Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:P61278 (somatostatin)
 22,083 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

During the last few years, many neuropeptides have been isolated, characterized and synthesized. Neuroendocrinology is one area in which there has been major progress, particularly through the isolation of two new hypothalamic factors, corticotropin releasing factor (CRF) and growth hormone releasing factor (GRF). CRF specifically stimulates pituitary secretion of ACTH and other peptides derived from pro-opiomelanocortin (beta-lipotropin, beta-endorphin), while GRF, together with somatostatin, controls secretion of the growth hormone. Knowledge of the structures of the hypothalamic factors has allowed the synthesis of the native substances as well as many potent analogues with agonist and antagonist properties. These substances have numerous clinical applications. LHRH or its analogues are presently used or being tested in various conditions such as treatment of hormone-related cancers (prostate, breast), endometriosis, idiopathic precocious puberty as well as in sterility problems. The recent availability of long acting somatostatin analogues has raised great therapeutic expectations in various endocrine and digestive diseases. Whereas GRF can be used in the treatment of short stature, CRF has so far not been shown to be a potential important therapeutic agent. However, its clinical application as a diagnostic test is clearly useful in many situations. There is a promising future for the clinical applications of these substances in various endocrine, digestive and perhaps in psychiatric diseases, and in hormone-related cancers.
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PMID:[Hypothalamic factors: recent diagnostic and therapeutic advances]. 289 Feb 1

Regulation by neurotransmitters of anterior pituitary hormone secretion is complex and a thorough understanding of their normal role in hormone secretion is a prerequisite to understanding their involvement in age-related changes in endocrine function. To date, uncertainties far out-number demonstrated causative relationships between alterations in neurotransmitter release and resulting age-associated changes in hormone secretion. The best demonstrated relationships are the following. First, a decline in function of the TIDA system is responsible, in part, for the age-related elevation in prolactin secretion and may be involved in the decline in LH secretion. Second, the age-related decrease in hypothalamic norepinephrine turnover plays a role in the decline in LH and GH secretion and may be involved in alterations in TSH secretion during aging. Third, the decline in circadian activity of suprachiasmatic nucleus serotoninergic neurons may account for the blunting of circadian rhythms in the secretions of several anterior pituitary hormones in old animals. Fourth, evidence exists for an age-related decline in function of LHRH neurons, which may contribute to the observation of blunted LH secretion in old animals. Finally, somatostatin release may be increased in old animals, which likely contributes to the age-related decline in GH secretion. Other hypothalamic-releasing hormones have only recently been isolated and characterized; thus, little research on their age-related alterations has been done. Research on these neuropeptides will contribute further to our understanding of the role of neurotransmitters in age-related alterations in hormone secretion.
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PMID:Influence of age on neurotransmitter function. 289 72

1. We have reviewed recent studies in which in situ hybridization histochemistry (ISHH) was used to investigate the regulation of expression of neurohypophysial peptides and hypothalamic releasing hormones. 2. ISHH is a technique in which the presence and quantity of a specific mRNA can be determined in tissue sections with a high degree of resolution and sensitivity. 3. ISHH has been used to measure changes in cellular levels of mRNAs encoding vasopressin, oxytocin, corticotropin-releasing factor, gonadotropin-releasing hormone, thyrotropin-releasing hormone and somatostatin in response to various physiological challenges. 4. A theme emerging from these studies is that changes in levels of mRNA encoding neuroendocrine peptides reflect changes in biosynthesis and secretion.
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PMID:Neuroendocrine gene expression in the hypothalamus: in situ hybridization histochemical studies. 289 79

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.
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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

Plasma GH responses to GHRH and somatostatin were examined in 43 patients with active acromegaly. Thirty-two of these patients showed GH increases 50% above the basal values in response to at least 1 of 3 stimuli (TRH, LHRH, arginine) (categorized as group I). The remaining 11 patients showed no response to any of the stimuli (categorized as group II). Following somatostatin infusion, group I (n = 31) showed significantly greater GH suppression than group II (n = 11) from 30 to 90 min (p less than 0.05-0.01). In addition, plasma GH responses to GHRH at 15 and 30 min was also greater in group I (n = 12) than in group II (n = 5) (p less than 0.05 & 0.01). There was a positive correlation between the log value of the peak GH after GHRH and the maximal % decrement after somatostatin (r = 0.64, p less than 0.02). However there were no differences in the responses of normal thyrotrophs (TSH) to TRH between the two groups. These results indicate that there are two types of acromegaly, i.e., one is more responsive and another is less responsive to either non-specific (TRH & LHRH) or specific GH stimulations (GHRH & somatostatin).
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PMID:The spectrum of GH responses to GHRH and somatostatin in patients with acromegaly. 290 3

Over the past twenty years, each of the five major hypothalamic releasing or release-inhibiting hormones has been sequenced and its gene structure determined. With the use of molecular biological techniques, such as in situ hybridization, Northern blot analysis or gene constructs for in vitro or in vivo transfection studies--together with 'traditional' neuroendocrinological techniques, such as immunocytochemistry, radio-immunoassay and portal vessel cannulation--investigators have been able to address major issues in neuroendocrine regulation. Several common themes have emerged: messenger RNA expression is uniformly present in neurons that are immunopositive for the specific hypothalamic hormone. Steady state RNA levels within the hypophysiotropic neuron groups are either increased or reduced by changes in specific target hormones that conform to predictions based on previous physiological data. Regulation by the requisite peripheral hormone is exquisitely anatomically specific and is not evident in extrahypophysiotropic regions. Determining the receptor or genetic basis of this specificity is a major focus of current research. Clarifying the apparently lesser role of afferent neural pathways to the hypothalamus in regulating releasing hormone mRNA levels is also an important challenge. Clinically, the measurement of levels of releasing hormones in the peripheral circulation appears to be of limited usefulness, except in rare cases of ectopic GRH or CRH secretion. For diagnostic purposes, each of the releasing hormones has specific utility in amplifying the release and measurement of pituitary hormones, both to clarify the overall physiological activity of the hypothalamic-pituitary-target hormone axis and to further define the anatomic locus of any underlying disturbance. The usefulness of somatostatin as a diagnostic tool is presently limited, but the development of SS receptor antagonists might have significant impact in future clinical investigation. The molecular mechanisms of action of the hypothalamic hormones have been separated into those whose receptor-effector function is mediated by the cAMP-adenylate cyclase pathway(s), GRH and CRH, and those working through the phosphoinositide-protein kinase C cascade, GnRH and TRH. Each of the hormone receptors is coupled to intermediary G proteins, somatostatin uniquely to the inhibitory subclass. The mechanisms responsible for sensitization (priming) or desensitization are not fully understood but are presumably related to receptor down regulation and protein phosphorylation.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Molecular biology and regulation of the hypothalamic hormones. 290 17

Four tumors consisting of pituitary adenomatous cells (AD) intricated with ganglion cells (GC) were studied. Each case was associated with a different clinical syndrome: acromegaly, amenorrhea-galactorrhea, Cushing's disease and isolated tumoral syndrome with no hormonal hypersecretion. (a) In the case with acromegaly, immunoreactive growth hormone (IR-GH) was present in 80% of AD. IR-vasoactive intestinal peptide (VIP) was found in 5%-10% of AD and in few GC. Rare GC and processes showed IR-GH-releasing hormone (GRH), -somatostatin (SRIH), -gonadotropin-releasing hormone and -adrenocorticotropin-releasing hormone. (b) In the case with amenorrhea-galactorrhea, IR-prolactin (PRL) was seen in 90% of AD. IR-PRL and -VIP were present in rare GC. (c) In the case with Cushing's disease, 60% of AD and very few GC contained IR-adrenocorticotropin (ACTH) and beta-lipotropin. Rare GC processes contained IR-SRIH. (d) In the case without pituitary hormone hypersecretion, PRL was localized in rare AD and GC. Pituitary hormone and neuropeptides were never colocalized in the same cells. No case displayed IR-neurophysins or -thyroliberin. Pituitary hormones were localized by ultrastructural immunogold labeling. These findings show that: (i) in three cases, pituitary hormones (PRL and ACTH), and, in one case, VIP could be localized in both adenomatous and ganglion cells; (ii) the pituitary hormone-containing cells in the tumors could be related to the hypersecretory syndromes; (iii) intratumoral IR-VIP and -GRH might be involved in GH and PRL hypersecretion in the cases with acromegaly and amenorrhea-galactorrhea.
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PMID:Immunocytochemistry of four mixed pituitary adenomas and intrasellar gangliocytomas associated with different clinical syndromes: acromegaly, amenorrhea-galactorrhea, Cushing's disease and isolated tumoral syndrome. 292 94

Within the past year, three similar peptides with specific growth hormone (GH) releasing effects have been extracted from human tissue, identified, and synthesized. Human pancreatic tumor GH releasing factor (I-40)-OH (hpGRF-40) was the sole hpGRF isolated from the pancreatic tumor of a patient in Charlottesville and was the predominant peptide isolated from the pancreatic tumor of a patient in Lyon. The Lyon tumor also contained hpGRF(1-37)-OH and hpGRF(1-44)-NH2. Both immunological and biochemical data suggest that hpGRF-40 and hpGRF-44 are present in the human hypothalamus and may be the human GH releasing hormone(s) (GHRH). In cultures of rat pituitary cells, hpGRF stimulates GH but affects neither basal and dopamine-inhibited prolactin release nor basal and gonadotropin releasing hormone (GnRH)-stimulated luteinizing hormone (LH) release. hpGRF stimulates cyclic AMP production within seconds, an effect which is blocked by somatostatin. In contrast, while hpGRF stimulates phosphatidylinositol turnover in the pituitary, the effect is not inhibited by somatostatin. In the human, hpGRF-40 (1 microgram/kg) given intravenously (i.v.) stimulates GH release within 5 minutes. hpGRF-40 does not elevate serum prolactin levels, thyrotropin (TSH), LH, or corticotropin (measured indirectly through plasma cortisol), or blood glucose or plasma concentrations of insulin, glucagon, pancreatic polypeptide, cholecystokinin, gastrin, gastric inhibitory peptide, motilin, or somatostatin. When graded doses of hpGRF (0.1-10 micrograms/kg) are given i.v., no differences are noted in the maximal levels of serum GH achieved.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Human pancreatic tumor GH-releasing factor. 298 23

Recent reports indicate that the main effect of systemically administered angiotensin II (AII) on ACTH release is probably due to some central nervous system mechanism. The present studies were designed to investigate whether the central action of AII on ACTH release is directly mediated through CRF. In order to test the participation of endogenous CRF in the AII-induced ACTH release in vivo, intact and pharmacologically blocked (pretreated with chlorpromazine-morphine-nembutal) female rats were injected iv with AII (8 nmol/100 g BW). Plasma levels of ACTH as well as CRF content in the median eminence (ME) and medial basal hypothalamus (MBH) were evaluated before and 1, 2.5, and 5 min after treatment. These responses were compared with the effect of 1 min ether exposure on hypothalamic CRF content and plasma ACTH levels in unanesthetized animals. AII injection and ether exposure increased plasma ACTH levels several-fold at both 2.5 and 5 min post treatment in intact rats. Conversely, AII failed to induce any significant increase in plasma ACTH levels in centrally blocked rats at any interval studied. On the other hand, AII injection and ether inhalation acted in similar fashion on CRF content in ME, inducing fast depletion at 1 min post treatment, recovering to control values at 2.5 min after injection, and finally, accumulating peptide at 5 min post treatment. In addition, CRF content in the MBH decreased significantly at 5 min, under both experimental conditions; AII had no effect on hypothalamic CRF content in centrally blocked rats. In vitro experiments using whole MBH (containing ME) fragments incubated with either neural peptides or high K+ solutions indicate that AII possesses a CRF releasing effect at concentrations of 10(-6) M or more. Conversely, other hypothalamic peptides, such as LHRH, TRH, and somatostatin did not induce significant release of CRF at any of the concentrations assayed (10(-7) to 10(-5) M). On the other hand, high K+ solutions released CRF in a concentration-related manner (15-60 mM). These studies suggest that the central effect of AII stimulation on ACTH release in vivo could be, at least in part, through the release of hypothalamic CRF into the portal circulation.
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PMID:Angiotensin II and adrenocorticotropin release: mediation by endogenous corticotropin-releasing factor. 301 75

Acromegaly is caused by GH-secreting pituitary adenomas and, in rare cases, by ectopic production of GRH with resultant hypersecretion of GH. Important systemic manifestations include acral enlargement, swelling, disfigurement, glucose intolerance and diabetes, hypertension, nerve entrapment, arthropathy, and cardiac disease. Tumor-related major manifestations are visual impairment, oculomotor paralysis, and hypopituitarism. Morbidity is substantial, and mortality is increased. Diagnosis should be made as early as possible by measuring plasma GH after an oral glucose load and plasma somatomedin C levels. Assessment of a pituitary lesion is best made by CT scanning in the coronal plane. Therapy is mandatory and consists of surgical removal of the pituitary adenoma (usually by the transsphenoidal route) or of the ectopic source of GRH (carcinoids or islet cell tumors). Adjunctive radiation and/or drug therapy is often necessary if complete surgical ablation of the adenoma is not possible. Radiation therapy can be administered as conventional supervoltage x-ray treatment or in the form of heavy particle beams. Drugs effective in partially lowering GH levels are bromocriptine and (not yet released) somatostatin analogues. Long-term follow-up of treated patients is important to guard against recurrence, progression, or development of hypopituitarism.
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PMID:Acromegaly. 331 99


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