Objective. To use an in vitro model of chondrogenesis to identify microRNAs (miRNAs) with a functional role in cartilage homeostasis.Methods. The expression of miRNAs was measured in the ATDC5 cell model of chondrogenesis using microarray and was verified using quantitative reverse transcription-polymerase chain reaction. MicroRNA expression was localized by in situ hybridization. Predicted miRNA target genes were validated using 3-untranslated region-Luc reporter plasmids containing either wild-type sequences or mutants of the miRNA target sequence. Signaling through the Smad pathway was measured using a (CAGA) 12 -Luc reporter.Results. The expression of several miRNAs was regulated during chondrogenesis. These included 39 miRNAs that are coexpressed with miRNA-140 (miR-140), which is known to be involved in cartilage homeostasis and osteoarthritis (OA). Of these miRNAs, miR-455 resides within an intron of COL27A1 that encodes a cartilage collagen. When human OA cartilage was compared with cartilage obtained from patients with femoral neck fractures, the expression of both miR-140-5p and miR-455-3p was increased in OA cartilage. In situ hybridization showed miR-455-3p expression in the developing limbs of chicks and mice and in human OA cartilage. The expression of miR-455-3p was regulated by transforming growth factor  (TGF) ligands, and miRNA regulated TGF signaling. ACVR2B, SMAD2, and CHRDL1 were direct targets of miR-455-3p and may mediate its functional impact on TGF signaling.Conclusion. MicroRNA-455 is expressed during chondrogenesis and in adult articular cartilage, where it can regulate TGF signaling, suppressing the Smad2/3 pathway. Diminished signaling through this pathway during the aging process and in OA chondrocytes is known to contribute to cartilage destruction. We propose that the increased expression of miR-455 in OA exacerbates this process and contributes to disease pathology.Osteoarthritis (OA) is a degenerative joint disease characterized by degradation of articular cartilage, thickening of subchondral bone, and formation of osteophytes (1). The etiology of OA is complex, with the contribution of genetic, developmental, biochemical, and biomechanical factors. Chondrocytes are the only cells in cartilage and are responsible for the synthesis and turnover of extracellular matrix (ECM), which is crucial to tissue function.During development, mesenchymal cells aggregate and differentiate into chondrocytes, which undergo a series of differentiation events: proliferation, hypertrophy, terminal differentiation, mineralization, and programmed cell death. Blood vessels penetrate the calcified matrix, bringing in osteoblasts that build new bone. The cartilage model grows by rounds of chondrocyte cell
We asked if ancestral liver damage leads to heritable reprogramming of hepatic wound-healing. We discovered that male rats with a history of liver damage transmit epigenetic suppressive adaptation of the fibrogenic component of wound-healing through male F1 and F2 generations. Underlying this adaptation was reduced generation of liver myofibroblasts, increased hepatic expression of antifibrogenic PPAR-γ and decreased expression of profibrogenic TGF-β1. Remodelling of DNA methylation and histone acetylation underpinned these alterations in gene expression. Sperm from rats with liver fibrosis were enriched for H2A.Z and H3K27me3 at PPAR-γ chromatin. These sperm chromatin modifications were transmittable by adaptive serum transfer from fibrotic rats and were induced in stem cells exposed to myofibroblast-conditioned media. A myofibroblast secreted soluble factor therefore stimulates heritable epigenetic signatures to sperm so as to adapt fibrogenesis in offspring. Humans with mild liver fibrosis display PPAR-γ promoter hypomethylation compared with severe fibrotics, thus lending support for epigenetic regulation of fibrosis.
ObjectiveThe aim of this study was to characterize the genome-wide DNA methylation profile of chondrocytes from knee and hip cartilage obtained from patients with osteoarthritis (OA) and hip cartilage obtained from patients with femoral neck fracture, providing the first comparison of DNA methylation between OA and non-OA hip cartilage, and between OA hip and OA knee cartilage.MethodsThe study was performed using the Illumina Infinium HumanMethylation450 BeadChip array, which allows the annotation of ∼480,000 CpG sites. Genome-wide methylation was assessed in chondrocyte DNA extracted from 23 hip OA patients, 73 knee OA patients, and 21 healthy hip control patients with femoral neck fracture.ResultsAnalysis revealed that chondrocytes from the hip cartilage of OA patients and healthy controls have unique methylation profiles, with 5,322 differentially methylated loci (DMLs) identified between the 2 groups. In addition, a comparison between hip and knee OA chondrocytes revealed 5,547 DMLs between the 2 groups, including DMLs in several genes known to be involved in the pathogenesis of OA. Hip OA samples were found to cluster into 2 groups. A total of 15,239 DMLs were identified between the 2 clusters, with an enrichment of genes involved in inflammation and immunity. Similarly, we confirmed a previous report of knee OA samples that also clustered into 2 groups.ConclusionWe demonstrated that global DNA methylation using a high-density array can be a powerful tool in the characterization of OA at the molecular level. Identification of pathways enriched in DMLs between OA and OA-free cartilage highlight potential etiologic mechanisms that are involved in the initiation and/or progression of the disease and that could be therapeutically targeted.
MicroRNAs have been shown to function in cartilage development and homeostasis, as well as in progression of osteoarthritis. The objective of the current study was to identify microRNAs involved in the onset or early progression of osteoarthritis and characterise their function in chondrocytes. MicroRNA expression in mouse knee joints post-DMM surgery was measured over 7 days. Expression of miR-29b-3p was increased at day 1 and regulated in the opposite direction to its potential targets. In a mouse model of cartilage injury and in end-stage human OA cartilage, the miR-29 family was also regulated. SOX9 repressed expression of miR-29a-3p and miR-29b-3p via the 29a/b1 promoter. TGFβ1 decreased expression of miR-29a, b, and c (3p) in primary chondrocytes, whilst IL-1β increased (but LPS decreased) their expression. The miR-29 family negatively regulated Smad, NFκB, and canonical WNT signalling pathways. Expression profiles revealed regulation of new WNT-related genes. Amongst these, FZD3, FZD5, DVL3, FRAT2, and CK2A2 were validated as direct targets of the miR-29 family. These data identify the miR-29 family as microRNAs acting across development and progression of OA. They are regulated by factors which are important in OA and impact on relevant signalling pathways.Key messagesExpression of the miR-29 family is regulated in cartilage during osteoarthritis.SOX9 represses expression of the miR-29 family in chondrocytes.The miR-29 family is regulated by TGF-β1 and IL-1 in chondrocytes.The miR-29 family negatively regulates Smad, NFκB, and canonical Wnt signalling.Several Wnt-related genes are direct targets of the miR-29 family.Electronic supplementary materialThe online version of this article (doi:10.1007/s00109-015-1374-z) contains supplementary material, which is available to authorized users.
Osteoarthritis (OA) is a complex multifactorial disease with a strong genetic component. Several studies have suggested or identified epigenetic events that may play a role in OA progression and the gene expression changes observed in diseased cartilage. The aim of this review is to inform about current research in epigenetics and epigenetics in OA. Epigenetic mechanisms include DNA methylation, histone modifications, and microRNAs. Collectively, these enable the cell to respond quickly to environmental changes and can be inherited during cell division. However, aberrant epigenetic modifications are associated with a number of pathological conditions, including OA. Advancements in epigenetic research suggests that global analysis of such modifications in OA are now possible, however, with the exception of microRNAs, it will be a significant challenge to demonstrate how such events impact on the disease.
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