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Query: UNIPROT:P61278 (
somatostatin
)
22,083
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
To determine the relationship between decreases in glucose and metabolic regulation in the absence of counterregulatory hormones, we infused overnight-fasted, conscious, adrenalectomized dogs (lacking cortisol and EPI) with
somatostatin
(to eliminate glucagon and growth hormone) and intraportal insulin (30 pmol.kg-1.min-1), creating arterial insulin levels of approximately 2000 pM. Glucose was infused during one 120-min period, two 90-min periods, and one 45-min period to establish levels of 5.9 +/- 0.1, 3.4 +/- 0.1, 2.5 +/- 0.1, and 1.7 +/- 0.1 mM, respectively. NE levels were 1.24 +/- 0.23, 1.85 +/- 0.27, 2.04 +/- 0.26, and 2.50 +/- 0.20 nM, respectively. During the euglycemic control period, the liver took up glucose (7.5 +/- 1.9 mumol.kg-1.min-1), but hypoglycemia triggered successively greater rates of net hepatic glucose output (3.0 +/- 0.7, 4.6 +/- 0.9, and 6.9 +/- 1.4 mumol.kg-1.min-1). Total gluconeogenic precursor uptake by the liver increased with hypoglycemia. Intrahepatic gluconeogenic efficiency rose progressively (by 106 +/- 42, 199 +/- 56, and 268 +/- 55%). Both glycerol and
NEFA
levels rose, indicating lipolysis was enhanced. Net hepatic
NEFA
uptake and ketone production increased proportionally, but the ketone level rose only with severe hypoglycemia. In conclusion, despite marked hyperinsulinemia and the absence of glucagon, EPI, and cortisol, we observed that lipolysis and glucose and ketone production increase in response to decreases in glucose. This suggests that neural and/or autoregulatory mechanisms can play a role in combating hypoglycemia.
...
PMID:Relationship between decrements in glucose level and metabolic response to hypoglycemia in absence of counterregulatory hormones in the conscious dog. 139 5
The metabolic responses to 4-h infusions of adrenaline (3 micrograms kg-1 h-1) and cortisol (10 mg m-2 h-1 for 2 h followed by 5 mg m-2 h-1 for 2 h), separately and in combination, have been studied in six healthy subjects with concurrent
somatostatin
infusion (250 micrograms h-1). A combined infusion of adrenaline, cortisol, glucagon (180 ng kg-1 h-1) and
somatostatin
has also been studied.
Somatostatin
plus adrenaline and
somatostatin
plus cortisol resulted in hyperglycaemia (at 240 min,
somatostatin
plus adrenaline 11.4 +/- 0.4 mmol l-1, P less than 0.001;
somatostatin
plus cortisol 6.7 +/- 0.3 mmol l-1, P less than 0.05;
somatostatin
alone 4.9 +/- 0.4 mmol l-1). No synergistic effect on blood glucose was seen with adrenaline and cortisol together. When glucagon was added, blood glucose rose more rapidly than without glucagon (9.3 +/- 0.4 mmol l-1 v. 7.2 +/- 0.5 mmol l-1 at 45 min, P less than 0.001), but plateau values were similar. Plasma
NEFA
levels were raised by
somatostatin
plus adrenaline (0.55 +/- 0.04-1.82 +/- 0.11 mmol l-1 at 60 min).
Somatostatin
plus cortisol had no more effect on plasma
NEFA
than
somatostatin
alone. During the combined infusion of
somatostatin
plus adrenaline plus cortisol, a synergistic effect on plasma
NEFA
was observed (2.30 +/- 0.11 mmol l-1 at 60 min, P less than 0.01 v.
somatostatin
plus adrenaline). This occurred despite a small escape of insulin secretion. The lipolytic actions of adrenaline are potentiated by elevated circulating cortisol levels in insulin-deficient man.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Interactions of stress hormones on lipid and carbohydrate metabolism in man with partial insulin deficiency. 287 80
The metabolic response to pathophysiologic concentrations of glucagon, induced by glucagon infusion, has been examined in normal man before and after 36-60 hr hypercortisolaemia, induced by administration of tetracosactrin-depot. Glucagon alone increased serum insulin levels twofold but blood glucose was unaltered. Plasma
NEFA
and blood ketone body concentrations were decreased by glucagon infusion. Tetracosactrin produced a threefold rise in serum cortisol levels and caused mild fasting hyperglycemia and hyperinsulinaemia. Subsequent glucagon infusion had no effect on circulating insulin, glucose,
NEFA
or ketone body concentrations. Simultaneous infusion of
somatostatin
, to produce partial insulin-deficiency, unmasked a hyperglycemic action of glucagon (+ 3.8 +/- 0.2 mmol/l at 90 min, p less than 0.02). This glucagon-induced rise in blood glucose was diminished by prior tetracosactrin administration. Tetracosactrin revealed a mild lipolytic action of glucagon in partial insulin deficiency, not apparent in the euadrenal state. Glucagon was equally hyperketonemic during
somatostatin
infusion before and after tetracosactrin. Thus the hyperglycemic and hyperketonemic actions of glucagon at pathophysiologic levels are restricted to insulin deficiency. Hypercortisolaemia reveals a lipolytic action of glucagon in insulin-deficient man but does not potentiate the hyperglycemic or hyperketonemic effects.
...
PMID:Metabolic interactions of glucagon and cortisol in man--studies with somatostatin. 612 61
The metabolic effects of chronic hypercortisolaemia were studied by administration of tetracosactrin-depot, 1 mg I.M. daily for 36-60 hr to normal subjects. Partial insulin and glucagon deficiency were induced at the end of the period by infusion of
somatostatin
, 100 micrograms/h for 210 min. Tetracosactrin alone induced a three fold rise in basal serum cortisol levels and fasting blood glucose concentration rose from 5.2 +/- 0.2 to 7.2 +/- 0.2 mmole/l (p less than 0.01) with a rise in fasting serum insulin from 5.2 +/- 1.2 to 13.1 +/- 1.9 mU/l (p less than 0.02). Concentrations of the gluconeogenic precursors lactate, pyruvate and alanine were also raised, but non-esterified fatty acid, glycerol and ketone body levels were unchanged.
Somatostatin
infusion caused a 30%-50% decrease in serum insulin and a 20%-60% decrease in plasma glucagon concentrations both before and after tetracosactrin administration. A similar rise in blood glucose concentration, relative to the saline control, occurred over the period of
somatostatin
infusion both with and without elevated cortisol levels. However, prior tetracosactrin administration caused a 100% greater rise in blood ketone body concentrations during infusion of
somatostatin
than was seen in the euadrenal state, despite similar plasma
NEFA
concentrations. Hypercortisolaemia causes hyperglycaemia and elevated gluconeogenic precursor concentrations but the associated rise in serum insulin concentrations limits lipolysis and ketosis. In insulin deficiency, a ketotic effort of glucocorticoid excess is evident which may be independent of lipolysis and occurs despite concurrent glucagon deficiency. These catabolic actions of cortisol are likely to be of major importance in the metabolic response to stress.
...
PMID:Metabolic effects of cortisol in man--studies with somatostatin. 612 62
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.
...
PMID:The metabolic effects of dopamine in man. 614 68
Eight crossbred wethers (51 +/- 2 kg BW), surgically fitted with abomasal cannulas, were used to determine the extent and time course of cysteamine (CSH)-induced depletion of
somatostatin
(SRIF) in abomasal tissue and associated changes in plasma metabolites, insulin, and growth hormone (GH). Cysteamine was administered as a single i.v. bolus (50 mg.kg BW-1 x 10 min-1) on d 0. Abomasal biopsies were obtained on d -7, -3, 0, 1, 3, and 10. On d 0, additional biopsies were taken at 2, 4, and 8 h after CSH administration. Jugular blood samples were collected over 8 h at 15-min intervals on d -2, 0, and 1. Cysteamine administration decreased (P < .05) tissue SRIF on d 0 (2, 4, and 8 h), 1, and 3; maximal depletion (42 to 55% of Pre-treatment; Pre-trt) occurred during the initial 24 h, returning to Pre-trt by d 10. Gel chromatography of pooled -7 d abomasal tissue extracts showed five peaks of SRIF immunoreactivity; the predominate peak eluted in the same position as synthetic SRIF-14. Plasma glucose, lactate, and
NEFA
concentrations increased (P = .001) after CSH administration and reached peak at 2 h after treatment and declined to Pre-trt concentrations by 24 h. Insulin increased (P = .001) to a maximum at h 4 and returned to Pre-trt by 24 h. Mean and baseline GH were higher (P < .07) on day of CSH administration, and pulse amplitude was lower (P < .10) on d 0 and 1. These data show that CSH rapidly reduces SRIF in abomasal tissue in a reversible manner; suggesting that CSH-treated sheep may provide a SRIF-deficient model for studying the physiological role of SRIF in ruminants.
...
PMID:Cysteamine-induced depletion of somatostatin in sheep: time course of depletion and changes in plasma metabolites, insulin, and growth hormone. 760 57
Growth hormone (GH) secretion, either spontaneous or evoked by provocative stimuli, is markedly blunted in obesity. In fact obese patients display, compared to normal weight subjects, a reduced half-life, frequency of secretory episodes and daily production rate of the hormone. Furthermore, in these patients GH secretion is impaired in response to all traditional pharmacological stimuli acting at the hypothalamus (insulin-induced hypoglycaemia, arginine, galanin, L-dopa, clonidine, acute glucocorticoid administration) and to direct somatotrope stimulation by exogenous growth hormone releasing hormone (GHRH). Compounds thought to inhibit hypothalamic
somatostatin
(SRIH) release (pyridostigmine, arginine, galanin, atenolol) consistently improve, though do not normalize, the somatotropin response to GHRH in obesity. The synthetic growth hormone releasing peptides (GHRPs) GHRP-6 and hexarelin elicit in obese patients GH responses greater than those evoked by GHRH, but still lower than those observed in lean subjects. The combined administration of GHRH and GHRP-6 represents the most powerful GH releasing stimulus known in obesity, but once again it is less effective in these patients than in lean subjects. As for the peripheral limb of the GH-insulin-like growth factor I (IGF-I) axis, high free IGF-I, low IGF-binding proteins 1 (IGFBP-1) and 2 (IGFBP-2), normal or high IGFBP-3 and increased GH binding protein (GHBP) circulating levels have been described in obesity. Recent evidence suggests that leptin, the product of adipocyte specific ob gene, exerts a stimulating effect on GH release in rodents; should the same hold true in man, the coexistence of high leptin and low GH serum levels in human obesity would fit in well with the concept of a leptin resistance in this condition. Concerning the influence of metabolic and nutritional factors, an impaired somatotropin response to hypoglycaemia and a failure of glucose load to inhibit spontaneous and stimulated GH release are well documented in obese patients; furthermore, drugs able to block lipolysis and thus to lower serum free fatty acids (
NEFA
) significantly improve somatotropin secretion in obesity. Caloric restriction and weight loss are followed by the restoration of a normal spontaneous and stimulated GH release. On the whole, hypothalamic, pituitary and peripheral factors appear to be involved in the GH hyposecretion of obesity. A SRIH hypertone, a GHRH deficiency or a functional failure of the somatotrope have been proposed as contributing factors. A lack of the putative endogenous ligand for GHRP receptors is another challenging hypothesis. On the peripheral side, the elevated plasma levels of
NEFA
and free IGF-I may play a major role. Whatever the cause, the defect of GH secretion in obesity appears to be of secondary, probably adaptive, nature since it is completely reversed by the normalization of body weight. In spite of this, treatment with biosynthetic GH has been shown to improve the body composition and the metabolic efficacy of lean body mass in obese patients undergoing therapeutic severe caloric restriction. GH and conceivably GHRPs might therefore have a place in the therapy of obesity.
...
PMID:Growth hormone in obesity. 1019 71
