Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01189 (beta-endorphin)
 21,003 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The purpose of this study was to evaluate the relationship between neuroendocrine function and the beta receptor activity of the lung in a group of 47 pediatric patients with bronchial asthma. It is postulated that since hypothalamic norepinephrine (NE) is known to inhibit corticotropin-releasing hormone (CRH), an increase in brain NE as measured by its metabolite 3-methoxy-4-hydroxy-phenylglycol (MHPG) could reflect the depression of the hypothalamic-pituitary-adrenal (HPA) axis as measured by urinary cortisol levels. Further, since cortisol influences epinephrine formation in the adrenal medulla and since cortisol and epinephrine contribute to beta receptor function, it is further postulated that an increase in brain NE by depressing the HPA axis could thereby, cause a relative decrease in both cortisol and epinephrine with resultant beta receptor dysfunction. In both age groups, the 3- to 11-year-olds and the adolescents, differences in NE were found among the three subgroups (P = .003) with the difference observed only between the wheezing (decreased NE) and control groups (P less than .05). There was a similar difference in MHPG (elevated) among these groups. In a similar manner, the MHPG/NE ratios (elevated) were statistically different in comparing the three groups in the 3- to 11-year-old range. In the adolescent group both the wheezing and nonwheezing groups were comparably elevated and showed statistically significant differences from their controls. The results of this study appear to support the hypothesis and suggests that brain NE may play a pivotal role in the beta-adrenergic dysfunction characteristic of bronchial asthma.
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PMID:Brain norepinephrine: a possible role in bronchial asthma. 335 38

Theophylline is thought to improve asthma by increasing intracellular cyclic adenosine 3'-5'-monophosphate (cAMP) levels. It has been demonstrated in experimental animals that elevation of intracellular cAMP in the adrenal cortex causes an increased secretion of cortisol. We studied whether therapeutic doses of theophylline given intravenously and orally to human subjects over 3 days would increase cortisol secretion. A single-blind, 6-day protocol was employed in five normal and five asthmatic volunteers. Adrenal function was monitored by 8 A.M. and 4 P.M. serum cortisol and adrenocorticotropic hormone (ACTH) levels; daily 24-hr urine for urinary-free cortisol (UFF), 17-hydroxysteroids (17-OH), and 17-ketosteroids (17-KS); and alternate-day cortisol secretory rates (FSR) measured by isotope dilution after intravenous 14C-cortisol. Serum theophylline concentration also was monitored. Results in normal and asthmatic subjects were similar. Theophylline caused a significant but transient increase in UFF and 17-OH excretion. Urine volumes also increased significantly, suggesting that the renal effect of theophylline accounted for the increased UFF and 17-OH excretion. FSR increased during the first 24 hr after theophylline in eight of nine cases (p < 0.05 by sign test), mean values increasing from 14.2 to 19.3 mg, but this effect had dissipated by day 3 of theophylline administration. In contrast to these findings, theophylline had no effect on serum cortisol or ACTH or urinary 17-KS. It is likely that serum cortisol and ACTH remained unchanged because the increase in cortisol secretion was offset by a concomitant increase in cortisol clearance. It is concluded that theophylline produces a small, transient increase in cortisol secretion and clearance, and this effect is similar in asthmatic and normal subjects.
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PMID:Effect of theophylline on cortisol secretion. 625 23

Serum beta-endorphin was measured by radioimmunoassay in 25 patients with atopic dermatitis and 100 healthy subjects. The neuropeptide was found to be markedly (p < 0.001) increased in patients with atopic dermatitis (9.2 +/- 3.4 pg/ml) as compared to normal controls (6.1 +/- 1.5 pg/ml). A correlation between increased serum beta-endorphin concentration and some clinical parameters of the disease has been found. The statistically significant elevation of beta-endorphin was found in patients with widespread atopic dermatitis lesions involving more than 20% of the skin surface (11.1 +/- 3.6 pg/ml), a high disease severity score (10.7 +/- 3.7 pg/ml), and previous bronchial asthma symptoms (11.6 +/- 3.1 pg/ml). A possible explanation of increased beta-endorphin is either its generation in atopic dermatitis lesions by inflammatory cells or activation of pituitary-adrenal axis by psychoneural factors in the mechanism of chronic stress.
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PMID:Increased concentration of beta-endorphin in the sera of patients with severe atopic dermatitis. 774 53

In the current investigation an approach has been made to explore possible relations between musical talent, left-handedness, anomalous dominance for verbal materials, and immune vulnerability. Fifty-one young adult musicians and non-musicians were tested with Wing's Standardized Tests of Musical Intelligence, with a handedness questionnaire, a dichotic listening task, and with a questionnaire assessing asthma/allergies, migraine and myopia. In addition, IgE, Ig total, beta-endorphin, testosterone, and estradiol were measured in blood serum. Musical talent was related to left-handedness and to anomalous dominance; immune vulnerability was found in female musicians, and in subjects with reversed dominance for language functions as well as in male left-handers, independently of musical talent.
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PMID:Functional brain organization, handedness, and immune vulnerability in musicians and non-musicians. 837 39

We have examined whether the lack of clinical response to corticosteroids seen in corticosteroid resistant (CR) bronchial asthma is reflected in abnormalities of endogenous cortisol secretion and in the sensitivity of the hypothalamic-pituitary-adrenal (HPA) axis in CR subjects by using a modification of the standard dexamethasone suppression test (DST) in response to 0.25 and 1 mg oral dexamethasone. Five corticosteroid-sensitive (CS) and five CR asthmatic subjects were studied on two occasions 1 mo apart. In the first limb of the study subjects received 0.25 mg of oral dexamethasone, and in the second limb they received 1 mg. Urinary cortisol was measured by fluorimetry after extraction, and plasma cortisol and adrenocorticotropic hormone (ACTH) concentrations were estimated by enzyme-linked immunosorbent assay (ELISA) and immunoradiometric assays, respectively. On Day 1, a 24-h urine sample was collected for estimation of urinary free cortisol. On Day 2, a fasting blood sample was taken at 9:00 A.M. for estimation of plasma cortisol and ACTH. At 11:00 P.M., 0.25 mg (1 mg) of dexamethasone was taken orally by each subject. On Day 3, blood was taken at 9:00 A.M. and 3:00 P.M. for similar estimations. The levels of urinary free cortisol (nmol/24 h) and predose plasma ACTH (ng/L) and cortisol (nmol/L) were 199 +/- 42, 27.4 +/- 5.7, and 300 +/- 48 (mean +/- SEM), respectively, in the CS group, and 210 +/- 74, 23.4 +/- 6.7, and 263 +/- 32 (mean +/- SEM), respectively, in the CR group (p > 0.05 for all comparisons). Plasma ACTH and cortisol concentrations were not significantly suppressed in either group after 0.25 mg dexamethasone, but were equally suppressed in both groups to undetectable levels by 1 mg dexamethasone. We conclude that CR asthma is not reflected in an altered secretory rate of endogenous cortisol or in an altered sensitivity of the HPA axis to dexamethasone suppression.
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PMID:Hypothalamic-pituitary-adrenal axis in corticosteroid-resistant bronchial asthma. 856 97

Gastroesophageal reflux and pulmonary disease have become causally associated owing to reports of improved pulmonary function in patients with asthma or stridor following antireflux pharmacotherapy or surgery. Mechanisms by which reflux causes pulmonary disease include direct aspiration and neural reflex arcs. A novel additional mechanism for acute life-threatening episodes implicates increased beta-endorphin levels resulting from acid-mediated esophageal pain in the depression of respiratory drive. Diagnostic modalities used in the evaluation of reflux have often been inadequate to demonstrate a cause-and-effect relationship between reflux and pulmonary disease. Recent studies using multiple site pH-metry have attempted to provide evidence for cause and effect but have achieved mixed results. Aggressive antireflux pharmacotherapy and, sometimes, surgery help those patients with chronic pulmonary disease mediated by gastroesophageal reflux.
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PMID:Evaluation and management of gastroesophageal reflux and pulmonary disease. 881 96

Current evidence indicates that the neuroendocrine system is the highest regulator of immune/inflammatory reactions. Prolactin and growth hormone stimulate the production of leukocytes, including lymphocytes, and maintain immunocompetence. The hypothalamus-pituitary-adrenal axis constitutes the most powerful circuit regulating the immune system. The neuropeptides constituting this axis, namely corticotrophin releasing factor, adrenocorticotrophic hormone, alpha-melanocyte stimulating hormone, and beta-endorphin are powerful immunoregulators, which have a direct regulatory effect on lymphoid cells, regulating immune reactions by the stimulation of immunoregulatory hormones (glucocorticoids) and also by acting on the central nervous system which in turn generates immunoregulatory nerve impulses. Peptidergic nerves are major regulators of the inflammatory response. Substance P and calcitonin gene-related peptide are pro-inflammatory mediators and somatostatin is anti-inflammatory. The neuroendocrine regulation of the inflammatory response is of major significance from the point of view of immune homeostasis. Malfunction of this circuit leads to disease and often is life-threatening. The immune system emits signals towards the neuroendocrine system by cytokine mediators which reach significant blood levels (cytokine-hormones) during systemic immune/inflammatory reactions. Interleukin-1, -6, and TNF-alpha are the major cytokine hormones mediating the acute phase response. These cytokines induce profound neuroendocrine and metabolic changes by interacting with the central nervous system and with many other organs and tissues in the body. Corticotrophin releasing factor functions under these conditions as a major co-ordinator of the response and is responsible for activating the ACTH-adrenal axis for regulating fever and for other CNS effects leading to a sympathetic outflow. Increased ACTH secretion leads to glucocorticoid production. alpha-melanocyte stimulating hormone functions under these conditions as a cytokine antagonist and an anti-pyretic hormone. The sympathetic outflow, in conjunction with increased adrenal activity. leads to the elevation of catecholamines in the bloodstream and in tissues. Current evidence suggests that neuroimmune mechanisms are essential in normal physiology, such as tissue turnover, involution, atrophy, intestinal function, and reproduction. Host defence against infection, trauma and shock relies heavily on the neuroimmunoregulatory network. Moreover, abnormalities of neuroimmunoregulation contribute to the aetiology of autoimmune disease, chronic inflammatory disease, immunodeficiency, allergy, and asthma. Finally, neuroimmune mechanisms play an important role in regeneration and healing.
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PMID:The immune effects of neuropeptides. 891 48

ANAESTHETICS, ENDOCRINE SYSTEM, AND STRESS: The effects of anaesthetics on the nervous system are invariably associated with endocrine reactions, which are of great importance for the general characterization of anaesthetics or anaesthetic regimens. In this context, the endocrine stress response is mainly represented by adrenaline (A), noradrenaline (NA), antidiuretic hormone/vasopressin (ADH), adrenocorticotropic hormone (ACTH), and cortisol. PHARMACOLOGICAL PROFILE AND ANAESTHETIC ACTION OF KETAMINE: The pharmacological profile of ketamine is characterized by the term "dissociative anaesthesia." At the present time, the anaesthetic action of ketamine cannot be explained by a single mechanism. Its overall action might be due to different central and peripheral factors, and stereospecific effects are obvious. ENDOCRINE RESPONSES TO RACEMIC KETAMINE AND S(+)-KETAMINE: In contrast to stereospecific differences in the anaesthetic action of racemic ketamine and S-(+)-ketamine, the endocrine reactions to the S-(+) isomer and the racemic mixture are very similar. When S(+)-ketamine is used as the sole anaesthetic, significant activation of the sympathoadrenergic system with increases in plasma levels of A and NA can be observed. This effect is mitigated by midazolam. In combination with propofol, sympathoadrenergic responsiveness is preserved without overwhelming effects. In contrast to monoanaesthesia with S(+)-ketamine, during combination with midazolam and propofol significant increases in plasma ADH levels are observed, which might be due to suppressed sympathoadrenergic reactivity. In addition, surgical stress activates the pituitary-adrenocortical system with increases in ACTH and cortisol. Effects of midazolam and propofol on this effect are similar. SYNOPSIS AND CLINICAL ASPECTS: S-(+)-ketamine as a monoanaesthetic has significant sympathomimetic properties, which are beneficial during induction of patients in shock and patients with asthma. The combination of S-(+)-ketamine and midazolam has weaker sympathomimetic and general endocrine-stimulating properties, and can be used for analgosedation in patients with cardiovascular instability and exogenous catecholamine requirements. In combination with propofol, the sympathomimetic and general endocrine-stimulating effects of S-(+)-ketamine are less pronounced because of contrasting properties of both drugs. This combination might be useful in patients with endocrine deficits and for analgosedation, when rapid recovery is necessary and negative circulatory effects should be avoided.
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PMID:[Endocrine reactions following S-(+)-ketamine]. 916 76

Glucocorticoids (GC) play an important role in the treatment of inflammatory diseases like asthma. However, in selected patients a relative resistance to GC has been reported. Recently, it has been suggested that GC sensitivity of peripheral blood leucocytes may be regulated in a dynamic fashion during exercise, in association with activation of the hypothalamic-pituitary-adrenal (HPA) axis. The aim of the present study was to explore changes in the GC sensitivity of cytokine production by leucocytes following strenuous exercise by well trained oarsmen. These changes were studied using lipopolysaccharide (LPS)-induced and anti-CD2/anti-CD28 MoAb-stimulated cytokine release in whole blood and its modulation by dexamethasone. Following exercise, significant decreases in LPS-induced release of IL-6, tumour necrosis factor-alpha (TNF-alpha) and IL-10 and anti-CD2/anti-CD28 MoAb-stimulated secretion of interferon-gamma (IFN-gamma) were observed. In addition, the inhibitory effect of dexamethasone on both IL-6 and TNF-alpha secretion was significantly reduced following exercise, whereas that on IL-10 and IFN-gamma release was not affected. These exercise-induced changes were accompanied by activation of the HPA axis, as indicated by an increase in circulating adrenocorticotropic hormone (ACTH) levels immediately following exercise. The results from the present study suggest that GC sensitivity of whole blood cytokine release can be regulated in a dynamic fashion and that this can be assessed using an ex vivo stimulation assay. Moreover, since dexamethasone responsiveness of anti-CD2/anti-CD28 MoAb-induced IFN-gamma secretion in whole blood is not affected by exercise, it may suggest that exercise differentially affects monocytes and lymphocytes. The dynamic regulation of steroid responsiveness of leucocytes, as observed in the present study, could have important consequences for the effectiveness of GC treatment in inflammatory diseases.
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PMID:Cytokine release and its modulation by dexamethasone in whole blood following exercise. 948 20

Stress worsens certain disorders such as migraines or asthma, and has also been implicated in sudden myocardial arrest. It was previously shown that acute psychological stress by immobilization results in dura mast cell degranulation, an effect blocked by pretreatment with antiserum against corticotropin-releasing hormone (CRH). Moreover, CRH was recently shown to induce skin mast cell degranulation. The effect of psychological stress was investigated on rat cardiac mast cells, because their release of coronary constrictive and proinflammatory molecules contributes to myocardial ischemia and possibly arrhythmias. Immobilization of rats for 30 min induced maximal cardiac mast cell degranulation as evidenced by light and electron microscopy. This effect was inhibited by pretreatment with the "antiallergic" drug sodium cromoglycate (cromolyn), which is thought to act primarily through mast cell stabilization. Mast cell degranulation was also blocked by preincubation with antiserum against CRH and was partially inhibited by a CRH type-1 receptor selective antagonist. Sensory neuropeptides did not appear to influence this effect, but a nonpeptide neurotensin receptor antagonist blocked stress-induced cardiac mast cell degranulation. This finding supports the involvement of neuropeptide neurotensin which is present in the heart and is known to trigger mast cell degranulation. These results indicate acute stress could result in local CRH and nonpeptide neurotensin release which could contribute to myocardial pathophysiology through direct or indirect release of cardiac mast cell mediators.
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PMID:A neurotensin receptor antagonist inhibits acute immobilization stress-induced cardiac mast cell degranulation, a corticotropin-releasing hormone-dependent process. 976 51


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