Background. Intervertebral disc (IVD) degeneration is a major cause of low back pain (LBP). Degenerate discs are associated with accelerated cellular senescence. Cell senescence is associated with a secretory phenotype characterised by increased production of catabolic enzymes and cytokines. However to date, the mechanism of cell senescence within disc degeneration is unclear. Senescence can be induced by increased replication or induced by stress such as reactive oxygen species or cytokines. This study investigated the association of cellular senescence with markers of DNA damage and presence of cytoplasmic DNA (which in cancer cells has been shown to be a key regulator of the secretory phenotype), to determine mechanisms of senescence in disc degeneration. Methods and Results. Immunohistochemistry for the senescence marker: p16. INK4A. was firstly utilised to screen human intervertebral discs for discs displaying at least 30% immunopostivity. These discs were then subsequently analysed for immunopostivity for DNA damage markers γH2AX and cGAS and the presence of cytoplasmic DNA. The number of immunopositive cells for p16. INK4A. positively correlated with the expression of γH2AX and cGAS. Senescent cells were also associated with the presence of cytoplasmic DNA. Conclusions. These new findings elucidated a role of cGAS and γH2AX as a link from genotoxic stress to cytokine expression, which is associated with senescent cells. The findings indicate that cellular senescence in vivo is associated with DNA damage and presence of cytoplasmic DNA. Whether this DNA damage is a result of replicative senescence or stress induced is currently being investigated in vitro. No conflicts of interest. Sources of funding: Funded by ARUK and MRC

Intervertebral disc (IVD) degeneration is a major cause of low back pain (LBP). Degenerate discs are associated with accelerated cellular senescence. Cell senescence is associated with a secretory phenotype characterised by increased production of catabolic enzymes and cytokines. However, to date, the mechanism of cell senescence within disc degeneration is unclear. Senescence can be induced by increased replication or induced by stress such as reactive oxygen species or cytokines. This study investigated the association of cellular senescence with markers of DNA damage and presence of cytoplasmic DNA (which in cancer cells has been shown to be a key regulator of the secretory phenotype), to determine mechanisms of senescence in disc degeneration. Immunohistochemistry for the senescence marker: p16INK4A was firstly utilised to screen human intervertebral discs for discs displaying at least 30% immunopostivity. These discs were then subsequently analysed for immunopostivity for DNA damage markers γH2AX and cGAS and the presence of cytoplasmic DNA. The number of immunopositive cells for p16 INK4A positively correlated with the expression of γH2AX and cGAS. Senescent cells were also associated with the presence of cytoplasmic DNA. These new findings elucidated a role of cGAS and γH2AX as a link from genotoxic stress to cytokine expression which is associated with senescent cells. The findings indicate that cellular senescence in vivo is associated with DNA damage and presence of cytoplasmic DNA. Whether this DNA damage is a result of replicative senescence or stress induced is currently being investigated in vitro

There is an evolving body of evidence that demonstrates the role of epigenetic mechanisms, such as DNA-methylation in the pathogenesis of OA. This systematic review aims to summarize the current evidence of DNA methylation and its influence on the pathogenesis of OA. A pre-defined protocol in alignment with the PRISMA guidelines was employed to systematically review eight bibliographic databases, to identify associations between DNA-methylation of articular chondrocytes and osteoarthritis. A search of Medline (Ovid), Embase, Web-of-Science, Scopus, PubMed, Cinahl (EBSCOhost), Cochrane Central and Google Scholar was performed between 1st January 2015 to 31st January 2021. Data extraction was performed by two independent reviewers. During the observation period, we identified 15 gene specific studies and 24 genome wide methylation analyses. The gene specific studies mostly focused on the expression of pro-inflammatory markers, such as IL8 and MMP13 which are overexpressed in OA chondrocytes. DNA hypomethylation in the promoter region resulted in overexpression, whereas hypermethylation was seen in non-OA chondrocytes. Others reported on the association between OA risk genes and the DNA methylation pattern close to RUNX2, which is an important OA signal. The genome wide methylation studies reported mostly on differentially methylated regions comparing OA chondrocytes and non-OA chondrocytes. Clustering of the regions identified genes that are involved in skeletal morphogenesis and development. Differentially methylated regions were seen in hip OA and knee OA chondrocytes, and even within different regions of an OA affected knee joint, differentially methylated regions were identified depending on the disease stage. This systematic review demonstrates the growing evidence of epigenetic mechanisms, such as DNA methylation, in the pathogenesis of OA. In recent years, there has been a focus on the interplay between OA risk genes and DNA methylation changes which revealed a reactivation of genes responsible for endochondral ossification during development. These are important findings and may help to identify eventual future therapeutic targets. However, the current body of literature is mostly showing the differences in DNA methylation of OA chondrocytes and non-OA chondrocytes, but a true longitudinal analysis demonstrating the DNA methylation changes actually happening is still not available

Aims. Cell-free DNA (cfDNA) and circulating tumour DNA (ctDNA) are used for prognostication and monitoring in patients with carcinomas, but their utility is unclear in sarcomas. The objectives of this pilot study were to explore the prognostic significance of cfDNA and investigate whether tumour-specific alterations can be detected in the circulation of sarcoma patients. Methods. Matched tumour and blood were collected from 64 sarcoma patients (n = 70 samples) prior to resection of the primary tumour (n = 57) or disease recurrence (n = 7). DNA was isolated from plasma, quantified, and analyzed for cfDNA. A subset of cases (n = 6) underwent whole exome sequencing to identify tumour-specific alterations used to detect ctDNA using digital droplet polymerase chain reaction (ddPCR). Results. Cell-free was present in 69 of 70 samples above 0.5 ng/ml. Improved disease-free survival was found for patients with lower cfDNA levels (90% vs 48% at one-year for ≤ 6 ng/ml and > 6 ng/ml, respectively; p = 0.005). Digital droplet PCR was performed as a pilot study and mutant alleles were detectable at 0.5% to 2.5% of the wild type genome, and at a level of 0.25 ng tumour DNA. Tumour-specific alterations (ctDNA) were found in five of six cases. Conclusion. This work demonstrates the feasibility and potential utility of cfDNA and ctDNA as biomarkers for bone and soft-tissue sarcomas, despite the lack of recurrent genomic alterations. A larger study is required to validate these findings. Cite this article: Bone Joint Res 2021;10(9):602–610

Aim. Periprosthetic joint infection (PJI) is one of the most frequent and devastating complications of total knee arthroplasty (TKA). Accurate diagnosis and proper treatment are essential to prevent functional loss and progression to systemic infection. However, the correct diagnosis of PJI is still a challenge since there is no accurate diagnostic method and the existing diagnostic criteria are based on serological, histological and microbiological tests that are imprecise and time-consuming. Recently, it was demonstrated that cell-free DNA is increased in the synovial fluid of patients with PJI. Therefore, this study aims to evaluate a new point-of-care methodology for quantifying free DNA in synovial fluid. Method. A prospective study was carried out with patients undergoing TKA revision surgery, from whom it was possible to collect synovial fluid (SF) during the surgical procedure. Cell-free DNA quantification was performed directly from the SF, using a portable fluorimeter. Sensitivity, specificity and receiver operating characteristic (ROC) curve were calculated. Results. Fifty-four patients were included in the study, of which 25 were diagnosed with PJI. Cell-free DNA levels measured immediately after collection were increased in the synovial fluid of patients with PJI (26.3 ± 14.8) in comparison with the uninfected group (4.6 ng/ml ± 3.8, p< 0.0001). The area under the receiver operating characteristic curve (AUC ROC) was 0.981 (95% CI 0.914 to 0.999). Conclusions. From the results presented, we can conclude that the quantification of free DNA with a portable fluorimeter proved to be a test with high sensitivity and specificity for the diagnosis of PJI

Introduction and Objective. Senescent bone cell overburden accelerates osteoporosis. Epigenetic alteration, including microRNA signalling and DND methylation, is one of prominent features of cellular senescence. This study aimed to investigate what role microRNA-29a signalling may play in the development of senile osteoporosis. Materials and Methods. Bone biopsy and serum were harvested from 13 young patients and 15 senior patients who required spine surgery. Bone mass, microstructure, and biomechanics of miR-29a knockout mice (miR-29aKO) and miR-29a transgenic mice (miR-29aTg) were probed using mCT imaging and three-point bending material test. Senescent cells were probed using senescence-associated b-galactosidase (SA-b-gal) staining. Transcriptomic landscapes of osteoblasts were characterized using whole genome microarray and KEGG bioinformatics. miR-29a and senescence markers p16. INK4a. , p21. Waf/cipl. and inflammatory cytokines were quantified using RT-PCR. DNA methylome was probed using methylation-specific PCR and 5-methylcytosine immunoblotting. Results. Senescent osteoblast overburden, DNA hypermethylation and oxidative damage together with significant decreases in serum miR-29a levels were present in bone specimens of aged patients. miR-29aKO mice showed a phenotype of skeletal underdevelopment, low bone mineral density and weak biomechanics. miR-29a knockout worsened age-induced bone mass and microstructure deterioration. Of note, aged miR-29aTg mice showed less bone loss and fatty marrow than aged wild-type mice. Transgenic overexpression of miR-29s compromised age-dysregulated osteogenic differentiation capacity of bone-marrow mesenchymal cells. In vitro, miR-29a promoted transcriptomic landscapes of antioxidant proteins in osteoblasts. The microRNA interrupted DNA methyltransferase (Dnmt3b)-mediated DNA methylation, inhibiting reactive oxygen radicals burst, IL-6 and RANKL production, and a plethora of senescent activity, including increased p16. INK4a. , p21. Waf/cipl. signalling and SA-b-gal activity. Conclusions. miR-29a loss is correlated with human age-mediated osteoporosis. miR-29a signalling is indispensable in bone mase homeostasis and microstructure integrity. Gain of miR-29a function is advantageous to delay age-induced bone loss through promoting antioxidant proteins to inhibit DNA hypermethylation-mediated osteoblast senescence. Collective investigations shine light onto the anabolic effects miR-29a signalling to bone integrity and highlight a new epigenetic protection strategy through controlling microRNA signalling to delay osteoblast senescence and senile osteoporosis development

Aims. To assess the alterations in cell-specific DNA methylation associated with chondroitin sulphate response using peripheral blood collected from Kashin-Beck disease (KBD) patients before initiation of chondroitin sulphate treatment. Methods. Peripheral blood samples were collected from KBD patients at baseline of chondroitin sulphate treatment. Methylation profiles were generated using reduced representation bisulphite sequencing (RRBS) from peripheral blood. Differentially methylated regions (DMRs) were identified using MethylKit, while DMR-related genes were defined as those annotated to the gene body or 2.2-kilobase upstream regions of DMRs. Selected DMR-related genes were further validated by quantitative reverse transcriptase polymerase chain reaction (qRT-PCR) to assess expression levels. Tensor composition analysis was performed to identify cell-specific differential DNA methylation from bulk tissue. Results. This study revealed 21,060 hypermethylated and 44,472 hypomethylated DMRs, and 13,194 hypermethylated and 22,448 hypomethylated CpG islands for differential global methylation for chondroitin sulphate treatment response. A total of 12,666 DMR-related genes containing DMRs were identified in their promoter regions, such as CHL1 (false discovery rate (FDR) = 2.11 × 10. -11. ), RIC8A (FDR = 7.05 × 10. -4. ), and SOX12 (FDR = 1.43 × 10. -3. ). Additionally, RIC8A and CHL1 were hypermethylated in responders, while SOX12 was hypomethylated in responders, all showing decreased gene expression. The patterns of cell-specific differential global methylation associated with chondroitin sulphate response were observed. Specifically, we found that DMRs located in TESPA1 and ATP11A exhibited differential DNA methylation between responders and non-responders in granulocytes, monocytes, and B cells. Conclusion. Our study identified cell-specific changes in DNA methylation associated with chondroitin sulphate response in KBD patients. Cite this article: Bone Joint Res 2024;13(5):237–246

Aim. Diagnosing Orthopaedic infection is limited by the sensitivity of culture methods. Next generation sequencing (NGS) offers an alternative approach for detection of microorganisms from clinical specimens. However, the low ratio of pathogen DNA to human DNA often inhibits detection of microorganisms from specimens. Depletion of human DNA may enhance the detection of microbial DNA. 1. Our aim was to compare four DNA extraction methods for the recovery of microbial DNA from orthopaedic samples for NGS. Method. Simulated samples; pooled culture negative sample matrix was spiked with known concentrations of microorganisms, each panel consisting of 7 samples. Broth culture was performed on simulated samples for comparison with NGS. *. . DNA Extraction; total nucleic acid extraction was performed on an automated extraction platform. **. using the viral NA assay. Modifications included: (1) mechanical lysis (glass beads), (2) lysis of human cells (saponin 0.025%), turbo DNase treatment and (3) mechanical lysis and addition of MspJI enzyme post-extraction for methylated DNA digestion. Detection of human and microbial DNA; human endogenous (HE) gene rtPCR. ***. was utilised following manufacturer's recommendations. Microbial DNA was detected using SYBR green 16s ribosomal RNA rtPCR with high resolution melt-curve analysis. ****. . Results. Broth culture recovered 64% (9/14) of the microorganisms from simulated samples. A significant increase (p<0.01) in the cycle threshold (C. T. ) (median C. T. 25.9 IQR 25.5, 26.1) of the HE gene rtPCR was observed using extraction method b, indicating a significant reduction in human DNA. No significant change (p=0.38) in the C. T. of the HE gene rtPCR was observed between the baseline method (median C. T. 19.2 IQR 18.5, 19.7) and modifications a (median C. T. 18.4 IQR 18.2, 19.4) and c (median C. T. 19.3 IQR 18.6, 19.4). Detection of microbial DNA was successful using the base line extraction method and modification a. Microbial DNA was not detected using the 16s ribosomal RNA rtPCR for modifications b and c. Conclusions. This study has demonstrated that modification of DNA extraction methods using selective enzymatic digestion of human DNA negatively impacts on the recovery of microbial DNA from simulated specimens. Total DNA extraction allows the successful recovery of microbial DNA alongside a significant amount of human DNA. The effect of the presence of human DNA will be subsequently assessed through NGS CosmosID analysis to establish if NGS is more sensitive than broth based culture

Previous research has shown an increase in chromosomal aberrations in patients with worn implants. The type of aberration depended on the type of metal alloy in the prosthesis. We have investigated the metal-specific difference in the level of DNA damage (DNA stand breaks and alkali labile sites) induced by culturing human fibroblasts in synovial fluid retrieved at revision arthroplasty. All six samples from revision cobalt-chromium metal-on-metal and four of six samples from cobalt-chromium metal-on-polyethylene prostheses caused DNA damage. By contrast, none of six samples from revision stainless-steel metal-on-polyethylene prostheses caused significant damage. Samples of cobalt-chromium alloy left to corrode in phosphate-buffered saline also caused DNA damage and this depended on a synergistic effect between the cobalt and chromium ions. Our results further emphasise that epidemiological studies of orthopaedic implants should take account of the type of metal alloy used

Fatty marrow and bone loss are prominent pathologic features of osteoporosis. DNA hypermethylation shifts mesenchymal stem cells towards adipocytes impairing bone formation. Brown adipocytes produce growth factors advantageous to osteogenesis, whereas white adipocytes secrete pro-inflammatory cytokines deleterious to bone homeostasis. We assess DNA methylation inhibitor action to brown and white adipocyte formation in marrow fat of osteoporotic skeletons. Osteoporotic skeletons in mice were induced by glucocorticoid, ovariectomy or ageing. Marrow adipose volume and bone structure were quantified using OsO4 contrast-μCT imaging. Brown and white adipocytes were probed using immunostaining, RT-PCR and primary bone-marrow mesenchymal stem cell cultures. Abundant marrow fat and spare trabecular bone existed in osteoporotic skeletons. Osteoporosis increased expressions of general adipogenic markers PPARγ2 and FABP4 and white adipocyte markers TCF21 and HOXc9, whereas expressions of brown adipocyte markers PGC-1α and UCP-1 and osteogenic markers Runx2 and osteocalcin were significantly decreased. Number of UCP-1 immunostaining-positive brown adipocytes also reduced in osteoporotic bone. In vitro, DNA methylation inhibitor 5'-aza-deoxycystidine significantly increased brown adipocyte formation and osteogenic differentiation and mitigated dexamethasone-induced white adipocyte formation in mesenchymal stem cells. 5'-aza-deoxycystidine control of brown adipogenesis and white fat formation appeared to be regulated by increasing Wnt3a/β-catenin and reducing Dkk1. Disintegrated brown adipocyte and white fat cell differentiation contribute to osteoporosis pathogenesis. Maintaining DNA hypomethylation promotes Wnt signalling and brown adipocyte differentiation facilitating osteogenic differentiation. This study shed a new light to the contribution of brown adipocytic cells to bone metabolism during osteoporosis

INTRODUCTION. Many patients suffering from osteoarthritis (OA) take daily glucosamine (GlcN) in the hope of slowing down disease progression and ameliorating pain. However, the physiological basis of this effect is not known. We previously presented preliminary data suggesting that GlcN prevented the increase in interleukin-1beta (IL-1b) expression caused by addition of inflammatory cytokines to cultures of healthy human articular chondrocytes. Previous studies had also shown that, in OA, epigenetic DNA methylation loss at specific CpG sites in relevant promoters ‘unsilences’ the genes and that this DNA de-methylation underlies the aberrant gene expression of proteases (Arthritis Rheum 52;3110-24). Furthermore, exogenous inflammatory cytokines have the capacity to cause DNA de-methylation in the IL-1b promoter (Arthritis Rheum. 2009, 60, 3303-3313). The aims of the present study were to investigate whether GlcN not only prevents the increased IL-1b expression, but also inhibits epigenetic unsilencing by preventing the cytokine-induced loss of DNA methylation. METHODS. Healthy chondrocytes were isolated from the articular cartilage of four femoral heads, after operations following femoral neck fracture (ethic permission was obtained). The chondrocytes were cultured for 5 weeks in four treatment groups: no treatment (control); with IL-1b and oncostatin M (IL1b+OSM); with 2.0mM GlcN; and with IL1b+OSM+GlcN. Total RNA and genomic DNA were extracted. The % DNA methylation at the CpG site at -299bp (previously identifies as the crucial CpG site) was determined after bisulphite modification with a pyrosequencer. Gene expression of IL-1B was quantified by SybrGreen-based qRT-PCR. RESULTS. The chondrocytes from one patient grew too slowly to obtain results. In two patients (aged 80 and 85), exogenous IL-1b increased expression of IL-1b several 100-fold and reduced the % DNA methylation from 60% to 40%. GlcN alone showed no significant difference to the control group. When GlcN was present together with IL1b, the increase in expression of IL1B was only 1/3 of that cause by IL-1b and the loss of DNA methylation was prevented. The final sample (patient aged 94), showed a low % DNA methylation (46%) even in the control culture and glucosamine had no effect. This may be an anomaly due to the great age of the patient. DISCUSSION. The results suggest that GlcN is capable of ameliorating the cytokine-induced loss of DNA methylation. However, patient numbers are too low to have statistical significance. Further work is clearly needed confirm the hypothesis that DNA de-methylation of the IL-1b promoter caused by exogenous IL-1b is reversed by GlcN

In osteoarthritis (OA), articular chondrocytes undergo a phenotypic change and acquire a gene expression repertoire that is characterized by the aberrant expression of numerous catabolic genes including matrix metalloproteinases 3, 9 and 13, ADAMTS-4 and interleukin-1beta (IL1B = gene, IL-1b=protein). Previous studies (Arthritis Rheum 52;3110-24) have shown that epigenetic DNA demethylation at specific CpG sites in the relevant promoters accounts for the aberrant expression and that inflammatory cytokines (TNF-alpha, oncostatin M, IL-1b) can cause both aberrant expression and loss of DNA methylation, at least in vitro (Arthritis Rheum. 2009, 60,3303-3313). If the mechanisms of DNA de-methylation were understood, they might provide a new molecular target for therapeutic intervention. We hypothesize that nuclear translocation of the transcription factor NF-kB is involved in de-methylation because 1) we and others have demonstrated that cytokine-induced expression of IL1B in healthy chondrocytes requires NF-kB and 2) DNA de-methylation during B cell maturation was crucially dependent on the rel/NF-kB family (Nat Genet. 1996, 13,435-441). The aims of the study were to determine whether the NF-kB inhibitor BAY 11-7082 (BAY) could prevent the cytokine-induced loss of DNA de-methylation and thereby show that NF-kB is required for DNA de-methylation. METHODS. Healthy chondrocytes were isolated from the articular cartilage of six femoral heads, obtained with ethical permission after operations following neck of femur fractures. Chondrocytes were cultured for 5 weeks in 4 separate groups: without treatment (control culture); with 2.5ng/ml IL-1b and 2.5ng/ml oncostatin M (IL-1b+OSM); with 1.0mM BAY alone; and IL-1b+OSM+BAY. Total RNA and genomic DNA were extracted from each sample. Gene expression of IL1B was determined by SybrGreen-based qRT-PCR. The % DNA methylation at a specific CpG site in the IL1B promoter (which had previously been identified as a crucial CpG site) was quantified after bisulfite modification with a pyrosequencer (Biotage). The data for IL1B expression and % DNA methylation were analyzed in Microsoft Excel using Wilcoxon's signed rank test. P values < 0.05 were considered significant. RESULTS. Although there was considerable variation between samples, expression of IL1B was increased by > 1000 fold in the IL-1b+OSM group compared with control culture, confirming previous results. When BAY was present together with IL-1b+OSM, the increase in IL1B expression was reduced from ∼1000-fold to ∼200-300-fold (P< 0.01). In addition, the % DNA methylation had changed. At the -299 CpG site of IL1B promoter the % methylation was 57% in control culture and 60% in the BAY alone group. IL-1b+OSM caused a decrease to 37% (P<0.01 compared with all other groups), whereas presence of BAY prevented this loss, since the % methylation was 58% in IL-1b+OSM+BAY group. DISCUSSION. The novel findings of this study are that when nuclear translocation of NF-kB is inhibited by BAY, the IL-1b induced increase of IL1B expression was ameliorated and the loss of DNA methylation in the IL1B promoter was prevented. The data confirm our hypothesis that NF-kB is required for the DNA de-methylation initiated by IL-1b+OSM

Aims. Extracellular vesicles (EVs) are nanoparticles secreted by all cells, enriched in proteins, lipids, and nucleic acids related to cell-to-cell communication and vital components of cell-based therapies. Mesenchymal stromal cell (MSC)-derived EVs have been studied as an alternative for osteoarthritis (OA) treatment. However, their clinical translation is hindered by industrial and regulatory challenges. In contrast, platelet-derived EVs might reach clinics faster since platelet concentrates, such as platelet lysates (PL), are already used in therapeutics. Hence, we aimed to test the therapeutic potential of PL-derived extracellular vesicles (pEVs) as a new treatment for OA, which is a degenerative joint disease of articular cartilage and does not have any curative or regenerative treatment, by comparing its effects to those of human umbilical cord MSC-derived EVs (cEVs) on an ex vivo OA-induced model using human cartilage explants. Methods. pEVs and cEVs were isolated by size exclusion chromatography (SEC) and physically characterized by nanoparticle tracking analysis (NTA), protein content, and purity. OA conditions were induced in human cartilage explants (10 ng/ml oncostatin M and 2 ng/ml tumour necrosis factor alpha (TNFα)) and treated with 1 × 10. 9. particles of pEVs or cEVs for 14 days. Then, DNA, glycosaminoglycans (GAG), and collagen content were quantified, and a histological study was performed. EV uptake was monitored using PKH26 labelled EVs. Results. Significantly higher content of DNA and collagen was observed for the pEV-treated group compared to control and cEV groups. No differences were found in GAG quantification nor in EVs uptake within any treated group. Conclusion. In conclusion, pEVs showed better performance than cEVs in our in vitro OA model. Although further studies are needed, pEVs are shown as a potential alternative to cEVs for cell-free regenerative medicine. Cite this article: Bone Joint Res 2023;12(10):667–676

In osteoarthritis (OA) there is a loss of matrix components, especially aggrecan, which is a major structural component important for the integrity and function of articular cartilage. The breakdown of aggrecan is mediated by enzymes from the ADAM-TS (a disintegrin and metalloproteinase with thrombospondin motifs) family and recent studies have suggested that, in humans, ADAM-TS4 (aggrecanase-1) plays a major role. Articular chondrocytes do not express ADAM-TS4 in contrast to clonal OA chondrocytes. Since in any somatic cell non-expressed genes are thought to be silenced by DNA methylation in the promoter region, the aims of the project were twofold:. to localize enzyme expression for ADAM-TS4 by immunocytochemistry and. to determine whether ‘unsilencing’ (i.e. DNA de-methylation) in the promoter of ADAM-TS4 was associated with the abnormal enzyme synthesis. Using immunocytochemistry, we confirmed that there is an increased expression of ADAM-TS4 in OA chondrocytes, which initially occurs in chondrocytes of the superficial zone. As the Mankin score increases, ADAM-TS4 positive chondrocytes were found in duplets, then quadruplets until, at Mankin score > 10, all the cells in a typical OA clone were immunopositive for ADAM-TS4, suggesting that abnormal enzyme expression was inherited by daughter cells. DNA was extracted from femoral head cartilage of 24 patients, who had undergone hip replacement surgery for either symptomatic OA or following a fracture of neck of femur (#NOF). The latter was used as control due to the inverse relationship between OA and osteoporosis. For OA samples, it was important to sample only those regions for which immunocytochemistry had shown the presence of ADAM-TS4 synthesizing cells, i.e. the superficial zones near the weight-bearing region. DNA methylation only occurs at cytosines of the sequence 5′...CG...3′, the so-called CpG sites. To determine methylation status of specific CpG sites, methylation sensitive restriction enzymes were used, which will only cut DNA in the absence of methylation. By designing PCR primers that bracketed these sites, presence or absence of PCR bands could distinguish between methylated and non-methylated CpGs respectively. The ADAM-TS4 promoter contains a total of 13 CpG sites. Using restriction enzyme/primers combinations, it was possible to analyze 7 of these sites for methylation status. In the control group, all 7 CpG sites were methylated, while there was an overall 49% decrease of methylation in the OA group (p=< 0.0001). Some of the CpG sites were more consistently demethylated then others, one site at −753bp upstream from the transcription start site, showed a 86% decrease in methylation in OA compared to the control group (p=0.0005), while at other sites the decrease in methylation ranged from 36–50%. Conclusions. This study confirmed by immunocytochemistry that ADAM-TS4 is produced by OA chondrocytes, contributing to the degradation of their matrix. This abnormal enzyme expression is associated with DNA methylation. If a causal relationship could be proven in the future, then DNA de-methylation might play an important role in the pathogenesis of osteoarthritis and future therapies might be directed at influencing the methylation status

Mitochondrial dysfunction has been demonstrated in aging and osteoarthritic tissues. We investigated knee joints of prematurely aging mitochondrial DNA mutator mice (PolgD275A) to evaluate a relationship between mitochondrial dysfunction and osteoarthritis. Cartilage damage was evaluated using OARSI histopathology grading and osteoclast numbers were quantified by tartrate-resistant acid phosphatase staining in wild type, heterozygous and homozygous PolgD275A mice. Subchondral cortical plate and epiphyseal trabecular bone structures were determined by micro-computed tomography. Apoptosis in cartilage and subchondral bone tissues was studied using an indirect TUNEL method. Homozygous mutants displayed osteopenia of the epiphyseal trabecular bone and subchondral cortical plate in comparison to wild type and heterozygous mutants. Subchondral osteopenia was associated with a strong increase of osteoclast numbers (0.88±0.30/mm bone perimeter) compared to heterozygous (0.25±0.03/mm) and wild type mice (0.12±0.04/mm). Wild type mice as well as hetero- and homozygous mutants displayed low-grade cartilage degeneration due to loss of cartilage proteoglycans. In contrast, chondrocyte hypertrophy was more abundant in the homozygous mice. There were no differences in chondrocyte apoptosis rates between groups. Prematurely ageing mtDNA mutator mice with or without further mechanic or metabolic stimuli might serve as a valuable model for further experimental studies on aging-induced osteoporotic OA phenotype

Introduction and Aims: A phenotypic and proteomic approach has identified novel targets for the development of a DNA vaccine to prevent Staphylococcus aureus infection in orthopaedics. Approximately 1% of joint replacement operations are complicated by infection. Thirty percent of these infections are due to S.aureus, which is often difficult to treat because of antibiotic resistance. As treatment of these infections is challenging, prevention with a vaccine is a very attractive option. Method: To infect a joint replacement, bacteria must first adhere to its surface. This adherence is mediated by specific adhesion proteins; the expression of which is controlled by virulence regulator genes within the bacterial cell. A DNA vaccine is being developed which targets this regulatory apparatus, thus preventing bacterial adhesion, allowing the immune system to rapidly clear any potential S.aureus infection. Results: Mutations of the agr,sar and sae virulence regulator genes have been made. Their properties have been explored using a flow cell system, which uses a scanning confocal laser microscope and image analysis software to accurately provide quantitative data in real-time of biofilm formation. We have shown that the sae mutant does not form biofilm in the same was as wild-type S.aureus. We have also shown that it does not adhere to steel as well as its wild-type counterpart. Conclusion: For such a dramatic difference in biofilm forming properties to be evident, there must be a difference in the adhesion proteins produced by the wild-type and the mutant bacteria. Gel-electrophoresis has compared protein expression of sae mutant and wild-type bacteria and identified differences. Those proteins which are not expressed in the non-biofilm-forming mutant are sequenced and from the protein sequences, DNA sequences are identified that will form part of the candidate DNA vaccine

Introduction. Microbiological diagnosis of bone and joint infections (BJIs) currently relies on standard cultures which are time consuming and lack sensitivity. Various molecular approaches have been described and allowed improvement of BJI diagnosis. This study evaluated for the first time the performance of a DNA microarray-based assay (Prove-it™ Sepsis assay, PISA) for the rapid (<6 hours) detection and identification of 50 different species involved in BJI directly from clinical samples. Material and methods. We retrospectively selected 130 bone and joint samples (67 synovial fluids and 63 bone biopsies) including 114 positive and 16 negative samples. The microbiological diagnosis had been previously established either by culture(C+, n=53) or by PCR16S and sequencing when culture was negative (C-/PCR+). The positive samples were selected to match the species targeted on the DNA microarray. DNA extraction was performed before proceeding to PISA amplification and hybridization on every selected sample. Results. Among the 16 negative samples, one was detected positive with S. epidermidis by PISA, result that was secondarily confirmed using specific PCR. Among the 114 positive samples, 62.3% were positive using PISA with highly concordant identification compared to culture and PCR16S/sequencing results. Forty-three samples (37.7%) remained negative, illustrating a defect of sensitivity. However, PISA accurately detected methicillin resistance not only among the 16 C+/PISA+ Staphylococcus species (n=5) but also among the 28 C-/PCR16S+ Staphylococcus species (n=12) offering crucial rapid information to adapt the treatment of staphylococcal BJIs. Seven polymicrobial samples were also identified without extensive experiments. Discussion – Conclusion. Even if the sensitivity deserves to be improved by optimizing DNA extraction and investigating on human DNA interference, these preliminary promising results highlight that this new and simple microarray method could be in the future an alternative to conventional PCR16S for the diagnosis of BJI

Clonal chondrocytes of osteoarthritic (OA) cartilage express an aberrant set of genes. We hypothesize that this aberrant gene expression may be due to clonally inherited epigenetic changes, defined as altered gene expression without changes in genetic sequence. The major epigenetic changes are due to altered DNA methylations in crucial parts of the promoter region. If the cytosines of CpG dinucleotides are methylated, the gene will be silenced, even if the right transcription factors are present. Similarly, de-methylations may activate previously silenced genes. Our aims were to provide ‘proof-of-concept’ data by examining the methylation status of genes in OA vs non-OA chondrocytes. Articular cartilage was obtained a) from the cartilage of fracture-neck-of-femur (#NOF) patients and b) from or around the eroded regions of OA samples. The former was full thickness cartilage, the latter was partially degraded cartilage, which contained mostly clonal chondrocytes as confirmed by histology. The cartilage samples were ground in a freezer mill (Glen Creston, UK) and DNA was extracted with a Qiagen DNeasy maxi kit. To assess DNA methylation status, the genomic DNA was treated overnight with methylation-sensitive restriction enzymes. Cleavage of selected sites was detected by PCR amplifications with primer pairs designed to bracket selected promoter regions. Loss of the PCR band after digestion with the enzymes indicated absence of methylations, whereas presence of the band indicated methylated cytosine. We selected MMP-9 as one of genes that is activated in OA. Transcription of mmp-9 is regulated by a 670 bp sequence at the 5′-end flanking region, which contains 6 CpGs and a further 21 CpGs within the 1.5 kb region further upstream. A PCR primer pair was designed to bracket a 350bp sequence upstream from the transcription start site of mmp-9, which contained four of the six potential methylation sites, cleaved by the methylation-sensitive enzymes AciI and HhaI. DNA from 9 OA patients, 5 #NOF patients and 1 rheumatoid arthritic (RA) patient were digested with HhaI or AciI and examined for the presence or absence of PCR bands. In all patients, digestion with HhaI abolished the PCR band, indicating that the HhaI site was never methylated in either #NOF or OA patients. However, a remarkable difference was found after digestion with AciI: in 8/9 OA patients, the PCR band was no longer detectable, while in 4/5 #NOF patients the PCR band was still present. This suggested that all three AciI cleavage sites were methylated in the majority of chondrocytes from #NOF patients, while at least one of the three AciI cleavage sites was unmethylated in OA patients. Interestingly, the PCR band was present in the RA patient, suggesting methylation of the AciI cleavage sites. The present study provides the first ‘proof-of-concept’ data that suggest epigenetic changes may play a role in the etiology of osteoarthritis. Clearly further work is required to establish the generality of the present findings and whether de-methylations are also found in the promoter regions of other genes that are aberrantly expressed in OA

Aims. The present study investigated receptor activator of nuclear factor kappa-Β ligand (RANKL), osteoprotegerin (OPG), and Runt-related transcription factor 2 (RUNX2) gene expressions in giant cell tumour of bone (GCTB) patients in relationship with tumour recurrence. We also aimed to investigate the influence of CpG methylation on the transcriptional levels of RANKL and OPG. Methods. A total of 32 GCTB tissue samples were analyzed, and the expression of RANKL, OPG, and RUNX2 was evaluated by quantitative polymerase chain reaction (qPCR). The methylation status of RANKL and OPG was also evaluated by quantitative methylation-specific polymerase chain reaction (qMSP). Results. We found that RANKL and RUNX2 gene expression was upregulated more in recurrent than in non-recurrent GCTB tissues, while OPG gene expression was downregulated more in recurrent than in non-recurrent GCTB tissues. Additionally, we proved that changes in DNA methylation contribute to upregulating the expression of RANKL and downregulating the expression of OPG, which are critical for bone homeostasis and GCTB development. Conclusion. Our results suggest that the overexpression of RANKL/RUNX2 and the lower expression of OPG are associated with recurrence in GCTB patients. Cite this article: Bone Joint Res 2024;13(2):84–91

Epigenetic DNA de-methylation at specific CpG promoter sites is associated with abnormal synthesis of matrix-degrading enzymes in human osteoarthritis (Arthritis Rheum 52:3110–24), but the mechanisms that trigger or cause loss of DNA methylation are not known. Since inflammatory cytokines are known to induce abnormal gene expression in cultured chondrocytes, we wanted to know whether this induction also involved loss of DNA methylation. If so, the abnormal gene expression would be permanent and transmitted to daughter cells rather than a simple up-regulation. To test this hypothesis, we selected IL-1b as the abnormally expressed gene. Healthy chondrocytes, harvested from human femoral head cartilage following a fracture, were divided into five groups: non-culture; control culture; culture with the de-methylating agent 5-aza-deoxycyti-dine (5-aza-dC); culture with the inflammatory cytokine IL-1b; or with TNF-a/oncostatin M. Total RNA and genomic DNA were extracted at confluency, relative mRNA expression of IL-1b was quantified by Syb-rGreen-based real-time PCR, and a method for quantifying the percent of cells with DNA methylation at a specific CpG site was developed (Epigenetics 2: 86–95). The methylation status of 16 CpG sites in the promoter of IL-1b was determined by the bisulfite modification method. The two CpG sites important for the epigenetic regulation of IL-1b were at -247bp and -290bp, the latter was selected to quantify DNA methylation. 5-aza-dC halved DNA methylation, which resulted in 4–8 fold increases in IL-1b expression; showing that DNA de-methylation per se increases gene expression. However, far greater effects were seen with the inflammatory cytokines. IL-1b increased its own expression 50–100 fold, whereas TNF-a/OSM increased IL-1b expression 500–1000 fold. DNA methylation varied inversely, IL-1b reducing methylation to ~15% and TNF-a/OSM abolishing DNA methylation almost completely. This is the first demonstration that inflammatory cytokines have the capacity to cause loss of DNA methylation. We also confirmed previous work that IL-1b induces its own expression in healthy chondrocytes, thus setting up a dangerous positive feed-back mechanism. If true in vivo, both the auto-induction and the heritable expression of IL-1b by a growing number of chondrocytes could explain the unrelenting progression of osteoarthritis