Leptin

Leptin was the first adipokine discovered to have a role in modulating adiposity, and it remains the best studied^26–29. Leptin is secreted almost exclusively by fat, and serves as a major ‘adipostat’ by repressing food intake and promoting energy expenditure. Predictably, animals and humans with mutations in either leptin or the leptin receptor are obese. The leptin receptor is expressed at low levels in numerous tissues, but is found at high levels in the mediobasal hypothalamus, particularly the arcuate nucleus, the ventromedial nucleus and the dorsomedial nucleus^30–32 (Fig. 2). Leptin receptor activation at these sites leads to repression of orexigenic pathways (for example, those involving neuropeptide Y, NPY, and agouti-related peptide, AgRP) and induction of anorexigenic pathways (such as those involving pro-opiomelanocortin, POMC, and cocaine and amphetamine-regulated transcript, CART). Leptin-dependent effects on food intake and energy expenditure ultimately diverge in the central nervous system (CNS), partly at the level of melanocortin MC4 receptor signalling³³. Recently, increased attention has been paid to leptin action in non-hypothalamic sites such as the caudal brainstem³⁴.

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Figure 2

Adipocytes regulate energy balance by endocrine and non-endocrine mechanisms

Adipocytes synthesize and secrete leptin, which circulates in the blood and acts on the CNS (primarily the hypothalamus) to reduce food intake and enhance energy expenditure. Adipose tissue also communicates with the CNS by means of a rich network of peripheral nerves, which can transmit afferent signals about energy status to the brain, such as when UCP-1 is expressed ectopically. This results in enhanced leptin sensitivity, which increases the effect of secreted leptin on energy balance.

Neural pathways

Fat pads are richly innervated by sympathetic fibres, and activation of these fibres is associated with enhanced lipolysis^35,36. These nerves also regulate fat pad cellularity — denervation of specific depots results in a twofold elevation in adipocyte number in hamsters and rats³⁵. Recent studies have also suggested that neural afferent signals from adipose tissue to the brain might also regulate adiposity. Direct introduction of low levels of UCP-1 into white adipose tissue causes a marked increase in leptin sensitivity in mice, with a concomitant reduction in food intake, and enhanced energy expenditure and weight loss³⁷ (Fig. 2). This effect is abrogated entirely when the manipulated fat pad is denervated. The actual parameter being monitored by the adipocyte is unclear, but might include reactive oxygen species (ROS), ATP levels or even local heat production.

Leptin

As described above, leptin is a multifunctional protein secreted primarily by adipocytes. In addition to its well-described role in energy balance, leptin has notable effects on glucose homeostasis, as it reverses hyperglycaemia in ob/ob mice before body weight is corrected²⁹. Similarly, pair feeding ob/ob mice to match control animals does not restore glucose tolerance as well as exogenous leptin does⁴⁷. Leptin also improves glucose homeostasis in lipodystrophic mice, and in humans with lipodystrophy or congenital leptin deficiency^48–50. Results in humans with ‘typical’ obesity have been disappointing in this regard⁵¹. However, this is consistent with the high levels of leptin and apparent leptin resistance seen in these patients.

The anti-hyperglycaemic actions of leptin are mediated through several different organs. First, leptin improves insulin sensitivity in muscles. Leptin also reduces intra-myocellular lipid levels through a combination of direct activation of AMP-activated protein kinase (AMPK) and indirect actions mediated through central neural pathways⁵². The effect on lipid partitioning might help to explain the improved insulin sensitivity, according to the current idea that intracellular lipids contribute to insulin resistance. Leptin also improves insulin sensitivity in the liver, an effect seen with either peripheral or intracerebroventricular administration⁵³. As in muscles, leptin functions in part to reduce hepatic intracellular triacylglycerol levels. There has also been discussion of an ‘adipo-insular axis’, with insulin promoting leptin secretion and leptin inhibiting insulin release⁵⁴. Consistent with this idea, ablation of leptin receptors from β-cells results in enhanced basal insulin secretion and fasting hypoglycaemia⁵⁵. The effect of leptin on insulin levels is due to inhibition of proinsulin synthesis as well as reduction of secretion⁵⁴.

Adiponectin

The hormone adiponectin was identified by several different groups and given various names (for example, apM1, GBP28, AdipoQ and ACRP30)⁵⁶. This 30-kDa protein has an amino-terminal collagen-like domain and a carboxy-terminal globular domain that mediates multimerization. Circulating adiponectin can exist as a trimer, hexamer or a higher-order multimer with 12–18 subunits^57,58; there is some controversy about which is the active form of the hormone. Two types of receptor have been proposed. One comprises two similar transmembrane proteins with homology to G-protein-coupled receptors, known as adipoR1 and adipoR2 (ref. 59); a second molecule (T-cadherin) without a transmembrane domain has been proposed to act as a co-receptor for the high-molecular-weight form of adiponectin on endothelial and smooth muscle cells⁶⁰. Interestingly, adiponectin circulates at extraordinarily high concentrations (5–10 µg ml⁻¹), accounting for 0.01% of all plasma protein⁶¹. Unlike almost all other adipokines, however, adiponectin levels are inversely correlated with body mass^62,63, for reasons that remain obscure.

Delivery of adiponectin to obese, diabetic mice stimulates AMP kinase activity in the liver and skeletal muscle, with profound effects on fatty acid oxidation and insulin sensitivity. Loss-of-function models of adiponectin have been more variable, with different groups reporting reduced insulin sensitivity on both chow and high-fat diets, high-fat diet only, or no effect on insulin action at all^64–66. The reason for these differences is unknown. Two groups have shown that part of the anti-diabetic action of TZDs requires adiponectin^67,68; TZDs significantly raise plasma adiponectin levels through effects on synthesis and secretion⁶⁹. Adiponectin has no effect on insulin secretion in islets from healthy mice or humans, but does enhance glucose-stimulated insulin secretion in islets from mice with diet-induced obesity⁷⁰.

Visfatin

The connection between visceral adiposity and insulin resistance has led several groups to try to identify secreted products derived specifically from this depot. The first such protein reported was visfatin, which had been identified in immune cells years earlier as pre-B-cell colony-enhancing factor (PBEF)⁷¹. There were several surprising aspects surrounding this discovery, including the fact that visfatin does not promote insulin resistance — on the contrary, it has a salutary effect on glucose uptake mediated by direct binding and activation of the insulin receptor. Visfatin circulates at concentrations well below those of insulin (<10%), however, and fasting and feeding do not regulate its expression, making it doubtful that visfatin alone is an important factor in insulin-receptor signalling. Other aspects of visfatin biology require further study. For example, serum levels of visfatin are variably correlated with type 2 diabetes and other insulin-resistant states⁷². Visfatin also has no signal sequence and has been shown to have enzymatic activity as a nicotinamide phosphoribosyltransferase with residence in the nucleus and cytosol⁷³. It is not clear whether there is regulated secretion of visfatin or whether serum levels reflect leakage from dead or damaged cells.

Omentin

Omentin is another peptide secreted predominantly by visceral fat. Like visfatin, it has positive effects on glucose uptake, although omentin works as an insulin sensitizer and does not have insulin-mimetic properties⁷⁴. Unlike visfatin, omentin seems to be made by stromal-vascular cells within the fat pad rather than adipocytes. Interestingly, omentin is produced in considerable quantities by adipose tissue in humans and macaques but not mice⁷⁴. Omentin’s mechanism of action, including target tissues, a receptor or relevant signal transduction pathways, remains obscure.

Tumour necrosis factor-α and other cytokines

Tumour necrosis factor-α (TNF-α) was the first secreted adipose protein to be shown to have effects on glucose homeostasis⁷⁵. TNF-α levels are elevated in obesity and in other insulin-resistant states (such as sepsis), addition of TNF-α to cells and mice reduces insulin action, and blockade of TNF-α action by biochemical or genetic means restores insulin sensitivity in vivo and in vitro. Interestingly, TNF-α seems to be derived from cell types other than adipocytes themselves. Macrophages in particular have been implicated in TNF-α production from murine fat pads⁷⁶. Other cytokines, including interleukin-6, are produced by adipocytes, and there is conflicting evidence suggesting that they have both insulin-resistance-promoting and insulin-sensitizing effects^77,78. Such ‘adipocytokines’ can promote insulin resistance through several mechanisms. These include c-Jun N-terminal kinase 1 (JNK1)-mediated serine phosphorylation of insulin receptor substrate-1 (IRS-1)⁷⁹, IκB kinase (IKK)-mediated nuclear factor-κB (NF-κB) activation⁸⁰, induction of suppressor of cytokine signalling 3 (SOCS3)⁸¹ and production of ROS⁸².

Resistin

Resistin is another small inflammatory molecule with hyperglycaemic action. Resistin (also known as FIZZ3) is one of a family of cysteine-rich resistin-like molecules (RELMs)⁸³. Resistin was discovered as a secreted product of mouse adipocytes that was repressed by TZDs⁸⁴. Levels of resistin are elevated in many murine models of obesity, and gain- and loss-of-function studies in rodents support a role for resistin in increasing hepatic glucose output^85,86. Resistin might also be involved in reducing glucose uptake by muscles and fat, but this is not as robust an effect as that seen in the liver. As with adiponectin, there are several multimeric forms of resistin circulating in plasma, and action at the cellular level seems to depend on species with lower molecular weight⁸⁷. There is considerable controversy surrounding the role of resistin in humans, in whom even the cellular source of resistin has been debated. The bulk of the data suggest that human resistin is the product of macrophages or other stromal cells within the fat pad^88,89.

Retinol-binding protein 4

Specific ablation of glucose transporter 4 (Glut4) in mouse adipose tissue was shown to significantly reduce whole-body insulin sensitivity, whereas transgenic overexpression of Glut4 had the opposite effect. Because the magnitude of the effect was greater than that predicted by altered glucose flux into adipose tissue alone, an endocrine effect was postulated⁹⁰. Transcriptional profiling of samples from these mice led to the discovery that a secreted member of the lipocalin superfamily, retinol-binding protein 4 (RBP4), was coordinately regulated by the changes in adipocyte GLUT4 levels. Subsequent studies showed that overexpression of RBP4 impairs hepatic and muscle insulin action, and Rbp4^−/− mice show enhanced insulin sensitivity⁹⁰. Fenretinide, a drug that enhances RBP4 clearance, also increases insulin sensitivity in mice fed a high-fat diet. Furthermore, high serum RBP4 levels are associated with insulin resistance in obese humans and those with type 2 diabetes as well as in lean, nondiabetic people with a family history of diabetes⁹¹. Much remains to be learned about how RBP4 impairs insulin action, and at present it is not clear whether the process involves the retinoid ligand or some other mechanism.

Non-esterified fatty acids

Although the concept of adipokines is relatively new, non-esterified fatty acids (NEFAs) have long been known to be an adipocyte-derived secreted product. NEFAs are primarily released during fasting as a nutrient source for the rest of the body, and have several actions on glucose homeostasis (Fig. 5). Circulating NEFAs reduce adipocyte and muscle glucose uptake, and also promote hepatic glucose output^92,93. The net effect of these actions is to promote lipid burning as a fuel source in most tissues, while sparing carbohydrate for neurons (and red blood cells), which depend on glucose as an energy source. Several mechanisms have been proposed to account for the effects of NEFAs on muscle, liver and adipose tissue, including protein kinase C (PKC) activation^94,95, oxidative stress⁹⁶, ceramide formation⁹⁷ and activation of the innate immune system^98,99. These pathways are not mutually exclusive, and probably function interdependently.

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Figure 5

Adipocyte-derived non-esterified fatty acids have several effects on glucose homeostasis

Lipolysis in adipocytes is repressed by insulin, so it is normal in the fasted state when insulin levels are low. Insulin resistance, however, is also associated with lipolysis and NEFA release into the circulation. Elevated serum NEFAs inhibit insulin’s ability to promote peripheral glucose uptake into muscle and fat and to reduce hepatic glucose production. Transiently elevated NEFAs (such as occur after a meal) tend to enhance insulin secretion, whereas chronic elevations in NEFAs (such as occur in insulin resistance) tend to reduce insulin secretion.

Because lipolysis in adipocytes is repressed by insulin, insulin resistance from any cause can lead to NEFA elevation, which, in turn, induces additional insulin resistance as part of a vicious cycle. β-cells are also affected by NEFAs, depending in part on the duration of exposure; acutely, NEFAs induce insulin secretion (as after a meal), whereas chronic exposure to NEFAs causes a decrease in insulin secretion¹⁰⁰. This effect is mediated by several mechanisms, including lipotoxicity-induced apoptosis of islet cells¹⁰¹. In β-cells that escape apoptosis, NEFAs decrease glucose sensing by inducing expression of uncoupling protein-2 (UCP-2), which decreases mitochondrial membrane potential, ATP synthesis and insulin secretion¹⁰¹.

Lipid sink

Another way, albeit indirect, in which adipose tissue can affect global glucose homeostasis is by serving as a lipid sink. This idea has emerged from the observation that animals and humans with lipodystrophy (in which adipose tissue fails to develop properly) have ectopic lipid deposition in the liver, muscles, β-cells and other organs, which can lead to insulin resistance and decreased insulin secretion¹⁰². The ability to store large amounts of esterified lipid in a manner that is not toxic to the cell or the organism as a whole might be one of the most critical functions of the adipocyte. However, the ability of exogenous leptin^49,50, alone or in combination with adiponectin¹⁰³, to improve whole-body glucose homeostasis in lipodystrophy suggests that the endocrine function of adipose tissue is also crucial to the regulation of glucose homeostasis.

Inflammation and adipose tissue in obesity

There is now overwhelming evidence that obesity and type 2 diabetes are inflammatory states, consistent with the production of TNF-α and other cytokines by adipose tissue, as described above. In obese animals and humans, bone-marrow-derived macrophages are recruited to the fat pad under the influence of proteins secreted by adipocytes, including macrophage chemoattractant protein-1 (MCP-1)^76,104. Targeted ablation of either MCP-1 or its receptor reduces macrophage infiltration of fat depots and improves insulin sensitivity despite causing no change in body weight¹⁰⁵, and overexpression of MCP-1 has the opposite effect^106,107. These data, combined with studies (mentioned above) that indicate a role for pro-inflammatory cytokines in insulin resistance, strongly suggest that intra-adipose macrophages are dominant contributors to the insulin resistance that is associated with obesity. Thiazolidinediones, which are PPAR-γ agonists used clinically as insulin sensitizers, reduce MCP-1 levels and macrophage infiltration into adipose tissue¹⁰⁸.

We thank B. Lowell and M. Herman for a critical reading of the manuscript.