Characterization of EHD4, an EH domain-containing protein expressed in the extracellular matrix.

To identify proteins that promote assembly of type VI collagen tetramers or stabilize type VI collagen filaments, a two-hybrid screen of a human placenta library was used and a new extracellular protein discovered. The cDNA sequence of the new protein encodes 541 amino acid residues. This cDNA sequence is identical to EHD4, a recently described member of the EH domain family of proteins. Two mRNAs of 4.4 and 3.0 kilobases were present in human skin fibroblasts and most tissues tested but were most prevalent in the heart. The chromosomal localization of the gene for this new protein was determined to be at 15q14-q15. Three polyclonal peptide antibodies were made against synthetic EHD4 peptides. The affinity-purified antibodies were used in immunofluorescent staining of developing limbs and matrices produced by human skin fibroblasts and mouse NIH3T3 fibroblasts in culture. Embryonic rat limb cartilage was strongly stained throughout development, and cultured fibroblasts deposited an extracellular filamentous network containing EHD4. In non-denaturing extracts of fetal bovine cartilage and in human skin fibroblast culture media, two components of approximately 220 and 158 kDa were observed, which, after reduction, migrated as a 56-kDa component on SDS-polyacrylamide gel electrophoresis. EHD4 is the first extracellular matrix protein described that contains an EH domain.

Fibrillin containing elastic microfibrils support platelet adhesion under dynamic shear conditions.

The vascular subendothelium contains macromolecular structures called microfibrils. Type VI collagen is one protein found in microfibrils that supports platelet adhesion and aggregation and we have previously evaluated the roles of platelet receptors and vWf involved in these processes under physiological shear conditions. Here we investigate the ability of fibrillin containing elastic microfibrils to support mural thrombus formation. Our results show that elastic microfibril surfaces support platelet adhesion under low shear conditions at a level similar to collagen VI tetramers. However, the degree of aggregation on the elastic microfibril surface is much higher. Both adhesion and aggregation were shown to be mediated by the GPIIb-IIIa platelet receptor. Elastic microfibrils do not support the formation of mural thrombi under high shear conditions. These results suggest roles for both collagen VI and fibrillin containing elastic microfibrils in modulating the platelet response to blood vessel injury.

Determination of the thermal loading of diode-pumped Nd:YVO(4) by use of thermally induced second-harmonic output depolarization.

A new method of using thermally induced second-harmonic output depolarization to determine the fractional thermal loading of a diode-pumped Nd:YVO(4) laser is proposed. The experimental results show that the fraction of the green output power polarized along the extraordinary axis of a KTP crystal, f(e) , is an oscillatory function of the absorbed pump power. The fractional thermal loading can be determined by measurement of the difference in the absorbed pump power between the peaks of f(e) .

Type VI collagen anchors endothelial basement membranes by interacting with type IV collagen.

Type VI collagen filaments are found associated with interstitial collagen fibers, around cells, and in contact with endothelial basement membranes. To identify type VI collagen binding proteins, the amino-terminal domains of the alpha1(VI) and alpha2(VI) chains and a part of the carboxyl-terminal domain of the alpha3(VI) chain were used as bait in a yeast two-hybrid system to screen a human placenta library. Eight persistently positive clones were identified, two coding the known matrix proteins fibronectin and basement membrane type IV collagen and the rest coding new proteins. The amino-terminal domain of alpha1(VI) was shown to interact with the carboxyl-terminal globular domain of type IV collagen. The specificity of this interaction was further studied using the yeast two-hybrid system in a one-on-one format and confirmed by using isolated protein domains in immunoprecipitation, affinity blots, and enzyme-linked immunosorbent assay-based binding studies. Co-distribution of type VI and type IV collagens in human muscle was demonstrated using double labeling immunofluorescent microscopy and immunoelectron microscopy. The strong interaction of type VI collagen filaments with basement membrane collagen provided a possible molecular pathogenesis for the heritable disorder Bethlem myopathy.

Morphological relationships of von Willebrand factor, type VI collagen, and fibrillin in human vascular subendothelium.

von Willebrand factor (vWF) plays an important role in the process of platelet adhesion after endothelial injury by serving as a bridge between constituents of the vascular subendothelium and platelet membrane receptors. We previously presented evidence that type VI collagen microfibrils serve as a binding site for vWF in human vascular subendothelium. However, others have proposed that vWF is not associated with type VI collagen but rather with the thicker elastin-associated microfibrils, which contain several proteins including fibrillin. We therefore investigated the relationships among vWF, type VI collagen, and fibrillin in human vascular subendothelium by immunoelectron microscopy using single- and double-labeling immunogold localization techniques. In addition, we observed the three-dimensional ultrastructure of vWF-microfibril complexes by stereo paired micrographs and stereo viewer. We found that vWF co-localizes only with the type VI collagen microfibrils in subendothelium but not with fibrillin microfibrils or striated collagen. The vWF is present in subendothelium in the form of electron-dense aggregates having diameters varying between 65 and 80 nm that are closely associated with, and enmesh, the type VI collagen microfibrils and have structural similarities to intracellular Weibel-Palade bodies. The occasional co-localization of type VI collagen and fibrillin adjacent to internal elastic lamina was observed. These results are consistent with the hypothesis that type VI collagen, but not fibrillin-containing microfibrils, serves as a physiologically relevant binding site for vWF in the vascular subendothelium, where the type VI collagen-vWF complex may play an important role modulating the hemostatic response to vascular injury.

The macromolecular structure of type-VI collagen. Formation and stability of filaments.

Type-VI collagen microfilaments were directly isolated from human amnion without using strong denaturing reagents. The microfilaments were characterized by electron microscopy, SDS/PAGE and immunoprecipitation. There was no evidence of other components bound to the isolated filaments and no covalent bonds between adjacent tetramers. The association between tetramers was further analyzed by studying the affinity between globular domains and the helix of type-VI collagen. Solid-phase-binding assays and conventional column chromatography showed that the globular domains have a high affinity for each other and for the helices of type-VI collagen, indicating that filaments may be assembled and stabilized in the absence of additional components. Hyaluronan did not stabilize the filaments nor facilitate the assembly of tetramers into filaments. The interaction between domains was also studied after modifying the sugar moieties of type-VI collagen globular domains and monomeric triple-helical domains. The oligosaccharides are involved in helix-helix interactions but not in interactions of the globular domains with each other or with the triple helix.

Neural crest cell interaction with type VI collagen is mediated by multiple cooperative binding sites within triple-helix and globular domains.

Collagen type VI (Col VI) is a primary constituent of the extracellular matrix encountered by migrating avian neural crest cells in situ and is effective in promoting attachment and motility of these cells in vitro. In this study, we have explored the molecular mechanisms of neural crest-Col VI interaction by using quantitative assays for cell attachment and migration in vitro, proteolytic fragments of the collagen, and a panel of domain-specific monoclonal antibodies. Removal of the predominant portion of the amino-terminal globular domains of Col VI tetramers by pepsin digestion (P6 fragment) resulted in a > fivefold decrease in their cell adhesion and motility-promoting activity. Further digestion of P6 with bacterial collagenase, which causes a complete loss of the amino-terminal domains plus an adjacent triple-helical segment, did not affect adhesion but reduced migration down to 40% of that seen on undigested P6. Untreated and pepsin-digested Col VI monomers were significantly less effective than their tetrameric counterparts and a M(r) 200,000 fragment, generated from pepsin-digested monomers by a second pepsin treatment, only retained 40% of the motility-promoting activity while preserving the adhesive capacity. A mixture of amino- and carboxyl-terminal globular domains supported both cell attachment and migration. While neural crest cells adhered equally well to the individual intact alpha 1 (VI)/alpha 2(VI) and alpha 3(VI) chains, they migrated most extensively on the alpha 3(VI) chain. Conversely, pepsin-digested individual alpha chains were significantly less effective in promoting cell adhesion and locomotion. Selective preincubation of Col VI microfilaments and isolated tetramers with a panel of monoclonal antibodies against triple helix, carboxyl-terminal, and amino-terminal epitopes of the different constituent chains differentially perturbed neural crest cell attachment and migration. Sites differentially involved in neural crest cell attachment and migration seemed to be present at the carboxyl termini of the alpha 1(VI) and alpha 2(VI) chains and at the amino-terminus of the alpha 3(VI) chain. The results suggest that neural crest cells interact with Col VI through multiple and cooperative binding sites present within its triple-helical and globular domains. The differential involvement and efficiency of these sites in stimulating neural crest cell adhesion and migration is strongly determined by the supramolecular organization of the collagen and requires inter- and intramolecular structural integrity. Since neural crest cell attachment and migration on Col VI was completely inhibited by anti-beta 1 integrin antibodies, there is evidence that this class of integrins is essential for the neural crest cell--Col VI interaction.

Collagen type VI in neural crest development: distribution in situ and interaction with cells in vitro.

We have examined the spatio-temporal distribution of collagen type VI (Col VI) during neural crest development in vivo and its ability to promote neural crest cell attachment and migration in vitro. An affinity purified antiserum and chain-specific monoclonal antibodies against chicken Col VI were employed to immunolocalize the collagen in tissue sections and by immunoblotting. At stages of initial neural crest cell migration, the alpha 1(VI) and alpha 2(VI) chains were immunolocalized in apposition with basement membranes of the neural tube, somites, notochord and ectoderm, whereas no immunoreactivity was seen for the alpha 3(VI) chain. Immunoblotting analysis confirmed the expression of alpha 1(VI) and alpha 2(VI) chains and the lack of detectable immunoreactivity for the alpha 3(VI) chain at these early phases of neural crest development. Conversely, at advanced phases of migration and following gangliogenesis, expression of alpha 3(VI) chain coincided with that of alpha 1(VI) and alpha 2(VI) chains in apposition with basement membranes, around the dorsal root ganglia, and in fibrillar arrangements within the developing dermis and ventral sclerotome. The ability of Col VI to promote neural crest cell attachment and migration was tested in vitro using quantitative assays for these processes. Both native microfilaments and isolated tetramers of Col VI strongly promoted neural crest cell attachment and migration. Optimal stimulation of neural crest cell adhesion and migration was dependent upon structural integrity of Col VI since unfolded and disassembled alpha chains only weakly promoted cell attachment and were virtually inactive in supporting cell movement. The importance of a native macromolecular organization of Col VI further was analyzed in experiments in which dissociated tetramers were reassociated by Ca(2+)- and temperature-dependent self-aggregation. In contrast to native microfilaments, these oligomeric complexes were less effective in promoting neural crest cell movement, but still retained the ability to stimulate maximal cell attachment. The results indicate that Col VI is a primary component of the extracellular matrix deposited along neural crest migratory pathways, where it may participate in the regulation of cell movement by functioning as a migratory substrate. The ability of Col VI to promote neural crest cell adhesion and motility is highly dependent upon maintainance of a native macromolecular arrangement.

Extraction of extendable beaded structures and their identification as fibrillin-containing extracellular matrix microfibrils.

High molecular weight aggregates were extracted from human amnion using buffers containing 6 M guanidine hydrochloride. Rotary shadowed preparations and negatively stained samples examined by electron microscopy showed that each aggregate appeared to be a string of globular structures joined by fine filaments, giving the appearance of beads on a string. The periodicity of the beads was variable. A mouse monoclonal antibody directed against a previously characterized pepsin fragment of fibrillin was used with gold-conjugated secondary antibody and immunoelectron microscopy to show that the aggregates contained fibrillin. Similar structures were found in non-denaturing homogenates of skin, tongue, ligament, ciliary zonule, cartilage, and vitreous humor. When immunogold-labeled beaded structures were prepared for electron microscopy in the same manner as tissue, the beaded structures could no longer be seen. Instead, gold-labeled microfibrils were found which appeared to be the same as the fibrillin-containing matrix microfibrils observed in connective tissues and often associated with elastin. Thus, standard TEM protocols including fixation, dehydration, and embedding alter the ultrastructural appearance of microfibrils as compared with negative stain or rotary shadowing techniques. When skin was stretched and prepared for electron microscopy while still under tension, beaded filaments were seen in the tissue sections, but were not visible in non-stretched controls. In addition, when stretched ligament was immunolabeled with antibody directed against fibrillin while still under tension, the periodicity of antibodies along the microfibrils increased compared with non-stretched controls. We propose that microfibrils contain globular structures connected by fine filaments composed at lease in part of highly ordered, periodically distributed fibrillin molecules, whose periodicity is subject to change dependent on the tensional forces applied to the tissue in which they are contained.

Mosaic structure of globular domains in the human type VI collagen alpha 3 chain: similarity to von Willebrand factor, fibronectin, actin, salivary proteins and aprotinin type protease inhibitors.

Human collagen alpha 3(VI) chain mRNA (approximately 10 kb) was cloned and shown by sequence analysis to encode a 25 residue signal peptide, a large N-terminal globule (1804 residues), a central triple helical segment (336 residues) and a C-terminal globule (803 residues). Some of the sequence was confirmed by Edman degradation of peptides. The N-terminal globular segment consists of nine consecutive 200 residue repeats (N1 to N9) showing internal homology and also significant identity (17-25%) to the A domains of von Willebrand Factor and similar domains present in some other proteins. Deletions were found in the N3 and N9 domains of several cDNA clones suggesting variation of these structures by alternative splicing. The C-terminal globule starts immediately after the triple helical segment with two domains C1 (184 residues) and C2 (248 residues) being similar to the N domains. They are followed by a proline rich, repetitive segment C3 of 122 residues, with similarity to some salivary proteins, and domain C4 (89 residues), which is similar to the type III repeats present in fibronectin and tenascin. The most C-terminal domain C5 (70 residues) shows 40-50% identity to a variety of serine protease inhibitors of the Kunitz type. The whole sequence contains 29 cysteines which are mainly clustered in short segments connecting domains N1, C1, C2 and the triple helix, and in the inhibitor domain. Five putative Arg-Gly-Asp cell-binding sequences are exclusively localized in the triple helical segment.(ABSTRACT TRUNCATED AT 250 WORDS)

Sequence analysis of alpha 1(VI) and alpha 2(VI) chains of human type VI collagen reveals internal triplication of globular domains similar to the A domains of von Willebrand factor and two alpha 2(VI) chain variants that differ in the carboxy terminus.

Amino acid sequences of human collagen alpha 1(VI) and alpha 2(VI) chains were completed by cDNA sequencing and Edman degradation demonstrating that the mature polypeptides contain 1009 and 998 amino acid residues respectively. In addition, they contain small signal peptide sequences. Both chains show 31% identity in the N-terminal (approximately 235 residues) and C-terminal (approximately 430 residues) globular domains which are connected by a triple helical segment (335-336 residues). Internal alignment of the globular sequences indicates a repetitive 200-residue structure (15-23% identity) occurring three times (N1, C1, C2) in each chain. These repeating subdomains are connected to each other and to the triple helix by short (15-30 residues) cysteine-rich segments. The globular domains possess several N-glycosylation sites but no cell-binding RGD sequences, which are exclusively found in the triple helical segment. Sequencing of alpha 2(VI) cDNA clones revealed two variant chains with a distinct C2 subdomain and 3' non-coding region. The repetitive segments C1, C2 and, to a lesser extent, N1 show significant identity (15-18%) to the collagen-binding A domains of von Willebrand factor (vWF) and they are also similar to some integrin receptors, complement components and a cartilage matrix protein. Since the globular domains of collagen VI come into close contact with triple helical segments during the formation of tissue microfibrils it suggests that the globular domains bind to collagenous structures in a manner similar to the binding of vWF to collagen I.

Orientation of type VI collagen monomers in molecular aggregates.

Type VI collagen, prepared from guanidine extracts of human amnion, contains very little monomeric material, the major forms being dimers and tetramers. In order to study the orientation of the molecules in these aggregates, they were digested with pepsin followed by bacterial collagenase. Two fragments were isolated, one containing part of the inner globular domain still attached to part of the triple helix and the other containing large fragments of the outer globular domain. Each fraction was further analyzed; peptides were isolated and their amino-terminal amino acid sequences determined. By comparing the determined sequences with published data, it was found that the outer globular domain contained sequences derived from the amino-terminal domain of all three chains of type VI collagen whereas the inner globular domain contained sequences from the carboxy-terminal domain. This provided direct chemical evidence that dimers and tetramers of type VI collagen are formed by overlapping carboxy-terminal regions of the monomers.

Anchoring fibrils contain the carboxyl-terminal globular domain of type VII procollagen, but lack the amino-terminal globular domain.

Type VII procollagen has been characterized as a product of epithelial cell lines. As secreted, it contains a large triple-helical domain terminated by a multi-globular-domained carboxyl terminus (NC-1), and a smaller amino-terminal globule (NC-2). The triple helix and the NC-1 domain have previously been identified in anchoring fibril-containing tissues by biochemical and immunochemical means, leading to the conclusion that type VII collagen is a major component of anchoring fibrils. In order to better characterize the tissue form of type VII collagen, we have produced a panel of monoclonal antibodies which recognize the NC-1 domain. Peptide mapping of these epitopes indicate that they are independent and span approximately 125,000 kDa of the total 150,000 kDa of each alpha chain contained in NC-1. All these antibodies elicit immunofluorescent staining of the basement membrane zone in tissues. Type VII collagen has been extracted from tissues. As previously reported, it is smaller than type VII procollagen, (Woodley, D. T., Burgeson, R. E., Lunstrum, G. P., Bruckner-Tuderman, L., and Briggaman, R. A., submitted for publication), and we now find that it predominantly occurs as a dimer. Following clostridial collagenase digestion, intact NC-1 has been recognized, indicating that the difference in apparent Mr between the tissue form of the molecule and type VII procollagen results from modification of the amino terminus. The size of the amino-terminal globule has been determined to be between approximately 96 and 102 kDa. Rotary shadowing analyses of extracted molecules indicate that dimeric molecules contain the NC-1 domain, but are missing intact NC-2. We propose that the tissue form monomer, Mr = 960,000, be referred to as "type VII collagen." These studies strongly suggest that anchoring fibrils contain dimeric molecules with intact NC-1 domains. The data also support the previous suggestion that the NC-2 domain is involved in the formation of disulfide bond-stabilized type VII collagen dimers, and is subsequently removed by physiological proteolytic processing.

Factors affecting the activation of rabbit muscle phosphofructokinase by actin.

The consistent application of phosphatase inhibitors and a novel final purification step using a connected series of DE-51, DE-52, and DE-53 anion-exchange chromatography columns facilitate the preparation of electrophoretically homogeneous subpopulations of rabbit muscle phosphofructokinase which differ in their catalytic properties and endogenous covalent phosphate content. A band of "high"-phosphate enzyme (fraction II) flanked by regions of "low"-phosphate enzyme (fractions I and III) is an unusual feature of the final purification profile. Fractions I (containing in this case 0.42 mol of P/82 000 g of enzyme) and II (containing 1.26 mol of P/82 000 g of enzyme) exhibit the most pronounced functional differences of the fractions. Following our original report [Liou, R.-S., & Anderson, S. R. (1980) Biochemistry 19, 2684], both are activated by the addition of rabbit skeletal muscle F-actin. Under the assay conditions, half-maximal stimulation of phosphofructokinase activity occurs at 15.4 nM actin (in terms of monomer) for fraction I and 9.7 nM for fraction II. The low-phosphate enzyme is synergistically activated in the presence of 0.12 microM actin plus 3.0 microM fructose 2,6-bisphosphate, with a marked increase in Vmax, while the high-phosphate enzyme is not. Neither fraction is activated appreciably by the addition of G-actin or the chymotrypsin-resistant actin "core". The covalently cross-linked trimer of actin stimulates the activity of both the low- and high-phosphate enzyme fractions. However, the previously mentioned synergistic activation characteristic of fraction I fails to occur in solutions containing the trimer plus fructose 2,6-bisphosphate. Phosphorylation of fraction I in an in vitro reaction catalyzed by the cAMP-dependent protein kinase causes its properties to become more like those of fraction II. The total amount of covalent phosphate present after in vitro phosphorylation approaches 2 mol of P/82 000 g of enzyme for both fractions.