Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0028754 (obesity)
124,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Enterostatin is a peptide which has been found to decrease food intake with a specificity for the fat contained in the food. In this work we have investigated the effect of enterostatin (Val-Pro-Asp-Pro-Arg) and its proteolytic fragments, des-arg-enterostatin (Val-Pro-Asp-Pro) and the tripeptide Asp-Pro-Arg, on insulin secretion. It was found that enterostatin and desarg-enterostatin inhibited insulin secretion from isolated rat islets by 55.3% (P < 0.05) and 53.6% (P < 0.05) at 1.6 x 10(-4) M concentration, while the tripeptide Asp-Pro-Arg at 1.6 x 10(-4) M concentration had no significant effect and increased insulin secretion by 33.0%. Enterostatin at 200 ng after intraventricular administration was found to inhibit the intake of a high-fat diet by 45.0%, while des-arg-enterostatin (200 ng) had no effect, in agreement with previous findings. The tripeptide Asp-Pro-Arg (200 ng) had no effect on the intake of a high-fat diet compared to saline injection. The ability of enterostatin to inhibit high-fat food intake and decrease insulin secretion may be important for the prevention of obesity and type II diabetes, conditions linked through hyperinsulinemia.
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PMID:Enterostatin--its ability to inhibit insulin secretion and to decrease high-fat food intake. 811 74

The effects of adrenalectomy on the feeding response to enterostatin and the mRNA levels of its parent protein, pancreatic colipase, have been investigated in lean (fa/?) and genetically obese (fa/fa) rats. Adrenalectomy reduced body weight gain and food intake of obese rats. Enterostatin inhibited the intake of high-fat diet in obese rats but not in lean rats. Adrenalectomy reduced food intake of all rats and abolished the response to enterostatin in the obese group. Obese rats had low levels of colipase mRNA, but these were normalized after adrenalectomy. The ability to respond to exogenous enterostatin is possibly linked to low levels of production of the peptide. The effects of adrenalectomy on brown adipose tissue uncoupling protein (UCP) mRNA and beta 3-adrenergic receptor (beta 3-AR) mRNA were also investigated. Northern blot analysis showed low levels of both UCP mRNA and beta 3-AR mRNA in obese rats that were restored to or toward the normal levels of lean rats by adrenalectomy. Adrenalectomy had no significant effects on mRNA levels in lean rats.
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PMID:Adrenalectomy of the obese Zucker rat: effects on the feeding response to enterostatin and specific mRNA levels. 839 27

A high fat intake, together with an inability to match lipid oxidation to fat intake, has been found to be correlated with obesity in humans. This review describes our current understanding of enterostatin, a peptide that selectively reduces fat intake. Enterostatin is formed in the intestine by the cleavage of secreted pancreatic procolipase, the remaining colipase serving as an obligatory cofactor for pancreatic lipase during fat digestion. Enterostatin is also produced in the gastric mucosa and the mucosal epithelia of the small intestine. Procolipase gene transcription and enterostatin release into the gastrointestinal lumen are increased by high-fat diets. After feeding, enterostatin appears in the lymph and circulation. Enterostatin will selectively inhibit fat intake during normal feeding and in experimental paradigms that involve dietary choice. Its anorectic effect has been demonstrated in a number of species. Both peripheral and central sites of action have been proposed. The peripheral mechanism involves an afferent vagal signaling pathway to hypothalamic centers. The central responses are mediated through a pathway that includes both serotonergic and opioidergic components. Chronically, enterostatin reduces fat intake, bodyweight, and body fat. This response may involve multiple metabolic effects of enterostatin, which include a reduction of insulin secretion, an increase in sympathetic drive to brown adipose tissue, and the stimulation of adrenal corticosteroid secretion. A possible pathophysiological role is suggested by studies that have linked low enterostatin production and/or responsiveness to strains of rat that become obese and prefer dietary fat. Humans with obesity also exhibit a lower secretion of pancreatic procolipase after a test meal, compared with persons of normal weight.
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PMID:Enterostatin--a peptide regulating fat intake. 928 45

Despite a rising worldwide epidemic of obesity there is currently only a very small number of anti-obesity drugs available to manage the problem. Large numbers of differing pharmacological agents reliably produce a reduction in food intake when administered acutely to animals, and when administered chronically they result in a significant decrease in body mass. Behavioural analysis of drug-induced anorexia in animals demonstrates that various compounds profoundly effect feeding behaviour in differing ways. This indicates the variety of mechanisms by which pharmacological agents can induce changes in food intake, body weight and eventually body composition. Some of the same drugs produce decreases in food intake and weight loss in humans. Some of these drugs do so by modifying the functioning of the appetite system as measured by subjective changes in feelings of hunger and fullness (indices of satiety). Such drugs can be considered as "appetite suppressants" with clinical potential as anti-obesity agents. Other drugs induce changes in food intake and body weight through various physiological mechanisms inducing feelings of nausea or even by side effect related malaise. Of the drugs considered suitable candidates for appetite suppressants are agents which act via peripherally satiety peptide systems (such as CCK, Bombesin/GRP, Enterostatin and GLP-1), or alter the CNS levels of various hypothalamic neuropeptides (NPY, Galanin, Orexin and Melanocortins) or levels of the key CNS appetite monoamine neurotransmitters such as serotonin (5-HT) and noradrenaline (NA). Recently, the hormone leptin has been regarded as a hormonal signal linking adipose tissue status with a number of key central nervous system circuits. The peptide itself stimulates leptin receptors and it links with POMC and MC-4 receptors. These receptors may also provide drug targets for the control of appetite. Any changes induced by a potential appetite suppressant should be considered in terms of the (i) psychological experience and behavioural expression of appetite, (ii) metabolism and peripheral physiology, and (iii) functioning of CNS neural pathways. In humans, modulation of appetite may involve changes in total caloric consumption, subjective changes in feelings of hunger and fullness, preferences for specific food items, and general macronutrient preferences. These may be expressed behaviourally as changes in meal patterns, snacking behaviour and food choice. Within the next 20 years it is certain that clinicians will have a new range of anti-obesity compounds available to choose from. Such novel compounds may act on a single component of the appetite system or target a combination of these components detailed in this review. Such compounds used in combination with lifestyle changes and dietary intervention may be useful in dealing with the rising world epidemic of obesity.
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PMID:Pharmacology of appetite suppression. 1085 85

Food intake is a regulated system. Afferent signals provide information to the central nervous system, which is the centre for the control of satiety or food seeking. Such signals can begin even before food is ingested through visual, auditory and olfactory stimuli. One of the recent interesting findings is the demonstration that there are selective fatty acid taste receptors on the tongue of rodents. The suppression of food intake by essential fatty acids infused into the stomach and the suppression of electrical signals in taste buds reflect activation of a K rectifier channel (K 1.5). In animals that become fat eating a high-fat diet the suppression of this current by linoleic acid is less than that in animals that are resistant to obesity induced by dietary fat. Inhibition of fatty acid oxidation with either mercaptoacetate (which blocks acetyl-CoA dehydrogenase) or methylpalmoxirate will increase food intake. When animals have a choice of food, mercaptoacetate stimulates the intake of protein and carbohydrate, but not fat. Afferent gut signals also signal satiety. The first of these gut signals to be identified was cholecystokinin (CCK). When CCK acts on CCK-A receptors in the gastrointestinal tract, food intake is suppressed. These signals are transmitted by the vagus nerve to the nucleus tractus solitarius and thence to higher centres including the lateral parabrachial nucleus, amygdala, and other sites. Rats that lack the CCK-A receptor become obese, but transgenic mice lacking CCK-A receptors do not become obese. CCK inhibits food intake in human subjects. Enterostatin, the pentapeptide produced when pancreatic colipase is cleaved in the gut, has been shown to reduce food intake. This peptide differs in its action from CCK by selectively reducing fat intake. Enterostatin reduces hunger ratings in human subjects. Bombesin and its human analogue, gastrin inhibitory peptide (also gastrin-insulin peptide), reduce food intake in obese and lean subjects. Animals lacking bombesin-3 receptor become obese, suggesting that this peptide may also be important. Circulating glucose concentrations show a dip before the onset of most meals in human subjects and rodents. When the glucose dip is prevented, the next meal is delayed. The dip in glucose is preceded by a rise in insulin, and stimulating insulin release will decrease circulating glucose and lead to food intake. Pyruvate and lactate inhibit food intake differently in animals that become obese compared with lean animals. Leptin released from fat cells is an important peripheral signal from fat stores which modulates food intake. Leptin deficiency or leptin receptor defects produce massive obesity. This peptide signals a variety of central mechanisms by acting on receptors in the arcuate nucleus and hypothalamus. Pancreatic hormones including glucagon, amylin and pancreatic polypeptide reduce food intake. Four pituitary peptides also modify food intake. Vasopressin decreases feeding. In contrast, injections of desacetyl melanocyte-stimulating hormone, growth hormone and prolactin are associated with increased food intake. Finally, there are a group of miscellaneous peptides that modulate feeding. beta-Casomorphin, a heptapeptide produced during the hydrolysis of casein, stimulates food intake in experimental animals. In contrast, the other peptides in this group, including calcitonin, apolipoprotein A-IV, the cyclized form of histidyl-proline, several cytokines and thyrotropin-releasing hormone, all decrease food intake. Many of these peptides act on gastrointestinal or hepatic receptors that relay messages to the brain via the afferent vagus nerve. As a group they provide a number of leads for potential drug development.
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PMID:Afferent signals regulating food intake. 1099 53

Given the current global epidemic of obesity there is a demand for new anti-obesity drugs to overcome the problem. Many pharmacological agents reduce food intake and significantly decrease body mass when administered to animals but affect feeding behaviour in a profoundly different way indicating the variety of biological mechanisms by which such agents act (appetite verses non-appetite). More limited clinical data demonstrates that some of the same drugs produce decreases in food intake and weight loss in humans. A few of these drugs do so by modifying the functioning of the appetite system as measured by subjective changes in feelings of hunger and fullness (indices of satiety). These drugs that modify the daily flux of appetite could be considered as 'appetite suppressants' with clinical potential as anti-obesity agents. Drugs that can be considered suitable candidates for appetite suppressants are agents that enhance peripherally satiety peptide systems (such as CCK, Bombesin/GRP, Enterostatin and GLP-1), alter the CNS levels of various hypothalamic neuropeptides (NPY, Galanin, Orexin, CART and Melanocortins) or monoamine neurotransmitters (such as serotonin, nor-adrenaline and possibly dopamine). Recently, the hormone leptin has become regarded as a key hormonal signal linking adipose tissue status with a number of key central nervous system circuits (NPY, CART, CRF, Melanocortins and possibly Orexins). This tonic system may also provide drug targets for the control of appetite. Any changes induced by a potential appetite suppressant should be considered in terms of the (i) psychological experience and behavioural expression of appetite, (ii) metabolism and peripheral physiology, and (iii) functioning of CNS neural pathways. In humans, such modulation of appetite will involve changes in total caloric consumption, subjective changes in feelings of hunger and fullness, preferences for specific food items, and general macronutrient preferences. These may be expressed behaviourally as changes in meal patterns, snacking behaviour and food choice. Within the next 20 years it is certain that clinicians will have a new range of anti-obesity compounds available to choose from. Such novel compounds may act on a single component of the appetite system or target a combination of these components detailed in this review. Such compounds used in combination with life style changes and dietary intervention may be critical in dealing with the rising world epidemic of obesity.
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PMID:Pharmacology of appetite suppression: implication for the treatment of obesity. 1173 37

A pentapeptide released from procolipase, enterostatin, selectively attenuates dietary fat intake when administered peripherally or centrally. Enterostatin may act through the afferent vagus nerve and in the hypothalamus and amygdala, primarily in the central nucleus of the amygdala. To investigate the physiological role of endogenous enterostatin, we created an enterostatin-deficient, colipase-sufficient (Ent(-/-)) mouse. Ent(-/-) mice are viable, normally active, and fertile. They exhibit normal growth on low-fat and high-fat diets. Furthermore, Ent(-/-) mice develop diet-induced obesity, as do Ent(+/+) mice, and have normal responses to a two-macronutrient choice diet and to a switch from a high-fat to a low-fat diet. Levels of total serum (P = 0.004) and non-HDL (P <or= 0.001) cholesterol were higher and levels of HDL cholesterol (P = 0.01) were lower in Ent(-/-) than in wild-type mice. To determine whether enterostatin contributed to the decreased survival or whether colipase deficiency was the sole contributor, we administered enterostatin to procolipase-deficient (Clps(-/-)) mouse pups. Enterostatin significantly improved survival (P <or= 0.001). Our results demonstrate that enterostatin is not critically required to regulate food intake or growth, suggesting that other pathways may compensate for the loss of enterostatin. Enterostatin has developmental effects on survival of newborns and alters cholesterol metabolism.
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PMID:Enterostatin deficiency increases serum cholesterol but does not influence growth and food intake in mice. 1962 81

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