Razvan L. Miclea scite author profile

In adult articular cartilage, the extracellular matrix is maintained by a balance between the degradation and the synthesis of matrix components. Chondrocytes that sparsely reside in the matrix and rarely proliferate are the key cellular mediators for cartilage homeostasis. There are indications for the involvement of the WNT signaling pathway in maintaining articular cartilage. Various WNTs are involved in the subsequent stages of chondrocyte differentiation during development, and deregulation of WNT signaling was observed in cartilage degeneration. Even though gene expression and protein synthesis can be activated upon injury, articular cartilage has a limited ability of self-repair and efforts to regenerate articular cartilage have so far not been successful. Because WNT signaling was found to be involved in the development and maintenance of cartilage as well as in the degeneration of cartilage, interfering with this pathway might contribute to improving cartilage regeneration. However, most of the studies on elucidating the role of WNT signaling in these processes were conducted using in vitro or in vivo animal models. Discrepancies have been found in the role of WNT signaling between chondrocytes of mouse and human origin, and extrapolation of results from mouse models to the human situation remains a challenge. Elucidation of detailed WNT signaling functions will provide knowledge to improve cartilage regeneration.

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Adenomatous polyposis coli-mediated control of β-catenin is essential for both chondrogenic and osteogenic differentiation of skeletal precursors

Miclea

Karperien

Bosch³

et al. 2009

BMC Dev Biol

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Primary chondrocytes enhance cartilage tissue formation upon co-culture with a range of cell types

et al. 2010

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Co-culture models have been increasingly used in tissue engineering applications to understand cell-cell interactions and consequently improve regenerative medicine strategies. Aiming at further elucidating cartilage tissue formation, we co-cultured bovine primary chondrocytes (BPCs) with human expanded chondrocytes (HECs), human dermal fibroblasts (HDFs), mouse embryonic stem cells (MESCs), or mouse-3T3 feeder cells (M3T3s) in micromasses. BPCs were either co-cultured (1 : 5 ratio) with all cell types allowing direct cell-cell contacts or as separate micromasses in the same well with HECs. In co-culture groups with direct cell-cell contacts cartilaginous tissue was formed in all experimental groups. In situ hybridization showed that only 16-27% of the cells expressed type II collagen mRNA. Corresponding with the fact that micromasses consisted for approximately 20% only of BPCs, the amount of GAG was similar between 100% BPC micromass and the co-culture groups with HECs and HDFs. Therefore, co-culture micromasses support cartilage tissue formation predominantly originating from primary chondrocytes in direct contact with a variety of cell types. These findings potentially could be applied to optimize cell-therapy treatments for cartilage regeneration.

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Novel Early Target Genes of Parathyroid Hormone-Related Peptide in Chondrocytes

Hoogendam

Parlevliet

Miclea

et al. 2006

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We have performed microarray analysis to identify PTHrP target genes in chondrocytes. ATDC5 cells were cultured as micromasses to induce chondrocyte differentiation. On d 8 of culture, the cells had a prehypertrophic appearance. This time point was chosen for isolation of RNA at 0, 1, 2, and 4 h after a challenge with 10(-7) M PTHrP. Samples were subjected to a cDNA microarray using competition hybridization. A list of 12 genes (P < 10(-3)), the expression regulation of which by PTHrP was confirmed by quantitative PCR analysis, was generated. This included seven up-regulated and five down-regulated genes. Three genes were known to be involved in PTHrP regulation, and six were previously found in growth plate chondrocytes. Most of the genes (10 of 12) were implicated in signal transduction and regulation. PTHrP also induced expression of the up-regulated genes in KS483 osteoblasts, suggesting involvement in a more generalized response to PTHrP. The vast majority of the up-regulated genes (six of seven) contained cAMP response element-binding protein- and/or activating protein-1 transcription factor-binding sites in their promoter regions. Remarkably, a number of PTHrP-regulated genes contained signal transducer and activator of transcription factor (Stat)-binding sites in their promoters. In transient transfection assays, we show that PTHrP is able to positively regulate the activity of Stat3-specific and negatively regulate the activity of Stat5-specific promoter-reporter constructs in ATDC5 and UMR106 cells. In combination with the expression regulation of genes involved in Janus kinase/Stat signaling, this data suggest a previously unrecognized interaction between PTHrP and Janus kinase/Stat signaling.

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Razvan L. Miclea

Inhibition of Gsk3β in cartilage induces osteoarthritic features through activation of the canonical Wnt signaling pathway

WNT Signaling and Cartilage: Of Mice and Men

Adenomatous polyposis coli-mediated control of β-catenin is essential for both chondrogenic and osteogenic differentiation of skeletal precursors

Primary chondrocytes enhance cartilage tissue formation upon co-culture with a range of cell types

Novel Early Target Genes of Parathyroid Hormone-Related Peptide in Chondrocytes

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