Osteoarthritis (OA) is a common disease characterized by cartilage degeneration and joint remodeling. The underlying molecular changes underpinning disease progression are incompletely understood. We investigated genes and pathways that mark OA progression in isolated primary chondrocytes taken from paired intact versus degraded articular cartilage samples across 38 patients undergoing joint replacement surgery (discovery cohort: 12 knee OA, replication cohorts: 17 knee OA, 9 hip OA patients). We combined genome-wide DNA methylation, RNA sequencing, and quantitative proteomics data. We identified 49 genes differentially regulated between intact and degraded cartilage in at least two –omics levels, 16 of which have not previously been implicated in OA progression. Integrated pathway analysis implicated the involvement of extracellular matrix degradation, collagen catabolism and angiogenesis in disease progression. Using independent replication datasets, we showed that the direction of change is consistent for over 90% of differentially expressed genes and differentially methylated CpG probes. AQP1, COL1A1 and CLEC3B were significantly differentially regulated across all three –omics levels, confirming their differential expression in human disease. Through integration of genome-wide methylation, gene and protein expression data in human primary chondrocytes, we identified consistent molecular players in OA progression that replicated across independent datasets and that have translational potential.
Osteoarthritis (OA) affects in excess of 40% of individuals over the age of 70 years1, and is a leading cause of pain and loss of physical function2. The molecular mechanisms underlying OA remain incompletely understood and there is no curative therapy for OA; disease progression culminates in joint replacement surgery. OA is a complex disease, with both heritable and environmental factors contributing to susceptibility3.
Cartilage degeneration is one of the key features of OA. Cartilage tissue is readily accessible at joint replacement surgery, providing an opportunity to characterize the molecular processes underpinning disease development in the right tissue, both to improve our fundamental understanding of disease biology and to identify novel therapeutic opportunities. In recent years, –omics studies in OA have expanded our understanding of disease pathogenesis, reviewed in refs 4,5,6,7. Here we apply integrated multi-omics (DNA CpG methylation, RNA sequencing and quantitative proteomics) in knee OA tissue to obtain a comprehensive molecular portrait of cartilage degeneration (Fig. 1a). The fundamental question here addresses the biological processes underpinning disease progression within the OA joint, which is of direct clinical relevance to patients suffering from OA. To achieve this, we collected individually-matched pairs of cartilage tissue from patients undergoing joint replacement surgery, with one sample demonstrating advanced degenerative change and the other demonstrating little or no evidence of cartilage degeneration. The findings were then replicated in several independent populations of patients undergoing joint replacement. By integrating all three of methylation, gene expression, and protein abundance data, we discover disease processes with involvement across multiple levels, and reveal novel and robustly replicating molecular players with translational potential.
For full details of methods see Supplementary Methods.
Patients and samples
Osteochondral samples were collected from 38 patients undergoing total joint replacement for OA (discovery cohort: 12 knee OA patients; 2 separate replication cohorts: 17 knee OA patients, 9 hip OA patients). Cartilage was separated from bone and chondrocytes were extracted from each sample. DNA, RNA, and protein were extracted from the isolated chondrocytes of each sample. All patients provided full written informed consent prior to participation. We obtained two cartilage samples from each patient. Knee samples were scored using the OARSI cartilage classification system8, 9: one sample with high OARSI grade signifying high-grade degeneration (“degraded sample”), and one sample with low OARSI grade signifying healthy tissue or low-grade degeneration (“intact sample”) (Supplementary Fig. S1). Hip samples were classified macroscopically and visually as high-grade (“degraded”) or low-grade (“intact”), details see Supplementary Methods.
Proteomics (discovery cohort)
LC-MS analysis was performed on the Dionex Ultimate 3000 UHPLC system coupled with the high-resolution LTQ Orbitrap Velos mass spectrometer. Proteins were defined as differentially abundant if the absolute median abundance ratio between degraded and intact samples was ≥ 0.75, the absolute median abundance ratio was greater than the standard deviation of abundance ratios, and the protein was detected in paired samples from at least 5 of 11 patients post-QC.
RNA-seq (discovery cohort)
Multiplexed libraries were sequenced on the Illumina HiSeq 2000 (75 bp paired-end read length) and individual indexed library BAM files were produced. Reads that passed quality control (QC) were re-aligned using tophat210, and reads aligning to each gene in each sample were counted using the HTSeq package11. Absolute transcript abundance was calculated using the FPKM (fragments per kilobase of transcript per million fragments mapped) measure across 15,418 genes post-QC. We used edgeR v3.012 to identify differentially expressed genes, applying a generalized linear model for tissue status (degraded or intact) with individual ID as covariate, and defined significance at 5% false-discovery rate (FDR).
Methylation (discovery cohort)
Methylation was assayed using the Illumina 450k BeadChip. Data were parsed and QCed using ChAMP13; the probe beta values were quantile-normalized using the ‘dasen’ method from the wateRmelon package14. Differential methylation on 425,694 probes post-QC was tested using the CpGassoc package15, applying a linear model for tissue status at each probe, with individual ID as covariate.
Following previous analyses16, differentially methylated regions (DMRs) were defined as regions of at least 3 probes with FDR ≤ 5% (DMPs) and no more than 3 non-significant probes, with no more than 1 kb between adjacent probes. We used bedtools17 to identify genes overlapping each DMR, extending gene boundaries to include likely promoter regions.
For a promoter-level analysis, we used the probe annotations from ChAMP to assign promoter probes to each gene. After computing the mean beta value in the promoter of each gene in each sample, we used a paired t-test to identify genes with differential promoter-region methylation between degraded and intact samples. Significance was set at 5% FDR.
Replication of gene expression and methylation changes
Gene expression and DNA methylation in both replication cohorts were measured using the same procedure as for the discovery data. We considered the expression of 14,762 genes that passed QC across all datasets; this included 332 of 349 genes with FDR ≤ 5% in the knee discovery data.
We considered 416,437 probes that passed QC across all datasets; this included 9,723 of 9,867 probes with FDR ≤ 5% in the knee discovery data (“DMPs”).
In silico replication
We carried out an additional replication analysis for gene expression changes using an available published dataset from the ongoing Research Arthritis and Articular Cartilage (RAAK) study18. This dataset comprised a comparison of affected and macroscopically preserved OA cartilage from 33 patients undergoing total joint replacement surgery (22 with hip OA, 11 with knee OA), measured using the Illumina HumanHT-12 v3 microarrays.
Gene set analyses
We tested whether particular biological gene sets were enriched among significant genes from each of the RNA-seq, methylation, and proteomics datasets. We used KEGG19, Reactome20, and, separately, Gene Ontology (GO) annotations21. Genes annotated to the same term were treated as a “pathway”. Enrichment was assessed using a 1-sided hypergeometric test, with significance at 5% FDR. Empirical p-values for the enrichments were obtained from randomisations.
For each gene set, we asked whether the association across the three –omics datasets (calculated as geometric mean of the p-values) was higher than expected by chance, obtaining empirical p-values from 100,000 randomisations.
Ethical approval information
The study was approved by Oxford NHS REC C (10/H0606/20). Tissue samples were collected under National Research Ethics approval reference 15/SC/0132, South Yorkshire and North Derbyshire Musculoskeletal Biobank, University of Sheffield; and under National Research Ethics approval reference 11/EE/0011, Cambridge Biomedical Research Centre Human Research Tissue Bank, Cambridge University Hospitals, UK. All participants provided written informed consent. All methods were carried out in accordance with the relevant guidelines and regulations.
All genome-wide summary statistics generated in the discovery component of this study are available as Supplementary Tables. All discovery RNA sequencing data are available in the EGA repository, https://www.ebi.ac.uk/ega/studies/EGAS00001001203. All discovery methylation data are available in the EGA repository, https://www.ebi.ac.uk/ega/studies/EGAS00001001213. The discovery proteomics data has been deposited in the PRIDE archive under study ID PXD002014 [publication in process].
We compared the degraded and intact tissue across patient-matched samples.
We identified 209 proteins with evidence of differential abundance (Supplementary Table S1): 90 at higher and 119 at lower abundance in the degraded samples. We confirmed the quality of the data using an orthogonal label-free approach and, separately, Western blotting (see Supplementary Note).
We identified 349 differentially expressed genes: 296 genes showed higher and 53 lower expression levels in the degraded samples (Supplementary Table S2). One of the most strongly down-regulated genes in degraded cartilage was CHRDL2. The corresponding protein was also found at lower abundance in degraded cartilage and we confirmed its expression in cartilage by immunohistochemistry (Supplementary Fig. S2). CHRDL2 is a bone morphogenetic protein (BMP) inhibitor that has been reported to be lost from chondrocytes of the superficial zone and shifted to the middle zone in OA cartilage in a targeted study22.
We identified 9,896 differentially methylated probes (DMPs) (Supplementary Table S3), and 271 differentially methylated regions (DMRs) composed of multiple differentially methylated CpG sites, overlapping 296 unique genes (Supplementary Table S4).
Integration across multiple –omics levels
Methylation, RNA sequencing, and proteomics
We identified 49 genes with evidence of differential regulation from at least two of the –omics analyses (Supplementary Table S5). Three genes demonstrated significant evidence for involvement in OA progression across all three levels: AQP1, COL1A1 and CLEC3B (Fig. 1b). All three genes were up-regulated in degraded tissue in both the RNA-seq and proteomics analyses (Fig. 2a). AQP1 and COL1A1 showed a consistent decrease in methylation of all CpG probes in their associated DMRs (commensurate with an increase in transcription), while the DMR associated with CLEC3B showed evidence of increased methylation. Using IHC we independently confirmed the presence of AQP1, COL1A1 and CLEC3B in articular cartilage chondrocytes (Supplementary Fig. S2). We also replicated the direction of gene expression change for all three genes in independent data (see below and Supplementary Table S6).
Of the 49 genes with evidence of differential regulation on at least two molecular levels, 33 add substantive evidence to genes previously reported and 16 genes (33%) have not previously been implicated in OA (Supplementary Table S5).
Proteomics and RNA sequencing
Among the 209 proteins with evidence of differential abundance in the proteomics data, 31 were also differentially expressed between degraded and intact samples at the RNA level (hypergeometric p = 5.3 × 10−7, Fig. 1b). Twenty-six of these 31 genes showed concordant directions of changes at both the protein and RNA level (binomial p = 0.0002). Five genes were over-expressed at the RNA level and less abundant at the protein level in the degraded tissue (COL4A2, CXCL12, FGF10, HTRA3 and WNT5B); all five are annotated as secreted proteins in the Human Protein Atlas23 (see Supplementary Note).
Using all samples irrespective of tissue status, we found a significant correlation between gene expression levels and protein abundance (Spearman’s rho = 0.29, p < 2.2 × 10−16, Supplementary Note and Supplementary Fig. S3). Considering the RNA and protein changes in degraded compared to intact samples (Fig. 2a), we also identified a significant positive correlation (Pearson’s r = 0.17, p < 2.2 × 10−16). This correlation became substantially higher when we only considered the 31 genes that were differentially expressed in both datasets (Pearson’s r = 0.43, p = 0.01).
Methylation and RNA sequencing
Sixteen of the genes overlapping a DMR were also differentially transcribed (Fig. 1b). In the direct comparison of methylation and gene expression using all samples irrespective of tissue status, we found the expected negative correlation between promoter region methylation and gene expression (Spearman’s rho = −0.43, p < 2.2 × 10−16, Supplementary Fig. S3). Based on the comparison of intact to degraded cartilage, the log-fold-changes in RNA expression and the differences in mean promoter region methylation values demonstrated a small but highly significant correlation (Pearson’s r = −0.08, p < 2.2 × 10−16, Fig. 2b, Supplementary Table S7). The correlation became substantially higher when we considered the 39 genes with significant differences at both the promoter methylation and transcription levels (Pearson’s r = −0.48, p = 0.002).
Replication of gene expression and methylation changes
We found good correlation between the global gene expression log-fold changes and the methylation log-fold changes estimated in the discovery and in the knee and, separately, hip replication data (Fig. 3a,b, Pearson r 0.5–0.9, p < 10−15) and excellent replication rates for differentially expressed genes and probes with differential methylation (Fig. 3c,d, over 90% have same direction of change in replication data and at least 47% reach nominal significance, Supplementary Table S8).
We specifically considered the 49 genes with evidence from at least two –omics levels. Of these, 47 had gene expression data in the discovery and both replication datasets; the direction of change replicated at nominal significance for 36 genes in the knee and for 26 genes in the hip replication data (Supplementary Table S6). Notably, the direction of change replicated in at least one of the knee and hip replication datasets at nominal significance for 13 of the 16 genes that have not previously been associated with OA (Supplementary Table S6).
We additionally pursued replication in a further independent, published microarray gene expression dataset from the RAAK study18. This study used pooled knee and hip samples, as they found good agreement between the pooled and joint-stratified analyses18; to increase power, we also used the pooled data as in silico replication. Despite the difference in genomics technology (RNA-seq in discovery, microarray in RAAK), we again found good agreement of the log-fold-changes for the differentially expressed genes from the discovery data (over 60% have same direction of effect, Pearson r in 0.24–0.43 at p ≤ 0.003, see Supplementary Note).
Pathways involved in OA progression
We identified biological processes with consistent evidence of involvement in OA progression at multiple levels (Fig. 4, Supplementary Fig. S4, Supplementary Tables S9–S10). A strong theme is cartilage matrix regulation, degeneration, and disassembly.
Positive regulation of ERK1/2 cascade, heparin-binding and platelet activation were also enriched at multiple molecular levels and are interconnected through common genes (Supplementary Note). We also found enrichment of genes involved in the regulation of angiogenesis at multiple levels, implicating pathways involved in blood vessel and nervous system formation (NCAM signaling for neurite outgrowth and PDGF signaling). The growth of blood vessels and nerves are closely linked processes that share regulatory mechanisms, including the ERK cascade and heparin-binding proteins24. Indeed, histological examination of the samples we investigated showed greater blood vessel ingrowth in tissues with more advanced OA (Supplementary Fig. S1).
Drug repurposing potential
To identify existing drugs that could be repurposed for OA, we searched Drugbank25 for the 49 genes differentially regulated across at least two –omics levels. We identified ten agents with investigational or established actions on nine of the dysregulated proteins, which already have Food and Drug Administration Marketing Authorization for use in humans (Table 1). Among them are non-steroidal anti-inflammatory agents active against prostacyclin synthase (NSAIDs), which already have marketing authorisation for the symptomatic treatment of OA. Our search also identified phylloquinone (vitamin K1), an agonist of osteocalcin (BGLAP gene). Periostin (POSTN gene), a protein with elevated expression in OA in this study and others26,27,28, is a vitamin K-dependent protein that induces cartilage degeneration29. A recent study has associated sub-clinical vitamin K deficiency with knee OA incidence30, adding evidence that this compound could be a disease-modifying agent in OA.
Characterisation of the molecular landscape of OA is now increasingly feasible and catalyzed by technological advances in functional genomics, and the accessibility of the relevant tissue at joint replacement surgery. Indeed, the field of functional genomics in OA is now budding31. Previous studies of osteoarthritis have investigated methylation32, 33, transcription18, 34,35,36,37, or protein expression38, 39 separately, or a combination of up to two of these –omics assays16, 40, 41, some with the addition of genetic data42. By contrast, this study provides a systematic analysis of biological changes involved in OA across genome-wide methylation, gene and protein expression levels.
We identify 49 genes with evidence of changes between intact and degraded cartilage on multiple molecular levels, including some novel molecular players in OA. We provide robustly-replicating evidence with convergence of all three –omics levels of the involvement of AQP1, COL1A1, and CLEC3B in disease progression.
AQP1 encodes aquaporin-1, a protein that facilitates water transport across biological membranes. Chondrocyte swelling and increased cartilage hydration has been suggested as an important mechanism in OA43. AQP1 has been found to be over-expressed in the meniscus of a rat model of knee OA44 and in degraded compared to intact articular cartilage in human patients with knee OA45. CLEC3B encodes tetranectin, which binds human tissue plasminogen activator (tPA)46. CLEC3B has previously been found to be up-regulated in OA34, 47. COL1A1 is one of several collagens that were differentially abundant at both the RNA and protein levels (see Supplementary Table S5). Collagens are the main structural components of cartilage and collagen dysregulation plays an important role in OA48, 49. A recent study identified up-regulation of COL1A1 in synovium from humans with end-stage OA, in the synovium of mice with induced OA and in human fibroblasts stimulated with TGF-β50. Moreover, the products of AQP1 and CLEC3B are targeted by existing drugs approved for human use: aquaporin-1 is inhibited by Acetazolamide, a carbonic anhydrase inhibitor diuretic agent, and tetranectin is bound by Tenecteplase, a thromobolytic agent (Table 1).
We further identify previously unreported genes with concordant molecular changes in the degraded tissue on multiple levels, and with robust replication in independent datasets. MAP1A and MAP1B were both significantly up-regulated in degraded cartilage at the RNA and protein levels (Fig. 2a). These proteins are mainly expressed in the brain and involved in regulating the neural cytoskeleton51. Cytoskeletal regulation is thought to be an important process in OA52 and recently these proteins were implicated in bone formation53. PXDN was up-regulated at the RNA level, confirmed by replication, and overlapped two hypo-methylated DMRs. PXDN encodes peroxidasin, which is secreted into the extracellular matrix and catalyses collagen IV cross-linking54. The other replicated genes not previously implicated in OA (Supplementary Table S6) have relatively little characterisation.
ANPEP (aminopeptidase E) is a broad specificity aminopeptidase that has previously been detected in the synovial fluid of OA patients55 and therefore has potential as a novel OA biomarker. CHRDL2 is a bone morphogenetic protein (BMP) inhibitor that has been reported to be lost from chondrocytes of the superficial zone and shifted to the middle zone in OA cartilage in a targeted study22. WNT5B, a ligand for frizzled receptors in the WNT signaling pathway, has been found to be differentially transcribed in osteoarthritic bone, consistent with current understanding that OA is a disease involving both cartilage and bone56.
We identify extracellular matrix organization, collagen catabolism and angiogenesis as biological pathways that have significant association with disease progression, in agreement with the consensus findings of previous methylation and gene expression studies of OA7. These results corroborate that increased ECM turnover is a crucial component in OA pathogenesis. We found suggestive evidence of a link between some of these pathways and genetic OA risk loci (see Supplementary Note, Supplementary Table S11). These signals would not have been identified directly from GWAS data, highlighting the importance of synthesizing information from multiple molecular levels to obtain a more powerful integrated view. Follow-up mechanistic studies will be required before causal relationships between the identified pathways and OA progression can be established. In the chondrocyte, we found little evidence of differential inflammatory pathway activity between the intact and degraded samples57, 58. This is not surprising, as all of the patients studied here had a diagnosis of OA and clinically advanced disease in at least one location within the joint. Inflammatory mediators are soluble factors present throughout the joint, to which both the healthy and the diseased chondrocyte populations are potentially exposed, and for which the regulatory molecules may differ compared to the articular cartilage tissue studied here.
Based on our discovery data, we estimate that ~95% of significantly different genes identified in this study are true positives (Supplementary Fig. S5). The replication data confirm the high true positive rate and yield independent strong evidence for multiple novel OA genes. This shows that the gene expression and methylation changes identified are robust. Within the constraints of this study, the changes between intact and degraded OA cartilage are largely joint-independent. Further work will be needed to narrow down which individual gene-level differences between intact and degraded cartilage are joint-independent and which are specific to a joint. This work is complementary to previous studies which examined differences in lesion-distant cartilage between joints59 or by pooling intact and degraded cartilage16, as neither of these studies examined differences between intact and degraded cartilage, and whether such differences are joint-independent.
Notably, this study is a proof-of-concept for integrative deep molecular phenotyping across methylation, gene expression, and protein abundance. As such, it was not powered to provide an exhaustive list of molecular targets and pathways. Indeed, we estimate that only ~10% of the true differentially expressed genes are statistically significant in this study (Supplementary Fig. S5). The sample size could also affect the degree of overlap and agreement between the methylation, gene expression, and protein abundance (this overlap could also be affected by difficulties in assigning the effects of methylation changes to genes: for example, it is possible that the expression of a gene is affected by methylation changes in a distal enhancer, or that a given gene contains an enhancer region for a different gene, and thus methylation of the first gene also affects the expression of the second). Larger sample sizes will be required for a more powerful characterisation of the molecular changes occurring with disease progression. Moreover, investigations of further OA-relevant cell types (including synoviocytes and adipocytes) will be necessary to identify disease-related changes in other tissues, and the biological mechanisms specific to such tissues.
In summary, the integrative functional genomics approach undertaken here has identified biological changes in disease-relevant tissues, highlighting three genes and several pathways that are involved on all three levels examined. Moreover, the approach identified nine genes with changes on multiple molecular levels that are already targeted by drugs approved for human use, highlighting the potential of discovering targets for intervention. These drugs have established safety profiles and pharmacokinetic data for use in humans, which would shorten the investigative pipeline to clinical use in OA. These agents cover a broad range of mechanisms of action and represent novel investigational targets for ‘first in disease’ studies of OA progression. Further studies will be necessary to comprehensively characterize the molecular signatures of OA.
Vos, T. et al. Years lived with disability (YLDs) for 1160 sequelae of 289 diseases and injuries 1990–2010: a systematic analysis for the Global Burden of Disease Study 2010. The Lancet 380, 2163–2196, doi:10.1016/s0140-6736(12)61729-2 (2012).
Dieppe, P. A. & Lohmander, L. S. Pathogenesis and management of pain in osteoarthritis. The Lancet 365, 965–973, doi:10.1016/s0140-6736(05)71086-2 (2005).
Valdes, A. M. & Spector, T. D. Genetic epidemiology of hip and knee osteoarthritis. Nat Rev Rheumatol 7, 23–32, doi:10.1038/nrrheum.2010.191 (2011).
Reynard, L. N. & Loughlin, J. The genetics and functional analysis of primary osteoarthritis susceptibility. Expert Rev. Mol. Med. 15, doi:10.1017/erm.2013.4 (2013).
Ruiz-Romero, C., Fernández-Puente, P., Calamia, V. & Blanco, F. J. Lessons from the proteomic study of osteoarthritis. Expert Review of Proteomics 12, 433–443, doi:10.1586/14789450.2015.1065182 (2015).
Ramos, Y. F. & Meulenbelt, I. The role of epigenetics in osteoarthritis: current perspective. Curr Opin Rheumatol. doi:10.1097/bor.0000000000000355 (2016).
Steinberg, J. & Zeggini, E. Functional genomics in osteoarthritis: Past, present, and future. Journal of orthopaedic research: official publication of the Orthopaedic Research Society 34, 1105–1110, doi:10.1002/jor.23296 (2016).
Mankin, H. J., Dorfman, H., Lippiello, L. & Zarins, A. Biochemical and metabolic abnormalities in articular cartilage from osteo-arthritic human hips. II. Correlation of morphology with biochemical and metabolic data. The Journal of bone and joint surgery. American volume 53, 523–537 (1971).
Pearson, R. G., Kurien, T., Shu, K. S. S. & Scammell, B. E. Histopathology grading systems for characterisation of human knee osteoarthritis – reproducibility, variability, reliability, correlation, and validity. Osteoarthritis and Cartilage 19, 324–331, doi:10.1016/j.joca.2010.12.005 (2011).
Kim, D. et al. TopHat2: accurate alignment of transcriptomes in the presence of insertions, deletions and gene fusions. Genome Biology 14, R36, doi:10.1186/gb-2013-14-4-r36 (2013).
Anders, S., Pyl, P. T. & Huber, W. HTSeq–a Python framework to work with high-throughput sequencing data. Bioinformatics 31, 166–169, doi:10.1093/bioinformatics/btu638 (2014).
Robinson, M. D., McCarthy, D. J. & Smyth, G. K. edgeR: a Bioconductor package for differential expression analysis of digital gene expression data. Bioinformatics 26, 139–140, doi:10.1093/bioinformatics/btp616 (2009).
Morris, T. J. et al. ChAMP: 450k Chip Analysis Methylation Pipeline. Bioinformatics 30, 428–430, doi:10.1093/bioinformatics/btt684 (2014).
Pidsley, R. et al. A data-driven approach to preprocessing Illumina 450K methylation array data. BMC Genomics 14, 293, doi:10.1186/1471-2164-14-293 (2013).
Barfield, R. T., Kilaru, V., Smith, A. K. & Conneely, K. N. CpGassoc: an R function for analysis of DNA methylation microarray data. Bioinformatics 28, 1280–1281, doi:10.1093/bioinformatics/bts124 (2012).
den Hollander, W. et al. Knee and hip articular cartilage have distinct epigenomic landscapes: implications for future cartilage regeneration approaches. Annals of the Rheumatic Diseases 73, 2208–2212, doi:10.1136/annrheumdis-2014-205980 (2014).
Quinlan, A. R. & Hall, I. M. BEDTools: a flexible suite of utilities for comparing genomic features. Bioinformatics 26, 841–842, doi:10.1093/bioinformatics/btq033 (2010).
Ramos, Y. F. M. et al. Genes Involved in the Osteoarthritis Process Identified through Genome Wide Expression Analysis in Articular Cartilage; the RAAK Study. PLoS ONE 9, e103056, doi:10.1371/journal.pone.0103056 (2014).
Kanehisa, M. KEGG: Kyoto Encyclopedia of Genes and Genomes. Nucleic Acids Research 28, 27–30, doi:10.1093/nar/28.1.27 (2000).
Matthews, L. et al. Reactome knowledgebase of human biological pathways and processes. Nucleic Acids Research 37, D619–D622, doi:10.1093/nar/gkn863 (2009).
Binns, D. et al. QuickGO: a web-based tool for Gene Ontology searching. Bioinformatics 25, 3045–3046, doi:10.1093/bioinformatics/btp536 (2009).
Nakayama, N. A novel chordin-like BMP inhibitor, CHL2, expressed preferentially in chondrocytes of developing cartilage and osteoarthritic joint cartilage. Development 131, 229–240, doi:10.1242/dev.00901 (2004).
Uhlen, M. et al. Tissue-based map of the human proteome. Science 347, 1260419–1260419, doi:10.1126/science.1260419 (2015).
Mapp, P. I. & Walsh, D. A. Mechanisms and targets of angiogenesis and nerve growth in osteoarthritis. Nat Rev Rheumatol 8, 390–398, doi:10.1038/nrrheum.2012.80 (2012).
Law, V. et al. DrugBank 4.0: shedding new light on drug metabolism. Nucleic Acids Research 42, D1091–D1097, doi:10.1093/nar/gkt1068 (2013).
Attur, M. et al. Elevated expression of periostin in human osteoarthritic cartilage and its potential role in matrix degradation via matrix metalloproteinase-13. The FASEB Journal 29, 4107–4121, doi:10.1096/fj.15-272427 (2015).
Chijimatsu, R. et al. Expression and pathological effects of periostin in human osteoarthritis cartilage. BMC Musculoskelet Disord 16, 215, doi:10.1186/s12891-015-0682-3 (2015).
Lourido, L. et al. Quantitative Proteomic Profiling of Human Articular Cartilage Degradation in Osteoarthritis. J. Proteome Res. 13, 6096–6106, doi:10.1021/pr501024p (2014).
Coutu, D. L. et al. Periostin, a Member of a Novel Family of Vitamin K-dependent Proteins, Is Expressed by Mesenchymal Stromal Cells. Journal of Biological Chemistry 283, 17991–18001, doi:10.1074/jbc.m708029200 (2008).
Misra, D. et al. Vitamin K Deficiency Is Associated with Incident Knee Osteoarthritis. The American Journal of Medicine 126, 243–248, doi:10.1016/j.amjmed.2012.10.011 (2013).
Meulenbelt, I. M. et al. The first international workshop on the epigenetics of osteoarthritis. Connect Tissue Res 58, 37–48, doi:10.3109/03008207.2016.1168409 (2017).
Jeffries, M. A. et al. Genome-Wide DNA Methylation Study Identifies Significant Epigenomic Changes in Osteoarthritic Cartilage. Arthritis & Rheumatology 66, 2804–2815, doi:10.1002/art.38762 (2014).
Moazedi-Fuerst, F. C. et al. Epigenetic differences in human cartilage between mild and severe OA. Journal of Orthopaedic Research 32, 1636–1645, doi:10.1002/jor.22722 (2014).
Karlsson, C. et al. Genome-wide expression profiling reveals new candidate genes associated with osteoarthritis. Osteoarthritis and Cartilage 18, 581–592, doi:10.1016/j.joca.2009.12.002 (2010).
Tew, S. R., McDermott, B. T., Fentem, R. B., Peffers, M. J. & Clegg, P. D. Transcriptome-Wide Analysis of Messenger RNA Decay in Normal and Osteoarthritic Human Articular Chondrocytes. Arthritis & Rheumatology 66, 3052–3061, doi:10.1002/art.38849 (2014).
Snelling, S. et al. A gene expression study of normal and damaged cartilage in anteromedial gonarthrosis, a phenotype of osteoarthritis. Osteoarthritis and Cartilage 22, 334–343, doi:10.1016/j.joca.2013.12.009 (2014).
Dunn, S. L. et al. Gene expression changes in damaged osteoarthritic cartilage identify a signature of non-chondrogenic and mechanical responses. Osteoarthritis and Cartilage 24, 1431–1440, doi:10.1016/j.joca.2016.03.007 (2016).
Stenberg, J., Rüetschi, U., Skiöldebrand, E., Kärrholm, J. & Lindahl, A. Quantitative proteomics reveals regulatory differences in the chondrocyte secretome from human medial and lateral femoral condyles in osteoarthritic patients. Proteome Sci 11, 43, doi:10.1186/1477-5956-11-43 (2013).
Ruiz-Romero, C. et al. Proteomic analysis of human osteoarthritic chondrocytes reveals protein changes in stress and glycolysis. Proteomics 8, 495–507, doi:10.1002/pmic.200700249 (2008).
den Hollander, W. et al. Transcriptional Associations of Osteoarthritis-Mediated Loss of Epigenetic Control in Articular Cartilage. Arthritis & Rheumatology 67, 2108–2116, doi:10.1002/art.39162 (2015).
Bonin, C. A. et al. Identification of Differentially Methylated Regions in New Genes Associated with Knee Osteoarthritis. Gene 576, 312–318, doi:10.1016/j.gene.2015.10.037 (2016).
Rushton, M. D. et al. Methylation quantitative trait locus analysis of osteoarthritis links epigenetics with genetic risk. Human Molecular Genetics 24, 7432–7444, doi:10.1093/hmg/ddv433 (2015).
Bush, P. G. & Hall, A. C. The volume and morphology of chondrocytes within non-degenerate and degenerate human articular cartilage. Osteoarthritis and Cartilage 11, 242–251, doi:10.1016/s1063-4584(02)00369-2 (2003).
Musumeci, G. et al. Aquaporin 1 (AQP1) expression in experimentally induced osteoarthritic knee menisci: An in vivo and in vitro study. Tissue and Cell 45, 145–152, doi:10.1016/j.tice.2012.10.004 (2013).
Geyer, M. et al. Differential transcriptome analysis of intraarticular lesional vs intact cartilage reveals new candidate genes in osteoarthritis pathophysiology. Osteoarthritis and Cartilage 17, 328–335, doi:10.1016/j.joca.2008.07.010 (2009).
Westergaard, U. B., Andersen, M. H., Heegaard, C. W., Fedosov, S. N. & Petersen, T. E. Tetranectin binds hepatocyte growth factor and tissue-type plasminogen activator. Eur J Biochem 270, 1850–1854, doi:10.1046/j.1432-1033.2003.03549.x (2003).
Valdes, A. M. et al. Association study of candidate genes for the prevalence and progression of knee osteoarthritis. Arthritis & Rheumatism 50, 2497–2507, doi:10.1002/art.20443 (2004).
Tchetina, E. V. Developmental Mechanisms in Articular Cartilage Degradation in Osteoarthritis. Arthritis 2011, 1–16, doi:10.1155/2011/683970 (2011).
Xia, B. et al. Osteoarthritis Pathogenesis: A Review of Molecular Mechanisms. Calcif Tissue Int 95, 495–505, doi:10.1007/s00223-014-9917-9 (2014).
Remst, D. F. G. et al. Gene Expression Analysis of Murine and Human Osteoarthritis Synovium Reveals Elevation of Transforming Growth Factor β-Responsive Genes in Osteoarthritis-Related Fibrosis. Arthritis & Rheumatology 66, 647–656, doi:10.1002/art.38266 (2014).
Halpain, S. & Dehmelt, L. The MAP1 family of microtubule-associated proteins. Genome Biology 7, 224, doi:10.1186/gb-2006-7-6-224 (2006).
Blain, E. J. Involvement of the cytoskeletal elements in articular cartilage homeostasis and pathology. International Journal of Experimental Pathology 90, 1–15, doi:10.1111/j.1365-2613.2008.00625.x (2009).
Kanenari, M., Zhao, J. & Abiko, Y. Enhancement of microtubule-associated protein-1 Alpha gene expression in osteoblasts by low level laser irradiation. Laser Ther 20, 47–51 (2011).
Péterfi, Z. & Geiszt, M. Peroxidasins: novel players in tissue genesis. Trends in Biochemical Sciences 39, 305–307, doi:10.1016/j.tibs.2014.05.005 (2014).
Balakrishnan, L. et al. Proteomic analysis of human osteoarthritis synovial fluid. Clin Proteomics 11, 6, doi:10.1186/1559-0275-11-6 (2014).
Hopwood, B., Tsykin, A., Findlay, D. M. & Fazzalari, N. L. Microarray gene expression profiling of osteoarthritic bone suggests altered bone remodelling, WNT and transforming growth factor-β/bone morphogenic protein signalling. Arthritis Res Ther 9, R100, doi:10.1186/ar2301 (2007).
Goldring, M. B. & Otero, M. Inflammation in osteoarthritis. Current Opinion in Rheumatology 23, 471–478, doi:10.1097/bor.0b013e328349c2b1 (2011).
Wojdasiewicz, P., Poniatowski, Ł. A. & Szukiewicz, D. The Role of Inflammatory and Anti-Inflammatory Cytokines in the Pathogenesis of Osteoarthritis. Mediators of Inflammation 2014, 1–19, doi:10.1155/2014/561459 (2014).
Rushton, M. D. et al. Characterization of the Cartilage DNA Methylome in Knee and Hip Osteoarthritis. Arthritis & Rheumatology 66, 2450–2460, doi:10.1002/art.38713 (2014).
The authors wish to thank Sara Dunn and Clive Buckle for contribution to extraction of RNA/DNA/protein from chondrocyte samples, Danielle Walker for research administration, and Pei-Chien Tsai and Jordana Bell for advice on the methylation analyses. The authors would like to acknowledge the contribution of the Wellcome Trust Sanger Institute Sample Management, Illumina Bespoke, and Genotyping teams to this work. This study utilized genotype data from arcOGEN (http://www.arcogen.org.uk/) funded by a special purpose grant from Arthritis Research UK (grant 18030). This study makes use of data generated by the Wellcome Trust Case-Control Consortium (the 1958 British Birth Cohort collection and the UK Blood Services Collection). A full list of the investigators who contributed to the generation of the data is available from www.wtccc.org.uk. We thank all participants of the RAAK study. We would like to acknowledge the Cambridge Biomedical Research Center Human Research Tissue Bank for storing the hip gene expression and methylation replication samples. This work was funded by the Wellcome Trust (WT098051). This study utilized genotype data from arcOGEN (http://www.arcogen.org.uk/) funded by a special purpose grant from Arthritis Research UK (grant 18030). The RAAK study is supported by Leiden University Medical Center. Research leading to the RAAK study results has received funding from the Dutch Arthritis Association (DAA 2010_017) and the IDEAL project (European Union’s Seventh Framework Program (FP7/2007–2011) under grant agreement no. 259679). GRSR was supported by the European Molecular Biology Laboratory and the Wellcome Trust Sanger Institute through an EBI-Sanger Postdoctoral Fellowship. RAB received funding from the National Institute for Health Research (Cambridge Biomedical Research Centre).
The authors declare that they have no competing interests.
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
About this article
Cite this article
Steinberg, J., Ritchie, G.R.S., Roumeliotis, T.I. et al. Integrative epigenomics, transcriptomics and proteomics of patient chondrocytes reveal genes and pathways involved in osteoarthritis. Sci Rep 7, 8935 (2017). https://doi.org/10.1038/s41598-017-09335-6