Estrogen attenuates the spondyloarthritis manifestations of the SKG arthritis model

Ankylosing spondylitis (AS) is a chronic inflammatory disease that primarily affects the sacroiliac joints and spine. Syndesmophytes and ankylosis occur as a consequence of longstanding inflammation, resulting in loss of function and disability. AS is a male-predominant disease and men with this disease also tend to have radiographic evidence of more severe damage [1]. Diagnosing this disease at an early stage is challenging; the classification criteria for axial spondyloarthritis (SpA) were developed by the Assessment of SpondyloArthritis international Society (ASAS) [2] and the ASAS criteria therefore cover both patients with or without established radiographic changes in the sacroiliac joint. The clinical presentation, clinical disease activity, and treatment responses of both groups are similar [3, 4]. However, patients with non-radiographic axial spondyloarthritis (nr-axSpA) have lower C-reactive protein (CRP) [5, 6] and less active inflammation on magnetic resonance imaging (MRI) than patients with AS [6]. Interestingly, the male-to-female ratio of nr-axSpA has been reported to be approximately 1:1, whereas it is 2:1 in patients with AS [5‐7]. The proportion of female patients was significantly lower among the group of patients who progressed from nr-axSpA to AS [8]. The female predominance of patients with nr-axSpA can be understood in the same context, as male patients with AS have more severe radiographic damage than female patients with AS [1, 9]. The underlying pathogenesis of the differences between men and women with AS is still unknown.

Jimenez-Balderas et al. reported that 17β-estradiol (E2) levels are lower in patients with active AS than in those with inactive AS. Peripheral arthritis was shown to subside and the clinical activity of AS was reduced after oral estrogen therapy [10]. Estrogen modulates immune-related processes, such as T cell differentiation and cytokine production [11]. Estrogen is involved in the immune response, characterized by a bias toward type 2 cytokine profiles [12]. Animal model studies have suggested that estrogen can inhibit the differentiation of T helper (Th)17 cells from naïve T cells [13, 14].

Wnt proteins play an important role in the anabolic pattern of joint remodeling in AS. Dickkopf-related protein 1 (Dkk1) is an inhibitor of the Wnt pathway and acts as a master regulator of joint remodeling [15]. Increased Dkk1 is related to bone resorption, whereas decreased Dkk1 is linked to new bone formation [16]. To the best of our knowledge, there are no data about the relationship between estrogen and Wnt inhibitors in patients with AS.

Sakaguchi et al. characterized the SKG mouse strain, which develops spontaneous autoimmune inflammatory arthritis after systemic ß-glucan exposure [17]. Although the SKG mouse model was first used as a rheumatoid arthritis (RA) model, Ruutu et al. reported that SKG mice have clinical characteristics of SpA, including spondylitis, enthesitis, and bowel inflammation [18]. The role of estrogen in the pathogenesis and disease activity of SpA has not been determined. We hypothesized that estrogen has an anti-inflammatory effect on the disease activity of SpA. Therefore, the aim of this study was to investigate the role of estrogen in the disease activity of SpA using the SKG mouse model. We evaluated the effect of estrogen on the development and progression of SpA and investigated the relationship between estrogen and inflammatory cytokines.

We investigated the role of estrogen in the disease activity of SpA. We found that estrogen suppressed the development of arthritis in SpA, using an animal model. The E2-treated group had significantly suppressed arthritis compared with both the ovariectomized and the sham groups. There was no difference between the ovariectomized and sham groups. We found that arthritis was induced in almost all female mice with normal ovaries, and the clinical score was almost 6 (the maximum score). We could not assess the difference between mice in the ovariectomized group and mice that received a physiologic dose of estrogen (the sham group) because female mice with normal ovaries (the sham group) already had zymosan-induced severe arthritis. A high dose of E2 pellets was used (72 mg, 60 days release), which was higher than the physiologic concentration [19]. The different responses between the E2-treated group and the sham group were likely due to the different estrogen doses received by these two groups.

The current study demonstrated that E2-treated mice had decreased expression of TNF in the joint tissue. These results support the hypothesis that estrogen inhibits the production of TNF [20]. E2 has been shown to downregulate TNF production and reduce the severity of experimental autoimmune encephalomyelitis in cytokine knockout mice [21]. Estrogen-deficient female rats are also reported to have higher bioactive serum TNF than estrogen-supplemented animals [22]. An in vitro study showed that E2 treatment downregulates cytokine-induced TNF gene expression [23]. Considering that TNF is a key cytokine in the pathogenesis of SpA, the results of the current study indicate that transcription of TNF might be regulated by estrogen in patients with SpA.

The current study demonstrated that E2 treatment significantly reduced the gene expression of IFN-γ, whereas the expression of IL-4 increased significantly in the joint tissues in response to E2 treatment. This corresponds well with recent data from a mouse model of autoimmune encephalomyelitis [24]. In that study, high and medium doses of estrogen increased the production of IL-4, IL-10, and transforming growth factor (TGF)-β, whereas estrogen treatment reduced the production of IFN-γ, IL-17, and IL-6. Estrogen triggers a shift in the Th1/Th2 balance toward Th2 production [25]. Thus, in Th1-mediated autoimmune diseases such as RA, symptoms often decrease during pregnancy and flare or initially develop in the postpartum period. In contrast, Th2-mediated diseases such as systemic lupus erythematosus (SLE) often flare during pregnancy [26]. Estrogen also inhibits Th17 cell production. In ovariectomized DBA/1 mice with established collagen-induced arthritis (CIA), E2 treatment reduces the severity of arthritis and results in fewer Th17 cells in the joints compared with controls [27]. Tyagi et al. reported that transcription factors that promote Th17 cell differentiation and IL-17 levels are increased in ovariectomized mice, and that these effects are reversed by E2 supplementation [13]. Another study also showed that E2 inhibits arthritis and reduces IL-17-producing γδT cells in the joints of CIA mice [28]. It is well known that the Th17 axis is overactive in patients with AS [29, 30], and the percentage of Th17 cells is significantly lower in nr-axSpA than in AS. Our data suggest that E2 modulates cells with IL-17-producing capacity during arthritis development in SpA.

The mechanism of the relationship between estrogen and T cell differentiation is unknown. In cross-sectional studies, testosterone levels have been found to be similar in patients with AS and controls, but serum dehydroepiandrosterone sulfate (DHEAS) and 17α- hydroxyprogesterone were more elevated in male patients with AS than in male controls [31‐33]. The gene for the enzyme, 21-hydroxylase, is located close to the human leukocyte antigen (HLA)-B locus on the short arm of chromosome 6. HLA-B27 might serve as a marker of partial 21-hydroxylase deficiency, resulting in high DHEAS and 17α-hydroxyprogesterone levels. A proinflammatory Th1 phenotype might be enhanced by increased DHEAS, whereas estrogen and progesterone suppress the Th1 phenotype [12]. β-catenin/TCF promotes differentiation of Th2 from naïve CD4 T cells and prevents the differentiation of Th17/Th1. Estrogen might be involved in T cell differentiation via the Wnt/β-catenin pathway [34]. The relationship between estrogen and T cell differentiation in SpA has not been investigated; therefore, further study is needed to determine the role of estrogen in T cell differentiation in SpA.

In the current study, we also evaluated the role of Wnt inhibitors in the disease activity of SpA. The German Spondyloarthritis Inception Cohort (GESPIC) study reported that patients with lower Dkk1 levels were more prone to develop syndesmophytes than those with higher levels [35]. In the present study, expression of Dkk1 was decreased in zymosan-treated mice compared with controls. In addition, expression of Dkk1 was significantly increased in E2-treated mice compared with the ovariectomized and sham groups. This corresponds well with the previous finding that expression of Dkk1 and SOST was reduced in the spine of a proteoglycan-induced spondylitis (PGISp) mouse model of SpA, compared with controls [36]. SOST is another Wnt inhibitor that is a potent suppressor of bone formation, and inhibits bone morphogenic protein. The absence of SOST expression results in increased bone formation and bone mass [37]. In the current study, SOST levels were significantly lower in all of the zymosan-treated groups than in the control group, and SOST levels were higher in the E2-treated group than the other groups. In the cohort study, devenir des spondyloarthrites indifférenciées récentes (DESIR), SOST was significantly lower in patients with SpA than in healthy controls [38]. In addition, SOST was significantly lower in patients with SpA than in control patients, whereas SOST was increased in patients with RA compared with controls [39, 40]. We therefore evaluated the expression of Wnt inhibitors in the SKG mouse model and demonstrated that estrogen inhibited Wnt signaling in SpA. Considering that blockade of Wnt inhibitors induced the fusion of sacroiliac joints and increased bone formation [37, 41], estrogen might be used as a therapeutic target to control the Wnt pathway.

This study had several limitations. First, uterine weights were not measured; rather, we measured the concentration of E2 in mouse serum. The mean concentration of E2 was significantly higher in E2-treated mice than in mice in the other groups, but there was no significant difference between E2 levels in the sham and ovariectomized groups. Inflammation affects ovulation and hormone production. Moreover, 50% of cases of premature ovarian failure have been ascribed to autoimmune disease [42]. Considering that mice in the sham group had severe inflammation in the joints, intestines, and skin at the time of sacrifice, estrogen production might have been decreased due to ovarian failure induced by systemic inflammation. Second, gene expression in the tail was not quantified. However, considering that the incidence of arthritis and the degree of inflammation in the peripheral joints were clinically and histologically closely tied to those of the tail joints, the gene expression patterns found in the joint tissue of the hind paws and forepaws likely reflected those in the tail joints. The strength of this study is that it is one of the few studies to evaluate the role of estrogen in disease activity in SpA. To the best of our knowledge, this is the first study to demonstrate the inhibitory effect of estrogen on SpA, using an animal model of SpA. Furthermore, our results suggest that estrogen might be an effective therapeutic approach to treating SpA. However, hormone treatment has various adverse effects, such as increased risk of breast cancer, endometrial cancer, and thromboembolism. Therefore, selective estrogen receptor modulators (SERMs) were developed to prevent their side effects. Recent studies reported that SERMs inhibit joint inflammation and osteoporosis in female CIA animal models [43, 44]. Further experiments are needed to evaluate the effects of SERMs in the SpA mouse model.

Estrogen suppressed arthritis development in an SpA mouse model. Results of this study suggest that estrogen has an anti-inflammatory effect on the SpA manifestations in the SKG arthritis model. Further study is warranted to determine the molecular mechanisms of estrogen in the pathogenesis of SpA and to evaluate if estrogen is an effective therapeutic treatment option for SpA.