Enzyme-antibody histochemistry

Summary Different types of distinct molecular forms of collagen are components of the extracellular matrix in most tissues. The common types can usually be detected by immunohistochemical methods but others may escape detection for lack of specific antisera. However, all these collagens are substrates for the collagenase of Clostridium histolyticum. In this report we describe a method that allows the visualization of collagens, collectively, in a tissue preparation. The method is based on the affinity between clostridial collagenase and collagen on one hand, and collagenase and its antibody on the other. Under the conditions of low temperature used in the procedure, collagenase binds to collagen, but digestion does not occur. Subequent reaction of the bound collagenase with the specific collagenase antibody is followed by reaction with a tagged anti-IgG reagent. This allows the visualization of the enzyme-substrate complex.The procedure is illustrated in sections of the heart and the aorta, as well as in the isolated cardiomyocytes and the collagen distribution is verified using collagens type I and IV specific antibodies. In all instances the collagenase staining pattern includes all structural features seen individually with the type specific anticollagen antibodies.Abbreviations BSA Bovine serum albumin - PBS phosphate buffored saline     

Specific identification of collagens and their fragments by clostridial and anti-collagenase antibody.

A method specific for identification of collagens irrespective of type, species, or tissue origin, and of their derived fragments of molecular weight more than 10,000, is described. The method is based on the low-temperature affinity between clostridial collagenase and almost all types of collagens as well as on the affinity between collagenase and its antibodies. Various collagens or fragments derived from them by treatment with CNBr were separated by SDS-PAGE and immobilized onto a nitrocellulose membrane by a slot-blot technique or electrotransfer. Following binding of clostridial collagenase to a collagen or its fragments at 0 degrees C, the collagen-collagenase complex was fixed with glutaraldehyde. The complex was then allowed to bind anti-collagenase antibody at room temperature. The new complex was subsequently treated with 125I-labeled donkey anti-rabbit IgG and visualized as an autoradiogram. Under the conditions of low temperature used, the collagenase binds to collagens without causing their digestion. This procedure is specific for detection of soluble collagens as well as of insoluble collagens converted to fragments by treatment with CNBr. The method is uniquely suited for detection of fragments of tissue collagens. Also, it may serve as a prototype for methods for detection of other specific polymeric substances.     

A comparative study of PAS-phosphotungstic acid-Diamine Supra Blue FGL and immunological reactions for type I collagen

Summary Immunohistochemical techniques proved valuable in histological studies of various types of collagens. However drawbacks include non-specific reactions of antibodies, masking of antigens, and the high cost of antibodies. This study was undertaken to ascertain the specificity of the PAS-phosphotungstic acid-Diamine Supra Blue FGL (PAS PTA-DSB-FGL) reaction for type I collagen, differentiating it from other collagens. Duplicate series of methaearn-fixed sections of various tissues were treated with the PAS-PTA-DSB FGL reaction and the peroxidase-antiperoxidase (PAP) technique for type I collagen and the staining patterns were compared. Fibers binding the blue dye were found only at sites reacting with antibodies against type I collagen. These observations indicate that the PAS-PTA-DSB FGL procedure is suitable for visualization of type I collagen, e.g. in screening of large series of sections and in the practice of surgical and autopsy pathology.     

Partial purification of collagenase and gelatinase from human polymorphonuclear leucocytes. Analysis of their actions on soluble and insoluble collagens.

The separation and further purification of human polymorphonuclear-leucocyte collagenase and gelatinase, using modifications of the method of Cawston & Tyler [(1979) Biochem J. 183, 647-656], are described. The final preparations yielded collagenase of specific activity 260 units/mg and gelatinase of specific activity 13 000 units/mg. Gelatinase was purified to apparent homogeneity in a latent form, and analysis of the activation of 125I-labelled latent enzyme by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and gel-filtration techniques suggested that no peptide material was lost on conversion into the active form. The purified natural inhibitors alpha 2-macroglobulin, tissue inhibitor of metalloproteinases ('TIMP') and amniotic-fluid inhibitor of metalloproteinases all inhibited the two polymorphonuclear-leucocyte metalloproteinases, but the last two inhibitors were slow to act and complete inhibition was difficult to attain. Collagenase degraded soluble types I and III collagen equally efficiently, but soluble type II collagen less well. Gelatinase alone had little activity on these substrates, although it enhanced the action of collagenase. Gelatinase was capable of degrading soluble types IV and V collagen at 25 degrees C, whereas collagenase was only active at higher temperatures when the collagens were susceptible to trypsin activity. By using tissue preparations of insoluble collagens (type I, II or IV) the activity of leucocyte collagenase was low and gelatinase activity was negligible, as measured by the solubilization of hydroxyproline-containing material. The two enzymes together were two or three times more effective in the degradation of these insoluble collagens.     

The collagen substrate specificity of rat uterus collagenase

The collagen substrate specificity of rat uterus collagenase was studied as a function of both collagen type and species of substrate origin. For each collagen examined, values for the basic kinetic parameters, Km and Vmax (kcat), were determined on collagen in solution at 25 degrees C. In all cases, Lineweaver-Burk plots were linear and rat uterus collagenase behaved as a normal Michaelis-Menten enzyme. Collagen types I, II, and III of all species tested were degraded by rat uterus collagenase. Collagen types IV and V were resistant to enzymatic attack. Both enzyme-substrate affinity and catalytic rates were very similar for all susceptible collagens (types I-III). Values for Km ranged from 0.9 to 2.5 X 10(-6) M. Values for kcat varied from 10.7 to 28.1 h-1. The homologous rat type I collagen was no better a substrate than the other animal species type I collagens. The ability of rat uterus collagenase to degrade collagen types I, II, and III with essentially the same catalytic efficiency is unlike the action of human skin fibroblast collagenase or any other interstitial collagenase reported to date. The action of rat uterus collagenase on type I collagen was compared to that of human skin fibroblast collagenase, with regard to their capacity to cleave collagen as solution monomers versus insoluble fibrils. Both enzymes had essentially equal values for kcat on monomeric collagen, yet the specific activity of the rat uterus collagenase was 3- to 6-fold greater on collagen fibrils than the skin fibroblast enzyme. Thus, in spite of their similar activity on collagen monomers in solution, the rat uterus collagenase can degrade collagen aggregated into fibrils considerably more readily than can human skin fibroblast collagenase.     

Susceptibility of cartilage collagens type II, IX, X, and XI to human synovial collagenase and neutrophil elastase

The action of purified rheumatoid synovial collagenase and human neutrophil elastase on the cartilage collagen types II, IX, X and XI was examined. At 25 degrees C, collagenase attacked type II and type X (45-kDa pepsin-solubilized) collagens to produce specific products reflecting one and at least two cleavages respectively. At 35 degrees C, collagenase completely degraded the type II collagen molecule to small peptides whereas a large fragment of the type X molecule was resistant to further degradation. In contrast, collagen type IX (native, intact and pepsin-solubilized type M) and collagen type XI were resistant to collagenase attack at both 25 degrees C and 35 degrees C even in the presence of excess enzyme. Mixtures of type II collagen with equimolar amounts of either type IX or XI did not affect the rate at which the former was degraded by collagenase at 25 degrees C. Purified neutrophil elastase, shown to be functionally active against soluble type III collagen, had no effect on collagen type II at 25 degrees C or 35 degrees C. At 25 degrees C collagen types IX (pepsin-solubilized type M) and XI were also resistant to elastase, but at 35 degrees C both were susceptible to degradation with type IX being reduced to very small peptides. Collagen type X (45-kDa pepsin-solubilized) was susceptible to elastase attack at 25 degrees C and 35 degrees C as judged by the production of specific products that corresponded closely with those produced by collagenase. Although synovial collagenase failed to degrade collagen types IX and XI, all the cartilage collagen species examined were degraded at 35 degrees C by conditioned culture medium from IL1-activated human articular chondrocytes. Thus chondrocytes have the potential to catabolise each cartilage collagen species, but the specificity and number of the chondrocyte-derived collagenase(s) has yet to be resolved.     

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.     

Fibril-forming collagens in lamprey

Five types of collagen with triple-helical regions approximately 300 nm in length were found in lamprey tissues which show characteristic D-periodic collagen fibrils. These collagens are members of the fibril forming family of this primitive vertebrate. Lamprey collagens were characterized with respect to solubility, mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, carboxylmethyl-cellulose chromatography, peptide digestion patterns, composition, susceptibility to vertebrate collagenase, thermal stability, and segment long spacing-banding pattern. Comparison with fibril-forming collagens in higher vertebrates (types I, II, III, V, and XI) identified three lamprey collagens as types II, V, and XI. Both lamprey dermis and major body wall collagens had properties similar to type I but not the typical heterotrimer composition. Dermis molecules had only alpha 1(I)-like chains, while body wall molecules had alpha 2(I)-like chains combined with chains resembling lamprey type II. Neither collagen exhibited the interchain disulfide linkages or solubility properties of type III. The conservation of fibril organization in type II/type XI tissues in contrast to the major developments in type I and type III tissues after the divergence of lamprey and higher vertebrates is consistent with these results. The presence of type II and type I-like molecules as major collagens and types V and XI as minor collagens in the lamprey, and the differential susceptibility of these molecules to vertebrate collagenase is analogous to the findings in higher vertebrates.     

Quantification and specific detection of collagenous proteins using an enzyme-linked immunosorbent assay and an immunoblotting for cyanogen bromide peptides

A method for the detection of collagenous proteins within cyanogen bromide digests of tissues has been devised. The peptides produced by digestion with cyanogen bromide were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transferred to a nitrocellulose filter. They were stained on the filter by incubation first with antibodies to collagen and then with a second antibody covalently linked to horseradish peroxidase, 4-chloro-1-naphthol was added, and the bound enzyme was assayed. This procedure is useful for the identification and characterization of collagens of types I, III, IV, and V in tissues. In addition, we have developed a sensitive and specific competitive enzyme-linked immunosorbent assay (ELISA) which is convenient for quantifying collagens (types I, III, and IV) in tissues. In this kind of assay, soluble cyanogen bromide peptides compete with cyanogen bromide peptides adsorbed onto a solid-phase support for rabbit anti-collagen antibodies. We determined the amount of bound antibody by using goat anti-rabbit immunoglobulin G covalently conjugated to horseradish peroxidase and then provided a substrate for the enzymatic reaction. The sensitivity range of the ELISA is 0.09 micrograms/ml in the region of 90 to 10% binding.     

Properties of radiolabeled type I, II, and III collagens related to their use as substrates in collagenase assays

Calf skin and rat tendon type I, bovine cartilage type II, and human amnion type III collagens have been radiolabeled by reaction with [3H]acetic anhydride, [3H]formaldehyde, and succinimidyl 2,3-[3H]propionate. All three reactions produce collagens with high specific activities that are suitable for use as substrates in collagenase assays. The identity of the radiolabel and the labeling indices do not alter the molecular weights or thermal stabilities of the collagens or the solubilities of the collagens or gelatins in dioxane-water mixtures at 4 degrees C. However, in contrast to native or sparsely labeled collagens, those with 40 or more lysine + hydroxylysine residues labeled per molecule do not undergo fibrillogenesis in the presence of 0.2-0.4 M NaCl in the 4-35 degree C temperature range. Thus, the modification reactions not only serve to introduce the radiolabel, but also to keep the collagens soluble over a wide range of temperatures and concentrations. The TCA, TCB fragments produced on partial reaction of each collagen type with tissue collagenases can be selectively denatured by a 10-minute incubation under specific conditions and the intact collagens selectively precipitated by addition of 50% v/v dioxane. This serves as the basis for soluble collagenase assays. The effect of labeling index on the properties of the collagens has been investigated and the results establish the range of conditions over which these collagens can be used as substrates for soluble versus fibrillar collagenase assays.     

Electrophoresis and electroblotting of native collagens

Electrophoretic and immunoblotting techniques, while now used routinely for the biochemical characterization of many proteins, have not been used for the identification of native collagens. We present here an acidic electrophoresis system using very low percentage acrylamide gels which maintains collagen solubility and allows migration of native dermal collagens. The method gives uniform gels which can be made mechanically stable for subsequent electroblotting. The resulting nitrocellulose transfer allows immunological detection of collagens using either polyclonal or monoclonal antibodies and can be used to screen antibody specificities. The majority of murine monoclonal antibodies directed against collagen bind only to conformational epitopes on the native triple-helical collagen, and thus cannot be screened by Western blotting. This method therefore enables the electrophoretic screening of these monoclonal antibodies and provides an alternative approach for their characterization.     

Collagenase activity in the normal rat myocardium. An immunohistochemical method

Fibrillar collagen in the myocardium provides a supportive framework for myocytes and capillaries. Disruption of this organized framework has been observed in certain pathological states. Collagen degradation is primarily mediated by the specific enzyme collagenase, which has been found to exist in various tissues including the myocardium. In this report we describe a method that detects collagenase activity in sections of cardiac tissue. This method is on the basis of degradation of collagen by collagenase on one hand and the visualization of disrupted collagen fibers by immunofluorescence on the other. Frozen rat heart sections were incubated under optimal conditions for collagenase activity (37 degrees C in the presence of 0.1 M calcium at pH 7.4) for 24 h and 48 h. Subsequently, immunofluorescence staining with antibody to type I collagen was performed and the collagenous structures were visualized by immunofluorescence light microscopy. As control, untreated rat heart sections and sections incubated in the absence of calcium were similarly treated with antibody. After the 24 h of incubation, we found no change in the structural integrity of collagen fibers. Marked disruption of the type I collagen fibers was observed 48 h after incubation. No evidence of collagen fiber disruption was found in control sections. Experiments with exogenous collagenase resulted in similar collagen fiber disruption in the frozen rat heart sections. We conclude that the disruption of collagen type I fibers after 48 h of incubation, under optimal conditions for collagenolytic digestion, is the result of collagen degradation by intrinsic collagenase of the myocardium.     

Codistribution of collagen types IV and AB2 in basement membranes and mesangium of the kidney. an immunoferritin study of ultrathin frozen sections

Affinity-purified rabbit antibodies specific for collagen types I, III, AB2 and for a partially characterized type IV collagen derived from a murine tumor were used to study the distribution of collagens in the normal mouse kidney. Immunofluorescence staining of conventional frozen sections demonstrated that types I and III were present in bundles around large vessels and in fibers surrounding glomeruli and tubules, whereas types IV and AB2 were distributed in a linear fashion along basement membranes of tubules, glomeruli, and Bowman's capsule and in the mesangial stalk. The distribution of types IV nd AB2 was examined at the ultrastructural level by staining of 600- to 800-A thick frozen sections with a three-stage procedure employing specific collagen antibodies, biotinyl sheep antirabbit IgG, and avidin-ferritin conjugates. Labeling by this procedure demonstrated codistribution of types AB2 and the putative type IV in all three basement membranes. In addition, mesangial matrix was shown to contain both of these collagen types. These results support recent biochemical evidence of collagen heterogeneity in basement membranes, and also support the concept of a structural relationship between mesangial matrix and glomerular basement membranes.     

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.     

Accurate, quantitative assays for the hydrolysis of soluble type I, II, and III 3H-acetylated collagens by bacterial and tissue collagenases

Accurate and quantitative assays for the hydrolysis of soluble 3H-acetylated rat tendon type I, bovine cartilage type II, and human amnion type III collagens by both bacterial and tissue collagenases have been developed. The assays are carried out at any temperature in the 1-30 degrees C range in a single reaction tube and the progress of the reaction is monitored by withdrawing aliquots as a function of time, quenching with 1,10-phenanthroline, and quantitation of the concentration of hydrolysis fragments. The latter is achieved by selective denaturation of these fragments by incubation under conditions described in the previous paper of this issue. The assays give percentages of hydrolysis of all three collagen types by neutrophil collagenase that agree well with the results of gel electrophoresis experiments. The initial rates of hydrolysis of all three collagens are proportional to the concentration of both neutrophil or Clostridial collagenases over a 10-fold range of enzyme concentrations. All three assays can be carried out at collagen concentrations. that range from 0.06 to 2 mg/ml and give linear double reciprocal plots for both tissue and bacterial collagenases that can be used to evaluate the kinetic parameters Km and kcat or Vmax. The assay developed for the hydrolysis of rat type I collagen by neutrophil collagenase is shown to be more sensitive by at least one order of magnitude than comparable assays that use rat type I collagen fibrils or gels as substrate.     

Type III collagen can be present on banded collagen fibrils regardless of fibril diameter

Monoclonal antibodies that recognize an epitope within the triple helix of type III collagen have been used to examine the distribution of that collagen type in human skin, cornea, amnion, aorta, and tendon. Ultrastructural examination of those tissues indicates antibody binding to collagen fibrils in skin, amnion, aorta, and tendon regardless of the diameter of the fibril. The antibody distribution is unchanged with donor age, site of biopsy, or region of tissue examined. In contrast, antibody applied to adult human cornea localizes to isolated fibrils, which appear randomly throughout the matrix. These studies indicate that type III collagen remains associated with collagen fibrils after removal of the amino and carboxyl propeptides, and suggests that fibrils of skin, tendon, and amnion (and presumably many other tissues that contain both types I and III collagens) are copolymers of at least types I and III collagens.     

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.     

Collagenase activity in the normal rat myocardium

Summary Fibrillar collagen in the myocardium provides a supportive framework for myocytes and capillaries. Disruption of this organized framework has been observed in certain pathological states. Collagen degradation is primarily mediated by the specific enzyme collagenase, which has been found to exist in various tissues including the myocardium. In this report we describe a method that detects collagenase activity in sections of cardiac tissue. This method is on the basis of degradation of collagen by collagenase on one hand and the visualization of disrupted collagen fibers by immunofluorescence on the other. Frozen rat heart secctions were incubated under optimal conditions for collagenase activity (37°C in the presence of 0.1 M calcium at pH 7.4) for 24 h and 48 h. Subsequently, immunofluorescence staining with antibody to type I collagen was performed and the collagenous structures were visualized by immunofluorescence light microscopy. As control, untreated rat heart sections and sections incubated in the absence of calcium were similarly treated with antibody. After the 24 h of incubation, we found no change in the structural integrity of collagen fibers. Marked disruption of the type I collagen fibers was observed 48 h after incubation. No evidence of collagen fiber disruption was found in control sections. Experiments with exogenous collagenase resulted in similar collagen fiber disruption in the frozen rat heart sections. We conclude that the disruption of collagen type I fibers after 48 h of incubation, under optimal conditions for collagenolytic digestion, is. the result of collagen degradation by intrinsic collagenase of the myocardium.     

Interaction of human thrombospondin with types I-V collagen: direct binding and electron microscopy

Binding of thrombospondin (TSP) to types I-V collagen was examined by direct binding assays using 125I-TSP and by visualization of rotary-shadowed intermolecular complexes in the electron microscope. The binding of TSP was highest to type V collagen in the absence of Ca, while lower but significant levels of binding were observed to all other collagen types in the presence or absence of Ca. Unlike intact TSP, the trimeric collagen-binding domain of TSP composed of 70-kD chains showed no Ca dependence in its binding to type V collagen. Further evidence for binding of TSP to types I and III collagen was obtained by competition studies in which these soluble collagens effectively inhibited binding of 125I-TSP to immobilized type V collagen. The binding of TSP to type V collagen was inhibited by heparin and fucoidin, both high-affinity ligands of TSP's heparin-binding domain. mAb A6.1, which binds to the 70-kD domain of TSP, is also the best of a panel of anti-TSP mAbs at inhibiting the TSP-collagen interaction. Electron microscopy of rotary-shadowed replicas of TSP-collagen complexes revealed that all five types of collagen examined had a binding site for TSP at one end of the pepsinized, triple helical molecule. The specificity of this site was tested by examining the ability of BSA to form a complex with the end of the pepsinized collagens. Rotary-shadowed replicas revealed a low frequency of apparent BSA-collagen complexes, and histograms of these data showed no evidence for the preferential association of BSA with the end of the collagen molecules. In addition to the specific end site, type V collagen had an internal binding site for TSP located about two-thirds of the distance along the length of the collagen molecule from the end site. The internal binding site for TSP on type V collagen is apparently the site responsible for the higher affinity binding of TSP to that protein observed in direct binding assays. The trimeric 70-kD collagen-binding domain of TSP bound to the same sites on the collagens as did intact TSP.     

Study of differential collagen synthesis during development of the chick embryo by immunofluorescence: II. Localization of type I and type II collagen during long bone development

The transition of type I and type II collagens during cartilage and bone development in the chick embryo was studied by immunofluorescence using antibodies against type I or type II collagens. Type II collagen was found in all cartilaginous structures which showed metachromatic staining. Type I collagen appeared in the perichondrium of the tibia at stage 28 and was also found in osteoid, periosteal and enchondral bone after decalcification, periosteum, and tendons, ligaments, and capsules.Using the immunohistological method it was possible to identify specific collagen types in areas undergoing rapid proliferation and collagen transition, such as diaphyseal and epiphyseal perichondrium, or in enchondral osteogenesis. During enchondral ossification type I collagen is deposited onto the eroded surface of cartilage. It partially diffuses into the cartilage matrix forming a “hybrid” collagen matrix with type II collagen, which is a site for subsequent ossification. During appositional growth of diaphyseal cartilage and differentiation of epiphyseal perichondrium into articular cartilage, perichondral cells switch from type I to type II collagen synthesis when differentiating into chondroblasts. In the transition zones, chondroblasts are imbedded in a “hybrid” matrix consisting of a mixture of type I and type II collagens.