Project description:To profile the diversity of cell types present in adult zebrafish synovial joints, we performed single-cell RNA sequencing of the uninjured adult jaw joint and identified multiple skeletal, connective tissue, and fibroblast subtypes, including a joint-specific periosteal population.

Project description:In 21 patients undergoing revision arthroplasty due to septic or aseptic implant loosening, synovial fluid was collected intraoperatively after opening the joint capsule. In a proteomic MS approach, we wanted now to investigate these synovial fluids for novel proteogenic markers of periprosthetic infections.

Project description:The synovial joint forms from a pool of progenitor cells in the interzone region of the future joint. Expression of Gdf5 and Wnt9a has been used to mark the earliest cellular processes in the formation of the interzone and the progenitor cells. However, progression and lineage specification toward the different tissues of the joint is not well understood. Here, by lineage tracing studies we identify a population of Lgr5+ interzone cells that contribute to the formation of cruciate ligaments, synovial membrane and articular chondrocytes of the joint. This is supported by single cell transcriptome analyses. Furthermore, we showed that Col22a1, a marker of early articular chondrocytes, co-expresses with Lgr5+ cells prior to cavitation as an important lineage marker specifying the progression towards articular chondrocytes. Lgr5+ cells contribute to the repair of a joint defect with the re-establishment of Col22a1 containing superficial layer.

Project description:Adult mammalian synovial joints have limited regenerative capacity, where injuries heal with mechanically inferior fibrotic joint tissues. Here we developed a unilateral whole-joint resection model in adult zebrafish to advance our understanding of how to stimulate regrowth of native synovial joint tissues. Using single-cell RNA sequencing, we profile RNA expression from live-sorted jaw joint cells throughout the time course of joint regeneration (1 to 70 days-post-joint-resection (dpjr)). Our findings reveal latent molecular and cellular programs within the adult skeleton that are deployed to regenerate a complex joint with lubricated articular cartilage.

Project description:Small RNA isolated from synovial fluid of the metacarpophalangeal joints of horses. Horses either had minimal signs of osteoarthritis based on macroscopic and microscopic joint scoring or early (mild) osteoarthritis. Differential expression of small non-coding RNAs was undertaken.

Project description:We conducted a genetic analysis of the developing temporo-mandibular joint (TMJ), a highly specialized synovial joint that permits movement and function of the mammalian jaw. First, we used laser capture microdissection to perform a genome-wide expression analysis of each of its developing components. The expression patterns of genes identified in this screen were examined in the TMJ and compared to other synovial joints including the shoulder joint and the hip joint. Striking differences were noted, indicating that the TMJ forms via a distinct molecular program. Several components of the Hedgehog (Hh) signaling pathway are among the genes identified in the screen, including Gli2, which is expressed specifically in the condyle and in the disk of the developing TMJ. We found that mice deficient in Gli2 display aberrant TMJ development such that the condyle loses its growth plate-like cellular organization and no disk is formed. In addition, we utilized a conditional strategy to remove activity of the Hh co-receptor encoded by Smo from chondrocyte progenitors. This cell autonomous loss of Hh signaling allows for disk formation, but the resulting structure fails to separate from the condyle. Thus, these experiments establish that Hh signaling acts at two distinct steps in disk morphogenesis, condyle initiation and disk-condyle separation, and provide a molecular framework for future studies of the TMJ. Experiment Overall Design: Mouse embryos fresh frozen and TMJ tissue captured by LCM. 3 samples in biological triplicate.

Project description:Osteoarthritis (OA) is a degenerative joint disease characterized by progressive cartilage loss, bone remodeling, synovial inflammation, and significant joint pain, often resulting in disability. Injury to the synovial joint such as the anterior cruciate ligament (ACL) tear is the major cause of OA in young adults. Currently, there are no approved therapies available to prevent joint degeneration or rebuild articular cartilage destroyed by OA, primarily because our understanding of the cellular and molecular changes that contribute to joint damage is very limited. The synovial joint is a complex structure composed of several tissues including articular cartilage, subchondral bone, synovium, synovial fluid, and tensile tissues including tendons and ligaments. In the present study, using single-cell RNA sequencing (scRNA-seq), we examined the cellular heterogeneity in articular cartilage from mouse knee joints and determined the knee joint injury-induced early molecular changes in the chondrocytes that could contribute to OA.

Project description:Lgr5 is a novel marker expressing in the interzone from around e14.5 of developing synovial joint. By comparing the expression profiles of e14.5 Lgr5+ interzone cells, surrounding Lgr5- non-interzone cells and also e13.5 digit, we have identified some differential expressing genes in the interzone. We have generated bulk RNAseq data of e14.5 Lgr5+ interzone cells, surrounding non-interzone cells and e13.5 Sox9+ chondrocytes cells in digit.

Project description:Synovial biopsies from rheumatoid arthritis patients were obtained and profiled using RNA-seq. Patients were stratified according to the number of swollen joints they had (SJC, swollen joint count) and divided in three groups for the differential expression analysis: None (SJC = 0), Low (1<= SJC <= 8), High (SJC > 8).

Project description:This study aimed to establish molecular endotypes in osteoarthritis soft joint tissue driven by obesity in both load-bearing and non-load bearing joints. Transcriptomic analysis found the inflammatory landscape of OA synovial fibroblasts (SF) are independently impacted by obesity, joint loading, and anatomical site with significant heterogeneity between obese and normal weight patients. These findings demonstrate the significance of obesity in changing the inflammatory landscape of synovial fibroblasts in both load bearing and non-load bearing joints. The molecular endotypes identified may provide a route for the stratification of patients in clinical trials, providing a rational for the therapeutic targeting of specific SF subsets in specific patient populations with arthritic conditions.