These findings indicated that ALA might be a potential therapeutic agent for the protection of articular cartilage against progression of OA through inhibition of oxidative stress, ER stress, inflammatory cytokine secretion, and Wnt/β-catenin activation.
Icariin, a traditional Chinese medicine, has previously been demonstrated to promote chondrogenesis of bone marrow mesenchymal stem cells (BMSCs) in traditional 2D cell culture. The present study investigated whether icariin has the potential to promote stable chondrogenic differentiation of BMSCs without hypertrophy in a 3D microenvironment. BMSCs were cultivated in a self-assembling peptide nanofiber hydrogel scaffold in chondrogenic medium for 3 weeks. Icariin was added to the medium throughout the culture period at concentrations of 1×10−6 M. Chondrogenic differentiation markers, including collagen II and SRY-type high mobility group box 9 (SOX9) were detected by immunofluorescence, reverse transcription-quantitative polymerase chain reaction and toluidine blue staining. Hypertrophic differentiation was further assessed by detecting collagen X and collagen I gene expression levels and alkaline phosphatase activity. The results demonstrated that icariin significantly enhanced cartilage extracellular matrix synthesis and gene expression levels of collagen II and SOX9, and additionally promoted more chondrocyte-like rounded morphology in BMSCs. Furthermore, chondrogenic medium led to hypertrophic differentiation via upregulation of collagen X and collagen I gene expression levels and alkaline phosphatase activity, which was not potentiated by icariin. In conclusion, these results suggested that icariin treatment may promote chondrogenic differentiation of BMSCs, and inhibit the side effect of growth factor activity, thus preventing further hypertrophic differentiation. Therefore, icariin may be a potential compound for cartilage tissue engineering.
Objectives: Chronic nonbacterial osteomyelitis (CNO) is an auto-inflammatory bone disorder. Since the origin and development of CNO involve many complex immune processes, resulting in delayed diagnosis and lack of effective treatment. Although bioinformatics analysis has been utilized to seek key genes and pathways of CNO, only a few bioinformatics studies that focus on CNO pathogenesis and mechanisms have been reported. This study aimed to identify key biomarkers that could serve as early diagnostic or therapeutic markers for CNO. Methods: Two RNA-seq datasets (GSE133378 and GSE187429) were obtained from the gene expression omnibus (GEO). Weighted gene co-expression network analysis (WGCNA) and differentially expressed genes (DEGs) analysis were conducted to identify the correlated genes associated with CNO. After that, the auto-inflammatory genes mostly associated with CNO were yielding based on the GeneCards database and the CNO prediction model, which was created by the LASSO machine learning algorithms. According to the receiver operating characteristic (ROC) curves, the accuracy of the model and auto-inflammatory genes was verified by utilizing external datasets (GSE7014). Eventually, we performed clustering analysis by ConsensusClusterPlus. Results: Totally, eighty CNO-related genes were identified, which were significantly enriched in the biological process of regulation of actin filament organization, cell-cell junction organization and gamma-catenin binding. The mainly enriched pathways were Adherens junction, Viral carcinogenesis and Systemic lupus erythematosus. Two auto-inflammatory genes with high expression in CNO samples were identified by combing an optimal machine learning algorithm (LASSO) with GeneCards database. The external validation dataset (GSE187429) was utilized for ROC analysis of prediction model and two genes, and the results have well validation efficiency. Then, we found that the expression of the two genes differed between clusters based on consensus clustering analysis. Finally, the ceRNA network of lncRNA and small molecule compounds of the two auto-inflammatory genes were predicted. Conclusion: Two auto-inflammatory genes, HCG18/has-mir-147a/UTS2/MPO axis and the signal pathways identified in this study can help us understand the molecular mechanism of CNO formation and provide candidate targets for the diagnosis and treatment of CNO.
Chronic nonbacterial osteomyelitis (CNO) is an autoinflammatory bone disorder. The origin and development of CNO involve many complex immune processes, resulting in delayed diagnosis and a lack of effective treatment. Although bioinformatics analysis has been utilized to seek key genes and pathways in CNO, only a few bioinformatics studies that focus on CNO pathogenesis and mechanisms have been reported. This study aimed to identify key biomarkers that could serve as early diagnostic or therapeutic markers for CNO. Two RNA-seq datasets (GSE133378 and GSE187429) were obtained from the Gene Expression Omnibus (GEO). Weighted gene coexpression network analysis (WGCNA) and differentially expressed gene (DEG) analysis were conducted to identify the genes associated with CNO. Then, the autoinflammatory genes most associated with CNO were identified based on the GeneCards database and a CNO prediction model, which was created by the LASSO machine learning algorithm. The accuracy of the model and effects of the autoinflammatory genes according to receiver operating characteristic (ROC) curves were verified in external datasets (GSE7014). Finally, we performed clustering analysis with ConsensusClusterPlus. In total, eighty CNO-related genes were identified and were significantly enriched in the biological processes regulation of actin filament organization, cell–cell junction organization and gamma-catenin binding. The main enriched pathways were adherens junctions, viral carcinogenesis and systemic lupus erythematosus. Two autoinflammatory genes with high expression in CNO samples were identified by combining an optimal machine learning algorithm (LASSO) with the GeneCards database. An external validation dataset (GSE187429) was utilized for ROC analysis of the prediction model and two genes, and the results indicated good efficiency. Then, based on consensus clustering analysis, we found that the expression of UTS2 and MPO differed between clusters. Finally, the ceRNA network of lncRNAs and the small molecule compounds targeting the two autoinflammatory genes were predicted. The identification of two autoinflammatory genes, the HCG18/has-mir-147a/UTS2/MPO axis and signalling pathways in this study can help us understand the molecular mechanism of CNO formation and provides candidate targets for the diagnosis and treatment of CNO.
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