Areas of asbestoid (amianthoid) fibers in human thyroid cartilage characterized by immunolocalization of collagen types I,II, IX,XI and X

The distribution of type I, II, IX, XI and X collagens in and close to areas of asbestoid (amianthoid) fibers in thyroid cartilages of various ages was investigated in this study. Asbestoid fibers were first detected in thyroid cartilage from a 3-year-old male child. Areas of asbestoid fibers functionally appear to serve as guide rails for vascularization of thyroid cartilage. Alcian blue staining in the presence of 0.3 M MgCl₂ revealed a loss of glycosaminoglycans in areas of asbestoid fibers. In addition, the fibers reacted positively with antibodies against collagen types II, IX and XI, but showed no staining with antibodies to collagen types I and X. Territorial matrix of adjacent chondrocytes showed the same staining pattern. In addition to staining for type II, IX and XI collagens, asbestoid fibers showed strong immunostaining for type I collagen after puberty but not for type X collagen. However, groups of chondrocytes within areas of asbestoid fibers reacted strongly with antibodies to type X collagen, suggesting that this collagen plays an important role in matrix of highly differentiated chondrocytes. The finding that these type X collagen-positive chondrocytes also revealed immunostaining for type I collagen confirms previous studies showing that hypertrophic chondrocytes can further differentiate into cells that are characterized by the synthesis of type X and I collagens.     

Collagen family of proteins

Collagen molecules are structural macro-molecules of the extracellular matrix that include in their structure one or several domains that have a characteristic triple helical conformation. They have been classified by types that define distinct sets of polypeptide chains that can form homo- and heterotrimeric assemblies. All the collagen molecules participate in supramolecular aggregates that are stabilized in part by interactions between triple helical domains. Fourteen collagen types have been defined so far. They form a wide range of structures. Most notable are 1) fibrils that are found in most connective tissues and are made by alloys of fibrillar collagens (types I, II, III, V, and XI) and 2) sheets constituting basement membranes (type IV collagen), Descemet's membrane (type VIII collagen), worm cuticle, and organic exoskeleton of sponges. Other collagens, present in smaller quantities in tissues, play the role of connecting elements between these major structures and other tissue components. The fibril-associated collagens with interrupted triple helices (FACITs) (types IX, XII, and XIV) appear to connect fibrils to other matrix elements. Type VII collagen assemble into anchoring fibrils that bind epithelial basement membranes and entrap collagen fibrils from the underlying stroma to glue the two structures together. Type VI collagen forms thin-beaded filaments that may interact with fibrils and cells.     

Histophysiological observations on the external auditory meatus,middle, and inner ear of the weddell seal (Leptonychotes weddelli)

The external auditory meatus, middle, and inner ear of the deep-diving Weddell seal (Leptonychotes weddelli) were studied with light microscopic, histological, and histochemical techniques in order to contribute to the open discussion on the orientation of this seal in the darkness of the deep Antarctic seas. The external auditory meatus is characterized by a well-developed venous plexus, single apocrine ceruminous, and numerous holocrine sebaceous glands and an incomplete tube of elastic cartilage. The tympanic membrane is comprised of two layers of radially and concentrically arranged collagen fibers and by elastic fibers which are concentrated in the outer part of the ear drum. The tympanic cavity is lined by a pseudostratified prismatic ciliated epithelium with goblet cells; a plexus of wide venous vessels marks the subepithelial lamina propria. The cochlea is about 10 mm high and forms about two and a half turns. The richly pigmented stria vascularis is well vascularized, while the cell-rich prominentia spiralis contains only single small blood vessels. The organ of Corti contains one row of inner and three rows of outer hair cells. Cells of Hensen, Claudius, and Boettcher are present. The basilar membrane is of comparatively uniform simple structure and is composed of abundant glycoproteins, proteoglycans, collagenous fibers, and the loose tissue of the tympanal layer. The spiral ligament is built up by abundant proteoglycans and a complex system of radial and concentric collagen fibers; close to the osseous wall of the bony cochlea it contains fine elastic fibers. The inner zone of the osseous wall of the cochlea strikingly contains hyaline cartilage. The thin lamina spiralis ossea is covered by a limbus spiralis with interdental cells secreting the lamina tectoria, which has a fibrous texture and contains glycoproteins and negatively charged components. J. Morphol. 234:25–36, 1997. © 1997 Wiley-Liss, Inc.     

A comparison of the immunofluorescent localization of collagen types I,III, and V with the distribution of reticular fibers on the same liver sections of the snow monkey (Macaca fuscata)

Summary Localizations of collagen types I, III, and V in monkey liver, as determined by the indirect immunofluorescence method, were photographically superimposed on the fibers revealed by silver-staining in the same tissue sections. Immunofluorescence for type I collagen was found to correspond with the brown collagen fibers and with some of the coarse reticular fibers, while that for type III collagen was found to correspond with most, but not all, reticular fibers of the liver as well as with the brown collagen fibers. The distribution of type V collagen coincides not only with the collagen fibers in the stroma of portal triads and around the central veins, but also with the coarse and fine reticular fibers in the liver lobules. By immuno-electron microscopy, reaction products with anti-type III and V collagens antibodies were demonstrated on cross-striated collagen fibrils, about 45 nm in diameter, in the space of Disse. From these observations, it is concluded that: (1) the fine reticular fibers are mainly composed of type III and type V collagens, and (2) the collagen fibers and coarse reticular fibers in the periphery of liver lobules are composed of type I, type III and type V collagens.     

Characterization of binding properties of the myelin-associated glycoprotein to extracellular matrix constituents.

The myelin-associated glycoprotein (MAG) can be obtained from adult mouse brain from detergent-lysates of a crude membrane fraction as a 96-100 kd form (detergent solubilized MAG), and from 100,000 g supernatants of homogenates as a 90-96 kd form (soluble MAG). The soluble form distributes into the Triton X-114-poor aqueous phase, while detergent-solubilized MAG predominantly enters the Triton X-114-rich phase. Both molecular forms bind to heparin in hypo- and isotonic buffers. Soluble MAG binds to several collagens (type G, I, II, III, IV, V, VI, IX) with a kd of 5.7 X 10(-8) M for collagen type IX and 2.0 X 10(-7) for collagen type IV. Binding of 125I-labeled MAG to collagen G can be completely inhibited by unlabeled MAG and collagen G, but not by heat-denatured collagen. MAG does not bind to itself, laminin, fibronectin, or the neural cell adhesion molecules L1 and N-CAM. Binding of MAG to collagen G is most effectively blocked by a high molecular weight dextran sulfate, heparan sulfate and heparin, with chondroitin sulfate and a low molecular weight dextran sulfate being less potent blockers. These findings are in agreement with previous observations on the localization of MAG in basal lamina and interstitial collagens of the sciatic nerve in situ.     

Involvement of HMGB1 and HMGB2 proteins in exogenous DNA integration reaction into the genome of HeLa S3 cells

Electrophoretic and Western blot studies were conducted on collagen fractions extracted from Sepia officinalis (cuttlefish) cartilage using a modified salt precipitation method developed for the isolation of vertebrate collagens. The antibodies used had been raised in rabbit against the following types of collagen: Sepia I-like; fish I; human I; chicken I, II, and IX; rat V; and calf IX and XI. The main finding was that various types of collagen are present in Sepia cartilage, as they are in vertebrate hyaline cartilage. However, the main component of Sepia cartilage is a heterochain collagen similar to vertebrate type I, and this is associated with minor forms similar to type V/XI and type IX. The cephalopod type I-like heterochain collagen can be considered a first step toward the evolutionary development of a collagen analogous to the typical collagen of vertebrate cartilage (type II homochain). The type V/XI collagen present in molluscs, and indeed all phyla from the Porifera upwards, may represent an ancestral collagen molecule conserved relatively unchanged throughout evolution. Type IX-like collagen seems to be essential for the formation of cartilaginous tissue.     

Immunohistochemical study of types I, III and IV collagen in diseased human gingiva of patients with rapidly progressive periodontitis: a light and electron microscopic study

The distribution of type I, III and IV collagens and their ultrastructural organization have been studied in diseased gingival connective tissue of patients with rapidly progressive periodontitis. This disease is characterized by acute destruction of the gingival collagenous components. The use of an immunofluorescent procedure has shown that the diseased connective tissue was made up of both type I and III collagens but that type III collagen was less resistant to acute inflammation. Ultrastructural immunolabelling, using the peroxidase procedure has shown that the large, dense bundles of type I collagen of PI, the main pattern of organization of the gingival connective tissue offered a better resistance to acute destruction than PII, a loose pattern of organization mainly composed of type III collagen. Type IV collagen was exclusively located in degraded lamina densa of basement membrane.     

Coordinate regulation of type IX and type II collagen synthesis during growth of chick chondrocytes in retinoic acid or 5-bromo-2'-deoxyuridine

Chondrocytes isolated from 15-day-old embryonic chick sterna were cultured as monolayers for 7 days in control medium or in medium supplemented with retinoic acid or 5-bromo-2'-deoxyuridine. Control cells exhibited characteristic polygonal morphology and maintained the synthesis of cartilage-specific collagens, i.e. type II, type IX, 1 alpha, 2 alpha, and 3 alpha chains, and 45 K (presumptive type X). Type IX was the second most prevalent collagen and represented 12-15% of the phenotype. When exposed to retinoic acid, chrondrocytes displayed a fibroblast-like morphology and decreased collagen synthesis by day 2. The synthesis of collagen types II and IX declined in parallel along with that of the other cartilage collagens and ceased by day 7. During the same period, the synthesis of collagen types I, III, and V and two unidentified collagen chains was initiated and stimulated. Similar changes in collagen expression were caused by 5-bromo-2'-deoxyuridine but were delayed, beginning after day 4. Type III collagen, however, was never detected in 5-bromo-2'-deoxyuridine or control cultures. Because two different agents and two rates of modulation produced parallel changes in the synthesis of collagen types II and IX, these collagens appear to be coordinately regulated.     

Association of collagen with preimplantation and peri-implantation mouse embryos

By immunofluorescence analyses, we have determined that Type III procollagen, Type III collagen, and B and C chains of basement membrane collagen are associated with preimplantation mouse embryos. Type III collagen and procollagen appear to be associated with embryos at the 4-cell stage and beyond, whereas antibodies to B and C collagen chains bind to 2-cell and later embryos. All of these collagen types are detected in increasing amounts as embryos develop in a defined medium, indicating that the embryo is capable of their synthesis. By the blastocyst stage, the collagens are primarily localized intercellularly. Cells of the inner cell mass (ICM) also bind collagen antibodies. When isolated ICMs become two-layered, both the inner presumptive ectoderm layer and the outer primitive endoderm layer react with antibodies to Type III collagen and procollagen. The endoderm cells also react avidly with antibodies to B- and C-chain collagens. Preimplantation embryos and ICMs fail to react with antibodies to Types I and II collagen. During peri-implantation stages, blastocysts continue to react with antibodies to Type III and basement membrane collagens. There is no obvious relationship between the intensity of immunofluorescence and the change in the blastocyst surface from nonadhesive to adhesive. Furthermore, blastocysts prevented from undergoing implantation-related events in utero and in vitro react extensively with collagen antibodies. Blastocyst surface collagens might, nevertheless, play a role in implantation by undergoing organizational changes.     

Immunohistochemical and biochemical studies on the collagenous proteins of human osteosarcomas

The distribution of type I, II, III, IV, V and VI collagens in 20 cases of osteosarcoma was demonstrated immunohistochemically using monospecific antibodies to different collagen types. In addition, biochemical analysis was made on collagenous proteins synthesized by tumor cells in short-term cultures obtained from seven representative cases and compared with dermal fibroblasts. In osteoblastic areas, most of the tumor osteoid consisted exclusively of type I collagen. Type V collagen was associated in some of them. Type III and type VI collagens were mainly localized in the perivascular fibrous stroma. Cultured tumor cells from osteoblastic osteosarcomas produced type I collagen exclusively and small amount of type V collagen constantly, while the synthetic activity of type III collagen was extremely low. In contrast, fibroblastic areas were characterized by the codistribution of type I, III, VI collagens and chondroblastic areas by type I, V, VI collagens as well as type II. Furthermore, type IV collagen was demonstrated in the stroma, other than the basement membrane region of blood vessels, in fibroblastic, intramedullary well-differentiated and telangiectatic osteosarcomas. In vitro, the production of variable amounts of type IV collagen, which was not detected in cultured dermal fibroblasts, was also recognized in the osteoblastic, fibroblastic, undifferentiated and intramedullary well-differentiated osteosarcomas examined. These findings suggest that the immunohistochemical approach using monospecific antibodies to different collagen types is useful not only in identifying some specific organoid components, such as tumor osteoid, but also in disclosing the biological properties of osteosarcoma cells with diverse differentiation.     

Electrophoretic and immunochemical study of collagens from Sepia officinalis cartilage

Electrophoretic and Western blot studies were conducted on collagen fractions extracted from Sepia officinalis (cuttlefish) cartilage using a modified salt precipitation method developed for the isolation of vertebrate collagens. The antibodies used had been raised in rabbit against the following types of collagen: Sepia I-like; fish I; human I; chicken I, II, and IX; rat V; and calf IX and XI. The main finding was that various types of collagen are present in Sepia cartilage, as they are in vertebrate hyaline cartilage. However, the main component of Sepia cartilage is a heterochain collagen similar to vertebrate type I, and this is associated with minor forms similar to type V/XI and type IX. The cephalopod type I-like heterochain collagen can be considered a first step toward the evolutionary development of a collagen analogous to the typical collagen of vertebrate cartilage (type II homochain). The type V/XI collagen present in molluscs, and indeed all phyla from the Porifera upwards, may represent an ancestral collagen molecule conserved relatively unchanged throughout evolution. Type IX-like collagen seems to be essential for the formation of cartilaginous tissue.     

Immunocytochemical localization of collagen types I,III, IV,and fibronectin in the human dermis

Summary The distribution of collagen types I, III, IV, and of fibronectin has been studied in the human dermis by light and electron-microscopic immunocytochemistry, using affinity purified primary antibodies and tetramethylrhodamine isothiocyanate-conjugated secondary antibodies. Type I collagen was present in all collagen fibers of both papillary and reticular dermis, but collagen fibrils, which could be resolved as discrete entities, were labeled with different intensity. Type III collagen codistributed with type I in the collagen fibers, besides being concentrated around blood vessels and skin appendages. Coexistence of type I and type III collagens in the collagen fibrils of the whole dermis was confirmed by ultrastructural double-labelling experiments using colloidal immunogold as a probe. Type IV collagen was detected in all basement membranes. Fibronectin was distributed in patches among collagen fibers and was associated with all basement membranes, while a weaker positive reaction was observed in collagen fibers. Ageing caused the thinning of collagen fibers, chiefly in the recticular dermis. The labeling pattern of both type I and III collagens did not change in skin samples from patients of up to 79 years of age, but immunoreactivity for type III collagen increased in comparison to younger skins. A loss of fibronectin, likely related to the decreased morphogenetic activity of tissues, was observed with age.     

Immunofluorescent localization of collagen types I, II, and III in the embryonic chick eye.

The appearance and distribution of type I, II, and III collagens in the developing chick eye were studied by specific antibodies and indirect immunofluorescence. At stage 19, only type I collagen was detected in the primary corneal stroma, in the vitreous body, and along the lens surface. At later stages, type I collagen was located in the primary and secondary corneal stroma and in the fibrous sclera, but not around the lens. Type II collagen was first observed at stage 20 in the primary corneal stroma, neural retina, and vitreous body. It was particularly prominent at the interface of the neural retina and vitreous body and, from stage 30 on, in the cartilaginous sclera. The primary corneal stroma consisted of a mixture of type I and II collagens between stages 20 and 27. Invasion of the primary corneal stroma by mesenchyme and subsequent deposition of fibroblast-derived collagen corresponded with a pronounced increase of type I collagen, throughout the entire stroma, and of type II collagen, in the subepithelial region. Type II collagen was also found in Bowman's and Descemet's membranes. A transient appearance of type III collagen was observed in the corneal epithelial cells, but not in the stroma (stages 20–30). The fully developed cornea contained both type I and II collagens, but no type III collagen. Type III collagen was prominent in the fibrous sclera, iris, nictitating membrane, and eyelids.     

The effects of mechanical stability on the macromolecules of the connective tissue matrices produced during fracture healing. I. The collagens

Summary The distribution of types I, II, III, V and IX collagens in healing fractures of the rabbit tibia has been demonstrated by immunofluorescent techniques. It has also been shown that the mechanical stability of the healing fracture affects both the distribution and types of the collagens present.The initial fibrous matrix contains types III and V collagens; type I collagen was only located in this matrix if unfixed tissue was used. In mechanically stable fractures, cancellous bone forms over the entire periosteal surface by 5–7 days; type I collagen is laid down within the previous fibrous matrix. The trabeculae are heterogeneous in their collagen content. The cavities contain a matrix of types III and V collagens. Small nodules of cartilage may be present between 7 and 14 days; these contain types II and IX collagens.In mechanically unstable fractures, cancellous bone is initially formed away from the fracture gap. The fibrous tissue over the gap is replaced by cartilage; types II and IX collagens are laid down on the pre-existing fibrous matrix. The cartilage is replaced by endochondral ossification. At the ossification front, type I collagen is found around the chondrocyte lacunae of the spicules of cartilage. The new trabeculae contain a core of cartilage which is surrounded by a bone matrix of types I and V collagens.The fracture gaps are invaded by fibrous tissue, which contain types III and V collagens. This is later replaced by cancellous bone.     

On the role of type IX collagen in the extracellular matrix of cartilage: type IX collagen is localized to intersections of collagen fibrils

The tissue distribution of type II and type IX collagen in 17-d-old chicken embryo was studied by immunofluorescence using polyclonal antibodies against type II collagen and a peptic fragment of type IX collagen (HMW), respectively. Both proteins were found only in cartilage where they were co-distributed. They occurred uniformly throughout the extracellular matrix, i.e., without distinction between pericellular, territorial, and interterritorial matrices. Tissues that undergo endochondral bone formation contained type IX collagen, whereas periosteal and membranous bones were negative. The thin collagenous fibrils in cartilage consisted of type II collagen as determined by immunoelectron microscopy. Type IX collagen was associated with the fibrils but essentially was restricted to intersections of the fibrils. These observations suggested that type IX collagen contributes to the stabilization of the network of thin fibers of the extracellular matrix of cartilage by interactions of its triple helical domains with several fibrils at or close to their intersections.     

Immunohistochemical study of subepidermal connective of molluscan integument

Sections of integument from gastropod, bivalve and cephalopod species were studied immunohistochemically to determine reactivity to antibody against the type I-like collagen from Sepia cartilage and antibodies against components of the extracellular matrix (ECM) of vertebrate connective tissue: type I, III, IV, V, and VI collagens, laminin, nidogen and heparan sulphate. All samples exhibited similar reactivities to the antibodies, although differences in the intensity and localization of the immunostaining were found that were clearly correlated with between-species differences in integumental ultrastructure. These findings indicate that the composition of the integumental ECM is similar in the three classes of molluscs examined and that several types of collagen are present. However molluscan subepidermal connective tissue differs from the ECM of vertebrate dermis: molluscan integumental ECM contains collagens similar to type I, V and VI collagens but has no type III-similar collagen. Furthermore molecules similar to the type IV collagen, laminin, nidogen and heparan sulphate of vertebrates were present ubiquitously in molluscan basement membrane, confirming the statement that the structure and composition of basement membrane have remained constant throughout the evolution of all animal phyla.     

Constituents of connective tissue around the capillary of chick pecten oculi

The constituents of the connective tissues around the capillary of the chick pecten oculi were examined electron microscopically by HCl-collagenase and HCl-elastase methods. The basal lamina like membrane below the endothelial cell of the pecten capillary was digested by collagenases I, II and IV and elastase, and may be a false basal lamina. The basal lamina of cells with pigment granules which surround the capillary was digested by collagenase IV and elastase, and contained type IV collagen. Fibrils between the basal lamina like membrane of the pecten capillary endothelium and the basal lamina of the cells with pigment granules were digested by collagenases I, II and IV, and elastase. Thus, these fibrils are composed of many kinds of collagen. Elastase may be responsible for the breakdown of most collagens as well as elastin.     

Are the polarization colors of picrosirius red-stained collagen determined only by the diameter of the fibers?

Polarization colors of various purified collagens were studied in fibers of similar thickness. Three different soluble collagens of type I, insoluble collagen type I, lathyritic collagen type I, two p-N-collagens type I, pepsin extract collagen type II, two soluble collagens type III, p-N-collagen type III, and soluble collagen type V were submitted to a routine histopathologic procedure of fixation, preparation of 5-microns-thick sections, staining with Picrosirius red and examination under crossed polars. Polarization colors were determined for thin fibers (0.8 micron or less) an thick fibers, (1.6-2.4 microns). Most thin fibers of collagens and p-N-collagens showed green to yellowish-green polarization colors with no marked differences between the various samples. Thick fibers of all p-N-collagens, lathyritic and normal 0.15 M NaCl-soluble collagens showed green to greenish-yellow polarization colors, while in all other collagens, polarization colors of longer wavelengths (from yellowish-orange to red) were observed. These data suggested that fiber thickness was not the only factor involved in determining the polarization colors of Picrosirius red-stained collagens. Tightly packed and presumably, better aligned collagen molecules showed polarization colors of longer wavelengths. Thus, packing of collagen molecules and not only fiber thickness plays a role in the pattern of polarization colors of Picrosirius red-stained collagens.     

Interaction between collagens and glycosaminoglycans investigated using a surface plasmon resonance biosensor.

The interactions of glycosaminoglycans with collagens and other glycoproteins in extracellular matrix play important roles in cell adhesion and extracellular matrix assembly. In order to clarify the chemical bases for these interactions, glycosaminoglycan solutions were injected onto sensor surfaces on which collagens, fibronectin, laminin, and vitronectin were immobilized. Heparin bound to type V collagen, type IX collagen, fibronectin, laminin, and vitronectin; and chondroitin sulfate E bound to type II, type V, and type VII collagen. Heparin showed a higher affinity for type IX collagen than for type V collagen. On the other hand, chondroitin sulfate E showed the highest affinity for type V collagen. The binding of chondroitin sulfate E to type V collagen showed higher affinity than that of heparin to type V collagen. These data suggest that a novel characteristic sequence included in chondroitin sulfate E is involved in binding to type V collagen.     

A morphologic and histochemical study of the mesentery in the guinea pig

The guinea pig mesentery is a uniform, continuous, thin (18 micron) sheet of connective tissue covered by a single layer of flattened mesothelial cells on both surfaces. Tight and gap junctions provide for cell-to-cell adhesion among mesothelial cells. These cells possess numerous micropinocytotic vesicles; a conspicuous basal lamina separates the mesothelium from the underlying connective tissue. Most of the material found between the two serous coverings consisted of a three-dimensional meshwork of abundant collagenous fibers intermingled with a sparse net of very thin (0.4 micron) elastic fibers. Two distinct populations of collagen fibrils are segregated into different compartments of the mesentery. One population is formed of thick (56 nm) fibrils which associate to form closely packed fibers. The second population, composed of loosely arranged thin (38 nm) fibrils which do not become assembled into fibers, is found underlying the basal lamina that separates the mesothelium from the connective tissue. These observations strongly suggest that the mesentery contains both collagens type I and type III. The guinea pig mesentery contains 6.8 mg of sulfated glycosaminoglycans/g dry weight. Most of these glycosaminoglycans (78%) were identified as dermatan sulfate, whilst the rest (22%) corresponded to heparan sulfate.