The absence of type II collagen and changes in proteoglycan structure of hyaline cartilage in a case of Langer-Saldino achondrogenesis

Summary Structural analysis of hyaline cartilage extracellular matrix components from the ribs and knee joint of a stillborn female with type II achondrogenesis was carried out. The absence of type II collagen, a decrease in the amount of proteoglycans (PG), and structural changes in PG, namely, increased electrophoretic mobility of PG, lower relative content of chondroitin 4-sulfate (Ch4-S), lower molecular weight and decreased total chondroitin sulfate (ChS) sulfation, were detected. Increased amounts of type I and type III collagens, atypical for hyaline cartilage, were revealed. Among the link proteins (LPs), a large protein with a mol. wt. of 48 kDa was predominant. Molecular and cellular mechanisms of the pathogenesis of achondrogenesis (chondrogenesis imperfecta) are discussed. The data obtained suggest that the primary defect in type II achondrogenesis involves ChS or type II collagen synthesis.     

Extracellular Protease Inhibition Alters the Phenotype of Chondrogenically Differentiating Human Mesenchymal Stem Cells (MSCs) in 3D Collagen Microspheres

Matrix remodeling of cells is highly regulated by proteases and their inhibitors. Nevertheless, how would the chondrogenesis of mesenchymal stem cells (MSCs) be affected, when the balance of the matrix remodeling is disturbed by inhibiting matrix proteases, is incompletely known. Using a previously developed collagen microencapsulation platform, we investigated whether exposing chondrogenically differentiating MSCs to intracellular and extracellular protease inhibitors will affect the extracellular matrix remodeling and hence the outcomes of chondrogenesis. Results showed that inhibition of matrix proteases particularly the extracellular ones favors the phenotype of fibrocartilage rather than hyaline cartilage in chondrogenically differentiating hMSCs by upregulating type I collagen protein deposition and type II collagen gene expression without significantly altering the hypertrophic markers at gene level. This study suggests the potential of manipulating extracellular proteases to alter the outcomes of hMSC chondrogenesis, contributing to future development of differentiation protocols for fibrocartilage tissues for intervertebral disc and meniscus tissue engineering.     

Collagen-binding proteins in collagenase-released matrix vesicles from cartilage. Interaction between matrix vesicle proteins and different types of collagen.

Recent evidence indicates that matrix vesicles (MV) interact with cartilage-specific collagens and other matrix proteins. Both type II and X collagens bind to and cosediment with MV. Our companion study shows that MV also are tightly coupled to proteoglycan link proteins (LP) and hyaluronic acid-binding region (HABR) in cartilage matrix. Here we sought to identify proteins responsible for the nexus between MV and matrix collagens using affinity chromatography with types I, II, and X collagen-Sepharose columns. Elution with NaCl step-gradients in the presence of nonionic detergent was used to assess the affinity between the MV proteins and the covalently attached collagens. Several MV proteins were found to bind to native type I, II, and X collagens but none bound to denatured type I collagen. Alkaline phosphatase, proteoglycan LP and HABR, and the 33- and 67-kDa annexins, bound with varying affinities to the native type I, II and X columns. In particular, LP and HABR, the 67-kDa annexin, and alkaline phosphatase bound with high affinity to the cartilage-specific collagens, although LP, HABR, and a 37-kDa protein also bound less tightly to native type I collagen. Thus, several MV proteins bind specifically to native type II and X collagens and should promote interaction between MV and the extracellular matrix. Such interactions may be important in MV formation, or in MV-mediated mineralization.     

Effect of stretching on gene expression of beta1 integrin and focal adhesion kinase and on chondrogenesis through cell-extracellular matrix interactions

Differentiation of skeletal tissues, such as bone, ligament and cartilage, is regulated by complex interaction between genetic and epigenetic factors. In the present study, we attempted to elucidate the possible role of cell-extracellular matrix (ECM) adhesion on the inhibitory regulation in chondrogenesis responding to the tension force. The midpalatal suture cartilages in rats were expanded by orthopedic force. In situ hybridization for type I and II collagens, immunohistochemical analysis for fibronectin, alpha5 and beta1 integrins, paxillin, and vinculin, and cytochemical staining for actin were used to demonstrate the phenotypic change of chondrocytes. Immunohistochemical analysis for phosphorylation and nuclear translocation of extracellular signal-regulated kinase (ERK)-1/2 was performed. The role of the cell-ECM adhesion in the response of the chondroprogenitor cells to mechanical stress and the regulation of gene expression of focal adhesion kinase (FAK) and integrins were analyzed by using an in vitro system. A fibrous suture tissue replaced the midpalatal suture cartilage by the expansive force application for 14 days. The active osteoblasts that line the surface of bone matrix in the newly formed suture tissue strongly expressed the type I collagen gene, whereas they did not express the type II collagen gene. Although the numbers of precartilaginous cells expressing alpha5 and beta1 integrin increased, the immunoreactivity of alpha5 integrin in each cell was maintained at the same level throughout the experimental period. During the early response of midpalatal suture cartilage cells to expansive stimulation, formation of stress fibers, reorganization of focal adhesion contacts immunoreactive to a vinculin-specific antibody, and phosphorylation and nuclear translocation of ERK-1/2 were observed. In vitro experiments were in agreement with the results from the in vivo study, i.e. the inhibited expression of type II collagen and upregulation in integrin expression. The arginine-glycine-aspartic acid-containing peptide completely rescued chondrogenesis from tension-mediated inhibition. Thus, we conclude that stretching activates gene expression of beta1 integrin and FAK and inhibits chondrogenesis through cell-ECM interactions of chondroprogenitor cells.     

Macromolecular specificity of collagen fibrillogenesis: fibrils of collagens I and XI contain a heterotypic alloyed core and a collagen I sheath

Suprastructures of the extracellular matrix, such as banded collagen fibrils, microfibrils, filaments, or networks, are composites comprising more than one type of macromolecule. The suprastructural diversity reflects tissue-specific requirements and is achieved by formation of macromolecular composites that often share their main molecular components alloyed with minor components. Both, the mechanisms of formation and the final macromolecular organizations depend on the identity of the components and their quantitative contribution. Collagen I is the predominant matrix constituent in many tissues and aggregates with other collagens and/or fibril-associated macromolecules into distinct types of banded fibrils. Here, we studied co-assembly of collagens I and XI, which co-exist in fibrils of several normal and pathologically altered tissues, including fibrous cartilage and bone, or osteoarthritic joints. Immediately upon initiation of fibrillogenesis, the proteins co-assembled into alloy-like stubby aggregates that represented efficient nucleation sites for the formation of composite fibrils. Propagation of fibrillogenesis occurred by exclusive accretion of collagen I to yield composite fibrils of highly variable diameters. Therefore, collagen I/XI fibrils strikingly differed from the homogeneous fibrillar alloy generated by collagens II and XI, although the constituent polypeptides of collagens I and II are highly homologous. Thus, the mode of aggregation of collagens into vastly diverse fibrillar composites is finely tuned by subtle differences in molecular structures through formation of macromolecular alloys.     

The extracellular matrix of Gadus morhua muscle contains types III, V, VI and IV collagens in addition to type I

Confocal microscopy and immuno‐histochemistry were used to examine collagens in the extracellular matrix of cod Gadus morhua swimming muscle. In addition to the well known presence of type I fibrous collagen, types III and VI were also found in the myocommata and the endomysium. The beaded collagen, type VI, was found in the endomysium and the network forming collagen, type IV, was found in the basement membrane. This is the first report of type V collagen in cod muscle and of types II, IV and VI in the muscle of a teleost.     

An immunohistochemical study of localization of type I and type II collagens in mandibular condylar cartilage compared with tibial growth plate

Immunohistochemical localization of type I and type II collagens was examined in the rat mandibular condylar cartilage (as the secondary cartilage) and compared with that in the tibial growth plate (as the primary cartilage) using plastic embedded tissues. In the condylar cartilage, type I collagen was present not only in the extracellular matrix (ECM) of the fibrous, proliferative, and transitional cell layers, but also in the ECM of the maturative and hypertrophic cell layers. Type II collagen was present in the ECM of the maturative and hypertrophic cell layers. In the growth plate, type II collagen was present in the ECM of whole cartilaginous layers; type I collagen was not present in the cartilage but in the perichondrium and the bone matrices. These results indicate that differences exist in the components of the ECM between the primary and secondary cartilages. It is suggested that these two tissues differ in the developmental processes and/or in the reactions to their own local functional needs.     

A comparison of the immunohistochemical localization of type I and type II collagens in craniofacial cartilages of the rat.

The immunohistochemical localization of types I and II collagen was examined in the following 4 cartilaginous tissues of the rat craniofacial region: the nasal septal cartilage and the spheno-occipital synchondrosis (primary cartilages), and the mandibular condylar cartilage and the cartilage at the intermaxillary suture (secondary cartilages). In both primary cartilages, type II collagen was present in the extracellular matrix (ECM) of the whole cartilaginous area, but type I collagen was completely absent from the ECM. In the secondary cartilages, type I collagen was present throughout the cartilaginous cell layers, and type II collagen was restricted to the ECM of the mature and hypertrophic cell layers. These observations indicate differences in the ECM components between primary and secondary craniofacial cartilages, and that these differences may contribute to their modes of chondrogenesis.     

Front Cover: Dynamic observation and quantification of type I/II collagen in chondrogenesis of mesenchymal stem cells by second‐order susceptibility microscopy (J. Biophotonics 2/2019)

Top row is time‐lapse, multiphoton imaging of induced chondrogenesis from stem cells. The second row shows the time‐lapse second harmonic generation imaging of generated collagen. However, only the third row of second order susceptibility imaging allows the differentiation of the content of the two types of collagen (I and II) that were produced over time. The method allows the noninvasive and label‐free discrimination of different collagen species in real time and can be used for quality control in tissue engineering. Further details can be found in the article by Chiu‐Mei Hsueh, Hung‐Ming Lin, Te‐Yu Tseng, et al. ( e201800097 ).

     

An immunohistochemical study of localization of type I and type II collagens in mandibular condylar cartilage compared with tibial growth plate

Summary Immunohistochemical localization of type I and type II collagens was examined in the rat mandibular condylar cartilage (as the secondary cartilage) and compared with that in the tibial growth plate (as the primary cartilage) using plastic embedded tissues. In the condylar cartilage, type I collagen was present not only in the extracellular matrix (ECM) of the fibrous, proliferative, and transitional cell layers, but also in the ECM of the maturative and hypertrophic cell layers. Type II collagen was present in the ECM of the maturative and hypertrophic cell layers. In the growth plate, type II collagen was present in the ECM of whole cartilaginous layers; type I collagen was not present in the cartilage but in the perichondrium and the bone matrices. These results indicate that differences exist in the components of the ECM between the primary and secondary cartilages. It is suggested that these two tissues differ in the developmental processes and/or in the reactions to their own local functional needs.     

Collagen synthesis by regenerating rabbit ear tissue

The principal collagen types synthesized during two distinct phases of regeneration in rabbit ears have been investigated, in order to relate altered phenotypic expression in connective tissue cells to regeneration of cartilage. To do this, radioactively labeled collagens synthesized in short-term culture by selected regenerating ear tissues were analyzed by ion-exchange chromatography and SDS-gel electrophoresis of the intact collagens and of the cyanogen bromide peptides derived from them. Prior to the appearance of cartilage, rabbit ear holes are filled by an outgrowth of mesenchyme-like cells derived locally from adjacent tissues. These cells produce a mixture of collagens including type I, [α1(I)]₂α2, and the type I trimer, [α1(I)]₃, but not type II collagen. Trimer production represents about one-fourth of the collagen synthesized in either a 4-, 10-, or a 24-hr incubation. Trimer is not made by tissues from healing skin wounds nor is it present in normal, uninjured ear tissues. Type II collagen synthesis was detected in tissues taken from late regenerates containing histologically recognizable cartilage, and direct analysis of regenerated cartilage confirmed the presence of type II collagen in the matrix. Thus, regenerated cartilage in the rabbit ear system contains the normal cartilage collagen, type II, while the proliferating cell mass from which the cartilage develops synthesizes the unusual collagen, [α1(I)]₃.     

Assembly of collagen types II, IX and XI into nascent hetero-fibrils by a rat chondrocyte cell line.

The cell line, RCS-LTC (derived from the Swarm rat chondrosarcoma), deposits a copious extracellular matrix in which the collagen component is primarily a polymer of partially processed type II N-procollagen molecules. Transmission electron microscopy of the matrix shows no obvious fibrils, only a mass of thin unbanded filaments. We have used this cell system to show that the type II N-procollagen polymer nevertheless is stabilized by pyridinoline cross-links at molecular sites (mediated by N- and C-telopeptide domains) found in collagen II fibrils processed normally. Retention of the N-propeptide therefore does not appear to interfere with the interactions needed to form cross-links and mature them into trivalent pyridinoline residues. In addition, using antibodies that recognize specific cross-linking domains, it was shown that types IX and XI collagens, also abundantly deposited into the matrix by this cell line, become covalently cross-linked to the type II N-procollagen. The results indicate that the assembly and intertype cross-linking of the cartilage type II collagen heteropolymer is an integral, early process in fibril assembly and can occur efficiently prior to the removal of the collagen II N-propeptides.     

Identification ofClostridium histolyticum collagenase hyperreactive sites in type I, II, and III collagens: Lack of correlation with local triple helical stability

The class I and IIClostridium histolyticum collagenases (CHC) have been used to identify hyperreactive sites in rat type I, bovine type II, and human type III collagens. The class I CHC attack both collagens at loci concentrated in the N-terminal half of these collagens starting with the site closest to the N-terminus. The class II CHC initiate collagenolysis by attacking both collagens in the interior to produce a mixture of C-terminal 62,000 and a N-terminal 36,000 fragments. Both fragments are next shortened by removal of a 3000 fragment. These results are very similar to those reported earlier for the hydrolysis of rat type I collagen by these CHC, indicating that the three collagens share many hyperreactive sites. Similar reactions carried out with the respective gelatins show that they are cleaved at many sites at approximately the same rate. Thus, the hyperreactivity of the sites identified must be attributed to their environment in the native collagens. N-terminal sequencing of the fragments produced in these reactions has allowed the identification of 16 cleavage sites in the 1(I), 2(I), 1(II), and 1(III) collagen chains. An analysis of the triple helical stabilities of these cleavage site regions as reflected by their imino acid contents fails to yield a correlation between reactivity and triple helical stability. The existence of these hyperreactive CHC cleavage sites suggests that type I, II, and III collagens contain regions that have specific nontriple helical conformations. The sequence of these sites presented here now makes it possible to investigate these conformations by computational and peptide mimetic techniques.     

Synthesis of cartilage matrix by mammalian chondrocytes in vitro. III. Effects of ascorbate

Chondrocytes isolated from bovine articular cartilage were plated at high density and grown in the presence or absence of ascorbate. Collagen and proteoglycans, the major matrix macromolecules synthesized by these cells, were isolated at times during the course of the culture period and characterized. In both control and ascorbate-treated cultures, type II collagen and cartilage proteoglycans accumulated in the cell-associated matrix. Control cells secreted proteoglycans and type II collagen into the medium, whereas with time in culture, ascorbate-treated cells secreted an increasing proportion of types I and III collagens into the medium. The ascorbate-treated cells did not incorporate type I collagen into the cell-associated matrix, but continued to accumulate type II collagen in this compartment. Upon removal of ascorbate, the cells ceased to synthesize type I collagen. Morphological examination of ascorbate-treated and control chondrocyte culture revealed that both collagen and proteoglycans were deposited into the extracellular matrix. The ascorbate-treated cells accumulated a more extensive matrix that was rich in collagen fibrils and ruthenium red-positive proteoglycans. This study demonstrated that although ascorbate facilitates the formation of an extracellular matrix in chondrocyte cultures, it can also cause a reversible alteration in the phenotypic expression of those cells in vitro.     

Deposition and ultrastructural organization of collagen and proteoglycans in the extracellular matrix of gel-cultured fibroblasts

Human skin fibroblasts were cultivated within the three-dimensional space of polymerized alginate and collagen, respectively. The in vitro synthesis of collagens and proteoglycans was measured during the first 3 days of culture, and the deposition as well as the ultrastructural organization of newly synthesized extracellular matrix components were examined by electron microscopy. The amount of collagens and proteoglycans synthesized by fibroblasts, embedded in calcium alginate gels as well as in collagen lattices, was lowered as compared to monolayer cultures. Furthermore, it was found that collagen synthesis was reduced to a greater extent in alginate gels than in collagen lattices. On the contrary, total proteoglycan biosynthesis was similarly reduced either in alginate gels or in collagen lattices. At the end of a 3-day-culture period, filamentous material as well as cross-striated banded structures were found extracellularly in the alginate gel. According to their periodicity, their banding pattern, their association with polyanionic matrix components and their sensitivity towards glycosaminoglycan-degrading enzymes we could distinguish (1) sheets of amorphous non-banded material consisting of irregularly arranged filaments and containing dermatan sulfate-rich proteoglycans (type I structures), (2) sheets of long-spacing fibrils consisting of parallel orientated filaments and containing chondroitin sulfate-rich proteoglycans (= zebra bodies; type II structures), and (3) fibrillar structures with a complex banding pattern different from that of native collagen fibrils (type III structures). In fibroblasts cultured in collagen lattices, we only sporadically found depositions which are identified as type I structures. Using indirect immunoelectron microscopy and monospecific polyclonal antibodies, we localized type VI collagen in type I structures and type II structures. Type III structures can be identified as type I collagen derived as becomes obvious by comparison with segment long spacing crystallites of type I collagen.     

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.     

Probing non-enzymatic glycation of type I collagen: A novel approach using Raman and infrared biophotonic methods

Background

Non-enzymatic glycation is the main post-translational modification of long-life proteins observed during aging and physiopathological processes such as diabetes and atherosclerosis. Type I collagen, the major component in matrices and tissues, represents a key target of this spontaneous reaction which leads to changes in collagen biomechanical properties and by this way to tissue damages.

Methods

The current study was performed on in vitro glycated type I collagens using vibrational microspectroscopies, FT-IR and Raman, to highlight spectral features related to glycation effect.

Results and conclusions

We report a conservation of the triple-helical structure of type I collagen and noticeable variations in the exposure of proline upon glycation. Our data also show that the carbohydrate band can be a good spectroscopic marker of the glycation level, correlating well with the fluorescent AGEs formation with sugar addition.

General significance

These non-invasive and label-free methods can shed new light on the spectral features of glycated collagens and represent an effective tool to study changes in the extracellular matrix observed in vivo during aging or on the advent of a pathological situation.