Introduction
MicroRNAs (miRNAs) are endogenous small (approximately 22 nucleotides) noncoding RNAs and regulate the activities of target mRNAs by binding at sites in the 3' untranslated region of the mRNAs [
1,
2], and currently more than 721 human miRNAs have been registered [
3]. miRNAs have been implicated in important cellular processes such as lipid metabolism [
4], apoptosis [
5], differentiation [
6], organ development [
7] and malignant tumors [
8‐
12], and there is a prediction that one-third of all mRNAs may be regulated by miRNAs [
13]. Recently Mitchell
et al showed that miRNAs are present in human plasma in a remarkably stable form that is protected from endogenous RNase activity [
14]. Furthermore, miRNAs are present in dried biological fluids such as semen, saliva, vaginal secretions, and menstrual blood [
15], and expected to be diagnostic and prognostic biomarkers of various cancers [
14,
16,
17].
Several cellular or tissue miRNAs associate with rheumatoid arthritis (RA). The expressions of miR-155, miR-146a, and miR-124a in RA fibroblast-like synoviocytes (FLSs); miR-146 and miR-155 in RA synovial tissue; or miR-146a, miR-155, miR-132, and miR-16 in RA peripheral blood (PB) mononuclear cells (MNCs) are upregulated compared with osteoarthritis (OA) or healthy controls (HCs) [
18‐
21].
On the other hand, there is no report associated with miRNAs in plasma or synovial fluid of RA or OA patients. In this study, we investigated the presence and the stability of miRNAs in synovial fluid, and compared synovial fluid miRNAs with plasma miRNAs. We also examined the differences in the expression of plasma miRNAs or in synovial fluid miRNAs between RA, OA and HC, and the correlation of plasma or synovial fluid miRNAs with disease activities of RA.
Materials and methods
Preparation of blood and joint fluid samples
Ethical approval for this study was granted by the ethics committee of Kyoto University Graduate School and Faculty of Medicine. Informed consent was obtained from 108 participants (40 with RA, 38 with knee OA, and 30 as HC, Tables
1 and
2). According to the request of the ethics committee, HCs were limited between 20 and 65 years old. RA and OA were diagnosed according to the criteria of the American College of Rheumatology [
22,
23]. Both peripheral blood and synovial fluid were obtained from 20 patients with RA and 22 patients with OA. Blood samples were collected with ethylenediaminetetraacetic acid dipotassium salt (EDTA-2K) containing tube to separate plasma. Both of samples were centrifuged 400 g for seven minutes and stored at -20°C until analyses.
Table 1
Clinical features of the participants who contributed plasma
Number of participants | 30 | 30 | 30 |
Sex, male/female | 8/22 | 7/23 | 13/17 |
Age, mean (range) | 60.1 (22 to 77) | 75.1 (65 to 89) | 46.5 (32 to 62) |
Disease duration (y), mean (range) | 10.4 (0.3 to 32) | NA | NA |
Positive anti-CCP antibody, n (%) | 10 (90.9%)† | NA | NA |
ESR (mm), mean (range) | 37.2 (4 to 116) | NA | NA |
CRP (mg/dl), mean (range) | 2.1 (0 to 9.6) | NA | NA |
MMP3 (ng/ml), mean (range) | 290.1 (32.4 to 800) | NA | NA |
DAS28, mean (range) | 4.4 (1.7 to 7.1) | NA | NA |
SJC, mean (range) | 4.3 (0 to 13) | NA | NA |
TJC, mean (range) | 4.5 (0 to 27) | NA | NA |
VAS | 42.3 (0 to 95) | NA | NA |
Steinbrocker Stage, n | I: 4, II: 3, III: 6, IV: 17 | NA | NA |
Steinbrocker Class, n | I: 1, II: 24, III: 5, IV: 0 | NA | NA |
Kellgren/Lawrence grade, n | NA | I: 0, II: 0, III: 9, IV: 21 | NA |
Medication, n (%) | | | |
Prednisolone | 21 (70%) | NA | NA |
Methotrexate | 18 (60%) | NA | NA |
Infliximab | 8 (27%) | NA | NA |
Eternercept | 2 (6.7%) | NA | NA |
Tocilizumab | 2 (6.7%) | NA | NA |
Tacrolimus | 2 (6.7%) | NA | NA |
Salazosulfapyridine | 6 (20%) | NA | NA |
Bucillamine | 5 (17%) | NA | NA |
Mizoribine | 0 (0%) | NA | NA |
Gold | 1 (3.3%) | NA | NA |
Table 2
Clinical features of the participants who contributed synovial fluid
Number of participants | 30 | 30 |
Sex, male/female | 6/24 | 6/24 |
Age, mean (range) | 63.1 (32 to 88) | 75.3 (67 to 89) |
Disease duration (y), mean (range) | 13.0 (0.5 to 50) | NA |
Positive anti-CCP antibody, n (%) | 10 (83.3%)¶ | NA |
ESR (mm), mean (range) | 49.6 (4 to 116) | NA |
CRP (mg/dl), mean (range) | 3.1 (0 to 13.9) | NA |
MMP3 (ng/ml), mean (range) | 362.7 (43.2 to 800) | NA |
DAS28, mean (range) | 4.9 (2.2 to 7.1) | NA |
SJC, mean (range) | 4.9 (0 to 17) | NA |
TJC, mean (range) | 5.1 (0 to 27) | NA |
VAS | 52.1 (10 to 95) | NA |
Steinbrocker Stage, n | I: 3, II: 3, III: 5, IV: 19 | NA |
Steinbrocker Class, n | I: 1, II: 22, III: 7, IV: 0 | NA |
Kellgren/Lawrence grade, n | NA | I: 0, II: 0, III: 11, IV: 19 |
Medication, n (%) | | |
Prednisolone | 20 (67%) | NA |
Methotrexate | 15 (50%) | NA |
Infliximab | 3 (10%) | NA |
Eternercept | 1 (3.3%) | NA |
Tocilizumab | 0 (0%) | NA |
Tacrolimus | 2 (6.7%) | NA |
Salazosulfapyridine | 8 (27%) | NA |
Bucillamine | 6 (20%) | NA |
Mizoribine | 1 (3.3%) | NA |
Gold | 2 (6.7%) | NA |
Preparation for conditioned medium of cells and tissues
PB or joint specimens from RA and OA patients were obtained during joint surgery or from an outpatient clinic. FLSs of RA and OA patients were prepared as previously described [
24]. After three to eight passages, FLSs were plated on six-well plates (Corning, NY, USA) in Dulbecco's Modified Eagle's Medium (DMEM; Sigma Aldrich, St. Louis, MO, USA) containing 10% fetal bovine serum (FBS; ICN, Aurora, OH, USA). At confluence, FLSs were washed three times with phosphate-buffered saline (PBS) and cultured in 2 ml of serum-free DMEM for 48 h. Serum-free medium was used to exclude the contamination of miRNAs in bovine serum.
Synovial tissues of 30 mg were incubated at 37°C in 1 ml of serum-free DMEM for 48 h. MNCs from PB and synovial fluid were collected using Histopaque-1077 (Sigma Aldrich) as previously described [
24]. One million MNCs were placed on 12-well plates (Corning) and cultured in 1 ml of serum-free RPMI 1640 (Sigma Aldrich) for 48 h. The resultant culture medium was collected, centrifuged 800 g for 10 minutes and stored as conditioned medium at -20°C until analyses.
RNA isolation
A hundred μl of human plasma or synovial fluid was thawed on ice, diluted with 150 μl of RNase free water and lysed with 750 μl of a phenol-based reagent for liquid sample, Isogen LS (Nippongene, Toyama, Japan). To normalize possible sample-to-sample variation caused by RNA isolation, 25 fmol (total volume of 5 μl) of synthetic C. elegans miRNA cel-miR-39 (Hokkaido System Science, Sapporo, Japan), which has no homologous sequences in humans, were added to each denatured sample. Samples were homogenized, incubated for five minutes, added with 0.2 ml chloroform, shaked vigorously for 15 seconds, incubated for three minutes and centrifuged at 12,000 g for 15 minutes at 4°C. Then 300 μl of aqueous phase was applied to High Pure miRNA Isolation Kit (Roche Applied Science, Mannheim, Germany) according to manufacture's protocol.
Total RNA included in 300 μl of conditioned medium was also isolated with High Pure miRNA Isolation Kit according to manufacture's protocol for liquid sample. After samples were mixed with binding buffer, which inhibits RNase activities, 25 fmol of synthetic cel-miR-39 was spiked.
Reverse transcription and quantitation of miRNAs by real-time PCR
Reverse transcription was performed using NCode VILO miRNA cDNA Synthesis Kit (Invitrogen, Carlsbad, CA, USA) according to the manufacture's protocol. Using EXPRESS SYBR GreenER qPCR SuperMix (Invitrogen), real-time polymerase chain reaction (PCR) was carried out on an Applied BioSystems 7300 Real-Time PCR System (Applied BioSystems, Tokyo, Japan) with standard plasmids generated as in the next paragraph. Forward primers were designed according to NCode miRNA Database [
25]. Data were analyzed with SDS Relative Quantification Software version 1.3 (Applied BioSystems, Tokyo, Japan).
Primer sequences were as follows: for hsa-miR-16, 5'-TAG-CAG-CAC-GTA-AAT-ATT-GGC-G-3'; for hsa-miR-132, 5'-TAA-CAG-TCT-ACA-GCC-ATG-GTC-G-3'; for hsa-miR-146a, 5'-TGA-GAA-CTG-AAT-TCC-ATG-GGT-T-3'; for hsa-miR-155, 5'-TTA-ATG-CTA-ATC-GTG-ATA-GGG-GTA-3'; for hsa-miR-223, 5'-TGT-CAG-TTT-GTC-AAA-TAC-CCC-A-3'; for cel-miR-39, 5'-CGT-CAC-CGG-GTG-TAA-ATC-AGC-TTG-3'.
TA Cloning of PCR products and generation of standard curve
To verify the PCR products and to generate standard curves of miRNAs, thymine adenine (TA) cloning was performed. The resultant reaction buffers of preliminary real-time PCR were directly put in TA cloning using pTAC-1 vector (BioDynamics Laboratory, Tokyo, Japan) according to the manufacture's protocol. We verified that the sequences of inserted approximately 60 nucleotides (about 20 nucleotides of miRNA and about 40 nucleotides added at the reverse transcripts) were all correct, and could not find pre-miRNAs inserted into the vector.
Plasmids with known copy number were put into real-time PCR over an empirically-derived range of copies to generate standard curves for each of the miRNA. Absolute copy number of each target miRNA and spiked cel-miR-39 in samples was obtained according to the generated standard curves. The concentrations of target miRNAs in each sample were calculated according to the obtained absolute copy numbers of spiked cel-miR-39 with known concentration and target miRNAs.
Statistical analysis
Data were presented as the mean ± standard deviation. Statistical analyses were performed using StatView Ver.5 for Windows (Hulinks, Tokyo, Japan). Differences between two groups were analyzed with Student's t-test. Differences among three groups were analyzed with Bonferroni method. Correlations with miRNA concentrations and other clinical factors were analyzed with Pearson product-moment correlation coefficient. The ROCKIT software version 0.9B (Metz, Herman, & Roe, The University of Chicago, Chicago, IL, USA) was used to calculate Receiver Operating Characteristic (ROC) curve values. A P-value less than 0.05 was considered statistically significant.
Discussion
Tissue miRNAs have been noted not only as key molecules in intracellular regulatory networks for gene expression, but also as biomarkers for various pathological conditions [
26]. Recent studies suggest that miRNAs in plasma can be biomarkers for the diagnosis of lung, colorectal and prostate cancer [
14,
27]. Plasma miRNAs are also suggested to be potential biomarkers for drug-induced liver injury, and myocardial injury [
28,
29]. In this report, we showed the presence and the stability of miRNAs in synovial fluid and plasma. We also found that the expression of miRNAs in synovial fluid was distinct from that in plasma and may reflect the condition of joint space. Consistently, synovial fluid concentrations of miR-16, miR-146a, miR-155 and miR-223 were significantly higher in RA than those in OA. Finally we referred the possibility of plasma and synovial fluid miRNAs as potential biomarkers of RA.
We quantified miRNAs by real-time PCR after using NCode VILO miRNA cDNA Synthesis Kit. This kit polyadenylates miRNAs and reverse-transcribes with a poly(T) adapter as reverse primer. Because the specificity of this procedure depends on the annealing of the forward primer to the sequence of mature miRNA in the amplicon during amplification, there is a low possibility that pre-miRNAs are also amplified [
30]. To exclude the contamination of pre-miRNAs and nonspecific amplification, we performed TA cloning of PCR products. We verified that all the inserted size was approximately 60 nucleotides by electrophoresis, and that sequences were correct. These results were probably attributed to low abundance of pre-miRNAs and difficulties in polyadenylation of pre-miRNA due to the presence of the stem loop structure [
31]. Even if there remains little possibility to amplify pre-miRNA, we think that procedures used in this study are useful for diagnosis and determination of activities.
Plasma miRNAs have been shown to be remarkably stable in plasma and protected from endogenous RNase activity [
14]. In previous reports, plasma miRNAs are stable at room temperature for up to 24 h and resistant for freeze-thawing from -80°C to room temperature up to eight times. We additionally demonstrated that miRNAs in synovial fluid were as stable as miRNAs in plasma and that both of these miRNAs were also stable at -20°C for up to seven days. These stabilities contribute to the handiness of plasma and synovial fluid miRNAs as biomarkers.
Although we showed that synovial tissue is a main source of synovial fluid miRNA, the mechanism for stability of synovial fluid miRNA remains to be determined. In plasma, some miRNAs are thought to be secreted in a form of exosomes, which are 50- to 90-nm membrane vesicles abundant in plasma containing mRNAs and miRNAs [
32‐
34]. Exosomes released from various cells can transfer proteins and RNA between cells, facilitating processes such as antigen presentation and in trans signaling to neighboring cells [
34‐
37]. However, other mechanisms for stabilization may exist (for example, in a RNA-induced silencing complex (RISC)), because some miRNAs were reported to be biomarkers of tissue injury (for example, liver, heart, kidney,
et al.). Exosomes were shown to exist in synovial fluid [
38], but there have been no report about the existence of miRNA in synovial fluid or its exosomes.
Investigated miRNAs in this study have already been shown to associate with RA or OA. miR-16 and miR-132 were shown to be upregulated in PB MNCs of RA patients [
21]. Although the function of miR-16 and miR-132 in RA has not been determined yet, miR-16 is present in high levels in most of cells and thought to be potentially a
master miRNA involved in determining mRNA stability via AU-rich element sites [
39]. miR-146a is upregulated in PB MNCs, FLS and synovial tissue of RA [
19‐
21] and expressed in cartilage of low-grade OA [
40]. The targets of miR-146a/b are IL-1β and TRAF6, which is a key molecule in the down stream of TNFα and IL-1β signaling [
41]. The expression of miR-155 is upregulated in RA FLS and has repressive effect to MMP-3 and 1 [
18]. The expression of miR-223 is down regulated in RA FLS [
19].
Our hypothesis was that in RA patients, miR-16, miR-132, miR-146 and miR-155 were upregulated in plasma and synovial fluid, but miR-223 down regulated. However, there were no statistically significant differences between plasma miRNAs of RA and those of OA. These results are not inconsistent with the previous report: Expression patterns of exosomal miRNAs were shown to be different from those of intracellular miRNAs [
34], though we could not directly show that the synovial fluid miRNA exist in the form of exosome. We showed synovial fluid miRNAs were similar to miRNAs secreted by synovial tissues, while plasma miRNAs were different from miRNAs secreted by MNCs. These facts suggest that synovial tissues and infiltrating cells are a main source of synovial fluid miRNAs, while plasma miRNAs are generated by various tissues.
In this study, all healthy controls were younger than 66 years old according to the request of our ethical committee, while patients with OA were older than 64 years old. When the age of patients and healthy controls was limited from 40 to 60 years to match the age background of groups, plasma miR-132 of HC (n = 9) was still significantly higher than that of RA (n = 16) (P < 0.01). This result suggests that the difference in age between groups has little effect on our analyses.
Plasma concentration of miR-132 differentiated patients with RA or OA from HC, though plasma and synovial fluid miR-132 failed to differentiate RA from OA. Furthermore, plasma miR-132 or its SF/PB ratio correlated with TJC. These results indicate that miR-132 might be involved in the systematic condition of patients with joint inflammation.
On the other hand, miR-16, miR-146a, miR-155 and miR-223 were higher in RA synovial fluids than in OA synovial fluids. Although these miRNAs of plasma had no differences between RA and OA, they significantly correlated with TJC, and plasma miR-16 also correlated with DAS28. Moreover, SF/PB ratio of miR-16 and miR-146a also correlated with TJC with moderate R2 values. These collectively imply that miR-16, miR-146a miR-155 and miR-223 are involved in the pathogenesis specific for RA.
As reported in the field of malignant tumors [
14,
16,
17], disease specific plasma miRNAs for RA or OA are expected. Although investigated plasma miRNAs failed to differentiate RA and OA, disease specific miRNAs that are not investigated in this study may exist. In our preliminary study, miR-124a, miR-142-3p, miR-142-5p, and miR-133a were also detectable. Further analysis for comprehensive plasma and synovial fluid miRNAs using larger number of samples including age-matched RA and OA patients with various severity and healthy controls are expected.
Competing interests
H Yoshitomi and K Murata are applying for a patent relating to the content of the manuscript. The authors do not receive any reimbursements, fees, funding, or salary from an organization that holds or has applied for patents relating to the content of the manuscript. The other authors declare that they have no competing interests.
Authors' contributions
KM conducted all experiments and drafted the manuscript. HY designed the experiment, recruited study subjects, assisted with statistical evaluation, and edited the manuscript. ST, MI and KN collected patients' samples. HI and TN recruited study subjects, provided clinical insights and advice. All authors read and approved the final manuscript.