UNIPROT:P01189 - FACTA Search

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Query: UNIPROT:P01189 (beta-endorphin)
21,003 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Agouti-related protein (AGRP) is synthesized in the same neurones in the arcuate nucleus as neuropeptide Y (NPY), another potent orexigenic peptide. AGRP antagonizes the action of alpha-melanocyte stimulating hormone, a derivative of pro-opiomelanocortin (POMC) at the hypothalamic MC4 receptor to increase food intake. Although leptin has been shown to regulate Agrp/Npy and Pomc-expressing neurones, there are differences with respect to Agrp regulation in leptin receptor-deficient mice and rats. Unlike the obese leptin receptor-deficient db/db mouse, which exhibits upregulation of Agrp mRNA expression in the medial basal hypothalamus (MBH) compared to lean controls, the obese leptin receptor-deficient (faf; Koletsky) rat does not exhibit upregulation of Agrp expression. To determine whether this represents a general difference between leptin receptor-deficient mice and rats, neuropeptide gene expression was analysed in the MBH of lean and obese rats segregating for a different leptin receptor mutation, Leprfa (Zucker). Fasting in lean rats (+/fa) for 72 h significantly increased Agrp and Npy mRNA expression, and decreased Pomc mRNA expression as detected by a sensitive solution hybridization/S1 nuclease protection assay. Npy mRNA levels were significantly increased in fed obese fa/fa compared to lean rats, and further increased in the obese animals after fasting. In contrast, Agrp mRNA levels did not differ between fed lean and fed obese rats, and fasting did not significantly change Agrp levels in obese rats. To determine whether the change in Agrp expression that occurs with food deprivation in lean rats could be prevented by leptin replacement, Sprague-Dawley rats were fasted and infused via subcutaneous osmotic micropumps for 48 h with either saline or recombinant mouse leptin. Fasting significantly increased Agrp and Npy, and decreased Pomc mRNA levels. Leptin infusion almost completely reversed these changes such that there was no significant difference between the levels in the fasted rats and those that were fed ad libitum. Thus, in fasted lean rats, Agrp and Npy are upregulated in parallel when leptin levels fall and are downregulated by leptin infusion. By contrast, the absence of a functional leptin receptor results in the upregulation of Npy but not Agrp mRNA.
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PMID:Leptin regulation of Agrp and Npy mRNA in the rat hypothalamus. 1173 54

Leptin affects feeding, metabolism, and neuroendocrine status. It is now clearly established that the hypothalamus coordinates these responses, though the specific brain regions engaged by leptin remain unclear. We have used combinations of neuroanatomic techniques to identify candidate pathways in the central nervous system underlying leptin action. Leptin decreases body weight in part by activating the sympathetic nervous system, resulting in increased thermogenesis and energy expenditure. We investigated hypothalamic pathways underlying leptin's effects on stimulating the sympathetic nervous system. We found that leptin activates neurons in the retrochiasmatic area (RCA) and lateral arcuate nucleus (Arc) that innervate the sympathetic preganglionic neurons in the thoracic spinal cord and also contain cocaine- and amphetamine-regulated transcript (CART). We also found that CART neurons in the RCA and the Arc coexpress pro-opiomelanocortin (POMC) mRNA. Recent studies have reinforced the view that the lateral hypothalamic area (LHA) regulates food intake and body weight. Using retrograde tracing with leptin administration, we found retrogradely labeled cells in the Arc contained neuropeptide Y (NPY) mRNA or POMC mRNA. Following leptin administration, NPY cells in the Arc did not express Fos but expressed suppressor of cytokine signaling-3 (SOCS-3) mRNA. In contrast, leptin induced both Fos and SOCS-3 expression in POMC neurons, many of which also innervated the LHA. We suggest that leptin directly activates POMC/CART neurons that project to the LHA, the paraventricular hypothalamic nucleus (PVH), and spinal sympathetic preganglionic neurons. These projections link circulating leptin and neurons that regulate feeding behavior, energy expenditure, and body weight homeostasis.
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PMID:Hypothalamic pathways underlying the endocrine, autonomic, and behavioral effects of leptin. 1179 Apr 32

Leptin (LEP), the product of the ob gene is an adipose-tissue secreted hormone that acts to decrease caloric intake and increase energy expenditure. Some observations suggest the mutual relationship between leptin and blood ACTH levels. In the rat acute LEP administration enhances blood ACTH levels while prolonged treatment lowers blood corticotropin concentrations. Since the pituitary-derived ACTH is an important element in functioning of that loop, studies were undertaken to investigate the effect of prolonged LEP administration on anterior pituitary ACTH cells of adrenalectomized rats. Studies were performed on bilaterally adrenalectomized adult female rats. They were administered for 3 or 6 days with 2.7 nmol/rat/day LEP (recombinant human leptin) or with the vehicle (0.9% NaCl). LEP administration did not affect the body weight of bilaterally adrenalectomized rats. During the whole experiment the average increase in body weight was 3.9-4.3 g/day. LEP administration into adrenalectomized rats had no effect on anterior pituitary weight. This treatment resulted in a significant increase in pituitary ACTH concentration and content, and these changes were accompanied by a potent decrease in blood corticotropin level. LEP administration into adrenalectomized rats only insignificantly lowered the quantity of anterior pituitary ACTH-immunoreactive cells and their average area. On the opposite, the average volume of pituitary corticotropes of LEP-treated rats was notably lower than that in adrenalectomized-vehicle administered ones. Results of performed experiments clearly demonstrate that prolonged LEP administration results in a notable inhibition of the growth and secretory activity of anterior pituitary corticotropes of the adrenalectomized rats.
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PMID:Anterior pituitary corticotropes of adrenalectomized, leptin-administered rats. 1182 8

Leptin affects body weight by decreasing food intake, activating the sympathetic nervous system and regulating neuroendocrine function. This type of regulation is a hallmark of hypothalamic control, which typically integrates autonomic, endocrine and behavioral responses. We have performed a series of experiments investigating hypothalamic pathways underlying these actions of leptin. We found that leptin activates neurons that coexpress pro-opiomelanocortin (POMC) and cocaine- and amphetamine-regulated transcript (CART) mRNA. These neurons innervate several sites, including sympathetic preganglionic neurons in the spinal cord, neurons in the paraventricular hypothalamic nucleus (PVH), and melanin-concentrating hormone and orexin neurons in the lateral hypothalamic area (LHA). Following leptin administration, POMC neurons express both Fos and suppressor of cytokine signalling-3 (SOCS-3) mRNA. In contrast, leptin induced SOCS-3 expression in neuropeptide Y (NPY) neurons but not Fos, suggesting that leptin acts differentially on NPY and POMC cells. We also investigated potential downstream targets of leptin responsive NPY and POMC neurons by assessing the distribution of the melanocortin 4 receptor (MC4-R) mRNA and Y1 and Y5 NPY receptor mRNA in chemically defined neurons. We found dense MC4-R mRNA expression in several sites including the PVH and LHA. Using dual-label in situ hybridization we found that MC4-R mRNA is coexpressed in PVH cells expressing pro-TRH mRNA. We also found Y1 and Y5 NPY receptor mRNA in the PVH in patterns very similar to that of MC4R, suggesting that these receptors may be coexpressed on at least some PVH neurons. These results provide a neuroanatomic framework explaining the endocrine, autonomic and behavioral effects of leptin.
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PMID:Hypothalamic pathways underlying the endocrine, autonomic, and behavioral effects of leptin. 1184 Feb 21

The biology of leptin has been studied most extensively in rodents and in humans. Leptin is involved in the regulation of food intake, energy homeostasis and immunity. Leptin is primarily produced in white adipose tissue and acts via a family of membrane bound receptors, including an isoform with a long intracellular domain (OB-Rb), and many isoforms with short intracellular domains (Ob-Rs). OB-Rb is predominantly expressed in the hypothalamic regions involved in the regulation of food intake and energy homeostasis. The other isoforms are distributed ubiquitously and are found in most peripheral tissues in far greater abundance than OB-Rb. The effects of leptin on food intake and energy homeostasis are central and are mediated via a network of orexigenic neuropeptides (neuropeptide Y, galanin, galanin-like peptide, melanin-concentrating hormone, orexins, agouti-related peptide) and anorexigenic neuropeptides (corticotropin-releasing hormone, pro-opiomelanocortin, alpha-melanocyte stimulating hormone and cocaine- and amphetamine-regulated transcript). In addition, leptin acts directly on immune cells to stimulate hematopoesis, T-cell immunity, phagocytosis, cytokine production, and to attenuate susceptibility to infectious insults. Emerging data in ruminants suggest that leptin is dynamically regulated by many factors and physiological states. Thus, leptin is secreted in a pulsatile fashion, but without a marked diurnal rhythm. A positive relationship between adiposity and plasma leptin concentration exists in growing and lactating ruminants. The concentration of plasma leptin increases during pregnancy, starts to decline 1--2 wk before parturition, and reaches a nadir in early lactation. The reduction of plasma leptin at parturition is likely to promote centrally mediated adaptations required in periods of energy deficit, but could have negative effects on immune cell function. Future research is needed in ruminants to address the roles played by leptin and the central nervous system in orchestrating metabolism during the periparturient period and during infectious diseases.
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PMID:Leptin and the regulation of food intake, energy homeostasis and immunity with special focus on periparturient ruminants. 1187 19

A chronic minor imbalance between energy intake and energy expenditure may lead to obesity. Both lean and obese subjects eventually reach energy balance and their body weight regulation implies that the adipose tissue mass is "sensed", leading to appropriate responses of energy intake and energy expenditure. The cloning of the ob gene and the identification of its encoded protein, leptin, have provided a system signaling the amount of adipose energy stores to the brain. Leptin, a hormone secreted by fat cells, acts in rodents via hypothalamic receptors to inhibit feeding and increase thermogenesis. A feedback regulatory loop with three distinct steps has been identified: (1) a sensor (leptin production by adipose cells) monitors the size of the adipose tissue mass; (2) hypothalamic centers receive and integrate the intensity of the leptin signal through leptin receptors (LRb); (3) effector systems, including the sympathetic nervous system, control the two main determinants of energy balance-energy intake and energy expenditure. While this feedback regulatory loop is well established in rodents, there are many unsolved questions about its applicability to body weight regulation in humans. The rate of leptin production is related to adiposity, but a large portion of the interindividual variability in plasma leptin concentration is independent of body fatness. Gender is an important factor determining plasma leptin, with women having markedly higher leptin concentrations than men for any given degree of fat mass. The ob mRNA expression is also upregulated by glucocorticoids, whereas stimulation of the sympathetic nervous system results in its inhibition. Furthermore, leptin is not a satiety factor in humans because changes in food intake do not induce short-term increases in plasma leptin levels. After its binding to LRb in the hypothalamus, leptin stimulates a specific signaling cascade that results in the inhibition of several orexigenic neuropeptides, while stimulating several anorexigenic peptides. The orexigenic neuropeptides that are downregulated by leptin are NPY (neuropeptide Y), MCH (melanin-concentrating hormone), orexins, and AGRP (agouti-related peptide). The anorexigenic neuropeptides that are upregulated by leptin are alpha-MSH (alpha-melanocyte-stimulating hormone), which acts on MC4R (melanocortin-4 receptor); CART (cocaine and amphetamine-regulated transcript); and CRH (corticotropin-releasing-hormone). Obese humans have high plasma leptin concentrations related to the size of adipose tissue, but this elevated leptin signal does not induce the expected responses (i.e., a reduction in food intake and an increase in energy expenditure). This suggests that obese humans are resistant to the effects of endogenous leptin. This resistance is also shown by the lack of effect of exogenous leptin administration to induce weight loss in obese patients. The mechanisms that may account for leptin resistance in human obesity include a limitation of the blood-brain-barrier transport system for leptin and an inhibition of the leptin signaling pathways in leptin-responsive hypothalamic neurons. During periods of energy deficit, the fall in leptin plasma levels exceeds the rate at which fat stores are decreased. Reduction of the leptin signal induces several neuroendocrine responses that tend to limit weight loss, such as hunger, food-seeking behavior, and suppression of plasma thyroid hormone levels. Conversely, it is unlikely that leptin has evolved to prevent obesity when plenty of palatable foods are available because the elevated plasma leptin levels resulting from the increased adipose tissue mass do not prevent the development of obesity. In conclusion, in humans, the leptin signaling system appears to be mainly involved in maintenance of adequate energy stores for survival during periods of energy deficit. Its role in the etiology of human obesity is only demonstrated in the very rare situations of absence of the leptin signal (mutations of the leptin gene or of the leptin receptor gene), which produces an internal perception of starvation and results in a chronic stimulation of excessive food intake.
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PMID:Leptin signaling, adiposity, and energy balance. 1207 65

It is known that leptin, an adipocyte-derived hormone, exerts a stimulatory effect on growth hormone (GH) secretion in various animal species. However, no previous study examined in vivo whether leptin affects the secretion of GH-releasing factor (GRF), somatostatin (SRIH), and some other closely relevant neurohormones in the hypothalamus. Therefore, in this study we investigated the effects of direct leptin infusion into the hypothalamus on the in vivo release of GRF, SRIH, alpha-melanocyte-stimulating hormone (alpha-MSH), and neuropeptide Y (NPY) in freely moving adult male rats using the push-pull perfusion. Leptin was infused into the median eminence-arcuate nucleus complex at three different concentrations, i.e., 1.0 (normal feeding level), 3.0, and 10 ng/ml (mild obesity level). In normally fed rats, only 10 ng/ml leptin was able to stimulate GH secretion, whereas in 3 d fasted rats, GH release was dose-dependently stimulated by 1.0 and 3.0 ng/ml leptin, although its 10 ng/ml dose did not produce additional effects. The facilitation of GH secretion occurred as increased pulse amplitudes without significant changes in the pulse frequency. During the leptin infusion, the hypothalamic GRF increased and SRIH decreased in magnitudes that approximately paralleled those of GH changes. Leptin stimulated the release of alpha-MSH in the fasted but not fed rats. It is likely that the fasting-induced increase in the hypothalamic alpha-MSH sensitivity to leptin is relevant to ingestive behavior involving leptin. Leptin was without effect on NPY release in either the fed or fasted group. Although it is certain that NPY mediates at least part of the metabolic actions of leptin, NPY is unlikely to be involved in the acute effects of leptin on GH, GRF, and SRIH secretion. These results demonstrate for the first time that leptin can alter the in vivo release of both GRF and SRIH in rat hypothalamus concurrently with the stimulation of GH secretion.
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PMID:Leptin regulates growth hormone-releasing factor, somatostatin, and alpha-melanocyte-stimulating hormone but not neuropeptide Y release in rat hypothalamus in vivo: relation with growth hormone secretion. 1212 85

In the hypothalamic arcuate nucleus, neurones that coexpress cocaine-amphetamine-regulated transcript (CART) and alpha-melanocyte-stimulating hormone [alpha-MSH; pro-opiomelanocortin (POMC) derived] peptides exert catabolic actions and are stimulated by leptin. However, leptin treatment also affects other circulating factors that influence hypothalamic gene expression. Notably, the hypercorticosteronaemia of ob/ob mice is lowered by leptin treatment. To examine the interaction between glucocorticoids and leptin on POMC/CART mRNA expression, an experiment combining leptin and adrenalectomy (ADX) in leptin deficient ob/ob mice was carried out. Obese ob/ob and lean littermate Ob/? mice were ADX or sham-operated. ADX mice received a pellet containing 25% corticosterone subcutaneously. Seven days postoperatively, mice were injected intraperitoneally for 5 days with either recombinant human leptin or vehicle. On the sixth day, the mice were decapitated and the brains removed and trunk blood was collected for corticosterone analysis. Plasma concentrations of corticosterone were elevated in all ob/ob groups compared to Ob/?. For both ob/ob and Ob/? groups, corticosterone concentrations exhibited a decline across groups: vehicle-sham>leptin-sham>ADX-vehicle>ADX-leptin. Leptin inhibited food intake and bodyweight in ob/ob-sham and ob/ob-ADX to a similar extent, whereas no effect of leptin was observed in Ob/? mice. Similarly, leptin caused an identical increase in arcuate POMC and CART mRNA expression in ob/ob-sham and ob/ob-ADX compared to vehicle. The present data support the view that leptin influences arcuate POMC and CART mRNA expression directly, and that the effect is not modulated by corticosterone across a wide range of circulating corticosterone concentrations.
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PMID:Effects of leptin on arcuate pro-opiomelanocortin and cocaine-amphetamine-regulated transcript expression are independent of circulating levels of corticosterone. 1242 41

It is still not known whether leptin, an adipocyte-derived hormone, acts directly within the hypothalamus to stimulate the gonadotropin-releasing hormone (GnRH)-luteinizing hormone (LH) system. In order to address this question, the present study examined the effects of direct intrahypothalamic perfusions with leptin on the in vivo release of GnRH in ovarian steroid-primed ovariectomized rats utilizing the push-pull perfusion technique. Both alpha-melanocyte-stimulating hormone (alpha-MSH) and neuropeptide Y were also measured in the hypothalamic perfusates. In normally fed animals, the leptin infusion was without effect on the release of these three hypothalamic peptides and also without effect on plasma LH and prolactin (PRL), whether leptin was infused into the medial preoptic area (where the majority of GnRH neuronal cell bodies exist) or the median eminence-arcuate nucleus complex (where axon terminals of GnRH neurons are located). In contrast, in 3-day fasted rats leptin was effective in stimulating the secretion of GnRH, alpha-MSH, and LH, regardless of the site of perfusion. These three hormones were increased in a temporal order of alpha-MSH, GnRH and LH. Irrespective of the site of perfusion, leptin was without effect on the release of neuropeptide Y. Only when leptin was infused into the median eminence-arcuate nucleus complex was PRL secretion also stimulated, although its onset was 1 h behind that of LH. The leptin-induced elevations of GnRH, alpha-MSH, LH and PRL were all dose-dependently stimulated by subnormal (1.0 ng ml(-1)) and normal (3.0 ng ml(-1)) concentrations of leptin, but at higher concentrations (10 ng ml(-1)) it did not produce additional effects. Leptin infusion into the anterior hypothalamic area, a control site equidistant from both the medial preoptic area and the median eminence-arcuate nucleus complex, did not produce a significant change in any of the hormones in either the fed or fasted rats. These results demonstrate for the first time that leptin can act at both the cell bodies and axon terminals of GnRH neurons to stimulate the release of the neurohormone in vivo, and they also suggest that alpha-MSH may play a significant intermediary role in linking leptin and GnRH secretion.
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PMID:Leptin directly acts within the hypothalamus to stimulate gonadotropin-releasing hormone secretion in vivo in rats. 1243 65

In experiment 1, nine light horse geldings (three 3 x 3 Latin squares) received dexamethasone (DEX; 125 microg/kg BW, i.m.), glucose (0.2 g/kg BW, i.v.), or nothing (control) once per day for 4 days. DEX increased (P < 0.001) glucose, insulin, and leptin concentrations and resulted in a delayed increase (P < 0.001) in IGF-I concentrations. In experiment 2, mares were similarly treated with DEX (n = 6) or vehicle (n = 6). DEX again increased (P < 0.01) glucose, insulin, and leptin concentrations; the delayed elevation in IGF-I concentrations occurred on day 10, 12, and 19, relative to the first day of treatment. In experiment 3, six light horse geldings received either 200 IU of adrenocorticotropin (ACTH) i.m. or vehicle twice daily for 4 days. ACTH increased (P < 0.001) cortisol concentrations. Further, ACTH resulted in increases (P < 0.01) glucose, insulin, and leptin concentrations. In experiment 4, plasma samples from four light horse stallions that were fed 6-n-propyl-2-thiouracil (PTU) at 6 mg/kg BW for 60 days to induce hypothyroidism were compared to samples from control stallions. On day 52, stallions receiving PTU had lower concentrations of thyroxine (P < 0.05) and triiodothyronine (P < 0.01) and higher (P < 0.01) concentrations of TSH. Leptin concentrations were higher (P < 0.01) in PTU-fed stallions from day 10 through 52. In conclusion, circulating concentrations of leptin in horses was increased by administering DEX. Treatment with ACTH increased cortisol and resulted in lesser increases in leptin, glucose, and insulin. In addition, PTU feeding results in lesser increases in leptin concentrations.
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PMID:Effects of dexamethasone, glucose infusion, adrenocorticotropin, and propylthiouracil on plasma leptin concentrations in horses. 1245 Jun 21

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