Several groups of investigators evaluating insulin resistance in rheumatoid arthritis (RA; Table 1)1,2,3,4,5,6,7,8,9 have reported that patients with RA have more insulin resistance than non-RA control subjects, even with similar body mass index (BMI)1,2,3,4,5. In many RA studies, insulin resistance was associated with markers of inflammation or disease activity5,6,7,8. Moreover, some studies that examined insulin resistance before and after treatment of RA with anti-tumor necrosis factor-α (TNF-α) or antiinterleukin 6 (IL-6) agents found that treatment with these drugs, and presumably the consequent decrease in inflammation, resulted in a significant improvement in insulin sensitivity10,11. These and other studies provide support for the notion that inflammation in RA promotes insulin resistance.
The concept that there is a relationship between the inflammation in RA and insulin resistance is also supported by studies performed in animals showing that inflammation promotes insulin resistance. For example, administration of TNF-α and IL-6 caused insulin resistance in rats and mice12,13. This finding is not surprising because cytokines such as IL-6 and TNF-α contribute to insulin resistance through downstream repression of insulin signaling (reviewed14).
In this issue of The Journal, AbouAssi and colleagues present a meticulous and thorough evaluation of insulin sensitivity in 39 patients with RA and 39 control subjects matched for not only age and sex, but also for BMI and physical activity15. Insulin sensitivity was quantified by frequently sampled intravenous glucose tolerance test (FSIVGTT). Factors assessed were disease activity, levels of proinflammatory cytokines, and potential confounders including physical activity measured by accelerometry over 7 days and adiposity determined by computerized tomography of the abdomen and thigh.
Three of their findings were unexpected and therefore thought-provoking: (1) insulin resistance was not increased in RA, (2) inflammation was not independently associated with insulin resistance, and (3) visceral adiposity was not increased in RA. We discuss some interpretations of the findings below.
Potential explanations for the finding that insulin sensitivity was not significantly altered in patients with RA compared to controls (in contrast to the studies described earlier) seem most likely to be found in the patient population studied and the method for measuring insulin sensitivity.
The RA patient population studied is similar to that in several other studies with respect to age, race, sex, disease duration, and seropositivity. One difference was that patients were excluded for use of any medication known to affect carbohydrate or lipid metabolism (such as statins, angiotensin-converting enzyme inhibitors, β-blockers, and angiotensin receptor blockers). This strategy has the important benefit of reducing the confounding effect of drugs on insulin sensitivity, but it has the potential disadvantage of decreasing generalizability by excluding many patients receiving treatment for hypertension and hyperlipidemia, 2 components of the metabolic syndrome. A second difference, reflecting therapeutic advances and changes in practice, was that a larger proportion (about 50%) of patients was receiving therapy with biologic agents; some biologic agents may improve insulin sensitivity in patients with RA10,11.
To measure insulin resistance/sensitivity, the investigators used the FSIVGTT. This contrasts with many of the previous studies, which used the simpler and less rigorous fasting homeostatic model assessment of insulin resistance (HOMA-IR) to evaluate insulin resistance in RA (Table 1). As the authors indicate, the fasting HOMA-IR reflects mostly hepatic insulin resistance and hepatic glucose production, rather than peripheral insulin sensitivity. The FSIVGTT method used by the investigators includes both hepatic and peripheral insulin sensitivity (reviewed16), but peripheral insulin sensitivity would likely be a much greater contributor. Thus, one possibility is that RA affects insulin sensitivity of the liver to a greater extent than the peripheral tissues.
The authors found that IL-6, but not C-reactive protein (CRP) or 28-joint Disease Activity Score (DAS28), was weakly associated with insulin resistance in RA. One consideration is that this unimpressive relationship between inflammation and insulin resistance may have been affected not only by the RA population studied, but also by their relatively low disease activity. The average DAS28 score of 3.1 is not unusual, but over 40% of patients were in remission, and CRP was not higher in the patients with RA (although IL-6 and TNF-α were). IL-6, one of the proinflammatory cytokines increased in the patients with RA, was correlated with insulin sensitivity only in univariate analysis (ρ = −0.3, p = 0.05); however, visceral adiposity was more strongly associated with insulin sensitivity, independent of IL-6 concentrations (p = 0.005). One can speculate that if the degree of inflammation in the subjects with RA had been higher, IL-6 might have been the stronger predictor of insulin sensitivity.
Total adiposity was found to be similar in RA and control subjects, but contrary to much of the literature9,16,17,18 (Table 1), visceral adiposity was about 25% lower among patients with RA. Given the matching for physical activity between RA and control subjects, this observation could suggest that the previously observed increase in visceral adiposity (and decrease in muscle mass) in RA is mainly due to inactivity. A different study, however, showed that RA patients with similar levels of physical activity to control subjects had greater central obesity and higher fat mass7. Thus, the lower visceral adiposity observed in the RA patients in the current study may have been related to patient selection (i.e., exclusions for many antihypertensive and lipid-lowering drugs leading to a lower proportion of patients with metabolic syndrome, as discussed), but it also suggests new possibilities regarding the relationship between visceral fat, inflammation, and insulin resistance in RA.
The authors found that visceral adiposity and waist circumference, which could be considered a surrogate for visceral adiposity, were most strongly independently associated (inversely) with insulin sensitivity in statistical models that focused on clinical variables and in models focused on laboratory variables. Although IL-6 concentrations were significantly inversely correlated with insulin sensitivity, this relationship was not independent of visceral adiposity. We wonder if the visceral adiposity is particularly important to insulin resistance in RA, and if the 2 synergistically contribute to insulin resistance in RA. Thus, the lower visceral adiposity in this group of patients may have contributed to the authors finding no significant alterations in insulin sensitivity.
Visceral fat may be altered in a state of high inflammation. For example, comparing RA and control subjects with the highest quartile of visceral adipose tissue, patients with RA had a 29% greater probability of elevated fasting blood glucose compared to control subjects19, raising the possibility that an interaction between visceral adipose tissue and inflammation contributes to insulin resistance.
Adipose tissue is an organ containing members of the innate and acquired immune systems. Macrophages accumulate to a greater extent in visceral than subcutaneous adipose tissue, and their proinflammatory cytokine release is considered a major contributor to the increased insulin resistance associated with obesity (reviewed20).
The role of cytokines in adipose tissue is complex. Systemically, proinflammatory cytokines promote insulin resistance through direct effects on insulin signaling and indirect effects by stimulating lipolysis; however, locally within the adipose tissue, IL-6 has a protective, homeostatic role. For example, obese mice with inactivated IL-6 receptor paradoxically showed increased tissue inflammation with greater proportion of proinflammatory M1 macrophages and insulin resistance21.
There is little information about how exactly RA affects adipose tissue, particularly in the visceral compartment. Perhaps in the setting of excess systemic inflammation as seen in RA, the homeostatic function of IL-6 within adipose tissue is deranged. Interestingly, a study that compared paired samples of articular and subcutaneous adipose tissue from patients with RA found a similar degree of infiltration of M2 macrophages, which would typically promote healing and secrete antiinflammatory cytokines. The M2 macrophages from the articular adipose tissue, however, were primed to produce an exaggerated inflammatory response to stimuli compared to those from the subcutaneous fat22. Although that study did not examine visceral fat, it showed altered function of macrophages within adipose tissue, which had likely been chronically exposed to high levels of proinflammatory cytokines.
The interesting clinical study reported by AbouAssi and colleagues provides new insights into insulin resistance in RA and has raised many questions about the relationship between visceral fat, inflammation, and insulin resistance, not only in RA but also in other diseases.
Footnotes
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Supported by US National Institutes of Health grants: P60 AR056116
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