Effects of Vitamin D Supplementation during the Induction and Progression of Osteoarthritis in a Rat Model.

Epidemiological studies correlate low levels of vitamin D with the osteoarthritis (OA) progression. Cytokines and metalloproteases play a major role in OA promoting the inflammation and degradation of the cartilage and can be induced through the Toll-like receptor (TLR) pathway. The aim of this study was to evaluate the protective effect of vitamin D supplementation on the development of osteoarthritis (OA) through examining the genetic regulation of TLRs, cytokines, and metalloproteases in chondrocytes as well as the wideness of cartilage in rats with OA. Our results demonstrate that the signaling through TLR-4 is a proinflammatory mechanism in osteoarthritis that drives the upregulation of MMP-3, IL-1ß, and TNF-α gene expression, leading to cartilage degradation and inflammation. Vitamin D supplementation had a protective effect during the onset but not during the chronic stage of OA in the rat model.

Cell death of chondrocytes is a combination between apoptosis and autophagy during the pathogenesis of Osteoarthritis within an experimental model.

The death of chondrocytes and the loss of extracellular matrix are the central features in cartilage degeneration during Osteoarthritis (OA) pathogenesis. The mechanism by which chondrocytes are removed in OA cartilage are still not totally defined, although previous reports support the presence of apoptotic as well as non apoptotic signals. In addition, in 2004 Roach and co-workers suggested the term "Chondroptosis" to design the type of cell death present in articular cartilage, which include the presence of some apoptotic and autophagic processes. To identify the mechanisms, as well as the chronology by which chondrocytes are eliminated during OA pathogenesis, we decided to evaluate apoptosis (by active caspase 3 and TUNEL signal) and autophagy (by LC3II molecule and cytoplasmic vacuolization) using Immunohistochemistry and Western blot techniques in an animal OA model. During OA pathogenesis, chondrocytes exhibit modifications in their death process in each zone of the cartilage. At early stages of OA, the death of chondrocytes starts with apoptosis in the superficial and part of the middle zones of the cartilage, probably as a consequence of a constant mechanical damage in the joint. As the degenerative process progresses, high incidence of active caspase 3 as well as LC3II expression are observed in the same cell, which indicate a combination of both death processes. In contrast, in the deep zone, due the abnormal subchondral bone ossification during the OA pathogenesis, apoptosis is the only mechanism observed.

Prolactin inhibits the apoptosis of chondrocytes induced by serum starvation.

The apoptosis of chondrocytes plays an important role in endochondral bone formation and in cartilage degradation during aging and disease. Prolactin (PRL) is produced in chondrocytes and is known to promote the survival of various cell types. Here we show that articular chondrocytes from rat postpubescent and adult cartilage express the long form of the PRL receptor as revealed by immunohistochemistry of cartilage sections and by RT-PCR and Western blot analyses of the isolated chondrocytes. Furthermore, we demonstrate that PRL inhibits the apoptosis of these same chondrocytes cultured in low-serum. Chondrocyte apoptosis was measured by hypodiploid DNA content determined by flow cytometry and by DNA fragmentation evaluated by the ELISA and the TUNEL methods. The anti-apoptotic effect of PRL was dose-dependent and was prevented by heat inactivation. These data demonstrate that PRL can act as a survival factor for chondrocytes and that it has potential preventive and therapeutic value in arthropathies characterized by cartilage degradation.

Do chondrocytes undergo "activation" and "transdifferentiation" during the pathogenesis of osteoarthritis? A review of the ultrastructural and immunohistochemical evidence.

Chondrocytes, which are the only cell type in the articular cartilage, show substantial morphological and functional differences, depending on their location within the tissue. In OA cartilage, outstanding modifications have been reported concerning their structure and functions. Based on the principle that both structure and function run in a parallel manner, new concepts are arising related to morphological observations. Observations on OA chondrocytes, such as cytoskeleton disruption, development of the secretory machinery (rough endoplasmic reticulum and Golgi complex), and cell death by apoptosis, among others, certainly must be related to the role of chondrocytes in OA pathogenesis. In this degradative process, it has been acknowledged that cell death, matrix degradation and subchondral bone remodelling are the main causes of cartilage breakdown in osteoarthritis. The aim of this review was to correlate and integrate in a logical manner the modifications of chondrocytes with cartilage breakdown during osteoarthritis pathogenesis. Furthermore, we intend to open a debate on cell cycle and mitosis, as well as on signalling molecules that might be involved in the morphofunctional changes in OA chondrocytes, which we propose to name "activation" and "transdifferentiation" of chondrocytes. We expect this analysis to be useful for studying OA pathogenesis in depth, with the aim of finding new strategies for the early diagnosis and therapeutic procedures for this invalidating disease, which is already an important public health problem.

Chondroptosis: an immunohistochemical study of apoptosis and Golgi complex in chondrocytes from human osteoarthritic cartilage.

The Golgi complex is thought to play an important role in the apoptotic process of osteoarthritic (OA) chondrocytes. However, the exact relationship between modifications of the Golgi complex and apoptosis in human OA cartilage requires to be established. We compared the patterns and immunolabeling intensities for anti-Golgi 58 K protein with apoptosis markers such as TUNEL and caspase-2L in OA cartilage removed from patients during knee total replacement surgery. We observed important modifications in labeling of the Golgi 58 K protein in OA chondrocytes compared with normal cell. Immunohistochemical analysis revealed co-localization between 58 K protein and caspase-2L, suggesting that this enzyme was localized in Golgi complex of OA chondrocytes. In addition, these cells labeled positive with the TUNEL technique, but in different proportions to caspase-2L. Our results support the concept, previously reported, that apoptosis in OA cartilage (chondroptosis) might be a variant of the classical apoptosis.

Cytoskeleton disruption in chondrocytes from a rat osteoarthrosic (OA) -induced model: its potential role in OA pathogenesis.

Morphological and functional changes of chondrocytes are typical in OA cartilage. In this work, we have described noteworthy changes in intermediate filaments cytoskeleton evidenced by transmission electron microscopy. Alterations in the distribution as well as in the content of vimentin, actin, and tubulin have been described by specific fluorescence labelling of each cytoskeletal component and confocal analysis. Normal vs OA cartilages showed a reduction in the percentage of labelled chondrocytes of 37.1% for vimentin, 4.7% for actin, and 20.1% for tubulin. Statistical analysis of fluorescence intensities (mean % +/- SEM) between normal and OA rat cartilage revealed a highly significant difference in vimentin, a significant difference in tubulin, and a non-significant difference in actin. Moreover, by western blot, altered electrophoretic patterns were observed mainly for vimentin and tubulin in OA cartilage in comparison with normal cartilage. These results allow us to suggest that substantial changes in vimentin and tubulin cytoskeleton of chondrocytes might be involved in OA pathogenesis.

Chondroptosis: a variant of apoptotic cell death in chondrocytes?

Evidence has accumulated in recent years that programmed cell death (PCD) is not necessarily synonymous with the classical apoptosis, as defined by Kerr and Wyllie, but that cells use a variety of pathways to undergo cell death, which are reflected by different morphologies. Although chondrocytes with the hallmark features of classical apoptosis have been demonstrated in culture, such cells are extremely rare in vivo. The present review focuses on the morphological differences between dying chondrocytes and classical apoptotic cells. We propose the term 'chondroptosis' to reflect the fact that such cells are undergoing apoptosis in a non-classical manner that appears to be typical of programmed chondrocyte death in vivo. Unlike classical apoptosis, chondroptosis involves an initial increase in the endoplasmic reticulum and Golgi apparatus, reflecting an increase in protein synthesis. The increased ER membranes also segment the cytoplasm and provide compartments within which cytoplasm and organelles are digested. In addition, destruction occurs within autophagic vacuoles and cell remnants are blebbed into the lacunae. Together these processes lead to complete self-destruction of the chondrocyte as evidenced by the presence of empty lacunae. It is speculated that the endoplasmic reticulum pathway of apoptosis plays a greater role in chondroptosis than receptor-mediated or mitochondrial pathways and that lysosomal proteases are at least as important as caspases. Because chondroptosis does not depend on phagocytosis, it may be more advantageous in vivo, where chondrocytes are isolated within their lacunae. At present the initiation factors or the molecular pathways involved in chondroptosis remain unclear.

Apoptotic chondrocytes from osteoarthrotic human articular cartilage and abnormal calcification of subchondral bone.

OBJECTIVE: Osteoarthrosis (OA) is accompanied by altered subchondral bone remodeling. We investigated the role of chondrocytes in the mechanism of abnormal cartilage calcification. METHODS: Knee articular cartilage samples from OA and normal tissue were studied. Macroscopic and microscopic observations, alkaline phosphatase staining for light and electron microscopy (bright and dark fields). TUNEL technique, electron diffraction, and x-ray microanalyses were performed. RESULTS: Chondrocytes from patients displayed a morphology of apoptosis and showed abundant alkaline phosphatase (ALP)-rich matrix vesicles (MV) budding from the plasma membrane with hydroxyapatite microcrystals on their surface. Farther from the cells, hydroxyapatite crystals were detected on the MV surface and increased as they approached the subchondral bone. The concentration of Ca and P and their ratio increased inside the ALP-rich MV in relation to the proximity to subchondral bone. In the OA subchondral bone the ratio Ca/P varied from 3.936 to 0.974. In normal tissue the ratio was very homogeneous (maximum 1.973, minimum 1.781). CONCLUSION: In situ, apoptotic chondrocytes correlate with factors known to be involved in the calcification of the extracellular matrix. This suggests that apoptosis is involved in the abnormal calcification of OA cartilage, and consequently in the altered remodeling of the subchondral bone.

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.

Variability in the cell phenotype of aggregates or "clones" of human osteoarthritic cartilage. A case report.

Human samples of articular cartilage from the knee of a clinically classified osteoarthritic patient, assessed by arthroscopy as part of the surgical treatment was studied by light and transmission electron microscopy. This particular case differed from others already reported in the variability of cell phenotype within the aggregates or "clones" frequently present in the osteoarthritic cartilage. The most common morphology of "clonal" cells forming the aggregates were large and rounded with an euchromatic nucleus. The cytoplasm was characterized by the presence of alternately clear and dense sites. At the ultrastructural level it was seen that the clear sites were formed by disrupted intermediates filaments and small particles, and that the dense sites were constituted by the segregation of different organelles of the chondrocytes. In addition, there were atypical aggregates composed only by secretory cells or by degenerating chondrocytes. Furthermore, a complex structure consisting of a very large cell inside a giant lacunae delimited by electron-dense material with small vesicles is described as a novel finding. The variability in the chondrocyte phenotype of the aggregates described here could be an indication of a better prognosis; nevertheless, the follow-up of the evolution of this patient is needed in order to know the final outcome.

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.