Chondromodulin-I expression in rat articular cartilage

The localization and expression of chondromodulin-I (ChM-I), an angiogenesis inhibitor, in the rat articular cartilage during maturation from 2 to 10 weeks of age were examined by immunohistochemistry, Western blot analysis and ribonuclease protection assay, and the results were compared with those in the epiphyseal cartilage. ChM-I was found to be diffusely immunostained in the inter-territorial space of the cartilage matrix from the intermediate to the deep layers at the immature stage. As the articular cartilage matured, the immunoreactivity was localized around the hypertrophic chondrocytes in the deep layer and the immunoreactivity became weak after maturation. In contrast, the ChM-I immunoreactivity was intense in the epiphyseal cartilage at all ages examined. ChM-I was detected by Western blotting as a broad band or occasionally as a cluster of multiple bands (approximately 25 kDa) in both the articular and the epiphyseal cartilage. The intensity of the bands decreased gradually with age in the articular cartilage, but was unchanged in the epiphyseal cartilage at all ages. Ribonuclease protection assay revealed that ChM-I mRNA also decreased gradually with age in the articular cartilage in parallel with the maturation of the articular cartilage, while no decrease in ChM-I mRNA was found in the epiphyseal cartilage. The expression of ChM-I mRNA in the articular cartilage was less than that in the epiphyseal cartilage at all ages. The decrease in amount of ChM-I in the mature articular cartilage suggests that ChM-I plays a more important role in the maintenance of avascularity in the immature articular cartilage than in the mature one. The avascular condition may be preserved by angiogenic inhibitors or mechanisms other than ChM-I in the mature articular cartilage.     

Demonstration of estrogen receptor-beta immunoreactivity in human growth plate cartilage

Estrogens affect longitudinal bone growth through their action on endochondral bone formation. Two estrogen receptors are known, the classical estrogen receptor-alpha (ER alpha), newly demonstrated in human growth plate cartilage, and a recently cloned estrogen receptor-beta (ER beta). The present study aimed to localize a possible expression of ER beta protein in human growth plates. Tissue samples were obtained from tibial and femoral growth plates in four female pubertal patients undergoing epiphyseal surgery. Immunohistochemistry, using two different ER beta-specific antibodies, demonstrated positive staining for ER beta in hypertrophic epiphyseal chondrocytes from all patients. No staining was noted in resting or proliferative chondrocytes. These data suggest that in addition to ER alpha, human epiphyseal chondrocytes also express ER beta. The physiological role of ER beta in the regulation of longitudinal bone growth in humans remains to be elucidated.     

The influence of respiratory sounds on breathlessness in children with asthma: a symptom-perception approach

Cartilage oligomeric matrix protein (COMP) is a macromolecule of yet unknown function with restricted distribution among tissues. In the present study, the ultrastructural localization of COMP in porcine immature joint cartilage and growth plate cartilage was semiquantitatively delineated. Tissues were fixed in a mixture of low concentration glutar- and paraformaldehyde, embedded at low temperature, and subjected to immunocytochemistry using polyclonal antibodies raised against bovine COMP. Protein A-coated colloidal gold was used for detection. The most intense immunolabeling for COMP was noted in the proliferative zones of the growth cartilages. Here the concentration of immunomarker was higher in the territorial compartment than in the pericellular and interterritorial areas. A low concentration of COMP was observed in the resting and hypertrophic zones. The immunolabeling for COMP did not differ between the three matrix compartments of these zones. Supported by previous data obtained by in situ hybridization, the concentration of immunolabeling in the proliferative zone indicates a high rate of COMP synthesis in proliferative chondrocytes. Hence, COMP may be considered as a marker for normal differentiation into proliferative chondrocytes.     

Distribution and subcellular immunolocalization of 1,25-dihydroxyvitamin D3 receptors in rat epiphyseal cartilage

The distribution and subcellular localization of the 1,25-dihydroxyvitamin D3 receptor (VDR) in the epiphyseal cartilage of normal weaning rats were examined immunocytochemically at the light and electron microscope level using a monoclonal anti-VDR antibody (9A7 gamma). VDR immunoreactivity was detected in the nuclei of chondrocytes in all zones of the epiphyseal plate cartilage from the resting to calcifying chondrocytes, and at much lower concentrations, in the cytoplasms. Perichondrial mesenchymal cells contained no VDR immunoreactivity. VDR immunoreactivity developed in the nuclei of cells in the lateral margin area as they acquired the chondroblast phenotype. VDR immunoreactivity was also found over the nucleoli of chondrocytes in all cells zones of the epiphyseal plate and appeared in the nucleoli of the cells in the lateral margin area before immunostaining of the nuclei, as the mesenchymal cells differentiated into chondroblasts. Electron microscopy showed that the immunoreactivity for 1,25(OH)2D3 receptor, indicated by gold particles, was associated with scattered clumps of compact chromatin and small clumps of dispersed chromatin. But the nuclei immunostaining patterns before and after mitosis were different in proliferative chondrocytes. The heterochromatin along the nuclear envelope was immunonegative in interphase chondrocytes, but there was VDR immunostaining over the rim of the perinuclear chromatin just after mitosis. In the nucleoli, the dense fibrillar component was immunostained, but the fibrillar centers and the perinuclear chromatin were not. This distribution of VDR immunoreactivity suggests that the hormone is directly involved in differentiation, proliferation and maturation of cartilage cells, and also with extracellular calcification in epiphyseal cartilage. The presence of immunoreactive VDR receptors in nucleoli of chondrocytes, particularly the fibrillar component, suggests that 1,25(OH)2D3 may be involved in regulation of ribosomal genes.     

Repair of large full-thickness articular cartilage defects with allograft articular chondrocytes embedded in a collagen gel

Full-thickness articular cartilage defects are a major clinical problem; however, presently there is no treatment available to regeneratively repair these lesions. The current therapeutic approach is to drill the base of the defect to expose the subchondral bone with its cells and growth factors. This usually results in a repair tissue of fibrocartilage that functions poorly in the loaded joint environment. The use of phenotypically appropriate chondrocytes embedded in a collagen gel delivery vehicle may provide a method that could be used to repair full-thickness articular cartilage defects with functionally satisfactory hyaline cartilage. Allograft articular chondrocytes embedded in a type I collagen gel were transplanted into large (6 x 3 x 3 mm), full-thickness articular cartilage defects in condylar and patellar weight-bearing surfaces to develop clinically applicable methods to repair articular cartilage defects. Chondrocytes were isolated from the articular cartilage of 4-week-old New Zealand rabbits and embedded in type I collagen gels. This composite was transplanted into a full-thickness defect on the medial femoral condyle and patellar groove of adolescent host rabbits. The repair cartilage was assessed histologically by a semiquantitative scoring system and biomechanically with a microindentation technique of specimens 4-48 weeks after chondrocyte transplantation. Defects in both locations were repaired with histologically apparent hyaline cartilage observed from as early as 4 weeks until 48 weeks after transplantation. The repair cartilage in the medial femoral condyle was more irregular than in the patellar groove, but in all other respects was similar. The grafted tissue did not remodel and differentiate into the morphological zones seen in normal articular cartilage. No tidemark or subchondral bony plate formed even 48 weeks after transplantation. Biomechanically, the repaired cartilage demonstrated indentation values similar to normal articular cartilage 12 weeks after transplantation and remained the same 48 weeks after transplantation. By contrast, the control (i.e., empty) defects healed with tissue that exhibited very poor metachromatic staining and exhibited very high indentation values. Incomplete bonding of the repair tissue to the normal cartilage was seen, and the surface was significantly irregular with major discontinuities. These observations provide the basis for considering the use of allograft articular chondrocytes to repair articular cartilage defects in the weight-bearing regions of the knee.     

Age changes in the articular tissue of human mandibular condyles from adolescence to old age: a semiquantitative light microscopic study

In a previous study (Luder, Anat. Rec., 1997;248:18-28), the articular tissue of the adult mandibular condyle was characterized semiquantitatively. However, questions about age changes of mature tissue were not answered, and the time course of tissue maturation from the end of condylar growth to the attainment of the adult appearance remained unknown. These issues are addressed in the present investigation. By using a light microscope, features of the superficial, intermediate, and deep articular tissue zones as well as of the subchondral bone were assessed at nine predetermined condylar sites. The frequencies of these features were recorded as scores from 0 (absent) to 10 (continuous) and were plotted against age. Analysis of covariance served for testing the significance of age and sex effects as well as intracondylar variability. Whereas almost all age-related changes in frequencies of tissue features were similar along the whole lateromedial dimension, changes at the putatively nonload-bearing, posterior slope differed significantly from those at the putatively load-bearing, anterior slope and zenith of the condyle. Two patterns of changes were noted. Frequencies of a first group of tissue features altered mainly during the age period from 15 years to 30 years and remained more or less stable thereafter. This course was characteristic for 1) a progressive cartilaginification of the superficial zone as well as 2) the disappearance of hypertrophic growth cartilage and 3) the appearance of grid-fibrous fibrocartilage in the deep zone, which were accompanied by 4) a decline in endochondral ossification and 5) the formation of a compact, subchondral bone plate. Frequencies of a second group of tissue features disclosed changes that continued up to middle and old age. This pattern was evident regarding 1) a decrease in the prominence associated with 2) a drop in cellularity and 3) progressive fibrosis or even cartilaginification of the intermediate zone. Among the age changes of condylar articular tissue, those affecting the superficial and deep zones as well as the subchondral bone are largely complete by about 30 years of age and seem to be related primarily to a gradual transition from growth to adulthood. In contrast, a second group of alterations, which progress to old age and involve mainly the intermediate zone, appears to be associated with continued maintenance and adaptive articular remodeling as well as possibly senescence. Both maturational and later age changes seem to depend markedly on articular load bearing.     

Terminal differentiation of chondrocytes is arrested at distinct stages identified by their expression repertoire of marker genes

During endochondral bone formation, cells in the emerging cartilaginous model transit through a cascade of several chondrocyte differentiation stages, each characterized by a specific expression repertoire of matrix macromolecules, until, as a final step, the hypertrophic cartilage is replaced by bone. In many permanent cartilage tissues, however, late differentiation of chondrocytes does not occur, due to negative regulation by the environment of the cells. Here, addressing the reason for the difference between chondrocyte fates in the chicken embryo sternum, cells from the caudal and cranial part were cultured separately in serum-free agarose gels with complements defined earlier that either permit or prevent hypertrophic development. Total RNA was extracted using a novel protocol adapted to agarose cultures, and the temporal changes in developmental stage-specific mRNA expression were monitored by Northern hybridization and phosphor image analysis. Kinetic studies of the mRNA accumulation not only showed significant differences between the expression patterns of cranial and caudal cultures after recovery, but also revealed two checkpoints of chondrocyte differentiation in keeping with cartilage development in vivo. Terminal differentiation of caudal chondrocytes is blocked at the late proliferative stage (stage Ib), while the cranial cells can undergo hypertrophic development spontaneously. The differentiation of cranial chondrocytes is reversible, since they can re-assume an early proliferative (stage Ia) phenotype under the influence of insulin, fibroblast growth factor-2 and transforming growth factor-beta in combination. Thus, the expression pattern in the latter culture resembles that of articular chondrocytes. We also provide evidence that the capacities of caudal and sternal chondrocytes to progress from the late proliferative (stage Ib) to hypertrophic stage (stage II) correlate with their differing abilities to express the Indian hedgehog gene.     

Apoptosis and proliferation of growth plate chondrocytes in rabbits

The growth plates of the femoral head of Japanese white rabbits aged 5, 10, 15 and 20 weeks were stained for apoptotic and proliferating chondrocytes using the TUNEL and PCNA antibody staining techniques. Both TUNEL- and PCNA-positive chondrocytes were detected in all of the specimens. The positive ratios of both stainings were calculated for the whole plate and for the resting, proliferating and hypertrophic zones. The highest ratios in both stainings occurred in the hypertrophic zone in all age groups. With growth, the TUNEL-positive ratio increased whereas the proliferating ratio decreased. We suggest that the increase in chondrocytic death by apoptosis and the decrease in cell proliferation potential led to closure of the growth plate.     

Differences in submicroscopic structure of the extracellular matrix of canine femoral and tibial condylar articular cartilages as revealed by polarization microscopical analysis

The submicroscopic orientation patterns of sulfated glycosaminoglycan side chains of proteoglycan molecules and collagen fibrils were compared in different extracellular matrix areas of femoral and tibial articular cartilages of young adult beagle dogs using qualitative and quantitative polarization microscopic analytical methods. Paraffin sections were cut perpendicularly to the articular surfaces from the femoral and tibial condyles and stained. Picrosirius red F38 staining combined with an antecedent digestion with testicular hyaluronidase was used to enhance the optical anisotropy of collagen. Birefringence of sulfated glycosaminoglycan molecules was selectively amplified by a combination of carboxymethylation with CH3I and a subsequent staining with toluidine blue. The specimens were analysed in a polarization microscope equipped with compensator plates, and retardation values of birefringence were determined in territorial and interterritorial matrix areas of different zones using monochromatic plane polarized light. It was found that besides some similarities there were significant differences in the submicroscopic organization of extracellular matrix between femoral and tibial articular cartilages. Common structural features of the femoral and tibial cartilages were the sulfated glycosaminoglycans and collagen fibrils which were circularly oriented in the territorial matrix, and these components were longitudinally arranged within the trabeculae of the interterritorial matrix. Furthermore, the territorial matrix was a more densely packed structure than the interterritorial matrix. Our results revealed the following major differences between the two cartilages: The degree of orientation of sulfated glycosaminoglycans was higher in the femoral cartilage matrix areas as compared to the identical structures of the tibial cartilage; the collagen structure was more densely packed in the interterritorial matrix of the superficial and mineralization zones of the femoral cartilage than in the tibial cartilage, and except for the zone of mineralization, the degree of collagen orientation was higher in the territorial matrix of the femoral than the tibial cartilage. These findings suggest that the extracellular matrix of femoral condylar cartilage has a more densely packed molecular structure than the softer tibial cartilage matrix. This structural difference may have an influence on the pathogenesis of diseases involving articular cartilage.     

The effect of experimental hypothyrosis on the fine structure of the epiphyseal cartilage of young rats

Authors studied the effect of hypothyrosis induced by thyro-parathyroidectomy and mercaptoimidazole treatment on the fine structure of the proximal epiphyseal cartilage of tibia in growing male rats. It has been established that the cell density of the epiphyseal cartilage decreases in the experimental hypothyrosis, about 30 to 50% of the chondrocytes display degenerative signs, whereas the Golgisystem seems to be well developed. The most characteristic alteration appear in the zones of proliferation and maturation of the epiphyseal cartilage. The endoplasmic reticulum (ER) and mitochondria show a considerable regression also in the chondrocytes displaying minimal or even no signs of degeneration. Elements indicating calcification were encountered more frequently in the cartilaginous matrix of the zones of maturation and calcification under the effect of mercaptoimidazole treatment as compared to the controls, whereas the matrix of the animals operated was poorer in minerals than the corresponding zones of the controls. This difference is attributed by the authors to the different levels of thyrocalcitonin in the two kinds of experiments.     

Damage to type II collagen in aging and osteoarthritis starts at the articular surface, originates around chondrocytes, and extends into the cartilage with progressive degeneration

Enhanced denaturation of type II collagen fibrils in femoral condylar cartilage in osteoarthritis (OA) has recently been quantitated immunochemically (Hollander, A.P., T.F. Heathfield, C. Webber, Y. Iwata, R. Bourne, C. Rorabeck, and A.R. Poole. 1994. J. Clin. Invest. 93:1722-1732). Using the same antibody that only reacts with denatured type II collagen, we investigated with immunoperoxidase histochemistry (results were graded for analysis) the sites of the denaturation (loss of triple helix) of this molecule in human aging (at autopsy, n= 11) and progressively degenerate (by Mankin grade [MG]) OA (at arthroplasty, n= 51) knee condylar cartilages. Up to 41 yr, most aging cartilages (3 of 4) (MG 0-4) showed very little denaturation. In most older cartilages, (4 of 7) (MG 2-4), staining was observed in the superficial and mid zones. This pattern of collagen II denaturation was also seen in all OA specimens with increased staining extending to the deep zone with increasing MG. Collagen II staining correlated directly both with MG and collagen II denaturation measured by immunoassay. Cartilage fibrillation occurred in OA cartilages with increased penetration of the staining for collagen II denaturation into the mid and deep zones and where denaturation was more pronounced by immunoassay. Thus in both aging and OA the first damage to type II collagen occurs in the superficial and upper mid zone (low MG) extending to the lower mid and deep zones with increasing degeneration (increasing MG). Initial damage is always seen around chondrocytes implicating them in the denaturation of type II collagen.     

Enhancement of SPARC (osteonectin) synthesis in arthritic cartilage. Increased levels in synovial fluids from patients with rheumatoid arthritis and regulation by growth factors and cytokines in chondrocyte cultures

OBJECTIVE: To investigate the roles of SPARC (secreted protein, acidic and rich in cysteine) (osteonectin) in arthritis, using cartilage and synovium specimens and synovial fluids (SF) from patients with rheumatoid arthritis (RA) or osteoarthritis (OA), and to examine the effects of cytokines, growth factors, and hormones on SPARC synthesis by chondrocytes in culture. METHODS: SPARC in cartilage and synovium was immunostained with monoclonal antibodies. SPARC synthesis by cultured chondrocytes was measured by Northern blot analysis, immunoblotting, and sandwich enzyme-linked immunosorbent assay. RESULTS: SPARC was identified in numerous chondrocytes in the superficial and middle zones and in regenerating chondrocytes of RA and OA joints, whereas such staining was absent in these zones of normal cartilage, except for weak signals from a few chondrocytes in the deep zone. In addition, SPARC synthesis was enhanced in synovial cells of RA and OA joints. The average SPARC level in SF was 10-fold higher in the RA than in the OA population. In rabbit articular chondrocyte cultures, administration of transforming growth factor beta 1 (TGF beta 1) and bone morphogenetic protein 2 increased SPARC levels at 24-48 hours, whereas interleukin-lbeta (IL-1 beta), IL-1 alpha, tumor necrosis factor alpha, lipopolysaccharide, phorbol myristate acetate, basic fibroblast growth factor, and dexamethasone decreased SPARC levels at 24-72 hours. TGF beta increased SPARC messenger RNA (mRNA) levels at 24 hours, whereas IL-1 beta caused a marked decrease in SPARC mRNA levels at 24 hours. Furthermore, IL-1 decreased the glycosylation of SPARC. CONCLUSION: These findings suggest that various growth factors and cytokines, including TGF beta 1 and IL-1 beta, regulate the production of SPARC by chondrocytes at pre- and posttranslational levels, and that SPARC synthesis is markedly enhanced in arthritic joints.     

Immunohistochemical findings type I and type II collagen in prenatal mouse mandibular condylar cartilage compared with the tibial anlage

In growing animals the mandibular condylar cartilage serves not only as an articular but also as a growth cartilage, yet, condylar cartilage has some characteristic features that are not found in growth cartilage. For example, some reports suggest that type I collagen, which is not seen in the growth plate cartilage of long bones, is present in the extracellular matrix of condylar cartilage postnatally. Here, the condylar and limb bud cartilage of fetal mice was examined. The distribution of type I and type II collagen in condylar cartilage was already different from that in the limb bud at the first appearance of the cartilage. Type I collagen was demonstrated in the extracellular matrix of the condylar cartilage that first appeared on day 15 of gestation. However, the reaction for type II collagen was much weaker than that for type I collagen. On day 18 of gestation, type I collagen was still found throughout the cell layers but became gradually weaker with depth. Type II collagen was limited exclusively to the deeper layers at this stage. These findings are different from those in the limb bud cartilage, indicating a characteristic feature of the cells in the condylar cartilage present from the prenatal period.     

Immunohistochemical study of extracellular matrices and elastic fibers in a human sternoclavicular joint

In this study, we clarified the distribution of elastic and oxytalan fibers in a human sternoclavicular joint (SCJ) using a color image system and in extracellular matrices using immunoperoxidase staining. Fine elastic fibers (EFs) were scattered in the fibrous layer of the sternoclavicular disk. This articular disk was composed of a collagenous bundle on the sternum side of the articular disk in the SCJ and cellular components including connective tissue on the clavicular side of the articular disk. The thickness of the disk gradually increased from the inferior to superior portion. Collagen fibers type I, III and V and other extracellular matrices (ECMs) were detected in the hypertrophic zone in the clavicular and sternum side of the SCJ and in the connective tissue of the articulatio condylar. On the cervical surface of the articular disk, cellular activity was higher than on the sternum surface.     

Expression of nerve growth factor and its high-affinity receptor Trk-A in the rat pancreas during embryonic and fetal life

We recently reported that nitric oxide (NO), which is produced by chondrocytes treated with interleukin-1beta (IL-1), releases basic fibroblast growth factor (bFGF) stored in the matrix of articular chondrocytes. To clarify the mechanism of the IL-1-induced bFGF release, we investigated the production and gene expression of bFGF, matrix metalloproteinases (MMPs), syndecan 3, and inducible NO synthase (iNOS) by IL-1-treated rabbit articular chondrocytes. IL-1 stimulated not only the release of bFGF but also the production of it. Gelatin and casein zymography revealed that IL-1 stimulated the production of not only MMP-9 but also MMP-3. The increase in the production of these MMPs preceded the IL-1-stimulated bFGF release. An MMP inhibitor partially suppressed the release of bFGF, indicating that matrix degradation is at least partially involved in the IL-1-stimulated bFGF release even if increased production of bFGF is related to the release. IL-1 sequentially stimulated mRNA expression of iNOS, membrane type 1-MMP, MMP-9 and -3, and bFGF, in that order. NG-Monomethyl-L-arginine, an inhibitor of NO production, inhibited gene expression of MMP-9 and bFGF. These findings suggest that elevation of the NO level via iNOS mRNA expression stimulated by IL-1 mediates gene expression and production of MMPs and bFGF, resulting in the release of bFGF, and also reveal molecular mechanisms implicating the degradation of articular cartilage followed by angiogenesis in the synovium in arthritic joints.     

Experimental studies of mechanically-induced articular cartilage defects following implantation of allogeneic embryonal chondrocytes in a collagen-fibrin gel in chickens

Full thickness defects (diameter 1,7 mm; depth 2,5 mm) were created mechanically in articular cartilage and subchondral bone of the condyles of tibiotarsal joints of 9-month old chickens. This full-thickness defects were repaired with cultured allogenic embryonic chick epiphyseal chondrocytes from the tibiae and femura of 10-days-old chicken embryos. The cells were embedded in a collagen-fibrinogen-matrix. Controls were similarly operated, but received either no treatment or implants the delivery substance only. Healing of the defects was observed macroscopically, histologically, histochemically and histomorphometrically after 3, 12 and 24 weeks. This graft was successfully transplanted in mechanically induced defects in 80%. The resulting hyaline cartilage was structurally reorganized according to the host pattern and under the influence of environmental conditions. The articular zone preserved it's cartilaginous phenotype, whereas the subchondral regions were transformed into bone. 12 weeks after the operation the defects in the experimental group were completely filled. In all instances in this group, there was an initial extreme increase of mitotic rate and cell number. After 24 weeks normal and subnormal values were founded. The defects in the control groups healed with fibrocartilage. Our results showed, that only the defects in the experimental group were completely filled with reparative hyaline cartilage tissue. In the present study the mixture of cultured allogenic embryonic chondrocytes and a collagen-fibrinogen-matrix was used successfully as a transplant for repairing defects in articular cartilage of chickens. Thus allogenic transplantation of cultured embryonal chondrocytes appears to be one of the most promising methods for the restoration of articular cartilage.     

Comparative studies on the effects of the combination drug lorazepam plus diphenhydramine (Somnium) versus lorazepam on the noopsyche, thymopsyche and psychophysiology in nonorganic insomnia related to generalized anxiety disorder

The immunohistochemical localization of type II and type I collagens was examined in the articular cartilage of the femoral head of growing rats injected systemically with 5 mg kg-1 dexamethasone for 2 weeks every other day. The intensities of immunostaining for type II collagen, measured by microphotometry, was highest in the flattened cell layer and high in the hypertrophic cell layer, moderate in the proliferative cell and transitional cell layers and low in the superficial layer. After dexamethasone administration, the intensities decreased markedly in the flattened cell layer and slightly in the hypertrophic cell layer, although the decreases in other layers were negligible. The staining intensities for type I collagen were highest in the flattened cell layer, low in the superficial and transitional cell layers and very low in the proliferative and hypertrophic cell layers. After dexamethasone administration, the intensities increased markedly in the flattened cell layer and slightly in the superficial and proliferative cell layers, but did not change in the transitional and hypertrophic cell layers. Thus, dexamethasone administration caused a decrease in type II collagen and an increase in type I collagen in the matrix of the surface portion of articular cartilage. The composition of isoforms of collagen in the matrix changed after the steroid administration. The results strongly that the shift in collagen composition from type II to type I predominance is a cause of the degeneration of the articular cartilage after glucocorticoid administration.     

Temporal expression of PTHrP during endochondral bone formation in mouse and intramembranous bone formation in an in vivo rabbit model

Expression of parathyroid hormone-related protein (PTHrP) messenger RNA (mRNA) and protein was investigated throughout the developmental progression of endochondral bone formation in mouse and intramembranous bone formation in an in vivo model in rabbit, using in situ hybridization and immunohistochemistry. Endochondral bone formation was investigated in a developing embryo, newborn, and adult mouse. In fetal long bones through to newborn (day 7), PTHrP mRNA and protein were consistently expressed in chondrocytes within the proliferative, transitional, and hypertrophic zones. In addition, high levels of PTHrP were also detected in osteoblasts on the surface of trabecular bone surfaces. Similarly, at the adult stage (week 7), PTHrP mRNA and protein were consistently expressed in chondrocytes at epiphyseal ends of the subarticular cartilage, within cortical periosteum, as well as in osteoblasts located at the metaphyseal trabecular bone surfaces. Using an in vivo intramembranous bone formation model in rabbits, expression of PTHrP mRNA and protein was demonstrated in preosteoblasts prior to trabecular bone formation (1-week bone harvest). As bone formed (2-, 3-, and 4-week bone tissue harvests), PTHrP mRNA and protein were highly expressed in actively synthesizing osteoblasts and in those osteocytes embedded within the superficial layers of the bone matrix. Lining osteoblasts and osteocytes buried deeply in the bone matrix displayed weak or no signal for PTHrP. The pattern of spatial and temporal expression of PTHrP demonstrated in cartilage cells and osteoblasts in the two systems suggests an important role of PTHrP in both endochondral and intramembranous bone formation.     

Laminin chain expression by chick chondrocytes and mouse cartilaginous tissues in vivo and in vitro

We have observed that laminins are expressed in the chondrocytes of chick embryo sternum, mouse limb bud, and adult mouse knee joint by the methods of in situ hybridization, immunohistochemistry, Western blotting, and immunoprecipitation. From in situ hybridization using similar sized RNA probes for different mouse laminin chains, mRNAs for the alpha 1, alpha 2, beta 1, beta 2, and gamma 1 chains were expressed in the chondrocytes of chick embryo sternum, mouse limb bud, and the articular cartilage cap and epiphyseal growth plate of adult mouse knee joint. Through the use of chain-specific antibodies, staining for laminins was observed in the cytoplasm of chondrocytes from chick embryo sternum, mouse limb bud, and adult mouse knee joint. Western blot analysis confirmed the presence of laminin chains in the cells and sternal tissues. Cultured chick embryonic sternal chondrocytes expressed laminin mRNAs in the proliferating stage (2-3 days of culture) but the level increased in the aggregated cells during the maturation stage (5-7 days of culture). Comparable data were also obtained after immunostaining the cells. Thus, laminins are expressed in significant amounts by chondrocytes and may have an important role in cartilage development.     

Compositional mapping of mouse chromosomes and identification of the gene-rich regions

The interleukin-1 (IL-1) cytokines stimulate the synthesis of degradative enzymes in joint tissues and may play a role in the pathological joint destruction in osteoarthritis (OA). In this study, we have used immunohistochemistry and Western blot analysis to identify IL-1 in human OA cartilage. IL-1 alpha and IL-1 beta were evident in chondrocytes at the articular surface, as well as distributed throughout the cartilage. In many specimens, IL-1 beta but not IL-1 alpha was detected as a diffuse staining of the extracellular matrix especially surrounding superficial zone chondrocytes. Although chondrocyte-associated IL-1 alpha and IL-1 beta were detected in most specimens, cartilages exhibiting early osteoarthritic changes had the highest intensity of staining and the highest frequency of positive cells. Western blot analysis revealed intense immunoreactive bands corresponding to the 35 kDa precursor form of IL-1 alpha in all four chondrocyte lysates tested. The processed 18 kDa IL-1 beta species was present in only one of four chondrocyte lysates, and there was no clear evidence of precursor form within these cells. The results of this study indicate increased IL-1 alpha in cartilage showing early degenerative changes, suggesting an autocrine/paracrine role for this cytokine in OA pathogenesis.