Marko Rehn

The Short and Long Forms of Type XVIII Collagen Show Clear Tissue Specificities in Their Expression and Location in Basement Membrane Zones in Humans

Two N-terminal ends of human type XVIII collagen chains have recently been identified. The two chains have different signal peptides and variant N-terminal noncollagenous NC1 domains of 493 (NC1-493) and 303 (NC1-303) amino acid residues, respectively, but share 301 residues of their NC1 domains as well as the collagenous and C-terminal noncollagenous portions of the molecule. Antibodies were produced against the NC1 region common to both human alpha1(XVIII) chain variants and against NC1 sequences specific to the long variant and were used in combination with in situ hybridization to localize this collagen in a number of human tissues. They were also used for Western blotting, which resulted in detection of overlapping high-molecular weight bands above the 200-kd standard in a kidney extract. Heparin lyase II and heparin lyase III digestions of kidney and placenta extracts indicated that at least in these tissues, type XVIII collagen contains heparin sulfate glycosaminoglycan side chains. Type XVIII collagen was found to be a ubiquitous basement membrane component, occurring prominently at vascular and epithelial basement membranes throughout the body. Comparison of the expression of the NC1-493 and NC1-303 variants revealed marked differences. The short variant was found in most conventional basement membranes, including blood vessels and the various epithelial structures, and around muscular structures. The long variant was expressed very strongly in liver, where it was virtually the only variant in the liver sinusoids, and it occurred only in minor amounts elsewhere. Thus, the 192 N-terminal residues specific to the long variant apparently confer some functional property needed above all in the liver sinusoids, but also at certain other locations.

Two New Collagen Subgroups: Membrane-associated Collagens and Types XV and XVIII

Publisher Summary This chapter discusses the two new subgroups among the large collagen gene family, the membrane-associated collagens, types XIII and XVII, and the subgroup formed, by collagen types XV and XVIII. Variant transcripts of collagens are discussed, as this phenomenon is pertinent for the members of both the new subgroups. The categorization of all known members of the collagen family into subgroups is also discussed in the chapter. The collagen types are numbered, by Roman numerals, in order of their discovery and the α- chains found in each collagen type are identified with Arabic numerals. Because some collagens consist of two or even more genetically distinct α-chains, over 30 genes exist to code for the constituent chains. In addition, several other proteins contain triple-helical Gly-X-Y sequences but are not formally classified as collagens, as they are not the structural components of the extracellular matrix. The significance of collagen types XIII, XV, and XVIII, identified solely on the grounds of their repetitive Gly-X-Y sequence, can only be fully assessed from a genetic analysis of mutations in the respective genes. It is, thus, hoped that gene “knockout” experiments in transgenic mice and the introduction of dominant-negative collagen mutations into mice will result in increased understanding of the function of these collagens. Furthermore, much information is needed on the chemical and physical nature of the proteins and their interactions in their native environment.

Type XIII collagen: a novel cell adhesion component present in a range of cell–matrix adhesions and in the intercalated discs between cardiac muscle cells

Recent analysis of type XIII collagen surprisingly showed that it is anchored to the plasma membranes of cultured cells via a transmembrane segment near its amino terminus. Here we demonstrate that type XIII collagen is concentrated in cultured skin fibroblasts and several other human mesenchymal cell lines in the focal adhesions at the ends of actin stress fibers, co-localizing with the known focal adhesion components talin and vinculin. This co-occurrence was also observed in rapidly forming adhesive structures of spreading and moving fibroblasts and in disrupting focal adhesions following microinjection of the Rho-inhibitor C3 transferase into the cells, suggesting that type XIII collagen is an integral focal adhesion component. Moreover, it appears to have an adhesion-related function since cell-surface expression of type XIII collagen in cells with weak basic adhesiveness resulted in improved cell adhesion on selected culture substrata. In tissues type XIII collagen was found in a range of integrin-mediated adherens junctions including the myotendinous junctions and costameres of skeletal muscle as well as many cell-basement membrane interfaces. Some cell-cell adhesions were found to contain type XIII collagen, most notably the intercalated discs in the heart. Taken together, the results strongly suggest that type XIII collagen has a cell adhesion-associated function in a wide array of cell-matrix junctions.

The frizzled motif: in how many different protein families does it occur?

Note: Collagen Research Unit, University of Oulu, Finland. marko.rehn@oulu.fi Reference GR-BUCHER-ARTICLE-1998-006doi:10.1016/S0968-0004(98)01290-0 Record created on 2007-12-17, modified on 2017-05-12

Characterization of the human type XVIII collagen gene and proteolytic processing and tissue location of the variant containing a frizzled motif.

Human type XVIII collagen was found to be expressed as three variants, termed NC1-303, NC1-493 and NC1-728, differing in their N-terminal non-collagenous domains (NC1). The corresponding gene was found to be approximately 105 kb in size and contain 43 exons. The short variant is derived from utilization of an upstream promoter associated with the first two exons of the gene. The two other variants are derived from a downstream promoter and alternative splicing of exon 3, resulting in 192 residues of shared sequences characterized by a putative approximately 30 residue conserved coiled-coil motif and 235 residues of sequences specific to NC1-728. The NC1-728 variant has a conserved cysteine-rich domain homologous with the ligand-binding part of the frizzled proteins. A polyclonal antibody specific to the NC1-728 variant was generated, and immunostaining of fetal tissues revealed staining in lung and skeletal muscle. Human serum contained 173- and 144-kDa alpha1(XVIII) chains corresponding to the NC1-728 and NC1-493 variants, respectively. A 200-kDa polypeptide was detected in cells transfected with a cDNA construct corresponding to the full-length NC1-728 variant, and EBNA-293 cells endogenously synthesizing low amounts of type XVIII collagen had a 45-kDa fragment in their culture medium that corresponded to most of the NC1 domain of the NC1-728 variant, suggesting processing of the N-terminal frizzled-containing domain.

Endostatin Overexpression Specifically in the Lens and Skin Leads to Cataract and Ultrastructural Alterations in Basement Membranes

Endostatin, a proteolytic fragment of type XVIII collagen, has been shown to inhibit angiogenesis, tumor growth, and endothelial cell proliferation and migration. We analyzed its functions in vivo by generating transgenic mice in which it was overexpressed in the skin and lens capsule under the keratin K14 promoter. Opacity of the lens occurred at 4 months of age in the mouse line J4, with the highest level of endostatin expression. The lens epithelial cells appeared to lose contact with the capsule and began to vacuolize. In 1-year-old mice the lens epithelial cell layer had entirely degenerated, and instead, large plaques of spindle-shaped cells had formed in the anterior region of the lens. Moreover, a widening of the epidermal basement membrane (BM) zone of the skin was observed in electron microscopy. The epidermal BM was conspicuously altered in the J4 mice with high transgene expression, including clear broadening and occurrence of pearl-like protrusions in some areas, whereas the BM was more even in appearance but consistently broadened in the mouse line G20 with moderate transgene expression. In both lines the BM was continuous. Measurements indicated that the lamina densa was 78.54 +/- 53.10 nm in line J4, the large variation reflecting the protrusions of the lamina densa, and 44.24 +/- 11.52 nm in line G20, compared with 33.74 +/- 9.96 nm in wild-type adult mice. Immunoelectron microscopy of wild-type mouse skin type XVIII collagen showed a polarized orientation in the BMs, with the C-terminal endostatin region localized in the lamina densa and the N terminus in average approximately 40 nm more on the dermal side. Type XVIII collagen was dispersed in the transgenic skin, suggesting that the transgene-derived endostatin fragment displaces the full-length collagen XVIII. This may impair the anchoring of the lamina densa to the dermis and thereby lead to loosening of the BMs, resembling the previously observed situation in collagen XVIII-null mice.

Physical mapping of mouse collagen genes on Chromosome 10 by high-resolution FISH

Abstract. Fluorescence in situ hybridization (FISH) on mechanically stretched chromosomes (MSCs) and extended DNA fibers enables construction of high-resolution physical maps by accurate ordering and orienting genomic clones as well as by measuring physical lengths of gaps and overlaps between them. These high-resolution FISH targets have hitherto been used mainly in the study of the human genome. Here we have applied both MSCs and extended DNA fibers to the physical mapping of the mouse genome. At first, five mouse collagen genes were localized by metaphase-FISH: Col10a1 to chromosomal bands 10B1-B3; Col13a1 to 10B4; and Col6a1, Col6a2, and Col18a1 to 10B5-C1. The mutual order of the genes, centromere–Col10a1–Col13a1–Col6a2–Col6a1–Col18a1–telomere, was determined by FISH on metaphase chromosomes, MSCs, and extended DNA fibers. To our knowledge, this is the first time mouse metaphase chromosomes have been stretched and used as targets for FISH. We also used MSCs to determine the transcriptional orientations, telomere–5′→3′–centromere, of both Col13a1 and Col18a1. With fiber-FISH, Col18a1, Col6a1, and Col6a2 were shown to be in a head-to-tail configuration with respective intergenic distances of about 350 kb and 90 kb. Comparison of our physical mapping results with the homologous human data reveals both similarities and differences concerning the chromosomal distribution, order, transcriptional orientations, and intergenic distances of the collagen genes studied.