Type IV collagen of the glomerular basement membrane. Evidence that the chain specificity of network assembly is encoded by the noncollagenous NC1 domains.

The ultrafiltration function of the glomerular basement membrane (GBM) of the kidney is impaired in genetic and acquired diseases that affect type IV collagen. The GBM is composed of five (alpha1 to alpha5) of the six chains of type IV collagen, organized into an alpha1.alpha2(IV) and an alpha3.alpha4.alpha5(IV) network. In Alport syndrome, mutations in any of the genes encoding the alpha3(IV), alpha4(IV), and alpha5(IV) chains cause the absence of the alpha3. alpha4.alpha5 network, which leads to progressive renal failure. In the present study, the molecular mechanism underlying the network defect was explored by further characterization of the chain organization and elucidation of the discriminatory interactions that govern network assembly. The existence of the two networks was further established by analysis of the hexameric complex of the noncollagenous (NC1) domains, and the alpha5 chain was shown to be linked to the alpha3 and alpha4 chains by interaction through their respective NC1 domains. The potential recognition function of the NC1 domains in network assembly was investigated by comparing the composition of native NC1 hexamers with hexamers that were dissociated and reconstituted in vitro and with hexamers assembled in vitro from purified alpha1-alpha5(IV) NC1 monomers. The results showed that NC1 monomers associate to form native-like hexamers characterized by two distinct populations, an alpha1.alpha2 and alpha3.alpha4.alpha5 heterohexamer. These findings indicate that the NC1 monomers contain recognition sequences for selection of chains and protomers that are sufficient to encode the assembly of the alpha1.alpha2 and alpha3.alpha4.alpha5 networks of GBM. Moreover, hexamer formation from the alpha3, alpha4, and alpha5 NC1 monomers required co-assembly of all three monomers, suggesting that mutations in the NC1 domain in Alport syndrome may disrupt the assembly of the alpha3.alpha4.alpha5 network by interfering with the assembly of the alpha3.alpha4.alpha5 NC1 hexamer.

New functions for non-collagenous domains of human collagen type IV. Novel integrin ligands inhibiting angiogenesis and tumor growth in vivo.

Collagen type IV is a major component of the basal lamina of blood vessels. Six genetically distinct collagen type IV chains have been identified and are distributed in a tissue-specific manner. Here we define a novel function for soluble non-collagenous (NC1) domains of the alpha2(IV), alpha3(IV), and alpha6(IV) chains of human collagen type IV in the regulation of angiogenesis and tumor growth. These NC1 domains were shown to regulate endothelial cell adhesion and migration by distinct alpha(v) and beta(1) integrin-dependent mechanisms. Systemic administration of recombinant alpha2(IV), alpha3(IV), and alpha6(IV) NC1 domains potently inhibit angiogenesis and tumor growth, whereas alpha1(IV), alpha4(IV), and alpha5(IV) showed little if any effect. These findings suggest that specific NC1 domains of collagen type IV may represent an important new class of angiogenesis inhibitors.

Recurrent Goodpasture's disease due to a monoclonal IgA-kappa circulating antibody.

We describe the case of a 54-year-old man who first presented with a clinical syndrome manifested by recurrent pulmonary hemorrhage, hematuria, and mild renal insufficiency. Direct immunofluorescence of renal biopsy sections showed linear deposition of IgA-kappa in the glomerular (GBM) and tubular basement membranes. Serum protein immunoelectrophoresis was positive for a monoclonal immunoglobulin A (IgA)-kappa protein. Serum analysis showed circulating IgA anti-GBM antibodies. Treatment with high-dose steroids, cyclophosphamide, and plasma exchange resulted in resolution of the clinical picture. To the best of our knowledge, this is the first report of Goodpasture's disease associated with the presence of a circulating monoclonal IgA-kappa antibody.

The goodpasture autoantigen. Mapping the major conformational epitope(s) of alpha3(IV) collagen to residues 17-31 and 127-141 of the NC1 domain.

The Goodpasture (GP) autoantigen has been identified as the alpha3(IV) collagen chain, one of six homologous chains designated alpha1-alpha6 that comprise type IV collagen (Hudson, B. G., Reeders, S. T., and Tryggvason, K. (1993) J. Biol. Chem. 268, 26033-26036). In this study, chimeric proteins were used to map the location of the major conformational, disulfide bond-dependent GP autoepitope(s) that has been previously localized to the noncollagenous (NC1) domain of alpha3(IV) chain. Fourteen alpha1/alpha3 NC1 chimeras were constructed by substituting one or more short sequences of alpha3(IV)NC1 at the corresponding positions in the non-immunoreactive alpha1(IV)NC1 domain and expressed in mammalian cells for proper folding. The interaction between the chimeras and eight GP sera was assessed by both direct and inhibition enzyme-linked immunosorbent assay. Two chimeras, C2 containing residues 17-31 of alpha3(IV)NC1 and C6 containing residues 127-141 of alpha3(IV)NC1, bound autoantibodies, as did combination chimeras containing these regions. The epitope(s) that encompasses these sequences is immunodominant, showing strong reactivity with all GP sera and accounting for 50-90% of the autoantibody reactivity toward alpha3(IV)NC1. The conformational nature of the epitope(s) in the C2 and C6 chimeras was established by reduction of the disulfide bonds and by PEPSCAN analysis of overlapping 12-mer peptides derived from alpha1- and alpha3(IV)NC1 sequences. The amino acid sequences 17-31 and 127-141 in alpha3(IV)NC1 have thus been shown to contain the critical residues of one or two disulfide bond-dependent conformational autoepitopes that bind GP autoantibodies.

Goodpasture antigen: expression of the full-length alpha3(IV) chain of collagen IV and localization of epitopes exclusively to the noncollagenous domain.

BACKGROUND: Tissue injury in Goodpasture (GP) syndrome (rapidly progressive glomerular nephritis and pulmonary hemorrhage) is mediated by antibasement membrane antibodies that are targeted to the alpha3(IV) chain of type IV collagen, one of five alpha(IV) chains that occur in the glomerular basement membrane. GP antibodies are known to bind epitopes within the carboxyl terminal noncollagenous domain (NC1) of the alpha3(IV) chain, termed the GP autoantigen. Whether epitopes also exist in the 1400-residue collagenous domain is unknown because studies to date have focused solely on the NC1 domain. A knowledge of GP epitopes is important for the understanding of the etiology and pathogenesis of the disease and for the development of therapeutic strategies. METHODS: A cDNA construct was prepared for the full-length human alpha3(IV) chain. The construct was stably transfected into human embryonic kidney 293 cells. The purified full-length r-alpha3(IV) chain was characterized by electrophoresis and electron microscopy. The capacity of this chain for binding of GP antibodies from five patients was compared with that of the human r-alpha3(IV)NC1 domain by competitive enzyme-linked immunosorbent assay. RESULTS: The r-alpha3(IV) chain was secreted from 293 cells as a single polypeptide chain that did not spontaneously undergo assembly into a triple-helical molecule. An analysis of GP-antibody binding to the full-length r-alpha3(IV) chain showed binding exclusively to the globular NC1 domain. CONCLUSION: The full-length human alpha3(IV) chain possesses the capacity to bind GP autoantibodies. The epitope(s) is found exclusively on the nontriple-helical NC1 domain of the alpha3(IV) chain, indicating the presence of specific immunogenic properties. The alpha3(IV) chain alone does not spontaneously undergo assembly into a triple-helical homotrimeric molecule, suggesting that coassembly with either the alpha4(IV) and/or the alpha5(IV) chain may be required for triple-helix formation.

Induction of anti-GBM nephritis in rats by recombinant alpha 3(IV)NC1 and alpha 4(IV)NC1 of type IV collagen.

The capability of the noncollagenous (NC1) domains of the six alpha chains of human type IV collagen to induce anti-glomerular basement membrane (GBM) nephritis in WKY rats was determined. This was accomplished by using recombinant technology to express the six NC1 domains in mammalian 293 cells and to purify the proteins using an anti-Flag affinity column. All rats injected with alpha 3(IV)NC1 and alpha 4(IV)NC1 developed proteinuria and hematuria. Rats injected with alpha 5(IV)NC1 developed mild hematuria, whereas rats injected with the alpha 1(IV)NC1, alpha 2(IV)NC1 and alpha 6(IV)NC1 domains developed neither proteinuria nor hematuria. The renal lesions induced by alpha 3(IV)NC1 and alpha 4(IV)NC1 domains were characteristic of those in patients with anti-GBM nephritis and Goodpasture syndrome. The experimental nephritis is mediated by anti-basement membrane antibodies that are targeted to alpha 3(IV)NC1 and alpha 4(IV)NC1 domains and which bind to the glomerular basement membrane. The uniqueness of the alpha 3(IV)NC1 and alpha 4(IV)NC1 domains, among the six NC1 domains, to induce severe anti-GBM disease may relate to the accessibility of epitopes in the GBM for binding of antibody. The pathogenicity of the alpha 4(IV)NC1 antibodies establishes a conundrum because the pathogenic antibodies in patients are not targeted to the alpha 4(IV)NC1, but are targeted to the alpha 3(IV)NC1 domain in anti-GBM nephritis and to the alpha 3(IV)NC1 and alpha 5(IV)NC1 domains in Alport post-transplant anti-GBM nephritis.

Goodpasture syndrome: selective removal of anti-alpha 3 (IV) collagen autoantibodies. A potential therapeutic alternative to plasmapheresis.

Anti-alpha 3(IV) collagen autoantibodies have been implicated in the pathogenesis of Goodpasture syndrome, an autoimmune disorder causing glomerulonephritis and pulmonary hemorrhage. Currently treatment involves removal of the entire IgG fraction of plasma by plasmapheresis or adsorption to protein A. The present study shows that the anti-alpha 3(IV)NC1 autoantibodies can be removed from plasma specifically and quantitatively by affinity chromatography utilizing either alpha 3 NC1 domain of bovine type IV collagen or recombinant alpha 3 NC1 domain of human type IV collagen immobilized to agarose beads. This study shows the feasibility of using affinity chromatography, as an alternative to plasmapheresis, to exclusively remove the pathogenic autoantibodies from the plasma of patients with Goodpasture syndrome.

A COL4A3 gene mutation and post-transplant anti-alpha 3(IV) collagen alloantibodies in Alport syndrome.

The X-linked Alport syndrome is associated with mutations and deletions in COL4A5 gene, one of six genes which constitute the alpha-chains of type IV collagen in basement membranes. The autosomal recessive form of Alport syndrome is characterized by mutations and deletions in the COL4A3 and COL4A4 genes. A fraction of Alport patients who undergo renal transplantation develop anti-glomerular basement membrane (GBM) nephritis, which results in loss of the renal allograft function. Recently, the target for alloantibodies from an X-linked Alport patient with complete COL4A5 gene deletion was determined to be the alpha 3 chain of type IV collagen. The present study characterized the post-transplant alloantibodies from an autosomal recessive Alport patient with anti-GBM glomerulonephritis and a COL4A3 gene mutation which predicted a loss of 85% of the alpha 3(IV) NC1 domain. The specificity of these new antibodies were studied using glomerular basement membrane constituents and recombinant type IV collagen domains. The results establish the target for the alloantibodies from an autosomal recessive Alport patient with COL4A3 deletion as principally the alpha 3(IV) collagen chain, similar to the post-transplant alloantibodies from X-linked Alport patients with COL4A5 gene deletions. The absence of alpha 3(IV) chain in the GBM of patients with both these forms of Alport syndrome, due either to a failure of synthesis or a failure of assembly, presumably leads to a loss of immunologic tolerance for the alpha 3(IV) NC1 domain in transplanted allografts.

The presence of UDP-N-acetylglucosamine:alpha-3-D-mannoside beta 1,2-N-acetylglucosaminyltransferase I activity in Spodoptera frugiperda cells (IPLB-SF-21AE) and its enhancement as a result of baculovirus infection.

A Golgi preparation from Spodoptera frugiperda (IPLB-SF-21AE) cells was incubated in the presence of the mannosidase II inhibitor, swainsonine, with the oligosaccharide, M(alpha 1,3)[[M(alpha 1,3)[M(alpha 1,6)]M(alpha 1,6)]] M(beta 1,4)Gn(beta 1,4)Gn (M5Gn2), the preferred substrate for the enzyme, UDP-N-acetylglucosamine:alpha-3-D-mannoside beta 1,2-N-acetylglucosaminyltransferase I (Gn-TI). This resulted in formation of the product, Gn(beta 1,2)M(alpha 1,3)[[M(alpha 1,3)[M(alpha 1,6)]M(alpha 1,6)]]- M(beta 1,4) Gn(beta 1,4)Gn (Gn(I)M5Gn2). A significantly increased (> 4-fold) rate of conversion of M5Gn2 to Gn(I)M5Gn2 occurred with insect cell-derived Golgi preparations that had been infected with a recombinant baculovirus for 66 h, a time at which significant amounts of complex-type oligosaccharides were assembled on a heterologous protein, human plasminogen, expressed in this system. Coupled with previous results (Davidson, D.J., Bretthauer, R.K., and Castellino, F.J. (1991) Biochemistry 30, 9811-9815) that demonstrated the occurrence of virally induced activation of a specific M6-mannosidase in IPLB-SF-21AE cells, it is clear that viral infection of lepidopteran insect cells makes available enzymes that provide and utilize the substrate, M5Gn2-protein. This is a key feature in the explanation of the previous original observations made by this laboratory, that lepidopteran insect cells are capable of assembly of complex-type oligosaccharides on glycoproteins.

The construction and expression of chimeric urokinase-type plasminogen activator genes containing kringle domains of human plasminogen.

A series of chimeric urokinase-type plasminogen activator (uPA) genes, which contain combinations of kringle domains of human plasminogen (HPg) in place of the uPA kringle (KuPA), has been constructed and expressed. Some of the resulting recombinant (r) variant uPA chimeras contain modules that potentially mediate the macroscopic binding of HPg to its activation effectors, fibrin(ogen) and 6-aminohexanoic acid (EACA). Such binding sites are not possessed by KuPA, but are present in certain of the HPg kringles, viz., kringle 1 (K1HPg), kringle 4 (K4HPg), and kringle 5 (K5HPg). The recombinant (r) chimeras constructed included molecules with replacements of KuPA with K1HPg (r-[KuPA-->K1HPg]uPA), and with KuPA replaced by double kringle combinations of K1HPgK4HPg (r-[KuPA-->K1HPgK4HPg]uPA), K2HPgK3HPg (r-[KuPA-->K2HPgK3HPg]uPA), and K4HPgK5HPg (r-[KuPA-->K4HPgK5HPg]uPA). All of these variant genes, along with their wild-type (wt) r-uPA counterparts, were expressed in human kidney 293 cells. In cases wherein EACA-binding kringles from HPg have been placed in uPA, this property has been retained in the chimeric molecule and employed as an essential part of the purification procedures for the variants. The steady state amidolytic activity of two-chain (tc) wtr-uPA toward the chromogenic substrate, H-D-pyroglutamyl-Gly-L-Arg-p-nitroanilide (S2444), is characterized by a kcat/KM (pH 7.4, 37 degrees C) of 120 s-1 mM-1. This value ranges from 92 s-1 mM-1 (tcr-[KuPA-->K1HPg]uPA) to 166 s-1 mM-1 (tcr-[KuPA-->K1HPgK4HPg]uPA) for each of the variants, demonstrating that the catalytic efficiency of the active site is altered only in a small way by changes in the noncatalytic domain of uPA. Small differences are also observed in the abilities of these tcr variants to interact with the fast-acting plasma inhibitor of uPA, viz., plasminogen activator inhibitor-1 (PAI-1). The second-order rate constant for the interaction of PAI-1 with tcr-uPA, 0.46 x 10(7) M-1s-1 (pH 7.4, 10 degrees C), ranges from 0.29 x 10(7) M-1s-1 (tcr-[KuPA-->K1HPgK4HPg]uPA) to 1.08 x 10(7) M-1s-1 (tcr-[KuPA-->K4HPgK5HPg]uPA), for the tcr-chimeric variants. Neither wtr-uPA nor any of its chimeric r-variants interacted macroscopically with a fibrin clot under conditions that allowed binding of 74% of single-chain r-tissue-type plasminogen activator. However, the tcr-chimeric uPA variants provided HPg-enriched clot lysis times between 0.2 (r-[KuPA-->K1HPgK4HPg]uPA) and 2.4 (r-[KuPA-->K2HPgK3HPg]uPA) relative to that of wtr-uPA.(ABSTRACT TRUNCATED AT 400 WORDS)