Basement Membrane Zone Collagens XV and XVIII/Proteoglycans Mediate Leukocyte Influx in Renal Ischemia/Reperfusion

Collagen type XV and XVIII are proteoglycans found in the basement membrane zones of endothelial and epithelial cells, and known for their cryptic anti-angiogenic domains named restin and endostatin, respectively. Mutations or deletions of these collagens are associated with eye, muscle and microvessel phenotypes. We now describe a novel role for these collagens, namely a supportive role in leukocyte recruitment. We subjected mice deficient in collagen XV or collagen XVIII, and their compound mutant, as well as the wild-type control mice to bilateral renal ischemia/reperfusion, and evaluated renal function, tubular injury, and neutrophil and macrophage influx at different time points after ischemia/reperfusion. Five days after ischemia/reperfusion, the collagen XV, collagen XVIII and the compound mutant mice showed diminished serum urea levels compared to wild-type mice (all p<0.05). Histology showed reduced tubular damage, and decreased inflammatory cell influx in all mutant mice, which were more pronounced in the compound mutant despite increased expression of MCP-1 and TNF-α in double mutant mice compared to wildtype mice. Both type XV and type XVIII collagen bear glycosaminoglycan side chains and an in vitro approach with recombinant collagen XVIII fragments with variable glycanation indicated a role for these side chains in leukocyte migration. Thus, basement membrane zone collagen/proteoglycan hybrids facilitate leukocyte influx and tubular damage after renal ischemia/reperfusion and might be potential intervention targets for the reduction of inflammation in this condition.     

Epitope-defined monoclonal antibodies against multiplexin collagens demonstrate that type XV and XVIII collagens are expressed in specialized basement membranes

Type XV and type XVIII collagens are classified as part of multiplexin collagen superfamily and their C-terminal parts, endostatin and restin, respectively, have been shown to be anti-angiogenic in vivo and in vitro. The alpha1(XV) and alpha1(XVIII) collagen chains are reported to be localized mainly in the basement membrane zone, but their distributions in blood vessels and nonvascular tissues have yet to be thoroughly clarified. In the present study, we raised monoclonal antibodies against synthetic peptides of human alpha1(XV) and alpha1(XVIII) chains and used them for extensive investigation of the distribution of these chains. We came to the conclusion that nonvascular BMs contain mainly one of two types: subepithelial basement membranes that contained type XVIII in general, or skeletal and cardiac muscles that harbored mainly type XV. But basement membranes surrounding smooth muscle cells in vascular tissues contained one or both of them, depending on their locations. Interestingly, continuous capillaries contained both type XV and type XVIII collagens in their basement membranes; however, fenestrated or specialized capillaries such as glomeruli, liver sinusoids, lung alveoli, and splenic sinusoids expressed only type XVIII in their basement membranes, lacking type XV. This observation could imply that different functions of basement membranes in various tissues and organs use different mechanisms for the endogenous control of angiogenesis.     

Improved stability of multivalent antibodies containing the human collagen XV trimerization domain

We recently described the in vitro and in vivo properties of an engineered homotrimeric antibody made by fusing the N-terminal trimerization region of collagen XVIII NC1 domain to the C-terminus of a scFv fragment [trimerbody (scFv-NC1)₃; 110 kDa]. Here, we demonstrated the utility of the N-terminal trimerization region of collagen XV NC1 domain in the engineering of trivalent antibodies. We constructed several scFv-based trimerbodies containing the human type XV trimerization domain and demonstrated that all the purified trimerbodies were trimeric in solution and exhibited excellent antigen binding capacity. Importantly, type XV trimerbodies demonstrated substantially greater thermal and serum stability and resistance to protease digestion than type XVIII trimerbodies. In summary, the small size, high expression level, solubility and stability of the trimerization domain of type XV collagen make it the ideal choice for engineering homotrimeric antibodies for cancer detection and therapy.Key words: antibody engineering, multivalent antibody, collagen XVIII, collagen XV, tumor targeting     

The role of collagen-derived proteolytic fragments in angiogenesis.

Basement membrane molecules and fragments derived from them are regulators of biological activities such as cell growth, differentiation and migration. This review describes proteolytically derived fragments from the non-collagenous (NC1) domain at the C-terminus of the basement membrane collagens type IV, XV and XVIII, which have been implicated as regulators of angiogenesis. Endostatin is an endogenous collagen XVIII/NC1 derivative, inhibiting endothelial cell proliferation and migration in vitro and tumor-growth in vivo. A homologous NC1 domain fragment of type XV collagen has anti-angiogenic activity as well. Furthermore, NC1 domain fragments of the most abundant basement membrane collagen, type IV collagen, have been shown to inhibit induced vessel growth.     

Improved stability of multivalent antibodies containing the human collagen XV trimerization domain

We recently described the in vitro and in vivo properties of an engineered homotrimeric antibody made by fusing the N-terminal trimerization region of collagen XVIII NC1 domain to the C-terminus of a scFv fragment [trimerbody (scFv-NC1)₃; 110 kDa]. Here, we demonstrated the utility of the N-terminal trimerization region of collagen XV NC1 domain in the engineering of trivalent antibodies. We constructed several scFv-based trimerbodies containing the human type XV trimerization domain and demonstrated that all the purified trimerbodies were trimeric in solution and exhibited excellent antigen binding capacity. Importantly, type XV trimerbodies demonstrated substantially greater thermal and serum stability and resistance to protease digestion than type XVIII trimerbodies. In summary, the small size, high expression level, solubility and stability of the trimerization domain of type XV collagen make it the ideal choice for engineering homotrimeric antibodies for cancer detection and therapy.     

Endostatins derived from collagens XV and XVIII differ in structural and binding properties, tissue distribution and anti-angiogenic activity

Endostatin is a fragment of the C-terminal domain NC1 of collagen XVIII that inhibits angiogenesis and tumor growth. We report the characterization of a collagen XV endostatin analogue and its parent NC1 domain, obtained by recombinant expression in mammalian cells. Both NC1 domains contain a trimerization domain, a hinge region that is more sensitive to proteolysis in collagen XVIII and the endostatin domain. Unlike endostatin-XVIII, endostatin-XV does not bind zinc or heparin, which is explained by the crystal structure of endostatin-XV. The collagen XV and XVIII fragments inhibited chorioallantoic membrane angiogenesis induced by basic fibroblast growth factor (FGF-2) or vascular endothelial growth factor (VEGF), but there are striking differences depending on which cytokine is used and whether free endostatins or NC1 domains are applied. The collagen XV and XVIII fragments showed a similar binding repertoire for extracellular matrix proteins. Differences were found in the immunohistological localization in vessel walls and basement membrane zones. Together, these data indentify endostatin-XV as an angiogenesis inhibitor, which differs from endostatin-XVIII in several important functional details.     

Tumor suppression by collagen XV is independent of the restin domain

Non-fibrillar collagen XV is a chondroitin sulfate modified glycoprotein that is associated with the basement membrane zone in many tissues. Its precise functions remain to be fully elucidated though it clearly plays a critical role in the structural integrity of the extracellular matrix. Loss of collagen XV from the basement membrane zone precedes invasion of a number of tumor types and we previously showed that collagen XV functions as a dose-dependent suppressor of tumorigenicity in cervical carcinoma cells. The carboxyl terminus of another non-fibrillar collagen (XVIII) is cleaved to produce endostatin, which has anti-angiogenic effects and thus may act as a tumor suppressor in vivo. Since collagen XV has structural similarity with collagen XVIII, its C-terminal restin domain could confer tumor suppressive functions on the molecule, though our previous data did not support this. We now show that expression of collagen XV enhances the adhesion of cervical carcinoma cells to collagen I in vitro as does the N-terminus and collagenous regions of collagen XV, but not the restin domain. Destruction of a cysteine residue in the collagenous region that is critical for intermolecular interactions of collagen XV abolished the enhanced adhesion to collagen I. Finally, we demonstrate that unlike full length collagen XV, expression of the restin domain alone does not suppress tumorigenicity of cervical carcinoma cells in vivo; hence, this process is dependent on functions and interactions of other parts of the protein.     

Crystal structure of the human collagen XV trimerization domain: A potent trimerizing unit common to multiplexin collagens

Correct folding of the collagen triple helix requires a self-association step which selects and binds α-chains into trimers. Here we report the crystal structure of the trimerization domain of human type XV collagen. The trimerization domain of type XV collagen contains three monomers each composed of four β-sheets and an α-helix. The hydrophobic core of the trimer is devoid of solvent molecules and is shaped by β-sheet planes from each monomer. The trimerization domain is extremely stable and forms at picomolar concentrations. It is found that the trimerization domain of type XV collagen is structurally similar to that of type XVIII, despite only 32% sequence identity. High structural conservation indicates that the multiplexin trimerization domain represents a three dimensional fold that allows for sequence variability while retaining structural integrity necessary for tight and efficient trimerization.     

Novel glycosylated forms of human plasma endostatin and circulating endostatin-related fragments of collagen XV.

Circulating elongated forms of the angiogenesis inhibitor and potential anti-cancer drug endostatin were isolated from human blood filtrate. Immunoreactive endostatin was identified by a polyclonal rabbit antiserum raised against an N-terminal epitope of the polypeptide and purified by consecutive chromatographic steps and immunoblotting. N- and C-terminal sequence analyses of the isolated molecules revealed different forms of endostatin starting with V(117)HLRPAR. lacking the last and final three residues of the noncollagenous domain 1 (NC-1) of collagen XVIII, respectively. These polypetides are found to be O-glycosylated at T(125) (residue 9) with a glycan structure of the mucin type consisting of galactose N-acetylgalactosamine and N-acetylneuraminic acid residues. Carbohydrate analyses were performed via the semiquantitative HPLC-electrospray ionization mass spectrometry (ESMS) technique after exoglycosidase hydrolysis. Circulating endostatins are present as sialoglycoprotein (22 000 and 21 841 Da +/- 0.02%) and asialoglycoprotein structures (21 710 and 21 549 Da +/- 0.02%), while the two completely deglycosylated forms are obtained only after enzymatic incubation. The described glycosylated endostatins may represent intermediates in the proteolytic pathway of the NC-1 domain of collagen XVIII resulting in bioactive endostatins. Furthermore, immunoreactive endostatin-related C-terminal fragments of human collagen XV are found in the hemofiltrate. These polypeptides exhibit the N-terminal sequences P(66)HLLPPP. and Y(81)EKPALH. of the collagen XV NC-1 domain. ESMS and immunoblotting analyses reveal three glycosylated polypeptides with a molecular mass ranging from 16 to 21 kDa. Due to the high degree of homology between collagen XV and collagen XVIII as well as their analoqous proteolytic processing, functional similarities of collagen XVIII- and XV-related fragments should be revealed in future experiments.     

Lack of collagen XVIII/endostatin results in eye abnormalities

Mice lacking collagen XVIII and its proteolytically derived product endostatin show delayed regression of blood vessels in the vitreous along the surface of the retina after birth and lack of or abnormal outgrowth of retinal vessels. This suggests that collagen XVIII/endostatin is critical for normal blood vessel formation in the eye. All basement membranes in wild-type eyes, except Descemet's membrane, showed immunogold labeling with antibodies against collagen XVIII. Labeling at sites where collagen fibrils in the vitreous are connected with the inner limiting membrane and separation of the vitreal matrix from the inner limiting membrane in mutant mice indicate that collagen XVIII is important for anchoring vitreal collagen fibrils to the inner limiting membrane. The findings provide an explanation for high myopia, vitreoretinal degeneration and retinal detachment seen in patients with Knobloch syndrome caused by loss-of-function mutations in collagen XVIII.     

Endostatin's heparan sulfate-binding site is essential for inhibition of angiogenesis and enhances in situ binding to capillary-like structures in bone explants

The functional role of endostatin's affinity for heparan sulfates was addressed using an ex vivo bone angiogenesis model. Capillary-like sprouts showed prominent expression of collagen XVIII/endostatin. Outgrowth of endothelial cells was not altered in the absence of collagen XVIII but inhibited by the addition of recombinant endostatin. Mutant non-heparan sulfate binding endostatin and the collagen XV endostatin homologue were ineffective. The ability of mutant endostatin to bind to capillary structures was reduced when compared to endostatin. Endostatin-XV completely failed to bind to endothelial cells. Our data indicate that endostatin's angiostatic function is heparan sulfate-dependent, and that in situ-binding of endostatin to endothelial cells is increased by heparan sulfates.     

The multiple functions of collagen XVIII in development and disease

Collagen XVIII is a heparan sulphate proteoglycan which is expressed ubiquitously in different basement membranes throughout the body. Its C-terminal fragment, endostatin, has been found to inhibit angiogenesis and tumor growth by restricting endothelial proliferation and migration and inducing apoptosis of endothelial cells. Collagen XVIII has three variants, of which the shortest one is found in most vascular and epithelial BM structures, whereas the longer variants are found especially in the liver. The longest or frizzled variant has a cysteine-rich domain in its N-terminus that has been shown to inhibit Wnt signaling in vitro. The presence of collagen XVIII homologues in organisms such as C. elegans, Xenopus laevis, zebrafish and chick suggests a fundamental role for this BM collagen. Mutations in the collagen XVIII gene lead to the Knobloch syndrome, which is characterized by high myopia, vitreoretinal degeneration with retinal detachment, macular abnormalities and occipital encephalocele. Mice lacking collagen XVIII also show several ocular abnormalities. This suggests that in physiological conditions collagen XVIII is mostly needed for the proper development of the eye. Moreover, it appears to be needed for the structural stability of basement membranes in several other organs, and increasing evidence shows its importance for other organs in non-physiological situations such as atherosclerosis, glomerulonephritis or other type of tissue damage. This review focuses on clarifying the roles of collagen XVIII and its variants and domains in various physiological and pathological conditions.     

Lack of collagen XVIII long isoforms affects kidney podocytes, whereas the short form is needed in the proximal tubular basement membrane

Collagen XVIII is characterized by three variant N termini, an interrupted collagenous domain, and a C-terminal antiangiogenic domain known as endostatin. We studied here the roles of this collagen type and its variant isoforms in the mouse kidney. Collagen XVIII appeared to be in a polarized orientation in the tubular basement membranes (BMs), the endostatin domain embedded in the BM, and the N terminus residing at the BM-fibrillar matrix interface. In the case of the glomerular BM (GBM), collagen XVIII was expressed in different isoforms depending on the side of the GBM. The orientation appeared polarized here, too, both the endothelial promoter 1-derived short variant of collagen XVIII and the epithelial promoter 2-derived longer variants having their C-terminal endostatin domains embedded in the BM and the N termini at the respective BM-cell interfaces. In addition to loosening of the proximal tubular BM structure, the Col18a1(-/-) mice showed effacement of the glomerular podocyte foot processes, and microindentation studies showed changes in the mechanical properties of the glomeruli, the Col18a1(-/-) glomeruli being ～30% softer than the wild-type. Analysis of promoter-specific knockouts (Col18a1(P1/P1) and Col18a1(P2/P2)) indicated that tubular BM loosening is due to a lack of the shortest isoform, whereas the glomerular podocyte effacement was due to a lack of the longer isoforms. We suggest that lack of collagen XVIII may also have disparate effects on kidney function in man, but considering the mild physiological findings in the mutant mice, such effects may manifest themselves only late in life or require other compounding molecular changes.     

Collagen XVIII and corneal reinnervation following keratectomy

The significance of collagen XVIII in the regulation of corneal reinnervation remains largely unknown. We used whole-mount immunoconfocal microscopy to localize collagen XVIII to the nerve basement membrane of wild-type (WT) mouse corneas. Transmission electron microscopy showed corneal nerve disorganization in collagen XVIII knockout mice (col18a1(-/-)). Antibody 2H3-specific neurofilament colocalized with collagens XVIII and IV and laminin-2 in WT mouse corneas, but did not colocalize with collagen IV and laminin-2 in col18a1(-/-) mouse corneas. Following keratectomy, col18a1(-/-) mice displayed decreased corneal neurite extension compared to WT mice. Our data indicate that collagen XVIII may play an important role in corneal reinnervation after wounding.     

Developmentally regulated expression of type XV collagen correlates with abnormalities in Col15a1(-/-) mice.

Lack of type XV collagen in mice results in mild skeletal myopathy and increases vulnerability to exercise-induced skeletal muscle and cardiac injury [Proc. Natl. Acad. Sci. USA 98 (2001), 1194]. The expression of type XV collagen was studied during murine fetal development from 10.5 to 18.5 dpc using immunofluorescence. The first sign of type expression was seen in the capillaries of many tissues at 10.5 dpc, some of them showing developmental transitions in the expression. Interestingly, capillaries forming the blood-brain barrier and those of the sinusoidal type were essentially lacking in this collagen. Early expression was also detected in the skeletal muscle and peripheral nerves, while expression in the heart, kidney and lung appeared to be developmentally regulated. In addition, distinct staining was found in the perichondrium of the cartilage. Collectively, the dynamics of its expression during development, its localization in the basement membrane--fibrillar matrix interface and the consequences of its absence in mice suggest a structural role in providing stability at least in skeletal muscle and capillaries. The early prominent expression of type XV collagen in newly forming blood vessels could also indicate a possible role in angiogenic processes.     

Functional characterization of neostatins, the MMP-derived, enzymatic cleavage products of type XVIII collagen

Several anti-angiogenic factors are derived from proteolytic processing of large molecules including endostatin from type XVIII collagen and angiostatin from plasminogen. In previous studies we showed that neostatin-7, the C-terminal 28kDa endostatin-spanning proteolytic fragment, is generated from the proteolytic action of matrix metalloproteinase matrilysin (MMP)-7 on type XVIII collagen. Now, we report a second member of the neostatin family of proteins, neostatin-14. Given the small quantities of neostatin-7 and -14 generated by the breakdown of naturally occurring collagen XVIII (using MMP-7 and -14, respectively), we used two other approaches to characterize the anti-angiogenic properties of these molecules: murine recombinant neostatin in vitro, and gene therapy. We demonstrate that murine recombinant neostatin-7 inhibits calf pulmonary artery endothelial cell proliferation and that microinjection of neostatin-7 and neostatin-14 naked DNA into the corneal stroma of mice results in significant reduction of basic fibroblast growth factor-induced corneal neovascularization. These results provide supportive evidence of the possible anti-angiogenic effect of neostatins.     

The collagen type XVIII endostatin domain is co-localized with perlecan in basement membranes in vivo.

The C-terminal globular endostatin domain of collagen type XVIII is anti-angiogenic in a variety of experimental tumor models, and clinical trials to test it as an anti-tumor agent are already under way. In contrast, many of its cell biological properties are still unknown. We systematically localized the mRNA of collagen type XVIII with the help of in situ hybridization (ISH) and detected it in epithelial and mesenchymal cells of almost all organ systems throughout mouse development. Light and electron microscopic immunohistochemistry (IHC) revealed that the endostatin domain is a widespread component of almost all epithelial basement membranes in all major developing organs, and in all basement membranes of capillaries and blood vessels. Furthermore, quantitative immunogold double labeling demonstrated a co-localization of 50% of the detected endostatin domain together with perlecan in basement membranes in vivo. We conclude that the endostatin domain of collagen type XVIII plays a role, even in early stages of mouse development, other than regulating angiogenesis. In the adult, the endostatin domain could well be involved in connecting collagen type XVIII to the basement membrane scaffolds. At least in part, perlecan appears to be an adaptor molecule for the endostatin domain in basement membranes in vivo.     

Antiangiogenic activity of restin, NC10 domain of human collagen XV: comparison to endostatin

Based on a homology search with endostatin, the C-terminus 185 aa of collagen XVIII, we report the cloning, expression, and antiangiogenic activity of a 22 kDa human collagen XV fragment, that we have named restin. Restin was expressed in the prokaryotic pET expression system. We have shown that restin inhibits the migration of endothelial cells in vitro but has no effect on the proliferation of these cells. A polyclonal antibody raised against endostatin cross-reacted with restin. Systemic administration of restin suppressed the growth of tumors in a xenograft renal carcinoma model.     

Cloning of cDNA and Genomic DNA Encoding Human Type XVIII Collagen and Localization of the α1(XVIII) Collagen Gene to Mouse Chromosome 10 and Human Chromosome 21

Types XV and XVIII collagen belong to a unique and novel subclass of the collagen superfamily for which we have proposed the name the MULTIPLEXIN family. Members of this class contain polypeptides with multiple triple-helical domains separated and flanked by non-triple-helical regions. In this paper, we report the isolation of human cDNAs and genomic DNAs encoding the α1(XVIII) collagen chain. Utilizing a genomic clone as probe, we have mapped the COL18A1 gene to chromosome 21q22.3 by fluorescence in situ hybridization. In addition, using an interspecific backcross panel, we have shown that the murine Col18a1 locus is on chromosome 10, close to the loci for Col6a1 and Col6a2.