Introduction
Osteoarthritis (OA) is a debilitating degenerative joint disease characterized by degradation of articular cartilage. Recent statistics show that approximately 5 million people in the UK suffer from moderate-to-severe OA. These patients are predominantly older than 45 years of age, with the major morbidity in patients over 60 years of age [
1]. Given the current demographic trend towards an older population, OA, for which age is an important risk factor, will be an increasing health and economic burden on society.
The molecular mechanisms underlying cartilage destruction in OA are poorly understood (reviewed in [
2]). Cartilage is made up of two main extracellular matrix (ECM) macromolecules: type II collagen and aggrecan, a large aggregating proteoglycan [
3,
4]. The former endows the cartilage with its tensile strength, whereas the latter enables cartilage to resist compression. Quantitatively, more minor components (e.g. type IX, XI and VI collagens, biglycan, decorin and cartilage oligomeric matrix protein) also have important roles in controlling the supramolecular organization of the matrix [
3]. Normal cartilage ECM is in a state of dynamic equilibrium, with a balance between synthesis and degradation. For the degradative process, there is a balance between proteinases that degrade the ECM and their inhibitors. In OA, the dogma is that a disruption of this balance, in favour of proteolysis, leads to pathological cartilage destruction.
The matrix metalloproteinases (MMPs) are a family of 23 enzymes in humans that facilitate ECM turnover and breakdown in physiology and pathology [
5]. The MMP family contains the only mammalian proteinases that can specifically degrade triple helical collagens at neutral pH. These so-called 'collagenases' specifically cleave a single locus in all three collagen chains at a point three-quarters of the length from the N-terminus of the molecule. The 'classical' collagenases (MMP-1, MMP-8 and MMP-13) have differing substrate specificities for collagens I, II and III, with MMP-13 showing a preference for type II collagen [
6]. More recently, gelatinase A (MMP-2) and MT1-MMP (MMP-14) have also been shown to make the specific collagen cleavage, although with less catalytic efficiency than the classical collagenases, at least
in vitro [
7,
8]. A second group of proteinases has been identified that affect ECM synthesis and degradation. The 'a disintegrin and metalloproteinase domain with thrombospondin motifs' (ADAMTS) family contains 19 members [
9]; these include enzymes involved in collagen biosynthesis as procollagen propeptidases (ADAMTS-2, ADAMTS-3 and ADAMTS-14) [
10‐
13]. Other members of the family are so-called 'aggrecanases' (ADAMTS-1, ADAMTS-4, ADAMTS-5, ADAMTS-8, ADAMTS-9 and ADAMTS-15) that degrade the interglobular domain separating G1 and G2 of aggrecan at a specific Glu373–Ala374 bond [
14‐
18].
A family of four specific inhibitors, the tissue inhibitors of metalloproteinases (TIMPs), has been described [
19]. These are endogenous inhibitors of MMPs and potentially the ADAMTS family. The ability of the TIMPs to block active MMPs is largely promiscuous. TIMP-3 seems to be the most potent inhibitor of the ADAMTS family, with a subnanomolar K
i against ADAMTS-4 and ADAMTS-5 [
20].
Although the dogma has been that OA is a 'noninflammatory' disease driven by the chondrocyte, there is certainly evidence for synovial involvement. Low-grade synovitis with thickening of the lining layer, increased vascularity and inflammatory-cell infiltration is reported in patients with all grades of OA [
21]. This results in the expression of cytokines and proteinases that could contribute to the pathogenesis of the disease [
22]. Arthroscopic studies have also shown that inflammatory changes in the OA synovium often occur where this tissue is in contact with cartilage [
23,
24]. More recent studies using magnetic resonance imaging (MRI) reinforce the idea that synovitis is a frequent feature, even of early OA [
25].
We recently published a complete expression profile of all MMPs, the ADAMTS family and the four TIMPs in normal cartilage compared with OA cartilage [
26]. This identified a number of genes that are regulated in OA, which are hence implicated in the disease process. Because the synovium might contribute to cartilage-matrix destruction in OA, we have extended the screening in the current study. Hence, we have profiled
MMP,
ADAMTS and
TIMP genes in both cartilage and synovium from normal and OA joints, giving a more complete picture of proteolysis in this disease.
Materials and methods
Cartilage samples
Human articular cartilage was obtained from femoral heads of patients undergoing total-hip-replacement surgery at the Norfolk and Norwich University Hospital (Norwich, UK). Samples from patients with OA (n = 16, of which 7 patients were female and 9 patients were male; age range, 61–84 years) were compared with cartilage from patients undergoing hip replacement following fracture to the neck of femur (NOF; n = 24, of which 19 patients were female and 5 patients were male; age range, 52–92 years). OA was diagnosed using the clinical history and an examination, coupled with X-ray findings; confirmation of gross pathology was made at time of joint removal. The fracture patients had no known history of joint disease and their cartilage was free of lesions; 80% of these patients underwent surgery within 36 hours of fracture. This study was performed with Ethical Committee approval and all patients provided informed consent.
Femoral head dissection
Intact femoral heads were washed in sterile PBS. Cartilage samples were removed from the femoral head using a razor blade, chopped into 2–5 mm pieces and snap frozen in liquid nitrogen within 15–30 minutes of surgery. Synovium was washed in sterile PBS, snap frozen and stored in liquid nitrogen.
Extractions were performed on the same day or within 24 hours of dissection from the femoral head following the basic method of Price
et al. [
27]. Cartilage was weighed and ground under liquid nitrogen using a freezer mill (SPEX CertiPrep 6750, Glen Creston, Stanmore, Middlesex, UK). TRIzol
® reagent (Invitrogen, Paisley, UK) was added immediately to ground cartilage (1 ml/0.2 g cartilage); the solution was mixed thoroughly and incubated at room temperature for 5 minutes. Ground cartilage was pelleted at 9,500 g for 10 minutes at 4°C and the supernatant recovered. To each 0.5 ml of TRIzol
®, 300 μl of chloroform was added; the resulting solution was vortexed for 15 seconds and incubated at room temperature 10 minutes. The TRIzol
®/chloroform solution was centrifuged at 9,500 g for 15 minutes at 4°C. The aqueous layer was recovered into a fresh tube and mixed with a half volume of 100% ethanol. Using the RNeasy Mini Kit (Qiagen, Crawley, West Sussex, UK) samples were applied to spin columns and centrifuged at 9,500 g for 15 seconds at room temperature and the flow-through discarded. Columns were then washed and eluted according to the manufacturer's instructions. RNA samples were quantified using the NanoDrop
® spectrophotometer (NanoDrop Technologies, Wilmington, Delaware, USA) and stored at -80°C.
To each 100 mg tissue sample, 1 ml of TRIzol® was added; the solution was homogenized using a TissueLyser (Qiagen, Crawley, West Sussex, UK). The homogenized sample was pelleted at 9,500 g for 10 minutes at 4°C and the supernatant recovered. To each 1 ml of TRIzol®, 400 μl of chloroform was added; the resulting solution was vortexed for 15 seconds and incubated at room temperature for 5 minutes. Samples were centrifuged at 9,500 g for 10 minutes at 4°C. The aqueous phase was recovered and 250 μl of isopropanol was added. This was vortexed, as before, and incubated at room temperature for 10 minutes. The mixture was centrifuged at 9,500 g for 10 minutes at 4°C and the supernatant discarded. The RNA pellet was washed with 75% ethanol solution and centrifuged at 9,500 g for 5 minutes at 4°C. The supernatant was discarded, and the pellet was air dried and then suspended in 20 μl of RNAse-free water. The RNA was incubated at 55°C for 10 minutes before storage at -80°C. RNA samples were quantified using the NanoDrop® spectrophotometer (NanoDrop Technologies, Wilmington, Delaware, USA).
Synthesis of cDNA
cDNA was synthesised from 1 μg of total RNA using Superscript II reverse transcriptase (Invitrogen, Paisley, UK) and random hexamers in a total volume of 20 μl according to the manufacturer's instructions. cDNA was stored at -20°C until used in downstream PCR.
Quantitative real-time PCR
Oligonucleotide primers and fluorescent-labelled probes were designed using Primer Express 1.0 software (Applied Biosystems, Warrington, UK). Sequences for
MMP and
TIMP primers and probes are as described in [
28] and sequences for
ADAMTS primers and probes are as described in [
29]. To control against amplification of genomic DNA, primers were placed within different exons close to an intron/exon boundary, with the probe spanning two neighbouring exons where possible. The BLAST was used to search for all the primer and probe sequences to ensure gene specificity. The
18S rRNA gene was used as an endogenous control to normalize for differences in the amount of total RNA present in each sample; the 18S rRNA primers and probe were purchased from Applied Biosystems (Warrington, UK). Primers for detection of specific splice variants of
MMP28 were as follows:
1. Variant 1 [GenBank NM_024302]: 5'-CTGCGGCAGTGTCATTGAATG-3' (forward), 5'-GGGCCCCGGAACCT-3' (reverse), and 5'-CATCGACCCCCTTTGAAG-3' (probe).
2. Variant 2 [GenBank NM_032950]: 5'-CTGCGGCAGTGTCATTGAATG-3' (forward), 5'-CCCACGATGGTTGGTATTCATATCA-3' (reverse), and 5'-TTCTTCAAAGTGCAATCCGT-3' (probe).
Relative quantification of genes was performed using the ABI Prism 7700 sequence detection system (Applied Biosystems, Warrington, UK) in accordance with the manufacturer's protocol. PCR reactions contained 5 ng of reverse-transcribed RNA (1 ng for 18S analyses), 50% TaqMan 2X Master Mix (Applied Biosystems, Warrington, UK), 100 nM of each primer and 200 nM of probe in a total volume of 25 μl. Conditions for the PCR reaction were as follows: 2 minutes at 50°C, 10 minutes at 95°C, 40 cycles of 15 seconds at 95°C, and 1 minute at 60°C.
The threshold cycle (C
T), the cycle number at which signal is detectable above the baseline, was transformed in two ways. To gain an approximate comparison across all genes measured, amplification efficiency was assumed identical across all primer sets and target gene expression was normalized to
18S expression using a logarithmic transformation proportional to normalized copy number (log
102
-ΔCT), where ΔC
T is C
T(target gene) – C
T(18S) [
30]. When comparing the expression of a single gene across the sample groups, standard curves for each gene were generated using the cDNA from one sample and making twofold serial dilutions across an appropriate range. Relative input amounts of template cDNA were then calculated from C
T using the standard curves; data are presented as relative levels of mRNA normalized to 18S rRNA. Statistical analyses between OA and fractured NOF samples were performed using this latter method.
For comparison of expression levels between genes, cDNA for 18S, MMP13, MMP28 and ADAMTS16 was subcloned into a plasmid vector. Serial dilutions of these plasmids, between 10-12 moles and 10-23 moles DNA, were used to create a standard curve. This enabled CT to be converted into the number of cDNA molecules and calculation of the ratio of target gene to 18S.
As a final quality control for the purified RNA samples, only cDNA falling within ± 1.5 C
T of the median value for
18S for all samples were used in the downstream study. To ascertain whether the amplification product was indeed that of the desired target gene, products were subcloned and sequenced. All primer and probe sets were shown to amplify specific products from appropriate human tissue samples [
28,
29].
Statistical analysis
Differences between control and OA groups were defined using a two-sided Mann-Whitney U test; this nonparametric test makes no prior assumption about the distribution of the data. Correlations between genes were assessed using Spearman's rank correlation.
Discussion
This is the first study to profile the expression of all
MMP,
ADAMTS and
TIMP genes in synovium and compare tissue from OA patients with those who have a fracture to the NOF. Konttinen
et al. had previously used conventional reverse-transcriptase PCR to profile the expression of 16
MMPs in synovium (
MMP1–3,
MMP7-17 and
MMP19), with induction of
MMP1,
MMP9,
MMP13,
MMP14 and
MMP15 in synovium from rheumatoid arthritis compared with trauma controls [
31].
Recent studies show that inflammatory changes in the OA synovium are variable throughout the tissue [
23,
24]. This might be expected to confound measurement of regulated gene expression in this tissue because variation across the tissue within a single joint would lead to greater variation in gene expression within each patient group. This is borne out by our study, in which more genes showed significant regulation between OA and fractured NOF in cartilage than synovium.
Several studies have measured MMPs in synovium or synovial fluid and demonstrated that levels of MMP-1 and MMP-3 are elevated in rheumatoid arthritis (compared with OA or other control groups, such as joint trauma; e.g. [
32‐
36]). High expression of a number of MMPs has been demonstrated in rheumatoid pannus, suggesting a role mediating cartilage destruction in RA (e.g. [
31,
37]). Indeed, levels of synovial fluid MMP-1 and MMP-3 correlate to synovial hyperplasia [
38]. Although levels of synovial fluid MMPs are generally raised in RA compared with OA, the levels of at least MMP-1–3, MMP-8, MMP-9 and TIMP-1 are reported to be raised in OA compared with control, nonarthritic, synovial fluid (e.g. [
39,
40]).
In this study, the four most significantly upregulated genes (
P < 0.0001) in OA synovium compared with fracture of the NOF are
MMP28,
ADAMTS16,
ADAMTS17 and
TIMP2. Interestingly, we recently published the first report of
MMP28 and
ADAMTS16 gene expression in cartilage and their upregulation in OA [
26]. Although these enzymes have no known function, the fact that their expression is switched on in at least two tissues of the OA joint underlines their probable role in this disease.
ADAMTS17 is another recently cloned ADAMTS family member with unknown function and this is the first report of its expression in synovium. TIMP-2 can inhibit the activity of all the MMPs and the increase in expression in OA synovium might represent an attempt to control proteolysis. The expression of
MMP13, the probable key collagenase in OA, is also upregulated in OA synovium, in addition to cartilage.
MMP-1, MMP-2, MMP-9–11, MMP-13 and TIMP-2 are all expressed in human growth plate hypertrophic chondrocytes [
41]. Interestingly, a significant subset of these (
MMP2,
MMP9,
MMP11,
MMP13 and
TIMP2) is upregulated in OA cartilage.
MMP-1 and MMP-3 are the most frequently measured enzymes in RA, where correlations of synovial fluid or serum levels to disease activity have been reported [
36,
39]. Our data show that in synovium there is no difference in expression between OA and fracture to the NOF, whereas in cartilage, as we and others have previously reported, there is a significant downregulation of expression in OA [
26,
42]. This might reflect the late stage of the disease tissue in our study (see below), or, for MMP-3, a maintenance role in cartilage metabolism. Our data support the fact that
MMP3 is a highly expressed gene in synovium, as previously reported [
37].
Other genes expressed at significantly higher levels in OA synovium compared with fracture to the NOF are
MMP9,
MMP11,
MMP16,
ADAMTS8,
ADAMTS10 and
ADAMTS13, although the absolute expression of
ADAMTS8 is low. MMP-9 has previously been reported as elevated in RA synovium (e.g. [
31,
38]) and in synovium and synovial fluid in a dog model of OA [
43]. Elevated
MMP11 expression has also been previously reported in late-stage OA [
42].
MMP16 expression has been reported in synovium, but was not associated with disease [
31], whereas
ADAMTS8,
ADAMTS10 and
ADAMTS13 have not previously been described in synovium. ADAMTS-8 is capable of degrading aggrecan [
44], although with lesser catalytic efficiency compared with, for example, ADAMTS-4 or ADAMTS-5.
The expression of
MMP10 was the most significantly downregulated of any
MMP in OA synovium compared with fractured NOF.
MMP10 expression has been previously described in synovium, but its regulation has not been described in disease [
31].
MMP10 expression has also been associated with the invasive potential of synovial fibroblasts in both OA and RA [
45].
We previously reported that the expression of
ADAMTS4,
ADAMTS5 and
ADAMTS9, all aggrecanases, was downregulated in OA cartilage compared with fractured NOF [
26]. These genes, particularly
ADAMTS4 and
ADAMTS9, are also downregulated in OA synovium. This could reflect a role for aggrecanases in the earlier phases of OA, but similar expression patterns in cartilage and synovium could also suggest a role for the synovium in aggrecan turnover and breakdown. Synovium has been shown to express soluble aggrecanase activity [
46], and ADAMTS-5 has been localized to human synovium [
47].
A comparison of the expression patterns of
MMP,
ADAMTS and
TIMP genes in cartilage in this study with those in our previous report shows predominantly similar data. Overall, a greater number of genes were regulated between OA and fractured NOF samples in the current study. This might reflect differences in the actual patient groups in each study or the rapidity of tissue dissection and processing. Genes induced in OA with weak significance in the current study,
MMP17,
MMP24 and
ADAMTS10, all show a trend towards induction in our previous cohort but did not reach significance. The same is true for
MMP12,
MMP15 and
ADAMTS3.
ADAMTS15 showed upregulation in OA in the current study at
P < 0.05 and similarly significant downregulation in our previous study. This might represent variation because of multiple testing. More difficult to explain are the significantly upregulated genes in OA in the current study,
MMP21 (
P < 0.001),
MMP19 (
P < 0.0001) and
MMP23 (
P < 0.0001); these genes showed no significant difference in our earlier cohort. Where genes are annotated as 'not detected' (Figures
1,
2,
3 and [
26], these might not be expressed at all in the tissue or the median C
T is 40, with a few samples showing a low level of expression.
For MMP9, MMP10, MMP12, MMP17, MMP23, MMP28, ADAMTS4, and ADAMTS9, there is a significant correlation between expression levels in the synovium and cartilage. This presumably reflects the fact that these tissues are exposed to a similar environment in terms of growth factors and cytokines. For genes where expression between the two tissues does not correlate, there must therefore be other factors driving expression, such as mechanical load, oxidative stress and cell-matrix interaction.
To resolve previously raised questions, we used plasmid cDNA for MMP13, MMP28 and ADAMTS16 to construct standard curves for these genes. This demonstrated that MMP13 was the most abundant mRNA of the three genes. It remains impossible to speculate about their relative importance because the substrates, and therefore the specific activities of MMP-28 and ADAMTS-16, are unknown.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
RKD helped design and coordinate the study, collected and processed tissue samples, performed real-time PCR, analysed data and helped draft the manuscript; JGW and LK helped in collecting and processing tissue samples; CD and AC took patient consent and coordinated tissue collection; STD helped design and coordinate study, tissue collection and interpretation of data; IMC helped conceive, design and coordinate the study, and helped to draft the manuscript. All authors read and approved the final manuscript.