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.

A short sequence in the N-terminal region is required for the trimerization of type XIII collagen and is conserved in other collagenous transmembrane proteins.

The recombinant transmembrane protein type XIII collagen is shown to reside on the plasma membrane of insect cells in a 'type II' orientation. Expressions of deletion constructs showed that sequences important for the association of three alpha1(XIII) chains reside in their N- rather than C-terminal portion. In particular, a deletion of residues 63-83 immediately adjacent to the transmembrane domain abolished the formation of disulfide-bonded trimers. The results imply that nucleation of the type XIII collagen triple helix occurs at the N-terminal region and that triple helix formation proceeds from the N- to the C-terminus, in opposite orientation to that of the fibrillar collagens. Interestingly, a sequence homologous to the deleted residues was found at the same plasma membrane-adjacent location in other collagenous transmembrane proteins, suggesting that it may be a conserved association domain. The type XIII collagen was secreted into insect cell medium in low amounts, but this secretion was markedly enhanced when the cytosolic portion was lacking. The cleavage occurred in the non-collagenous NC1 domain after four arginines and was inhibited by a furin protease inhibitor.

Type XIII collagen is identified as a plasma membrane protein.

The complete primary structure of the mouse type XIII collagen chain was determined by cDNA cloning. Comparison of the mouse amino acid sequences with the previously determined human sequences revealed a high identity of 90%. Surprisingly, the mouse cDNAs extended further in the 5' direction than the previously identified human clones. The 5' sequences contained a new in-frame ATG codon for translation initiation which resulted in elongation of the N-terminal noncollagenous domain by 81 residues. These N-terminal sequences lack a typical signal sequence but include a highly hydrophobic segment that clearly fulfills the criteria for a transmembrane domain. The sequence data thus unexpectedly suggested that type XIII collagen may be located on the plasma membrane, with a short cytosolic N-terminal portion and a long collagenous extracellular portion. These sequence data prompted us to generate antipeptide antibodies against type XIII collagen in order to study the protein and its subcellular location. Western blotting of human tumor HT-1080 cell extract revealed bands of over 180 kDa. These appeared to represent disulfide-bonded multimeric polypeptide forms that resolved upon reduction into 85-95-kDa bands that are likely to represent a mixture of splice forms of monomeric type XIII collagen chains. These chains were shown to contain the predicted N-terminal extension and thus also the putative transmembrane segment. Immunoprecipitation of biotinylated type XIII collagen from surface-labeled HT-1080 cells, subcellular fractionation, and immunofluorescence staining were used to demonstrate that type XIII collagen molecules are indeed located in the plasma membranes of these cells.

Decorin regulates collagenase gene expression in fibroblasts adhering to vitronectin.

Vitronectin, a principal cell adhesion molecule in plasma and extracellular matrix, mediates cell adhesion and spreading via the alpha V family of integrins. In this study we demonstrate that decorin, a small dermatan sulfate proteoglycan, regulates extracellular matrix remodeling in rabbit synovial fibroblasts adhering to vitronectin. Decorin induced the expression of the matrix metalloproteinase collagenase (MMP-1) when present on the substrate with vitronectin, or with the 120-kDa cell-binding domain of fibronectin, but not when present with intact fibronectin or Type I collagen. Secreted collagenase was detected within 8 h of adhesion, there was no associated alteration in cell shape or focal contact formation in cells adhering to decorin plus vitronectin, whereas cell rounding was observed in cells adhering to decorin plus the 120-kDa fragment of fibronectin. The core protein of decorin, but not the glycosaminoglycan moiety, was sufficient to induce collagenase expression on both substrates; however, the glycosaminoglycan moiety of decorin as well as the core were required for cell rounding observed in cells adhering to the 120-kDa domain of fibronectin. The collagenase-inducing effect of decorin seems to be independent of its effects on transforming growth factor-beta, as function-blocking antibodies against transforming growth factor-beta did not interfere with the collagenase-inducing effects of decorin. These data indicate that decorin has specific gene regulatory effects in cells when present in the matrix with vitronectin or the 120-kDa fragment of fibronectin, polypeptides that are present in actively remodeling tissues. Thus, in combination, these adhesion regulatory molecules transduce novel signals that may contribute to the tissue remodeling process in morphogenesis, wound healing and disease states.

Cooperative signaling by alpha 5 beta 1 and alpha 4 beta 1 integrins regulates metalloproteinase gene expression in fibroblasts adhering to fibronectin.

Rabbit synovial fibroblasts (RSF) express basal levels of the metalloproteinases (MMP) collagenase, stromelysin-1 and 92-kD gelatinase when plated on intact fibronectin (FN), but elevated levels when plated on either the central RGD-containing cell-binding region of FN (120FN) or antibody against the alpha 5 beta 1 integrin, suggesting that domains outside 120FN may suppress the induction of MMP (Werb, Z., P. M. Tremble, O. Behrendtsen, E. Crowley, and C.H. Damsky. 1989. J. Cell Biol. 109:877-889). We therefore attempted to reconstitute the basal signaling of intact FN by plating RSF on 120FN together with domains of FN outside this region. Large COOH-terminal fragments containing both the heparin-binding and HICS domains suppressed MMP when combined with 120FN. To map the active sequences, peptides from this region and larger fragments that did, or did not, include the CS-1 portion of IIICS were tested. Only CS-1 peptide, or larger fragments containing CS-1, suppressed MMP expression induced by 120FN. In contrast, peptide V from the heparin-binding region, shown previously to stimulate focal contact formation, further enhanced MMP expression by RSF when present on the substrate with 120FN. RSF expressed alpha 4 beta 1 integrin, the receptor for CS-1, and the anti-alpha 4 mAb blocked the ability of CS-1 to suppress MMP induction by 120FN. These results show that signals modulating MMP expression and focal contact assembly are regulated independently, and that cooperative signaling by alpha 5 beta 1 and alpha 4 beta 1 integrins plays a dominant role in regulating expression of these extracellular matrix-remodeling genes in response to FN. This work demonstrates directly the modular way in which information in the extracellular matrix is detected and processed by cell surface receptors.

Molecular cloning of murine 72-kDa type IV collagenase and its expression during mouse development.

We report the isolation of a cDNA clone providing the first and complete sequence of mouse 72-kDa type IV collagenase. The clone contains 2800 nucleotides with a 1986-nucleotide open reading frame coding for 662 amino acids. The amino acid sequence includes a 29-residue signal peptide, an 80-residue propeptide, and a 553-residue enzyme proper. The sequence identity between the mouse and human enzymes is 96% with all cysteine residues conserved. The carboxyl-terminal domain of the mouse enzyme contains two more residues than the human enzyme. Northern hybridization analysis revealed considerable expression of the enzyme gene in newborn mouse lung, heart, kidney, and psoas muscle tissues, whereas only weak or no signals were observed in liver, spleen, and brain. Expression of the gene was substantially reduced in the same tissues of 3-month-old mice. In situ hybridization analysis of 72-kDa type IV collagenase expression in 10-15-day-old mouse embryos showed that the gene was intensely expressed in mesenchymal cells. Brain and surface ectoderm were completely negative. The epithelial tissue component of developing organs was negative with the exception of salivary gland. Although the expression varied somewhat between different mesenchymal tissues, no temporal or spatial changes could be associated with the advancement of epithelial branching morphogenesis. These findings together with our previous data on the expression of 72-kDa type IV collagenase in human tumors indicate that this enzyme has some very specific roles both in the physiological and pathological degradation of extracellular matrix. Furthermore, it has become clear that the closely related 92-kDa type IV collagenase differs completely with respect to expression pattern as well as gene regulation. The mouse cDNA clones reported in this study may provide important tools unraveling the actual roles of these enzymes in vivo.

Localization of messenger RNA for Mr 72,000 and 92,000 type IV collagenases in human skin cancers by in situ hybridization.

We have examined the expression of 2 type IV collagen degrading enzymes (Mr 72,000 and 92,000 type IV collagenases) in human skin cancer by in situ hybridization. In all cases of infiltrating carcinomas of squamous cell (9 of 9) and basal cell (5 of 5) types, messenger RNA for the Mr 72,000 type IV collagenase was present in numerous fibroblasts. These were especially abundant in the stroma adjacent to the invasive tumor nodules. Malignant cells were negative for mRNA for the Mr 72,000 enzyme in all cases as were all other epithelial as well as endothelial cells. mRNA for the Mr 92,000 type IV collagenase was present in all 9 squamous cell and in 3 of the 5 basal cell carcinomas. In all these cases, a subpopulation of tissue macrophages was found to be positive, while malignant cells showed a signal for Mr 92,000 type IV collagenase in 6 of the squamous cell carcinomas but in none of the basal cell carcinomas. In all cases, the signal for this mRNA was confined to cells located at the tumoral/stromal interface or in the close vicinity of tumor nodules. No mRNA for any of the 2 collagenases was detected in 3 biopsies of normal skin. In vitro studies have indicated that collagenases are involved in the degradation of the extracellular matrix during cancer invasion. The present findings are consistent with such a role of the Mr 72,000 and 92,000 type IV collagenases in squamous and basal cell carcinomas in situ. The findings also demonstrate that degradative enzymes are not necessarily produced by the malignant cells themselves but may be generated by induction or recruitment of nonmalignant stromal cells.

70 K type IV collagenase (gelatinase).

Type IV collagenase (gelatinase) is a 70,000 dalton neutral metalloproteinase that specifically cleaves type IV collagen in addition to degrading denatured collagen (gelatin). It is secreted in a latent proenzyme form that is converted proteolytically in the extracellular space to a 62,000 dalton active enzyme. The primary structure, enzymatic properties as well as gene structure, demonstrate that type IV collagenase is closely related with the other well characterized metalloproteinases, interstitial collagenase and stromelysin. However, the structure of type IV collagenase differs from the others in that it is larger and contains three internal repeats that resemble the type II domains of fibronectin. Also, initial characterization of the promoter region of the gene indicates that its regulation differs from the other proteinase genes. Type IV collagenase is presumably required for the normal turnover of basement membranes. Augmented activity is linked with the invasive potential of tumor cells and the enzyme is believed to play a major role in the penetration of basement membranes by metastatic cells. Measurements of enzyme activity and mRNA levels as well as immunostaining of a variety of tumor cells and tissues suggest that assays for the enzyme may have value in the follow-up of malignant growth.

Complete structure of the human gene for 92-kDa type IV collagenase. Divergent regulation of expression for the 92- and 72-kilodalton enzyme genes in HT-1080 cells.

The complete structure of the human gene for 92-kDa type IV collagenase was determined. Two overlapping genomic clones spanning 26 kilobases (kb) of genomic DNA were shown to contain the entire 7.7-kb structural gene together with 15 and 3.5 kb of 5'-end and 3'-end flanking regions, respectively. The 92-kDa type IV collagenase gene contains 13 exons as does the 72-kDa type IV collagenase gene. All intron locations of the 92-kDa enzyme gene coincided with intron locations in the 72-kDa enzyme gene. Exons 5, 6, and 7 which were 174, 174, and 177 base pairs long, respectively, each encoded one complete internal repeat which resembles the collagen-binding domains of fibronectin. The sequence coding for a unique 48-residue segment in the 92-kDa type IV collagenase that has no counterpart in other metalloproteinases was not present in a separate exon, but was contained in exon 9 which also codes for sequences with homology to the other metalloproteinases. The initiation site for transcription was determined by primer extension analysis. Sequencing analysis of 599 base pairs of the 5'-end flanking region showed that the promoter does not have a TATA motif, but a TTAAA sequence at position -29 to -25. A CAAT motif was not observed but there was one GC box. Two putative 12-O-tetradecanoyl-phorbol-13-acetate (TPA) response elements, that might serve as binding sites for the transcription factor AP-1 and a consensus sequence of a transforming growth factor beta 1 (TGF-beta 1) inhibitory element were found in the promoter region. Gelatinase assay of enzyme secreted by cultured human fibrosarcoma cells (HT-1080) revealed only low levels of 92-kDa type IV collagenase activity, whereas considerable activity of the 72-kDa enzyme was present. Northern hybridization analysis confirmed these findings. Treatment of the HT-1080 cells with TPA resulted in induction of the secretion of 92-kDa type IV collagenase activity. This induction could not be significantly inhibited by concomitant incubation with TGF-beta 1. TPA and TGF-beta 1 did not markedly affect the activities of the 72-kDa enzyme. The activities of the secreted 92- and 72-kDa enzymes by HT-1080 cells correlated with the amounts of mRNA as estimated by Northern analyses.

Structure of the human type IV collagenase gene.

The structure of the gene for human 70-kDa type IV collagenase (gelatinase) was determined. Three overlapping genomic clones were isolated and shown to contain 0.4 kilobase (kb) of the 5'-flanking region, the 27-kb structural gene, and 4.5 kb of the 3'-flanking region. The gene has 13 exons that vary in length from 110 to 901 base pairs (bp) and 12 introns that range from 175 to 4350 bp. Alignment of intron locations demonstrated that introns 1-4 and 8-12 of the type IV collagenase gene coincide with intron locations in the interstitial collagenase and stromelysin genes, indicating a close structural relationship of these metalloproteinase genes. Exons 5-7 are each 174 bp in size, and each codes for one complete internal repeat that resembles the collagen-binding domains of fibronectin. The transcription initiation site was determined by primer extension and S1 nuclease analyses. Analysis of the 0.4-kb 5'-flanking region of the gene showed that, in contrast to the genes of interstitial collagenease and stromelysin, there is no TATA box or 12-O-tetradecanoylphorbol-13-acetate-responsive element present in the promoter region, whereas there are two GC boxes. There is no CAAT box, but a potential binding site (CCCCAGGC) for the transcription factor AP-2 is located in the first exon.

Completion of the primary structure of the human type IV collagenase preproenzyme and assignment of the gene (CLG4) to the q21 region of chromosome 16.

The complete amino acid sequence of the human type IV collagenase preproenzyme was determined from cDNA and genomic clones. Primer extension and S1 nuclease analyses as well as nucleotide sequencing of a genomic clone indicate that the first exon has two closely spaced initiation sites for transcription and codes for 290 and 280 nt of a 5' untranslated region and a 29-residue signal peptide. The gene (CLG4) was localized to 16q21 using somatic cell hybrids and in situ hybridization.