Introduction
Rheumatoid arthritis (RA) is a chronic inflammatory disease characterized by polyarticular joint inflammation, synovial hyperplasia, and cartilage and bone destruction, with subsequent joint deformities. The inflammatory synovial fluid in RA patients contains–in addition to various cytokines and growth factors–high levels of leukotrienes, with leukotriene B
4 (LTB
4) being predominant [
1].
LTB
4 is a powerful proinflammatory lipid mediator and one of the most potent chemotactic agents known to date [
2]. This leukotriene is produced mainly by neutrophils, macrophages and mast cells, and promotes neutrophil recruitment and activation [
3]. Neutrophils are the most abundant leukocytes in rheumatoid joints [
4], and have destructive potential by secreting proteases and reactive oxygen species and by promoting synthesis of matrix metalloproteinases [
5,
6]. Several lines of evidence have implicated LTB
4 as an important mediator of joint inflammation in RA. LTB
4 is present at higher levels in serum of patients with active RA compared with patients with inactive arthritis or normal subjects [
7], and its levels correlate with the disease severity [
8].
A critical contribution of neutrophil-derived LTB
4 to arthritis induction and severity has recently been revealed in a mouse serum transfer model of inflammatory arthritis [
9]. In this study it was shown that mice lacking 5-lipoxygenase (5-LO) or leukotriene A
4 hydrolase enzymes are protected from developing the disease and that there is a specific requirement for LTB
4 and not other leukotrienes for the pathogenesis in this model. 5-LO and 5-LO activating protein (FLAP), followed by leukotriene A
4 hydrolase, are the enzymes responsible for the sequential formation of LTB
4 from arachidonic acid (AA).
15-Lipoxygenase (15-LO) is a lipid-peroxidizing enzyme mainly expressed in airway epithelial cells, eosinophils, reticulocytes and macrophages. In humans, 15-LO exists as two different enzymes with different cell localizations and product profiles [
10]. 15-LO-1 converts AA to an unstable intermediate, 15-hydroperoxyeicosatetraenoic acid, which can be further converted to 15-hydroxyeicosatetraenoic acid (15-HETE). The 15-LO-1 enzyme has proinflammatory actions, with high levels of 15-HETE reported in sputum of asthmatic patients along with increased macrophage 15-LO-1 mRNA expression [
11]. 15-LO-1 expression is induced by IL-13 in human blood monocytes [
12] and by IL-4 in monocytes, alveolar macrophages, dendritic cells, mast cells and rheumatoid arthritis synovial cells [
12‐
18]. Only recently was it reported that 15-LO-1 can catalyze the metabolism of AA to the proinflammatory eoxins that can increase permeability of the endothelial cell monolayer
in vitro, indicating that they can enhance vascular permeability [
19]. 15-LO-1 products, however, were also demonstrated to have protective roles in inflammatory disorders due to formation of anti-inflammatory lipoxins [
20‐
22]. The 15-LO-1 mRNA was demonstrated to be present in RA synovial membranes [
23] and its expression was stronger in RA compared with osteoarthritis (OA) biopsies [
24].
The 5-LO cascade and the role of LTB
4 in RA are well documented. Although the presence of 5-LO enzyme in the synovial lining of rheumatoid tissue has recently been reported [
24], a detailed characterization of cells expressing 5-LO in human synovial tissue is lacking. Evidence is also limited regarding the influence of current therapy for RA on this pathway.
Glucocorticoids (GCs) are used in RA as an efficient adjuvant therapy and their efficacy is related to their broad anti-inflammatory profile, with inhibition of inflammatory cells functions [
25]. Controversial results have been reported about the effects of GCs on 5-LO expression and LTB
4 formation. Some studies reported that 5-LO pathway activity is decreased in the presence of GCs [
26,
27], while other investigators have shown that
in vivo GC administration had no influence on LTB
4 formation [
28,
29]. In contrast, leukotriene synthesis and 5-LO expression were increased in human blood monocytes [
30] and mast cells [
31] by dexamethasone. In addition, blood polymorphonuclear neutrophils from RA patients released higher amounts of LTB
4 after GC pulse therapy [
32] while intraarticular corticosteroids reduced the LTB
4 level in synovial fluid of RA patients [
33].
In comparison, there are few studies to date investigating the effects of corticosteroids on 15-LO-1 expression. In a rabbit model for atherosclerosis, corticosteroid treatment was shown to decrease atherosclerotic plaque formation along with increasing 15-LO-1 expression in the arterial wall [
34]. GC treatment of asthma patients, however, has been reported to decrease the expression of 15-LO-1 in the lung [
35].
In the present study we characterized the expression pattern of 5-LO and 15-LO-1 enzymes in synovial tissue of RA and OA patients and phenotyped the positive cells. In addition, we determined the effects of intraarticular glucocorticoids on the expression of these enzymes in RA synovium.
Materials and methods
Patients
In the first study group, we analyzed synovial biopsies from six RA patients and from five OA patients collected at the time of orthopedic surgery. In a second group, 11 RA patients were recruited into the study. The demographical and clinical data of the second patients group are presented in Table
1.
Table 1
Demographical and clinical data of the second patient group (n = 11)
Age (years) | 68 (35 to 83) |
Gender (male/female) | 3/8 |
Disease duration (months) | 24 (3 to 240) |
Current knee arthritis episode duration (months) | 2 (0.5 to 6) |
Taking disease-modifying antirheumatic drugs | 6 |
Taking oral corticosteroids | 2 |
Taking nonsteroidal anti-inflammatory drugs | 4 |
Time between biopsies (days) | 10 (7 to 12) |
All patients in the second group received an intraarticular knee injection of 40 mg triamcinolone hexacetonide, and synovial biopsies were collected by arthroscopy immediately prior to treatment and a median of 10 days after treatment. The treatment regimen remained unchanged from at least 2 weeks prior to and during the entire study period.
All RA patients fulfilled the 1987 American College of Rheumatology diagnostic criteria for RA [
36]. The ethics committee at the Karolinska Hospital approved all experiments on human cells and tissues. Informed consent was obtained from all study subjects.
Tissue preparation and immunohistochemical analysis
Serial cryostat sections (7 μm) were fixed for 20 minutes in 2% formaldehyde (v/v), air-dried and then stored at -70°C. Immunohistochemical staining was performed as described previously [
37]. The inhouse antibodies used were affinity-purified rabbit polyclonal antibody against human 5-LO and rabbit polyclonal anti-human 15-LO-1 antibody. Rabbit IgG served as the negative control. Stained synovial biopsies were evaluated using a Polyvar II microscope (Reichert-Jung, Vienna, Austria) and photographs were taken with a digital camera (300F; Leica, Cambridge, UK). Synovial expression of 5-LO and 15-LO-1 was quantified by computer-assisted image analysis and was expressed as the percentage of positive stained area versus total tissue area.
Synovial fluid cells from RA patients were collected on slides by cytospin centrifugation. The slides were then fixed and processed for immunhistochemical detection of 15-LO-1 as described above.
Immunofluorescence staining
Double immunofluorescence staining was performed using rabbit anti-human 5-LO or 15-LO-1, mouse anti-human CD163 (Ber-MAC3; DakoCytomation, Glostrup, Denmark), mouse anti-human CD68 (KP1; DakoCytomation), mouse anti-human prolyl 4-hydrolase (DakoCytomation), mouse anti-human CD66b (80H3; Beckman Coulter, France), mouse anti-human CD3 (SK7; BD Biosciences, San Jose, CA, USA), mouse anti-human CD20 (DakoCytomation), mouse anti-human CD31 (EN4; Novakemi AB, Handen, Sweden), and mouse anti-human mast cell tryptase (Chemicon International, Temecula, CA, USA) antibodies.
The staining procedure has been published previously [
38]. Briefly, after blocking with an avidin–biotin kit (Vector Laboratories, Peterborough, UK), sections were incubated overnight with primary antibodies. Subsequently, slides were incubated with secondary biotinylated goat anti-rabbit antibody (heavy and light chain; Vector Laboratories) and streptavidin-conjugated fluorochrome Alexa 488 (Molecular Probes, Leiden, the Netherlands). The slides were blocked again with the avidin–biotin kit and were incubated with the next secondary biotinylated horse anti-mouse antibody (IgG heavy and light chain; Vector Laboratories), followed by streptavidin-conjugated fluorochrome Alexa 546 (Molecular Probes). Matched IgG isotype controls were included for all markers.
15-LO-1 product measurement in RA synovial fluid cells
Synovial fluid from RA patients was centrifuged and the pelleted cells were resuspended in PBS and washed twice. The cellular composition of synovial fluid cells was analyzed using flow cytometry. Monocyte, neutrophil and lymphocyte populations were identified using a FACSCalibur (Becton Dickinson, San Jose, CA, USA) and Cell Quest software (Becton Dickinson). AA was added to a final concentration of 40 μM and the cells were incubated for 5 minutes at 37°C. Buffer control without cells was used to assess for spontaneous degradation of AA. Subsequently, the samples were centrifuged and the supernatant collected and stored at -70°C until analysis by enzyme immunoassay according to the manufacturer's instructions (Cayman Chemicals, Ann Arbor, MI, USA).
Statistical analysis
Statistical analysis was performed using the Wilcoxon test and Bonferroni correction for multiple comparisons for paired samples for the synovial biopsy data, and using the Mann–Whitney test for 15-HETE production.
Discussion
The leukotriene pathway, and in particular LTB4, has long been recognized to have deleterious effects in arthritis. Nevertheless, the enzymes responsible for arthritis formation have not been well characterized in synovial tissues, and nor is it known whether they are targeted by current RA therapy.
In the present study we showed that 5-LO is expressed in synovial tissue from patients with RA, mainly in macrophage-like cells and to a lesser extent in neutrophils and mast cells. We did not, however, detect 5-LO enzyme in T cells or B cells in RA biopsies. Although previous studies indicate that tonsillar B lymphocytes and B-cell lines are abundant in 5-LO protein [
39,
40], recent data reveal that, within the tonsils, it is the mantle-zone B cells that are 5-LO-positive and not the germinal-centre B cells or plasma cells [
41]. In fact, it has been suggested that RA synovial B cells mainly represent mature activated memory B cells and plasma cells [
42]. Our findings that RA CD20
+ B cells display no detectable 5-LO staining may therefore be explained in part by the specific B-cell subsets present in RA synovium. The wide expression of 5-LO in the synovial tissue of RA patients is in agreement with studies describing the LTB
4 presence in RA synovial fluid [
1] and the 5-LO-positive immunostaining in areas coinciding with macrophage localization [
24].
We also observed a low number of cells expressing 5-LO in OA tissue, scattered in areas with more abundant synovial membranes. By quantifying the positive staining areas, we showed that OA synovium expresses significantly less 5-LO than RA tissue. Indeed, OA synovial fluid has been shown to contain less LTB
4 than RA fluid [
8] and OA synovium is known to contain a low degree of infiltrating inflammatory cells, which is in line with our observations.
There are a limited number of studies investigating the 15-LO-1 pathway in chronic inflammatory disorders, although the products of this pathway have long been recognized to play important roles in immune regulation and inflammation [
43]. We underwent a detailed study characterizing the expression of 15-LO-1 enzyme in RA synovium, showing that it is highly expressed in synovial lining and scattered sublining fibroblast and macrophages and also in vessels of different sizes. In addition, we showed here that endothelial cells from both RA and OA biopsies express 15-LO-1. In OA, however, few synovial lining cells stained positively for 15-LO-1 while 15-LO-1 was abundantly present in vessels. The overall 15-LO expression was significantly lower in OA synovium compared with RA synovium.
The expression of functional 15-LO-1 in endothelial cells has been somewhat controversial, although some studies have demonstrated expression of 15-LO-1 in these cells [
44]. Human and rabbit aortic endothelial cells, however, were more recently revealed to express 15-LO-1 mRNA and protein [
45]. In addition, the presence of 15-LO-1 in endothelial cells was correlated with an induction of NF-κB activity and a subsequent increase in intracellular adhesion molecule expression [
46], which may augment the local influx of cells. Our finding that 15-LO-1 is localized in endothelial cells from RA synovium may therefore be related to its ability to form mediators that locally attract immune cells and promote inflammation.
Although 15-LO-1 is largely present in the synovial tissue, its main product (15-HETE) was not detectable in synovial fluid in the present study. Synovial fluid cells incubated with AA form only small amounts of this eicosanoid product. One explanation for this may reside in the methodology we used, such as a short incubation time. Furthermore, the synovial fluid was isolated from patients treated with various regimens. Cells incubated with AA still form significantly higher amounts of 15-HETE compared with cells without AA, demonstrating the capacity of these cells to produce 15-HETE.
We further demonstrated that 5-LO expression in synovial tissue was significantly decreased following intraarticular administration of GCs. This finding is consistent with previous work documenting reduced synthesis of LTB
4 in neutrophils of patients with RA after intraarticular GC injection [
33]. It has been demonstrated previously that the number of macrophages in RA synovial tissue is not influenced by therapy with local GCs [
47]. This suggests that the decrease in 5-LO expression we observe here most probably reflects a decrease in cellular expression and not a lower number of cells locally present. Other investigators, however, have found that systemic treatment with GCs is followed by reduced macrophage infiltration in RA synovium [
48]. Different biological mechanisms may operate when administrating GCs intraarticularly or systemically. Further investigation is therefore needed to elucidate the mechanism for the reduction in 5-LO expression.
GCs are very efficient in achieving important clinical and radiographic outcomes in RA [
49]. Intraarticular GC may also confer a bone-protecting effect in RA by decreasing the RANKL/osteoprotegerin ratio [
50]. Previous studies have indicated LTB
4 to be a negative regulator of bone metabolism by activating osteoclasts and inhibiting osteoblasts, thus promoting bone degradation and inhibiting bone formation [
51,
52]. In this context, the decrease in 5-LO expression after intraarticular GC therapy may indicate a potential role for 5-LO in bone degradation associated with inflammatory arthritis and suggests a new mechanism for the bone-protecting effects of intraarticular GCs.
Since LTB4 has been demonstrated to be a key regulator in the pathogenesis of murine arthritis [
9], it may be conceivable that targeting the 5-LO pathway could provide additional benefits in the treatment of RA, by reducing the formation of LTB
4 and, by this means, decreasing the chemotaxis of inflammatory cells. Few studies have investigated the effects of 5-LO pathway inhibition in RA patients. In a 4-week clinical trial, treatment with zileuton showed a trend towards clinical improvement, but the duration of the study was not adequate to assess efficacy [
53]. Novel 5-LO inhibitors may possibly offer better treatment effects.
There are few studies to date on 15-LO-1 in RA, and the role of its products in inflammation is not clearly defined. We demonstrate here that locally administered corticosteroids do not significantly change the expression of 15-LO-1 in RA synovium. Previously, it was shown that 15-LO-1 metabolites confer proinflammatory actions by increasing vascular permeability
in vitro [
19], enhancing expression of monocyte chemotactic protein-1 and TNFα in vascular smooth muscle cells via activation of NF-κB [
54]. On the other hand, 15-LO-1 products may also have anti-inflammatory properties, by reducing synovitis through decreased LTB
4 in experimental arthritis [
55], inhibiting chemotaxis of neutrophils to LTB
4 [
56] or through transcellular formation of lipoxins [
57]. In this sense, it is noteworthy that IL-13, known to increase 15-LO-1 expression in several cell systems, is constantly present in synovial fluid of RA patients and has the ability to decrease proinflammatory cytokine production by synovial fluid mononuclear cells [
58]. 15-LO-1 and its metabolites may therefore have dual roles in inflammation, and the net effect in RA needs further investigation.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
KRG performed acquisition and interpretation of data, performed statistical analysis and wrote the manuscript. MK participated in acquisition and interpretation of data, and in writing the manuscript. AIC provided the patient biopsies and their clinical data and participated in writing the manuscript. LB participated in the collection of data. EaK provided patient biopsies and participated in writing the manuscript. H-EC participated in the study design and preparation of the manuscript. OR participated in writing the manuscript. P-JJ was responsible for study design, interpretation of data and participated in writing the manuscript.