Development of elastic fibers of nuchal ligament, aorta, and lung of fetal and postnatal sheep: an ultrastructural and electron microscopic immunohistochemical study

The morphogenesis of elastic fibers of the nuchal ligament, aorta, and lung of sheep was studied by light microscopy, transmission electron microscopy, and immunohistochemical methods for the detection of elastin. The degree of maturation of the amorphous materials of elastic fibers was assessed morphologically in preparations stained by the tannic acid and periodic acid methenamine-silver methods. With both of these methods, the amorphous components of mature fibers stained less intensely than did those of immature fibers. Elastic fibers in early stages of development consisted of many microfibrils and few, small, branching masses of immature amorphous material. Thicker fibers were formed by the coalescence of growing masses of amorphous materials. In late stages of formation of elastic fibers, the mature amorphous materials were associated with few microfibrils; and they were partially surrounded by immature amorphous materials associated with many microfibrils. Antielastin antibody reacted evenly with amorphous materials in very early stages of elastic-fiber development, but reacted only with the other zones of amorphous materials in later stages; it also reacted with the microfibrils in all stages. These findings were interpreted as indicating that the microfibrils were associated with small amounts of elastin on their surfaces. This conclusion is in agreement with ultrastructural observations showing 1) that development of microfibrils precedes that of the amorphous material and 2) that the microfibrils adjacent to the immature amorphous materials are covered with small amounts of tannic acid-positive amorphous materials. These observations suggest that microfibrils serve as sites for elastin deposition, both in early elastogenesis and in subsequent growth of elastic fibers. However, the nature of the interaction between elastin and microfibrils remains unknown.     

The infrastructure of aortic elastic fibers

Elastic fibers are composed of a central core of elastin that is amorphous and electron-lucent in conventional transmission electron micrographs and peripheral microfibrils. A complex infrastructure within the amorphous elastin of mature rat aorta is made visible by fixation and staining with a glutaraldehyde-ruthenium red mixture in phosphate buffer or osmium-ruthenium red in cacodylate buffer. The infrastructure is composed of at least two interlacing but distinct elastic structural components; a framework of circumferentially orientated microfibrils and a three-dimensional meshwork of filaments that permeate the fiber. The latter resembles a reticulum that has previously been observed in freeze-fractured and negatively stained elastin and attributed to the supramolecular organization of elastin. Microfibrils also extend from the core of the elastic fiber into the surrounding matrix where they appear to function as anchoring fibers. These observations indicate that the elastic properties of the arterial wall are an integrated function of both elastin and microfibrils.     

The elastic fiber. I. The separation and partial characterization of its macromolecular components

The two morphologically different constituents of the mature elastic fiber, the central amorphous and the peripheral microfibrillar components, have been separated and partially characterized. A pure preparation of elastic fibers was obtained from fetal bovine ligamentum nuchae by extraction of the homogenized ligament with 5 M guanidine followed by digestion with collagenase. The resultant preparation consisted of elastic fibers which were morphologically identical with those seen in vivo. The microfibrillar components of these elastic fibers were removed either by proteolytic enzymes or by reduction of disulfide bonds with dithioerythritol in 5 M guanidine. The microfibrils solubilized by both methods were rich in polar, hydroxy, and sulfur-containing amino acids and contained less glycine, valine, and proline than the amorphous component of the elastic fiber. In contrast, the amino acid composition of the amorphous component was identical with that previously described for elastin. This component demonstrated selective susceptibility to elastase digestion, but was relatively resistant to the action of other proteolytic enzymes and to reduction. These observations establish that the microfibrils consist of a different connective tissue protein (or proteins) that is neither collagen nor elastin. During embryologic development the microfibrils form an aggregate structure before the amorphous component is secreted. These microfibrils may therefore play a primary role in the morphogenesis of the elastic fiber.     

Ultrastructural cytochemical properties of elastinassociated microfibrils and their relation to fibronectin

Summary The characteristics of elastin-associated microfibrils were investigated in the tunica adventitia of mouse aortas at the ultrastructural cytochemical level. The high iron diamine-thiocarbohydrazide-silver proteinate (HID-TCH-SP) method specific for sulphate groups was used with and without prior treatment ofen bloc specimens with either monopersulphate or cupric sulphite reagent. Amorphous elastin formed a clearly identifiable central core with microfibrils located both peripherally and interstitially. Sequential oxidation with monopersulphate and HID-TCH-SP demonstrated a characteristic staining for oxytalan fibres and intensely stained the microfibrils, whereas amorphous elastin stained weakly. Sequential thiosulphation with cupric sulphite and HID-TCH-SP for the demonstration of disulphide linkages and sulphydryl groups intensely stained microfibrils and weakly to moderately stained the amorphous elastin. This reactivity of the microfibrils was not altered by digestion with chondroitinase ABC, performed prior to or after treatment with either monopersulphate or cupric sulphite. In the specimens not exposed to either monopersulphate or cupric sulphite there was no definite HID-TCH-SP staining of microfibrils and amorphous elastin. Further, immunostaining with rabbit antibody specific for mouse fibronectin localized fibronectin in the microfibrils but not in the amorphous, elastin. These results indicate that elastin-associated microfibrils in mouse aorta lack stainable sulphate complex carbohydrates but are enriched with either disulphide or sulphydryl groups, or both, and further demonstrate the close correlation between these glycoproteins and fibronectin.     

Fine mapping of tropoelastin-derived components in the aorta of developing chick embryo

Summary Affinity-purified antitropoelastin antibodies have been used to localize tropoelastin-derived components in aortas from chick embryos of different age by immunoelectron microscopy. Staining in the matrix is first noted at day 3 associated with irregular bundles of filaments resembling microfibrils, in the absence of amorphous elastin deposits. Amorphous material, which rapidly accumulates at later stages, is heavily labelled, while surrounding microfibrils are only poorly labelled. By contrast, a more intense staining of microfibrils persists in regions in which amorphous material is not morphologically evident. These observations indicate that the initial accumulation of elastin requires microfibrils, while the two components are not in close association in the subsequent growth of the amorphous core of the fibre. Intracellular staining is evident in the secretory apparatus of the cell and in peripheral large vesicles. Differentiated cells also show regions of close contact with elastic fibres in which immunological staining for elastin is very close to the cell membrane.     

Ultrastructure and staining properties of aortic microfibrils (oxytalan)

Microfibrils are the insoluble, 10- to 12-nm components of the extracellular matrix that are involved in elastogenesis. Reports of their ultrastructure vary: they have been described as tubular and beaded and as nontubular filaments that are devoid of any periodicity. Ultrastructurally, microfibrils resemble oxytalan fibers that have been observed in peridontal membranes, skin, and other locations. Whether microfibrils have the staining characteristics of oxytalan is difficult to determine in tissues because available light microscopic stains also stain elastin. Calf aortic smooth muscle cells grown in media without added ascorbate provide a unique model for examining the ultrastructure and staining characteristics of chemically defined microfibrils. Microfibrils are the predominant insoluble extracellular protein in such cultures, which do not deposit collagen or elastin. These studies demonstrate that microfibrils are tubular structures with 10- and 12-nm striations and have the same staining characteristics as oxytalan, reacting with aldehyde fuchsin and orcein after oxidation. Microfibrillar protein is enriched in glutamic and aspartic acids and the electron density of microfibrils is enhanced by fixation in the presence of cationic dyes. In such preparation, microfibrils are made visible within the core of amorphous elastin as well as in regions that are free of elastin. The widespread distribution of microfibrils (oxytalan) indicates that their function extends beyond elastogenesis. Their localization within tissues suggests that they serve as an elastic attachment protein in sites that are subject to mechanical stress.     

Microfibrils: a constitutive component of reticular fibers in the mouse lymph node

Summary Fibrous components other than collagen fibrils in the reticular fiber of mouse lymph node were studied by electron microscopy. Bundles of microfibrils not associated by elastin and single microfibrils dispersed among collagen fibrils were present. The diameter of the microfibrils was 13.29±2.43 nm (n=100). Elastin-associated microfibrils occurred at the periphery of the reticular fiber. Elastin was enclosed by microfibrils, thus forming the elastic fiber, which was clearly demonstrated by tannic acid-uranyl acetate staining. In the reticular fiber of lymph nodes, the elastic fiber consisted of many more microfibrils and a small amount of elastin. These microfibrils, together with the collagen fibrils, may contribut to the various functions of the reticular fibers.     

STRUCTURAL BIOLOGY OF THE FIBRES OF THE COLLAGENOUS AND ELASTIC SYSTEMS

The different types of fibres of the collagenous and elastic systems can be demonstrated specifically in tissue sections by comparing the typical ultrastructural picture of each of the fibre types with studies using selective staining techniques for light microscopy. A practicalmodus operandi, which includes the recommended staining procedures and interpretation of the results, is presented. Micrographs and tables are provided to summarize the differential procedures. Reticulin fibres display a distinct argyrophilia when studied by means of silver impregnation techniques, and show up as a thin meshwork of weakly birefringent, greenish fibres when examined with the aid of the Picrosirius-polarization method. In addition, electron-microscopic studies showed that reticulin fibres are composed of a small number of thin collagen fibrils, contrasting with the very many thicker fibrils that could be localized ultrastructurally to the sites where non-argyrophilic, coarse collagen fibres had been characterized by the histochemical methods used. The three different fibre types of the elastic system belong to a continuous series: oxytalan—elaunin—elastic (all of the fibre types comprising collections of microfibrils with, in the given sequence, increasing amounts of elastin). The three distinct types of elastic system fibres have different staining characteristics and ultrastructural patterns. Ultrastructurally, a characteristic elastic fibre consists of two morphologically different components: a centrally located solid cylinder of amorphous and homogeneous elastin surrounded by tubular microfibrils. An oxytalan fibre is composed of a bundle of microfibrils, identical to the elastic fibre microfibrils, without amorphous material. In elaunin fibres, dispersed amorphous material (elastin) is intermingled among the microfibrils.     

Demonstration of microfibrils in Bruch's membrane of the eye

The cationic dyes ruthenium red and alcian blue were used to visualize a population of microfibrils in Bruch's membrane, a compound basement membrane located in the uveal tract of the eye between the retinal pigment epithelium and choriocapillaris. Microfibrils were tubular structures, 10-12 nm in diameter, that showed a characteristic beaded pattern. The majority of microfibrils appeared as a dense mantle around the layer of amorphous elastin. Microfibrils and collagen fibers were also present as a loosely organized meshwork in the collagenous zone of the membrane. Microfibrils were also seen along the basal surface of the retinal pigment epithelium where they appeared to insert into the substance of the basal lamina. Ruthenium red staining of microfibrils was not abolished by prior exposure of tissue to several kinds of degradative enzymes. The findings suggest that the elastic properties of Bruch's membrane may depend on both the elastin and microfibrillar components.     

Association of elastin with oxytalan fibers of the dermis and with extracellular microfibrils of cultured skin fibroblasts

The formation of a mature elastic fiber is thought to proceed by the deposition of elastin on pre-existing microfibrils (10-12 nm in diameter). Immunohistochemical evidence has suggested that in developing tissues such as aorta and ligamentum nuchae, small amounts of elastin are associated with microfibrils but are not detected at the light microscopic and ultrastructural levels. Dermal tissue contains a complex elastic fiber system consisting of three types of fibers--oxytalan, elaunin, and elastic--which are believed to differ in their relative contents of microfibrils and elastin. According to ultrastructural analysis, oxytalan fibers contain only microfibrils, elaunin fibers contain small quantities of amorphous elastin, and elastic fibers are predominantly elastin. Using indirect immunofluorescence techniques, we demonstrate in this study that nonamorphous elastin is associated with the oxytalan fibers. Frozen sections of normal skin were incubated with antibodies directed against human aortic alpha elastin and against microfibrillar proteins isolated from cultured calf aortic smooth muscle cells. The antibodies to the microfibrillar proteins and elastin reacted strongly with the oxytalan fibers of the upper dermis. Oxytalan fibers therefore are composed of both microfibrils and small amounts of elastin. Elastin was demonstrated extracellularly in human skin fibroblasts in vitro by indirect immunofluorescence. The extracellular association of nonamorphous elastin and microfibrils on similar fibrils was visualized by immunoelectron microscopy. Treatment of these cultures with sodium dodecyl sulfate/mercaptoethanol (SDS/ME) solubilized tropoelastin and other proteins that reacted with the antibodies to the microfibrillar proteins. It was concluded that the association of the microfibrils with nonamorphous elastin in intact dermis and cultured human skin fibroblasts may represent the initial step in elastogenesis.     

THE FINE STRUCTURE OF ELASTIC FIBERS

The fine structure of developing elastic fibers in bovine ligamentum nuchae and rat flexor digital tendon was examined. Elastic fibers were found to contain two distinct morphologic components in sections stained with uranyl acetate and lead. These components are 100 A fibrils and a central, almost amorphous nonstaining area. During development, the first identifiable elastic fibers are composed of aggregates of fine fibrils approximately 100 A in diameter. With advancing age, somewhat amorphous regions appear surrounded by these fibrils. These regions increase in prominence until in mature elastic fibers they are the predominant structure surrounded by a mantle of 100 A fibrils. Specific staining characteristics for each of the two components of the elastic fiber as well as for the collagen fibrils in these tissues can be demonstrated after staining with lead, uranyl acetate, or phosphotungstic acid. The 100 A fibrils stain with both uranyl acetate and lead, whereas the central regions of the elastic fibers stain only with phosphotungstic acid. Collagen fibrils stain with uranyl acetate or phosphotungstic acid, but not with lead. These staining reactions imply either a chemical or an organizational difference in these structures. The significance and possible nature of the two morphologic components of the elastic fiber remain to be elucidated.     

Distribution and organization of the elastic system fibres in healthy human gingiva

Summary The ultrastructural distribution and organization of the elastic system fibres, i.e. oxytalan, elaunin and elastic fibres, were studied by transmission electron microscopy and by an immunohistochemical method for the detection of elastin in healthy human gingiva. The morphological distribution of these fibres was characterized by the presence of oxytalan, elaunin and elastic fibres, respectively, in the upper, medium, and deep layers of gingival connective tissue. Anti-elastin antibody reacted with microfibrils and amorphous material of the elastic system fibres throughout the gingival connective tissue. These findings were interpreted as indicating that the microfibrils were associated with small amounts of elastin at their surface.     

Emilin, a component of elastic fibers preferentially located at the elastin-microfibrils interface

The fine distribution of the extracellular matrix glycoprotein emilin (previously known as glycoprotein gp115) (Bressan, G. M., I. Castellani, A. Colombatti, and D. Volpin. 1983. J. Biol. Chem. 258: 13262-13267) has been studied at the ultrastructural level with specific antibodies. In newborn chick aorta the protein was exclusively found within elastic fibers. In both post- and pre-embedding immunolabeling emilin was mainly associated with regions where elastin and microfibrils are in close contact, such as the periphery of the fibers. This localization of emilin in aorta has been confirmed by quantitative evaluation of the distribution of gold particles within elastic fibers. In other tissues, besides being associated with typical elastic fibers, staining for emilin was found in structures lacking amorphous elastin, but where the presence of tropoelastin has been demonstrated by immunoelectron microscopy. This was particularly evident in the oxitalan fibers of the corneal stroma, in the Descemet's membrane, and in the ciliary zonule. Analysis of embryonic aorta revealed the presence of emilin at early stages of elastogenesis, before the appearance of amorphous elastin. Immunofluorescence studies have shown that emilin produced by chick embryo aorta cells in culture is strictly associated with elastin and that the process of elastin deposition is severely altered by the presence of antiemilin antibodies in the culture medium. The name of the protein was derived from its localization at sites where elastin and microfibrils are in proximity (emilin, elastin microfibril interface located protein).     

Elastic fiber formation in monolayer and organ cultures of chondrocytes isolated from auricular cartilage.

Chondrocytes were isolated from auricular cartilage of immature rabbits and maintained in monolayer or organ culture for 14 days. In both types of culture the chondrocytes formed conspicuous elastic fibers. In monolayer culture the fibers could be identified by orcein staining in the culture dish. Electron microscopy of organ cultures revealed the presence of two basic components of elastic fibers, i.e. microfibrils and elastin.     

Characterization of an in vitro model of elastic fiber assembly

Elastic fibers consist of two morphologically distinct components: elastin and 10-nm fibrillin-containing microfibrils. During development, the microfibrils form bundles that appear to act as a scaffold for the deposition, orientation, and assembly of tropoelastin monomers into an insoluble elastic fiber. Although microfibrils can assemble independent of elastin, tropoelastin monomers do not assemble without the presence of microfibrils. In the present study, immortalized ciliary body pigmented epithelial (PE) cells were investigated for their potential to serve as a cell culture model for elastic fiber assembly. Northern analysis showed that the PE cells express microfibril proteins but do not express tropoelastin. Immunofluorescence staining and electron microscopy confirmed that the microfibril proteins produced by the PE cells assemble into intact microfibrils. When the PE cells were transfected with a mammalian expression vector containing a bovine tropoelastin cDNA, the cells were found to express and secrete tropoelastin. Immunofluorescence and electron microscopic examination of the transfected PE cells showed the presence of elastic fibers in the matrix. Biochemical analysis of this matrix showed the presence of cross-links that are unique to mature insoluble elastin. Together, these results indicate that the PE cells provide a unique, stable in vitro system in which to study elastic fiber assembly.     

Effect of monoclonal antibodies to defined regions of tropoelastin on elastogenesis in vitro.

Primary cultures of chick embryo aorta cells were grown for one week in the presence of mouse monoclonal antibodies directed against defined regions of chick tropoelastin. This treatment did not significantly alter cell proliferation, cell viability and incorporation of labeled amino acids into total protein or tropoelastin compared with control cultures in which antibodies were either omitted or substituted with an unrelated monoclonal antibody. Tropoelastin-reactive material in the cell layer was revealed by immunologic staining with rabbit antibodies against the chick protein both at the optical and ultrastructural level. Immunofluorescence of control cultures showed that tropoelastin was incorporated into thin and straight fibrils which were sometimes associated with spot-like elements. In the electron microscope tropoelastin-reactive sites were found mainly on the amorphous core of typical, small elastic fibers. The morphological picture of tropoelastin deposits in cultures exposed to anti-tropoelastin monoclonal antibodies depended on the molecular form (whole antibody or Fab fragments) and the binding specificity of the antibody used. Although alterations common to different antibodies were observed, the main structural features were peculiar for each antibody. Two antibodies which bound epitopes present in two regions of tropoelastin grossly altered the formation of amorphous elastin. Moreover, two antibodies directed against the region of tropoelastin containing the polypentapeptide-repeat (VPGVG)n stimulated the deposition of the protein into the amorphous core of normal-looking elastic fibers and disorganized the compact bundles of parallel microfibrils seen in controls. Finally, one antibody which recognized a unique epitope close to the carboxy-terminal end of tropoelastin and Fab fragments from all antibodies apparently inhibited the formation of the amorphous nuclei of elastic fibers, but not the association of tropoelastin with microfibrils. The data suggest that the association of tropoelastin molecules during fiber assembly is not random, but follows an ordered alignment process which the antibodies alter by imposing a different molecular packing.     

Ultrastructural immunolocalization of lysyl oxidase in vascular connective tissue

The localization of lysyl oxidase was examined in calf and rat aortic connective tissue at the ultrastructural level using polyclonal chicken anti-lysyl oxidase and gold conjugated rabbit anti-chicken immunoglobulin G to identify immunoreactive sites. Electron microscopy of calf aortic specimens revealed discrete gold deposits at the interface between extracellular bundles of amorphous elastin and the microfibrils circumferentially surrounding these bundles. The antibody did not react with microfibrils which were distant from the interface with elastin. There was negligible deposition of gold within the bundles of amorphous elastin and those few deposits seen at these sites appeared to be associated with strands of microfibrils. Lysyl oxidase was similarly localized in newborn rat aorta at the interface between microfibrils and nascent elastin fibers. Gold deposits were not seen in association with extracellular collagen fibers even after collagen-associated proteoglycans had been degraded by chondroitinase ABC. However, the antibody did recognize collagen-bound lysyl oxidase in collagen fibers prepared from purified collagen to which the enzyme had been added in vitro. No reaction product was seen if the anti-lysyl oxidase was preadsorbed with purified lysyl oxidase illustrating the specificity of the antibody probe. The present results are consistent with a model of elastogenesis predicting the radial growth of the elastin fiber by the deposition and crosslinking of tropoelastin units at the fiber-microfibril interface.     

Immuno-electron-microscopic application of antiserum against elastin

The antiserum against insoluble elastin from human aorta was applied to immuno-electron microscopy. In the preembedding method, only the outer surface of the amorphous component (elastin) of elastic fibers showed a positive reaction. A major problem encountered with the preembedding method is associated with the penetration of either the primary antiserum or the secondary antibody into the tissue and, in particular, into elastin. On the contrary, a positive reaction was observed inner zones of elastin in the postembedding method. While the postembedding method employed here has limitations with nonspecific binding to the embedding medium, the postembedding method offers a decided advantage over the preembedding method.     

Microfibrils, elastic anchoring components of the extracellular matrix, are associated with fibronectin in the zonule of Zinn and aorta

Microfibrils are striated tubules that play a role in the formation of elastin fibers by providing a scaffold upon which newly synthesized elastin is deposited. Ultrastructural and staining studies also demonstrate microfibrils that terminate where elastin is sparse or absent in basal laminae, plasma membranes, and the collagenous matrix. The most striking accumulation of microfibrils is found in the zonule of Zinn, the transparent and elastic suspensory ligament of the lens, which contains no elastin. Application of immunocytochemical staining with a peroxidase-antiperoxidase (PAP) procedure demonstrates that fibronectin is associated with the microfibrils of the zonule and aorta. Aggregates of microfibrils are identical to oxytalan ('acid enduring') fibers that have been described in peridontal membranes and other sites subject to mechanical stress and they can be found in sites as disparate as the rabbit zonule, rat hepatic stroma and human cardiac papillary muscle, indicating that microfibrils are a widely distributed connective tissue element with a function that extends beyond elastogenesis; their association with fibronectin and localization suggests that they serve as an elastic anchoring component of the extracellular matrix.     

Elastogenesis in rat arterial grafts: elastin deposits on microfibrillar and non-microfibrillar structures

Summary Endothelial lesions and the subsequent migration of smooth muscle cells in the intima layer are frequently observed after vascular grafting. The expression of secretory phenotype by these cells leads to the accumulation of connective tissue and thereby provides a model for the study of elastin depositionin vivo. Rats bearing aortic grafts of auto-, iso- or homologous origin were sacrificed between 3 and 18 months after implantation. Samples were treated for routine ultrastructural observations and for post-embedding by immunoelectron microscopy using anti-human elastin and protein A-gold.Grafts showed a large intimal thickening composed of several layers of smooth muscle cells and an abundant extracellular matrix. Mature elastic fibres (amorphous elastin associated with peripheral microfibrils) were always encountered in hyperplasia, suggesting that elastin deposition may follow the classical pathway involving microfibrils, which serve as a framework for polymerization of tropoelastin molecule into the amorphous component. However, an unusual localization of elastin aggregates was observed within basement membrane-like material surrounding smooth muscle cells. When sections were stained with methanolic uranyl acetate, these areas showed small electron-dense bodies, which were also labelled with anti-elastin antibody. These structures were apparently devoid of surrounding microfibrils. These results indicate that non-microfibrillar basement membrane material might be involved in the early events of elastin deposition.