Project description:Osteoarthritis (OA) is a serious degenerative joint disease with high morbidity and is currently incurable because of its poorly defined underlying molecular basis. Here, we demonstrated that Tiki2, a membrane-tethered proteolytic Wnt inhibitor, is highly expressed in the articular chondrocytes of hyaline cartilage and that its expression negatively correlates with osteoarthritis. Tiki2 haploinsufficiency in mice causes spontaneous articular cartilage degeneration. Tiki2 deletion in chondrocytes accelerates instability-induced knee joint osteoarthritis progression in mice. Mechanistically, Tiki2 antagonizes Wnt signaling in chondrocytes and maintains chondrocyte anabolic gene expression. Moreover, intra-articular administration of a TIKI2-expressing adeno-associated virus significantly alleviated OA progression in mice, and expressing TIKI2 promoted chondrogenesis and chondrocyte redifferentiation and inhibited hypertrophic differentiation in vitro. Our results reveal the function of Tiki2 in articular cartilage homeostasis and osteoarthritis and suggest that Tiki2 is a potential target for osteoarthritis therapy.

Project description:Osteoarthritis (OA) of the hand is a common disease resulting in pain and impaired function. The pathogenesis of hand OA (HOA) is elusive and models to study it have not been described so far. Culture of chondrocytes is a model to study the development of cartilage degeneration, which is a hallmark of OA and well established in OA of the knee and hip. In the current study we investigated the feasibility human chondrocyte culture derived from proximal interphalangeal (PIP) finger joints of dissecting room cadavers. Index and middle fingers without signs of osteoarthritis were obtained from 30 cadavers using two different protocols. Hyaline cartilage from both articulating surfaces of the proximal interphalangeal (PIP) joint was harvested and digested in collagenase. Cultured chondrocytes were monitored for contamination, viability, and expression of chondrocyte specific genes. Chondrocytes derived from knee joints of the cadavers were cultured under identical conditions. Gene expression comparing chondrocytes from PIP and knee joints was carried out using Affymetrix GeneChip Human 2.0 ST arrays. The resulting differentially expressed genes were validated by real-time PCR and immunohistochemistry.Chondrocytes harvested up to 101 hours after death of the donors were viable. mRNA expression of collagen 2A1, aggrecan and Sox9 was significantly higher in chondrocytes as compared to cultured fibroblasts. Comparison of gene expression by chondrocytes from PIP and knee joints yielded 528 differentially expressed genes. Chondrocytes from the same joint region had a higher grade of similarity than chondrocytes of the same individual. These results were validated using real-time PCR and immunohistochemistry.We demonstrate for the first time a reliable method for culture of chondrocytes derived from PIP joints. PIP chondrocytes show a specific gene expression pattern and could be used as tool to study cartilage degeneration in HOA. Three samples of cultured chondrocytes from knee and proximal interphalangeal finger joints were compared. Gene expression of the four most differentially regulated genes was confirmed by real-time PCR in 10 independent samples.

Project description:Osteoarthritis (OA) of the hand is a common disease resulting in pain and impaired function. The pathogenesis of hand OA (HOA) is elusive and models to study it have not been described so far. Culture of chondrocytes is a model to study the development of cartilage degeneration, which is a hallmark of OA and well established in OA of the knee and hip. In the current study we investigated the feasibility human chondrocyte culture derived from proximal interphalangeal (PIP) finger joints of dissecting room cadavers. Index and middle fingers without signs of osteoarthritis were obtained from 30 cadavers using two different protocols. Hyaline cartilage from both articulating surfaces of the proximal interphalangeal (PIP) joint was harvested and digested in collagenase. Cultured chondrocytes were monitored for contamination, viability, and expression of chondrocyte specific genes. Chondrocytes derived from knee joints of the cadavers were cultured under identical conditions. Gene expression comparing chondrocytes from PIP and knee joints was carried out using Affymetrix GeneChip Human 2.0 ST arrays. The resulting differentially expressed genes were validated by real-time PCR and immunohistochemistry.Chondrocytes harvested up to 101 hours after death of the donors were viable. mRNA expression of collagen 2A1, aggrecan and Sox9 was significantly higher in chondrocytes as compared to cultured fibroblasts. Comparison of gene expression by chondrocytes from PIP and knee joints yielded 528 differentially expressed genes. Chondrocytes from the same joint region had a higher grade of similarity than chondrocytes of the same individual. These results were validated using real-time PCR and immunohistochemistry.We demonstrate for the first time a reliable method for culture of chondrocytes derived from PIP joints. PIP chondrocytes show a specific gene expression pattern and could be used as tool to study cartilage degeneration in HOA.

Project description:Osteoarthritis (OA) is a chronic, degenerative whole-joint disorder that interferes with quality of life in older individuals. Here, we report a high expression of ZDHHC11 in articular chondrocytes, which is downregulated in the degenerated cartilage of aged mice and OA patients. ZDHHC11 prevents chondrocyte senescence and fosters cartilage anabolism, culminating in an improved OA phenotype. Mice with Zdhhc11 deletion (Zdhhc11fl/fl) exacerbate OA progression in a destabilized medial meniscus (DMM) model.

Project description:Avascular soft tissues of the skeletal system, including articular cartilage, have an extremely limited healing capacity, in part due to their low metabolic activity. No drugs are available that can prevent or slow the development of osteoarthritis (OA) after joint injury. Therefore, mesenchymal stromal cell (MSC)-based regenerative therapies are increasingly common in the treatment of OA, but questions regarding their clinical efficacy and mechanisms of action remain unanswered. Our group recently reported that mitochondrial dysfunction is one of the earliest responses of cartilage to injury, resulting in chondrocyte death, extracellular matrix degeneration, and ultimately OA. MSCs have been found to rescue injured cells and improve healing by donating healthy mitochondria in highly metabolic tissues, but mitochondrial transfer has not been investigated in cartilage. To investigate how gene expression changes in stressed chondrocytes, and therefore how they might elicit mitochondrial donation from MSCs, we developed a custom quantitative PCR panel of relevant genes involved in chondrocyte metabolism and OA. We cultured chondrocytes under conditions known induce chondrocyte mitochondrial dysfunction, including stimulation with rotenone/antimycin and non-physiologic culture conditions (hyperoxia and hyperglycemia). We found that expression of gap junction alpha 1 (GJA1), the gene that encodes the Cx43 protein, was increased in hyperoxia. The senescence associated markers, cyclin-dependent kinase inhibitor 2A (CDKN2A) and tissue inhibitor of metalloproteinases 1 (TIMP1), were also increased in hyperoxia. In addition, hyperoxia caused chondrocytes to increase the expression of the antioxidant enzyme, SOD2. This work provides insights into the chemical and environmental conditions that can alter gene expression in chondrocytes. Further, this provides supporting evidence to our hypothesis that stressed chondrocytes may trigger mitochondrial donation from MSCs may via direct or indirect signaling involving the inflammation- and senescence-related genes identified in the present study.

Project description:Mechanical overload is essential to cartilage degeneration during osteoarthritis (OA) development. Recent studies have confirmed that circular RNAs (circRNAs) are mechanically sensitive and that the circRNA-associated competitive endogenous RNA (ceRNA) network regulates cartilage degeneration and OA development. However, the involvement of the circRNA-associated ceRNA network in chondrocyte senescence induced by mechanical overloading remains unestablished.Here,we examined the circRNA, miRNA and mRNA expression of chondrocytes subjected to mechanical overloading.

Project description:Mechanical overload is essential to cartilage degeneration during osteoarthritis (OA) development. Recent studies have confirmed that circular RNAs (circRNAs) are mechanically sensitive and that the circRNA-associated competitive endogenous RNA (ceRNA) network regulates cartilage degeneration and OA development. However, the involvement of the circRNA-associated ceRNA network in chondrocyte senescence induced by mechanical overloading remains unestablished.Here,we examined the circRNA, miRNA and mRNA expression of chondrocytes subjected to mechanical overloading.

Project description:Mechanical overload is essential to cartilage degeneration during osteoarthritis (OA) development. Recent studies have confirmed that circular RNAs (circRNAs) are mechanically sensitive and that the circRNA-associated competitive endogenous RNA (ceRNA) network regulates cartilage degeneration and OA development. However, the involvement of the circRNA-associated ceRNA network in chondrocyte senescence induced by mechanical overloading remains unestablished.Here,we examined the circRNA, miRNA and mRNA expression of chondrocytes subjected to mechanical overloading.

Project description:Osteoarthritis (OA) is the most common degenerative joint disease. During its initiation and early progression a disruption in subchondral bone (SCB) remodeling, induced by excessive and cumulative mechanical loading, occurs before cartilage degeneration. While it is known that osteocytes in the SCB are mainly responsible for mechanosensing, their role in the early phases of OA are still unclear. Here, we found that mechanical stress induces SCB osteocytes to secrete extracellular vesicles (EVs) that accelerate cartilage metabolic dysregulation. By gain- and loss-of function experiments we show that such EVs via miR-23b-3p promote cartilage catabolism while inhibiting their anabolism. Mechanistically, miR-23b-3p inhibits mitophagy by targeting OTUD4 to promote this metabolic skewing. Further, by inhibiting miR-23b-3p in either osteocytes or chondrocytes we could alleviate cartilage degeneration and OA progression in a mouse model. Together, our findings show that SCB osteocytes communicate with chondrocytes via EVs and that targeting a key EV-derived miRNA can ameliorate OA progression.

Project description:Osteoarthritis (OA) is the most common degenerative joint disease. During its initiation and early progression a disruption in subchondral bone (SCB) remodeling, induced by excessive and cumulative mechanical loading, occurs before cartilage degeneration. While it is known that osteocytes in the SCB are mainly responsible for mechanosensing, their role in the early phases of OA are still unclear. Here, we found that mechanical stress induces SCB osteocytes to secrete extracellular vesicles (EVs) that accelerate cartilage metabolic dysregulation. By gain- and loss-of function experiments we show that such EVs via miR-23b-3p promote cartilage catabolism while inhibiting their anabolism. Mechanistically, miR-23b-3p inhibits mitophagy by targeting OTUD4 to promote this metabolic skewing. Further, by inhibiting miR-23b-3p in either osteocytes or chondrocytes we could alleviate cartilage degeneration and OA progression in a mouse model. Together, our findings show that SCB osteocytes communicate with chondrocytes via EVs and that targeting a key EV-derived miRNA can ameliorate OA progression.