Project description:Objective: When primary chondrocytes are cultured in monolayer, they undergo dedifferentiation during which they lose their phenotype and their capacity to form cartilage. Dedifferentiation is an obstacle for cell therapy for cartilage degeneration. In this study, we aimed to systemically evaluate the changes in gene expression during dedifferentiation of human articular chondrocytes to identify underlying mechanisms. Methods: RNA was isolated from monolayer-cultured primary human articular chondrocytes at serial passages. Gene expression was analyzed by microarray. Based on the microarray analysis, relevant genes and pathways were identified. Their functions in chondrocyte dedifferentiation were further investigated in detail. Results: In vitro expanded human chondrocytes showed progressive changes in gene expression during dedifferentiation. Strikingly, an overall decrease in total gene expression was detected. Genes in the Wnt and BMP pathways exhibited significant changes in expression. The non-canonical rather than the canonical Wnt pathway was found to be involved in the loss of collagen II synthesis. BMP2 was able to decelerate the dedifferentiation and reinforce the maintenance of chondrocyte phenotype in monolayer culture. DNA methylation was in part responsible for the expression downregulation of a set of genes. Conclusion: Our study revealed the roles of ERK, Wnt and BMP pathways as well as DNA methylation in chondrocyte dedifferentiation in monolayer culture. RNA human chondrocytes were allowed to dedifferentiate for 8 passages. RNA was isolated at week 0, 2 ,4, 6 and 8, which was subjected to whole genome gene expression analysis.

Project description:Microarray analysis of lncRNAs and mRNAs in the process of human hyaline chondrocyte dedifferentiation in vitro

Project description:Objective: When primary chondrocytes are cultured in monolayer, they undergo dedifferentiation during which they lose their phenotype and their capacity to form cartilage. Dedifferentiation is an obstacle for cell therapy for cartilage degeneration. In this study, we aimed to systemically evaluate the changes in gene expression during dedifferentiation of human articular chondrocytes to identify underlying mechanisms. Methods: RNA was isolated from monolayer-cultured primary human articular chondrocytes at serial passages. Gene expression was analyzed by microarray. Based on the microarray analysis, relevant genes and pathways were identified. Their functions in chondrocyte dedifferentiation were further investigated in detail. Results: In vitro expanded human chondrocytes showed progressive changes in gene expression during dedifferentiation. Strikingly, an overall decrease in total gene expression was detected. Genes in the Wnt and BMP pathways exhibited significant changes in expression. The non-canonical rather than the canonical Wnt pathway was found to be involved in the loss of collagen II synthesis. BMP2 was able to decelerate the dedifferentiation and reinforce the maintenance of chondrocyte phenotype in monolayer culture. DNA methylation was in part responsible for the expression downregulation of a set of genes. Conclusion: Our study revealed the roles of ERK, Wnt and BMP pathways as well as DNA methylation in chondrocyte dedifferentiation in monolayer culture.

Project description:Objectives: Articular cartilage damage has become a universal health burden. Despite the recent progresses in cell-based cartilage regeneration, chondrocyte dedifferentiation has compromised the clinical outcomes, which is frequently seen in chondrocyte expansion and osteoarthritis, involving functional phenotype loss. However, its concept remains elusive with unknown intermediate process and mechanisms. Here we demonstrated a time-lapse atlas of chondrocyte dedifferentiation, to provide molecular details and informative biomarkers for clinical chondrocyte evaluation. Methods: Single-cell RNA sequencing (scRNA-seq) was employed to dissect the chondrocyte dedifferentiation and identify distinct cellular subpopulations. To validate the findings, live-cell metabolic assay, high-resolution imaging and ¡°assay for transposase-accessible chromatin with high throughput sequencing¡± (ATAC-seq) were conducted. Using a chemical inhibitor BTB06584 affecting on mitochondrial F1F0ATPase, we revealed the recovery potential of early and late dedifferentiated chondrocytes. Results:Our findings shape a biphasic model consist of early and late dedifferentiation stages. Early dedifferentiated chondrocytes uniquely obtained a transient glycolytic phenotype with an activation of metabolic and anti-oxidant genes; late dedifferentiated chondrocytes exhibited ultrastructural changes including mitochondrion damages and stress-associated chromatin remodeling. Using a chemical inhibitor BTB06584, we revealed that early and late dedifferentiated chondrocytes possessed distinguished recovery potential from functional phenotype loss. BTB06584 treatment ameliorated early phenotype loss through inhibiting MAPK pathway. Notably, this two-stage transition was validated in human chondrocyte culture. An image-based approach was established for clinical utilization, to efficiently predict chondrocytes plasticity with stage-specific biomarkers. Conclusion: Thus this study lays a foundation for future clinical chondrocyte quality regulation and provides insights for deeper understanding of chondrocyte dedifferentiation.

Project description:Objectives: Articular cartilage damage has become a universal health burden. Despite the recent progresses in cell-based cartilage regeneration, chondrocyte dedifferentiation has compromised the clinical outcomes, which is frequently seen in chondrocyte expansion and osteoarthritis, involving functional phenotype loss. However, its concept remains elusive with unknown intermediate process and mechanisms. Here we demonstrated a time-lapse atlas of chondrocyte dedifferentiation, to provide molecular details and informative biomarkers for clinical chondrocyte evaluation. Methods: Single-cell RNA sequencing (scRNA-seq) was employed to dissect the chondrocyte dedifferentiation and identify distinct cellular subpopulations. To validate the findings, live-cell metabolic assay, high-resolution imaging and ¡°assay for transposase-accessible chromatin with high throughput sequencing¡± (ATAC-seq) were conducted. Using a chemical inhibitor BTB06584 affecting on mitochondrial F1F0ATPase, we revealed the recovery potential of early and late dedifferentiated chondrocytes. Results:Our findings shape a biphasic model consist of early and late dedifferentiation stages. Early dedifferentiated chondrocytes uniquely obtained a transient glycolytic phenotype with an activation of metabolic and anti-oxidant genes; late dedifferentiated chondrocytes exhibited ultrastructural changes including mitochondrion damages and stress-associated chromatin remodeling. Using a chemical inhibitor BTB06584, we revealed that early and late dedifferentiated chondrocytes possessed distinguished recovery potential from functional phenotype loss. BTB06584 treatment ameliorated early phenotype loss through inhibiting MAPK pathway. Notably, this two-stage transition was validated in human chondrocyte culture. An image-based approach was established for clinical utilization, to efficiently predict chondrocytes plasticity with stage-specific biomarkers. Conclusion: Thus this study lays a foundation for future clinical chondrocyte quality regulation and provides insights for deeper understanding of chondrocyte dedifferentiation.

Project description:Cartilage pellets generated from ectomesenchymal progeny of human pluripotent stem cells (hPSCs) in vitro eventually show signs of commitment of chondrocytes to hypertrophic differentiation. When transplanted subcutaneously, most of the surviving pellets were fully mineralized by 8 weeks. In contrast, treatment with the adenylyl cyclase activator, forskolin, in vitro resulted in slightly enlarged cartilage pellets containing an increased proportion of proliferating immature chondrocytes that expressed very low levels of hypertrophic/terminally matured chondrocyte-specific genes. Forskolin treatment also enhanced hyaline cartilage formation by reducing type I collagen gene expression and increasing sulfated glycosaminoglycan accumulation in the developed cartilage. Furthermore, forskolin treatment in vitro increased the frequency at which the cartilage pellets maintained unmineralized chondrocytes after subcutaneous transplantation. To elucidate the type of cartilage that forskolin preferentially promotes and potential molecular mechanisms involved in the forskolin-suppression of chondrocyte hypertrophic differentiation in vitro, we performed genome-wide, comparative transcriptomic analyses on the cartilage pellets formed from 3 to 4 independent pellet cultures of ectomesenchymal cells with or without forskolin treatment. RNAs were isolated on day 26-28 and mRNA-sequencing (RNA-seq) analyses were performed.

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:The purpose of this study was to understand the how the supression of H3K9me3 impacts the phenotype of chondrocytes during a monolayer expansion process which causes chondrocyte dedifferentiation. Therefore, we compared the mRNA expression profiles of chondrocytes isolated from H3K9M (inducible histone H3.3 lysine-to-methionine mutant) and H3WT (inducibly expressed wild-type H3.3) after 16 population doublings.

Project description:Long non-coding RNAs (lncRNAs) are expressed in a highly tissue-specific manner where they function in various aspects of cell biology, often as key regulators of gene expression. In this study we established a role for lncRNAs in chondrocyte differentiation. Using RNA sequencing we identified a human articular chondrocyte repertoire of lncRNAs from normal hip cartilage donated by neck of femur fracture patients. Of particular interest are lncRNAs upstream of the master chondrocyte transcription factor SOX9 locus. SOX9 is an HMG-box transcription factor which is essential for chondrocyte development by directing the expression of chondrocyte specific genes. Two of these lncRNAs are upregulated during chondrogenic differentiation of MSCs. Depletion of one of these lncRNA, LOC102723505, which we termed ROCR (regulator of chondrogenesis RNA), by RNAi disrupted MSC chondrogenesis, concomitant with reduced cartilage-specific gene expression and incomplete matrix component production, indicating an important role in chondrocyte biology. Specifically, SOX9 induction was significantly ablated in the absence of ROCR, and overexpression of SOX9 rescued the differentiation of MSCs into chondrocytes. Our work sheds further light on chondrocyte specific SOX9 expression and highlights a novel method of chondrocyte gene regulation involving a lncRNA.

Project description:A comprehensive analysis of Sox9 binding profiles in developing chondrocytes identified marked enrichment of an AP-1-like motif (Ohba et al. 2015). Here, we have explored the functional interplay between Sox9 and AP-1 in mammalian chondrocyte development. Among AP-1 family members, Jun and Fosl2 were highly expressed within prehypertrophic and early hypertrophic chondrocytes. Chromatin immunoprecipitation followed by DNA sequencing (ChIP-seq) showed a striking overlap in Jun- and Sox9-bound regions throughout the chondrocyte genome, a reflection of direct binding of each factor to target motifs in shared enhancers, and physical interactions of AP-1 with Sox9. In vitro expression analysis indicates that direct co-binding of Sox9 and AP-1 at target motifs enhanced target gene expression, while protein-protein interactions suppressed AP-1- and Sox9-driven transcription. Analysis of prehypertrophic chondrocyte removal of Sox9 demonstrated Sox9 was essential for hypertrophic chondrocyte development, while in vitro and ex vivo analyses showed AP-1 promotes chondrocyte hypertrophy. Sox9 and Jun co-bound and co-activated a Col10a1 enhancer in Sox9 and AP-1 motif-dependent manners consistent with their combined action promoting hypertrophic gene expression. Together, the data support a model where AP-1-family members promote Sox9-action in the transition of chondrocytes to a terminal hypertrophic program. Intersection of ChIP-seq data from Sox9 and AP-1 factor Jun, RNA-seq data from developing rib chondrocytes and Col10a1mCherry positive hypertrophic chondrocytes in neonatal mice to uncover regulation of Sox9 by AP-1 factors during chondrocyte hypertrophy.