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Query: UNIPROT:P61278 (
somatostatin
)
22,083
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A multiple peptide-synthesizing clonal rat cell line was used to study the effect(s) of
GRF
and basic fibroblast growth factor (bFGF) on the synthesis and secretion of
somatostatin
(SS). The presence of SS-specific mRNA in 44-2C cells was shown morphologically by in situ hybridization. The release and cellular content of SS increased significantly after treatment with rat hypothalamic
GRF
(rGRF), the ED50 for rGRF stimulation of intracellular SS was 1.9 X 10(-11) M.
GRF
stimulated SS production in serum-supplemented and serum-free cultures. Results obtained after incubation of 44-2C cells with 125I-labeled rGRF indicated uptake and nuclear localization of rGRF by 44-2C cells. FGF stimulated the secretion and cellular content of SS. We propose that bFGF regulates the short term secretion and accumulation of SS and mediates rGRF-stimulated SS expression.
...
PMID:Growth hormone-releasing factor and fibroblast growth factor regulate somatostatin gene expression. 289 28
Studies on the morphological distribution of histamine (HA)-secreting neurons and their hypothalamic projections suggest that HA may play a key role in regulating neuroendocrine functions, some of which have been recently elucidated. To investigate possible interactions between the somatotropinergic and histaminergic systems in the brain, the effects of
GRF
-44 [0.1-10 micrograms intracerebroventricular (icv)] and
somatostatin
(SS-14; 0.1-10 micrograms, icv) on HA in five different parts of the hypothalamo-hypophyseal system, and in the hippocampus and frontal cortex, were studied using a highly sensitive HPLC system for determination of HA.
GRF
-44 (1 microgram, icv) elicited significant (P less than 0.005) increases in the concentration of HA in the anterior hypothalamus, posterior hypothalamus, median eminence, adenohypophysis, neurohypophysis, frontal cortex, and, to a lesser extent, in the hippocampus, after a clear time-dependent pattern with maxima 15 min after injection. In contrast, SS-14 (1 microgram, icv) significantly (P less than 0.005) decreased the levels of HA in all areas studied, except in the neurohypophysis. The SS-induced HA levels reached minima 30 min after injection. The antagonistic effects of
GRF
-44 and SS-14 on the release of brain HA were dose dependent, showing an inverse linear correlation within the range 0.1-10 micrograms in the anterior hypothalamus (r = -0.59) and posterior hypothalamus (r = -0.75). Responses of HA to
GRF
-44 and SS-14 (range: 0.1-10 micrograms) also exhibited an inverse linear correlation in the median eminence (r = -0.90) and adenohypophysis (r = -0.58), while in the hippocampus and frontal cortex the antagonistic effects of
GRF
and SS displayed an inverse curvilinear correlation. SS-14 ED50 values ranged from 0.6 to 1.75 nmol with Emax of 0.65-6.10 nmol.
GRF
-44 ED50 values ranged from 0.02-0.3 nmol and the Emax values oscillated between 0.2 and 1.90 nmol in the regions studied. The greatest responses of HA to
GRF
-44 and SS-14 were obtained in the hypothalamo-hypophyseal system. Although brain HA is present in both the neuronal and the mast cell compartments, changes induced in the concentration of HA by centrally administered
GRF
-44 and SS-14 appear to occur mostly in the neuronal compartment. Therefore, it is likely that the somatotropinergic and histaminergic systems reciprocally interact at the central level to regulate still unknown neuroendocrine functions.
...
PMID:Antagonistic effects of growth hormone-releasing factor and somatostatin on brain histamine. 289 95
Using a monolayer approach, we have examined the acute (3 h) effects of
GRF
,
somatostatin
(SRIF), and insulin-like growth factor I (IGF-I) on GH release from pituitary cells of male and female 70-, 100-, and 130-day-old fetuses and newborn lambs and of prepubertal male lambs.
GRF
stimulated basal GH release in a dose-dependent (10(-12)-10(-8) M) manner at each stage in development. There was no linear relationship between maximal response and increasing age of the donor animals. The ED50 values for
GRF
were similar in all groups, except in the pituitaries from male and female 130-day-old fetuses, where the ED50 values were significantly higher. SRIF elicited a dose-related (10(-10)-10(-6) M) inhibition of basal GH secretion at each stage of fetal life and in the prepubertal period; although the response was lower in the youngest fetal pituitaries, there was no significant change in maximal response during the fetal or prepubertal period. No effect of SRIF on basal GH secretion was observed in newborn lambs. However, SRIF (10(-7) M) was able to block
GRF
(10(-8) M)-stimulated GH release in 100- and 130-day-old fetal and prepubertal as well as newborn lamb pituitary cells. Plasma IGF-I concentrations increased from 15.0 +/- 0.7 (mean +/- SE) and 13.8 +/- 0.9 ng/ml for male and female animals, respectively, at 70 days gestation to 55.8 +/- 3.2 and 51.8 +/- 11.1 ng/ml at the time of birth. The increase was much more pronounced in prepubertal lambs, especially in male animals, where IGF-I levels reached 300.8 +/- 37.7 ng/ml. IGF-I (100 ng/ml) had no effect on basal GH release in 70- and 100-day-old fetal, newborn, and prepubertal lamb pituitary cultures, but significantly inhibited basal GH secretion from 130-day-old fetal cells. This dose of IGF-I had no effect on
GRF
(10(-9) M)-stimulated GH release at 70 days gestation. It significantly inhibited this effect at 100 days and in prepubertal lamb cells. In 130-day-old fetal and newborn lamb pituitary cultures, IGF-I completely blocked the GH response to
GRF
.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:In vitro regulation of growth hormone (GH) release from ovine pituitary cells during fetal and neonatal development: effects of GH-releasing factor, somatostatin, and insulin-like growth factor I. 289 19
Injection of gastrin-releasing peptide-27 (GRP) into the third ventricle (IVT) has been shown previously to lower plasma GH levels and block the GH release induced by
GRF
, suggesting that GRP might act via stimulation of the release of
somatostatin
(SRIF) into hypophysial portal vessels. Several experiments were performed to test this hypothesis. In the first experiment rat median eminence (ME) fragments were incubated in medium containing concentrations of GRP ranging from 1 pM to 1 microM, and SRIF levels were measured after the 30-min incubation period. GRP significantly stimulated SRIF release at doses of 0.1 nM to 1 microM. Microinjection of SRIF antiserum (3 microliters) IVT prevented GRP (2 micrograms, IVT) from inhibiting the GH surge induced by
GRF
(1 microgram/kg, iv). A slight but significant decrease in basal plasma GH levels was observed after GRP administration even in the presence of SRIF antiserum. Finally, to rule out a GRP-
GRF
interaction at the pituitary level, tubes containing dispersed rat pituitary cells (2.5 x 10(5) cells/tube) were incubated for 1.5 h in medium containing various concentrations of
GRF
(0.4-40 nM) alone or with 0.1 microM GRP. The addition of GRP to the medium had no significant effect on the dose-dependent stimulation of GH release by
GRF
. The results of these studies demonstrate that GRP can directly stimulate SRIF release in vitro. They further suggest that SRIF is a component of the mechanism whereby GRP inhibits GH release in vivo. Finally, the possibility that GRP acts at the pituitary level to inhibit GH release by blocking
GRF
receptors on somatotrophs has been ruled out.
...
PMID:The inhibition of growth hormone release by gastrin-releasing peptide involves somatostatin release. 289 83
To clarify the role of
somatostatin
(SRIF) in pulsatile GH secretion, profiles of the hormone release from intact anterior pituitaries of male rats were examined in an in vitro perifusion system. Infusion of human (h)
GRF
(0.1 microM) into the perifusion system for 10 min stimulated GH release, which peaked within 30-40 min. Two hours after the first stimulation, when basal GH release had not yet fallen to the original levels, the response to a second hGRF stimulation was attenuated to as low as 47.7 +/- 10.0% (+/- SE) of the first response. However, when GH release after the first stimulation had returned to the basal level after the first stimulation had returned to the basal level after perifusion with the medium for 3 h, the second response to hGRF was restored to a level similar to that of the first response. In contrast, when SRIF (0.1 microM) was infused for 50 min 1 h after the first stimulation to lower the GH baseline, the second response to hGRF was also restored to the level of the first response. Neither SRIF infusion after the first hGRF stimulation nor infusion of SRIF without hGRF caused any rebound increase in GH release after cessation of the perifusion. To determine whether SRIF exerts a direct action on the GH response, a prestimulatory perifusion with SRIF (0.1 microM) for 50 min was performed. The treatment tended to facilitate the pituitary response to hGRF. When 50-min pretreatment with SRIF at a lower concentration (0.05 microM) was given, a significantly facilitated response to the first hGRF stimulation (0.05 microM) was observed. These results suggest that 1) SRIF perifusion rapidly restores the attenuated response to a second hGRF challenge by lowering GH release to basal levels; and 2) SRIF pretreatment facilitates the GH response to the first hGRF challenge.
...
PMID:Somatostatin rapidly restores rat growth hormone (GH) release response attenuated by prior exposure to human GH-releasing factor in vitro. 289 84
Experiments were performed in vitro to examine the possible role of calcium and calmodulin in
GRF
-induced
somatostatin
(SRIF) release from the median eminence. Adult male rats were used as tissue donors. The median eminences were first prestimulated in 0.4 ml Krebs Ringer bicarbonate glucose buffer (pH 7.4) containing bacitracin at 37C in an atmosphere of 95% O2, 5% CO2 with constant shaking for 30 min. When calcium was omitted, this medium was used during the prestimulation and stimulation periods. After prestimulation, the medium was discarded and replaced by medium containing the different substances to be tested (
GRF
, EGTA, calcium channel blockers, and calmodulin inhibitors). The stimulation of SRIF release induced by 10(-10) M
GRF
was not inhibited by omission of extracellular calcium or when the remaining CA+2 was chelated with 10(-4) M EGTA. The calcium channel blockers, nifendipine and verapamil (10(-6) M), failed to alter the increase of SRIF release induced by rGRF. Three calmodulin inhibitors were employed to examine the possible influence of calmodulin on
GRF
-induced SRIF release. Trifluoperazine (10(-6) M), triflupromazine (10(-6) M) and penfluridol (10(-7) M) had an inhibitory effect on the stimulation of SRIF release induced by
GRF
and failed to alter resting release. Thus,
GRF
can evoke SRIF release independently of extraterminal Ca+2 concentration and Ca+2 influx into the nerve terminals, but the releasing process involves translocation of Ca+2 from intracellular stores. The inhibitory effect of the calmodulin inhibitors on
GRF
-induced SRIF release, suggests that the translocated Ca+2 must bind to calmodulin in order to release SRIF.
...
PMID:Calmodulin dependence of somatostatin release stimulated by growth hormone-releasing factor. 289 60
Platelet-activating factor (PAF) exhibits a wide range of biological activities, including the stimulation of secretory processes in various cell types. However, little is known regarding its possible influence on the release of brain neuropeptides. In the present study we have examined the effect of PAF on the release of three hypothalamic releasing hormones in adult male rats, and have characterized the presence of specific PAF binding sites in rat hypothalamic membranes. PAF decreased LHRH and
somatostatin
(SRIF) release from the median eminence with a maximal inhibition at 10(-14) M for both neuropeptides, whereas
GRF
release was not significantly altered. Moreover, PAF strongly counteracted the Ca2+ ionophore A 23187-stimulated release of LHRH and SRIF from median eminence and medial basal hypothalamus (greater than 50% inhibition). These results suggest an involvement of Ca2+ dependent events in PAF action. This inhibitory effect was specifically exerted at a hypothalamic site because PAF failed to depress LH and GH release from the anterior pituitary. A specific, reversible and saturable binding of [3H]PAF to membrane preparations of rat hypothalamus was demonstrated and two classes of binding sites were characterized. The affinity (KD) of each binding class was 2.14 +/- 0.32 nM and 61.63 +/- 16.4 nM, respectively, and the corresponding maximal number of each binding class was 25.41 +/- 3.2 fmol/mg protein and 146.2 +/- 47.5 fmol/mg protein. In the same conditions no specific binding was observed using rat pituitary membranes. The specificity of PAF analogs for these binding sites was well correlated to their relative effectiveness in altering LHRH and SRIF release (order of potency: L-652,731, kadsurenone greater than BN 52021 greater than Lyso-PAF). These data suggest that the binding sites identified in the hypothalamus have the characteristics expected of a specific PAF receptor and that PAF effect on neuropeptides release is a receptor-mediated process.
...
PMID:Inhibitory effect of platelet-activating factor (PAF) on luteinizing hormone-releasing hormone and somatostatin release from rat median eminence in vitro correlated with the characterization of specific PAF receptor sites in rat hypothalamus. 289 62
Possible inhibitory effects of
somatostatin
(SRIF) on
GRF
were studied by assessing spontaneous GH secretion and
GRF
content and release in adult male rats depleted of hypothalamic SRIF by anterolateral hypothalamic deafferentation (AHD) or electrolytic lesions in the medial preoptic area (MPO). Plasma GH levels were measured 7 days postoperatively every 20 min in conscious animals with indwelling iv cannulae. Median eminence SRIF was markedly reduced 8 days postoperatively in both AHD and MPO rats, as determined by immunohistochemistry and RIA (P less than 0.01). Although
GRF
immunoreactivity in the median eminence of AHD and MPO animals appeared well preserved immunocytochemically, hypothalamic
GRF
content by RIA was significantly decreased at 8 days (P less than 0.01). Spontaneous GH secretion was pulsatile in sham-operated animals. In contrast, basal GH levels in AHD and MPO animals were markedly elevated (P less than 0.01), and secretory pulses were absent. Intravenous injection of specific anti-
GRF
serum into MPO animals decreased the elevated plasma GH levels (P less than 0.01), indicating increased hypothalamic
GRF
secretion.
GRF
release from hypothalamic median eminence-arcuate nucleus complexes in vitro was significantly greater in AHD and MPO animals than in control animals 4 and 8 days postoperatively in response to 30 mM K+ (P less than 0.01), but not under basal conditions. These results suggest that hypothalamic medial preoptic area somatostatinergic neurons play a tonic inhibitory role in the regulation of
GRF
release and that GH hypersecretion observed after MPO and AHD is attributable to changes in both SRIF and
GRF
.
...
PMID:Inhibitory effect of hypothalamic medial preoptic area somatostatin on growth hormone-releasing factor in the rat. 289 98
Distribution and staining intensities of growth hormone releasing factor (GR (
GRF
) and
somatostatin
(SRIF) were examined in young (3 months of age) and old (24 months of age) male rats of Sprague-Dawley strain, using the PAP immunocytochemical procedure. Some animals of each age group were intraventricularly injected with colchicine to demonstrate immunoreactive neuronal perikarya.
GRF
-immunoreactive intensities of old rats were markedly reduced in the median eminence as compared with those of young rats. No remarkable difference could be detected between SRIF immunoreactivities in the young and old animals, since intensive SRIF immunoreactivities were found in the external layer of the median eminence of both groups of animals. Between two age groups injected with colchicine, we also found no difference in the distribution and staining intensities of immunoreactive perikarya of
GRF
and SRIF in the hypothalamus and also detected no significant difference in total neuron numbers of each peptide. These findings suggest that the synthesis and/or release of
GRF
in
GRF
-containing neurons are decreased, though
GRF
-containing neurons themselves remain alive and have the capacity to synthesize
GRF
.
...
PMID:Age-related changes in growth hormone releasing factor and somatostatin in the rat hypothalamus. 289 47
Somatostatin
(SRIF) and GRFs play key roles in regulating GH secretion. We previously presented a model of SRIF-cAMP interaction; SRIF blocks rat (r) GH release without preventing its accumulation in a potentially releasable pool. This phenomenon may represent a mechanism whereby tonic SRIF inhibition and its subsequent reduction or withdrawal can modulate the magnitude if not the initiation of rGH pulses. Herein we test that model using human
GRF
-44 (hGRF-44). Tritium-prelabeled rat anterior pituitary fragments were perifused until stored [3H]rGH and [3H]rPRL release rates were stable. SRIF (10 or 25 nM), with and without hGRF-44 (3 or 10 nM), was added in short (1-h hGRF-44) and long (3-h hGRF-44) protocols; SRIF was then withdrawn while hGRF-44 was continued. Release of stored prelabeled [3H]rGH and [3H]rPRL was assessed by immunoprecipitation. Effects on PRL release were followed for comparison. SRIF-induced inhibition of release was only partially reversed by hGRF-44. At these concentrations and so long as SRIF was present, hGRF-44 could not stimulate the rate of hormone release to values above pre-SRIF basal rates. On the other hand, the amplitude of post-SRIF rebound release was increased by prolonging exposure to SRIF alone, by including hGRF-44 with SRIF, by increasing the amount of hGRF-44 included with SRIF, by prolonging exposure to hGRF-44 plus SRIF, and by using a smaller concentration of SRIF during exposure to hGRF-44. Interaction of hGRF-44-SRIF effects generated peak rates of hormone release after SRIF withdrawal which exceeded the maximum rates achieved using hGRF-44 alone in this system. Lactotroph responses were much smaller, but qualitatively resembled somatotroph responses. We conclude that the interplay of simultaneous hGRF-44 and SRIF effects can regulate the amplitude of rGH pulses. Although
GRF
can initiate physiological GH release, and
GRF
antisera can block GH pulses, we suggest that the surge of release that follows reduction of SRIF-induced inhibitory tone in vitro represents a potential mechanism that could contribute to the initiation of some pulses of release. Finally, we also present a theoretical model of secretagogue interactions at the cellular level to explain our results. The model is compatible with either a homogeneous cell population in which each secretory cell has multiple capabilities or a heterogeneous cell population composed of cell subgroups with complementary secretory abilities.
...
PMID:Combined effects of human growth hormone (GH)-releasing factor-44 (GRF) and somatostatin (SRIF) on post-SRIF rebound release of GH and prolactin: a model for GRF-SRIF modulation of secretion. 290 Jan 35
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