Assembly and routing of von Willebrand factor variants: the requirements for disulfide-linked dimerization reside within the carboxy-terminal 151 amino acids

The precursor protein of von Willebrand factor (pro-vWF) consists of four different repeated domains, denoted D1-D2-D'-D3-A1-A2-A3-D4-B1-B2-B3-C1-C2, followed by a carboxy-terminal region of 151 amino acids without obvious internal homology. Previously, we have shown the requirement of the domains D1, D2, D', and D3 of pro-vWF in the assembly of pro-vWF dimers into multimers. Here, we define the domains of vWF involved in dimerization, using deletion mutants of full-length vWF cDNA transiently expressed in monkey kidney COS-1 cells. It is shown that only the carboxy-terminal 151 amino acid residues of vWF are required for dimerization. In addition, by analyzing a construct, encoding only the carboxy-terminal 151 amino acids of vWF, we find that the formation of dimers is an event independent of other domains present on pro-vWF, such as the domains C1 and C2 previously suggested to be involved in dimerization. Furthermore, it is shown that a deletion mutant of vWF, lacking the carboxy-terminal 151 amino acid residues and thus unable to dimerize, is proteolytically degraded in the ER. In contrast, a mutant protein, composed only of the carboxy-terminal 151 amino acids of vWF, and able to dimerize, is transported from the ER in a similar fashion as wild-type vWF. The role of the ER in the assembly of vWF is discussed with regard to the data presented in this paper on the intracellular fate of several vWF mutant proteins.     

Expression of variant von Willebrand factor (vWF) cDNA in heterologous cells: requirement of the pro-polypeptide in vWF multimer formation.

Von Willebrand factor (vWF) is a multimeric plasma glycoprotein synthesized by vascular endothelial cells as a pre-pro-polypeptide with a highly repetitive domain structure, symbolized by the formula: (H)-D1-D2-D'-D3-A1-A2-A3-D4-B1-B2-B3-C1-C2-(OH) A heterologous expression system for the synthesis of recombinant vWF protein was developed, consisting of a monkey kidney cell line (COS-1), transfected with full-length vWF cDNA. This system was shown to mimic the constitutive secretory pathway of vWF in endothelial cells, since dimerization and multimerization occur similarly. To determine whether the pro-polypeptide, composed of the domains D1 and D2, is involved in vWF multimerization, a vWF cDNA was constructed that lacked the coding sequence for the pro-polypeptide. The mutant vWF protein, expressed by COS-1 cells transfected with this cDNA, did not assemble beyond the dimer stage. From this observation, we conclude that (i) dimerization does not involve the pro-polypeptide of pro-vWF and (ii) the presence of the pro-polypeptide, as part of pro-vWF, is obligatory for multimerization. It is argued that the interactions, required for interchain binding, are mediated by the D domains.     

Biogenesis of von Willebrand factor-containing organelles in heterologous transfected CV-1 cells.

Von Willebrand factor (vWF) is a multimeric protein involved in the adhesion of platelets to an injured vessel wall. vWF is synthesized by the endothelial cell and the megakaryocyte as a precursor protein (pro-vWF) that consists of four repeated domains, denoted D1-D2-D'-D3-A1-A2-A3-D4-B1-B2-B3-C1-C2. Previously, we have defined the domains on the pro-vWF molecule involved in dimerization as well as the domains involved in multimer assembly of vWF dimers. In the endothelial cell, part of the vWF multimers is stored in specialized organelles, the Weibel-Palade bodies. By using immunoelectron microscopy, we demonstrate that upon expression of full-length vWF cDNA, vWF-containing organelles are encountered in monkey kidney CV-1 cells that are morphologically similar to the endothelial-specific Weibel-Palade bodies. Expression in CV-1 cells of a series of vWF cDNA deletion mutants, lacking one or more domains, revealed that only those vWF mutant proteins that are able to assemble into multimers are encountered in dense-cored vesicles. Our data show that this process is independent of a particular domain on vWF and indicate that a 'condensed', multimeric vWF is required for targeting to the Weibel-Palade body.     

Full-length von Willebrand factor (vWF) cDNA encodes a highly repetitive protein considerably larger than the mature vWF subunit.

Full-length human von Willebrand factor (vWF) cDNA was assembled from partial, overlapping vWF cDNAs. This cDNA construct includes a coding sequence of 8439 nucleotides which encode a single-chain precursor of 2813 amino-acid residues, representing a putative signal peptide, a prosequence and mature vWF of 22, 741 and 2050 amino acids, respectively. This represents the longest coding sequence determined to date. In-vitro expression of full-length vWF cDNA revealed the synthesis of a polypeptide with a mol. wt corresponding with that of the unglycosylated precursor. The precursor is a highly repetitive protein which consists of two duplicated (B, C), a triplicated (A), a quadruplicated (D) and a partly duplicated domain (D'), in the following order: H-D1-D2-D'-D3-A1-A2-A3-D4-B1-B2-C1-C2-OH. Both the prosequence, composed of two D domains (D1, D2), and mature vWF harbor an arg-gly-asp ('R-G-D') sequence which has been implicated in cell-attachment functions. It is argued that the pro-sequence is equivalent to von Willebrand Antigen II (vW AgII).     

Proteolytic cleavage of the precursor of von Willebrand factor is not essential for multimer formation

Monkey kidney cells (COS-1), transfected with full-length human von Willebrand factor (vWF) cDNA encoding the precursor of vWF (pro-vWF), mimic the characteristics of the biosynthesis and of the constitutive secretory pathway, displayed by cultured vascular endothelial cells. Such heterologous transfected cells are able to cleave pro-vWF, generating the propolypeptide and mature vWF, and to assemble pro-vWF dimers into a series of multimers, similarly to endothelial cells. Evidence is presented showing that proteolytic processing of pro-vWF by COS-1 cells occurs at the peptide bond between arginine and serine in the sequence Lys762-Arg763-Ser764, identical to endothelial cell-associated proteolysis. This conclusion stems from the observation that substitution of Arg763 by a glycine residue completely abolishes proteolytic processing. As a result, transfection of COS-1 with the mutant vWF-Gly763 cDNA does not significantly affect the multimeric organization of secreted vWF molecules. Consequently, we conclude that proteolytic processing of pro-vWF is not required for multimer formation. Pulse-chase labeling of COS-1 cells transfected with full-length vWF cDNA reveals pro-vWF exclusively in cell lysates, whereas both pro-vWF and mature vWF are encountered in the conditioned medium. These observations indicate that proteolytic processing of pro-vWF is a "late" event during intracellular routing of these molecules or may occur extracellularly.     

In vivo and in vitro processing of recombinant pro-von Willebrand factor

Von Willebrand factor (vWF) is synthesized in endothelial cells as pre-pro-vWF and processed intracellularly to propeptide (vWFpp) and mature vWF. Recombinant pro-vWF when infused into animals can also be processed extracellularly in vivo. Within 1 h of infusion in a dog and mice the multimer pattern changed to that typically seen in mature vWF indicating that propeptide cleavage from unprocessed vWF occurs extracellularly in the circulation. Incubation of a recombinant pro-vWF preparation with canine and human vWF-deficient plasma induced a time-dependent decrease in pro-vWF antigen and an increase in vWFpp antigen without changing total vWF antigen or collagen-binding activity. Multimer analysis showed the gradual transformation of the pro-vWF multimers to mature vWF multimers and cleaved vWFpp was visualized on autoradiograms of SDS-polyacrylamide electrophoresis gels using (125)I-labeled pro-vWF. When recombinant pro-vWF was incubated with increasing amounts of purified thrombin, the extent of pro-vWF processing was dose dependent. The specific cleavage of vWFpp was confirmed by immunoblots using an anti-vWFpp antibody and by amino-terminal amino acid analysis. Hirudin preconditioning of vWF-deficient mice attenuated processing of infused recombinant pro-vWF suggesting that thrombin plays a part in the processing events in vivo.     

The propeptide of von Willebrand factor independently mediates the assembly of von Willebrand multimers

The biosynthesis of von Willebrand Factor (vWF) by vascular endothelial cells involves a complex series of processing steps that includes proteolytic cleavage of a 741-residue propeptide and the assembly of disulfide-linked multimers. Using a model system in which experimentally altered vWF cDNAs are expressed in COS-1 cells, we have shown that the vWF propeptide contains determinants that govern the assembly of vWF multimers. Furthermore, the role of the propeptide (in the assembly process) does not require it to be a contiguous part of the pro-vWF primary structure, since independently expressed propeptide was shown to promote the assembly of mature vWF subunits into multimers. Pulse-chase experiments indicated that the independently expressed propeptide formed a transient association with the mature vWF subunit inside the cell. Thus, it appears that the vWF propeptide segment can act in "trans" to direct the assembly of disulfide-linked vWF multimers.     

Human TRPV4 channel splice variants revealed a key role of ankyrin domains in multimerization and trafficking

The TRPV4 cation channel exhibits a topology consisting of six predicted transmembrane domains (TM) with a putative pore loop between TM5 and TM6 and intracellular N- and C-tails, the former containing at least three ankyrin domains. Functional transient receptor potential (TRP) channels are supposed to result following the assembly of four subunits. However, the rules governing subunit assembly and protein domains implied in this process are only starting to emerge. The ankyrin, TM, and the C-tail domains have been identified as important determinants of the oligomerization process. We now describe the maturation and oligomerization of five splice variants of the TRPV4 channel. The already known TRPV4-A and TRPV4-B (delta384-444) variants and the new TRPV4-C (delta237-284), TRPV4-D (delta27-61), and TRPV4-E (delta237-284 and delta384-444) variants. All alternative spliced variants involved deletions in the cytoplasmic N-terminal region, affecting (except for TRPV4-D) the ankyrin domains. Subcellular localization, fluorescence resonance energy transfer, co-immunoprecipitation, glycosylation profile, and functional analysis of these variants permitted us to group them into two classes: group I (TRPV4-A and TRPV4-D) and group II (TRPV4-B, TRPV4-C, and TRPV4-E). Group I, unlike group II variants, were correctly processed, homo- and heteromultimerized in the endoplasmic reticulum, and were targeted to the plasma membrane where they responded to typical TRPV4 stimuli. Our results suggest that: 1) TRPV4 biogenesis involves core glycosylation and oligomerization in the endoplasmic reticulum followed by transfer to the Golgi apparatus for subsequent maturation; 2) ankyrin domains are necessary for oligomerization of TRPV4; and 3) lack of TRPV4 oligomerization determines its accumulation in the endoplasmic reticulum.     

Characterization of newly identified four isoforms for a putative cytosolic protein tyrosine phosphatase PTP36

In the course of determining the expression profiles of protein tyrosine phosphatases in lactating mammary gland, we found the expression of an isoform for a putative cytosolic and cytoskeleton-associated protein tyrosine phosphatase PTP36. Further detailed RT-PCR and Northern blot analyses revealed the expression of several isoforms for PTP36 in a tissue-dependent manner. We have cloned the cDNAs encoding four truncated isoforms for PTP36 and designated PTP36-A, -B, -C, and -D, respectively. PTP36-A and -C had new sequences generated due to frameshift, whereas PTP36-B and -D were in-frame variants. Gly- and Glu-rich domains and a putative PTP domain were missing from PTP36-A, but the band 4.1 domain remained. PTP36-B retained the band 4.1 and PTP domains but lacked Pro-, Gly- and Glu-rich domains. Most domain structures were lacking in PTP36-C and -D. Interestingly, PTP36-C contained an incomplete band 4.1 domain, but the newly created sequence exhibited high homology to human nebulette, which was also suggested to associate with cytoskeletons. When transiently expressed in COS7 and HEK293 cells, not only the wild type but also all the isoforms were recovered in Triton X-100-insoluble cytoskeleton-associated fractions and this distribution was not affected by mechanical cell detachment and treatment with a kinase inhibitor staurosporine. Such cellular distribution of PTP36 was also observed in stable COS7 clones. Further studies using deletion mutants suggested that the first 30 amino acids as well as the band 4.1 domain of PTP36 were involved in association with Triton X-100 insoluble cytoskeletons. Tissue-dependent expression and deletion in domain structures might reflect the biological significance of the isoforms for PTP36 in certain physiological conditions.     

Construction and characterization of an active factor VIII variant lacking the central one-third of the molecule

The primary structure of factor VIII consists of 2332 amino acids that exhibit 3 distinct structural domains, including a triplicated region (A domains), a unique region of 909 amino acids (B domain), and a carboxy-terminal duplicated region (C domains), that are arranged in the order A1-A2-B-A3-C1-C2. The B domain (residues 741-1648) of factor VIII is lost when factor VIII is activated by thrombin, which proteolytically processes factor VIII to active subunits of Mr 50,000 (domain A1), 43,000 (domain A2), and 73,000 (domains A3-C1-C2). To determine if the B domain is required for factor VIII coagulant activity, a variant was constructed by using recombinant DNA techniques in which residues 797-1562 were eliminated. This shortened the B domain from 909 to 142 amino acids. This variant factor VIIIdes-797-1652 was expressed in mammalian cells and was found to be functional. The factor VIIIdes-797-1562 protein was purified and shown to be processed by thrombin in the same manner as full-length factor VIII. The factor VIIIdes-797-1562 variant also bound to von Willebrand factor (vWF) immobilized on Sepharose. These results indicate that most of the highly glycosylated B domain of factor VIII is not required for the expression of factor VIII coagulant activity and its interaction with vWF.     

Alternative splicing produces transcripts encoding four variants of mouse G-protein-coupled receptor kinase 6.

A family of protein kinases, termed G-protein-coupled receptor kinases (GRK1-6), is known to phosphorylate agonist-occupied G-protein-coupled receptors. We have identified mRNAs encoding four distinct mouse GRK6 isoforms (mGRK6), designated mGRK6-A through mGRK6-D. Mouse GRK6-B and mGRK6-C diverge from the known human GRK6 (577 residues) at residue 560 and are 13 residues longer and 16 residues shorter, respectively, than human GRK6, while mGRK6-A very likely represents the mouse equivalent of human GRK6. Mouse GRK6-D is identical to the other mGRK6 variants in the amino-terminal region, but comprises only 59 of the 263 amino acids of the putative catalytical domain. As mGRK6-D retains the region involved in interacting with activated receptors, but most likely lacks catalytic activity, this variant might represent a naturally occurring inhibitor of other GRKs. Analysis of the genomic organization of mGRK6 gene revealed that the four mRNAs are generated by alternative RNA splicing from a single approximately 14. 5-kb gene, made up of at least 17 exons and located on mouse chromosome 13. Similar to human GRK6, mGRK6-A contains three cysteine residues within its carboxyl-terminal region known to serve as substrates for palmitoylation. Mouse GRK6-B lacks these palmitoylation sites, but carries a basic carboxyl-terminus containing consensus sequences for phosphorylation by protein kinases C and cAMP/cGMP-dependent protein kinases. Mouse GRK6-C displays none of these motifs. Thus, mGRK6-A, mGRK6-B, and mGRK6-C are predicted to differ in terms of their regulation by carboxyl-terminal posttranslational modification. Analysis of mRNA expression revealed that the four mGRK6 mRNAs are differentially expressed in mouse tissues, suggesting that the four mGRK6 isoforms are involved in regulating tissue- or cell type-specific functions in vivo.     

Analysis of DNA from human adenovirus type 6 with restriction endonucleases HindIII, BglIII and BamHI

The genome of the type 6 human adenovirus has three restriction sites for R.BamHI, thirteen for R.HindIII and ten for R.BglII. The terminal fragments of DNA cleaved by each of the enzymes have been determined by means of terminal nucleotidyl transferase and by analysis of the DNA-terminal protein complex. The sequence of the cleaved fragments has been determined by partial cleavage of DNA, simultaneous digestion of DNA with various combinations of enzymes and secondary digestion of individual isolated fragments with other enzymes. The following order of the cleaved fragments in the adenovirus type 6 genome has been found (the figures in brackets are the weights in mega-daltons): for R.BamHI-B(7.1)-D(3.0)-C(4.05)-A(8.5); for R.HindIII-F(1.7)-C1(2.14)-A(3.44)-M(0.046)-I(1.24)-J(0.77)-D(2.1)-E(1.96)-B(3.18)-H(1.36)-L(0.18)-C2(2.14)-G(1.44)-K(0.16); for R.BglII-E(2.07)-B(3.58)-A(4.8)-C(3.36)-I(0.78)-D(3.25)-G(1.37)-J(0.21)-F(1.85)-K(0.17)-H(0.94).     

The variable C-terminal extension of G-protein-coupled receptor kinase 6 constitutes an accessorial autoregulatory domain

G-protein-coupled receptor kinases (GRK) are known to phosphorylate agonist-occupied G-protein-coupled receptors. We expressed and functionally characterized mouse GRK6 proteins encoded by four distinct mRNAs generated by alternative RNA splicing from a single gene, mGRK6-A to mGRK6-D. Three isoforms, mGRK6-A to mGRK6-C differ in their C-terminal-most portion, which is known to mediate membrane and/or receptor interaction and regulate the activity of GRK4-like kinases. One isoform, mGRK6-D, is identical to the other mGRK6 variants in the N-terminal region, but carries an incomplete catalytical domain. Mouse GRK6-D was catalytically inactive and specifically present in the nucleus of transfected cells. Recombinant mouse GRK6-A to mGRK6-C were found to be membrane-associated in cell-free systems and in transfected COS-7 cells, suggesting that the very C-terminus of GRK6-A, lacking in GRK6-B and mGRK6-C and carrying consensus sites for palmitoylation, is not required for membrane interaction. Interestingly, the shortest catalytically active variant, mGRK6-C, was conspicuously more active in phosphorylating light-activated rhodopsin than mGRK6-A and mGRK6-B, implying that the C-terminus of the latter two variants may fulfil an autoinhibitory function. Mutation and removal of C-terminal-most region of mGRK6-A by site-directed mutagenesis revealed that this region contains three autoregulatory elements: two discontinuous inhibitory elements consisting of a single residue, D560, and the sequence between residues S566 and L576, and an intervening stimulatory element. The results suggest that mGRK6-C may be considered a basic, prototypic representative of the GRK4-like kinases, which is capable of interacting with both plasma membrane and its receptor substrate, but is resistant to further regulatory modification conferred to the prototype via C-terminal extension.     

Phylogenetic and functional analysis of histidine residues essential for pH-dependent multimerization of von Willebrand factor

von Willebrand factor (VWF) is a multimeric plasma protein that mediates platelet adhesion to sites of vascular injury. The hemostatic function of VWF depends upon the formation of disulfide-linked multimers, which requires the VWF propeptide (D1D2 domains) and adjacent D′D3 domains. VWF multimer assembly occurs in the trans-Golgi at pH ∼6.2 but not at pH 7.4, which suggests that protonation of one or more His residues (pK_a ∼6.0) mediates the pH dependence of multimerization. Alignment of 30 vertebrate VWF sequences identified 13 highly conserved His residues in the D1D2D′D3 domains, and His-to-Ala mutagenesis identified His³⁹⁵ and His⁴⁶⁰ in the D2 domain as critical for VWF multimerization. Replacement of His³⁹⁵ with Lys or Arg prevented multimer assembly, suggesting that reversible protonation of this His residue is essential. In contrast, replacement of His⁴⁶⁰ with Lys or Arg preserved normal multimer assembly, whereas Leu, Met, and Gln did not, indicating that the function of His⁴⁶⁰ depends primarily upon the presence of a positive charge. These results suggest that pH sensing by evolutionarily conserved His residues facilitates the assembly and packaging of VWF multimers upon arrival in the trans-Golgi.     

The C5 domain of the collagen VI alpha3(VI) chain is critical for extracellular microfibril formation and is present in the extracellular matrix of cultured cells

Collagen VI, a microfibrillar protein found in virtually all connective tissues, is composed of three distinct subunits, alpha1(VI), alpha2(VI), and alpha3(VI), which associate intracellularly to form triple helical heterotrimeric monomers then dimers and tetramers. The secreted tetramers associate end-to-end to form beaded microfibrils. Although the basic steps in assembly and the structure of the tetramers and microfibrils are well defined, details of the interacting protein domains involved in assembly are still poorly understood. To explore the role of the C-terminal globular regions in assembly, alpha3(VI) cDNA expression constructs with C-terminal truncations were stably transfected into SaOS-2 cells. Control alpha3(VI) N6-C5 chains with an intact C-terminal globular region (subdomains C1-C5), and truncated alpha3(VI) N6-C1, N6-C2, N6-C3, and N6-C4 chains, all associated with endogenous alpha1(VI) and alpha2(VI) to form collagen VI monomers, dimers and tetramers, which were secreted. These data demonstrate that subdomains C2-C5 are not required for monomer, dimer or tetramer assembly, and suggest that the important chain selection interactions involve the C1 subdomains. In contrast to tetramers containing control alpha3(VI) N6-C5 chains, tetramers containing truncated alpha3(VI) chains were unable to associate efficiently end-to-end in the medium and did not form a significant extracellular matrix, demonstrating that the alpha3(VI) C5 domain plays a crucial role in collagen VI microfibril assembly. The alpha3(VI) C5 domain is present in the extracellular matrix of SaOS-2 N6-C5 expressing cells and fibroblasts demonstrating that processing of the C-terminal region of the alpha3(VI) chain is not essential for microfibril formation.     

Characteristics of von Willebrand Factor multimer adhesion and its bio-inspired applications

The von Willebrand Factor (vWF) is a large multimeric protein that aids blood clotting. Hydrodynamic force triggers elongation of vWF; this regulates its activity by exposing binding sites for platelets and collagen. To investigate mechanisms of vWF multimer adhesion to relevant biological entities, a coarse grain molecular model is used to explore vWF interaction with collagen-coated surfaces. The vWF multimer model incorporates observed mechanical properties of vWF monomers in that the model A2 domain in each monomer is capable of significant elongation with sufficient applied force on the molecule. Brownian dynamics simulations have been performed to understand a single vWF multimer adhesion process in both free-draining and hydrodynamic interactions (HI) cases. Results show the configuration at the moment of adhesion is critical, as this dictates the configuration of vWF thereafter. The presence of the collagen-coated surface increases the stretching of vWF multimers and the elongation of model A2 domains. HI effect plays a hindering role in unfolding of vWF multimer and elongation of model A2 domains. The adhesion is impeded by HI, and results in hydrodynamic lift leading to vWF multimer migration away from the wall.     

Identification of bacterial clones encoding bovine caseins by direct immunological screening of the cDNA library

A sensitive immunoassay was used to identify recombinant plasmids carrying cDNA fragments of bovine caseins in the cDNA library from bovine mammary gland mRNA. Colonies grown on nitrocellulose filters were lysed in situ and proteins from the lysates were blotted onto CNBr-activated cellulose filter paper. Antigens covalently bound to CNBr-activated paper or bound to nitrocellulose filters were detected by reaction with antiserum to caseins, followed by ¹²⁵I-labelled Staphylococcus aureus protein A and autoradiography. Six clones were found positive among 5400 of the cDNA library: 3-A1, 3-B2, 3-B5, 3-H7, 2-A5 and 2-C9. The molecular weights of chimeric pre-β-lactamase: casein proteins synthesized in Escherichia coli were estimated by immunoblotting. Colony hybridization and nucleotide sequence analysis showed that clone 3-B5 contained a cDNA fragment of bovine χ-casein, clone 3-H7 contained a cDNA fragment of β-casein, while clones 2-A5 and 2-C9 carried cDNA fragments of α_si-casein.     

Characterization of ephrin-A1 and ephrin-A4 as ligands for the EphA8 receptor protein tyrosine kinase.

The Eph receptors are the largest known family of receptor protein tyrosine kinases, which play important roles with their ligands called ephrin in the neural development, angiogenesis, and vascular network assembly. It was previously shown that ephrin-A2, -A3 and -A5 bind to, and activate the EphA8 receptor tyrosine kinase, respectively. In this study, we have examined if there are other additional ephrin ligands interacting with the EphA8 receptor tyrosine kinase expressed in NIH3T3 fibroblasts. For this purpose, we have constructed chimeric ephrin-A1, -A4, -B1, -B2 or -B3 ligands consisting of the Fc portion of human IgG fused to their carboxyl-terminus. Both ephrin-A1 and ephrin-A4 chimeric ligands efficiently bound to the EphA8 receptor expressed in NIH3T3 fibroblasts, whereas the transmembrane ligands including ephrin-B1, -B2 and -B3 did not. Additionally we have demonstrated that both the EphA8-TrkB chimeric receptor and the EphA8 receptor expressed in NIH3T3 fibroblasts are efficiently tyrosine-phosphorylated upon stimulating with epthin-A1 or -A4 but none of transmembrane ephrin-B proteins. These results strongly indicate that the EphA8 receptor functions exclusively as an glycosyl phosphatidylinositol (GPI)-linked ephrin ligand-dependent receptor protein tyrosine kinase.     

The N-terminal N5 subdomain of the alpha 3(VI) chain is important for collagen VI microfibril formation

Collagen VI assembly is unique within the collagen superfamily in that the alpha 1(VI), alpha 2(VI), and alpha 3(VI) chains associate intracellularly to form triple helical monomers, and then dimers and tetramers, which are secreted from the cell. Secreted tetramers associate end-to-end to form the distinctive extracellular microfibrils that are found in virtually all connective tissues. Although the precise protein interactions involved in this process are unknown, the N-terminal globular regions, which are composed of multiple copies of von Willebrand factor type A-like domains, are likely to play a critical role in microfibril formation, because they are exposed at both ends of the tetramers. To explore the role of these subdomains in collagen VI intracellular and extracellular assembly, alpha 3(VI) cDNA expression constructs with sequential N-terminal deletions were stably transfected into SaOS-2 cells, producing cell lines that express alpha 3(VI) chains with N-terminal globular domains containing modules N9-N1, N6-N1, N5-N1, N4-N1, N3-N1, or N1, as well as the complete triple helix and C-terminal globular domain (C1-C5). All of these transfected alpha 3(VI) chains were able to associate with endogenous alpha 1(VI) and alpha 2(VI) to form collagen VI monomers, dimers, and tetramers, which were secreted. Importantly, cells that expressed alpha 3(VI) chains containing the N5 subdomain, alpha 3(VI) N9-C5, N6-C5, and N5-C5, formed microfibrils and deposited a collagen VI matrix. In contrast, cells that expressed the shorter alpha 3(VI) chains, N4-C5, N3-C5, and N1-C5, were severely compromised in their ability to form end-to-end tetramer assemblies and failed to deposit a collagen VI matrix. These data demonstrate that the alpha 3(VI) N5 module is critical for microfibril formation, thus identifying a functional role for a specific type A subdomain in collagen VI assembly.