Project description:We examined the change of chondrocyte transcriptome after EGFR activation by TGF-α and inhibition by gefitinib. Data analysis showed that EGFR activation down-regulates cartilage ECM biosynthesis and promotes ECM degradation. Gefitinib can reverse the effects of EGFR on chondrocytes.

Project description:The ability to generate chondrocytes and osteoblasts from induced pluripotent stem cells (iPSCs) will provide insights into skeletal development and genetic skeletal disorders and generate cells for regenerative medicine applications. Here we describe a method that directs iPSC-derived sclerotome to chondroprogenitors in 3D pellet culture then to articular chondrocytes or, alternatively, along the growth plate cartilage pathway to become hypertrophic chondrocytes that can transdifferentiate to osteoblasts. Osteogenic organoids deposit and mineralize a collagen I extracellular matrix (ECM), mirroring in vivo endochondral bone formation. We have identified gene expression signatures at key developmental stages including chondrocyte maturation, hypertrophy and transdifferentiation to osteoblasts, and show that this system can be used to model genetic cartilage and bone disorders.

Project description:RIP1 perturbation induces chondrocyte necroptosis and promotes osteoarthritis pathogenesis

Project description:Mycobacterium tuberculosis is exposed to a variety of stresses during a chronic infection, as the immune system simultaneously produces bactericidal compounds and starves the pathogen for essential nutrients. The intramembrane protease, Rip1, plays an important role in the adaptation to these stresses, at least partially by the cleavage of membrane bound transcriptional regulators. Although Rip1 is known to be critical for surviving copper intoxication and nitric oxide exposure, these stresses do not fully account the regulatory protein’s essentiality during infection. In this work, we demonstrate that Rip1 is also necessary for growth in low iron and zinc conditions, similar to those imposed by the immune system. Using a newly generated library of sigma factor mutants, we show that the known regulatory target of Rip1, SigL, shares this defect. Transcriptional profiling under iron limiting conditions supported the coordinated activity of Rip1 and SigL and demonstrated that the loss of these proteins produces an exaggerated iron starvation response. These observations demonstrate that Rip1 coordinates several aspects of metal homeostasis and suggest that a Rip1- and SigL-dependent pathway is involved in the adaptation to the iron deficient environments encountered during infection.

Project description:Osteoarthritis (OA) is the most common joint disease and is the leading cause of chronic disability among older people. Chondrocyte death was involved in OA pathogenesis. Ferroptosis is an iron-dependent cell death associated with peroxidation of lipids. Expression of GPX4 in the OA cartilage from OA patients were significantly lower than normal cartilage.In order to analyze the mechanism of GPX4, we conducted RNA-sequencing in mouse chondrocytes with or without GPX4 knockdown.Our results showed that Gpx4 downregulation could increase the sensitivity of chondrocytes to oxidative stress and aggravate ECM degradation in chondrocytes.

Project description:Transcriptional control of any biological process occurs through the action of one to many gene regulatory networks (GRNs), but studies analyzing GRN interaction are lacking. To address this, we tested for the first time in vivo the hypothesis that two independent GRNs, which are active during formation of two discrete skeletal cell types (immature chondrocytes and osteoblasts), interact during differentiation of a third skeletal cell type (mature chondrocytes). These three cell types were isolated from the mouse embryo specifically using laser capture microdissection, and then RNA was extracted. Multiple analyses of corresponding RNA-seq data supported the hypothesis. Gene co-expression network analyses of differentially expressed genes suggested that one GRN containing the chondrogenic transcription factor Sox9 characterizes immature chondrocytes, one GRN containing the osteogenic transcription factor Runx2 characterizes osteoblasts, and both GRNs operate in mature chondrocytes. Indeed, mature chondrocytes differentially expressed fewer genes than the other cell types, consistent with the idea that overlapping actions of the immature chondrocyte and osteoblast GRNs regulate mature chondrocytes. Clustering analyses provided molecular insights into potential GRN interactions. Several genes in mature chondrocytes had expression levels that represented an averaging between levels in the immature chondrocyte and osteoblast. Interestingly, expression levels of one gene cluster, containing the hallmark mature chondrocyte genes Collagen type 10a1 and Indian hedgehog, suggested a synergistic interaction between immature chondrocyte and osteoblast GRNs. In addition to identifying novel genes expressed in mature chondrocytes, these results outline a novel in vivo experimental system through which to understand GRN organization and interaction.

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:Knowledge of cell signaling pathways that drive human neural crest differentiation into craniofacial chondrocytes is incomplete, yet essential for using stem cells to regenerate craniomaxillofacial structures. To accelerate translational progress, we developed a differentiation protocol that generated self-organizing craniofacial cartilage organoids from human embryonic stem cell-derived neural crest stem cells. Histological staining of cartilage organoids revealed tissue architecture and staining typical of elastic cartilage. Protein and post-translational modification (PTM) mass spectrometry and snRNASeq data showed that chondrocyte organoids expressed robust levels of cartilage extracellular matrix (ECM) components: many collagens, aggrecan, perlecan, proteoglycans, and elastic fibers. We identified two populations of chondroprogenitor cells, mesenchyme cells and nascent chondrocytes and the growth factors involved in paracrine signaling between them. We show that ECM components secreted by chondrocytes not only create a structurally resilient matrix that defines cartilage, but also play a pivotal autocrine cell signaling role to determine chondrocyte fate.

Project description:Cartilage aging is a quintessential feature of knee osteoarthritis, and extracellular matrix (ECM) stiffening is a typical feature of cartilage aging. However, the mechanism of ECM stiffening to influence chondrocytes and downstream molecules is still poorly understood. Here, we mimicked the physiological and pathological stiffness of human cartilage by using polydimethylsiloxane-based substrates. We show that the epigenetic regulation of Parkin by histone deacetylase 3 (HDAC3) represents a new mechanosensitive mechanism by which the stiff matrix affects the physiology of chondrocytes. We found that ECM stiffening could accelerate the senescence of cultured chondrocytes in vitro, and also found that stiff ECM downregulated HDAC3, drove Parkin acetylation to activate excessive mitophagy, and accelerated chondrocyte senescence and osteoarthritis in mice. In contrast, intra-articular injection of adeno-associated virus expressing HDAC3 restored the young phenotype of aged chondrocytes stimulated by ECM stiffening and alleviated osteoarthritis in mice. Our findings indicate that changes in the mechanical properties of ECM initiate pathogenic mechanotransduction signals, promote the acetylation of Parkin and hyperactivate mitophagy, and damage the health of chondrocytes. These findings may provide new insights into how the mechanical properties of ECM regulate chondrocytes.

Project description:Histone deacetylases (HDACs), as important enzymes regulating acetylation, participate in a series of cell physiological process. Here we reported that HDAC3-deficient macrophages had elevated expression of multiple cathepsins and over-expressed cathepsins such as cathepsin B (CTSB) caused remarkable degradation of receptor (TNFRSF)-interacting serine-threonine kinase 1 (RIP1), which resulted in reduced TNFα mediated NF-κB activation and inflammatory response. Consistent with these findings, mice with macrophage specific knockout of HDAC3 were impaired in inflammatory response and susceptible to pseudomonas aeruginosa infection. Thus, our studies uncovered important roles of HDAC3 in the regulation of cathepsin-mediated lysosomal degradation and RIP1-mediated inflammatory response in macrophages as well as in host defense against bacterial infection.