The ob gene product (leptin)--a new hormone of adipose tissue

Obesity--an important problem in modern societies--is caused by energy balance dysregulation and produces numerous adverse effects on health. Recently a particular attention has been paid to molecular and physiological mechanisms in the development of obesity and to the signalling role of adipose tissue in energy stores maintenance on the hypothalamic level. Leptin, the obese gene product discovered in 1995, may play a key role in the feedback system between adipose tissue and the ventromedial nucleus of the hypothalamus (satiety centre). The level of ob gene expression in adipose tissue and plasma leptin concentrations in humans are highly correlated with BMI. So far no mutations in the ob gene in obese subjects have been reported therefore leptin molecule could be active. Despite markedly increased leptin levels found in obesity its central action decreasing food intake and increasing energy expenditure is hindered. Defective ob protein signalling to the brain may be due to receptor and post-receptor defects. Neuropeptide Y, the hypothalamic neurotransmitter involved in the maintaining of energy homeostasis, is a likely candidate for mediating leptin afferent signals. In adipose tissue, the level of ob mRNA is regulated by insulin and glucocorticoids--hormones responsible for glucose homeostasis as well as for the central regulation of feeding behaviour. Until now the character of interactions between leptin and other hormones that regulate energy balance is not known, neither is the exact nature of leptin hypothalamic receptor defect. Defining of the role of leptin in the regulation of satiety and energy expenditure will undoubtedly contribute to a better understanding of the pathogenesis of obesity and its related metabolic complications and may lead to a new treatment approach to human obesity based on leptin or its analogues. At present research work focuses on leptin receptor studies and on ob gene polymorphism and its expression in feeding disorders including obesity and anorexia nervosa. The ob gene is one of a few genes involved in energy balance, however, very promising one.     

The biology of leptin: a review

Leptin, a 16-kDa protein secreted from white adipocytes, has been implicated in the regulation of food intake, energy expenditure, and whole-body energy balance in rodents and humans. The gene encoding leptin was identified by positional cloning and is the mutation leading to the profound obese phenotype of the ob/ob mouse. Exogenous administration of leptin to ob/ob mice leads to a significant improvement in reproductive and endocrine status as well as reduced food intake and weight loss. The expression and secretion of leptin is highly correlated with body fat mass and adipocyte size. Cortisol and insulin are potent stimulators of leptin expression, and expression is attenuated by beta-adrenergic agonists, cAMP, and thiazolidinediones. The role of other hormones and growth factors in the regulation of leptin expression and secretion is emerging. Leptin circulates specifically bound to proteins in serum, which may regulate its half-life and biological activity. Isoforms of the leptin receptor, members of the interleukin-6 cytokine family of receptors, are found in multiple tissues, including the brain. Many of leptin's effects on food intake and energy expenditure are thought to be mediated centrally via neurotransmitters such as neuropeptide Y. Multiple peripheral effects of leptin have also been recently described, including the regulation of insulin secretion by pancreatic beta cells and regulation of insulin action and energy metabolism in adipocytes and skeletal muscle. Leptin is thought to be a metabolic signal that regulates nutritional status effects on reproductive function. Leptin also plays a major role in hematopoeisis and in the anorexia accompanying an acute cytokine challenge. The profound effects of leptin on regulating body energy balance make it a prime candidate for drug therapies for humans and animals.     

Evaluating genetics and environment in development of obesity

Previous studies with twins had demonstrated that heredity exerts a definite impact on the development of overweight even more than environmental conditions of nutrition. In recent years studies of molecular genetics in imbred obese mice lead to the discovery of the ob-gene coding for the expression of the ob-protein (leptin) in adipose tissue. Mutation of this gene and also of other genes coding for the expression of receptor proteines for leptin were also discovered in obese mice. In humans, however, mutations of the ob-gene were found only in a few families with hereditary obesity obviously as rarities as compared to a huge number of overweight people with high leptin of normal structure in western societies. About the molecular structure of leptin receptors or its possible mutation in obesity are no human results are available at the present time. In this survey further observations about genetics and mutations of transmitters regulating feeding and for energy expenditure are reported. Although all these results come from animals it may be presumed that they will provide an experimental basis for a better understanding of genetic mechanisms leading to obesity in humans and also for future development of drugs interfering with these mechanisms thus offering a chance for medical treatment of obesity.     

Leptin as a metabolic regulator during fetal and neonatal life and in childhood and adolescence

Body weight is regulated by a feedback loop in which peripheral signals report nutritional information to an integratory center in the brain. The cloning of the ob gene is consistent with this concept and suggests that body fat content in adult rodents is regulated by a negative feedback loop centered in the hypothalamus/1-8/. In a recent report, two severely obese children with congenital leptin deficiency due to a homozygous frame-shift mutation involving the deletion of a single guanine nucleotide in codon 133 of the ob gene have been described. This discovery provides the first genetic evidence that leptin is an important regulator of energy balance in humans. However, it has become increasingly clear that apart from leptin's function in the central nervous system and in regulation of energy balance, leptin also acts in the periphery and might be important as a hormone modulating processes in regard to reproduction, glucose metabolism and insulin resistance, as well as growth and development of many tissues and organs either directly or indirectly. This report reviews some of the topics of leptin research that are of particular importance and relevance for pediatric and adolescent medicine and for pediatric endocrinology in particular.     

Regulation of ob gene and overexpression in obesity

The ob gene product, called leptin, is a recently discovered hormone secreted by the adipose cells. By acting as a satiety factor and increasing energy expenditure, leptin plays a major role in body weight homeostasis in mice. Ob gene and leptin production by the adipose cells are under the control of various hormonal and metabolic factors. Ob mRNA levels are markedly reduced by fasting and restored to normal by refeeding. High-fat feeding increases ob gene and plasma leptin, and induces a state of resistance to leptin. Two hormones, insulin and corticosterone, increase leptin production in rodent and human adipose cells. In contrast, the activity of the sympathetic nervous system exerts an opposite effect, mainly through activation of the adipose beta 3-adrenergic receptors. Leptin synthesis is also decreased by thiazolidinediones, a new class of antidiabetic drugs. The obese Zucker fa/fa rats bear a mutation in the leptin receptor gene (OB-R) and are leptin resistant. In these rats, ob mRNA levels are increased early in life and are not reduced by fasting. This suggests that functional OB-Rs are required for the generation of the signal(s) that downregulates ob gene expression in the adipose cell. The extent to which this is relevant to human obesities, which are characterized by increased leptin levels, remains to be determined.     

Relation between circulating leptin concentrations and appetite during a prolonged, moderate energy deficit in women

BACKGROUND: On the basis of observations in rodents, leptin is thought to play a key role in the regulation of energy expenditure and food intake, but less is known of its influence on ingestive behavior and energy balance in humans. OBJECTIVE: We examined the effect in women of a chronic energy deficit on plasma leptin concentrations and self-reported appetite and explored possible relations between leptin and appetite sensations. DESIGN: Twelve healthy women (body mass index, in kg/m2: 23-37) participated in a metabolic ward study in which 3 wk of neutral energy balance was followed by 12 wk of energy deficit (energy intake reduced by 2 MJ/d and energy expenditure increased by 0.8 MJ/d). Body weight and composition were monitored, fasting leptin concentrations were measured 4 times, and feelings of hunger, fullness, desire to eat, and prospective consumption were monitored hourly throughout the day on 7 selected days. RESULTS: Adiposity-adjusted leptin decreased by 54% after 1 wk of a moderate energy deficit and remained low after 6 and 12 wk. Leptin was associated with self-reported hunger, desire to eat, and prospective consumption (range of r: -0.6 to -0.7, P < 0.01). The greatest hunger increase coincided with the largest percentage drop in circulating leptin and the lowest final leptin concentration. The relation between leptin and hunger was not influenced by amount of weight or body fat loss. CONCLUSIONS: These findings support the idea that leptin is a physiologic regulator of hunger during energy deficits in humans; the role of leptin in the long-term regulation of food intake warrants further study.     

Leptin and the regulation of body weight

Leptin has received considerable attention as a newly recognized metabolic hormone and for its potential for therapeutic use in the treatment of human obesity. Furthermore, defects in the leptin signal pathway that result in obesity in animal models have raised the possibility of a similar etiology for obesity in humans. This review will summarize the current findings on leptin in both humans and rodents. These findings will be discussed with respect to our view of the physiology and potential for pathophysiology in leptin-mediated regulation of body weight and composition.     

Total energy expenditure and the level of physical activity correlate with plasma leptin concentrations in five-year-old children

Leptin, the product of the ob gene, is a hormone secreted by adipocytes that is known to decrease food intake and increase energy expenditure in ob/ob mice. In humans, variants in the OB gene have not been detected and very little is known about the action of leptin on food intake and energy expenditure, although circulating leptin concentrations are positively correlated to body fat stores. The purpose of this study was to assess the relationship between fasting plasma leptin concentrations and energy expenditure in 123 5-yr-old Pima Indian children (67 males/76 females). Body composition was assessed by isotopic water dilution (18O) whereas total energy expenditure (TEE) and resting metabolic rate (RMR) were measured using doubly labeled water and indirect calorimetry, respectively. The physical activity level was calculated as the ratio of TEE:RMR. Plasma leptin concentrations were positively correlated to percent body fat (r = 0.84, P < 0.0001), but were similar in boys and girls after adjusting for percent body fat. Most importantly, we found that, independent of the percentage of body fat, plasma leptin concentrations correlated with TEE (in absolute values, r = 0.37, P < 0.0001, or adjusted for body size r = 0.42; P < 0.0001) and with physical activity level (r = 0.26, P < 0.01), but not RMR. These results suggest that, as in animal models, leptin plays a role in energy expenditure in humans.     

Genetic studies of the leptin receptor gene in morbidly obese French Caucasian families

Family studies have shown that in some populations up to 75% of the variation of body mass index can be explained by genetic factors. However, in humans, no major obesity gene has been identified to date. In contrast, there are a number of genetically well defined animal models for obesity. In two of those models (ob/ob and db/db), defects in the same pathway are responsible for obesity. Recently, some evidence has been found for the OB gene also being involved in human obesity. In this study we investigated the potential role of the OB receptor (OBR) in the etiology of massive obesity in humans using familial linkage analyses and case-control association studies. The typing of two microsatellite markers (D1S198 and D1S209), flanking the OBR gene, in 256 sib pairs showed no evidence for linkage with obesity. In order to be able to detect small gene effects, association studies with a 3'-UTR insertion/deletion polymorphism were carried out. The results of these analyses remained non-significant (chi 2 = 3.442, P = 0.18). However, subjects heterozygous for the insertion/deletion polymorphism showed a slight trend towards lower insulin values 30 min after an oral glucose load compared to homozygous individuals (P = 0.02). In summary, our results do not support a major role of the human OBR gene in the development of morbid obesity in our population.     

Recessive inheritance of obesity in familial non-insulin-dependent diabetes mellitus, and lack of linkage to nine candidate genes

Segregation analysis of body-mass index (BMI) supported recessive inheritance of obesity, in pedigrees ascertained through siblings with non-insulin dependent diabetes mellitus (NIDDM). BMI was estimated as 39 kg/m2 for those subjects homozygous at the inferred locus. Two-locus segregation analysis provided weak support for a second recessive locus, with BMI estimated as 32 kg/m2 for homozygotes. NIDDM prevalence was increased among those subjects presumed to be homozygous at either locus. Using both parametric and nonparametric methods, we found no evidence of linkage of obesity to any of nine candidate genes/regions, including the Prader-Willi chromosomal region (PWS), the human homologue of the mouse agouti gene (ASP), and the genes for leptin (OB), the leptin receptor (OBR/DB), the beta3-adrenergic receptor (ADRB3), lipoprotein lipase (LPL), hepatic lipase (LIPC), glycogen synthase (GYS), and tumor necrosis factor alpha (TNFA).     

Leptin Receptor

Leptin is a fat cell-derived satiety factor that regulates food intake and energy expenditure. Its effects are mediated by interactions with the leptin receptor (Ob-R) that is alternatively spliced to encode at least five isoforms(a-e), which are distributed in a wide range of tissues including the hypothalamus. Ob-R is a member of cytokine receptors and involves the JAK-STAT signal transduction system. We found Ob-R mutations in Zucker fatty rats and obese Koletsky rats and demonstrated that Ob-R dysfunction brings around hyperphagia and obesity. However we and others have not found any Ob-R mutation in human obese subjects.     

Leptin concentrations in relation to body mass index and the tumor necrosis factor-alpha system in humans

The expression of leptin, an adipocyte-derived protein whose circulating levels reflect energy stores, can be induced by tumor necrosis factor (TNF)alpha in rodents, but an association between the TNF alpha system and leptin levels has not been reported in humans. To evaluate the potential association between serum leptin and the TNF alpha system, we measured the levels of soluble TNF alpha-receptor (sTNF alpha-R55), which has been validated as a sensitive indicator of activation of the TNF alpha system. We studied two groups: 1) 82 young healthy normal controls and 2) 48 patients with noninsulin dependent diabetes mellitus (NIDDM) and 24 appropriately matched controls. By simple regression analysis in controls, there was a strong positive association between leptin and 3 parameters: body mass index, sTNF alpha-R55, and insulin levels. In a multiple regression analysis model, leptin remained significantly and strongly associated with body mass index, and the association of leptin with both insulin and sTNF alpha-R55, although weakened, remained significant. Patients with NIDDM had leptin concentrations similar to controls of similar weight. Importantly, serum levels of sTNF alpha-R55 were also positively and independently associated with leptin in this group of diabetic subjects and matched controls. These data are consistent with the hypothesis that the TNF alpha system plays a role in regulating leptin levels in humans. Further elucidation of a possible role of the TNF alpha system in leptin expression and circulating levels may have important implications for our understanding of obesity and cachexia in humans.     

Overexpression of leptin receptors in pancreatic islets of Zucker diabetic fatty rats restores GLUT-2, glucokinase, and glucose-stimulated insulin secretion

The high-Km glucose transporter, GLUT-2, and the high-Km hexokinase of beta cells, glucokinase (GK), are required for glucose-stimulated insulin secretion (GSIS). GLUT-2 expression in beta cells of Zucker diabetic fatty (ZDF) rats is profoundly reduced at the onset of beta-cell dysfunction of diabetes. Because ZDF rats are homozygous for a mutation in their leptin receptor (OB-R) gene and are therefore leptin-insensitive, we expressed the wild-type OB-R gene in diabetic islets by infusing a recombinant adenovirus (AdCMV-OB-Rb) to determine whether this reversed the abnormalities. Leptin induced a rise in phosphorylated STAT3, indicating that the transferred wild-type OB-R was functional. GLUT-2 protein rose 17-fold in AdCMV-OB-Rb-treated ZDF islets without leptin, and leptin caused no further rise. GK protein rose 7-fold without and 12-fold with leptin. Preproinsulin mRNA increased 64% without leptin and rose no further with leptin, but leptin was required to restore GSIS. Clofibrate and 9-cis-retinoic acid, the partner ligands for binding to peroxisome proliferator-activator receptor alpha (PPARalpha) and retinoid X receptor, up-regulated GLUT-2 expression in islets of normal rats, but not in ZDF rats, in which PPARalpha is very low. Because the fat content of islets of diabetic ZDF rats remains high unless they are treated with leptin, it appears that restoration of GSIS requires normalization of intracellular nutrient homeostasis, whereas up-regulation of GLUT-2 and GK is leptin-independent, requiring only high expression of OB-Rb.     

Obesity and mild hyperinsulinemia found in neuropeptide Y-Y1 receptor-deficient mice

To elucidate the role of neuropeptide Y (NPY)-Y1 receptor (Y1-R) in food intake, energy expenditure, and other possible functions, we have generated Y1-R-deficient mice (Y1-R-/-) by gene targeting. Contrary to our hypothesis that the lack of NPY signaling via Y1-R would result in impaired feeding and weight loss, Y1-R-/- mice showed a moderate obesity and mild hyperinsulinemia without hyperphagia. Although there was some variation between males and females, typical characteristics of Y1-R-/- mice include: greater body weight (females more than males), an increase in the weight of white adipose tissue (WAT) (approximately 4-fold in females), an elevated basal level of plasma insulin (approximately 2-fold), impaired insulin secretion in response to glucose administration, and a significant changes in mitochondrial uncoupling protein (UCP) gene expression (up-regulation of UCP1 in brown adipose tissue and down-regulation of UCP2 in WAT). These results suggest either that the Y1-R in the hypothalamus is not a key molecule in the leptin/NPY pathway, which controls feeding behavior, or that its deficiency is compensated by other receptors, such as NPY-Y5 receptor. We believe that the mild obesity found in Y1-R-/- mice (especially females) was caused by the impaired control of insulin secretion and/or low energy expenditure, including the lowered expression of UCP2 in WAT. This model will be useful for studying the mechanism of mild obesity and abnormal insulin metabolism in noninsulin-dependent diabetes mellitus.     

Phenotype of the obese Koletsky (f) rat due to Tyr763Stop mutation in the extracellular domain of the leptin receptor (Lepr): evidence for deficient plasma-to-CSF transport of leptin in both the Zucker and Koletsky obese rat

The obese phenotypes of the diabetes (db) mouse and fatty fa) rat are due to functional null mutations of the leptin receptor (Lepr). The recessive mutation in the Koletsky (f) obese rat maps to the same genetic intervals as db and fa and fails to complement the fa mutation. Comparison of the sequence of brain Lepr cDNA from +/+ and f/f animals reveals a T2349A transversion resulting in a Tyr763Stop nonsense mutation in the gene just before the transmembrane domain. Virtual absence of Lepr mRNA in whole brain from f/f animals is consistent with the presence of a null mutation. The predicted reduced cerebrospinal fluid (CSF) transport of leptin in both f/f and fa/fa mutants is reflected in the approximately 10-fold lower ratio of CSF/plasma leptin concentration in the obese versus lean animals. However, equivalent CSF leptin concentration between lean and obese rats (fa/fa, f/f) indicates that leptin can enter the CSF through a non-Lepr-mediated mechanism, which may be saturated at normal physiological plasma leptin concentration.     

Serum leptin and energy expenditure in children

Leptin has been hypothesized to play an important role in energy balance by affecting both energy intake and energy expenditure. The purpose of our study was to determine the relationship between fasting serum leptin concentrations and measures of energy expenditure in prepubertal children. We measured total energy expenditure (TEE; by the doubly labeled water technique), resting energy expenditure (REE; after an overnight fast), activity energy expenditure (AEE; TEE-REE), body composition (by dual energy x-ray absorptiometry), and fasting serum leptin concentration (by RIA) in 76 children. Simple correlations showed that all measures of energy expenditure (TEE, REE, and AEE) were positively related to the serum leptin concentration (r = 0.50, P < 0.001; r = 0.45, P < 0.001; and r = 0.30, P < 0.01, respectively). However, after adjusting for body composition (fat-free mass and fat mass), gender, and ethnicity, serum leptin concentrations were not related to any measure of energy expenditure (TEE, P = 0.61; REE, P = 0.97; AEE, P = 0.65). These latter findings were further confirmed using structural equation models with leptin and energy expenditure as dependent variables, and fat-free mass and fat mass as independent variables. Results from these models showed no direct effect of leptin and no indirect effect of fat mass (through leptin) on any measure of energy expenditure, when a path between fat mass and energy expenditure was present in the model. Thus, our data do not support the hypothesis that the serum leptin concentration (independent of fat mass) is related to measures of energy expenditure in children.