DNA-synthesis in degenerated and normal joint cartilage in full-grown rabbits

An In Vivo Stable Isotope Labeling Method to Investigate Individual Matrix Protein Synthesis, Ribosomal Biogenesis, and Cellular Proliferation in Murine Articular Cartilage

Targeting chondrocyte dynamics is a strategy for slowing osteoarthritis progression during aging. We describe a stable-isotope method using in vivo deuterium oxide labeling and mass spectrometry to measure protein concentration, protein half-life, cell proliferation, and ribosomal biogenesis in a single sample of murine articular cartilage. We hypothesized that a 60-d labeling period would capture age-related declines in cartilage matrix protein content, protein synthesis rates, and cellular proliferation. Knee cartilage was harvested to the subchondral bone from 25- to 90-wk-old female C57BL/6J mice treated with deuterium oxide for 15, 30, 45, and 60 d. We measured protein concentration and half-lives using targeted high resolution accurate mass spectrometry and d2ome data processing software. Deuterium enrichment was quantified in isolated DNA and RNA to measure cell proliferation and ribosomal biogenesis, respectively. Most collagen isoforms were less abundant in aged animals, with negligible collagen synthesis at either age. In contrast, age altered the concentration and half-lives of many proteoglycans and other matrix proteins, including several with greater concentration and half-lives in older mice such as proteoglycan 4, clusterin, and fibronectin-1. Cellular proteins were less abundant in older animals, consistent with reduced cellularity. Nevertheless, deuterium was maximally incorporated into 60% of DNA and RNA by 15 d of labeling in both age groups, suggesting the presence of two large pools of either rapidly (<15 d) or slowly (>60 d) proliferating cells. Our findings indicate that age-associated changes in cartilage matrix protein content and synthesis occur without detectable changes in the relative number of proliferating cells.

Proliferative remodeling of the spatial organization of human superficial chondrocytes distant from focal early osteoarthritis

OBJECTIVE

Human superficial chondrocytes show distinct spatial organizations, and they commonly aggregate near osteoarthritic (OA) fissures. The aim of this study was to determine whether remodeling or destruction of the spatial chondrocyte organization might occur at a distance from focal (early) lesions in patients with OA.

METHODS

Samples of intact cartilage (condyles, patellofemoral groove, and proximal tibia) lying distant from focal lesions of OA in grade 2 joints were compared with location-matched nondegenerative (grade 0-1) cartilage samples. Chondrocyte nuclei were stained with propidium iodide, examined by fluorescence microscopy, and the findings were recorded in a top-down view. Chondrocyte arrangements were tested for randomness or significant grouping via point pattern analyses (Clark and Evans Aggregation Index) and were correlated with the OA grade and the surface cell densities.

RESULTS

In grade 2 cartilage samples, superficial chondrocytes were situated in horizontal patterns, such as strings, clusters, pairs, and singles, comparable to the patterns in nondegenerative cartilage. In intact cartilage samples from grade 2 joints, the spatial organization included a novel pattern, consisting of chondrocytes that were aligned in 2 parallel lines, building double strings. These double strings correlated significantly with an increased number of chondrocytes per group and an increased corresponding superficial zone cell density. They were observed in all grade 2 condyles and some grade 2 tibiae, but never in grade 0-1 cartilage.

CONCLUSION

This study is the first to identify a distinct spatial reorganization of human superficial chondrocytes in response to distant early OA lesions, suggesting that proliferation had occurred distant from focal early OA lesions. This spatial reorganization may serve to recruit metabolically active units as an attempt to repair focal damage.

Use of microscopical techniques in the study of human chondrocytes from osteoarthritic cartilage: an overview

Several microscopical techniques, such as high resolution light microscopy, Normaski microscopy, laser confocal and transmission electron microscopy, were used in a correlative morphological study of human osteoarthritic (OA) cartilage. Emphasis was made on the characterization of chondrocytes heterogeneity observed in this tissue. Novel findings were assessed in the morphological and immunocytological study of the chondrocytes organized in aggregates or "clones" typical of this degenerative disease, consisting of the modification of certain elements of the cytoskeleton that influence changes in the cell shape. Also, the presence of cilia and centrioles found in certain cell raised the question if chondrocytes are able to move and regroup as an alternative mechanism to mitosis in the formation of cell clusters or "clones." The presence of two types of secretory chondrocytes was observed and discussed. The use of a correlative approach of several microscopical techniques in a systematic morphological and immunocytological characterization of chondrocyte population within the fibrillated and nonfibrillated human osteoarthritic cartilage gave complementary information that could be important for a better understanding of the histopathogenesis of OA.

Ultrastructural study of chondrocytes from fibrillated and non-fibrillated human osteoarthritic cartilage

Knee articular cartilage samples obtained by arthroscopy from ten patients with well defined knee osteoarthritis (OA) were studied by light and transmission electron microscopy. The morphological phenotype of cells from fibrillated and non-fibrillated regions of OA cartilage was characterized. Three different cell sub-populations were identified. Type 1 cells were found in the superficial and upper middle zones and comprised single chondrocytes and cells organized in aggregates or "clones' that showed a typical chondrocyte phenotype. Type 2 cells displayed a secretory phenotype. Type 3 cells comprised chondrocytes undergoing a degenerative process and were distributed throughout all zones of the cartilage. Changes in the cytoskeletal arrangement, presence of abundant filopodia, peripheral localization of centrioles, and presence of primary cilia were found in many chondrocytes suggesting that they are active motile cells. No mitotic figures were found in this study. Morphometrical analysis was performed to determine the total number of cells and the number of chondrocytes per lacuna in the superficial and upper middle zones of fibrillated and non-fibrillated OA cartilage. There were no statistically significant differences in the total number of cells. In contrast, fibrillated OA cartilage contained a statistically significantly higher percentage of lacunae containing four of more chondrocytes than non-fibrillated OA cartilage samples. The absence of mitotic figures and the presence of motile elements in many chondrocytes raise the possibility that cell aggregates or "clones' in damaged OA cartilage originate by an active process of cell migration rather than by cellular division.

Skeletal development and osteoarthritis

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Chondrons from articular cartilage. III. Morphologic changes in the cellular microenvironment of chondrons isolated from osteoarthritic cartilage

Chondrons were isolated from human and canine osteoarthritic cartilage using low-speed homogenization techniques. Changes in chondron morphology were evaluated using differential interference-contrast microscopy, phase-contrast microscopy, and histochemical and ultrastructural methods. Chondrocyte viability was assessed using fluorescein diacetate staining, and chondron metabolism was investigated using autoradiography. The results suggest that initial changes in the collagen and proteoglycan distribution within the chondron are followed by chondrocyte proliferation to form clusters. These techniques offer the potential to study cell matrix interactions in degenerative osteoarthritis.

Magnetic resonance imaging of knee hyaline cartilage and intraarticular pathology

Injuries to the hyaline cartilage of the knee joint are difficult to diagnose without invasive techniques. Even though these defects may be the most important prognostic factors in assessing knee joint injury, they are usually not diagnosed until arthrotomy or arthroscopy. Once injuries to hyaline cartilage are found and/or treated, no technique exists to follow these over time. Plain radiographs, arthrograms, and even computed tomography fail to detail most hyaline cartilage defects. We used magnetic resonance imaging (MRI) to evaluate five fresh frozen cadaver limbs and 10 patients whose pathology was known from arthrotomy or arthroscopic examination. Using a 0.35 Tesla superconducting magnet and spin-echo imaging technique with a head coil, we found that intraarticular fluid or air helped to delineate hyaline cartilage pathology. The multiplane capability of MRI proved to be excellent in detailing small (3 mm or more) defects on the femoral condyles and patellar surface. Cruciate ligaments were best visualized on sagittal oblique projections while meniscal pathology was best seen on true sagittal and coronal projections. MRI shows great promise in providing a noninvasive technique of evaluating hyaline cartilage defects, their response to treatment, and detailed anatomical information about cruciate ligaments and menisci.

Papain-induced mitosis of chondrocytes in adult joint cartilage: an experimental study in full-grown rabbits

When diluted papain is injected intra-articularly into the knee joints of adult rabbits, slowing progressing, degenerative changes develop in the articular cartilage. After intravenous injection of crude papain no significant degenerative changes are found. With the aid of radioactive thymidine, it is possible to demonstrate that the chondrocytes recover their ability to divide before any degenerative changes can be found. At the same time the matrix loses its staining properties with Safranin-O and toluidine blue.

Papain-induced changes in the knee joints of adult rabbits

Rapidly progressing joint disease can be produced in the rabbit by intra-articular injection of concentrated papain. With the use of radioactive thymidine it is possible to demonstrate that the cartilage cells recover their ability to divide by mitosis at the same time as degenerative changes appear in the cartilage. Clusters of chondrocytes arise by mitosis of chondrocytes and not by a floating together of cartilage cells.

The effect of osteotomy and cartilage damage on mitotic activity. An experimental study in rabbits

In 15 rabbits, osteotomy and osteotomy including cartilage damage were performed. With autoradiography (3H-thymidine) it was shown that only one knee in the osteotomy group had labeled chondrocytes in the tibial cartilage. In the knees with articular damage, labeled chondrocytes were found in the femur as well, which could be the result of a factor liberated from the damaged cartilage, a factor stimulating mitotic activity.

Chondrocyte mitosis in the articular cartilage of femoral heads with various diseases

Autoradiographic studies using thymidine-3H reveal the mitosis of chondrocytes in degenerated joints, i.e. joints having secondary osteoarthritis or aseptic necrosis of the femoral head. The findings obtained provide additional support for the recent investigations regarding chondrocyte mitosis in primary osteoarthritic cartilage. Histologic and histochemical examinations suggest that a loss of glycosaminoglycans in the matrix is evidence for conversion of chondrocyte activity to mitosis which occurs, however, within the limit of "the point of irreversibility", analogous to the observations from the biochemical point of view. Biomechanical and nutritional factors are also discussed in relation to the results obtained from cartilages of the femoral heads in cases of femoral neck fracture and aseptic necrosis of the femoral head.

Nucleic acids in articular cartilage from rabbits of different ages

The joint cartilage of immature, adult and old rabbits was examined. The joint cartilage in adult and old rabbits contained less nucleic acids than that in young rabbits. The synthesis of DNA decreases with advancing age, while no difference was found in the concentration of nucleic acids between adult and old rabbits.