Statins (hydroxymethylglutaryl coenzyme A reductase inhibitors) have been shown to be effective in reducing the risk of cardiovascular morbidity and mortality in patients with hyperlipidemia, hypertension, or type II diabetes 1234. In addition to their cholesterol-lowering activity, several studies have shown that statins have anti-inflammatory and immunomodulatory properties 5678. We hypothesized that because of these immunomodulatory properties statin use may eventually lead to dysregulation of immune responses, possibly resulting in autoimmunity. In line with this hypothesis, we have recently shown in an observational study that statin use was associated with an increased risk of developing rheumatoid arthritis (RA) 9. Moreover, based on individual case reports we found a positive association between statin use and the occurrence of lupus-like syndrome 10. This latter association was recently confirmed by another research group 11.

To investigate whether a causal relationship can be established for these observations, we evaluated the effects of statin administration on arthritis in the collagen type II (CII)-induced arthritis (CIA) mouse model. In this model for RA, mice are immunized with CII mixed with Freund's complete adjuvant, and are challenged 3 weeks later with CII alone. Arthritis is scored from the time of challenge onwards 12.

Several studies have shown beneficial effects of statin administration on joint inflammation in the mouse CIA model 13141516. However, these studies did not specifically address the effects of statin administration before arthritis induction, an issue that follows from our observational study 9. Nonetheless, to relate our results to the animal studies indicated above 13141516, we also evaluated effects of statin administration after arthritis induction.

Here we show that statin administration accelerated arthritis onset and resulted in 100% arthritic animals, whereas only seven out of 12 nonstatin control animals developed arthritis. Atorvastatin administration after CIA induction resulted in earlier onset than atorvastatin administration before induction, or than pravastatin administration before or after induction. The arthritic score of animals given pravastatin before CIA induction was similar to that of the nonstatin controls, whereas the other groups that received statins showed higher arthritic scores. Atorvastatin administration, especially before CIA induction, increased anti-CII autoantibody production. IL-2 and IL-17 production by lymph node (LN) and spleen cells was not affected by statin administration. Atorvastatin administration before CIA induction increased IFNγ production.

Here we have shown that statin administration results in 100% arthritic animals, whereas only seven out of 12 nonstatin control animals developed arthritis. Moreover, statin administration accelerated arthritis onset. This accelerated onset was seen when statin administration was started either before or after CIA induction. Accelerated onset resulting from statin administration before CIA induction is in line with our hypothesis of statin-induced immune deviation resulting in autoimmunity 910. In addition, we observed that atorvastatin administration after CIA induction resulted in earlier arthritis induction than administration with the same statin before CIA induction. Overall, atorvastatin had a somewhat stronger effect on accelerating onset than pravastatin. Atorvastatin administration before or after CIA induction, or pravastatin administration after CIA induction, resulted in a similar mean arthritic score compared with the nonstatin control, while pravastatin administration before CIA induction resulted in a lower mean arthritic score. In this latter pravastatin group the acceleration of arthritis onset was 5 days, while that in the other cases was 7 or 9 days. This lower mean arthritic score may suggest a beneficial effect of pravastatin. This dosing regime, however, also results in accelerated arthritis onset and an increased number of arthritic animals.

Other studies using the mouse CIA model have shown beneficial effects of statin administration on joint inflammation 13141516. To establish whether statin type, dose, route of administration, or timing of administration relative to CIA induction influenced the clinical outcome, the results of the above-mentioned studies as well as our data are compared in Table 1. Suppression of arthritis development was seen after oral administration of 10 mg/kg atorvastatin (the same exposure route and dose as we used in our study) during (almost) the whole period from immunization to euthanasia 13. This finding contrasts our results that show accelerated onset when 10 mg/kg atorvastatin was given orally either before or after CII challenge. This issue needs to be resolved in future studies. Suppression of arthritis development was also found after intraperitoneal administration of 100 mg/kg pravastatin 14 or 40 mg/kg simvastatin 1516. Using other statins, lower doses, or other exposure routes failed to show an effect on arthritis. An accelerated onset of arthritis was only found in our study.

Atorvastatin administration before CIA induction resulted in increased anti-CII antibody production, whereas atorvastatin administration after CIA induction resulted in a nonsignificant increase in production of this antibody. Pravastatin administration before and after CIA induction, however, did not affect anti-CII IgG antibody production.

Atorvastatin administration before CIA induction resulted in accelerated arthritis onset and increased autoantibody production. This observation may suggest that increased autoantibody production plays a role in accelerated arthritis onset. Our observational study showed that statin use is associated with an increased risk of developing RA 9. In humans, IgM rheumatoid factor and anti-cyclic citrullinated peptide antibodies have been found years before RA becomes clinically apparent 23. For RA patients that used statins before developing clinically manifest disease, therefore, statin use may have coincided with autoantibody development. Statins may be speculated to increase autoantibody production, thereby facilitating RA development.

CIA induction resulted in increased IL-2 production by Concanavalin-A-stimulated LN cells, probably reflecting the stronger activation or higher frequency of T cells in the LN draining the inflamed joints. Production of this cytokine was not significantly affected by statin administration. Similarly, CIA induction resulted in increased IL-2 production by CII-stimulated spleen cells, and production of IL-2 was not significantly affected by statin administration.

Furthermore, CIA induction resulted in increased IL-17 production by CII-stimulated spleen cells. Since IL-23-deficient mice that lack IL-17-producing CD4⁺ cells (Th17 cells) are resistant to CIA induction 24, Th17 cells are assumed to play an essential role in CIA. The activation or frequency of Th17 cells in the spleen is probably increased in arthritic mice, in line with previous studies 24252627. Importantly, IL-17 production was not significantly affected by statin administration.

In addition, CIA induction resulted in decreased IFNγ production by LN cells (0.75-fold) and CII-stimulated spleen cells (0.71-fold), albeit not statistically significantly (data not shown). Since IFNγ acts as a disease-limiting factor in CIA 28, reduced levels of this cytokine may possibly be characteristic for CIA. Since atorvastatin was shown to inhibit IFNγ production 29, and absence of IFNγ signaling resulted in accelerated arthritis onset 3031, reduced production of this cytokine may be a possible mechanism underlying accelerated arthritis onset due to atorvastatin treatment. We did not, however, observe altered IFNγ production due to statin administration. Taking together the IL-17 and IFNγ data, the increased IL-17 and decreased IFNγ production upon CIA induction fits the selective induction of Th17 and not T-helper type 1 cells in CIA 24.

Another possible mechanism by which statins may affect arthritis is through their induction of caspase-1, IL-1β, and IL-18 in monocytes, resulting in increased IFNγ production by T cells 32. Interestingly, this increased IFNγ production occurred only at low statin concentrations. Caspase-1 activation results in cleavage of pro-IL-1β and pro-IL-18 to their mature (active) forms. Caspase-1, IL-1β, and IL-18 are all implicated in CIA. The pharmacologic caspase-1 inhibitor VX-765 reduced paw inflammation when given as a prophylactic and a therapeutic 33. IL-1β administration accelerated arthritis 34, while anti-IL-1β treatment markedly suppressed established arthritis 35. IL-18 administration resulted in higher arthritis incidence and severity 3637, while IL-18-deficient mice showed reduced arthritis incidence and severity 38. This observation may suggest that statins aggravate arthritis by activating caspase-1, thereby inducing IL-1β and IL-18. Increased IFNγ production may, on the contrary, reduce arthritis. Taking the two possible mechanisms together, caspase-1 activation by statins may aggravate arthritis by inducing IL-1β and IL-18. The resulting IFNγ induction that in itself reduces arthritis may be counteracted by the T-helper type 2 skewing effect of statins. Clearly, disease outcome results from a complicated interplay between various effects of statins. In our hands, statin exposure resulted in accelerated arthritis onset.

In summary, the anti-CII antibody, IL-2, IL-17, and IFNγ data do not provide a possible mechanism for the accelerated arthritis observed in this study. It should be noted, however, that establishing such a mechanism was not the aim of our study. We aimed to investigate whether a causal relationship could be established for the association between statin use and an increased risk of developing RA.

The CIA model was chosen because our observational study has shown that statin use was associated with an increased risk of developing RA 9; because it is a model for RA, recapitulating many aspects of the disease 39404142; because an induced model is preferred to a spontaneous model, since only in an induced model can the effects of statin use prior to expression of arthritis be tested; and because the mouse CIA model is both B-cell and T-cell mediated and is therefore more similar to human RA than models such as the rat adjuvant arthritis model, which is (only) T-cell mediated.

Here we have shown that administration of atorvastatin and pravastatin resulted in accelerated arthritis onset in a mouse CIA model. Atorvastatin administration after CIA induction resulted in earlier onset than atorvastatin administration before CIA induction, or than pravastatin administration before or after CIA induction. Atorvastatin administration, especially before CIA induction, resulted in increased autoantibody production. Importantly, our data provide a causal relationship for previous results obtained from observational studies 910.

CIA: collagen-induced arthritis; CII: collagen type II; ELISA: enzyme-linked immunosorbent assay; ET₅₀: median time when 50% of the animals develop arthritis; FCS: fetal calf serum; IFN: interferon; IL: interleukin; LN: lymph node; PBS: phosphate-buffered saline; RA: rheumatoid arthritis; Th17: T-helper type 17 cells; TNF: tumor necrosis factor.

The authors declare that they have no competing interests.

RJV, J-WCT, WS, JWVDL, and HVL designed the study. RJV and ERG performed the experiments. RJV and WS performed the statistical analysis. RJV, WS, and HVL analyzed and interpreted the data. RJV, HJIDJ, OHK, J-WCT, WS, JWVDL, and HVL prepared the manuscript. All authors read and approved the final manuscript.