Mechanical Forces Regulate Cartilage Tissue Formation by Chondrocytes via Integrin-mediated cell Spreading

Ferguson, Caroline

09 March 2010

In vitro grown cartilage is functionally inferior to native tissue, and improvements in its quality should be attempted so it can be used therapeutically. In these studies we investigated the effects of cell shape on tissue quality through alteration of substrate geometry and application of mechanical stimuli. Articular chondrocytes were isolated and cultured on the surface Ti-6Al-4V substrates with various geometries. When cultured on fully porous titanium alloy substrates, chondrocyte spreading was enhanced over those grown on substrates with solid bases. Chondrocytes which remained round did not synthesize significant amounts of matrix and were thus unable to form cartilaginous tissue. In contrast, chondrocytes which were directed to spread to a limited amount, resulting in a polygonal morphology, accumulated significantly more matrix molecules and in time formed cartilage-like tissue. Computational fluid dynamics analyses demonstrated that cells on fully porous substrates experience time-dependent shear stresses that differ from those experienced by cells on substrates with solid bases where media flow-through is restricted. Integrin-blocking experiments revealed that integrins are important regulators of cell shape, and appeared to influence the accumulation of collagen and proteoglycans by chondrocytes. Furthermore, compressive mechanical stimulation induced a rapid, transient increase in chondrocyte spreading by 10 minutes, followed by a retraction to pre-stimulated size within 6 hours. This has been shown to be associated with increased accumulation of newly synthesized proteoglycans. Blocking the α5β1 integrin, or its β1 subunit, inhibited cell spreading and resulted in a partial inhibition of compression-induced increases in matrix accumulation, thereby substantiating the role of β1 integrins in this process. These results suggest that both fluid induced shear forces and compressive forces regulate chondrocyte matrix accumulation by altering cell morphology, which is mediated by integrins. Identifying the molecular mechanisms that influence chondrocyte shape and thus tissue formation may ultimately lead to the development of a tissue that more closely resembles native articular cartilage.

articular chondrocytes

tissue engineering

0794

Mechanical Forces Regulate Cartilage Tissue Formation by Chondrocytes via Integrin-mediated cell Spreading

Ferguson, Caroline

09 March 2010

In vitro grown cartilage is functionally inferior to native tissue, and improvements in its quality should be attempted so it can be used therapeutically. In these studies we investigated the effects of cell shape on tissue quality through alteration of substrate geometry and application of mechanical stimuli. Articular chondrocytes were isolated and cultured on the surface Ti-6Al-4V substrates with various geometries. When cultured on fully porous titanium alloy substrates, chondrocyte spreading was enhanced over those grown on substrates with solid bases. Chondrocytes which remained round did not synthesize significant amounts of matrix and were thus unable to form cartilaginous tissue. In contrast, chondrocytes which were directed to spread to a limited amount, resulting in a polygonal morphology, accumulated significantly more matrix molecules and in time formed cartilage-like tissue. Computational fluid dynamics analyses demonstrated that cells on fully porous substrates experience time-dependent shear stresses that differ from those experienced by cells on substrates with solid bases where media flow-through is restricted. Integrin-blocking experiments revealed that integrins are important regulators of cell shape, and appeared to influence the accumulation of collagen and proteoglycans by chondrocytes. Furthermore, compressive mechanical stimulation induced a rapid, transient increase in chondrocyte spreading by 10 minutes, followed by a retraction to pre-stimulated size within 6 hours. This has been shown to be associated with increased accumulation of newly synthesized proteoglycans. Blocking the α5β1 integrin, or its β1 subunit, inhibited cell spreading and resulted in a partial inhibition of compression-induced increases in matrix accumulation, thereby substantiating the role of β1 integrins in this process. These results suggest that both fluid induced shear forces and compressive forces regulate chondrocyte matrix accumulation by altering cell morphology, which is mediated by integrins. Identifying the molecular mechanisms that influence chondrocyte shape and thus tissue formation may ultimately lead to the development of a tissue that more closely resembles native articular cartilage.

articular chondrocytes

tissue engineering

0794

Chondrocyte Regulation by IL-I and IGF-I: Interconnection Between Anabolic and Catabolic Factors

Porter, Ryan Michael

18 November 2005

Articular cartilage functions to reduce the mechanical stresses associated with diarthrodial joint movement, protecting these joints over a lifetime of use. Tissue function is maintained through the balance between synthesis and resorption (i.e., metabolism) of extracellular matrix (ECM) by articular chondrocytes (ACs). Two important hormonal regulators of cartilage metabolism are interleukin-1 (IL-1) and insulin-like growth factor-I (IGF-I). These factors have antagonistic effects on chondrocyte activity, and during the progression of osteoarthritis, IL-1 is thought to promote chondrocyte hyporesponsiveness to IGF-I. To better understand how the anabolic (IGF-I) and catabolic (IL-1) stimuli are linked within articular cartilage, we examined the mechanisms by which IL-1 regulates the IGF-I signaling system of ACs. Equine chondrocytes from non-arthritic stifle joints were multiplied over serial passages, re-differentiated in alginate beads, and stimulated with recombinant equine IL-1β. Chondrocytes were assayed for type I IGF receptor (IGF-IR), IGF binding proteins (IGFBPs), and endogenously-secreted IGF-I. Our experimental findings solidify the significance of IL-1 as a key regulator of IGF-I signaling within articular cartilage, demonstrating that regulation of the IGF-I system occurs through both direct (transcription) and indirect (proteolysis) mechanisms. These results have implications for molecular therapies (e.g., gene transfer) directed at reversing osteoarthritic cartilage deterioration. The presented research concerns not only cartilage biology but also tissue engineering strategies for cartilage repair. Alginate hydrogel culture has been reported to re-establish chondrocytic phenotype following monolayer expansion, but studies have not addressed effects on the signaling systems responsible for chondrocyte metabolism. We investigated whether chondrocyte culture history influences the IGF-I system and its regulation by IL-1. ACs expanded by serial passaging were either encapsulated in alginate beads or maintained on tissue culture plastic (TCP). Bead and TCP cells were plated at high-density, stimulated with IL-1β, and assayed for expression of IGF-I signaling mediators. Intermediate alginate culture yielded disparate basal levels of IGF-IR and IGFBP-2, which were attributed to differential transcription. The distinct mediator profiles coincided with varied effects of exogenous IL-1β and IGF-I on collagen Ia1 expression and cell growth rate. This study demonstrates that culture strategy impacts the IGF-I system of ACs, likely impacting their capability to mediate cartilage repair. / Ph. D.

articular chondrocytes

insulin-like growth factor-I (IGF-I)

osteoarthritis

equine

cell signaling

interleukin-1 (IL-1)