Leptin fluctuates in intestinal ischemia-reperfusion injury as inflammatory cytokine

As leptin is an active mediator mainly secreted by adipose tissue and is closely related with energy metabolism, we evaluate both the changes of leptin levels in serum and adipose tissue with a concise radioimmunoassay and the changes of leptin mRNA expression in adipose tissue with RT-PCR, during the severe metabolic impediment in rat intestinal ischemia-reperfusion (I/R) injury. Results show that not only leptin levels in serum and adipose tissue but also its mRNA expression in adipose tissue undergo a fluctuation according to different injury times. Therefore, we conclude that leptin has a time-dependent response to acute inflammatory stimuli and acts as an anti-inflammatory cytokine.     

Leptin induces angiopoietin-2 expression in adipose tissues

Adipose tissues consisting of adipocytes, microvasculature, and stroma are completely ablated upon over-expression of leptin in rats. This tissue regression is mediated by enhanced lipid beta-oxidation, adipocyte dedifferentiation, and apoptosis. To further characterize this phenomenon, we studied the possible effect of leptin on the adipose microvasculature. Tissue microvasculature is maintained by the interplay between positive and negative signals mediated by factors including vascular endothelial growth factor (VEGF), basic fibroblast growth factor, angiopoietin-1 (Ang-1), and Ang-2. Expression of the negative signal Ang-2 was reported in fetal tissues and in the adult ovary, which undergoes vascular remodeling or regression. We demonstrate that leptin induces the expression of Ang-2 in adipose tissue without a concomitant increase in VEGF. Induction of Ang-2 occurred in an autocrine manner, as demonstrated in cultured adipocytes but not in several other cell types. This tissue-specific induction of Ang-2 coincided with initiation of apoptosis in adipose endothelial cells. We propose that induction of Ang-2 by leptin in adipose cells is one of the events leading to adipose tissue regression.     

The adipoinsular axis: effects of leptin on pancreatic beta-cells

The prevalence of obesity and related diabetes mellitus is increasing worldwide. Here we review evidence for the existence of an adipoinsular axis, a dual hormonal feedback loop involving the hormones insulin and leptin produced by pancreatic beta-cells and adipose tissue, respectively. Insulin is adipogenic, increases body fat mass, and stimulates the production and secretion of leptin, the satiety hormone that acts centrally to reduce food intake and increase energy expenditure. Leptin in turn suppresses insulin secretion by both central actions and direct actions on beta-cells. Because plasma levels of leptin are directly proportional to body fat mass, an increase of adiposity increases plasma leptin, thereby curtailing insulin production and further increasing fat mass. We propose that the adipoinsular axis is designed to maintain nutrient balance and that dysregulation of this axis may contribute to obesity and the development of hyperinsulinemia associated with diabetes.     

Ciliary neurotrophic factor injected icv induces adipose tissue apoptosis in rats

Recent findings show that ciliary neurotrophic factor (CNTF) and leptin have similar effects on food intake and body weight, suggesting possible overlapping mechanisms. Intracerebroventricular (icv) injection of leptin results in adipose tissue apoptosis. To determine if CNTF has similar activity, male Sprague Dawley rats implanted with lateral cerebroventricular cannulas were randomly assigned to four treatment groups ( N = 8), including control (aCSF), 10 microg/day leptin, 1 microg/day CNTF, and 5 microg/day CNTF. Rats received daily icv injections for 4 successive days. Both leptin and CNTF (5 microg) decreased BW (8.6% and 11.77%, respectively, p <.05) and cumulative food intake was decreased 43% by leptin ( p <.05). Leptin and CNTF (5 microg) reduced adipose tissue mass in epididymal adipose (Epi) by 30 and 33.5%, ( p <.05), in inguinal adipose (Ing) by 51 and 55% ( p <.05), in retroperitoneal adipose (Rp) by 65 and 64% ( p <.05), and in intrascapular brown adipose (iBAT) by 34 and 25% ( p <.05), respectively. Gastrocnemius muscle was not affected. Leptin and CNTF (5 microg) increased apoptosis in Epi by 84 and 150%, respectively ( p <.05) and in Rp by 121 and 146%, respectively ( p <.05). Loss of adipocytes by apoptosis may provide an explanation for the unexpected delay in return to initial energy status following CNTF treatments.     

Effects of central or peripheral leptin administration on norepinephrine turnover in defined fat depots

Leptin preserves lean tissue but decreases adipose tissue by increasing lipolysis and/or inhibiting lipogenesis. The sympathetic nervous system (SNS) is a primary regulator of lipolysis, but it is not known if leptin increases norepinephrine turnover (NETO) in white adipose tissue. In this study, we examined the effect of leptin administered either as a chronic physiological dose (40 microg/day for 4 days from ip miniosmotic pumps) or as an acute injection in the third ventricle (1.5 microg injected two times daily for 2 days) on NETO and the size of brown and white fat depots in male Sprague Dawley rats. NETO was determined from the decline in tissue norepinephrine (NE) during 4 h following administration of the NE synthesis inhibitor alpha-methyl-para-tryrosine. The centrally injected leptin-treated animals demonstrated more dramatic reductions in food intake, body weight, and fat pad size and an increase in NETO compared with the peripherally infused animals. Neither route of leptin administration caused a uniform increase in NETO across all fat pads tested, and in both treatment conditions leptin decreased the size of certain fat pads independent of an increase in NETO. Similar discrepancies in white fat NETO were found for rats pair fed to leptin-treated animals. These results demonstrate that leptin acting either centrally or peripherally selectively increases sympathetic outflow to white fat depots and that a leptin-induced change in fat pad weight does not require an increase in NETO.     

CNS melanocortin and leptin effects on stearoyl-CoA desaturase-1 and resistin expression

The objective of this study was to determine whether centrally administered leptin decreased liver and adipose SCD1 expression or adipose resistin expression, and whether these effects were mediated by central melanocortin receptors. Male Sprague-Dawley rats were injected into the lateral cerebral ventricle (i.c.v.) once daily for 4 days with artificial cerebrospinal fluid (aCSF, 5 microl), leptin (10 microg) or MTII (0.1 nmol); two other groups were pretreated icv with the melanocortin antagonist, SHU9119 (1.0 nmol), followed by leptin or MTII. Epididymal and inguinal adipose tissue and liver were collected after rats were killed and mRNA expression of SCD1 and resistin was measured. Both leptin and MTII reduced SCD1 expression and pretreatment with SHU9119 reversed their effects. Neither leptin nor MTII affected resistin expression, but it was increased by SHU9119. These results show that CNS melanocortin receptors are likely mediators of leptin's effects on SCD1 expression in liver and adipose tissue, The findings were inconclusive concerning the effects of leptin and melanocortins on adipose resistin expression.     

Roles for melanocortins and leptin in adipose tissue apoptosis and fat deposition

Leptin has a wide range of effects on physiological functions related to the regulation of body energy balance. Many of leptin's effects are mediated through neuropeptide-containing neurons and neuropeptide receptors in the hypothalamus. The melanocortin system includes both agonist (alpha-melanocyte stimulating hormone, alphaMSH) and antagonist peptides (agouti related peptide, AGRP). Increased melanocortin receptor stimulation following leptin administration plays an important role in leptin-induced hypophagia and increased sympathetic nervous system activity and is partly responsible for leptin-induced weight loss. However, melanocortins do not appear to mediate some of the more striking centrally-mediated effects of leptin on adipose tissue, including adipose tissue apoptosis, that lead to the extensive depletion of fat.     

Morphological characteristics of neonatal adipose tissue

The aim of the present work was to study the morphological characteristics of neonatal adipose tissue using rats as an animal model. The results revealed that the subcutaneous adipose tissue of newborns consists of packets of unilocular adipose cells (one large lipid drop occupying the whole cell and pushing the cytoplasm and the nucleus to the cell periphery) and some multilocular fat cells (several lipid droplets of different size and an almost centrally located nucleus). All the adipocytes demonstrated positive immunohistochemical expression for leptin, whereas the multilocular adipose cells were positive for cyclin D1. These findings suggest that the multilocular adipose cells are preadipocytes that have not yet finished proliferation and differentiation and could under some external and/or internal stimuli conclude their development and become mature unilocular adipocytes, thus increasing fat mass.     

Interleukin-6-deficient mice develop mature-onset obesity.

The immune-modulating cytokine interleukin-6 (IL-6) is expressed both in adipose tissue and centrally in hypothalamic nuclei that regulate body composition. We investigated the impact of loss of IL-6 on body composition in mice lacking the gene encoding IL-6 (Il6-/- mice) and found that they developed mature-onset obesity that was partly reversed by IL-6 replacement. The obese Il6-/- mice had disturbed carbohydrate and lipid metabolism, increased leptin levels and decreased responsiveness to leptin treatment. To investigate the possible mechanism and site of action of the anti-obesity effect of IL-6, we injected rats centrally and peripherally with IL-6 at low doses. Intracerebroventricular, but not intraperitoneal IL-6 treatment increased energy expenditure. In conclusion, centrally acting IL-6 exerts anti-obesity effects in rodents.     

Leptin and leptin receptor expression in a lipoblastoma in an 8-year-old girl

Leptin is a hormone that is produced by adipocytes. Leptin acts on specific receptors in the hypothalamus. RNA was isolated from a lipoblastoma of an 8-year-old girl and the expression of leptin and leptin receptor mRNA was analyzed by RT-PCR. The lipoblastoma tumor, a rare form of childhood tumors, expressed leptin and leptin receptors in a fashion similar to normal adipose tissue. We hypothesize that the peripheral action of leptin via its receptors could play a role in the development and/or progression of lipoblastoma. Whether or not leptin and leptin receptor expression play a role in the development and/or progression of lipoblastoma and other tumors is not clear to date. Copyrightz1999S.KargerAG, Basel     

Serum leptin concentrations during short-term administration of growth hormone and triiodothyronine in healthy adults: a randomised, double-blind placebo-controlled study.

The regulation of adipose tissue mass and energy expenditure is currently subject to intensive research, which primarily relates to the discovery of leptin. Leptin is a peptide, which is the product of the obese (ob) gene expressed in adipose tissue of several species icluding humans. Leptin is supposed to serve both as an index of fat mass and as a sensor of energy balance. Administration of recombinant murine leptin in ob/ob-mice, which do not produce leptin, decreases food intake and increases thermogenesis both of which result in a reduction in body weight and adipose tissue mass. The calorigenic effect of leptin presumably acts through an increase in sympathetic outflow which in turn activates the beta3 adrenergic receptor in brown adipose tissue. The regulation and action of endogenous leptin in humans are less well understood, and clinical grade recombinant human leptin is so far not available. Serum leptin correlates logarithmically with total body fat in both normal weight and obese subjects, which suggest insensitivity to leptin in obese patients. Furthermore, more rapid excursions in serum leptin have been reported following short-term changes in caloric intake and administration of insulin. Growth hormone (GH) exerts pronounced effects on lipid metabolism and resting energy expenditure. The lipolytic actions of GH appear to involve both increased sensitivity to the beta-adrenergic pathway, and a suppression of adipose tissue lipoprotein lipase activity. The calorigenic effects of GH have been shown not only to be secondary to changes in lean body mass. Growth hormone administration furthermore increases the peripheral conversion of thyroxine to triiodothyronine, which may contribute to the overall actions of GH on fuel and energy metabolism. So far, little is known about the effects of GH and iodothyronines on serum leptin levels in humans. We therefore measured serum leptin levels and energy expenditure before and after the administration of GH and triiodothyronine, alone and in combinaion, in a randomized double-blind placebo-controlled study in healthy young male adults. The dose of triiodothyronine was selected to obtain serum levels comparable to those seen after GH administration.     

Response of leptin mRNA to 24-h food deprivation and refeeding is influenced by age in rats

To obtain an insight into the influence of aging on leptin gene expression, the responses of leptin mRNA in retroperitoneal and epididymal adipose tissues and plasma leptin concentrations to 24-h food deprivation and refeeding were examined in 2-, 10- and 24-month-old normal rats. The basal level of leptin gene expression in retroperitoneal adipose tissue was significantly higher in 10- and 24-month-old rats than that in 2-month-old rats, while the level in epididymal adipose tissue was highest in 10-month-old rats for all three age groups. The basal concentrations of plasma leptin was significantly higher in 10- and 24-month-old rats than those in 2-month-old rats. The 24-h food deprivation was followed by a significant reduction in leptin mRNA expression in both retorperitoneal and epididymal adipose tissues for all three age groups. The leptin gene expression was restored to control levels 24 h following refeeding in the 2- and 10-month-old rats, but failed to be restored in the 24-month-old rats. In addition, the time course of recovery for leptin mRNA expression by refeeding to the control levels differed between the retroperitoneal and the epididymal adipose tissue in 2- and 10-month-old rats. The concentrations of plasma leptin 24 h following refeeding were compatible with the leptin mRNA levels in adipose tissues in three age groups. These results suggest that the expression of the leptin gene in response to food-deprivation and refeeding is influenced by an animal's age and that this expression is different for different regions of white adipose tissue.     

Hypoxia and the endocrine and signalling role of white adipose tissue

White adipose tissue is a major endocrine and signalling organ. It secretes multiple protein hormones and factors, termed adipokines (such as adiponectin, leptin, IL-6, MCP-1, TNFalpha) which engage in extensive cross-talk within adipose tissue and with other tissues. Many adipokines are linked to inflammation and immunity and these include cytokines, chemokines and acute phase proteins. In obesity, adipose tissue exhibits a major inflammatory response with increased production of inflammation-related adipokines. It has been proposed that hypoxia may underlie the inflammatory response in adipose tissue and evidence that the tissue is hypoxic in obesity has been obtained in animal models. Cell culture studies have demonstrated that the expression and secretion of key adipokines, including leptin, IL-6 and VEGF, are stimulated by hypoxia, while adiponectin (with an anti-inflammatory action) production falls. Hypoxia also stimulates glucose transport by adipocytes and may have a pervasive effect on cell function within adipose tissue.     

Leptin action in normal and pathological pregnancies

Leptin is now considered an important signalling molecule of the reproductive system, as it regulates the production of gonadotrophins, the blastocyst formation and implantation, the normal placentation, as well as the foeto‐placental communication. Leptin is a peptide hormone secreted mainly by adipose tissue, and the placenta is the second leptin‐producing tissue in humans. Placental leptin is an important cytokine which regulates placental functions in an autocrine or paracrine manner. Leptin seems to play a crucial role during the first stages of pregnancy as it modulates critical processes such as proliferation, protein synthesis, invasion and apoptosis in placental cells. Furthermore, deregulation of leptin levels has been correlated with the pathogenesis of various disorders associated with reproduction and gestation, including polycystic ovary syndrome, recurrent miscarriage, gestational diabetes mellitus, pre‐eclampsia and intrauterine growth restriction. Due to the relevant incidence of the mentioned diseases and the importance of leptin, we decided to review the latest information available about leptin action in normal and pathological pregnancies to support the idea of leptin as an important factor and/or predictor of diverse disorders associated with reproduction and pregnancy.     

瘦素诱导体外培养大鼠脂肪间充质干细胞凋亡

为观察瘦素诱导体外培养大鼠脂肪间充质干细胞凋亡的作用, 采用胶原酶消化法分离培养大鼠附睾脂肪垫间充质干细胞, 第3代细胞用于实验。细胞免疫荧光化学方法鉴定CD105、Vimentin表达阳性率约80%以上, 10-6 mol/L的瘦素作用细胞48 h、72 h后激光共聚焦显微镜观察分别可见早期及中晚期特征表现; 0 mol/L、10-8 mol/L、10-7 mol/L、10-6 mol/L瘦素分别作用于细胞48 h后, 应用AnnexinⅤ/PI双染色法流式细胞仪检测早期凋亡率分别为2.50%±0.72%、6.78%±1.99%、11.99%±1.58%、17.93%±4.82% (P<0.05); 随着瘦素浓度的增加和作用时间的延长, Caspase-3的活性逐渐增高, 至48 h时达到高峰。说明瘦素可以直接诱导脂肪间充质干细胞凋亡, 从数量上减少脂肪组织的含量。     

The role of the sympathetic nervous system in the regulation of leptin synthesis in C57BL/6 mice

The objectives of this study were to determine whether leptin synthesis is regulated by the sympathetic nervous system and if so whether beta-adrenergic receptors mediate this effect. We show that sympathetic blockade by reserpine increases leptin mRNA levels in brown but not white adipose tissue, while acute cold-exposure decreases leptin expression 10-fold in brown adipose tissue and 2-fold in white adipose tissue. The cold-induced reduction in leptin mRNA can be prevented by a combination of propranolol and SR 59230A but not by either antagonist alone, indicating that beta3-adrenergic receptors and classical beta1/beta2-adrenergic receptors both mediate responses to sympathetic stimulation. Circulating leptin levels reflect synthesis in white adipose tissue but not in brown adipose tissue.     

Evidence that triiodothyronine decreases rat serum leptin concentration by down-regulation of leptin gene expression in white adipose tissue

Conflicting results have been reported regarding the effect of triiodothyronine (T(3)) on serum leptin and adipose tissue leptin gene expression in human and animals. The aim of the present study was to evaluate the effect of administration of increasing doses of T(3) on serum leptin concentration and on leptin mRNA abundance in white adipose tissue of rats. The results presented in this paper indicate that administration of single different doses of T(3) to euthyroid rats resulted dose dependent increases of serum total T(3) concentrations which are associated with a decrease in white adipose tissue leptin mRNA level. The leptin mRNA level in white adipose tissue was negatively correlated with serum total T(3) concentration (r=-0.8, p<0.001). Like white adipose tissue leptin mRNA level, serum leptin concentration decreased after T(3) administration, and was also negatively correlated with the serum T(3) concentration (r=-0.8, p<0.001). In contrast, administration of T(3) to the same rats led to a significant increase in white adipose tissue expression of the malic enzyme gene (malic enzyme activity and malic enzyme mRNA level), a known target gene for T(3). The results indicate that T(3) exerts a selective inhibitory effect on white adipose tissue leptin gene expression in vivo. A conclusion is that T(3) decreases rat serum leptin concentration by down-regulation of leptin gene expression in white adipose tissue.