The alpha1.alpha2 network of collagen IV. Reinforced stabilization of the noncollagenous domain-1 by noncovalent forces and the absence of Met-Lys cross-links

Collagen IV networks are present in all metazoa and underlie epithelia as a component of basement membranes. The networks are essential for tissue function and are defective in disease. They are assembled by the oligomerization of triple-helical protomers that are linked end-to-end. At the C terminus, two protomers are linked head-to-head by interactions of their trimeric noncollagenous domains, forming a hexamer structure. This linkage in the alpha1.alpha2 network is stabilized by a putative covalent Met-Lys cross-link between the trimer-trimer interface (Than, M. E., Henrich, S., Huber, R., Ries, A., Mann, K., Kuhn, K., Timpl, R., Bourenkov, G. P., Bartunik, H. D., and Bode, W. (2002) Proc. Natl. Acad. Sci. U. S. A. 99, 6607-6612) forming a nonreducible dimer that connects the hexamer. In the present study, this cross-link was further investigated by: (a) comparing the 1.5-A resolution crystal structures of the alpha1.alpha2 hexamers from bovine placenta and lens capsule basement membranes, (b) mass spectrometric analysis of monomer and nonreducible dimer subunits of placenta basement membrane hexamers, and (c) hexamer dissociation/re-association studies. The findings rule out the novel Met-Lys cross-link, as well as other covalent cross-links, but establish that the nonreducible dimer is an inherent structural feature of a subpopulation of hexamers. The dimers reflect the reinforced stabilization, by noncovalent forces, of the connection between two adjoining protomers of a network. The reinforcement extends to other types of collagen IV networks, and it underlies the cryptic nature of a B-cell epitope of the alpha3.alpha4.alpha5 hexamer, implicating the stabilization event in the etiology and pathogenesis of Goodpasture autoimmune disease.     

The NC1 dimer of human placental basement membrane collagen IV: does a covalent crosslink exist?

Triple-helical collagen IV protomers associate through their N- and C-termini, forming a three-dimensional network that provides basement membranes with mechanical strength. Within this network, the C-terminal non-collagenous (NC1) domains form tight dimeric junctions. Crystallographic analyses of isolated NC1 domains show two trimeric cap-like structures interacting via a large interface. Previously, for NC1 from human placenta type-IV collagen we described covalent alpha1-alpha1 and alpha2-alpha2 crosslinks between Met93 and Lys211 of opposing alpha1(IV) and alpha2(IV) NC1-chains, which further stabilize this interface and explain the occurrence of reduction-insensitive NC1-chain dimers. However, their existence was recently questioned, and we therefore analyzed NC1-domain dimers in more detail by biochemical and protein crystallographic methods. Short-exposure diffraction data show a clear electron density cross-connecting the respective residues, which gradually disappears with prolonged crystal irradiation. Sequence analyses of isolated tryptic peptides derived from denatured NC1 monomers and dimers indicate that only the dimers, but not the monomers, yield these chemically labile cross-linked peptides. These data clearly demonstrate the presence of reduction-resistant, but chemically and radiation-sensitive covalent crosslinks between the side chains of Met93 and Lys211 in human placenta type-IV collagen.     

Identification of the Goodpasture antigen as the alpha 3(IV) chain of collagen IV

The organizational relationship between the recently identified alpha 3 chain of basement membrane collagen (Butkowski, R.J., Langeveld, J.P.M., Wieslander, J., Hamilton, J., and Hudson, B.G. (1987) J. Biol. Chem. 262, 7874-7877) and collagen IV was determined. This was accomplished by the identification of subunits in hexamers of the NC1 domain of collagen IV that were immunoprecipitated with antibodies prepared against subunits M1, corresponding to alpha 1(IV)NC1 and alpha 2(IV)NC1, and M2, corresponding to alpha 3NC1, and by amino acid sequence analysis. The presence of at least two distinct types of hexamers was revealed, one enriched in M1 and the other enriched in M2, but in both types, M1 and M2 coexist. Evidence was also obtained for the existence of heterodimers comprised of M1 and M2. These results indicate that M2 is an integral component of the NC1 hexamer of collagen IV. The amino acid sequence of the NH2-terminal region of M2 was found to be highly related to the collagenous-NC1 junctional region of the alpha 1 chain of collagen IV. Therefore, M2 is designated alpha 3(IV)NC1 and its parent chain alpha 3(IV). These findings lead to a new concept about the structure of collagen IV: namely, 1) collagen IV is comprised of a third chain (alpha 3) together with the two classical ones (alpha 1 and alpha 2); the alpha 3(IV) chain exists within the same triple-helical molecule together with the alpha 1(IV) and alpha 2(IV) chains and/or within a separate triple-helical molecule, exclusive of alpha 1(IV) and alpha 2(IV) chains, but connected through the NC1 domains to the classical triple-helical molecule comprised of alpha 1(IV) and alpha 2(IV) chains. Additionally, a portion of those triple-helical molecules exclusive of alpha 1(IV) and alpha 2(IV) chains may be connected to each other through their NC1 domains; and 3) the epitope to which the major reactivity of autoantibodies are targeted in glomerular basement membrane in patients with Goodpasture syndrome is localized to the NC1 domain of the alpha 3(IV) chain.     

Mechanism of chain selection in the assembly of collagen IV: a prominent role for the alpha2 chain

Collagens comprise a large superfamily of extracellular matrix proteins that play diverse roles in tissue function. The mechanism by which newly synthesized collagen chains recognize each other and assemble into specific triple-helical molecules is a fundamental question that remains unanswered. Emerging evidence suggests a role for the non-collagenous domain (NC1) located at the C-terminal end of each chain. In this study, we have investigated the molecular mechanism underlying chain selection in the assembly of collagen IV. Using surface plasmon resonance, we have determined the kinetics of interaction and assembly of the alpha1(IV) and alpha2(IV) NC1 domains. We show that the differential affinity of alpha2(IV) NC1 domain for dimer formation underlies the driving force in the mechanism of chain discrimination. Given its characteristic domain recognition and affinity for the alpha1(IV) NC1 domain, we conclude that the alpha2(IV) chain plays a regulatory role in directing chain composition in the assembly of (alpha1)(2)alpha2 triple-helical molecule. Detailed crystal structure analysis of the [(alpha1)(2)alpha2](2) NC1 hexamer and sequence alignments of the NC1 domains of all six alpha-chains from mammalian species revealed the residues involved in the molecular recognition of NC1 domains. We further identified a hypervariable region of 15 residues and a beta-hairpin structural motif of 13 residues as two prominent regions that mediate chain selection in the assembly of collagen IV. To our knowledge, this report is the first to combine kinetics and structural data to describe molecular basis for chain selection in the assembly of a collagen molecule.     

Supramolecular Organization of the α121-α565 Collagen IV Network

Collagen IV is a family of 6 chains (α1-α6), that form triple-helical protomers that assemble into supramolecular networks. Two distinct networks with chain compositions of α121 and α345 have been established. These oligomerize into separate α121 and α345 networks by a homotypic interaction through their trimeric noncollagenous (NC1) domains, forming α121 and α345 NC1 hexamers, respectively. These are stabilized by novel sulfilimine (SN) cross-links, a covalent cross-link that forms between Met⁹³ and Hyl²¹¹ at the trimer-trimer interface. A third network with a composition of α1256 has been proposed, but its supramolecular organization has not been established. In this study we investigated the supramolecular organization of this network by determining the chain identity of sulfilimine-cross-linked NC1 domains derived from the α1256 NC1 hexamer. High resolution mass spectrometry analyses of peptides revealed that sulfilimine bonds specifically cross-link α1 to α5 and α2 to α6 NC1 domains, thus providing the spatial orientation between interacting α121 and α565 trimers. Using this information, we constructed a three-dimensional homology model in which the α565 trimer shows a good chemical and structural complementarity to the α121 trimer. Our studies provide the first chemical evidence for an α565 protomer and its heterotypic interaction with the α121 protomer. Moreover, our findings, in conjunction with our previous studies, establish that the six collagen IV chains are organized into three canonical protomers α121, α345, and α565 forming three distinct networks: α121, α345, and α121-α565, each of which is stabilized by sulfilimine bonds between their C-terminal NC1 domains.     

Properties of the collagenous domain of the alpha 3(IV) chain, the Goodpasture antigen, of lens basement membrane collagen. Selective cleavage of alpha (IV) chains with retention of their triple helical structure and noncollagenous domain

A third chain, alpha 3(IV), of basement membrane collagen was recently discovered and was identified as the primary target for the autoantibodies of patients with Goodpasture syndrome (Saus, J., Wieslander, J., Langeveld, J. P. M., Quinones, S., and Hudson, B. G. (1988) J. Biol. Chem. 263, 13374-13380). In the present study, this chain was excised in the form of a truncated promoter by cleavage of basement membrane with Pseudomonas aeruginosa elastase and characterized. The triple helical structure and NC1 domain were retained. Elastase selectively cleaved at a site within the triple helical domain of the alpha 3 chain that is distinct from the cleavage site of the alpha 1 and alpha 2 chains. The truncated alpha 3 chain was found to contain 1460 residues, of which 1225 comprise the collagenous domain, and is cross-linked within this domain by disulfide bonds, forming a high Mr complex (greater than 300,000). Truncated protomers with a length of 340 nm corresponding to the theoretical length for the truncated alpha 3 chain were observed by electron microscopy as suprastructures in which the triple helical domains of three protomers were interwined. These protomers were also connected to each other and to the 140-nm protomers that appear to be comprised of the alpha 1 and alpha 2 chains. These results extended the known length of the alpha 3 chain by about 1000 residues and suggested that protomers of this chain self-associate through interactions between their triple helical domains and between their NC1 domains.     

A role for collagen IV cross-links in conferring immune privilege to the Goodpasture autoantigen: structural basis for the crypticity of B cell epitopes

The detailed structural basis for the cryptic nature (crypticity) of a B cell epitope harbored by an autoantigen is unknown. Because the immune system may be ignorant of the existence of such "cryptic" epitopes, their exposure could be an important feature in autoimmunity. Here we investigated the structural basis for the crypticity of the epitopes of the Goodpasture autoantigen, the alpha3alpha4alpha5 noncollagenous-1 (NC1) hexamer, a globular domain that connects two triple-helical molecules of the alpha3alpha4alpha5 collagen IV network. The NC1 hexamer occurs in two isoforms as follows: the M-isoform composed of monomer subunits in which the epitopes are accessible to autoantibodies, and the D-isoform composed of both monomer and dimer subunits in which the epitopes are cryptic. The D-isoform was characterized with respect to quaternary structure, as revealed by mass spectrometry of dimer subunits, homology modeling, and molecular dynamics simulation. The results revealed that the D-isoform contains two kinds of cross-links as follows: S-hydroxylysyl-methionine and S-lysyl-methionine cross-links, which stabilize the alpha3alpha5-heterodimers and alpha4alpha4-homodimers, respectively. Construction and analysis of a three-dimensional model of the D-isoform of the alpha3alpha4alpha5 NC1 hexamer revealed that crypticity is a consequence of the following: (a) sequestration of key residues between neighboring subunits that are stabilized by domain-swapping interactions, and (b) by cross-linking of subunits at the trimer-trimer interface, which stabilizes the structural integrity of the NC1 hexamer and protects against binding of autoantibodies. The sequestrated epitopes and cross-linked subunits represent a novel structural mechanism for conferring immune privilege at the level of quaternary structure. Perturbation of the quaternary structure may be a key factor in the etiology of Goodpasture disease.     

Multiple replacements at position 211 in the alpha subunit of tryptophan synthase as a probe of the folding unit association reaction

Equilibrium and kinetic studies on the folding of a series of amino acid replacements at position 211 in the alpha subunit of tryptophan synthase from Escherichia coli were performed in order to determine the role of this position in the rate-limiting step in folding. Previous studies [Beasty, A. M., Hurle, M. R., Manz, J. T., Stackhouse, T., Onuffer, J. J., & Matthews, C. R. (1986) Biochemistry 25, 2965-2974] have shown that the rate-limiting step corresponds to the association/dissociation of the amino (residues 1-188) and carboxy (residues 189-268) folding units. In terms of the secondary structure, the amino folding unit consists of the first six strands and five alpha helices of this alpha/beta barrel protein. The carboxy folding unit comprises the remaining two strands and three alpha helices; position 211 is in strand 7. Replacement of the wild-type glycine at position 211 with serine, valine, and tryptophan at most alters the rate of dissociation of the folding units; association is not changed significantly. In contrast, glutamic acid and arginine dramatically decelerate and accelerate, respectively, both association and dissociation. The difference in effects is attributed to long-range electrostatic interactions for these charged side chains; steric effects and/or hydrogen bonding play lesser roles. When considered with previous data on replacements at other positions in the alpha subunit [Hurle, M. R., Tweedy, N. B., & Matthews, C. R. (1986) Biochemistry 25, 6356-6360], it is clear that beta strands 6 (in the amino folding unit) and 7 (in the carboxy folding unit and containing position 211) dock late in the folding process.     

Isolation and sequencing of cDNAs and genomic DNAs encoding the alpha 4 chain of basement membrane collagen type IV and assignment of the gene to the distal long arm of human chromosome 2.

We cloned three overlapping cDNAs covering 2,452 base pairs encoding a new basement membrane collagen chain, alpha 4(IV), from rabbit corneal endothelial cell RNA. Nucleotide sequence analysis demonstrated that the clones encoded a triple-helical domain of 392 1/3 amino acid residues and a carboxyl non-triple-helical (NC1) domain of 231 residues. We also isolated a genomic DNA fragment for the human alpha 4(IV) chain, which contained two exons encoding from the carboxyl end of the triple-helical domain to the amino end of the NC1 domain. Identification of the clones was based on the amino acid sequence identity between the cDNA-deduced amino acid sequence and the reported amino acid sequence obtained from a fragment of the alpha 4(IV) collagen polypeptide M28+ (Butkowski, R. J., Shen, G.-Q., Wieslander, J., Michael, A. F., and Fish, A. J. (1990) J. Lab. Clin. Med. 115, 365-373). When compared with four other type IV collagen chains, the NC1 domain contained 12 cysteinyl residues in positions identical to those of the residues in those chains. The domain demonstrated 61, 70, 55, and 60% amino acid similarity with human alpha 1, human alpha 2, bovine alpha 3, and human alpha 5 chains, respectively. The human genomic DNA fragment allowed us to map the alpha 4(IV) gene (COL4A4) to the 2q35-2q37.1 region of the human genome.     

Quaternary organization of the goodpasture autoantigen,the alpha 3(IV) collagen chain. Sequestration of two cryptic autoepitopes by intrapromoter interactions with the alpha4 and alpha5 NC1 domains

Goodpasture's (GP) disease is caused by autoantibodies that target the alpha3(IV) collagen chain in the glomerular basement membrane (GBM). Goodpasture autoantibodies bind two conformational epitopes (E(A) and E(B)) located within the non-collagenous (NC1) domain of this chain, which are sequestered within the NC1 hexamer of the type IV collagen network containing the alpha3(IV), alpha4(IV), and alpha5(IV) chains. In this study, the quaternary organization of these chains and the molecular basis for the sequestration of the epitopes were investigated. This was accomplished by physicochemical and immunochemical characterization of the NC1 hexamers using chain-specific antibodies. The hexamers were found to have a molecular composition of (alpha3)(2)(alpha4)(2)(alpha5)(2) and to contain cross-linked alpha3-alpha5 heterodimers and alpha4-alpha4 homodimers. Together with association studies of individual NC1 domains, these findings indicate that the alpha3, alpha4, and alpha5 chains occur together in the same triple-helical protomer. In the GBM, this protomer dimerizes through NC1-NC1 domain interactions such that the alpha3, alpha4, and alpha5 chains of one protomer connect with the alpha5, alpha4, and alpha3 chains of the opposite protomer, respectively. The immunodominant Goodpasture autoepitope, located within the E(A) region, is sequestered within the alpha3alpha4alpha5 protomer near the triple-helical junction, at the interface between the alpha3NC1 and alpha5NC1 domains, whereas the E(B) epitope is sequestered at the interface between the alpha3NC1 and alpha4NC1 domains. The results also reveal the network distribution of the six chains of collagen IV in the renal glomerulus and provide a molecular explanation for the absence of the alpha3, alpha4, alpha5, and alpha6 chains in Alport syndrome.     

Melanoma cell CD44 interaction with the alpha 1(IV)1263-1277 region from basement membrane collagen is modulated by ligand glycosylation

Invasion of the basement membrane is believed to be a critical step in the metastatic process. Melanoma cells have been shown previously to bind distinct triple-helical regions within basement membrane (type IV) collagen. Additionally, tumor cell binding sites within type IV collagen contain glycosylated hydroxylysine residues. In the present study, we have utilized triple-helical models of the type IV collagen alpha1(IV)1263-1277 sequence to (a) determine the melanoma cell receptor for this ligand and (b) analyze the results of single-site glycosylation on melanoma cell recognition. Receptor identification was achieved by a combination of methods, including (a) cell adhesion and spreading assays using triple-helical alpha1(IV)1263-1277 and an Asp(1266)Abu variant, (b) inhibition of cell adhesion and spreading assays, and (c) triple-helical alpha1(IV)1263-1277 affinity chromatography with whole cell lysates and glycosaminoglycans. Triple-helical alpha1(IV)1263-1277 was bound by melanoma cell CD44/chondroitin sulfate proteoglycan receptors and not by the collagen-binding integrins or melanoma-associated proteoglycan. Melanoma cell adhesion to and spreading on the triple-helical alpha1(IV)1263-1277 sequence was then compared for glycosylated (replacement of Lys(1265) with Hyl(O-beta-d-galactopyranosyl)) versus non-glycosylated ligand. Glycosylation was found to strongly modulate both activities, as adhesion and spreading were dramatically decreased due to the presence of galactose. CD44/chondroitin sulfate proteoglycan did not bind to glycosylated alpha1(IV)1263-1277. Overall, this study (a) is the first demonstration of the prophylactic effects of glycosylation on tumor cell interaction with the basement membrane, (b) provides a rare example of an apparent unfavorable interaction between carbohydrates, and (c) suggests that sugars may mask "cryptic sites" accessible to tumor cells with cell surface or secreted glycosidase activities.     

The alpha 1 beta 1 heterodimer of ATP synthase

The alpha 3 beta 3 hexamer was reconstituted from the alpha and beta subunits of TF1 portion of ATP synthase of thermophilic bacterium (Kagawa et al. (1989) FEBS Lett. 249, 67). The alpha 1 beta 1 heterodimer of ATP synthase was isolated by high performance liquid chromatography (HPLC) of the alpha 3 beta 3 hexamer in the presence of AT(D)P-Mg. On polyacrylamide gel electrophoresis, both bands corresponding to the dimer and hexamer showed ATPase activity. The alpha 1 beta 1 dimer was dissociated into the equal amounts of the alpha and beta monomers by sodium dodecyl sulfate. The alpha and beta monomers were practically inactive. The alpha 2 and beta 2 homodimers were not detected by electrophoresis and HPLC.     

Type XII collagen. A large multidomain molecule with partial homology to type IX collagen

Three overlapping cDNAs encoding alpha 1 (XII) collagen have been isolated and sequenced. The DNAs define five sequence domains within the chain. Three domains are nontriple-helical; two are relatively short triple-helical regions. The amino acid sequences of tryptic peptides derived from 16- and 10-kDa pepsin-resistant fragments isolated from tendon extracts are in full agreement with the deduced sequences of the triple-helical regions. Two of the five sequence domains in alpha 1 (XII), one triple-helical and one nontriple-helical, show a high degree of similarity to regions in type IX collagen chains. In addition, examination of seven exons in the alpha 1 (XII) gene shows that the gene is, in part, similar to the structure of type IX collagen genes. Therefore, collagen types IX and XII are partially homologous. The alpha 1 (XII) sequence data predict an asymmetric structure for type XII collagen molecules, fully consistent with the rotary shadowing images. These images show a triple-helical 75-nm tail attached through a central globule to three finger-like structures, each 60 nm long (Dublet, B., Oh, S., Sugrue, S. P., Gordon, M. K., Gerecke, D. R., Olsen, B. R., and van der Rest, M. (1989) J. Biol. Chem. 264, 13150-13156).     

Exon/intron structure of the human alpha 3(IV) gene encompassing the Goodpasture antigen (alpha 3(IV)NC1). Identification of a potentially antigenic region at the triple helix/NC1 domain junction.

The Goodpasture antigen has been identified as the non-collagenous (NC1) domain of alpha 3(IV), a novel collagen IV chain (Saus, J., Wieslander, J., Langeveld, J., Quinones, S., and Hudson, B.G. (1988) J. Biol. Chem. 263, 13374-13380). In the present study, the exon/intron structure and sequence for 285 amino acids of human alpha 3(IV), comprising 53 amino acids of the triple-helical domain and the complete NC1 domain (232 amino acids), were determined. Based on the comparison of the amino acid sequences of the alpha 1(IV), alpha 2(IV), alpha 3(IV), and alpha 5(IV) NC1 domains, a phylogenetic tree was constructed which indicates that alpha 2(IV) was the first chain to evolve, followed by alpha 3(IV), and then by alpha 1(IV) and alpha 5(IV). The exon/intron structure of these domains is consistent with this evolution model. In addition, it appears that alpha 3(IV) changed most after diverging from the parental gene. Analysis of its primary structure reveals that, at the junction between the triple-helical and NC1 domains, there exists a previously unrecognized, highly hydrophilic region (GLKGKRGDSGSPATWTTR) which is unique to the human alpha 3(IV) chain, containing a cell adhesion motif (RGD) as an integral part of a sequence (KRGDSGSP) conforming to a number of protein kinase recognition sites. Based on primary structure data, we outline new aspects to be explored concerning the molecular basis of collagen IV function and Goodpasture syndrome.     

Construction and characterization of cDNA encoding the alpha 2 chain of chicken type IX collagen

We have isolated and characterized a cDNA encoding the carboxy-terminal half of one of the polypeptide subunits of a novel disulfide-bonded collagen found in hyaline cartilage. This collagen has been given the type assignment type IX, and it has several unusual characteristics. First, the polypeptide subunits are shorter than alpha-chains of the fibrillar collagens types I, II, and III. Second, type IX molecules are heterotrimers of three genetically distinct polypeptide subunits. Third, type IX molecules contain three triple-helical collagenous domains interspersed with noncollagenous domains. When chicken cartilage collagens are extracted with pepsin, type IX collagen is cleaved and gives rise to the triple-helical fragments HMW and LMW. The identification of the cDNA reported here is based on a comparison of the amino acid composition of tryptic peptides derived from LMW with the composition of tryptic peptides predicted from the nucleotide sequence of the cDNA. We also show that the amino-terminal sequence of one of the subunits of LMW is identical with the sequence predicted from the nucleotide sequence of the cDNA. Finally, we demonstrate that the amino-terminal amino acid sequence of a tryptic peptide isolated from one of the subunits of HMW is identical with a sequence predicted from the cDNA. We have given the polypeptide chain encoded by the cDNA reported here the name alpha 2(IX), and we show that it is homologous to the alpha 1(IX) chain previously characterized by us.     

Glomerular basement membrane. Identification of dimeric subunits of the noncollagenous domain (hexamer) of collagen IV and the Goodpasture antigen

The noncollagenous (NC1) domain hexamer of glomerular basement membrane (GBM) collagen is composed of a multiplicity of monomeric and dimeric subunits, and specific subunits are the targets for anti-GBM autoantibodies of patients with Goodpasture (GP) syndrome. The identity of GBM monomers has been established and the alpha 3(IV)NC1 monomer identified as the one that binds GP antibodies (Gunwar, S., Saus, J., Noelken, M. E., and Hudson, B. G. (1990) J. Biol. Chem. 265, 5466-5469). In the present study, the chain origin of 25 dimeric components and the identity of those that bound the anti-GBM antibodies from two GP patients were determined. This was accomplished by NH2-terminal sequence analysis and immunoblotting analysis of dimeric components that were resolved by two-dimensional electrophoresis in combination with high pressure liquid chromatography. The results revealed that (a) the components are mainly homodimers of the NC1 domains of alpha 1, alpha 2, alpha 3, alpha 4, and probably alpha 5 chains of collagen IV, reflecting a specificity of promoter-promoter association and (b) each homodimer had several size and charge isoforms. The GP antibodies bound exclusively to both alpha 3(IV)NC1 monomers and dimers and not to other basement membrane constituents. These findings provided new insights about the structure of GBM collagen and together with our previous findings firmly established the alpha 3(IV) chain as the target for the anti-GBM antibodies that mediate glomerulonephritis and pulmonary hemorrhage in patients with Goodpasture syndrome.     

The complete primary structure of mouse alpha 2(IV) collagen. Alignment with mouse alpha 1(IV) collagen

We have determined the nucleotide and amino acid sequences of mouse alpha 2(IV) collagen which is 1707 amino acids long. The primary structure includes a putative 28-residue signal peptide and contains three distinct domains: 1) the 7 S domain (residues 29-171), which contains 5 cysteine and 8 lysine residues, is involved in the cross-linking and assembly of four collagen IV molecules; 2) the triple-helical domain (residues 172-1480), which has 24 sequence interruptions in the Gly-X-Y repeat up to 24 residues in length; and 3) the NC1 domain (residues 1481-1707), which is involved in the end-to-end assembly of collagen IV and is the most highly conserved domain of the protein. Alignment of the primary structure of the alpha 2(IV) chain with that of the alpha 1(IV) chain reported in the accompanying paper (Muthukumaran, G., Blumberg, B., and Kurkinen, M. (1989) J. Biol. Chem. 264, 6310-6317) suggests that a heterotrimeric collagen IV molecule contains 26 imperfections in the triple-helical domain. The proposed alignment is consistent with the physical data on the length and flexibility of collagen IV.     

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.     

Porcine parvovirus removal using trimer and biased hexamer peptides

Assuring the microbiological safety of biological therapeutics remains an important concern. Our group has recently reported small trimeric peptides that have the ability to bind and remove a model nonenveloped virus, porcine parvovirus (PPV), from complex solutions containing human blood plasma. In an effort to improve the removal efficiency of these small peptides, we created a biased library of hexamer peptides that contains two previously reported trimeric peptides designated WRW and KYY. This library was screened and several hexamer peptides were discovered that also removed PPV from solution, but there was no marked improvement in removal efficiency when compared to the trimeric peptides. Based on simulated docking experiments, it appeared that hexamer peptide binding is dictated more by secondary structure, whereas the binding of trimeric peptides is dominated by charge and hydrophobicity. This study demonstrates that trimeric and hexameric peptides may have different, matrix-specific roles to play in virus removal applications. In general, the hexamer ligand may perform better for binding of specific viruses, whereas the trimer ligand may have more broadly reactive virus-binding properties.     

Small-angle X-ray scattering studies of Mg.AT(D)P-induced hexamer to dimer dissociation in the reconstituted alpha 3 beta 3 complex of ATP synthase from thermophilic bacterium PS3.

The alpha 3 beta 3 complex of ATP synthase obtained from a thermophilic bacterium PS3 was isolated and found to show the ATPase activity (Kagawa, Y., Ohta, S., and Otawara-Hamamoto, Y. (1989) FEBS Lett. 249, 67-69). The structure and the nucleotide binding effects of the alpha 3 beta 3 complex were investigated by means of small-angle x-ray scattering and high performance liquid chromatography. The scattering profile from the alpha 3 beta 3 complex was explained with a model in which the complex is made of an ellipsoid of revolution with the axes of 121.8, 121.8, and 72.0 A having an elliptical hollow cavity with the axes of 35.4, 35.4, and 72.0 A. By the addition of Mg.AT(D)P, significant changes in the scattering profile were observed, in which the radius of gyration decreased from 44 to 35 A. This change was found by gel filtration to be caused by the dissociation reaction from the alpha 3 beta 3 hexamer to the alpha beta dimer. The dissociation of the alpha 3 beta 3 complex was not induced by unhydrolyzable ATP analogue, nor by Pi, Mg2+, and Pi + Mg2+. The structure of the dimer was well explained by the triaxial ellipsoidal model with the axes of 105.2, 39.4, and 108.2 A. The dissociation into the dimer is considered to be related to the ATPase activity because the AT(D)P-induced dissociation is observed only in the presence of Mg2+ ions.