Project description:Chondrocytes are the only cell type in cartilage and play a pivotal role in tissue homeostasis and cartilage remodeling in Osteoarthritis (OA). OA-dependent metabolic changes affecting extracelluar matrix composition as well as variations in the response to cytokines and growth factors have been investigated in human chondrocytes. However, the molecular mechanisms causing age-dependent variation of the chondrocyte phenotype are poorly characterized. The proinflammatory mediator nitric oxide (NO) is produced when chondrocytes are exposed to cytokines such as IL-1. NO affects the energy metabolism of cells through interfering with mitochondrial respiration and glycolysis and has been implicated in extracellular matrix synthesis and degradation and chondrocyte death. NO may contribute to the aging process by compromising the energy balance in chondrocytes through the generation of an oxidizing environment and this may in turn affect matrix gene expression. In human chondrocytes NO effects on the expression of extacelluar matrix genes or genes related to matrix structure have not been addressed comprehensively.

Project description:Osteoarthritis (OA) is an aging-associated disease of diarthrodial joints that involves changes in the bone, cartilage and soft tissue. Chondrocytes are the only cell type in cartilage and play a pivotal role in tissue homeostasis and cartilage remodeling in OA. Age- or OA-dependent metabolic changes affecting extracelluar matrix composition as well as variations in the response to cytokines and growth factors have been investigated in human chondrocytes. However, the molecular mechanisms causing age-dependent variation of the chondrocyte phenotype are poorly characterized. The proinflammatory mediator nitric oxide (NO) is produced when chondrocytes are exposed to cytokines such as IL-1. NO affects the energy metabolism of cells through interfering with mitochondrial respiration and glycolysis and has been implicated in extracellular matrix synthesis and degradation and chondrocyte death. NO may contribute to the aging process by compromising the energy balance ! in chondrocytes through the generation of an oxidizing environment and this may in turn affect matrix gene expression. In human chondrocytes NO effects on the expression of extacelluar matrix genes or genes related to matrix structure have not been addressed comprehensively. In chondrocytes NO has profound effects on extracellular matrix: Interleukin-1 induced the production of nitric oxide in human articular chondrocytes in alginate culture and simultaneously inhibited the biosynthesis of proteoglycans. NG-monomethyl-L-arginine (L-NMMA) inhibited nitric oxide formation and the suppression of proteoglycan synthesis. The nitric oxide donor, S-nitrosyl-acetyl-D,L- penicillamine (SNAP) also inhibited proteoglycan biosynthesis suggesting that interleukin-1 suppresses matrix synthesis through mechanisms involving the production of NO. Slices of rabbit articular cartilage synthesized large quantities of nitric oxide (NO) following exposure to IL-1 and strongly suppressed the incorporation of 35SO4 into the glycosaminoglycans (GAGs) of cartilage proteoglycans. Simultaneous treatment of cartilage fragments with IL-1 and L-NMMA inhibited NO synthesis in response to IL-1 and restored proteoglycan synthesis. SNAP reversibly mimicked the effect! of IL-1 on proteoglycan synthesis. These data suggest that endogenously synthesized NO is the mediator which reduces cartilage proteoglycan synthesis in response to cytokines such as IL-1. Aggrecan and type II collagen synthesis are also affected by NO. Our hypothesis entails that in human chondrocytes endogenous NO modulates the expression of matrix genes as well as enzymes involved in extracellular matrix remodelling. Experimental approach: In this experiment cultured chondrocytes from 3 donors was left unstimulated (control) or stimulated with IL-1, L-NMMA or IL-1 + L-NMMA for a period of 8 days in order to achieve sufficiently high levels of intracellular NO and stable expression of a subset of genes. Total RNA was isolated using the Trizol procedure. Gene expression will be probed using the Glycov2 chip. In this study cultured chondrocytes from three donors will either be left unstimulated (control) or stimulated with IL-1, L-NMMA or IL-1 L-NMMA for a period of 8 days in order to achieve sufficiently high levels of intracellular NO and stable expression of a subset of genes. 12 Samples were hybridized and analyzed using the GLYCOv2 array, three from each class.

Project description:Osteoarthritis (OA) is an aging-associated disease of diarthrodial joints that involves changes in the bone, cartilage and soft tissue. Chondrocytes are the only cell type in cartilage and play a pivotal role in tissue homeostasis and cartilage remodeling in OA. Age- or OA-dependent metabolic changes affecting extracelluar matrix composition as well as variations in the response to cytokines and growth factors have been investigated in human chondrocytes. However, the molecular mechanisms causing age-dependent variation of the chondrocyte phenotype are poorly characterized. The proinflammatory mediator nitric oxide (NO) is produced when chondrocytes are exposed to cytokines such as IL-1. NO affects the energy metabolism of cells through interfering with mitochondrial respiration and glycolysis and has been implicated in extracellular matrix synthesis and degradation and chondrocyte death. NO may contribute to the aging process by compromising the energy balance ! in chondrocytes through the generation of an oxidizing environment and this may in turn affect matrix gene expression. In human chondrocytes NO effects on the expression of extacelluar matrix genes or genes related to matrix structure have not been addressed comprehensively. In chondrocytes NO has profound effects on extracellular matrix: Interleukin-1 induced the production of nitric oxide in human articular chondrocytes in alginate culture and simultaneously inhibited the biosynthesis of proteoglycans. NG-monomethyl-L-arginine (L-NMMA) inhibited nitric oxide formation and the suppression of proteoglycan synthesis. The nitric oxide donor, S-nitrosyl-acetyl-D,L- penicillamine (SNAP) also inhibited proteoglycan biosynthesis suggesting that interleukin-1 suppresses matrix synthesis through mechanisms involving the production of NO. Slices of rabbit articular cartilage synthesized large quantities of nitric oxide (NO) following exposure to IL-1 and strongly suppressed the incorporation of 35SO4 into the glycosaminoglycans (GAGs) of cartilage proteoglycans. Simultaneous treatment of cartilage fragments with IL-1 and L-NMMA inhibited NO synthesis in response to IL-1 and restored proteoglycan synthesis. SNAP reversibly mimicked the effect! of IL-1 on proteoglycan synthesis. These data suggest that endogenously synthesized NO is the mediator which reduces cartilage proteoglycan synthesis in response to cytokines such as IL-1. Aggrecan and type II collagen synthesis are also affected by NO. Our hypothesis entails that in human chondrocytes endogenous NO modulates the expression of matrix genes as well as enzymes involved in extracellular matrix remodelling. Experimental approach: In this experiment cultured chondrocytes from 3 donors was left unstimulated (control) or stimulated with IL-1, L-NMMA or IL-1 + L-NMMA for a period of 8 days in order to achieve sufficiently high levels of intracellular NO and stable expression of a subset of genes. Total RNA was isolated using the Trizol procedure. Gene expression will be probed using the Glycov2 chip.

Project description:Autologous chondrocyte transplantation (ACT) is a routine technique to regenerate focal cartilage lesions. However, patients with osteoarthritis (OA) are lacking an appropriate long-lasting treatment alternative, partly since it is not known if chondrocytes from OA patients have the same chondrogenic differentiation potential as chondrocytes from donors not affected by OA. Articular chondrocytes from patients with OA undergoing total knee replacement (Mankin Score >3, Ahlbäck Score >2) and from patients undergoing ACT, here referred to as normal donors (ND), were isolated applying protocols used for ACT. Their chondrogenic differentiation potential was evaluated both in high-density pellet and scaffold (Hyaff-11) cultures by histological proteoglycan assessment (Bern Score) and immunohistochemistry for collagen types I and II. Chondrocytes cultured in monolayer and scaffolds were subjected to gene expression profiling using genome-wide oligonucleotide microarrays. Expression data were verified by using quantitative RT-PCR. Chondrocytes from ND and OA donors demonstrated accumulation of comparable amounts of cartilage matrix components, including sulphated proteoglycans and collagen types I and II. The mRNA expression of cartilage markers (COL2A1, COMP, aggrecan, CRTL1, SOX9) and genes involved in matrix synthesis (biglycan, COL9A2, COL11A1, TIMP4, CILP2) was highly induced in 3D cultures of chondrocytes from both donor groups. Genes associated with hypertrophic or OA cartilage (COL10A1, RUNX2, periostin, ALP, PTHR1, MMP13, COL1A1, COL3A1) were not significantly regulated between the two groups of donors. The expression of 661 genes, including COMP, FN1, and SOX9, were differentially regulated between OA and ND chondrocytes cultured in monolayer. During scaffold culture, the differences diminished between the OA and ND chondrocytes, and only 184 genes were differentially regulated. Only few genes were differentially expressed between OA and ND chondrocytes in Hyaff-11 culture. The risk of differentiation into hypertrophic cartilage does not seem to be increased for OA chondrocytes. Our findings suggest that the chondrogenic capacity is not significantly affected by OA and OA chondrocytes fulfill the requirements for matrix-associated ACT. Experiment Overall Design: Gene expression profiles of monolayer cultures (ML; passage 2) and Hyaff-11 scaffold cultures (3D; 14 days in vitro) of chondrocytes from 3 normal donors (ND; underwent ACT treatment) and 3 donors suffering from Osteoarthritis (OA; underwent knee replacement surgery) were determined. Comparative analyses between 3D and ML cultures (3D vs. ML) were performed to assess differentiation capacity of ND and OA chondrocytes. Furthermore, OA-related differences were determined comparing OA and ND monolayers as well as scaffold cultures (each OA vs. ND).

Project description:We have studied the expression profile of 3D cultured human chondrocytes that were stimulated with supernatant of synovial fibroblasts derived from a RA patient (RASF=HSE cell line) and from a normal donor (NDSF=K4IM cell line), respectively. For this purpose, passage 2 human chondrocytes were cultured for 14 days in alginate beads and subsequently stimulated for 48 hours with supernatant of RASF and NDSF. Baseline expression was determined of unstimulated chondrocytes. Differential genome-wide microarray analysis of RASF and NDSF stimulated chondrocytes disclosed a distinct expression profile related to cartilage destruction involving marker genes of inflammation (COX-2), NF-kappa B signaling pathway (TLR2), cytokines/chemokines and receptors (CXCL1-3, CCL20, CXCL8, CXCR4, IL-6, IL-1beta), matrix degradation (MMP-10, MMP-12) and suppressed matrix synthesis (COMP). Thus, transcriptome profiling of RASF and NDSF stimulated chondrocytes revealed a disturbed catabolic-anabolic homeostasis of chondrocyte function. This study provides a comprehensive insight into the molecular regulatory processes induced in human chondrocytes during RA-related cartilage destruction. Experiment Overall Design: To reveal the RA-related chondrocyte gene expression profile, genome-wide microarray analysis of RASF stimulated human chondrocytes compared to NDSF stimulation was performed. Unstimulated chondrocytes were analyzed for baseline gene expression. For microarray analysis of RASF and NDSF stimulated and unstimulated chondrocytes, respectively, two RNA pools were analyzed, each pool consisting of equal amounts of RNA from three different donors.

Project description:Autologous chondrocyte transplantation (ACT) is a routine technique to regenerate focal cartilage lesions. However, patients with osteoarthritis (OA) are lacking an appropriate long-lasting treatment alternative, partly since it is not known if chondrocytes from OA patients have the same chondrogenic differentiation potential as chondrocytes from donors not affected by OA. Articular chondrocytes from patients with OA undergoing total knee replacement (Mankin Score >3, Ahlbäck Score >2) and from patients undergoing ACT, here referred to as normal donors (ND), were isolated applying protocols used for ACT. Their chondrogenic differentiation potential was evaluated both in high-density pellet and scaffold (Hyaff-11) cultures by histological proteoglycan assessment (Bern Score) and immunohistochemistry for collagen types I and II. Chondrocytes cultured in monolayer and scaffolds were subjected to gene expression profiling using genome-wide oligonucleotide microarrays. Expression data were verified by using quantitative RT-PCR. Chondrocytes from ND and OA donors demonstrated accumulation of comparable amounts of cartilage matrix components, including sulphated proteoglycans and collagen types I and II. The mRNA expression of cartilage markers (COL2A1, COMP, aggrecan, CRTL1, SOX9) and genes involved in matrix synthesis (biglycan, COL9A2, COL11A1, TIMP4, CILP2) was highly induced in 3D cultures of chondrocytes from both donor groups. Genes associated with hypertrophic or OA cartilage (COL10A1, RUNX2, periostin, ALP, PTHR1, MMP13, COL1A1, COL3A1) were not significantly regulated between the two groups of donors. The expression of 661 genes, including COMP, FN1, and SOX9, were differentially regulated between OA and ND chondrocytes cultured in monolayer. During scaffold culture, the differences diminished between the OA and ND chondrocytes, and only 184 genes were differentially regulated. Only few genes were differentially expressed between OA and ND chondrocytes in Hyaff-11 culture. The risk of differentiation into hypertrophic cartilage does not seem to be increased for OA chondrocytes. Our findings suggest that the chondrogenic capacity is not significantly affected by OA and OA chondrocytes fulfill the requirements for matrix-associated ACT. Keywords: time course, cell type comparison, tissue engineered cartilage; osteoarthritis; Hyaff-11 scaffold; human chondrocytes; gene expression profiling; regenerative medicine; differentiation potential

Project description:Osteoarthritis (OA) is a degenerative joint disease characterized by cartilage degradation and inflammation. This study investigates the therapeutic potential of secretome derived from adipose tissue mesenchymal stem cells (ASCs) in mitigating inflammation and promoting cartilage repair in an in vitro model of OA. Our in vitro model comprised chondrocytes inflamed with TNF. To assess the therapeutic potential of secretome, inflamed chondrocytes were treated with it and concentrations of pro-inflammatory cytokines, metalloproteinases (MMPs) and extracellular matrix markers were measured. In addition, secretome-treated chondrocytes were subject to a microarray analysis to determine which genes were upregulated and which were downregulated. Treating TNF-inflamed chondrocytes with secretome in vitro inhibits the NF-κB pathway, thereby mediating anti-inflammatory and anti-catabolic effects. Additional protective effects of secretome on cartilage are revealed in the inhibition of hypertrophy markers such as RUNX2 and COL10A1, increased production of COL2A1 and ACAN and upregulation of SOX9. These findings suggest that ASC-derived secretome can effectively reduce inflammation, promote cartilage repair, and maintain chondrocyte phenotype. This study highlights the potential of ASC-derived secretome as a novel, non-cell-based therapeutic approach for OA, offering a promising alternative to current treatments by targeting inflammation and cartilage repair mechanisms.

Project description:Articular cartilage degeneration, which may lead to osteoarthritis (OA), is a normal component of the aging process, but its underlying mechanism remains unknown. We found that chondrocytes exhibited an energy metabolism shift from glycolysis to oxidative phosphorylation (OXPHOS) during aging. Reprogrammed cartilage metabolism by parkin ablation decreased OXPHOS and increased glycolysis, with ameliorated aging-related OA. Metabolomics analysis indicated that lauroyl-L-carnitine (LLC) was decreased in aged cartilage, but increased in parkin-deficient cartilage. In vitro, LLC improved the cartilage matrix synthesis of OA chondrocytes. In vivo, intraarticular injection of LLC in mice with anterior cruciate ligament transaction (ACLT) ameliorated OA. These results suggest that metabolic changes are regulated by parkin-impaired cartilage during aging, and targeting the metabolomic changes by supplementation with LLC is a promising treatment strategy for ameliorating OA.

Project description:Articular cartilage degeneration, which may lead to osteoarthritis (OA), is a normal component of the aging process, but its underlying mechanism remains unknown. We found that chondrocytes exhibited an energy metabolism shift from glycolysis to oxidative phosphorylation (OXPHOS) during aging. Reprogrammed cartilage metabolism by parkin ablation decreased OXPHOS and increased glycolysis, with ameliorated aging-related OA. Metabolomics analysis indicated that lauroyl-L-carnitine (LLC) was decreased in aged cartilage, but increased in parkin-deficient cartilage. In vitro, LLC improved the cartilage matrix synthesis of OA chondrocytes. In vivo, intraarticular injection of LLC in mice with anterior cruciate ligament transaction (ACLT) ameliorated OA. These results suggest that metabolic changes are regulated by parkin-impaired cartilage during aging, and targeting the metabolomic changes by supplementation with LLC is a promising treatment strategy for ameliorating OA.

Project description:Articular cartilage degeneration, which may lead to osteoarthritis (OA), is a normal component of the aging process, but its underlying mechanism remains unknown. We found that chondrocytes exhibited an energy metabolism shift from glycolysis to oxidative phosphorylation (OXPHOS) during aging. Reprogrammed cartilage metabolism by parkin ablation decreased OXPHOS and increased glycolysis, with ameliorated aging-related OA. Metabolomics analysis indicated that lauroyl-L-carnitine (LLC) was decreased in aged cartilage, but increased in parkin-deficient cartilage. In vitro, LLC improved the cartilage matrix synthesis of OA chondrocytes. In vivo, intraarticular injection of LLC in mice with anterior cruciate ligament transaction (ACLT) ameliorated OA. These results suggest that metabolic changes are regulated by parkin-impaired cartilage during aging, and targeting the metabolomic changes by supplementation with LLC is a promising treatment strategy for ameliorating OA.