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Query: UNIPROT:P61278 (
somatostatin
)
22,083
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The present review is dealing with the five major hypothalamic hypophysiotropic neuropeptides (H.H.N.P.) purified and synthesized so far. Four of them specifically stimulate the secretion of one or several anterior pituitary (A.P.) hormones, i.e. thyroliberin (TRH) on TSH and prolactin, gonadoliberin (GnRH) on LH and FSH, corticoliberin (CRF) on ACTH and precursor peptides and somatocrinine (
GRF
) on GH. The fifth one,
somatostatin
(SRIF), inhibits the secretion of all A.P. hormones, excepted LH and FSH. All H.H.N.P. affect, positively or negatively, in a dose- and time-dependent manner, the release of stored hormones and their neosynthesis. These responses are submitted to multihormonal modulations. They are initiated by the occupancy of high affinity specific binding sites which have been extensively characterized and morphologically localized. Informations concerning molecular characterization and cloning of receptors for any H.H.N.P. are still awaited. By contrast, the transduction mechanisms which are activated by the occupation of receptors have been extensively studied. They vary depending on H.H.N.P.: TRH and GnRH activate the catabolism of polyphosphoinositides and ensuing pathways, CRF and
GRF
activate and SRIF inhibits adenylate cyclase dependent pathways. In addition, Ca2+, from extracellular and intracellular sources, play a pivotal role in all cases. The intracellular mechanisms responsible for the last steps of H.H.N.P. action, i.e. exocytosis of secretory granules and transcription of target genes, are however still unknown.
...
PMID:[Hypothalamic hypophysiotropic neuropeptide receptors]. 255 5
The purpose of this study was to characterize the adenylate cyclase system in a purified population of normal somatotrophs derived from rat pituitary and to determine the responses of this system to
GRF
,
somatostatin
, guanine nucleotides, and cations. Additionally, experiments were performed to evaluate the interrelationships among changes in adenylate cyclase activity, cellular cAMP levels, and GH release induced by
GRF
and
somatostatin
. The results obtained using homogenates and membrane preparations from somatotrophs included the following. 1)
GRF
caused guanine nucleotide-dependent concentration-related (Ka, approximately 10(-8) M) stimulation of adenylate cyclase activity. 2) Guanine nucleotides were effective in stimulating cyclase in the absence of
GRF
; the concentration of guanine nucleotide required for half-maximal stimulation was decreased more than 10-fold in the presence of
GRF
. 3) Adenylate cyclase activity increased with increasing concentrations of free Mg2+ (0.25-20 mM); activation by
GRF
and guanine nucleotide resulted in an approximately 7-fold increase in the enzyme's affinity for free Mg2+. 4)
Somatostatin
, up to 10(-6) M, did not alter basal or
GRF
-stimulated adenylate cyclase activity. 5) Ca2+ (0.5-11.9 microM) produced concentration-dependent inhibition of basal (up to 28%) and
GRF
-stimulated (up to 47%) cyclase activities; the inhibitory effect of Ca2+ was accompanied by a decrement (2- to 3-fold) in the apparent affinities of the enzyme for both
GRF
and guanine nucleotide. In intact somatotrophs,
GRF
produced concentration-dependent stimulation of GH release (Ka, approximately 6 x 10(-11) M), preceded by a marked elevation of cAMP levels. While
somatostatin
blocked
GRF
-induced GH release, the augmented cAMP levels were only slightly reduced.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Growth hormone-releasing factor-sensitive adenylate cyclase system of purified somatotrophs: effects of guanine nucleotides, somatostatin, calcium, and magnesium. 256 26
Serum GH concentrations in the ovine fetus are much higher than those in the neonate, and the maximal GH response induced by
GRF
is 5-fold greater in the fetus than in the neonate. To clarify these in vivo observations further, we studied the effects of
GRF
,
somatostatin
(SRIF), and insulin-like growth factor I (IGF-I) on primary cultures of fetal and neonatal ovine pituitary cells. GH secretion from fetal ovine pituitary cells increased from 148 +/- 34 to 950 +/- 130 ng/10(5) cells.3 h in response to 1 nM
GRF
, whereas GH secretion from neonatal pituitary cells rose from 113 +/- 26 to 1221 +/- 129 ng/10(5) cells.3 h, a significantly greater response (P less than 0.001). This greater
GRF
-induced GH response in neonatal than fetal cells differs from the response in vivo and suggests that the increased in vivo response in the fetus is not due to inherently increased sensitivity of pituitary cells to
GRF
. SRIF (10 nM) decreased maximal
GRF
-induced GH secretion by 37 +/- 3% in fetal cells compared with 59 +/- 8% in neonatal cells (P less than 0.01). This may explain in part the decreased in vivo sensitivity to SRIF in the ovine fetus compared to that in the neonatal lamb. In fetal pituitary cells, 10 nM
GRF
increased ovine (o) GH mRNA from 100 +/- 14% to 145 +/- 40%, SRIF decreased oGH mRNA to 84 +/- 3%, and
GRF
and SRIF in combination increased fetal oGH mRNA to 126 +/- 24%. Values in neonatal pituitary cell cultures were similar (control, 100 +/- 17%;
GRF
, 132 +/- 6%, SRIF, 85 +/- 15%;
GRF
plus SRIF, 105 +/- 26%). Pretreating fetal cells with 100 nM IGF-I for 3 days reduced
GRF
-stimulated GH secretion from 1049 +/- 38 to 232 +/- 8 ng/10(5) cells.3 h (P less than 0.001). Similarly, IGF-I pretreatment of neonatal cells reduced
GRF
-stimulated GH secretion from 810 +/- 18 to 419 +/- 16 ng/10(5) cells.3 h (P less than 0.001). The mean secreted IGF-I was 0.58 U/ml (36 nM) in culture medium from neonatal cells and was unchanged by incubation for 3 days with 5 micrograms/ml hGH. Secreted IGF-I in medium from fetal cells was 0.87 U/ml (54 nM) without GH and 0.81 U/ml (51 nM) after incubation with human GH. IGF-I mRNA was present in neonatal pituitary and brain.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Regulation of growth hormone (GH) secretion by GH-releasing factor, somatostatin, and insulin-like growth factor I in ovine fetal and neonatal pituitary cells in vitro. 256 28
We postulated that an increase in the biological effectiveness of
somatostatin
(SRIF) accounts, at least in part, for the decrease in basal and
GRF
-induced ovine GH (oGH) secretion observed around birth in the ovine fetus and neonate. To test this hypothesis, SRIF (SRIF-14; given as 30 micrograms/kg iv bolus, followed by 2 micrograms/kg.min for 75 min) was infused into chronically catheterized fetal and neonatal lambs, and the oGH response induced by
GRF
[
GRF
-(1-44) amide; 1 microgram/kg] in the presence of exogenous SRIF was compared to the oGH response induced by
GRF
in saline-infused controls. In fetuses of 115-122 days gestation, SRIF had no detectable effect on the oGH response to
GRF
[peak incremental oGH response (mean +/- SEM), 527 +/- 124 vs. 562 +/- 103 ng/ml in controls]. In neonatal lambs (3-17 days old), SRIF completely suppressed the immediate oGH response to
GRF
(peak incremental response, 0.8 +/- 1.3 vs. 111 +/- 34 ng/ml in controls; P less than 0.02). In late gestational fetuses (126-139 days old), a transitional pattern was observed (peak incremental oGH response, 207 +/- 56 vs. 324 +/- 30 ng/ml in controls; P less than 0.04). In the second part of this study, we explored, in the neonatal lamb, the hypothesis that SRIF withdrawal plays a role in pulsatile GH secretion and that the amount of
GRF
to which the somatotrope is exposed before SRIF withdrawal is a major factor in determining the amplitude of GH bursts. SRIF (SRIF-14; a 30 micrograms/kg bolus, followed by 2 micrograms/kg.min) was infused iv for 40 min,
GRF
[
GRF
-(1-44) amide; 1 microgram/kg] was injected iv 20 min after starting the SRIF infusion, and the oGH rise after SRIF withdrawal was evaluated. In one series of controls
GRF
was replaced by saline, and in the other SRIF was replaced by saline. The oGH rise during recovery after SRIF alone was lower than that after the combined administration of SRIF and
GRF
(peak oGH increment, 8 +/- 3 vs. 38 +/- 12 ng/ml; P less than 0.04). The amplitude of the GH pulse after SRIF and
GRF
was similar to the immediate oGH response to
GRF
alone. These studies show that SRIF is unable to suppress the immediate oGH response to
GRF
in the ovine fetus, and that the suppressive effect of SRIF on the immediate oGH response to
GRF
increases gradually in late gestation and sharply at birth.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Hormone ontogeny in the ovine fetus and neonate. XXII. The effect of somatostatin on the growth hormone (GH) response to GH-releasing factor. 256 81
Pituitary GH secretion is regulated by a delicate interplay between stimulatory (
GRF
) and inhibitory [
somatostatin
(SRIF)] hypothalamic hormones, although the nature of the
GRF
/SRIF interaction remains to be elucidated. In the present study, we documented a significant elevation of plasma SRIF-like immunoreactivity in 72-h fasted rats compared to that in fed controls (129.0 +/- 17.9 vs. 38.2 +/- 5.8 pg/ml; P less than 0.01) and used this model of high SRIF tone to further delineate the interrelation between
GRF
and SRIF in physiological regulation of pulsatile GH secretion. We examined pituitary GH responsiveness to
GRF
, both in vivo and in vitro, after 72-h exposure to nutritional deprivation and high SRIF secretion. In vivo,
GRF
-induced GH release was markedly enhanced in the face of high circulating SRIF; freely moving, starved rats released 4- to 8-fold more GH than fed controls in response to rat
GRF
iv. In vitro, both basal and human
GRF
-induced GH release were augmented 2- to 4-fold in perifused dispersed anterior pituitary cells of starved rats compared to those in fed controls, and this enhanced responsiveness persisted in the presence of 10(-9) M SRIF. These results demonstrate that SRIF not only inhibits GH secretion stimulated by
GRF
, but that under different temporal conditions SRIF may act in a paradoxically positive manner to sensitize pituitary GH responsiveness to
GRF
. Such a cooperative interaction of the two peptides may be necessary to optimize pulsatile GH release. Our findings provide support for the hypothesis that the temporal patterning of hypothalamic
GRF
/SRIF signals to pituitary somatotrophs may be the major determinant for pulsatile GH secretion and, ultimately, body growth.
...
PMID:Paradoxical enhancement of pituitary growth hormone (GH) responsiveness to GH-releasing factor in the face of high somatostatin tone. 256 83
To examine the role of protein kinase-C in the mediation of GH release we used acutely dispersed purified somatotrophs in static incubation and acutely dispersed adenohypophyses in perifusion. In static incubation, activation of protein kinase-C by phorbol 12-myristate 13-acetate (PMA) and 1,2-dioctanoyl-rac-glycerol (diC8) resulted in an increase in GH release and a concurrent concentration-dependent increase in cAMP accumulation. The GH response to diC8 in perifusion was reversible and repeatable. On the other hand, the GH response to PMA was not repeatable. The lack of repeatability is most likely due to the depletion of protein kinase-C by prolonged treatment with PMA. This assumption is strengthened by the observation that 1 h of perifusion with PMA left the somatotrophs refractory to a subsequent application of diC8. When graded pulses of
GRF
were applied during treatment with PMA, the GH response to
GRF
was not altered.
Somatostatin
reduced (in static incubation) or blocked (in perifusion) the release of GH induced by diC8 and PMA, but the accumulation of cAMP was not affected. We conclude that 1) activation of protein kinase-C in normal somatotrophs results in GH release which may not be completely independent of the cAMP pathway; 2) activation of protein kinase-C is not essential for
GRF
-induced GH release; and 3) SRIF acts at a site distal to or independent of cAMP to inhibit GH release induced by activators of protein kinase-C.
...
PMID:Protein kinase C is not essential for growth hormone (GH)-releasing factor-induced GH release from rat somatotrophs. 256 18
In the male rat, GH secretion is characterized by high amplitude pulses that appear at regular intervals of 3-4 h, with low basal levels between such pulses. In the female, the pulses are irregular and more frequent, with lower amplitudes, while basal secretion is higher. The present study was designed to exclude the indirect effects of sex steroids on the pituitary, enabling investigation of the direct effects of sex steroids on the pituitary. Rats were gonadectomized at 22 days of age, and 12 days later their anterior pituitaries were trypsinized for cell dispersion. Testosterone (T) or 17 beta-estradiol (E2), 5 nM, was added to the medium for 6 days, and subsequently,
GRF
or
somatostatin
was added for 4 h. In a perifusion system, the male-derived cell response to
GRF
was augmented after pretreatment with T, but not with E2. The female-derived cell response to
GRF
was augmented by E2, but not by T. T increased the sensitivity of the cells to
GRF
from 3.0-0.03 nM and increased the maximal potency of GH secretion 3-fold. E2 had no significant effect on the sensitivity, but lowered the potency.
Somatostatin
(1 nM) inhibited GH secretion by 44% in T-treated cells. In E2-treated cells,
somatostatin
was ineffective.
GRF
increased the total amount of GH (medium plus cells) in both T- and E2-treated cells, but not in control pituitary cells. It is suggested that T has direct effects on the male somatotroph. By increasing the pituitary cell responses to
GRF
and
somatostatin
, T contributes to the high amplitude peak/low baseline pattern of the male. By decreasing the pituitary cell responses to
GRF
and
somatostatin
, E2 contributes to the low amplitude peak/high baseline pattern of the female.
...
PMID:Effects of sex steroids on the response of cultured rat pituitary cells to growth hormone-releasing hormone and somatostatin. 256 24
Sex differences in the hypothalamic control of growth hormone (GH) secretion were investigated by measuring rat GH-releasing factor (rGRF) and
somatostatin
in male and female rats. Rat
GRF
-like immunoreactivity (rGRF-IR) was higher in the median eminence and hypothalamic tissue outside of the median eminence of adult (90-day-old) male compared to female rats. A similar pattern of rGRF-IR content was found in the median eminence of 35-day-old rats. This sex difference developed between days 25 and 35 of age, during which time serum concentrations of insulin-like growth factor (IGF-1) and body weight increased in both sexes. To a lesser extent, the content of
somatostatin
-like immunoreactivity (SLI) was higher in the median eminence of adult female rats compared to male rats. Whole hypothalamic rGRF-IR and SLI contents were influenced only moderately by adult gonadectomy or gonadal steroid treatments. For example, estrogen increased rGRF-IR content in castrated rats, but orchidectomy alone or orchidectomy followed by testosterone did not influence rGRF-IR content. Additionally, whole hypothalamic SLI content was unaffected by orchidectomy or orchidectomy followed by testosterone or estrogen. One month after ovariectomy, rGRF-IR and SLI in whole hypothalamic fragments were similar to their respective contents in gonad-intact males. However, ovariectomy followed by estrogen or testosterone did not restore rGRF-IR content and partially restored SLI content to levels seen in gonad-intact females.
...
PMID:Sexual and developmental differences in peptides regulating growth hormone secretion in the rat. 257 53
The aims of this study were: (1) to test the possibility that pre-GHRH plasma GH values could reflect the functional status of the hypothalamic-somatotroph rhythm (HSR) at testing, and thus explain if it is responsible for the marked variability in GH responsiveness to GHRH challenge and (2) to see if exogenous
somatostatin
(SS) could disrupt this endogenous HSR and thus make the GH responses homogeneous. (1) Two to 14 GHRH acute tests (
GRF
-29, 1 micrograms/kg, i.v. bolus) were performed in 12 normal men and 10 normal women at the same time (0830 h) at random intervals (2 to 60 days). Blood samples to measure plasma GH were drawn at 15 min intervals before and after GHRH challenge. Given that the increments in pre-GHRH plasma GH values (I = value at 0 min minus value at -15 min) were highly correlated with either GHRH-elicited peaks of GH (men, r = 0.81; women; r = 0.69; P less than 0.0001) or the rise in GH after the challenge (r = 0.685; P less than 0.0001, in the total of tests performed), three theoretical HSR phases were proposed: (A) I greater than or equal to 0.4 microgram/l Secretory Phase; (B) I less than or equal to 0, (from GH at -15 min greater than or equal to 1.5 microgram/l), Secretion Plateau; (C) I less than or equal to 0, (from GH at -15 min less than or equal to 1.5 microgram/l), Refractory Phase. Individually, 91% of the men and 86% of the women showed a constant HSR phase when tested at the same time of day independently of the intervals between tests. GH responses (peaks, mean +/- SEM, g/l) in Phase A (women, 51.5 +/- 4.1; men, 31.4 +/- 3.2) were significantly higher (P less than 0.01) than those in Phase B (women, 22.6 +/- 1.8; men, 19.7 +/- 1.5), and these than those in Phase C (women, 9.2 +/- 1.5; men, 6.2 +/- 0.5). The great dispersion observed when GH peaks were analysed as a whole disappeared (except in Phase A in women) when they were evaluated according to the HSR Phase at testing. (2) In seven men and eight women 7 min after stopping an infusion of SS (250 micrograms/h for 3 h) a new GHRH test was performed. Plasma GH variations prior to SS infusion expressed the previous HSR Phase, while the GHRH-elicited peak of GH established the Phase at the moment of testing.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Reasons for the variability in growth hormone (GH) responses to GHRH challenge: the endogenous hypothalamic-somatotroph rhythm (HSR). 257 45
Previous research has established that growth hormone pulse amplitude declines with increasing age. The purpose of this study was to determine whether this decline is associated with (1) increased pituitary response to
somatostatin
, and/or (2) increased number or affinity of pituitary
somatostatin
receptors. In the first study, pituitary slices from young (3-4 months), middle-aged (12-14 months), and old (22-24 months) male Fischer 344 rats were superfused with minimal essential medium (1 ml/min) and fractions collected at 5-min intervals. Tissues were stimulated with 10(-7) M hpGRF (1-44) for 1 min and, 40 min later, with hpGRF in the presence of 5 x 10(-9) M somatostatin-14 or somatostatin-28. Two pituitaries from each age group were superfused simultaneously and the experiment replicated 4 times. Growth hormone release was measured by radioimmunoassay. In a second study,
somatostatin
receptors in purified pituitary membranes from the three age groups were compared using iodo-[Tyr0]-D-Trp8 somatostatin-14. Animals from each age group were pooled, membranes extracted, and incubated with increasing doses of cold peptide. Binding characteristics were analyzed by Scatchard analysis and Ka and Bmax calculated. Results indicated that (1) basal growth hormone release diminished both with age and
somatostatin
administration, (2)
GRF
-induced release of growth hormone was similar in all age groups when data were expressed as percent increase from baseline, and (3) in the presence of somatostatin-14,
GRF
-induced release of growth hormone was attenuated in old as compared to young or middle-aged rats (p less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Increased pituitary response to somatostatin in aging male rats: relationship to somatostatin receptor number and affinity. 257 35
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