Jeffrey S. Flier scite author profile

Adipose tissue is a complex, essential, and highly active metabolic and endocrine organ. Besides adipocytes, adipose tissue contains connective tissue matrix, nerve tissue, stromovascular cells, and immune cells. Together these components function as an integrated unit. Adipose tissue not only responds to afferent signals from traditional hormone systems and the central nervous system but also expresses and secretes factors with important endocrine functions. These factors include leptin, other cytokines, adiponectin, complement components, plasminogen activator inhibitor-1, proteins of the renin-angiotensin system, and resistin. Adipose tissue is also a major site for metabolism of sex steroids and glucocorticoids. The important endocrine function of adipose tissue is emphasized by the adverse metabolic consequences of both adipose tissue excess and deficiency. A better understanding of the endocrine function of adipose tissue will likely lead to more rational therapy for these increasingly prevalent disorders. This review presents an overview of the endocrine functions of adipose tissue.

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TLR4 links innate immunity and fatty acid–induced insulin resistance

Shi¹,

Kokoeva²,

Inouye³

et al. 2006

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TLR4 is the receptor for LPS and plays a critical role in innate immunity. Stimulation of TLR4 activates proinflammatory pathways and induces cytokine expression in a variety of cell types. Inflammatory pathways are activated in tissues of obese animals and humans and play an important role in obesity-associated insulin resistance. Here we show that nutritional fatty acids, whose circulating levels are often increased in obesity, activate TLR4 signaling in adipocytes and macrophages and that the capacity of fatty acids to induce inflammatory signaling in adipose cells or tissue and macrophages is blunted in the absence of TLR4. Moreover, mice lacking TLR4 are substantially protected from the ability of systemic lipid infusion to (a) suppress insulin signaling in muscle and (b) reduce insulin-mediated changes in systemic glucose metabolism. Finally, female C57BL/6 mice lacking TLR4 have increased obesity but are partially protected against high fat diet-induced insulin resistance, possibly due to reduced inflammatory gene expression in liver and fat. Taken together, these data suggest that TLR4 is a molecular link among nutrition, lipids, and inflammation and that the innate immune system participates in the regulation of energy balance and insulin resistance in response to changes in the nutritional environment.

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Role of leptin in the neuroendocrine response to fasting

Ahima

Prabakaran

Mantzoros

et al. 1996

Nature

2,856

138

2,040

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A total deficiency in or resistance to the protein leptin causes severe obesity. As leptin levels rise with increasing adiposity in rodents and man, it is proposed to act as a negative feedback 'adipostatic signal' to brain centres controlling energy homeostasis, limiting obesity in times of nutritional abundance. Starvation is also a threat to homeostasis that triggers adaptive responses, but whether leptin plays a role in the physiology of starvation is unknown. Leptin concentration falls during starvation and totally leptin-deficient ob/ob mice have neuroendocrine abnormalities similar to those of starvation, suggesting that this may be the case. Here we show that preventing the starvation-induced fall in leptin with exogenous leptin substantially blunts the changes in gonadal, adrenal and thyroid axes in male mice, and prevents the starvation-induced delay in ovulation in female mice. In contrast, leptin repletion during this period of starvation has little or no effect on body weight, blood glucose or ketones. We propose that regulation of the neuroendocrine system during starvation could be the main physiological role of leptin.

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Obesity and insulin resistance

Kahn¹,

Flier²

2000

J. Clin. Invest.

2,739

1,979

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Obesity and the Regulation of Energy Balance

Spiegelman

Flier

2001

Cell

2,139

1,546

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and the Department of Cell Biology that triglycerides are stored in essentially anhydrous Harvard Medical School form; polysaccharides such as glycogen are hydrated Boston, Massachusetts 02115 in storage form, decreasing their efficiency as fuel. † Beth Israel Deaconess Medical Center To understand obesity, one must understand the con-Division of Endocrinology and the Department cept of energy balance (Figure 1). Assuming that an of Medicine individual has no problem with the absorption of nutri-Harvard Medical School ents, stored energy will increase only if energy intake Boston, Massachusetts 02115 exceeds total body energy expenditure. Energy expenditure takes the form of physical activity, basal metabolism, and adaptive thermogenesis. Physical activity re-Obesity is defined medically as a state of increased body fers to all voluntary movement, while basal metabolism weight, more specifically adipose tissue, of sufficient refers to the myriad biochemical processes necessary magnitude to produce adverse health consequences. to sustain life. Adaptive thermogenesis refers to energy There has been an alarming increase recently in the dissipated in the form of heat in response to environprevalence of this heterogeneous group of disorders in mental changes, such as exposure to cold and alterthe Western world (Kuczmarski et al., 1994

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Hepatic Fibroblast Growth Factor 21 Is Regulated by PPARα and Is a Key Mediator of Hepatic Lipid Metabolism in Ketotic States

et al. 2007

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Mice fed a high-fat, low-carbohydrate ketogenic diet (KD) exhibit marked changes in hepatic metabolism and energy homeostasis. Here, we identify liver-derived fibroblast growth factor 21 (FGF21) as an endocrine regulator of the ketotic state. Hepatic expression and circulating levels of FGF21 are induced by both KD and fasting, are rapidly suppressed by refeeding, and are in large part downstream of PPARalpha. Importantly, adenoviral knockdown of hepatic FGF21 in KD-fed mice causes fatty liver, lipemia, and reduced serum ketones, due at least in part to altered expression of key genes governing lipid and ketone metabolism. Hence, induction of FGF21 in liver is required for the normal activation of hepatic lipid oxidation, triglyceride clearance, and ketogenesis induced by KD. These findings identify hepatic FGF21 as a critical regulator of lipid homeostasis and identify a physiological role for this hepatic hormone.

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FGF21 regulates PGC-1α and browning of white adipose tissues in adaptive thermogenesis

Fisher¹,

Kleiner²,

Douris³

et al. 2012

Genes Dev.

1,300

1,277

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Certain white adipose tissue (WAT) depots are readily able to convert to a ''brown-like'' state with prolonged cold exposure or exposure to b-adrenergic compounds. This process is characterized by the appearance of pockets of uncoupling protein 1 (UCP1)-positive, multilocular adipocytes and serves to increase the thermogenic capacity of the organism. We show here that fibroblast growth factor 21 (FGF21) plays a physiologic role in this thermogenic recruitment of WATs. In fact, mice deficient in FGF21 display an impaired ability to adapt to chronic cold exposure, with diminished browning of WAT. Adipose-derived FGF21 acts in an autocrine/paracrine manner to increase expression of UCP1 and other thermogenic genes in fat tissues. FGF21 regulates this process, at least in part, by enhancing adipose tissue PGC-1a protein levels independently of mRNA expression. We conclude that FGF21 acts to activate and expand the thermogenic machinery in vivo to provide a robust defense against hypothermia.

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A Transgenic Model of Visceral Obesity and the Metabolic Syndrome

Masuzaki

Paterson

Shinyama

et al. 2001

Science

1,607

1,243

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The adverse metabolic consequences of obesity are best predicted by the quantity of visceral fat. Excess glucocorticoids produce visceral obesity and diabetes, but circulating glucocorticoid levels are normal in typical obesity. Glucocorticoids can be produced locally from inactive 11-keto forms through the enzyme 11beta hydroxysteroid dehydrogenase type 1 (11beta HSD-1). We created transgenic mice overexpressing 11beta HSD-1 selectively in adipose tissue to an extent similar to that found in adipose tissue from obese humans. These mice had increased adipose levels of corticosterone and developed visceral obesity that was exaggerated by a high-fat diet. The mice also exhibited pronounced insulin-resistant diabetes, hyperlipidemia, and, surprisingly, hyperphagia despite hyperleptinemia. Increased adipocyte 11beta HSD-1 activity may be a common molecular etiology for visceral obesity and the metabolic syndrome.

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Jeffrey S. Flier

Adipose Tissue as an Endocrine Organ

TLR4 links innate immunity and fatty acid–induced insulin resistance

Role of leptin in the neuroendocrine response to fasting

Obesity and insulin resistance

Obesity and the Regulation of Energy Balance

Hepatic Fibroblast Growth Factor 21 Is Regulated by PPARα and Is a Key Mediator of Hepatic Lipid Metabolism in Ketotic States

FGF21 regulates PGC-1α and browning of white adipose tissues in adaptive thermogenesis

A Transgenic Model of Visceral Obesity and the Metabolic Syndrome

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