Eléonore Maury

Adipokine dysregulation, adipose tissue inflammation and metabolic syndrome.

Obesity plays a causative role in the pathogenesis of the metabolic syndrome. Adipokines may link obesity to its co-morbidities. Most adipokines with pro-inflammatory properties are overproduced with increasing adiposity, while some adipokines with anti-inflammatory or insulin-sensitizing properties, like adiponectin are decreased. This dysregulation of adipokine production may promote obesity-linked metabolic disorders and cardiovascular disease. Besides considering adipokines, this review will also highlight the cellular key players and molecular mechanisms involved in adipose inflammation. Targeting the changes in the cellular composition of adipose tissue, the underlying molecular mechanisms, and the altered production of adipokines may have therapeutic potential in the management of the metabolic syndrome.

Adipokines identified as new downstream targets for adiponectin: lessons from adiponectin-overexpressing or -deficient mice

Adipokines play a central role in the pathogenesis of the metabolic syndrome. Among them, adiponectin (ApN), a master regulator of immune and fuel homeostasis, is decreased. Identifying downstream adipokines targeted by ApN may help in deciphering this syndrome. We have generated transgenic mice, allowing persistent and moderate overexpression of ApN (ApN-Overex) specifically in white adipose tissue (AT). We took advantage of this model to unravel the adipokine secretion profile triggered by ApN. AT was fractionated into adipocytes and stromal-vascular cells (SVC), which were cultured for 8 h. Profiling of secretory products by antibody arrays and subsequent ELISAs showed that the secretion of three proinflammatory factors (IL-17B, IL-21, TNFα) and three hematopoietic growth factors [GF; thrombopoietin and granulocyte (macrophage) colony-stimulating-factors] was reduced in adipocytes of ApN-Overex mice compared with wild-type mice. In the SVC of these mice, besides the hematopoietic GFs, the secretion of another GF (vascular endothelial GF receptor 1), two chemokines (RANTES and ICAM-1), and two proinflammatory factors (IL-6 and IL-12p70) was reduced as well. Only one cytokine, IL-1 receptor 4, was oversecreted by SVC of ApN-Overex mice, which may exhibit anti-inflammatory properties. Most of these changes in secretion were due to corresponding changes in mRNAs. A reverse profile of adipokine expression was observed in ApN-KO mice. In conclusion, ApN regulates in vivo the secretion of downstream adipokines, thereby inducing a shift of the immune balance in both adipocytes and SVC toward a less inflammatory phenotype. These downstream adipokines may be new therapeutic targets for the management of the metabolic syndrome.

Effect of Obesity on Growth‐related Oncogene Factor‐α, Thrombopoietin, and Tissue Inhibitor Metalloproteinase‐1 Serum Levels

We have recently identified several adipokines as oversecreted by omental adipose tissue (AT) of obese subjects: two chemokines (growth‐related oncogene factor‐α (GRO‐α), macrophage inflammatory protein‐1β (MIP‐1β)), a tissue inhibitor of metalloproteinases‐1 (TIMP‐1), an interleukin‐7 (IL‐7) and a megakaryocytic growth‐factor (thrombopoietin (TPO)). These adipokines are involved in insulin resistance and atherosclerosis. The objectives of this study were to determine whether the circulating levels of these adipokines were increased in obesity and to identify the responsible factors. A cross‐sectional study including 32 lean (BMI (kg/m2) <25), 15 overweight (BMI: 25–29.9), 11 obese (BMI: 30–39.9), and 17 severely obese (BMI >40) age‐matched women was carried out. Serum adipokine levels, insulin sensitivity, and substrate oxidation were measured by ELISA, euglycemic–hyperinsulinemic clamp, and indirect calorimetry, respectively. Circulating levels of GRO‐α, TPO, and TIMP‐1 were higher in obese and/or severely obese women than in lean ones (+30, 55, and 20%, respectively). Serum levels of these adipokines positively correlated with insulinemia or glycemia, and negatively with insulin sensitivity. TIMP‐1 also positively correlated with blood pressure, and TPO with triglyceride levels. Multiple regression analysis showed that fat mass per se was an independent determinant of GRO‐α, TPO, and TIMP‐1 levels, suggesting that hypertrophied adipocytes and recruited macrophages in expanded AT mainly contribute to this hyperadipokinemia. Insulinemia, glycemia and resistance of glucose oxidation to insulin were additional predictors for TPO. Circulating GRO‐α, TPO, and TIMP‐1 levels are increased in obesity. This may be partially due to augmented adiposity per se and to hyperinsulinemia/insulin resistance. These high systemic levels may in turn worsen/promote insulin resistance and cardiovascular disease.

In Vitro Hyperresponsiveness to Tumor Necrosis Factor-α Contributes to Adipokine Dysregulation in Omental Adipocytes of Obese Subjects

Results: Adipocytes of obese subjects mainly overexpressed adipokines, in comparison with those of lean ones, when cultured in SVC-conditioned media. This was abrogated by immunoneutralization of TNF, indicating that among the numerous factors secreted by SVCs, TNFis a crucial contributor to adipokine dysregulation. Accordingly, adipocytes of obese subjects overproduced adipokines in response to direct exposure of TNF. This hyperresponsiveness was mediated by TNFreceptor 1 and hyperactivation of the nuclear factorB (NFB) pathway. Correspondingly, NFB activity was increased in adipocytes of obese subjects and correlated with adipocyte size, adipokine expression, and in vivo insulin resistance. Eventually adipokine overexpression in adipocytes of obese subjects was prevented by NFB inhibitors.