UNIPROT:P61278 - FACTA Search

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Query: UNIPROT:P61278 (somatostatin)
22,083 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Epinephrine and TRH independently release TSH from rat anterior pituitary cells in primary monolayer culture (ED50, 11 and 5 nM, respectively; maximum responses, 80% and 110%, respectively). The effects of these compounds together are additive, even at concentrations at which each is maximally effective alone. Dopamine inhibited basal and epinephrine-stimulated TSH secretion by 25 +/- 5% (+/-SE; ED50, 50 +/- 9 nM in each case). Somatostatin was effective against epinephrine-stimulated, but not basal, TSH secretion (80 +/- 4% inhibition; ED50, 1 +/- 3 nM). The data show that epinephrine is a potential regulator of TSH secretion by its own action and via its interactions with TRH, dopamine, and somatostatin.
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PMID:Interactions among epinephrine, thyrotropin (TSH)-releasing hormone, dopamine, and somatostatin in the control of TSH secretion in vitro. 614 35

The metabolic effects of dopamine have been investigated by its infusion in normal man with and without simultaneous somatostatin administration. Dopamine was infused into overnight fasted men at 1.5 microgram/kg/min (n = 6) and 3.0 micrograms/kg/min (n = 5) for 120 min. Plasma dopamine concentrations at 120 min were 78 +/- 9 nmol/l and 117 +/- 17 nmol/l respectively, associated with a marginal rise in plasma noradrenaline. Dopamine (1.5 microgram/kg/min) induced an early and sustained rise in plasma glucagon (48 +/- 9 pg/ml versus 19 +/- 6 pg/ml in saline controls at 10 min, p less than 0.01) and a transient elevation in serum growth hormone which peaked to 17.7 (range 4.5-71.8) mU/l at 60 min (7.2 (range 0.6-37.7) mU/l with saline, p less than 0.05) but did not alter serum insulin, blood glucose or other metabolite levels. At 3.0 micrograms/kg/min, dopamine in addition provoked mild and transient elevations in blood glucose and serum insulin. Somatostatin (250 micrograms/h) suppressed circulating insulin, glucagon, and growth hormone levels and abolished the small hyperglycaemic effect seen with the higher dopamine dose. Somatostatin alone induced a progressive rise in circulating non-esterified fatty acid and 3-hydroxybutyrate levels reflecting insulin deficiency. This rise in NEFA and 3-hydroxybutyrate was increased by dopamine particularly at the higher dosage (plasma NEFA; somatostatin alone, 1.08 +/- 0.13 mmol/l; somatostatin plus dopamine 3 micrograms/kg/min, 1.44 +/- 0.17 mmol/l at 120 min, p less than 0.01: blood 3-hydroxybutyrate; somatostatin alone, 0.32 +/- 0.04 mmol/l; somatostatin plus dopamine 3 micrograms/kg/min, 0.56 +/- 0.12 mmol/l at 120 min, p less than 0.05). Thus: 1) dopamine at pharmacological dosage has minor effects when other endocrine mechanisms are intact, 2) it enhances lipolysis and ketogenesis during somatostatin-induced insulin deficiency; 3) the hyperglycaemia effect of the higher dopamine dose is probably mediated through stimulated glucagon secretion.
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PMID:The metabolic effects of dopamine in man. 614 68

The mechanism of postinhibitory rebound increase in GH secretion was studied in 5 normal and 7 acromegalic subjects. Both normal and acromegalic subjects showed prompt GH decreases during the infusion of somatostatin (500 micrograms/75 min) (% decrease: 69.1 +/- 10.4 vs. 73.9 +/- 6.5) and rebound rises after its termination. The rebound rises occurred more promptly and markedly in normal controls than in acromegalic subjects, i.e. the rebound peak appeared at 15 min in normal controls and at 45 min in acromegalic patients after the cessation of somatostatin infusion. Dopamine (DA) infusion (5 micrograms/kg/min for 90 min) also induced similar inhibition and postinhibitory rebound rises in GH secretion in 6 patients with acromegaly. Although the maximum inhibitions (67.1 +/- 7.3% vs. 73.7 +/- 7.1%) and the inhibitory areas (4354.5 +/- 471.0% . min vs. 3796.5 +/- 322.5% . min) during the DA and somatostatin infusions were not different, the rebound at 15 min was significantly greater after DA than after somatostatin (p less than 0.05). All seven patients with acromegaly were TRH responsive in their plasma GH (% of basal: 93.5 to 944.3). When TRH was injected at the termination of somatostatin infusion, the rebound increase was significantly enhanced and the rebound peak appeared 30 min earlier than after single somatostatin administration. These results indicate that the mechanisms participating in the postinhibitory rebound rise are different in normal controls and acromegalic patients, and that the magnitude of the rebound differs with agents employed. Also, it is evident that the rebound phenomenon in acromegaly is possibly modified by exogenous hypothalamic releasing factors.
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PMID:The mechanism of postinhibitory rebound increases in plasma gh in acromegalic patients. 614 95

Prolactin secretion from ovine pituitary cell cultures was stimulated by thyrotropin-releasing hormone (TRH) (10(-10)-10(-7) M) with a half-maximal effect at approximately 2.5 X 10(-9) M. A maximally effective concentration of TRH produced a peak secretory response, 5-10-fold stimulation over basal release, within 15 min. Dopamine (10(-10)-10(-7) M) but not somatostatin caused a dose-related inhibition of TRH (10(-8) M) stimulated prolactin release. Both dopamine (10(-7) M) and somatostatin (10(-7) M) inhibited basal secretion from the cells. TRH did not significantly increase pituitary cell cyclic AMP levels under any of the conditions tested. Stimulation of prolactin secretion by TRH was not prevented when Ca2+ was omitted from the incubation medium. Dopamine inhibited secretion induced by TRH under low Ca2+ conditions. Our results are consistent with a hypothesis that TRH may stimulate prolactin secretion via release of intracellular Ca2+ rather than increased cellular Ca2+ uptake, and imply that dopamine inhibition involves a lowering of intracellular Ca2+ levels.
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PMID:Studies of TRH-induced prolactin secretion and its inhibition by dopamine, using ovine pituitary cells. 614 44

Pituitary glands of grassfrog (Rana pipiens), bullfrog (Rana catesbeiana), clawed toad (Xenopus laevis) and two species of terrapin (Chrysemys picta and Pseudemys scripta) were incubated in medium containing hypothalamic extract (HE), thyrotrophin releasing hormone (TRH), somatostatin, dopamine, or combinations of these treatments. Prolactin and GH concentrations in the medium were determined by densitometry after polyacrylamide-gel electrophoretic separation. Hypothalamic extract stimulated secretion of both hormones in all species tested. Thyrotrophin releasing hormone stimulated secretion of prolactin and GH, showing a biphasic pattern of response. Dopamine had little effect alone, but inhibited HE- and TRH-stimulated release of prolactin, but not GH, in both amphibia and reptiles. Somatostatin by itself had no apparent effect on release of hormones, but it inhibited HE- and TRH-stimulated release of GH from both amphibian and reptilian pituitary glands. These results indicate that factors affecting mammals and birds also interact in the regulation of secretion of prolactin and GH in lower vertebrate species.
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PMID:Effects of synthetic mammalian thyrotrophin releasing hormone, somatostatin and dopamine on the secretion of prolactin and growth hormone from amphibian and reptilian pituitary glands incubated in vitro. 614 54

Ketogenesis may be controlled at several sites. Lipolysis with release of plasma nonesterified fatty acid (NEFA) substrate is the first step. Plasma NEFA are taken up by the liver in a concentration-dependent fashion and, after conversion to the acyl-CoA derivative, may either be reesterified or enter the mitochondria via the carnitine shuttle. After beta-oxidation the resultant acetyl-CoA may either be converted to ketone bodies that are then released into the circulation or be condensed with oxaloacetate and enter the tricarboxylic acid cycle, the third potential control point. In humans, infusion of epinephrine causes a transient two- to threefold increase in fatty acids, glycerol, and ketone bodies. Insulin levels show a small absolute increase. Norepinephrine has similar effects, although insulin levels tend to be suppressed and glucagon levels rise somewhat. If somatostatin is added simultaneously, the lipolytic and ketogenic effects are accentuated and prolonged. Dopamine, in a high dose, has no effect on ketone bodies alone but shows small increases in NEFA and ketone bodies in the presence of somatostatin and may play a modulatory role in ketogenesis. The ketogenic effect of catecholamines could thus be in the adipocyte or in the liver. Studies with perfused liver or hepatocytes showed only trivial effects on ketogenesis even with supraphysiological doses of catecholamines. Furthermore infusion studies in rats showed decreased rather than increased ketogenesis with no change in NEFA levels. The data suggest that a) there are species differences, and b) in humans epinephrine- and norepinephrine-induced increases in ketogenesis are secondary to increases in NEFA substrate supply.
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PMID:Mechanisms of catecholamine effects on ketogenesis. 614 93

To evaluate the GH regulating mechanism in acromegalic patients, post-inhibitory rebound rise in GH secretion induced by somatostatin was studied in these cases and normal subjects, and was compared with the rebound GH rise induced by dopamine. After somatostatin infusion (500 micrograms/75 min) both 5 normal and 9 acromegalic subjects showed prompt GH decreases during the infusion (% decrease: 69.1 +/- 10.4 vs 74.4 +/- 5.1) and showed rebound rises after its termination. However, the rebound rises occurred more promptly and markedly in normal controls than in acromegalic patients, i.e. the rebound peak appeared at 45 min in normal controls and at 75 min in acromegalic patients after the cessation of somatostatin infusion. Dopamine (DA) infusion (5 micrograms/kg/min for 90 min) also induced similar inhibition and postinhibitory rebound rises in GH secretion in 7 patients with acromegaly. Although the maximum inhibition (65.6 +/- 6.4% vs 74.4 +/- 5.1%) and the inhibitory area (4338.0 +/- 481.5% X min vs 3682.5 +/- 295.5% X min) during the DA or somatostatin infusion were not different, the rebound at 15 min was significantly greater after DA than after somatostatin (p less than 0.02). When TRH was injected at the termination of somatostatin infusion, the rebound increase was significantly enhanced and the rebound peak appeared 45 min earlier than after a single somatostatin administration. Similarly, hp GRF (1-44)-NH2 enhanced the postinhibitory rebound rises in 4 patients studied.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Modulation of postinhibitory rebound rise in plasma GH by hypothalamic hormones in patients with acromegaly. 615 22

The distribution of immunofluorescent somata and processes within the interpeduncular nucleus (IPN) containing substance P (SP), cholecystokinin (CCK), vasoactive intestinal peptide (VIP), somatostatin (SST), leu-enkephalin (L-ENK), dopamine beta hydroxylase (DBH), and serotonin (5HT) was examined in male rats treated with colchicine 48 hours prior to perfusion. Serial sections were examined for immunofluorescence and variations in the density of fluorescence rated 1 + (sparse) to 4 + (dense). The rostral subnucleus contained SP, SST, and L-ENK-positive somata and processes. Substance P and VIP processes were present throughout the rostral subnucleus but were concentrated in two ovoid areas located dorsally in the caudal region of this subnucleus. Cholecystokinin and L-ENK processes surrounded these ovoid areas. The entire width of the central subnucleus was crossed by SP and L-ENK processes oriented horizontally in narrow bands. Substance P processes were also aligned into vertical columns adjacent to the lateral margins of the central subnucleus. Leu-enkephalin and 5HT processes were distributed throughout this subnucleus, while VIP processes were present only caudally. Dopamine beta hydroxylase processes were evenly distributed but were restricted from the vertical columns laterally. The intermediate subnuclei contained a sparse density of SP and 5HT processes that were present in proximity to the major blood vessels penetrating this subnucleus. Only DBH processes were evenly distributed. The lateral subnuclei contained a dense concentration of SP processes. The medial edges of this subnucleus were distinguished by VIP, CCK, L-ENK, and 5HT processes. The dorsal subnucleus contained 5HT, L-ENK, and SST-positive somata and processes. Substance P, VIP, CCK, and DBH processes were also present. Dorsal-lateral subnuclei contained SP, SST, L-ENK, and DBH processes. Interstitial subnuclei contained SP, CCK, L-ENK, 5HT, and DBH processes. This study demonstrates that perikarya and processes containing peptides and monoamines are distributed within subnuclei of IPN in a topographic and heterogeneous pattern. New features of IPN organization are revealed.
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PMID:The subnuclear distribution of substance P, cholecystokinin, vasoactive intestinal peptide, somatostatin, leu-enkephalin, dopamine-beta-hydroxylase, and serotonin in the rat interpeduncular nucleus. 620 27

Two recent developments in the medical treatment of patients with pituitary disease are discussed. Conventional treatment for patients with acromegaly has been surgery and/or radiotherapy. Dopamine agonist therapy may be useful. Somatostatin is a naturally occurring neuropeptide that inhibits growth hormone (GH) secretion. The development of long-acting preparations has resulted in a considerable advance in the medical treatment of acromegaly, though some caution remains about the long-term side-effects of such therapy (e.g. cholelithiasis) and its cost/benefit analysis. Although further epidemiological studies are required, hypopituitarism appears to be associated with an increased mortality rate, and this has largely been attributed to GH deficiency. With the widespread availability of recombinant GH (thereby circumventing any risks from cadaveric GH) many adult GH-deficient patients are now being treated. Beneficial effects on body composition, nitrogen and calcium balance and bone mass have already emerged, although studies on 'well being' have been conflicting. The debate continues concerning the minimum effective dose and who exactly should be treated, in view of the costs incurred. The endocrinologists' use of long-acting somatostatin analogues and recombinant GH will undoubtedly increase over the next few years. Whilst it is clear that many patients with both acromegaly and hypopituitarism will benefit, long-term controlled trials are still required to establish firmly the benefit in terms of major morbidity.
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PMID:Advances in medical therapy for pituitary disease: treating patients with growth hormone excess and deficiency. 810 42

There is compelling evidence that excessive exposure to manganese (Mn) produces neurotoxicity, especially in the basal ganglia, resulting in a dystonic Parkinsonian disorder. Several experimental or clinical observations suggest that Mn neurotoxicity could involve impairment of energy metabolism. We examined the neurotoxic effects of Mn following local intrastriatal injection. Three hours after the injection of 2 mumol of MnCl2 into rat striatum, ATP levels were reduced to 51% of the control side and lactate level were increased by 97%, indicating an impairment of oxidative metabolism. Neurochemical analysis of the striata 1 week after Mn injection showed changes consistent with a N-methyl-D-aspartate (NMDA) excitotoxic lesion. Dopamine, gamma-aminobutyric acid, and substance P concentrations showed dose-dependent significant decreases, but concentrations of somatostatin-like immunoreactivity and neuropeptide Y-like immunoreactivity were unchanged. The lesions were blocked by prior removal of the cortico-striatal glutamatergic input or by treatment with the noncompetitive NMDA antagonist MK-801. These findings indicate that Mn neurotoxicity involves a NMDA receptor-mediated process similar to that we have previously found with two characterized mitochondrial toxins, aminooxyacetic acid, and 1-methyl-4-phenylpyridinium. Our results show that Mn may produce neuronal degeneration by an indirect excitotoxic process secondary to its ability to impair oxidative energy metabolism.
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PMID:Manganese injection into the rat striatum produces excitotoxic lesions by impairing energy metabolism. 847 30

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