Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:P61278 (somatostatin)
 22,083 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Major phases of the physiology of food intake regulation remain hypothetical. There is a central regulatory mechanism for hunger and satiety, but the signals and messages that activate the brain centers remain conjectural. The alimentary tract regulation, the regulation by osmoreceptors, the thermostatic, the glucostatic, the lipostatic, the amino acid, and the hormonal food intake regulation theories leave many questions unanswered. Low molecular weight peptides appear to have an important effect on brain functions. Hypothalamic peptides such as thyrotropin-releasing hormone, gonadotropin-releasing hormone, and somatostatin have been assigned new roles in various brain functions. The hypothalamus and probably other parts of the brain produce also anorexigenic peptides. Anorexia is a common manifestation of cancer. It is proposed that peptides, oligonucleotides, and other small metabolites produced by the cancer and by the tumor-bearing host are responsible for the genesis of the anorexia. They produce the anorexia through a peripheral effect on neuroendocrine cells and neuroreceptors and through a direct effect on hypothalamic and other central nervous system sensor and responder cells.
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PMID:Anorexia-producing intermediary metabolites. 17 68

In addition to established gastrointestinal hormones--secretin, cholecystokinin-pancreozymin (CCK-PZ), gastrin, and glucagon---some 30 polypeptides with gastrointestinal actions can be listed. New aspects of these substances include the following: Gastrin and vasoactive intestinal peptide (VIP) can be also encountered in the central nervous system and may act as transmitters. CCK-PZ-serum concentrations are found markedly elevated in patients with exocrine pancreatic insufficiency; this may provide the opportunity to establish a realtively simple screening test. Moreover, there is evidence that serum-CCK-PZ levels serve as satiety signal. Secretin secretion is said to be enhanced in hunger and then to act as a lipolytic hormone. In addition to enteroglucagon, a gastrintestinal peptide identical to pancreatic glucagon has been detected. Gastric inhibitory polypeptide (GIP) inhibits gastric secretion and motility (enterogastrone activity) and together with glucose it stimulates insulin release (incretin activity). Motilin increases lower esophageal sphincter pressure, enhances gastric pepsin secretion and slows down gastric evacuation. Serum levels of pancreatic polypeptide may be found elevated as a diagnostic index in patients with endocrine peptide tumors of the pancreas. Recently, the potential importance of local (paracrine) actions of gastrointestinal polypeptides has been amphasized. Predominantly paracrine activity is exhibited by some prototype hormones, e.g. somatostatin, substance P, bombesian, and the non-polypeptide compounds, prostaglandins.
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PMID:[New views on gastrointestinal hormones]. 85 99

In chronic experiments on dogs and rabbits, i.v. administration of somatostatin (3.3 to 330.0 ng/kg) exerted activating effects in resting and in hunger upon the myoelectrical activity of stomach, duodenum, small intestine and ileum whereas in the course of digestion the effects were inhibitory. Somatostatin exerted mainly an inhibitory effect on the myoelectrical activity of stomach and small intestine in rabbits. Possible mechanisms of the somatostatin effect upon the contractile activity of the stomach and duodenum smooth muscles are discussed.
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PMID:[Effect of somatostatin on the myoelectrical activity of the stomach and small intestine in conscious dogs and rabbits]. 285 24

Using combined immuno-staining and retrograde tracing techniques many of the ascending visceral and taste pathways within the rat central nervous system have been shown to be composed of a variety of neuropeptide and catecholamine synthesizing enzyme containing neurones. The pathway we examined extended from the periphery to sensory cortex and included: the nodose ganglion (periphery)----solitary nucleus (medulla)----parabrachial nucleus (pons)----ventral posterior medial nucleus (thalamus)----visceral and taste sensory areas (cortex). In the solitary nucleus of the medulla many neuronal cell bodies could be shown to be both immuno-positive for one of 6 neuropeptides including avian pancreatic peptide (APP), cholecystokinin (CCK), enkephalin (ENK), neurotensin (NT), somatostatin (SOM) and substance P (SP) or the catecholamine synthesizing enzyme tyrosine hydroxylase (TOH) and to have a projection to the parabrachial nucleus of the pons. In the parabrachial nucleus of the pons many neuronal cell bodies could be shown to be immuno-positive for one of 5 neuropeptides (CCK, ENK, NT, SOM, SP) and have a projection to the ventral posterior medial nucleus of the thalamus. In the ventral posterior medial nucleus of the thalamus several neuronal cell bodies were shown to be immuno-positive for one of 3 neuropeptides (CCK, ENK, SOM) and project to the visceral and taste sensory cortex. This is the first report of neuropeptides being present in the projection neurones of any sensory system in the central nervous system and for the first time describes an entire set of putative neurotransmitters which extends from the periphery to the sensory cortex. From previous studies it also appears that in all cases examined the relevant receptors are present in these visceral and taste relay nuclei in order for the neuropeptide or catecholamine to produce an effect upon release. Comparisons between rat and other animals suggest that a similar organization of these visceral and taste pathways may also be present in other mammals including man. Functionally these neuropeptides containing projection neurones appear to be primarily involved in relaying visceral information rather than taste information. In this capacity activation of these neurones may produce such visceral sensations as malaise, well being, hunger, satiety or thirst.
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PMID:Neuropeptides are present in projection neurones at all levels in visceral and taste pathways: from periphery to sensory cortex. 673 52

Somatostatin (ST) inhibits gastrointestinal motility and exocrine and endocrine secretions. In animals, ST has been demonstrated to decrease food intake. We investigated, in a randomized double-blind investigation in 10 healthy humans, the effects of an intravenous ST infusion compared to saline on subjective hunger feelings. After 1 h, a low dose of fat was given intraduodenally to induce the release of endogenous upper-intestinal satiety factors. Ninety minutes later sandwiches were served and eaten until satiation. In the first hour, when no intraduodenal fat was given, there was a significant decrease in feelings of hunger with ST (p < 0.05). During the intraduodenal fat infusion this pattern reversed with a trend towards less satiety with ST. Food intake during intraduodenal fat infusion tended to be higher during ST (305 +/- 42 g) than during saline (205 +/- 36 g) although not significantly. In the 5 h after the experiment hunger feelings were significantly less after ST. In conclusion, we found evidence for a satiety effect of ST in humans which reversed towards less satiety when intraduodenal intralipid, which presumably produced endogenous satiety factors, was given. Postmeal satiety is higher after ST.
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PMID:Effects of somatostatin on human satiety. 775 30

Bulimia nervosa is an eating disorder characterised by recurrent episodes of binge eating and associated efforts to purge the ingested calories through self-induced vomiting, laxative or diuretic abuse, fasting or intensive exercise. The aetiopathogenesis and pathophysiology of the disorder are currently unclear. Biological bases have been proposed repeatedly, based on several lines of evidence: hunger, satiety and food choice are regulated by neurotransmitters and neuropeptides, and impairment of eating habits may be related to alterations in the secretion of these chemicals; genetic studies suggest that these neurotransmitter systems are dysfunctional in individuals with bulimia nervosa; and the frequent comorbidity of bulimia nervosa with major depressive and obsessive-compulsive disorders, conditions in which multiple alterations of brain biochemical functions have been demonstrated. Data in the literature suggest that levels of noradrenaline (norepinephrine) and serotonin (5-hydroxytryptamine; 5-HT) are lower in individuals with bulimia nervosa than in healthy controls. Levels of dopamine are similar to, or lower than, those in controls. After remission of the disorder, noradrenergic function returns to that seen in controls, whereas dopaminergic and serotonergic function rebound to levels higher than in controls. Among the neuropeptides, alterations in the levels of neuropeptide Y, peptide YY, beta-endorphin, corticotrophin-releasing hormone, somatostatin, cholecystokinin and vasopressin have been found in the symptomatic phase of bulimia nervosa, with a return to levels seen in controls after remission. Pharmacological treatment of bulimia nervosa that is directed at correction of the neurochemical alterations observed is difficult because of the complexity of the impairments. However, such treatment is necessary and should be continued long after symptomatic remission to ensure reinstitution of cerebral biochemical homeostasis.
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PMID:Aetiopathogenesis and pathophysiology of bulimia nervosa: biological bases and implications for treatment. 1146 Aug 90

The stimulation of exocrine pancreatic secretion that has been attributed by Pavlov exclusively to various reflexes (nervism), was then found that it depend also on numerous enterohormones, especially cholecystokinin (CCK) and secretin, released by duodeno-jejunal mucosa and originally believed to act via an endocrine pathway. Recently, CCK and other enterohormones were found to stimulate the pancreas by excitation of sensory nerves and triggering vago-vagal and entero-pancreatic reflexes. Numerous neurotransmitters and neuropeptides released by enteric nervous system (ENS) of gut and pancreas have been also implicated in the regulation of exocrine pancreas. This article was designed to review the contribution of vagal nerves and entero-hormones, especially CCK and other enterohormones, involved in the control of appetitive behavior such as leptin and ghrelin and pancreatic polypeptide family (peptide YY and neuropeptide Y). Basal secretion shows periodic fluctuations with peals controlled by ENS and by motilin and Ach. Plasma ghrelin, that is considered as hunger hormone, increases under basal conditions, while plasma leptin falls to the lowest level. Postprandial pancreatic secretion, classically divided into cephalic, gastric and intestinal phases, involves predominantly CCK, which under physiological conditions acts almost entirely by activation of vago-vagal reflexes to stimulate the exocrine pancreas, being accompanied by the fall in plasma ghrelin and increase of plasma leptin, reflecting feeding behavior. We conclude that the major role in postprandial pancreatic secretion is played by vagus and gastrin in cephalic and gastric phases and by vagus in conjunction with CCK and secretin in intestinal phase. PP, PYY somatostatin, leptin and ghrelin that affect food intake appear to participate in the feedback control of postprandial pancreatic secretion via hypothalamic centers.
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PMID:Brain-gut axis in pancreatic secretion and appetite control. 1456 70

Leptin-responsive neurons of the hypothalamus constitute a heterogeneous population expressing a vast array of different neuropeptides and neurotransmitters, some of which participate in the regulation of hunger and satiety. Here we report that somatostatin modulates the efficacy of leptin-signalling in the rat hypothalamus. Using a two-pulse paradigm at 30-min intervals, we delivered somatostatin or somatostatin receptor subtype-selective agonists in combination with leptin into the lateral cerebral ventricle of stereotaxically cannulated rats. To monitor the effect of somatostatin on the leptin-signalling pathway, we quantified changes in the leptin-mediated activation of STAT3, the signal transducer and activator of transcription 3. Successive administration of somatostatin and leptin diminished the level of STAT3-phosphorylation and nuclear STAT3 translocation in the ventromedial and dorsomedial hypothalamic nuclei, the lateral hypothalamic area, and the arcuate nucleus by about 40% compared to leptin administration alone. Furthermore, application of subtype-selective somatostatin receptor agonists suggests that the observed reduction in leptin-responsiveness is predominantly mediated by the sst3 receptor-subtype, followed by sst1 and sst2. In addition, the intensity of the negative-regulatory effect of somatostatin on leptin-signalling displayed regional differences for the three receptor-subtypes involved. Addressing the functional consequences of the diminished leptin-signalling, behavioural analyses showed that centrally applied somatostatin counteracts the leptin-mediated suppression of food intake. These results suggest that the pleiotropic effector somatostatin also plays a role in the central regulation of energy homeostasis.
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PMID:Somatostatin, a negative-regulator of central leptin action in the rat hypothalamus. 1708 45

The first "growth hormone secretagogues" (GHSs) were discovered by Bowers et al. in 1977. In 1996 the GHSs receptor (GHS-R 1a) was cloned. The endogenous ligand for this receptor, ghrelin, was not identified until 1999. Synthetic molecules termed GHSs are substances that stimulate growth hormone (GH) release, via a separate pathway distinct from GH releasing hormone (GHRH)/somatostatin. Ghrelin displays strong GH-releasing activity through the activation of the GHS-R 1a. Apart from stimulating GH secretion, ghrelin and many synthetic GHSs: 1) stimulate prolactin and ACTH secretion; 2) negatively influence the pituitary-gonadal axis; 3) stimulate appetite and positive energy balance; 4) modulate pancreatic endocrine function and affect glucose levels; 5) have cardiovascular actions. The control of ghrelin secretion is not well established at present, although nutrition is an important regulator. Investigators have exploited the ability of GHSs and ghrelin to release GH by mechanisms different from GHRH as a diagnostic tool, which is the present main clinical use of some GHSs. As an alternative to GH, GH deficient conditions could be treated with any substance which would release endogenous GH, such as synthetic GHSs. It is likely that GHSs, acting as either agonists or antagonists on different pathophysiological processes, might have some other clinical impact and therapeutic potential. At least theoretically ghrelin receptor antagonists could be anti-obesity drugs, as blockers of the orexigenic signal from the gastrointestinal tract to the brain. Inverse agonists of the ghrelin receptor, by blocking the constitutive receptor activity, might lower the set-point for hunger between meals.
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PMID:Ghrelin and growth hormone secretagogues, physiological and pharmacological aspect. 1927 40

Circadian and seasonal rhythms are a fundamental feature of all living organisms and their organelles. Biological rhythms are responsible for daily food intake; the period of hunger and satiety is controlled by the central pacemaker, which resides in the suprachiasmatic nucleus (SCN) of the hypothalamus, and communicates with tissues via bidirectional neuronal and humoral pathways. The molecular basis for circadian timing in the gastrointestinal tract (GIT) involves interlocking transcriptional/translational feedback loops which culminate in the rhythmic expression and activity of a set of clock genes and related hormones. Interestingly, it has been found that clocks in the GIT are responsible for the periodic activity (PA) of its various segments and transit along the GIT; they are localized in special interstitial cells, with unstable membrane potentials located between the longitudinal and circular muscle layers. The rhythm of slow waves is controlled in various segments of the GIT: in the stomach (about 3 cycles per min), in the duodenum (12 cycle per min), in the jejunum and ileum (from 7 to 10 cycles per min), and in the colon (12 cycles per min). The migrating motor complex (MMC) starts in the stomach and moves along the gut causing peristaltic contractions when the electrical activity spikes are superimposed on the slow waves. GIT hormones, such as motilin and ghrelin, are involved in the generation of MMCs, while others (gastrin, ghrelin, cholecystokinin, serotonin) are involved in the generation of spikes upon the slow waves, resulting in peristaltic or segmental contractions in the small (duodenum, jejunum ileum) and large bowel (colon). Additionally, melatonin, produced by neuro-endocrine cells of the GIT mucosa, plays an important role in the internal biological clock, related to food intake (hunger and satiety) and the myoelectric rhythm (produced primarily by the pineal gland during the dark period of the light-dark cycle). This appears to be an endocrine encoding of the environmental light-dark cycle, conveying photic information which is used by organisms for both circadian and seasonal organization. Motor and secretory activity, as well as the rhythm of cell proliferation in the GIT and liver, are subject to many circadian rhythms, mediated by autonomic cells and some enterohormones (gastrin, ghrelin and somatostatin). Disruption of circadian physiology, due to sleep disturbance or shift work, may result in various gastrointestinal diseases, such as irritable bowel syndrome (IBS), gastroesophageal reflux disease (GERD) or peptic ulcer disease. In addition, circadian disruption accelerates aging, and promotes tumorigenesis in the liver and GIT. Identification of the molecular basis and role of melatonin in the regulation of circadian rhythm allows researchers and clinicians to approach gastrointestinal diseases from a chronobiological perspective. Clinical studies have demonstrated that the administration of melatonin improves symptoms in patients with IBS and GERD. Moreover, our own studies indicate that melatonin significantly protects gastrointestinal mucosa, and has strong protective effects on the liver in patients with non-alcoholic steatohepatitis (NASH). Recently, it has been postulated that disruption of circadian regulation may lead to obesity by shifting food intake schedules. Future research should focus on the role of clock genes in the pathophysiology of the GIT and liver.
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PMID:Gut clock: implication of circadian rhythms in the gastrointestinal tract. 2167 61


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