIII), consisting of a short triple-helical domain of 454 amino acid residues flanked by non-triple-helical domains of 117 and 173 amino acid residues at the amino and carboxyl ends, respectively (Yamaguchi, N., Benya, P. D., van der Rest, M., and Ninomiya, Y. (1989) J. Biol. Chem. 264, 16022-16029). The sequence of alpha 1(VIII) is strikingly similar to that of alpha 1(X) collagen, a product of hypertrophic chondrocytes. Also, characterization of the alpha 1(VIII) and alpha 1(X) collagen genes has shown that they are quite similar in their exon organization. It has been concluded, therefore, that they are homologous members of a distinct subclass of collagen genes (Yamaguchi, N., Mayne, R., and Ninomiya, Y. (1991) J. Biol. Chem. 266, 4508-4513). We have given this subclass the name short chain collagens because of the relatively small size of the triple-helical domain. In the present study, we report on the identification and characterization of a collagen gene encoding a polypeptide which is co-expressed with the alpha 1(VIII) chain in corneal endothelial cells. This collagen chain contains a triple-helical and a carboxyl non-triple-helical domain encoded by a single, large exon both in mice and humans. We conclude, therefore, that the genes encodes a novel member of the short chain collagen family, and we have given this chain the designation alpha 2(VIII) collagen. By in situ hybridization we demonstrate that the alpha 2(VIII) gene is located in the p32.3-p34.3 region of the short arm of chromosome 1.     

Type VIII collagen signals via β1 integrin and RhoA to regulate MMP-2 expression and smooth muscle cell migration

The extracellular matrix signals and regulates the behavior of vascular cells during the pathogenesis of atherosclerosis. Type VIII collagen, a short chain collagen, is scarcely present in normal arteries, but is dramatically upregulated in atherosclerosis and after other types of vascular injury. Cell culture studies have revealed that this protein supports smooth muscle cell (SMC) adhesion and stimulates migration, however little is known about the signaling or the mechanisms by which this occurs. SMCs isolated from wild-type C57BL/6 and type VIII collagen deficient mice were studied using assays to measure chemotactic and haptotactic migration, and remodeling and contraction of 3-dimensional type I collagen gels. Col8^?/? SMCs exhibited impairments in migration, and a strongly adhesive phenotype with prominent stress fibers, stable microtubules and pronounced central basal focal adhesions. The addition of exogenous type VIII collagen to the Col8^?/? SMCs rescued the impairments in migration, and restored cytoskeletal architecture so that it was similar to Col8^+/+ cells. We measured elevated levels of active GTP-RhoA in the Col8^?/? cells, and this too was reversed by treatment with exogenous type VIII collagen. We showed that type VIII collagen normally suppresses RhoA activation through a beta-1 integrin dependent mechanism. MMP-2 levels were reduced in the Col8^?/? SMCs, and knockdown of MMP-2 in Col8^+/+ SMCs partially recapitulated the decreases in migration and 3D gel contraction seen in Col8^?/? cells, showing that type VIII collagen-stimulated migration was dependent on MMP-2. Inhibition of Rho restored MMP-2 activity in the Col8^?/? cells, and partially rescued migration, demonstrating that the elevations in RhoA activity were responsible for the suppression of migration of these cells. In conclusion, we have shown that type VIII collagen signals through beta-1 integrin receptors to suppress RhoA, allowing optimal configuration of the cytoskeleton, and the stimulation of MMP-2-dependent cell migration.     

Cleavage of type VIII collagen by human neutrophil elastase.

In this report, the susceptibility of type VIII collagen to human neutrophil elastase is compared to other extracellular matrix components. Type X collagen is degraded to specific fragments at a substrate to enzyme ratio of 5:1 after 20 h at room temperature, but type VIII collagen is almost completely degraded after only 4 h incubation at a substrate to enzyme ratio of 50:1 and partly degraded after only 15 min. Laminin, merosin and types I, III, IV and V collagen exhibit no susceptibility to neutrophil elastase under the latter conditions, while fibronectin is degraded.     

Histochemical specifity of staining methods for connective tissue fibers: Resorcin-fuchsin and van Gieson's picro-fuchsin

Conclusions and summary Depending on the pretreatment of tissue sections, resorcin-fuchsin stained collagen, reticulum fibers and/or basement membranes and ring fibers intensely. It must therefore be concluded that resorcin-fuchsin is not specific for the protein elastin, that is elastic fibers in the chemical sense of the term.Studies of van Gieson-type stains showed relation between dye structure and affinity for connective tissue fibers. These observations are in good agreement with data from textile and leather dyeing that the behaviour of sulfonated dyes is largely determined by the configuration of the dye molecule and the presence of additional reactive groups.Polarization microscopic studies of stained sections — based on data derived from textile chemistry — demonstrated the possibility to obtain information concerning the submicroscopic structure of tissue components. Several methods, though still in the experimental stage, have been found valuable for the study of pathological lesions of connective tissue. Because electron microscopy is unsuitable for routine histopathology, it is highly desirable to develop convenient methods for the study of submicroscopic structures in general hospital pathology.Paper presented at the International Collagen Symposium in connection with the VIII. Congress of the International Union of Leather Chemists Societies, Den Haag, Netherlands, 1963.     

Localization and synthesis of type III collagen and fibronectin in human reparative dentine

Summary The injury of dental pulp tissue, following caries, is accompanied by the deposit of a typical hard scar tissue known as reparative dentine which should be regarded as the mineralization of a new organic matrix. Highly purified antibodies were used in combination with immunoperoxidase or immunogold technique at the ultrastructural level to reveal the distribution and synthesis of types I and III collagen and fibronectin elaborated by typical matrix-forming cells in the new tissue.Specific immunoperoxidase labelling, on demineralized teeth, clearly demonstrated that type I collagen represents the main type of collagen (88%). It is associated with bundles of fine striated fibrils of type III collagen and in close vicinity with fibronectin and constituted, at least, the new organic matrix of reparative dentine.Immunogold staining gave precise localization mainly over Golgi apparatus for the 3 components, thus suggesting that the cells concerned should not be considered as new odontoblasts but rather as pulpal cells in the process of differentiation participating in the formation of new dentine. Moreover, these events are very similar to those observed during wound healing in other tissues.     

Collagen-bound von Willebrand factor has reduced affinity for factor VIII

von Willebrand factor (vWf) is a multimeric adhesive glycoprotein that serves as a carrier for factor VIII in plasma. Although each vWf subunit displays a high affinity binding site for factor VIII in vitro, in plasma, only 2% of the vWf sites for factor VIII are occupied. We investigated whether interaction of plasma proteins with vWf or adhesion of vWf to collagen may alter the affinity or availability of factor VIII-binding sites on vWf. When vWf was immobilized on agarose-linked monoclonal antibody, factor VIII bound to vWf with high affinity, and neither the affinity nor binding site availability was influenced by the presence of 50% plasma. Therefore, plasma proteins do not alter the affinity or availability of factor VIII-binding sites. In contrast, when vWf was immobilized on agarose-linked collagen, its affinity for factor VIII was reduced 4-fold, with KD increasing from 0.9 to 3.8 nM. However, one factor VIII-binding site remained available on each vWf subunit. A comparable reduction in affinity for factor VIII was observed when vWf was a constituent of the subendothelial cell matrix and when it was bound to purified type VI collagen. In parallel with the decreased affinity for factor VIII, collagen-bound vWf displayed a 6-fold lower affinity for monoclonal antibody W5-6A, with an epitope composed of residues 78-96 within the factor VIII-binding motif of vWf. We conclude that collagen induces a conformational change within the factor VIII-binding motif of vWf that lowers the affinity for factor VIII.     

Localization and synthesis of type III collagen and fibronectin in human reparative dentine. Immunoperoxidase and immunogold staining

The injury of dental pulp tissue, following caries, is accompanied by the deposit of a typical hard scar tissue known as reparative dentine which should be regarded as the mineralization of a new organic matrix. Highly purified antibodies were used in combination with immunoperoxidase or immunogold technique at the ultrastructural level to reveal the distribution and synthesis of types I and III collagen and fibronectin elaborated by typical matrix-forming cells in the new tissue. Specific immunoperoxidase labelling, on demineralized teeth, clearly demonstrated that type I collagen represents the main type of collagen (88%). It is associated with bundles of fine striated fibrils of type III collagen and in close vicinity with fibronectin and constituted, at least, the new organic matrix of reparative dentine. Immunogold staining gave precise localization mainly over Golgi apparatus for the 3 components, thus suggesting that the cells concerned should not be considered as new odontoblasts but rather as pulpal cells in the process of differentiation participating in the formation of new dentine. Moreover, these events are very similar to those observed during wound healing in other tissues.     

Expression and supramolecular assembly of recombinant alpha1(viii) and alpha2(viii) collagen homotrimers

Collagen VIII is an extracellular matrix macromolecule comprising two polypeptide chains, alpha1(VIII) and alpha2(VIII), that can form homotrimers in vitro and in vivo. Here, recombinant collagen VIII was expressed to study its supramolecular assembly following secretion. Cells transfected with alpha1(VIII) or alpha2(VIII) assembled and secreted homotrimers that were stable in denaturing conditions and had a molecular mass of approximately 180 kDa on SDS-PAGE gels. Co-transfection with prolyl 4-hydroxylase generated homotrimers with stable pepsin-resistant triple-helical domains. Size fractionation of native recombinant collagen VIII molecules expressed with or without prolyl 4-hydroxylase identified urea-sensitive high molecular mass assemblies eluting in the void volume of a Superose 6HR 10/30 column and urea-resistant assemblies of approximately 700 kDa, all of which were composed of homotrimers. Immunofluorescence analysis highlighted the extracellular deposition of recombinant alpha1(VIII)(3), alpha2(VIII)(3), and co-expressed alpha1(VIII)(3)/alpha2(VIII)(3). Microscopy analysis of recombinant collagen VIII identified rod-like molecules of 134 nm in length that assembled into angular arrays with branching angles of approximately 114 degrees and extensive networks. Based on these data, we propose a model of collagen VIII assembly in which four homotrimers form a tetrahedron stabilized by central interacting C-terminal NC1 trimers. Tetrahedrons may then act as building blocks of three-dimensional hexagonal lattices generated by secondary interactions involving terminal and helical sequences.     

Production of type VI collagen by human macrophages: a new dimension in macrophage functional heterogeneity

Macrophages derived from human blood monocytes perform many tasks related to tissue injury and repair. The main effect of macrophages on the extracellular matrix is considered to be destructive in nature, because macrophages secrete metalloproteinases and ingest foreign material as part of the remodeling process that occurs in wound healing and other pathological conditions. However, macrophages also contribute to the extracellular matrix and hence to tissue stabilization both indirectly, by inducing other cells to proliferate and to release matrix components, and directly, by secreting components of the extracellular matrix such as fibronectin and type VIII collagen, as we have recently shown. We now report that monocytes and macrophages express virtually all known collagen and collagen-related mRNAs. Furthermore, macrophages secrete type VI collagen protein abundantly, depending upon their mode of activation, stage of differentiation, and cell density. The primary function of type VI collagen secreted by macrophages appears to be modulation of cell-cell and cell-matrix interactions. We suggest that the production of type VI collagen is a marker for a nondestructive, matrix-conserving macrophage phenotype that could profoundly influence physiological and pathophysiological conditions in vivo.