Mechanical Regulation of Mitogen-activated Protein Kinase Signaling in Articular Cartilage

Fanning, Paul; Emkey, Gregory R.; Smith, Robert J.; Grodzinsky, Alan J.; Szász, Nóra; Trippel, Stephen B.

doi:10.1074/jbc.m305107200

Cited by 119 publications

(96 citation statements)

References 50 publications

(59 reference statements)

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“…The recent studies found that p38 and ERK MAPK pathways were involved in TGF-ß1-induced chondrogenesis of ATDC5 cells [54,55], whereas Sox9 induction by fibroblast growth factors in chondrocytes and undifferentiated mesenchymal cells was mediated by the ERK MAPK pathway [56]. Moreover, it was recently demonstrated that the MAPK signal pathway was activated in cartilage by static compressive loading with a rapid induction of ERK and p38 MAPK pathways and a delayed stimulation of SAPK/JNK MAPK pathway [57]. Therefore, three major MAPK pathways could be activated in BM-MSCs by dynamic compressive loading.…”

Section: Discussionmentioning

confidence: 99%

Temporal Expression Patterns and Corresponding Protein Inductions of Early Responsive Genes in Rabbit Bone Marrow–Derived Mesenchymal Stem Cells Under Cyclic Compressive Loading

2005

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Our recent study suggested that cyclic compressive loading may promote chondrogenesis of rabbit bone-marrow mesenchymal stem cells (BM-MSCs) in agarose cultures through the transforming growth factor (TGF)-β signaling pathway. It has been shown that the activating protein 1 (AP-1) (JunFos) complex mediated autoinduction of TGF-ß1 and its binding activity was essential for promoting chondrogenesis of mesenchymal cells, whereas Sox9 was identified as an essential transcription factor for chondrogenesis of embryonic mesenchymal cells. The objective of this study was to examine temporal expression patterns of early responsive genes (Sox9, c-Fos, c-Jun, and TGF-ß type Ι and II receptors) and induction of their corresponding proteins in agarose culture of rabbit BM-MSCs subjected to cyclic compressive loading. The rabbit BM-MSCs were obtained from the tibias and femurs of New Zealand White rabbits. Cell-agarose constructs were made by suspending BM-MSCs in 2% agarose gel (10 7 cells/ml) for cyclic, unconfined compression tests performed in a custommade bioreactor. In the loading experiment, specimens were subjected to sinusoidal loading with a magnitude of 15% strain at a frequency of 1 hertz for 4 hours per day. Experiments were conducted for 2 consecutive days. This study showed that cyclic compressive loading promoted gene expressions of Sox9, cJun, and both TGF-ß receptors and productions of their corresponding proteins, whereas those gene expressions exhibited different temporal expression patterns among genes and between 2 days of testing. The gene expression of c-Fos was detected only in the samples subjected to 1-hour dynamic compressive loading. These findings suggest that the TGF-ß signal transduction and activities of AP-1 and Sox9 are involved in the early stage of BM-MSC chondrogenesis promoted by dynamic compressive loading.

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Section: Discussionmentioning

confidence: 99%

Temporal Expression Patterns and Corresponding Protein Inductions of Early Responsive Genes in Rabbit Bone Marrow–Derived Mesenchymal Stem Cells Under Cyclic Compressive Loading

2005

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“…For example, the milder stimulation of c-Fos and c-Jun (Group M3) in response to the dynamic loading compared with static loading may be related to the lower amplitude of the initial deformation applied to the cartilage in dynamic loading. c-Fos and c-Jun are downstream of the mitogen-activated protein kinases (39), which have been identified as mechanically sensitive to static compression (40,41). Extracellular signal-regulated kinases 1 and 2 become maximally phosphorylated within 10 min of application of a 50% static compression, indicating an immediate response to the changing environmental conditions (40).…”

Section: Discussionmentioning

confidence: 99%

Shear and Compression Differentially Regulate Clusters of Functionally Related Temporal Transcription Patterns in Cartilage Tissue

Fitzgerald

Jin

Grodzinsky

2006

Journal of Biological Chemistry

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102

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Chondrocytes are subjected to a variety of biophysical forces and flows during physiological joint loading, including mechanical deformation, fluid flow, hydrostatic pressure, and streaming potentials; however, the role of these physical stimuli in regulating chondrocyte behavior is still being elucidated. To isolate the effects of these forces, we subjected intact cartilage explants to 1-24 h of continuous dynamic compression or dynamic shear loading at 0.1 Hz. We then measured the transcription levels of 25 genes known to be involved in cartilage homeostasis using real-time PCR and compared the gene expression profiles obtained from dynamic compression, dynamic shear, and our recent results on static compression amplitude and duration. Using clustering analysis, we determined that transcripts for proteins with similar function had correlated responses to loading. However, the temporal expression patterns were strongly dependent on the type of loading applied. Most matrix proteins were up-regulated by 24 h of dynamic compression or dynamic shear, but down-regulated by 24 h of 50% static compression, suggesting that cyclic matrix deformation is a key stimulator of matrix protein expression. Most matrix proteases were up-regulated by 24 h under all loading types. Transcription factors c-Fos and c-Jun maximally responded within 1 h to all loading types. Pre-incubating cartilage explants with either a chelator of intracellular calcium or an inhibitor of the cyclic AMP pathway demonstrated the involvement of both pathways in transcription induced by dynamic loading.Mechanical forces within synovial joints are known to influence the metabolic behavior of chondrocytes, the sole cell type of cartilage (1-3). Chondrocytes are responsible for the maintenance and turnover of the cartilage extracellular matrix, in particular the biosynthesis of type II collagen and proteoglycan (aggrecan), which in combination provide the tensile, shear, and compressive stiffness of cartilage. Cartilage thickness and proteoglycan content were found to be enhanced in load-bearing areas in vivo (4). Joint inactivity (1, 2) and injury (5) have been found to promote degradation of the extracellular matrix and to reduce cartilage load bearing capacity. The exact mechanisms by which mechanical forces influence the biological activity of chondrocytes are under intense study. In addition, the precise component(s) of the physical stimuli that induce such biological changes following joint movement are not known.The effects of mechanical loading on cartilage in vivo have been studied using intact human and animal cartilage explants in vitro to determine the precise biophysical forces and physicochemical changes that result (for reviews, see Refs. 6 and 7

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“…Intracellular calcium release, cAMP, and the phospholipase C pathway have been implicated for aggrecan gene up-regulation in response to static compression in cartilage explants (25). Static compression also increased ERK1/2 phosphorylation within minutes of application, with sustained increases during 24 h of compression (26). Although such signaling pathways have been identified in the mechanical regulation of aggrecan gene expression, less is known about chondrocyte gene expression patterns of other ECM-related molecules or whether common upstream signaling pathways are responsible for their regulation.…”

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confidence: 99%

Mechanical Compression of Cartilage Explants Induces Multiple Time-dependent Gene Expression Patterns and Involves Intracellular Calcium and Cyclic AMP

Fitzgerald

Jin

Dean

et al. 2004

Journal of Biological Chemistry

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223

184

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Chondrocytes are influenced by mechanical forces to remodel cartilage extracellular matrix. Previous studies have demonstrated the effects of mechanical forces on changes in biosynthesis and mRNA levels of particular extracellular matrix molecules, and have identified certain signaling pathways that may be involved. However, the broad extent and kinetics of mechano-regulation of gene transcription has not been studied in depth. We applied static compressive strains to bovine cartilage explants for periods between 1 and 24 h and measured the response of 28 genes using real time PCR. Compression time courses were also performed in the presence of an intracellular calcium chelator or an inhibitor of cyclic AMP-activated protein kinase A. Cluster analysis of the data revealed four main expression patterns: two groups containing either transiently up-regulated or duration-enhanced expression profiles could each be subdivided into genes that did or did not require intracellular calcium release and cyclic AMP-activated protein kinase A for their mechano-regulation. Transcription levels for aggrecan, type II collagen, and link protein were up-regulated ϳ2-3-fold during the first 8 h of 50% compression and subsequently down-regulated to levels below that of free-swelling controls by 24 h. Transcription levels of matrix metalloproteinases-3, -9, and -13, aggrecanase-1, and the matrix protease regulator cyclooxygenase-2 increased with the duration of 50% compression 2-16-fold by 24 h. Thus, transcription of proteins involved in matrix remodeling and catabolism dominated over anabolic matrix proteins as the duration of static compression increased. Immediate early genes c-fos and c-jun were dramatically up-regulated 6 -30-fold, respectively, during the first 8 h of 50% compression and remained up-regulated after 24 h. Articular cartilage is responsible for the smooth articulation of synovial joints during locomotion. Chondrocytes within cartilage constantly remodel the extracellular matrix (ECM) 1 of the tissue throughout life. The major load-bearing constituents of the ECM are type II collagen and aggregates of the proteoglycan, aggrecan, which provide the tensile and compressive stiffness of the tissue, respectively. Also present in the ECM are families of matrix proteinases, tissue inhibitors of matrix metalloproteinases (TIMPs), growth factors, and cytokines that together regulate ECM remodeling and turnover in health and disease (1). It is known that mechanical exercise of the knee joint in vivo increases the density of aggrecan in cartilage (2), whereas knee joint inactivity results in decreased aggrecan deposition (3, 4). Traumatic injury to cartilage diminishes mechanical strength and leads to excessive catabolism of the ECM, increasing the risk of osteoarthritis later in life (5).A number of model systems have been developed to simulate various aspects of the mechanical loading forces experienced by articular cartilage in vivo. Compressive and shear forces have been applied to cartilage explants and chondrocyte cul...

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Mechanical Regulation of Mitogen-activated Protein Kinase Signaling in Articular Cartilage

Cited by 119 publications

References 50 publications

Temporal Expression Patterns and Corresponding Protein Inductions of Early Responsive Genes in Rabbit Bone Marrow–Derived Mesenchymal Stem Cells Under Cyclic Compressive Loading

Temporal Expression Patterns and Corresponding Protein Inductions of Early Responsive Genes in Rabbit Bone Marrow–Derived Mesenchymal Stem Cells Under Cyclic Compressive Loading

Shear and Compression Differentially Regulate Clusters of Functionally Related Temporal Transcription Patterns in Cartilage Tissue

Mechanical Compression of Cartilage Explants Induces Multiple Time-dependent Gene Expression Patterns and Involves Intracellular Calcium and Cyclic AMP

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