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Query: UMLS:C0011849 (diabetes)
 277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Leptin is the product of OB gene. This 16 kDa protein is produced by mature adipocytes and is secreted in plasma. Its plasma levels are strongly correlated with adipose mass in rodents as well as in humans. Leptin inhibits food intake, reduces body weight and stimulates energy expenditure. It has been suggested that leptin could be the link between obesity and diabetes. Recent experiments in rodents have shown that leptin expression in adipocytes is also regulated at short-term by hormones and nutrients. Leptin expression increases after food intake and decreases during fasting and diabetes. Insulin and glucocorticoids increase leptin expression, whereas catecholamines, via beta-adrenergic receptors and cAMP, and long-chain fatty acids (and thiazolidinediones), via PPARy, inhibit leptin expression. Leptin is a cytokine that binds to transmembrane receptors similar to the receptors of cytokine family (type IL-6), and transmit their information inside the cell, after dimerisation. A short-form of leptin receptor (with a cytoplasmic domain of 34 amino residues) has been identified in the choroid plexus. This type of receptor should be used for leptin transport across the blood-brain barrier. Then leptin binds to a long-form of leptin receptor in the hypothalamus (with a cytoplasmic domain of 302 amino residues) and decreases the production of neuropeptide Y, a neuromediator of food intake. The long-form of leptin receptor, transmits its information via the Janus Kinases (JAK) who subsequently phosphorylate transcription factors of the STAT family. Intermediary forms of leptin receptor have been identified in other tissues: liver, heart, skeletal muscles, endocrine pancreas. The role of leptin receptors in these tissues remains obscure, but is of considerable interest. Recent studies have shown that leptin inhibits insulin secretion and have anti-insulin effects on liver and adipose tissue. If these effects are confirmed, leptin could play a role similar to TNF alpha and could participate in the insulin-resistance of obesity and type II diabetes.
Diabetes Metab 1997 Sep
PMID:Is leptin the link between obesity and insulin resistance? 934 38

The fat-derived hormone, leptin, is thought to regulate adipose tissue mass by acting on the brain to reduce food intake and increase thermogenesis. We have produced obesity in rats more than 8 weeks old by feeding a high-calorie diet and have then examined the inhibitory effect of intracerebroventricularly injected recombinant murine leptin on their food intake versus control rats. In control rats, randomized injections of leptin (0.5, 2.0, or 10.0 microg) or sterile saline vehicle into the lateral ventricle produced a dose-dependent reduction in normal laboratory diet consumed 1, 4, and 24 h after the lights were turned off. However, in diet-induced obesity, the dose-dependent inhibition of food intake was observed at 1 h only, and the effect was attenuated. Switching the diet-induced obese rats to a normal laboratory diet 1 week before injections of leptin were commenced resulted in a reduction in the daily food consumption. These data suggest that rats made obese by feeding a high-calorie diet override the normal satiety effects of leptin since when they are returned to a normal laboratory diet, they reduce their calorie intake, possibly as a result of a restoration of the satiety effects of endogenous leptin. However, the fact that the hypophagic response to exogenous leptin is impaired in these rats at this time suggests some residual impairment of the satiety signal, perhaps caused by reduced receptor sensitivity and/or near total occupation of receptors by endogenous leptin molecules, levels of which are raised in plasma.
Diabetes 1997 Nov
PMID:Inhibition of food response to intracerebroventricular injection of leptin is attenuated in rats with diet-induced obesity. 935 26

Leptin, a hormone secreted by adipose tissue in proportion to body adiposity, is proposed to be involved in the central nervous regulation of food intake and body weight. In addition, evidence is emerging that leptin regulates neuroendocrine and metabolic functions as well, presumably via its action in the central nervous system (CNS). To investigate this regulatory effect of leptin, we infused 3.5 microg of human leptin directly into the third cerebral ventricle (i3vt) of lean male Long-Evans rats, 90 min before the onset of their dark phase. Before and after infusion, blood samples were withdrawn through indwelling catheters for assessment of hormonal (plasma corticosterone, insulin, leptin), autonomic (plasma norepinephrine, epinephrine), and metabolic (plasma glucose) parameters. I3vt leptin caused an increase in plasma corticosterone and plasma leptin levels relative to the control condition. The effects of i3vt leptin on corticosterone secretion became particularly apparent after the onset of the dark phase. The results of the present study indicate that i3vt leptin stimulates the hypothalamo-pituitary-adrenal (HPA) axis, particularly when rats normally encounter their largest meals. These results are consistent with the possibility that high circulating leptin levels may underlie the increased activity of the HPA axis that is generally characteristic of human obesity and most animal models of obesity.
Diabetes 1997 Nov
PMID:Central leptin stimulates corticosterone secretion at the onset of the dark phase. 935 47

The recently discovered ob gene and its circulating product, leptin, may be critical factors in the control of energy balance. Recent studies in ob/ob mice, which lack circulating leptin, have shown dramatic reductions in food intake and bodyweight after leptin treatment. In addition, studies in both humans with obesity and animal models of obesity have demonstrated hyperleptinemia. Here, we report a longitudinal study examining changes in circulating leptin during the development of obesity and diabetes in Psammomys obesus. Over the 8 weeks of the study, lean animals increased their bodyweight by 154% and leptin levels remained essentially unchanged. In contrast, animals that developed obesity (223% increase in bodyweight), hyperglycemia, and hyperinsulinemia also developed hyperleptinemia between 4 weeks and 8 weeks of age. These results demonstrate that the development of hyperleptinemia is associated with the development of obesity and subsequent metabolic abnormalities.
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PMID:Leptin and the development of obesity and diabetes in Psammomys obesus. 938 21

Obesity is associated with diabetes, and leptin is known to be elevated in obesity. To investigate whether leptin has a direct effect on insulin secretion, isolated rat and human islets and cultured insulinoma cells were studied. In all cases, mouse leptin inhibited insulin secretion at concentrations within the plasma range reported in humans. Insulin mRNA expression was also suppressed in the cultured cells and rat islets. The long form of the leptin receptor (OB-Rb) mRNA was present in the islets and insulinoma cell lines. To determine the significance of these findings in vivo, normal fed mice were injected with two doses of leptin. A significant decrease in plasma insulin and associated rise in glucose concentration were observed. Fasted normal and leptin receptor-deficient db/db mice showed no response to leptin. A dose of leptin, which mimicked that found in normal mice, was administered to leptin-deficient, hyperinsulinemic ob/ob mice. This caused a marked lowering of plasma insulin concentration and a doubling of plasma glucose. Thus, leptin has a powerful acute inhibitory effect on insulin secretion. These results suggest that the action of leptin may be one mechanism by which excess adipose tissue could acutely impair carbohydrate metabolism.
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PMID:Leptin rapidly suppresses insulin release from insulinoma cells, rat and human islets and, in vivo, in mice. 938 36

We have investigated the antidiabetic action of troglitazone in aP2/DTA mice, whose white and brown fat was virtually eliminated by fat-specific expression of diphtheria toxin A chain. aP2/DTA mice had markedly suppressed serum leptin levels and were hyperphagic, but did not gain excess weight. aP2/DTA mice fed a control diet were hyperlipidemic, hyperglycemic, and had hyperinsulinemia indicative of insulin-resistant diabetes. Treatment with troglitazone alleviated the hyperglycemia, normalized the tolerance to intraperitoneally injected glucose, and significantly decreased elevated insulin levels. Troglitazone also markedly decreased the serum levels of cholesterol, triglycerides, and free fatty acids both in wild-type and aP2/DTA mice. The decrease in serum triglycerides in aP2/DTA mice was due to a marked reduction in VLDL- and LDL-associated triglyceride. In skeletal muscle, triglyceride levels were decreased in aP2/DTA mice compared with controls, but glycogen levels were increased. Troglitazone treatment decreased skeletal muscle, but not hepatic triglyceride and increased hepatic and muscle glycogen content in wild-type mice. Troglitazone decreased muscle glycogen content in aP2/DTA mice without affecting muscle triglyceride levels. The levels of peroxisomal proliferator-activated receptor gamma mRNA in liver increased slightly in aP2/DTA mice and were not changed by troglitazone treatment. The results demonstrate that insulin resistance and diabetes can occur in animals without significant adipose deposits. Furthermore, troglitazone can alter glucose and lipid metabolism independent of its effects on adipose tissue.
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PMID:Troglitazone action is independent of adipose tissue. 938 57

The ob/ob mouse is genetically deficient in leptin and exhibits a phenotype that includes obesity and non-insulin-dependent diabetes mellitus. This phenotype closely resembles the morbid obesity seen in humans. In this study, we demonstrate that a single intramuscular injection of a recombinant adeno-associated virus (AAV) vector encoding mouse leptin (rAAV-leptin) in ob/ob mice leads to prevention of obesity and diabetes. The treated animals show normalization of metabolic abnormalities including hyperglycemia, insulin resistance, impaired glucose tolerance, and lethargy. The effects of a single injection have lasted through the 6-month course of the study. At all time points measured the circulating levels of leptin in the serum were similar to age-matched control C57 mice. These results demonstrate that maintenance of normal levels of leptin (2-5 ng/ml) in the circulation can prevent both the onset of obesity and associated non-insulin-dependent diabetes. Thus a single injection of a rAAV vector expressing a therapeutic gene can lead to complete and long-term correction of a genetic disorder. Our study demonstrates the long-term correction of a disease caused by a genetic defect and proves the feasibility of using rAAV-based vectors for the treatment of chronic disorders like obesity.
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PMID:Long-term correction of obesity and diabetes in genetically obese mice by a single intramuscular injection of recombinant adeno-associated virus encoding mouse leptin. 939 Nov 28

Tumor necrosis factor-alpha (TNF-alpha) production by adipocytes is elevated in obesity, as shown by increased adipose tissue TNF-alpha mRNA and protein levels and by increased circulating concentrations of the cytokine. Furthermore, TNF-alpha has distinct effects on adipose tissue including induction of insulin resistance, induction of leptin production, stimulation of lipolysis, suppression of lipogenesis, induction of adipocyte dedifferentiation, and impairment of preadipocyte differentiation in vitro. Taken together, these effects all tend to decrease adipocyte volume and number and suggest a role for TNF-alpha in limiting increase in fat mass. The aim of the present study was to determine if TNF-alpha could induce apoptosis in human adipose cells, hence delineating another mechanism by which the cytokine could act to limit the development of, or extent of, obesity. Cultured human preadipocytes and mature adipocytes in explant cultures were exposed in vitro to human TNF-alpha at varying concentrations for up to 24 h. Apoptosis was assessed using morphological (histology, nuclear morphology following acridine orange staining, electron microscopy) and biochemical (demonstration of internucleosomal DNA cleavage by gel electrophoresis and of annexin V staining using immunocytochemistry) criteria. In control cultures, apoptotic indexes were between 0 and 2.3% in all experiments. In the experimental systems, TNF-alpha induced apoptosis in both preadipocytes and adipocytes, with indexes between 5 and 25%. Therefore, TNF-alpha induces apoptosis of human preadipocytes and adipocytes in vitro. In view of the major metabolic role of TNF-alpha in human adipose tissue, and the knowledge that adipose tissue is dynamic (with cell acquisition via preadipocyte replication/differentiation and cell loss via apoptosis), these findings describe a further mechanism whereby adipose tissue mass may be modified by TNF-alpha.
Diabetes 1997 Dec
PMID:Tumor necrosis factor-alpha induces apoptosis of human adipose cells. 939 77

Glucagon-like peptide I (GLP-I) stimulates glucose-dependent insulin secretion and inhibits food intake in the central nervous system. Because leptin reduces food intake but inhibits insulin secretion, we examined leptin action in mice with a null mutation in the GLP-I receptor. Intracerebroventricular leptin administration inhibited food intake in both wild-type and GLP-I receptor (GLP-IR) -/- mice, and daily intraperitoneal administration of leptin for 2 weeks produced comparable reductions in food intake and body weight in control and GLP-IR -/- mice. Glucose tolerance was improved in both wild-type and GLP-IR -/- mice, whether pair fed or leptin treated; however, blood sugars were significantly lower in the leptin-treated GLP-IR -/- mice following oral glucose challenge (P < 0.01). Glucose-stimulated insulin was reduced in both pair-fed and leptin-treated mice (P < 0.01-0.001); however, insulin levels were significantly lower in leptin-treated versus pair-fed GLP-IR -/- mice (P < 0.01). A single leptin injection had no effect on glucose tolerance in GLP-IR -/- mice, but decreased hepatic PEPCK mRNA in both wild-type and GLP-IR -/- mice. The improvement in blood glucose excursion, despite lower levels of glucose-stimulated insulin in lean leptin-treated GLP-IR -/- mice, suggests that leptin may have beneficial effects on control of blood glucose in the absence of obesity. Furthermore, the greater effects of leptin on glucose and insulin in leptin-treated versus pair-fed GLP-IR -/- mice raises the possibility that disruption of GLP-I signaling modifies the sensitivity to leptin in vivo.
Diabetes 1997 Dec
PMID:Leptin sensitivity in nonobese glucagon-like peptide I receptor -/- mice. 939 91

Humans and rats tend to gain weight as they age. Leptin is one regulator of food intake and energy expenditure. To determine if the increase in adiposity with age is related to altered leptin gene expression, we assessed adiposity levels, leptin mRNA levels in epididymal and inguinal white adipose tissue (EWAT and IWAT), and uncoupling protein (UCP1) mRNA levels in interscapular brown adipose tissue (IBAT) from F344 x BN rats ages 3, 12, 18, 24, and 30 months (n = 8/age). Levels of adiposity determined by the adiposity index and the Lee index increased between ages 3 and 24 months, with a decrease at age 30 months. There were parallel increases with age in body weight, EWAT, and IWAT depot size up to age 24 months, followed by a nonsignificant decrease at age 30 months. Daily food intake was unchanged with age. In EWAT, leptin mRNA per microgram of RNA was unchanged with age, whereas in IWAT, it increased up to 24 months, then declined at 30 months. Total leptin mRNA levels in both IWAT and EWAT depots increased with age, peaking at age 24 months, and were correlated with adiposity. Serum leptin levels increased with age, also peaking at age 24 months, and were correlated with total leptin mRNA in WAT pads and adiposity. The rate of increase in serum leptin was greater than the increase in adiposity with age, suggesting contributions from both the increase in leptin expression per unit of WAT and the increase in WAT depot size. In addition, UCP1 mRNA levels in IBAT did not change with age. These data suggest that adiposity increases with age and cannot be attributed to increased food intake, impaired leptin gene expression, or decreased UCP1 mRNA level in IBAT. Furthermore, leptin gene expression in IWAT increases with age independent of increasing adiposity.
Diabetes 1997 Dec
PMID:Leptin gene expression increases with age independent of increasing adiposity in rats. 939 92


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