The nature of the microfibrillar glycoproteins of elastic fibres. A biosynthetic study

Fell-Muir Lecture: Fibrillin microfibrils: structural tensometers of elastic tissues?

Fibrillin microfibrils are indispensable structural elements of connective tissues in multicellular organisms from early metazoans to humans. They have an extensible periodic beaded organization, and support dynamic tissues such as ciliary zonules that suspend the lens. In tissues that express elastin, including blood vessels, skin and lungs, microfibrils support elastin deposition and shape the functional architecture of elastic fibres. The vital contribution of microfibrils to tissue form and function is underscored by the heritable fibrillinopathies, especially Marfan syndrome with severe elastic, ocular and skeletal tissue defects. Research since the early 1990s has advanced our knowledge of biology of microfibrils, yet understanding of their mechanical and homeostatic contributions to tissues remains far from complete. This review is a personal reflection on key insights, and puts forward the conceptual hypothesis that microfibrils are structural 'tensometers' that direct cells to monitor and respond to altered tissue mechanics.

Microfibrils from the arterial subendothelium

Microfibrillar structures of the subendothelium are represented by either type VI collagen or elastin-associated microfibrils which are also referred to as fibrillin-containing microfibrils. These structures are present throughout the subendothelium irrespective of the presence of elastin. The localization, structure, and protein composition of microfibrils are reviewed. The arterial subendothelium is thrombogenic despite its very low content in fibrillar collagens. This thrombogenicity is linked to the microfibrillar structures, essentially to type VI collagen and to thrombospondin-containing microfibrils. Their respective ability to bind the von Willebrand factor and to activate blood platelets is discussed.

Microfibrillar elements of the dermal matrix

Connective tissue microfibrils are key structural elements of the dermal matrix which play major roles in establishing and maintaining the structural and mechanical integrity of this complex tissue. Type VI collagen microfibrils form extensive microfibrillar networks which intercalate between the major collagen fibrils and are juxtaposed to cellular basement membranes, blood vessels and other interstitial structures. Fibrillin microfibrils define the continuous elastic network of skin, and are present in dermis as microfibril bundles devoid of measureable elastin extending from the dermal-epithelial junction and as components of the thick elastic fibres present in the deep reticular dermis. Electron microscopic analyses have revealed both classes of microfibrils to have complex ultrastructures. The ability to isolate intact native microfibrils from skin has enabled a combination of high resolution and biochemical techniques to be applied to elucidate their structure:function relationships. These approaches have generated new information about their molecular organisation and physiological interactions in health and disease.

Fibrillin-containing microfibrils: structure and function in health and disease

Fibrillin-containing microfibrils are a unique class of connective tissue macromolecules whose critical contribution to the establishment and maintenance of diverse extracellular matrices was underlined by the recent linkage of their principal structural component fibrillin to Marfan syndrome, a heritable disorder with pleiotrophic connective tissue manifestations. The complexity of the structure: function relationships of these macromolecules was highlighted by the recent elucidation of the primary structure of fibrillin and characterisation of fibrillin mutations in Marfan patients. This review examines current understanding of the expression and assembly of fibrillin and describes new approaches which are now being applied to elucidate the many outstanding structural, organisational and functional aspects of the fibrillin-containing microfibrils.

Determination of free and total proline and hydroxyproline in plasma and tissue samples by gas chromatography with flame photometric detection

A selective and sensitive method for the determination of free and total proline (Pro) and 4-hydroxyproline (Hyp) by gas chromatography (GC) was developed. For free Pro and Hyp analysis, plasma and tissue homogenate were extracted with methanol. For total Pro and Hyp analysis, these samples were hydrolysed in 6 M HCl. After removal of primary amino compounds by the reaction with o-phthaldialdehyde, Pro and Hyp in methanol extract and acid hydrolysate were converted into their N-dimethylthiophosphoryl methyl ester derivatives and then determined by GC with flame photometric detection using a DB-5 capillary column. This method was successfully applied to small samples without prior clean-up, and Pro and Hyp in these samples could be analysed without any influence from coexisting substances. Overall recoveries of Pro and Hyp added to plasma and tissue samples were 92-106%. The analytical results of free and total Pro and Hyp in human plasma and mouse tissue samples are presented.

The elastic system fibres in healthy human gingiva

In human gingiva, the elastic system fibres, namely oxytalan, elaunin and elastic fibres, are distributed in the upper, medium and deep layers of gingival connective tissue, respectively. They are formed by a microfibrillar and an amorphous component characterized as elastin. In the gingival connective tissue fibroblastic cells are likely to be the main source of production of elastin in the extracellular matrix. Elastin is secreted as a soluble precursor (tropoelastin), which spontaneously forms insoluble aggregates of elastin. Elastin is then laid down at the surface of the microfibrillar component, which could serve as a site for deposition of elastin during elastogenesis, and subsequently be incorporated in an amorphous area to form elaunin and elastic fibres.

Tumor cell interactions with elastin: implications for pulmonary metastasis

Elastin surrounds microvessels in the pulmonary circulation and may pose a barrier to the extravasation of metastatic tumor cells. We find that lung-colonizing murine melanoma cells produce an enzymatic activity that degrades elastin. In addition, the elastin fragments liberated by enzymatic digestion of insoluble elastin stimulate tumor cell chemotaxis. Chemotactic activity is associated with other forms of soluble elastin, including alpha-elastin and tropoelastin. Val-Gly-Val-Ala-Pro-Gly, a synthetic peptide that is a repeat sequence in the elastin molecule, also displayed tumor cell chemotactic activity. The ability to degrade elastin and to migrate in response to soluble elastin peptides is not a property of all tumor cells, but it is most commonly found associated with metastatic tumor cells that colonize pulmonary tissue. We postulate that the ability to migrate in response to elastin fragments may facilitate tumor cell invasion of elastin-rich pulmonary tissue.

The distribution of elastin in developing and adult rat organs using immunocytochemical techniques

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Heterogeneity of elastin expression in cutis laxa fibroblast strains

Cutis laxa is a genetically heterogeneous connective tissue disease that occurs in both inherited and acquired forms. The most apparent defect is loose, redundant, nonresilient skin, but systemic connective tissue abnormalities exist, especially in conjunction with the early onset or autosomal recessive variety. The elastic fiber shows morphologic alterations. We studied dermal skin biopsies and cultured skin fibroblasts from 6 patients with congenital forms of cutis laxa in an effort to correlate alterations in elastin morphology and metabolism. In general, ultrastructural analysis revealed occasional variance in collagen fiber diameter, whereas elastic tissue varied in content, appearance, and the proportion and manner by which elastin and microfibrillar component associated. Fibroblast cell lines comprised of normal donors from a similar age group produced an average of 35 +/- 10 X 10(3) tropoelastin molecular equivalents per cell per hour, as measured by an ELISA. Three of six cutis laxa cell strains were markedly (5-20-fold) reduced in tropoelastin production. Two of these cell strains had specifically reduced levels of tropoelastin production relative to total protein synthesis. Analysis of elastin specific messenger RNA levels indicated this reduced expression of tropoelastin was regulated at a pretranslational level. In other strains, diminished production of elastin did not appear to be the primary defect, underscoring the heterogeneous nature of cutis laxa at both the biochemical and ultrastructural levels.

Tissue amyloid P component in normal human dermis is non-covalently associated with elastic fiber microfibrils

Tissue amyloid P component (TAP), a protein that crossreacts immunohistochemically with the normal plasma glycoprotein serum amyloid P component (SAP), is invariably associated with elastic fiber microfibrils in adult humans. We have investigated the nature of this association. Aliquots of minced, homogenized dermis, obtained following ethylenediamine tetraacetic acid (EDTA) separation of whole adult human skin, were extracted with different reagents, and the presence or absence of TAP in the pellet and in the supernatant following centrifugation was determined by SDS-PAGE and immunoblotting using anti-SAP antibodies. TAP was extractable from dermis using reagents which disrupt non-covalent bonds, including sodium dodecyl sulfate (SDS) and guanidine hydrochloride. TAP was not extracted by high molarity salt solutions, non-ionic detergents, or the reducing agents dithiothreitol and 2-mercaptoethanol. EDTA solution was similarly unsuccessful at eluting TAP from the dermal preparation, indicating that the association of TAP with elastic fiber microfibrils is not simply the result of Ca++-dependent binding. Collagenase solubilized some TAP, but this does not prove covalent linkage to elastic tissue of part of the TAP, because the apparent Mr of TAP extracted was identical to that of normal SAP subunits. We cannot completely exclude the possibility that a few subunits in each multimeric TAP molecule are covalently attached to the microfibrils. However, our findings that denaturing agents alone extracted most of the TAP from normal human dermis strongly suggest that the great majority of the dermal TAP is non-covalently bound to elastic fiber microfibrils. Thus TAP is not an integral constitutent of elastic fiber microfibrils.

Three-dimensional organization of the extracellular matrix secreted by cultured rat smooth muscle cells

Specific interactions between cells and the extracellular matrix (ECM) in which they are embedded play a vital role in tissue organization. In recent years, many of the individual components of the extracellular matrix have been isolated and their molecular structures elucidated, but the detailed topography of most extracellular matrices, as they are deposited by cells, is still largely unknown. In this study, the insoluble extracellular matrix produced by cultured rat vascular smooth muscle cells has been characterized morphologically using high-resolution electron microscopy of rotary platinum replicas. These cells grew as flat sheets in culture, secreting their matrix laterally and basally. The matrix was composed of a cross-linked fibrillar meshwork. Some fine fibers (10 to 15 nm in diameter) were naked, but most of the filamentous mesh was covered with coarse granular material. Limited digestion with trypsin or pancreatic elastase removed most of this coating, indicating that the granules were glycoproteins and proteoglycans. Another subset of matrix fibrils (20 to 40 nm in diameter) was identified as type I collagen by direct comparison with purified bovine skin collagen. In addition to exposing the underlying filamentous substructure of the matrix, protease treatment also revealed large, straight fiber bundles and globules of amorphous material suspended in the filamentous web. This novel view of a complex matrix promises to provide spatial information that will be useful in future studies of cell interactions with the ECM.

Fibrillin, a new 350-kD glycoprotein, is a component of extracellular microfibrils

A new connective tissue protein, which we call fibrillin, has been isolated from the medium of human fibroblast cell cultures. Electrophoresis of the disulfide bond-reduced protein gave a single band with an estimated molecular mass of 350,000 D. This 350-kD protein appeared to possess intrachain disulfide bonds. It could be stained with periodic acid-Schiff reagent, and after metabolic labeling, it contained [3H]glucosamine. It could not be labeled with [35S]sulfate. It was resistant to digestion by bacterial collagenase. Using mAbs specific for fibrillin, we demonstrated its widespread distribution in the connective tissue matrices of skin, lung, kidney, vasculature, cartilage, tendon, muscle, cornea, and ciliary zonule. Electron microscopic immunolocalization with colloidal gold conjugates specified its location to a class of extracellular structural elements described as microfibrils. These microfibrils possessed a characteristic appearance and averaged 10 nm in diameter. Microfibrils around the amorphous cores of the elastic fiber system as well as bundles of microfibrils without elastin cores were labeled equally well with antibody. Immunolocalization suggested that fibrillin is arrayed periodically along the individual microfibril and that individual microfibrils may be aligned within bundles. The periodicity of the epitope appeared to match the interstitial collagen band periodicity. In contrast, type VI collagen, which has been proposed as a possible microfibrillar component, was immunolocalized with a specific mAb to small diameter microfilaments that interweave among the large, banded collagen fibers; it was not associated with the system of microfibrils identified by the presence of fibrillin.

HB8: a monoclonal antibody recognizing elastic fibre microfibrils

We report an ultrastructural study of the reactivity of an IgG monoclonal antibody, which reacts with human dermal elastic fibres. On electron microscopy, immunogold labelling demonstrated the reactivity of HB8 with the microfibrillar component of the fibres. In contrast, the electron-dense granular component which contains elastin was unlabelled with HB8. A fine network of microfibrils from the level of the oxytalan fibres to the large elastic fibres of the deep dermis was labelled with gold particles. No reactivity was detected on collagen fibres. These results demonstrate that HB8 reacts with the microfibrillar glycoproteins of the elastic fibres in normal skin. The precise biochemical nature of the antigens identified by HB8 is still unknown.

Type VI collagen and glycoprotein MFPI are distinct components of the extracellular matrix

Two collagenous glycoproteins, Mr 140,000 and Mr 150,000, are synthesized and secreted into the medium of cultured fibroblasts. The glycoprotein of Mr 140,000 is identical with the 140K(VI) component of type VI collagen by both immunological and physicochemical criteria. The glycoprotein of Mr 150,000 is immunologically distinct and exhibits the physicochemical characteristics of the putative elastic microfibrillar glycoprotein MFPI.

Immunolocalization of a 35K structural glycoprotein to elastin-associated microfibrils

In this study, a rabbit antiserum directed against a 35K glycoprotein (35K-GP), extracted from connective tissue, was used to examine the localisation of this antigen within foetal bovine ligamentum nuchae at stages of development preceding (4th month) and coinciding with (7th month) active elastin biosynthesis. In these tissues the antibody, detected by a colloidal gold conjugate technique, localised specifically to 11-nm fibrils, identified as the microfibrillar component, present both in the form of independent bundles and in association with elastin in the developing elastic fibres. No other connective tissue component was recognised by the antibodies which had been purified by affinity chromatography. The ability of the antibodies to bind to the microfibrils appeared to be dependent on embedding in LR White resin, as colloidal gold binding was greatly reduced in tissue embedded in epoxy resin. These results are discussed with respect to the role that 35K-GP may play in the morphogenesis of the elastic fibre.

Structure and macromolecular organization of type VI collagen

Collagen VI is a large, disulfide-bonded protein complex which is widely distributed in connective tissue. The constituent polypeptide chains (Mr = 110,000-140,000) consist of collagenous and noncollagenous segments, are degraded to chains of about half the size when collagen VI is solubilized by pepsin, and assemble to a unique pattern of oligomers. As revealed by electron microscopy, the triple-stranded protomer consists of a triple helix 105 nm in length flanked on each side by globular domains of similar size (diameter about 7 nm). Protomers are assembled to dimers by an antiparallel staggered alignment of triple-helical segments. This leads to inner regions, 75 nm in length, of two slightly supercoiled triple helices flanked by globular domains. At both sides 30-nm-long outer triple-helical segments emerge that are terminated by globules. Tetramers are formed from laterally aligned dimers that cross with their outer triple-helical segments in a scissors-like fashion. The same structures, except with much smaller globular domains, are found in pepsin-treated collagen VI. Disulfide-linked collagen VI produced by cultured fibroblasts has a size similar to that of genuine collagen VI found in tissue extracts. Larger forms of collagen VI are assembled from tetramers by end-to-end aggregation which because of an overlap of the outer segments brings all globular domains close together. This arrangement predicts microfibrillar structures in tissues with a periodicity of 100-110 nm and a diameter of 5-10 nm. Structures consistent with this proposal were indeed found by immunoelectron microscopy of placenta and aorta using the ferritin technique. Large, lateral aggregates of collagen VI microfibrils may in addition exist in cell cultures and tissues ("zebra collagen," "Luse bodies") and are presumably maintained by contacts between globular domains.

Isolation from bovine elastic tissues of collagen type VI and characterization of its form in vivo

Foetal-bovine nuchal ligament and aorta, together with adult-bovine aorta and pregnant uterus, were extracted under dissociative conditions in the absence and in the presence of a reducing agent. A collagenous glycoprotein of Mr 140000 [designated component 140K(VI)], identified in these extracts as the major periodate/Schiff-positive component, was shown to be related to collagen type VI. Digestion of non-reduced extracts with pepsin yielded periodate/Schiff-positive peptides that, on the basis of their electrophoretic mobilities, amino acid analyses and peptide 'maps', were identical with type VI collagen fragments prepared by standard procedures. It is concluded that collagen type VI occurs in vivo as molecule comprising three chains of Mr 140000 in which the helical domains account for about one-third of each polypeptide. Biosynthetic experiments with nuchal-ligament fibroblasts in culture demonstrated that a bacterial-collagenase-sensitive [3H]fucose-labelled glycoprotein, Mr 140000, was immunoprecipitated from culture medium by a specific antibody to the pepsin-derived form of collagen type VI. This result suggests that the collagenous polypeptides [140K(VI) components] represent the biosynthetic precursors of type VI collagen that do not undergo processing to smaller species before deposition in the extracellular matrix. Analyses of 5M-guanidinium chloride extracts of tissues with markedly different elastin contents and at different stages of development suggested that there was no relationship between collagen type VI and elastic-fibre microfibrils, a conclusion supported by the observation that the immunoprecipitated glycoprotein, Mr 140000, was distinct from the glycoprotein MFPI, Mr 150000, believed to be a constituent of these microfibrils [Sear, Grant & Jackson (1981) Biochem. J. 194, 587-598].

Radioimmunoassay for human type VI collagen and its application to tissue and body fluids

A liquid phase radioimmunoassay (RIA) was developed for pepsin-solubilized human type VI collagen, allowing quantitative analysis of this protein down to a concentration of 3 ng/ml. No cross-reactivity was observed with human collagens type I, III, IV (triple helical portion and 7-S domain), and V, nor with laminin fragment Pl and plasma fibronectin. Significant amounts of closely related antigenic material were detected in serum, bile, ascites, and mesenchymal cell culture media. Type VI collagen could be completely solubilized from several tissues by a repeated pepsin digest, and its content as determined by RIA was found to be less than 0.1% of total collagen (55-70 micrograms/g protein). In fibrotic liver tissue type VI collagen was elevated up to 10-fold (620 micrograms/g protein) when compared to normal liver. Sera of patients with fibrotic liver disease, however, revealed antigen levels usually below the narrow normal range of 22 +/- 7.8 ng/ml (mean +/- 2.5 SD). We conclude that, although type VI collagen represents a minor fraction of the interstitial collagens, its comparatively high serum levels point to a considerable turnover in the normal individual. Our data suggest that in fibrosis as exemplified in fibrotic liver disease, the metabolism of this collagen is down-regulated, while at the same time, it accumulates in the interstitial matrix.

Characterization of a type VI collagen-related Mr-140 000 protein from cutis-laxa fibroblasts in culture

The precise biochemical defects in connective-tissue metabolism that are responsible for the laxity of skin seen in the syndrome of cutis laxa are largely unknown. We have studied fibroblasts cultured from skin explants of a 2-year-old male with the syndrome. Electron-microscopic examination of this skin revealed decreased amounts of amorphous elastin and an increase in elastin-associated microfibrils. Although the cultured fibroblasts were similar to control skin fibroblasts in morphology, growth rate and total protein synthesis, there was a 4-6-fold increase in accumulation of a collagenous protein of Mr 140 000 in both the culture medium and in the cell layer. This protein was structurally distinct from collagen types I, III, IV, V and VIII. It was found to be related to a cell-surface-associated glycoprotein, GP140, by both antigenic cross-reactivity and peptide mapping. Our data support observations that GP140 is a precursor of at least one form of pepsin-extracted type VI collagen.

Size and domain structure of collagen VI produced by cultured fibroblasts

Disulfide-bonded forms of collagen VI were analyzed by immunoblotting of fibroblast culture medium and cell extracts. The protein consists of pepsin and collagenase-resistant domains of about equal size indicating a molecular mass of 340 kDa for collagen VI monomers.

Beaded filaments and long-spacing fibrils: relation to type VI collagen

"Beaded filaments" have been found in fibroblast cultures prepared from chicken embryo leg tendons and cornea and from the dermis of human skin. With negative staining, they appear as single, unbranched, flexible strands approximately 3 nm in width and up to at least 2 microns in length. Pairs of "beads" are distributed on the filament at regular intervals of 110 nm. The beaded filaments appear to be resistant to the action of trypsin and bacterial collagenase. The filaments also occur in bundles with beads laterally aligned to form long-spacing-type fibrils, which appear to be identical with many fibrous-long-spacing-type fibrils described, but not identified, by others in a variety of normal and pathological tissues. The long-spacing fibrils are numerous at several sites of active collagen fibrillogenesis. Comparison of the beaded filament structure with molecular models for various collagens described in the literature suggests that they are a filamentous form of type VI collagen.

Immunochemistry, genuine size and tissue localization of collagen VI

Collagen VI was solubilized with pepsin from human placenta and used for preparing rabbit antisera. Major antigenic determinants were located in the central region of the antigen including triple-helical and globular structures. Antisera prepared against a constituent-chain showed preferential reactions with unfolded structures. Antibodies were purified by affinity chromatography and failed to cross-react with other collagen types I-V and with fibronectin. These antibodies demonstrated intracellular and extracellular collagen VI in fibroblast and smooth muscle cell cultures. Immunoblotting identified a disulfide-bonded constituent chain about twice as large as those of the pepsin fragments in both cell cultures and tissue extracts. Rotary shadowing electron microscopy indicated that the increase in mass is due to larger globular domains present at both ends of collagen VI monomers. Indirect immunofluorescence demonstrated a wide occurrence of collagen VI in connective tissue particularly of large vessels, kidney, skin, liver and muscle. Collagen VI is apparently not a typical constituent of cartilage or of basement membranes. Ultrastructural studies using the immunoferritin technique showed collagen VI along thin filaments or in amorphous regions of aortic media or placenta but not in association with thick, cross-striated collagen fibrils or elastin. This supports previous suggestions that collagen VI is a constituent of microfibrillar structures of the body.

A collagenous glycoprotein found in dissociative extracts of foetal bovine nuchal ligament. Evidence for a relationship with type VI collagen

A collagenous glycoprotein (Mr 140000) was isolated from dissociative extracts of foetal bovine nuchal ligament and purified by a combination of ion-exchange and gel-filtration chromatography. This glycoprotein (designated MFPI) exists as a large-Mr disulphide-bonded aggregate in the absence of a reducing agent. The purified glycoprotein was shown to contain about 6% (w/w) carbohydrate, mostly as galactose, glucose and mannose. Amino acid analysis showed the presence of hydroxyproline and hydroxylysine, indicative of its collagenous nature. The collagenous nature of this glycoprotein was further investigated by enzyme digestion. Pepsin digestion produced three major fragments, which were identical with peptides of type VI collagen. Bacterial-collagenase digestion of the unreduced glycoprotein also produced several discrete peptides. However, reduction of the glycoprotein before bacterial-collagenase digestion resulted in the degradation of these discrete peptides. Glycoprotein MFPI extracted in dissociative conditions appears to be a larger-Mr form of type VI collagen, believed to originate from microfibrillar components in the intact tissue.

Collagen heterogeneity and quantification in developing bovine nuchal ligament

The collagenous components were investigated in peptic digests of developing bovine nuchal ligament. Types I and III collagen were the major species isolated, but the presence of types IV, V and VI was also shown. Changes in the pepsin-susceptibility of nuchal ligament during foetal development were observed. CNBr-cleavage peptide analysis indicated that type I collagen became cross-linked rapidly, as evidenced by the lack of alpha 1(I)CB6. At present it is not clear if this decrease in pepsin-susceptibility is due to cross-linking of collagen, to increased deposition of elastin, or to both. Quantification of collagen types I and III was shown to depend on the method used. When pepsin-solubilized material was examined an apparent increase in type III collagen with respect to foetal age was observed, whereas when CNBr digests of intact ligament were examined a relatively constant amount of type III collagen (approx. 24%) was found. The constant amount of type III collagen observed during foetal development changed at birth and increased in mature nuchal ligament to represent approx. 45% of the total collagen.

Fetal calf ligament fibroblasts in culture secrete a low molecular weight collagen with a unique resistance to proteolytic degradation

A highly unusual collagen was secreted by fibroblasts cultured from 150- and 270-d-old fetal calf nuchal ligaments. Purification revealed that this protein (which may be synthesized in a higher molecular weight form) was precipitated at unusually high concentrations of ammonium sulfate and was also eluted from DEAE-cellulose at greater salt concentrations than were types I and III procollagens. On SDS PAGE, the collagenous protein exhibited an Mr of approximately 12,750 that was not altered in the presence of reducing agent. The low molecular weight collagen (FCL-1) was sensitive to bacterial collagenase and had a [3H]glycine content comparable to that found in type I procollagen, although the [3H]Hyp to [3H]Pro ratio was 0.43. FCL-1 was not cleaved by human skin collagenase, mast cell protease, trypsin, Staphylococcal V8 protease, or proteinase K at 37 degrees C. The collagen was susceptible to trypsin, but not to V8 protease, only after heating at 80 degrees C for 30 min. Preliminary structural studies indicate that FCL-1 was resistant to cleavage by CNBr but exhibited limited proteolysis with pepsin. Both 150- and 270-d-old fibroblasts produced comparable levels of interstitial (types I and III) procollagens, which comprised approximately 70% of the total protein secreted into the culture medium. However, 270-d-old (term) fibroblasts secreted approximately 50% more FCL-1, as percent of total culture medium protein, in comparison to the cells from the earlier gestational stage. This collagen may therefore play a role in the development of the nuchal ligament.

Ultrastructure of Reichert's membrane, a multilayered basement membrane in the parietal wall of the rat yolk sac

The ultrastructure of Reichert's membrane, a thick basement membrane in the parietal wall of the yolk sac, has been examined in 13-14-d pregnant rats. This membrane is composed of more or less distinct parallel layers, each one of which resembles a common basement membrane. After routine fixation in glutaraldehyde followed by osmium tetroxide, the layers appear to be mainly composed of 3-8-nm thick cords arranged in a three-dimensional network. Loosely scattered among the cords are unbranched, straight tubular structures with a diameter of 7-10 nm, which mainly run parallel to the surface and to one another; they are referred to as basotubules. Permanganate fixation emphasizes the presence of a thick feltwork of irregular material around basotubules. Finally, minute dot-like structures measuring 3.5 nm and referred to as double pegs are present within the meshes of the cord network. Reichert's membranes have been treated for 2-48 h at 25 degrees C with plasmin, a proteolytic enzyme known to rapidly digest laminin and fibronectin. After a 2-h treatment, most of the substance of the cords is digested away leaving a three-dimensional network of 1.5-2.0-nm thick filaments. The interpretation is that the cords are formed of a plasmin-resistant core filament and a plasmin-extractable sheath. When plasmin treatment is prolonged for 15 h or longer, the filaments are dissociated and disappear, while basotubules are maintained. Plasmin digestion also reveals that basotubules are composed of two parts: a ribbon-like helical wrapping and tubule proper. Further changes in the tubule under plasmin influence are interpreted as a dissociation into pentagonal units suggestive of the presence of the amyloid P component. After 48 h of plasmin treatment, basotubules are further disaggregated and dispersed, leaving only linearly arranged double pegs. Reichert's membranes with or without a 2-hr plasmin treatment have been immunostained by exposure to antibodies against either laminin or type IV collagen with the help of peroxidase markers. The results indicate that the sheath of the cords contains laminin antigenicity, while the core filament contains type IV collagen antigenicity. It is proposed that Reichert's membrane consists mainly of a three-dimensional network of cords composed of a type IV collagen filament enclosed within a laminin-containing sheath. Also present are basotubules--which may contain the amyloid P component--and double pegs whose nature is unknown.

Elastic fibres of the human ductus deferens

The distribution of elastic fibres in the human ductus deferens from birth to senility was studied by light and electron microscopy. Elastic fibres are lacking in the ductus deferens in infants and children. In the adult ductus deferens, they form two layers in the lamina propria: (1) an inner layer of circumferentially oriented elastic fibres, and (2) an outer meshwork of elastic fibres. Elastic fibres are also present in the narrow intercellular spaces between the smooth muscle cells of the muscular coat, mainly in the inner muscular layer. A layer of elastic fibres surrounds the muscular coat. The ductus deferens of ageing subjects shows fragmentation and disorganisation of the elastic fibre layers of the lamina propria. Elastic fibres in the muscular coat are more abundant than in younger adults, forming larger bundles. Electron microscopy demonstrated the presence of immature elastic fibres at puberty as collections of microfibrils, some of them containing loci of amorphous substance (elastin). In the adult ductus most elastic fibres have a mature appearance. The amount of amorphous substance has increased and the number of microfibrils has decreased. Electron-dense inclusions are present within the amorphous substance. With advancing age the amorphous substance forms large, structureless masses showing abundant electron-dense inclusions and areas of rarefaction. A thin layer of microfibrils is present only at the periphery of the elastic fibres. Whether or not androgenic hormones are in any way involved in the formation of elastic fibres in the ductus deferens and testis is something which requires further study.

What is collagen, what is not

Collagen represents a series of proteins that are broadly related in terms of chemical features, structure, and function. This presentation focuses on current information relevant to the function, chemistry, and structure of collagen in order to more precisely define the parameters within which a protein may be recognized as collagen. It is noted that ultrastructural investigation of collagen based on transmission and scanning electron microscopy alone is of limited value, but that chemical analyses of tissue specimens and the use of immunohistochemical techniques are essential in evaluating collagenous proteins in normal and pathologic tissues. In addition to the specific types of collagen (I-VI), the role of collagen in the biology and pathophysiology of connective tissue is discussed.

Electron-microscopical approach to a structural model of intima collagen

Intima collagen was studied by electron microscopy (rotary shadowing and negative staining) and by analytical ultracentrifugation. It was found that the monomeric unit (Mr 170 000) consists of a 105 nm-long triple helix terminated by a small globular domain (Mr about 30 000) at one end and a large globular domain (Mr about 40 000) at the other end. The monomer was produced by selective reduction of interchain disulphide bridges. Before reduction, dimers, tetramers and larger filamentous structures were found. Dimers are lateral staggered aggregates of two monomers aligned in an anti-parallel fashion. This gives rise to an inner 75 nm-long region of two slightly intertwisted triple helices flanked by the large globular domains. The outer triple-helical segments (length 30 nm) with the small globular domains at their ends emerge at both sides of this structure. Interchain disulphide bridges are probably located in the vicinity of the large domains. Only the outer segments could be degraded by bacterial collagenase. In tetramers the outer segments of two dimers are covalently linked, forming a scissors-like structure. In the fibrous forms several tetramers are assembled end-to-end with an overlap between the outer segments. The molecular masses and sedimentation coefficients were calculated for these various forms from the electron-microscopically observed dimensions and agreed with results obtained by ultracentrifugation. The unique structure of intima collagen suggests that it originates from a microfibrillar component and that it can be considered a unique collagenous protein, for which we propose the designation type VI collagen.

Structural glycoproteins from rabbit aortic media

Rabbit aortic intima-media fragments were incubated with [14C]mannose and [3H]fucose for 6 h to detect glycoproteins synthesized in situ. The radioactively labelled and the non-labelled samples were extracted with 0.2 mM-CaCl2/0.5 mM-dithiothreitol/0.5 mM-ATP and chloroform/methanol/water (4:4:1, by vol.). The delipidated residue was extracted with 5 M-guanidinium chloride/0.05 M-dithiothreitol/0.1 M-Tris/0.4% Na2EDTA, pH 7.5, before (extract 1) and after hydrolysis with collagenase (extract 2). The proteins in extracts 1 and 2 were S-carboxamidomethylated and separated by molecular-sieve chromatography, polyacrylamide-gel electrophoresis and isoelectric focusing in sucrose gradients in urea. The apparent molecular weights of glycoproteins were 36 000 (glycoprotein I) from extract 1, 50 000 (glycoprotein II) and 130 000 (glycoprotein III) from extract 2. The molecular weights of the non-labelled and radioactively labelled glycoproteins were identical. Glycoproteins I, II and III contain large amounts of polar amino acids and methionine. They contain neither hydroxyproline nor 3-methylhistidine. A hydroxyproline-containing component of 160 000-apparent-mol.wt. relatively rich in polar amino acids and labelled with incorporated sugars was isolated from extract 1. The incorporation in vitro of radioactive sugars into glycoproteins I, II, III and collagenous glycoproteins indicates that they are synthesized in the surviving aorta by the smooth-muscle cells.