Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01275 (glucagon)
 26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Diagnosis and treatment of hypoglycemia is an actual problem because glucose is the principal source of energy for central nervous system except permanent starvation when the ketone bodies are used by the central nervous system for energy. Glucose homeostasis depends on primary glucoregulatory organs--pancreas, liver, adrenal glands, and hypophysis. Insulin, glucagon, cathecholamines, cortisol, and growth hormone take part in this interaction. Hypoglycemia can develop if there are disorders of glucoregulatory organs resulting in imbalance of normal glucose homeostasis. Hypoglycemia presents with autonomic symptoms--hunger, palpitations, tremor, sweating--and with neuroglycopenic symptoms--confusion, drowsiness, odd behavior, speech difficulties, incoordination. None of these symptoms is specific just to hypoglycemia. Frequently hypoglycemia has to be differentiated with neurologic, psychiatric, and cardiovascular disorders. In this article the causes, symptoms, diagnosis, and treatment of hypoglycemia are reviewed.
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PMID:[Causes, diagnosis, and treatment of hypoglycemia]. 1709 Sep 87

Ghrelin is a potent orexigenic and adipogenic hormone that strongly influences fat deposition and the generation of hunger in obesity. Indeed, hyperghrelinemia appears to promote an increase in food intake as seen in Prader-Willi Syndrome (PWS). Exendin (Ex)-4 is an agonist of the glucagon-like peptide (GLP)-1 receptor (GLP-1r) that has anorexigenic and fat-reducing properties. Here, we report that Ex-4 reduces the levels of ghrelin by up to 74% in fasted rats. These effects are dose dependent and long lasting (up to 8 h), and they can be detected after both central and peripheral administration of Ex-4. Suppression of ghrelin was neither mimicked by GLP-1(7-36)-NH(2) nor blocked by the GLP-1r antagonist Ex-(9-39). Moreover, it was independent of the levels of leptin and insulin. The decrease in ghrelin levels induced by Ex-4 may explain the reduced food intake in fasted rats, justifying the more potent anorexigenic effects of Ex-4 when compared with GLP-1. As well as the potential benefits of Ex-4 in type 2 diabetes, the potent effects of Ex-4 on ghrelin make it tempting to speculate that Ex-4 could offer a therapeutic option for PWS and other syndromes characterized by substantial amounts of circulating ghrelin.
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PMID:Exendin-4 potently decreases ghrelin levels in fasting rats. 1719 76

Postprandial glucagon-like peptide-1 (GLP-1) secretion can act as a meal termination signal in animals and humans. We tested the hypothesis that the postprandial changes in plasma GLP-1 concentrations are associated with changes in the human brain activity in response to satiety by performing a post-hoc analysis of a cross-sectional study of neuroanatomical correlates of hunger and satiation using (15)O-water positron-emission tomography (PET). Forty-two subjects (22M/20F, age 31+/-8 years) spanning a wide range of adiposity (body fat: 7-44%) were included in this analysis. Outcome measures included changes in PET-measured regional cerebral blood flow (rCBF) and plasma concentrations of GLP-1, glucose, insulin, and free-fatty acids (FFA), elicited by the administration of a satiating amount of a liquid formula meal. The peak postprandial increases in plasma GLP-1 concentrations were correlated with increases in rCBF in the left dorsolateral prefrontal cortex (including the left middle and inferior frontal gyri), previously implicated in PET studies of human satiation, and the hypothalamus, previously implicated in the regulation of food intake in animal and human studies, both before and after adjustment for sex, age, body fat, and changes in plasma glucose, insulin, and serum FFA concentrations. The postprandial GLP-1 response is associated with activation of areas of the human brain previously implicated in satiation and food intake regulation.
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PMID:Postprandial glucagon-like peptide-1 (GLP-1) response is positively associated with changes in neuronal activity of brain areas implicated in satiety and food intake regulation in humans. 1731 22

This study investigated the acute effects of exercise on the postprandial levels of appetite-related hormones and metabolites, energy intake (EI) and subjective measures of appetite. Ghrelin, polypeptide YY (PYY), glucagon-like peptide-1 (GLP-1) and pancreatic polypeptide (PP) were measured in the fasting state and postprandially in 12 healthy, normal-weight volunteers (six males and six females) using a randomised crossover design. One hour after a standardised breakfast, subjects either cycled for 60 min at 65% of their maximal heart rate or rested. Subjective appetite was assessed throughout the study using visual analogue scales and subsequent EI at a buffet meal was measured at the end (3-h post-breakfast and 1-h post-exercise). Exercise significantly increased mean PYY, GLP-1 and PP levels, and this effect was maintained during the post-exercise period for GLP-1 and PP. No significant effect of exercise was observed on postprandial levels of ghrelin. During the exercise period, hunger scores were significantly decreased; however, this effect disappeared in the post-exercise period. Exercise significantly increased subsequent absolute EI, but produced a significant decrease in relative EI after accounting for the energy expended during exercise. Hunger scores and PYY, GLP-1 and PP levels showed an inverse temporal pattern during the 1-h exercise/control intervention. In conclusion, acute exercise, of moderate intensity, temporarily decreased hunger sensations and was able to produce a short-term negative energy balance. This impact on appetite and subsequent energy homeostasis was not explained by changes in postprandial levels of ghrelin; however, 'exercise-induced anorexia' may potentially be linked to increased PYY, GLP-1 and PP levels.
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PMID:Effects of exercise on gut peptides, energy intake and appetite. 1747 May 16

Traditionally there has been a tendency to focus on peripheral "bottom-up" feeding-related signals and their resulting downstream actions on hypothalamic centers when studying the feeding behaviour of animals. A problem with this hierarchal approach emerges especially with respect to acquiring a human model attempting to explain what is ultimately a distributed control of feeding and energy balance. This review focuses on illuminating the means by which we have come to understand the complexities of feeding, and takes the next step in an attempt to propose a distinctive top-down view of this composite behaviour. It is argued that in evolutionary terms humans demonstrate behaviours unique to all species as represented by an expanded forebrain and the resultant psychological "non-homeostatic" mediators of feeding. Emphasis is placed on a distributionist "two-tier" model, arguing that traditional short-term (cholescystokinin, ghrelin, peptide YY, glucagon-like peptide 1, etc.) and long-term (insulin and leptin) feeding signals may be actively suppressed by the nested nuclei and projections of cortical-limbic brain areas. It is the motivational state (dependent on depletion-repletion signals of hunger and satiety) that in turn has the capability to modulate how rewarding or how palatable a food item may be perceived; thus, both sides of the two-tiered model of feeding behaviour are complimentary and interdependent all at once. In the end, this paper is both commentary and critical review. This synthesis purports that as evolutionary processes spawned consciousness, the psychology of hunger and the present-day discordance of gene-environment interaction forever changed the feeding behaviour of Homo sapiens.
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PMID:Getting to the bottom of feeding behaviour: who's on top? 1748 58

The signaling systems underlying eating behavior control are complex. The current review focuses on gastrointestinal (GI) signaling systems as physiological key functions for metabolic control. Many of the peptides that are involved in the regulation of food intake in the brain are also found in the enteric nervous system and enteroendocrine cells of the mucosa of the GI tract. The only identified hunger-driving signal from the GI tract is ghrelin, which is mainly found in the mucosa of the stomach. Neuropeptides in the brain that influence food intake, of which neuropeptide Y, agouti gene-related peptide and orexins are stimulatory, while melanocortins and alpha-melanocortin stimulating hormone are inhibitory, are influenced by peptide signaling from the gut. These effects may take place directly through action of gut peptide in the brain or through nervous signaling from the periphery to the brain. The criteria for considering a gut hormone or neurotransmitter in a satiety signal seem to be fulfilled for cholecystokinin, glucagon-like peptide-1 and peptide YY(3-36). Other endogenous gut signals do not fulfill these criteria as they do not increase food intake in knock-out animals or in response to receptor antagonism, or display an inconsistent temporal profile with satiety and termination of the meal. Satiety signals from the GI tract act through the arcuate nucleus of the hypothalamus and the solitary tract nucleus of the brain stem, where neuronal networks directly linked to hypothalamic centers for food intake and eating behavior are activated. We have primarily focused on GI effects of various gut peptides involved in the regulation of food intake, using motor activity as a biomarker for the understanding of gut peptide effects promoting satiety.
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PMID:Appetite signaling: from gut peptides and enteric nerves to brain. 1758 45

Fermentable dietary fiber has been shown to cause fat loss and to increase peptide-YY (PYY) and glucagon-like peptide 1 (GLP-1) levels in rodents. In single meal tests, humans have an increase in PYY and GLP-1 to dietary fiber, but the response of these hormones to longer-term treatment is not known. Viscofiber (Cevena Bioproducts Inc., Edmonton, AB, Canada) is a high-viscosity fermentable dietary fiber made by a proprietary process from oats and barley. Seven healthy overweight and obese subjects were treated with a calorie-restricted diet, a lifestyle change program, and 4 g of Viscofiber/day for 16 weeks. Hunger, satiety, PYY, and GLP-1 were measured before and 1 hour after a standard meal test before and at week 14 of the study. Hunger and satiety were measured by Visual Analog Scales. PYY and GLP-1 were measured by radioimmunoassay and enzyme-linked immunosorbent assay, respectively. Weight was reduced 3.07 +/- 3.13 kg (P < .05) over the 16 weeks. Fasting PYY increased 8.67 +/- 6.62 pg/mL (P < .05) and fasting GLP-1 increased 2.67 +/- 0.84 pmol/L (P < .01) at 14 weeks compared to baseline. Satiety increased 1.78 +/- 1.43 cm (P < .01) at the 1-hour post-meal time point on week 14 compared to the study baseline. We conclude that 14 weeks of treatment with Viscofiber at 4 g/day along with a lifestyle change program and diet causes weight loss and increases fasting PYY, fasting GLP-1, and satiety at 1 hour following a standard meal, which extends the single meal test observations in humans.
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PMID:Fourteen weeks of treatment with Viscofiber increased fasting levels of glucagon-like peptide-1 and peptide-YY. 1815 48

A trial was conducted to determine the effects of different feeding regimens on plasma hormone and metabolite levels in 16-wk-old broiler breeder pullets. A flock of 350 Cobb 500 breeder pullets was divided in 2 at 28 d of age and fed either every day (ED, 5 pens of 35 birds) or skip-a-day (SKIP, 5 pens of 35 birds) from 28 to 112 d of age. Total feed intake did not differ between the 2 groups. At 112 d, 52 randomly selected pullets from the larger flock of ED-fed pullets, and 76 from the SKIP-fed pullets were individually caged and fed a meal of 74 g (ED) or 148 g (SKIP). Blood samples were collected from 4 pullets in each group by cardiac puncture at intervals after feeding. Plasma was analyzed for insulin, glucagon, insulin-like growth factor-I and insulin-like growth factor-II, triiodothyronine and thyroxine, corticosterone, leptin, glucose, nonesterified fatty acids, triglycerides, and uric acid. Feed retention in the crop was also noted at each interval. In ED birds, the crop was empty by 12 h and in SKIP birds, the crop was empty by 24 h after feeding. The physiological responses to fasting, such as increased glucagon and corticosterone and reduced plasma triglyceride, occurred at times coincidental with crop emptying in both ED and SKIP birds. Overall, mean insulin-like growth factor-I levels were higher (P < 0.05) in ED birds. Triiodothyronine was higher (P = 0.09) in SKIP birds. Overall mean plasma corticosterone was 2-fold higher in SKIP-fed birds, which may be related to the increased length of fasting periods, hunger, and stress. Plasma leptin was consistently higher in ED-fed birds, which was indicative of their more consistent food supply and more stable energy status. In summary, the experiment reported here shows that different feeding regimens can alter hormone and metabolite profiles, in spite of total feed intakes being equal.
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PMID:An examination of the role of feeding regimens in regulating metabolism during the broiler breeder grower period. 2. Plasma hormones and metabolites. 1821 69

In normal individuals hypoglycemic counterregulation is a multifactorial, redundant process that involves reduction of insulin secretion, increasing glucagon secretion, adrenergic activation, and increased growth hormone and cortisol secretion. Metabolically, these lead to increased glucose production, initially through glycogenolysis and later through gluconeogenesis, decreased muscle glucose oxidation and storage and increased release and use of alternative fuels, primarily free fatty acids. They also lead to hypoglycemic symptoms and hunger which increase food intake. These systems are designed to provide as much glucose as possible for brain glucose use. In patients with type 1 diabetes there are multiple impairments of these responses. Insulin does not decrease. Glucagon secretion is decreased or absent. Recovery from hypoglycemia is therefore dependent on the adrenergic response. Hypoglycemia increases plasma levels of both epinephrine and norepinephrine. These catechols are released primarily from the adrenal medulla. However, it is well documented that hypoglycemic increases muscle sympathetic nerve activity, and that both alpha and beta adrenergic activity increase. Increased beta-activity increases free fatty acid release which increase glucose production and decrease glucose utilization. The increased alpha-adrenergic activity's primary role is to counteract beta-adrenergic vasodilation. It may also reduce neurogenic and neuroglycopenic symptoms. Lastly, there is evidence that both cardiac and adrenergic sensitivity are altered in type 1 diabetes. It is hoped that this information can be used in the future to help develop ways to protect patients with type 1 diabetes from hypoglycemia and its adverse effects.
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PMID:Sympathetic mechanisms of hypoglycemic counterregulation. 1822 Jun 70

The metabolic state affects the level of general activity of an organism. Satiety is related to relaxation while hunger is coupled to elevated activity which supports the chance to balance the energy deficiency. The unrestricted food availability in modern industrial nations along with no required locomotor activity are risk factors to develop disorders such as obesity. One of the strategies to find new targets for future treatment of metabolic disorders in men is to gain detailed knowledge of molecular and cellular mechanisms involved in the regulation of metabolic homeostasis in less complex, i.e. invertebrate systems. This review reports recent molecular studies in insects about how hunger signals may be linked to global activation. Adipokinetic peptide hormones (AKHs) are the insect counterpart to the mammalian glucagon. They are released upon lack of energy and mobilize internal fuel reserves. In addition, AKHs stimulate the locomotor activity which involves their activity within the central nervous system. In the cockroach Periplaneta americana various neurons express the AKH receptor. Some of these, the dorsal unpaired median (DUM) neurons belonging to a general arousal system, release the biogenic amine octopamine, the insect counterpart to mammalian adrenergic hormones. The two Periplaneta AKHs activate Gs proteins, and AKH I also potently activates Gq proteins. AKH I and - less effectively - AKH II accelerate spiking of DUM neurons via an increase of a pacemaking Ca2+ current. Systemically injected AKH I stimulates locomotion in contrast to AKH II. This behavioral difference corresponds to the different effectiveness of the AKHs on the level of G-proteins.
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PMID:Metabolic regulation and behavior: how hunger produces arousal - an insect study. 1822 Sep 52


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