Intracerebroventricular Injection Of Leptin Research Articles

Interaction between leptin and glutamatergic system on food intake regulation in neonatal chicken: role of NMDA and AMPA receptors

Objective: The aim of the current study was to determine the possible interaction of the central leptin and Glutamatergic systems on feeding behavior in neonatal 3-hours food deprived (FD3) broilers chickens.Methods: In experiment 1, FD3 chicken received intracerebroventricular (ICV) injection of control solution (group i) and 2.5, 5 and 10 µg of Leptin (groups ii–iv). In experiment 2, FD3 chicken were ICV injected with (group i) control solution and groups ii–iv with 2.5, 5 and 10 nmol of AG-490 (JAK2 antagonist). In experiment 3, injections were (i) control solution, (ii) Leptin (10 µg), (iii) AG-490 (2.5 nmol) and (iv) Leptin + AG-490. In experiment 4, broiler chickens were ICV injected with (i) control solution, (ii) Leptin (10 µg), (iii) MK-801 (NMDA glutamate receptors antagonist; 15 nmol) and (iv) Leptin + MK-801. Experiments 5–9 were similar to experiment 1, except chicken were ICV injected with CNQX (AMPA receptor antagonist, 390 nmol), UBP-302 (Kainate receptor antagonist, 390 nmol), AIDA (mGluR1 antagonist, 2 nmol), LY341495 (mGluR2 antagonist, 150 nmol) and UBP1112 (mGluR3 antagonist, 2 nmol) instead of MK-801. Then, food intake was measured until 120 min after injection.Results: ICV injection of leptin (2.5, 5 and 10 µg) significantly decreased food intake in a dose dependent manner (p < 0.05). Also, ICV injection of the JAK2 antagonist (2.5, 5 and 10 nmol) had hyperphagic effect in chicken (p < 0.05). Co-administration of leptin + AG-490, partially decreased leptin-induced hypophagia in broiler chicken (p < 0.05). In addition, co-injection of leptin + MK-801 significalty inhibited leptin-induced hypophagia in neonatal chicken (p < 0.05). Also, co-administration of leptin + CNQX partially attenuated hypophagic effect of leptin in chicken (p < 0.05).Conclusion: The results of present study suggest that leptin has hypophagic effect in neonatal chicken and this effect is probably mediated via NMDA and AMPA glutamatergic receptors.

MicroRNA-7 inhibits melatonin synthesis by acting as a linking molecule between leptin and norepinephrine signaling pathways in pig pineal gland.

MicroRNAs, including microRNA-7 (miR-7), are important modulators of numerous gene expressions and the related biological processes. Melatonin is a key hormone regulating daily and seasonal rhythms, in which a variety of positive and negative regulatory factors, such as norepinephrine (NE) and leptin, are involved. However, the interactions among these factors and the mechanisms remain to be elucidated. The aims of the present study were to identify the functions and the related mechanisms of miR-7 in regulating melatonin synthesis and secretion through in vitro and in vivo experiments in pineal gland of pigs, which is an important animal model for agricultural and biomedical studies. Our results firstly show that miR-7 is specifically expressed in porcine pinealocytes and negatively regulates melatonin synthesis. The further functional studies show that the dynamic expression levels of miR-7 are contrary to the melatonin levels throughout the day, and the forced inhibition of endogenous miR-7 in porcine pinealocytes sharply increases arylalkylamine N-acetyltransferase (AANAT) expression by 80.0% (P=0.0031) and melatonin levels by 81.0% (P=0.0421), whereas miR-7 over-expression down-regulates AANAT expression by 38.6% (P=0.0004) and melatonin levels by 37.6% (P=0.0212). In addition, the miR-7 expression is up-regulated by leptin through the JAK/STAT3 signaling pathway, and the in vivo intracerebroventricular injection of leptin increases miR-7 expression by 80.0% (P=0.0044) in porcine pineal glands and reduces melatonin levels by 57.1% (P=0.0060) compared with the controls. This functional inhibition of melatonin synthesis by miR-7 is accomplished by its binding to the 3'-UTR of Raf1. Further, our results demonstrate that the RAF1/MEK/ERK signaling pathway mediates NE-induced AANAT expression, whereas leptin attenuates NE's function through miR-7. Taken together, the results demonstrated that leptin activates the JAK/STAT3 signaling pathway to increase the expression of miR-7, which acts as a negative regulatory molecule inhibiting NE-activated RAF1/MEK/ERK signaling pathway by targeting Raf1, resulting in decreased AANAT expression and melatonin synthesis. These findings suggest that miR-7 is a novel negative regulator of melatonin synthesis and links leptin- and NE-mediated signaling pathways in porcine pineal glands, which will contribute to our understanding in the establishment of the biological rhythms resulting from melatonin.

Central Injection of Leptin Increases Sympathetic Nerve Outflows to the Stomach and Spleen in Anesthetized Rats.

Leptin, one of the hormones produced in white adipose tissue, is an efferent sympathetic stimulator. Actually, an injection of leptin into the brain has been shown to activate sympathetic nerve activities innervating the kidney, adrenal gland, adipose tissues, liver, and lumbar in rats. This study investigated the effects of an intracerebroventricular injection of leptin on the activities of sympathetic nerves innervating the stomach and spleen in anesthetized rats. Leptin injection activated the neural activities of sympathetic traffic to both the stomach and spleen. In addition, to investigate the role of AMP-activated protein kinase (AMPK), the effects of 5-aminoimidazole-4-carboxamide 1-beta-D-ribofuranoside (AICAR), an AMPK activator, or compound C, an AMPK inhibitor, on leptin-induced sympathoexcitation, were assessed. Central pretreatment with AICAR or compound C eliminated not only leptin-induced gastric sympathoexcitation but also leptin-induced splenic sympathoexcitation. Leptin stimulates efferent sympathetic outflow to the stomach and spleen through the hypothalamic AMPK.

Functional interleukin-6 receptor-α is located in tanycytes at the base of the third ventricle.

Interleukin (IL)‐6−/− mice develop mature onset obesity, whereas i.c.v. injection of IL‐6 decreases obesity in rodents. Moreover, levels of IL‐6 in cerebrospinal fluid (CSF) were reported to be inversely correlated with obesity in humans. Tanycytes lining the base of the third ventricle (3V) in the hypothalamus have recently been reported to be of importance for metabolism. In the present study, we investigated whether tanycytes could respond to IL‐6 in the CSF. With immunohistochemistry using a well characterised antibody directed against the ligand binding receptor for IL‐6, IL‐6 receptor α (IL‐6Rα), it was found that tanycytes, identified by the two markers, vimentin and dopamine‐ and cAMP‐regulated phosphoprotein of 32 kDa, contained IL‐6Rα. There were fewer IL‐6Rα on another type of ventricle‐lining cells, ependymal cells, as identified by the marker glucose transporter‐1. To demonstrate that the immunoreactive IL‐6Rα were responsive to IL‐6, we injected IL‐6 i.c.v. This treatment increased immunoreactive phosphorylated signal transducer and activator of transcription‐3 (pSTAT3) in tanycytes after 5 minutes and in cells in the medial part of the arcuate nucleus after 5 and 15 minutes. Intracerebroventricular injection of leptin exerted similar effects. As expected, i.p. injection of leptin also induced pSTAT3 staining in the hypothalamus, whereas i.p. IL‐6 injection had little effect on this parameter. Intracerebroventricular or i.p. injection of vehicle only had no effect on pSTAT3‐immunoreactivity. In summary, there are functional IL‐6Rα on tanycytes at the bottom of the 3V, in agreement with the possibility that ventricular administration of IL‐6 decreases obesity in mice via an effect on this cell type.

Leptin Controls Parasympathetic Wiring of the Pancreas during Embryonic Life.

The autonomic nervous system plays a critical role in glucose metabolism through both its sympathetic and parasympathetic branches, but the mechanisms that underlie the development of the autonomic innervation of the pancreas remain poorly understood. Here, we report that cholinergic innervation of pancreatic islets develops during mid-gestation under the influence of leptin. Leptin-deficient mice display a greater cholinergic innervation of pancreatic islets beginning in embryonic life, and this increase persists into adulthood. Remarkably, a single intracerebroventricular injection of leptin in embryos caused a permanent reduction in parasympathetic innervation of pancreatic β cells and long-term impairments in glucose homeostasis. These developmental effects of leptin involve a direct inhibitory effect on the outgrowth of preganglionic axons from the hindbrain. These studies reveal an unanticipated regulatory role of leptin on the parasympathetic nervous system during embryonic development and may have important implications for our understanding of the early mechanisms that contribute to diabetes.

Role of the Paraventricular Nucleus of the Hypothalamus in the Sympathoexcitatory Effects of Leptin.

Leptin binds to receptors in multiple hypothalamic nuclei to increase sympathetic nerve activity; however, the neurocircuitry is unclear. Here, using anesthetized male Sprague-Dawley rats, we investigated the role of the paraventricular nucleus of the hypothalamus. Intracerebroventricular injection of leptin slowly increased lumbar sympathetic nerve activity (LSNA), heart rate, mean arterial pressure, and baroreflex control of LSNA and heart rate. Inhibition of the paraventricular nucleus with muscimol completely reversed leptin's effects. Blockade of paraventricular melanocortin 3/4 receptors with SHU9119 or ionotropic glutamate receptors with kynurenate, alone or together, each partially reversed the effects of leptin, implicating increased activation of glutamate and melanocortin 3/4 receptors. Conversely, although blockade of neuropeptide Y Y1 receptors in the paraventricular nucleus increased LSNA, mean arterial pressure, and heart rate, these responses were prevented by intracerebroventricular or arcuate nucleus injections of leptin, suggesting that, at least in part, leptin also increases sympathetic nerve activity by suppression of tonic neuropeptide Y inhibitory inputs from the arcuate nucleus. Injection of the melanocortin 3/4 receptor agonist melanotan-II into the paraventricular nucleus increased LSNA, mean arterial pressure, and heart rate only after blockade of neuropeptide Y Y1 receptors. Therefore, we conclude that leptin increases LSNA in part via increased glutamatergic and α-melanocyte-stimulating hormone drive of paraventricular sympathoexcitatory neurons, the latter of which requires simultaneous withdrawal of tonic neuropeptide Y inhibition.

Leptin attenuates the detrimental effects of β-amyloid on spatial memory and hippocampal later-phase long term potentiation in rats

β-Amyloid (Aβ) is the main component of amyloid plaques developed in the brain of patients with Alzheimer's disease (AD). The increasing burden of Aβ in the cortex and hippocampus is closely correlated with memory loss and cognition deficits in AD. Recently, leptin, a 16kD peptide derived mainly from white adipocyte tissue, has been appreciated for its neuroprotective function, although less is known about the effects of leptin on spatial memory and synaptic plasticity. The present study investigated the neuroprotective effects of leptin against Aβ-induced deficits in spatial memory and in vivo hippocampal late-phase long-term potentiation (L-LTP) in rats. Y maze spontaneous alternation was used to assess short term working memory, and the Morris water maze task was used to assess long term reference memory. Hippocampal field potential recordings were performed to observe changes in L-LTP. We found that chronically intracerebroventricular injection of leptin (1μg) effectively alleviated Aβ1–42 (20μg)-induced spatial memory impairments of Y maze spontaneous alternation and Morris water maze. In addition, chronic administration of leptin also reversed Aβ1–42-induced suppression of in vivo hippocampal L-LTP in rats. Together, these results suggest that chronic leptin treatments reversed Aβ-induced deficits in learning and memory and the maintenance of L-LTP.

Dissociating the Metabolic and Cardiovascular Effects of Leptin Through mTORC1 Signaling

Leptin is an adipocyte‐derived hormone which acts in the brain to regulate energy homeostasis by suppressing appetite and increasing energy expenditure. Leptin also promotes arterial pressure elevation by increasing sympathetic nerve activity (SNA). Recent evidences indicate that the mechanistic target of rapamycin complex 1 (mTORC1) plays a key role in mediating the metabolic and sympathetic effects of leptin. To test the consequence of disrupting mTORC1 on leptin actions, we conditionally deleted Raptor, a critical subunit of mTORC1, in leptin receptor (LRb) expressing cells using genetically modified mice in which the Raptor gene is flanked by Lox‐P sites (Raptorfl/fl) and Cre recombinase driven by the LRb promoter (LRbCre). We measured body weight weekly from 4 weeks of age and observed no differences between LRbCre/Raptorfl/fl and control littermates (29.6±0.8g vs 31.0±0.8g at 14 weeks). Additionally, food intake and body weight were recorded daily at baseline and after treatment with vehicle or leptin (1mg/g bw, intraperitoneally, twice daily) for 4 days. We found no significant difference in the cumulative decrease in food intake (‐1.6±0.8g vs ‐1.1±1.7g) or body weight (‐5.9±0.8% vs ‐5.7±0.7%) caused by leptin between LRbCre/Raptorfl/fl mice and WT littermates. Finally, we performed multifiber nerve recordings of renal SNA to determine the contribution of mTORC1 to the cardiovascular sympathetic action of leptin. Interestingly, intracerebroventricular injection of leptin (2 mg) increased renal SNA in control mice (106±20%), but not in LRbCrexRaptorfl/fl mice (‐28±11%, P&lt;0.05 vs controls). We concluded that mTORC1 is necessary for the renal SNA effect of leptin, but not critical for the metabolic actions of leptin.

Intracellular Renin in the Brain Contributes to Cardiovascular and Metabolic Control

Renin gene expression is regulated by two distinct promoter‐first exon combinations that target renin either for secretion (exon 1a initiates secreted renin) or cytoplasmic retention (exon 1b initiates intracellular renin, icREN). Interestingly, icREN is expressed predominantly in the brain. We selectively deleted exon 1b and developed icREN KO mice to examine the role of icREN in cardiovascular and metabolic control. Systolic blood pressure in the light phase as measured by telemetry was increased in KO mice (126±2 mmHg, n=8 vs 116±2 mmHg, n=7, P&lt;0.01). The low‐ to high‐frequency ratio (LF/HF) derived from power spectral analysis of heart rate variability was increased in KO mice (1.24±0.21, n=7 vs 0.70±0.11, n=7, P&lt;0.05). Body weight was normal in KO mice fed normal chow. However, high fat diet‐induced obesity was attenuated in male KO mice (body weight, 32.4±1.3 g, n=5 vs 36.6±1.4 g, n=9; relative fat mass, 26.1±2.3 %, n=5 vs 34.4±2.3 %, n=9, both P&lt;0.05). The resting metabolic rate measured by respirometry was increased in KO mice (0.156±0.005 kcal/h, n=46, P&lt;0.05) vs controls (0.145±0.003 kcal/h, n=53). We previously reported that the brain renin‐angiotensin system facilitates renal sympathetic nerve activity (RSNA) response to acute intracerebroventricular injection of leptin. Interestingly, the RSNA response to leptin was greater in KO mice compared to controls (214±40 % baseline, n=5 vs 114±18 % baseline, n=10, P&lt;0.01). Further, in KO mice, AT1a receptor mRNA was upregulated in the paraventricular nucleus (P&lt;0.05). These data suggest that this novel icREN isoform contributes to cardiovascular and metabolic control possibly through the modulation of AT1a receptor expression in the brain.

Pre-pubertal serum leptin levels and sensitivity to central leptin injection of prenatally undernourished female rats

It has been reported that intrauterine undernutrition is closely associated with the pathogeneses of certain diseases in adulthood; i.e., insulin resistance and diabetes, and that leptin resistance plays a pivotal role in the pathology of such intrauterine growth restriction (IUGR)-related conditions. Therefore, examinations of IUGR-induced leptin resistance in early developmental period are important for protecting against future disease. In this study, the effects of prenatal undernutrition on the serum leptin levels and central leptin responses of rats during the neonatal and/or pre-pubertal period were examined. The 50% food-restricted undernourished dams’ offspring (UNO) exhibited a significantly lower birth weight than the normal nutrition dams’ offspring (NNO). However, the UNO grew rapidly, and their mean body weight had caught up with that of the NNO by postnatal day 8. Thus, there were no significant differences between the body weights of the two groups at postnatal day 12, 16, 20, or 28. The serum leptin levels of the UNO were significantly higher than those of the NNO at postnatal days 20 and 28. At postnatal day 28, no significant difference in the hypothalamic mRNA level of neuropeptide Y, which is the main target of leptin, or that of ObRb, which is the leptin receptor, was detected between the NNO and UNO. The chronic intracerebroventricular injection of leptin attenuated body weight gain in both the NNO and UNO; however, there were no significant differences between the body weights of the two groups at any of the examined postnatal time points, indicating that the UNO and NNO exhibited similar central sensitivity to leptin during the pre-pubertal period. These results suggest that prenatal undernutrition induces leptin resistance until the neonatal to pre-pubertal period and that these alterations might be caused by impaired transportation of leptin to central tissues.

Early postweaning exercise improves central leptin sensitivity in offspring of rat dams fed high-fat diet during pregnancy and lactation.

Maternal high-fat (HF) diet has long-term consequences on the metabolic phenotype of the offspring. Here, we determined the effects of postweaning exercise in offspring of rat dams fed HF diet during gestation and lactation. Pregnant Sprague-Dawley rats were maintained on chow or HF diet throughout gestation and lactation. All pups were weaned onto chow diet on postnatal day (PND) 21. At 4 wk of age, male pups were given free access to running wheels (RW) or remained sedentary (SED) for 3 wk, after which all rats remained sedentary, resulting in four groups: CHOW-SED, CHOW-RW, HF-SED, and HF-RW. Male HF offspring gained more body weight by PND7 compared with CHOW pups and maintained this weight difference through the entire experiment. Three weeks of postweaning exercise did not affect body weight gain in either CHOW or HF offspring, but reduced adiposity in HF offspring. Plasma leptin was decreased at the end of the 3-wk running period in HF-RW rats but was not different from HF-SED 9 wk after the exercise period ended. At 14 wk of age, intracerebroventricular injection of leptin suppressed food intake in CHOW-SED, CHOW-RW, and HF-RW, while it did not affect food intake in HF-SED group. At death, HF-RW rats also had higher leptin-induced phospho-STAT3 level in the arcuate nucleus than HF-SED rats. Both maternal HF diet and postweaning exercise had effects on hypothalamic neuropeptide and receptor mRNA expression in adult offspring. Our data suggest that postweaning exercise improves central leptin sensitivity and signaling in this model.

Phosphatidylinositol 3‐kinase is an Upstream Regulator of the Phosphodiesterase 3B Pathway of Leptin Signalling that may not Involve Activation of Akt in the Rat Hypothalamus

Leptin, the product of the obese gene, regulates energy homeostasis by acting primarily at the level of the hypothalamus. Leptin action through its receptor involves various pathways, including the signal transducer and activator of transcription (STAT)3, phosphatidylinositol 3-kinase (PI3K), and phosphodiesterase 3B (PDE3B)-cAMP signalling in the central nervous system and peripheral tissues. In the hypothalamus, leptin stimulates STAT3 activation, and induces PI3K and PDE3B activities, among others. We have previously demonstrated that PDE3B activation in the hypothalamus is critical for transducing the anorectic and body weight reducing effects of leptin. Similarly, PI3K has been implicated to play a critical role in leptin signalling in the hypothalamus. Although, in the insulin signalling pathway, PI3K is known to be an upstream regulator of PDE3B in non-neuronal tissues, it is still unknown whether this is also the case for leptin signalling in the hypothalamus. To address this possibility, the effect of wortmannin, a specific PI3K inhibitor, was examined on leptin-induced PDE3B activity in the hypothalamus of male rats. Intracerebroventricular injection of leptin (4 μg) significantly increased PDE3B activity by two-fold in the hypothalamus as expected. However, previous administration of wortmannin completely reversed the stimulatory effect of leptin on PDE3B activity in the hypothalamus. To investigate whether leptin stimulates phospho (p)-Akt levels and that there might be a possible upstream regulator of PDE3B, we examined the effects of i.c.v. leptin on p-Akt levels in the hypothalamus and compared them with the known stimulatory effect of insulin on p-Akt. We observed that insulin increased p-Akt levels but leptin failed to do so, although it increased p-STAT3 levels, in the rat hypothalamus. Immunocytochemistry confirmed the biochemical findings in that leptin failed but insulin increased the number of p-Akt positive cells in various hypothalamic nuclei. Taken together, these results implicate PI3K but not Akt as an upstream regulator of the PDE3B pathway of leptin signalling in the rat hypothalamus.

Role of Central Leptin Signaling in the Starvation-Induced Alteration of B-Cell Development

Nutritional deprivation or malnutrition suppresses immune function in humans and animals, thereby conferring higher susceptibility to infectious diseases. Indeed, nutritional deprivation induces atrophy of lymphoid tissues such as thymus and spleen and decreases the number of circulating lymphocytes. Leptin, a major adipocytokine, is exclusively produced in the adipose tissue in response to the nutritional status and acts on the hypothalamus, thereby regulating energy homeostasis. Although leptin plays a critical role in the starvation-induced T-cell-mediated immunosuppression, little is known about its role in B-cell homeostasis under starvation conditions. Here we show the alteration of B-cell development in the bone marrow of fasted mice, characterized by decrease in pro-B, pre-B, and immature B cells and increase in mature B cells. Interestingly, intracerebroventricular leptin injection was sufficient to prevent the alteration of B-cell development of fasted mice. The alteration of B lineage cells in the bone marrow of fasted mice was markedly prevented by oral administration of glucocorticoid receptor antagonist RU486 (11β-[p-(dimethylamino)phenyl]-17β-hydroxy-17-(1-propynyl)estra-4,9-dien-3-one). It was also effectively prevented by intracerebroventricular injection of neuropeptide Y Y(1) receptor antagonist BIBP3226 [(2R)-5-(diaminomethylideneamino)-2-[(2,2-diphenylacetyl)amino]-N-[(4-hydroxyphenyl)methyl]pentanamide], along with suppression of the otherwise increased serum corticosterone concentrations. This study provides the first in vivo evidence for the role of central leptin signaling in the starvation-induced alteration of B-cell development. The data of this study suggest that the CNS, which is inherent to integrate information from throughout the organism, is able to control immune function.

Cardiovascular and Sympathetic Effects of Disrupting Tyrosine 985 of the Leptin Receptor

Leptin acts in the brain to regulate food intake and energy expenditure. Leptin also increases renal sympathetic nerve activity and arterial pressure. The divergent signaling capacities of the leptin receptor (ObRb) mediate the stimulation of various intracellular pathways that are important for leptin control of physiological processes. We evaluated the cardiovascular and sympathetic consequences of disrupting the signal emanating from tyrosine985 of ObRb. For this, we used Lepr(L985) (l/l) mice, which carry a loss of function mutation replacing tyrosine985 of ObRb with leucine. Body weight of l/l mice was not significantly different from wild-type controls. In contrast, radiotelemetry measurements revealed that the l/l mice had higher arterial pressure and heart rate as compared with controls. Ganglionic blockade caused a greater arterial pressure fall in the l/l mice relative to controls. In addition, leptin treatment induced a larger increase in arterial pressure and heart rate in the l/l versus wild-type mice. Finally, we compared the response of renal and brown adipose tissue sympathetic nerve activity to intracerebroventricular injection of leptin (2 μg) between l/l and control mice. Leptin-induced increase in renal sympathetic nerve activity was greater in l/l mice relative to controls. In contrast, the brown adipose tissue sympathetic nerve activity response to leptin was attenuated in the l/l mice relative to controls. These data indicate that selective loss of leptin receptor signaling emanating from tyrosine985 enhances the cardiovascular and renal sympathetic effects of leptin. These findings provide important insight into the molecular mechanisms underlying leptin's effects on the sympathetic cardiovascular function and arterial pressure.

Letter by Landa et al Regarding Article, “Protein Tyrosine Phosphatase 1B, a Major Regulator of Leptin-Mediated Control of Cardiovascular Function”

Fil: Landa, Maria Silvina. Consejo Nacional de Investigaciones Cientificas y Tecnicas. Oficina de Coordinacion Administrativa Houssay. Instituto de Investigaciones Medicas; Argentina. Universidad de Buenos Aires. Facultad de Medicina. Instituto de Investigaciones Medicas; Argentina

Decreased blood–brain leptin transfer in an ovine model of obesity and weight loss: resolving the cause of leptin resistance

Hypothalamic resistance to the anorexigenic actions of the peripheral adipostat hormone leptin is characteristic of obesity. Here, we use an obese animal model of similar body weight to that of the human to test in vivo whether leptin resistance is due to decreased blood-brain leptin transport or intra-hypothalamic insensitivity, and whether sensitivity to leptin is restored by weight loss. For 40 weeks, adult sheep surgically prepared with intra-cerebroventricular (ICV) cannulae were given a complete natural diet ad libitum ('Obese' group) or in restricted quantities ('Lean' group), and then the dietary amounts were reversed for 16 weeks until mean group body weights converged ('Slimmers' and 'Fatteners', respectively). ICV leptin injection (0.5 mg) at 8-week intervals acutely decreased voluntary food intake by approximately 35% in the 'Obese' group on each occasion and in 'Slimmers' and 'Fatteners' at the end, providing no evidence of intra-hypothalamic insensitivity. The ratio between endogenous leptin concentrations in ventricular cerebrospinal fluid (CSF) and peripheral blood decreased with increasing leptinaemia in 'Obese' sheep, indicating decreased efficiency of blood-brain leptin transport, whereas leptin concentrations remained low and the CSF:blood ratio remained high in 'Lean' sheep. Compared with 'Fatteners' of similar body weight, 'Slimmers' were hypoleptinaemic, but their CSF:blood leptin concentration ratio remained low. Thus, the obesity-induced impairment of leptin blood-brain transport was sustained despite an approximately 15% weight loss. These results support the hypothesis that central resistance to leptin in obesity with associated peripheral hyperleptinaemia is attributable to decreased efficiency of leptin transport into the brain and not to intra-hypothalamic leptin insensitivity. However, leptin transport efficiency is not restored after weight loss by caloric restriction despite the prevailing hypoleptinaemia.

Intracerebroventricular injection of leptin inhibits gastric emptying but has no effect on intestinal transit in rats

Intracerebroventricular injection of leptin inhibits gastric emptying but has no effect on intestinal transit in rats

Mechanisms mediating renal sympathetic activation to leptin in obesity

Leptin plays a critical role in the control of energy homeostasis. The sympathetic cardiovascular actions of leptin have emerged as a potential link between obesity and hypertension. We previously demonstrated that in mice, modest obesity induced by 10 wk of a high-fat diet is associated with preservation of leptin ability to increase renal sympathetic nerve activity (SNA) despite the resistance to the metabolic effects of leptin. Here, we examined whether selective leptin resistance exists in mice with late-stage diet-induced obesity (DIO) produced by 20 wk of a high-fat diet. The decrease in food intake and body weight induced by intraperitoneal or intracerebroventricular injection of leptin was significantly attenuated in the DIO mice. Regional SNA responses to intravenous leptin were also attenuated in DIO mice. In contrast, intracerebroventricularly administered leptin caused contrasting effects on regional SNA in DIO mice. Renal SNA response to intracerebroventricular leptin was preserved, whereas lumbar and brown adipose tissue SNA responses were attenuated. Intact renal SNA response to leptin combined with the increased cerebrospinal fluid leptin levels in DIO mice represents a potential mechanism for the adverse cardiovascular consequences of obesity. Lastly, we examined the role of phosphoinositol-3 kinase (PI3K) and melanocortin receptors (MCR) in mediating the preserved renal SNA response to leptin in obesity. Presence of PI3K inhibitor (LY294002) or MC3/4R antagonist (SHU9119) significantly attenuated the renal SNA response to leptin in DIO and agouti obese mice. Our results demonstrate the importance of PI3K and melanocortin receptors in the transduction of leptin-induced renal sympathetic activation in obesity.

Leptin inhibits and ghrelin augments hypothalamic noradrenaline release after stress

Metabolic conditions affect hypothalamo-pituitary-adrenal responses to stressful stimuli. Here we examined effects of food deprivation, leptin and ghrelin upon noradrenaline release in the hypothalamic paraventricular nucleus (PVN) and plasma adrenocorticotropic hormone (ACTH) concentrations after stressful stimuli. Food deprivation augmented both noradrenaline release in the PVN and the increase in plasma ACTH concentration following electrical footshocks (FSs). An intracerebroventricular injection of leptin attenuated the increases in hypothalamic noradrenaline release and plasma ACTH concentrations after FSs, while ghrelin augmented these responses. These data suggest that leptin inhibits and ghrelin facilitates neuroendocrine stress responses via noradrenaline release and indicate that a decrease in leptin and an increase in ghrelin release after food deprivation might contribute to augmentation of stress-induced ACTH release in a fasting state.

The Long Form of the Leptin Receptor Regulates STAT5 and Ribosomal Protein S6 via Alternate Mechanisms

The action of leptin via the long form of its receptor (LepRb) is central to the control of body energy homeostasis and neuroendocrine function, but the mechanisms by which LepRb regulates intracellular signaling have remained incompletely understood. Here we demonstrate that leptin stimulates the phosphorylation of STAT5 and ribosomal protein S6 in the hypothalamic arcuate nucleus in mice. In cultured cells, we investigate the mechanisms by which leptin regulates each of these pathways. Our analysis reveals a dominant role for LepRb Tyr(1077) (which we demonstrate to be phosphorylated during receptor activation) and a secondary role for LepRb Tyr(1138) in the acute phosphorylation of STAT5a and STAT5b. Tyr(1138) and STAT3 attenuate STAT5-dependent transcription over the long-term, however. In contrast, Tyr(985) (the LepRb phosphorylation site required for ERK activation) mediates the phosphorylation of the ribosomal S6 kinase (RSK) and S6, as well as cap-dependent translation. Thus, these data demonstrate the phosphorylation of Tyr(1077) on LepRb during receptor activation, substantiate the hypothalamic regulation of STAT5 and S6 by leptin, and define the alternate LepRb signaling pathways that mediate each of these signals and their effects in cultured cells. Dissecting the contributions of these individual pathways to leptin action will be important for our ultimate understanding of the processes that regulate energy balance in vivo.