AnatomyOrganismsDiseasesChemicals and DrugsPhenomena and Processes
Collagen Type XChondrogenesisCartilageChondrocytesCollagenCollagen Type ICollagen Type IIICollagen Type IICollagen Type IVCollagen Type VFibrillar CollagensCollagen Type VICollagen Type XIGrowth PlateExtracellular MatrixReceptors, CollagenExtracellular Matrix ProteinsProcollagenCells, CulturedCollagen Type XVIIIChick EmbryoHydroxyprolineCartilage, ArticularOsteochondrodysplasiasFibroblastsCollagen Type XIIFibronectinsBasement MembranePepsin AProteoglycansSternumMicrobial CollagenaseLamininRNA, MessengerCollagen DiseasesHypertrophyCattleDecorinCollagen Type IXFibrosisAggrecansCalcification, PhysiologicCollagenasesSkinAminopropionitrile

Competency for nonsense-mediated reduction in collagen X mRNA is specified by the 3' UTR and corresponds to the position of mutations in Schmid metaphyseal chondrodysplasia. (65/149)

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Endochondral ossification signals in cartilage degradation during osteoarthritis progression in experimental mouse models. (66/149)

Osteoarthritis (OA), one of the most common skeletal disorders characterized by cartilage degradation and osteophyte formation in joints, is induced by accumulated mechanical stress; however, little is known about the underlying molecular mechanism. Several experimental OA models in mice by producing instability in the knee joints have been developed to apply approaches from mouse genetics. Although proteinases like matrix metalloproteinases and aggrecanases have now been proven to be the principal initiators of OA progression, clinical trials of proteinase inhibitors have not been successful for the treatment, turning the interest of researchers to the upstream signals of proteinase induction. These signals include undegraded and fragmented matrix proteins like type II collagen or fibronection that affects chondrocytes through distinct receptors. Another signal is pro-inflammatory factors that are produced by chondrocytes and synovial cells; however, recent studies that used mouse OA models in knockout mice did not support that these factors have a role in the central contribution to OA development. Our mouse genetic approaches found that the induction of a transcriptional activator Runx2 in chondrocytes under mechanical stress contributes to the pathogenesis of OA through chondrocyte hypertrophy. In addition, chondrocyte apoptosis has recently been identified as being involved in OA progression. We hereby propose that these endochondral ossification signals may be important for the OA progression, suggesting that the related molecules can clinically be therapeutic targets of this disease.  (+info)

Genetic variation in the patterns of skeletal progenitor cell differentiation and progression during endochondral bone formation affects the rate of fracture healing. (67/149)

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Upregulation of Runx2 and Osterix during in vitro chondrogenesis of human adipose-derived stromal cells. (68/149)

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Phosphorylation of GSK-3beta by cGMP-dependent protein kinase II promotes hypertrophic differentiation of murine chondrocytes. (69/149)

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Altered endochondral ossification in collagen X mouse models leads to impaired immune responses. (70/149)

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Cbfa1-dependent expression of an interferon-inducible p204 protein is required for chondrocyte differentiation. (71/149)

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Activating transcription factor-2 affects skeletal growth by modulating pRb gene expression. (72/149)

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