International journal of obesity and related metabolic disorders : journal of the International Association for the Study of Obesity最新文献

Antidiabetic effects associated with salicylates have been known for years, although the underlying mechanisms were not understood. We have been reinvestigating these effects in the light of recent discoveries in the areas of signal transduction and insulin resistance. Our findings showed that signaling pathways leading to I kappa B kinase beta (IKK beta) and NF-kappa B are activated in insulin-responsive tissues of obese and high-fat-fed animals. Since activation correlates with the development of insulin resistance, we asked whether signaling through this might be involved in the pathogenesis of insulin resistance. Heterozygous gene deletion (Ikk beta+/-) or salicylates, working as IKK beta inhibitors, improved insulin sensitivity in insulin-resistant rodent models. Furthermore, high doses of salicylates (aspirin or salicylate) improved insulin sensitivity in patients with type II diabetes. Our studies implicate an inflammatory process in the pathogenesis of insulin resistance in obesity and type II diabetes mellitus and identify the IKK beta/NF-kappa B pathway as a molecular mediator of insulin resistance and pharmacological target for insulin sensitization.

Insulin resistance refers to a decreased capacity of circulating insulin to regulate nutrient metabolism. It is associated with the development of type II diabetes, a 21st century epidemic. Recent studies reveal that agents that induce insulin resistance exploit phosphorylation-based negative feedback control mechanisms otherwise utilized by insulin itself, to uncouple the insulin receptor from its downstream effectors and thereby terminate insulin signal transduction. This article focuses on the cardinal role of Ser/Thr protein kinases, which phosphorylate insulin receptor substrates, as key players in the uncoupling of insulin signaling and the induction of an insulin resistance state.

Insulin resistance, both in nondiabetic and diabetic subjects, is frequently associated with obesity, particularly an excess of central fat. Many of the features that have been ascribed to the metabolic or insulin-resistance syndrome are also more commonly found in obese subjects. These phenotypes include diabetic dyslipidaemia, elevation of levels of plasminogen activator inhibitor-1, microalbuminuria and endothelial dysfunction. More recently, features of acute-phase activation and low-grade inflammation, including elevated levels of fibrinogen, C-reactive protein and interleukin-6, have been associated with (central) obesity. Adipose tissue generation of cytokines has been shown in vitro and in vivo, and a number of novel cytokine-like molecules, collectively termed adipocytokines, have been identified as adipocyte products. While several of these, such as tumour necrosis factor-alpha, may act predominantly in autocrine or paracrine fashion, others are released into the systemic circulation, acting as signalling molecules to remote tissues, including liver, skeletal muscle and endothelium. A clearer understanding of adipose tissue signalling, and its contribution to the state of low-grade inflammation of obesity, will require physiological, as well as cellular and molecular, studies.

Peroxisome proliferator-activated receptors (PPARs) are members of the nuclear receptor family. After activation by specific ligands, they regulate the transcription of genes involved in lipid and lipoprotein metabolism, glucose and energy homeostasis, as well as cellular differentiation. Recent studies have identified expression of the three PPARs in all cells of the arterial wall, where they control cholesterol homeostasis as well as the inflammatory response and, as a consequence, modulate atherogenesis. More generally, PPARs influence cell proliferation as well as the immune and inflammatory response in different tissues and cells. In this review, we will summarize the evidence indicating that PPARs are modulators of the inflammatory response with potential therapeutic applications not only in atherosclerosis, but potentially also in other inflammation-related diseases, such as hepatic inflammation and inflammatory bowel disease.

The last 10 y have seen an enormous surge in research focused on inflammation and atherosclerotic heart disease. In parallel, inflammation (used as a term to represent a broad array of response systems) has become a topic of interest in a number of different areas of chronic disease including type II diabetes, cognitive decline and frailty, among others. These discoveries are opening up many new opportunities for risk assessment. For example, markers of inflammation such as C-reactive protein are becoming established as important additions in helping to define those at the greatest risk of progressive vascular disease. These discoveries are also important in the area of risk management. Older medications now in wide use are being found to have previously unknown anti-inflammatory effects (eg, statins); these effects are now viewed as being important to the overall effectiveness of these compounds. In addition, the many different aspects of inflammation provide a wealth of targets for new therapeutics, which will be increasingly important as the population continues to age. Although daunting in complexity, studies on the relation of inflammation to disease have already proven useful, and hold promise for providing fundamental advances in both basic biology and clinical medicine.

Peroxisome proliferator-activated receptors (PPARs) are nuclear receptor isoforms with key roles in the regulation of lipid and glucose metabolism. Synthetic ligands for PPAR gamma (and PPAR alpha) have effects of promoting insulin sensitization in the context of obesity. Recent evidence suggests that activation of PPAR delta might produce similar effects. Both PPAR gamma and PPAR alpha have also been shown to produce selected anti-inflammatory effects and to reduce the progression of atherosclerosis in animals (alpha and gamma) or in humans (alpha). Mechanisms underlying insulin-sensitizing effects are complex. For PPAR gamma, direct effects on adipose tissue lipid metabolism with secondary benefits in liver and/or muscle (lipid levels and insulin signaling) have been implicated. For PPAR alpha, accelerated lipid catabolism may contribute to reduced muscle or liver 'steatosis'. Anti-inflammatory mechanisms as contributors to the beneficial metabolic effects of PPAR activation are also worth considering for the following reasons: (1) obesity and insulin resistance are associated with a proinflammatory milieu. (2) PPAR gamma has clear effects to oppose the effects of tumor necrosis factor-alpha (TNFalpha) in adipocytes. (3) effects of PPAR ligands on cytokine-mediated signaling (eg via NF-kappa B) may be expected to enhance insulin action. (4) Adipose production of several molecules that are implicated as markers or mediators of inflammation is reduced. (5) In humans, treatment with either PPAR alpha or PPAR gamma agonists has been shown to reduce circulating levels of proteins that serve as markers of inflammation. (6) Adiponectin, a fat-derived circulating factor that has been implicated as having anti-inflammatory activity, is induced by PPAR gamma agonism.

The macrophage plays a diverse array of roles in atherogenesis and lipoprotein metabolism. The macrophage functions as a scavenger cell, an immune mediator cell, and as a source of chemotactic molecules and cytokines. Chemokines have been implicated in promoting migration of monocytes into the arterial intima. Monocyte chemoattractant protein-1 (MCP-1) attracts monocytes bearing the chemokine receptor CCR-2. Macrophage expression of cyclooxygenase-2, a key enzyme in inflammation, promotes atherosclerotic lesion formation in low-density lipoprotein receptor (LDLR)-deficient mice. In the arterial intima, monocytes differentiate into macrophages, which accumulate cholesterol esters to form lipid-laden foam cells. Foam cell formation can be viewed as an imbalance in cholesterol homeostasis. The uptake of atherogenic lipoproteins is mediated by scavenger receptors, including SR-A and CD36. In the macrophage, ACAT-1 is responsible for esterifying free cholesterol with fatty acids to form cholesterol esters. Surprisingly, deficiency of macrophage ACAT-1 promotes atherosclerosis in LDLR-deficient mice. A number of proteins have been implicated in the process of promoting the efflux of free cholesterol from the macrophage, including apoE, ABCA1, and SRB-1. Macrophage-derived foam cells express the adipocyte fatty acid-binding protein (FABP), aP2, a cytoplasmic FABP that plays an important role in regulating systemic insulin resistance in the setting of obesity. ApoE-deficient mice null for macrophage aP2 expression develop significantly less atherosclerosis than controls wild type for macrophage aP2 expression. These results demonstrate a significant role for macrophage aP2 in the formation of atherosclerotic lesions independent of its role in systemic glucose and lipid metabolism. Furthermore, macrophages deficient in aP2 display alterations in inflammatory cytokine production. Through its distinct actions in adipocytes and macrophages, aP2 links features of the metabolic syndrome including insulin resistance, obesity, inflammation, and atherosclerosis.