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)

The hypothalamic paraventricular nucleus (PVN) has been implicated in a remarkable number of functions including control of pituitary-adrenocortical activity in response to stress, body fluid homeostasis, milk ejection reflex, prolactin secretion, thyroid hormone secretion, analgesia, food intake, gastrointestinal functions, cardiovascular functions, and control of pineal melatonin synthesis. Paraventricular neurons produce hormones of key importance in neuroendocrine regulation such as vasopressin (VP), oxytocin (OX), 41-residue corticotropin releasing factor (CRF), thyrotropin releasing hormone (TRH), somatostatin (SOM) and the putative prolactin releasing factor vasoactive intestinal polypeptide (VIP). Three recent advances pertinent to the organization of the PVN include: (1) the evidence that the structure of the PVN is compartmental in nature, topographically segregated cellular units seem to carry out different functions; (2) the discovery that paraventricular neurons are capable of expressing a multitude of neuromediators simultaneously, thus cellular units can be best specified by a certain combination of neuromediators; (3) evidence that the composition of the neuromediator "cocktail" in individual neurons is variable and depends on the physiological status of the animal. Hence, the PVN may be best considered as a dynamic mosaic of chemically specified subgroups of neurons. The flexibility of neurotransmitter status in paraventricular neurons may play a central role of a functional plasticity of fixed anatomical circuits.
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PMID:Dynamism of chemoarchitecture in the hypothalamic paraventricular nucleus. 304 19

Inappropriate TSH hypersecretion was diagnosed in a 38-year-old woman (case 1) and in a 38-year-old man (case 2). Both of them had earlier been treated by ablative therapy for hyperthyroidism. The present diagnosis was based on elevated basal serum TSH levels despite elevated serum free thyroid hormone levels. Both of them had exaggerated TSH responses to TRH (peak value 240 mU/l in case 1 and 408 mU/l in case 2). Their albumin and prealbumin levels were normal. The serum TBG level was normal in case 1 but was elevated in case 2. Serum levels of alpha-subunits of TSH, and pituitary CT scans were normal. Despite mild clinical hyperthyroidism, peripheral indices of thyroid hormone action were normal. They had also relatives with apparent resistance to thyroid hormones. In view of the possibility that prolonged pituitary thyrotrophic stimulation is detrimental, various therapeutic approaches to suppress TSH levels were tried. Both T3 and T4 treatments lowered serum TSH levels, but were poorly tolerated. Acute administration of L-dopa or bromocriptine reduced serum TSH levels, but this was not seen during long-term therapy. TRIAC treatment lowered serum TSH levels, and the drug was well tolerated. Serum TSH responses to TRH were not blunted during T3, T4 or TRIAC treatments. Somatostatin also reduced serum TSH levels, but did not potentiate the effect of low dose T3 therapy. Our results suggest that the patients had unbalanced pituitary and peripheral thyroid hormone resistance, predominantly at the pituitary level. Of the drugs studied, TRIAC seemed to be the most suitable therapy.
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PMID:Effects of thyroid hormones (T4,T3), bromocriptine and Triac on inappropriate TSH hypersecretion. 321 42

Inappropriate secretion of thyrotropin (IST) is characterized by elevated serum free thyroid hormone and unsuppressed thyrotropin (TSH) levels, and results from either a TSH-secreting pituitary tumor (nIST) or a selective resistance to thyroid hormone action (nnIST). Although in most patients TSH levels are definitely high, in a quarter of the cases they are within the 'normal range'. In some of these cases, TSH had an elevated biologic activity and an apparent molecular weight smaller than in normals. The current availability of ultrasensitive TSH immunoradiometric assay, able to distinguish suppressed from unsuppressed TSH levels enables the recognition of the disease. The distinction between nnIST and nIST rests on clinical, neuroradiological, and biochemical criteria, the most useful of which are the alpha-subunit:TSH molar ratio (increased in nIST), and the evaluation of the TSH responses to thyrotropin-releasing hormone and high doses of 3,5,3'-triiodothyronine, both qualitatively normal in nnIST, while absent in nIST. The therapy of choice for patients with nIST is pituitary surgery, followed by irradiation in case of surgical failure. Chronic administration of bromocriptine is effective in a minority of cases. The long-acting somatostatin analogue SMS 201-995 has given promising results in 2 patients. In nnIST, bromocriptine is frequently uneffective, while small doses of 3,5,3'-triiodothyronine or 3,5,3'-triiodothyroacetic acid, a thyroid hormone derivative with a strong inhibitory effect on TSH secretion but poor thyromimetic activity on peripheral tissues, are effective in controlling TSH hypersecretion.
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PMID:Inappropriate secretion of thyrotropin by the pituitary. 329 65

This paper reports the case of a 31-year-old woman with hyperthyroidism, increased TSH and thyroid hormone levels, evidence of a pituitary adenoma, hyperprolactinaemia, amenorrhoea, and galactorrhoea. Following trans-sphenoidal pituitary adenomectomy, mild hyperthyroidism and increased TSH and alpha subunit levels persisted, whereas hyperprolactinaemia, amenorrhoea, and galactorrhoea disappeared. Serum TSH levels were not affected by administration of TRH, metochlopramide, domperidone, l-dopa or somatostatin. Serum TSH chromatography showed a normal pattern. Following a second trans-sphenoidal pituitary adenomectomy and radiotherapy, hyperthyroidism disappeared, and the TSH and alpha subunit levels returned to normal. Light microscopy showed no specific TSH immunostaining although electron microscopy revealed numerous secretory granules alined along the plasma membrane. The post-operative follow-up confirmed the presence of a TSH-secreting pituitary adenoma associated to functional hyperprolactinaemia.
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PMID:Hyperthyroidism due to a thyroid-stimulating hormone (TSH)-secreting pituitary adenoma associated with functional hyperprolactinaemia. A case report. 342 60

A non-neoplastic syndrome of inappropriate secretion of TSH (ITSHS) was diagnosed in a hemithyroidectomized and clinically euthyroid 44-yr-old man, who also exhibited limping (Perthes' disease), genu valgum, pes supinatus and lateral nystagmus. Computed tomography demonstrated an enlarged sella turcica due to empty sella. Baseline serum T3, T4, free T3, free T4 and TSH fluctuated between 179 and 274 ng/dl, 6.0 and 13.2 micrograms/dl, 4.2 and 6.0 pg/ml, 7.6 and 15.3 pg/ml, and 4.3 and 33.0 microU/ml, respectively. Serum alpha-TSH subunit was repeatedly normal (0.36-0.69 ng/ml) over the follow-up period (greater than 3 yr). No changes in serum liver enzymes and lipids were observed after thyroid hormone administration, whereas red blood cell glucose-6-phosphate dehydrogenase (G-6-PD) and urinary OH-proline were slightly enhanced during 120 micrograms/day L-T3 regimen. This also resulted in an inappropriately normal glucagon-stimulated cAMP levels. Tachycardia was experienced only during L-T3 and very high L-T4 dose treatments. Therefore, the patient showed some evidence for thyroid hormone peripheral refractoriness. Patient's TSH was physiologically responsive to agents (thyrotropin releasing hormone, methimazole, the dopamine antagonists domperidone and sulpiride) known to elicit its release into circulation, while it responded paradoxically to those which normally inhibit TSH secretion. In fact, the infusion of somatostatin (320 micrograms/h) or dopamine (4 micrograms/Kg/min), and the oral administration of bromocriptine or nomifensine (two dopamine agonists) or corticosteroids (dexamethasone) provoked an unexpected elevation of both unstimulated and TRH-stimulated TSH levels.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Abnormal daily periodicity of serum thyrotropin (TSH) and evidence for defective TSH suppression in a case of non-neoplastic syndrome of inappropriate TSH secretion. 358 59

Large increases in gastric acid and pepsin secretion, antral gastrin concentration, and decreases in serum gastrin occur during the third week of life in the neonatal rat. At the same time gastrin receptors appear and gastrin release becomes sensitive to somatostatin, indicating that absence and then appearance of specific hormone receptors may be responsible for some of the ontogenic pattern. At this time the mucosa also begins to grow rapidly, with a greater proportion of cells leaving the proliferative pool and differentiating. For the first 2.5-3 weeks these ontogenic changes can be triggered by corticosterone. Their full expression depends on dietary changes associated with weaning. Neither hormones, dietary changes, nor the weaning process itself is essential for development, because in the absence of these, all of the changes still occur--although they may be delayed or be smaller in magnitude. Figure 1 provides a generalized summary of the normal functional development of the stomach and how it is altered by changes in corticosterone levels and the absence of weaning. These findings indicate that ontogeny is genetically programmed and that the full expression of this program depends on hormones, luminal contents, and other environmental factors. In comparison with the small intestine, for example, gastric ontogeny has not received adequate attention. There are essentially no studies directed toward understanding changes in motility during this period. There is really only one study examining the growth pattern of the mucosa during development, and this study is aimed at changes in DNA synthesis and cell loss. Experiments involving the cell cycle are needed to understand whether existing cells mature and differentiate or whether newly created cells suddenly leave the proliferative pool to differentiate. There have been no experiments in which the effects of thyroid hormone on gastric development have been adequately examined. In addition, little or nothing is known about EGF in the ontogenic process. Studies implanting fetal tissue into adult hosts are needed to determine which gastric functions can develop in the absence of luminal stimulation and hormone changes. The cell biology of the gastric mucosa is difficult to examine--especially that involving the cells concerned with growth and differentiation. The stem cells are dispersed throughout the tissue and are a small portion of the cell population. These have never been isolated for study. In vitro culture of mucosal cells, however, is a technique that can possibly be used to examine development at the cellular and molecular level.
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PMID:Functional development of the stomach. 392 87

After mentioning insulin deficiency diabetes in animals produced by drugs such as Alloxan, Diazoxide or Streptozotocin only drugs are discussed, which are used in elderly patients and may either provoke diabetes mellitus (or temporary hyperglycemia) or may change the clinical course of diabetes. In the first group endocrine products such as corticosteroids, estrogens, somatotrophic hormone, thyroid hormone, glucagon, somatostatin, catecholamines and hormones with anabolic effects are listed. The second group comprises saluretics, salicylates, amphetamines, pentamidine, nicotinic acid and its derivatives, beta-receptor blockers and finally laxatives. Hypopotassemia alone can also be the cause of hyperglycemia. Speaking of the sulfonylureapreparations, their interaction with alcohol, with phenylbutazone, with some sulfonamides and the effect of the sulfonylureas on peripheric insulin-receptors is discussed. In case of severe diabetic vascular disease the use of anticoagulants may lead to hemorrhages. If such an hemorrhage occurs in the eyes, it may lead to blindness. In diabetic nephropathy the use of phenacetine and its derivatives should be substituted by another medication. This review is not at all complete but should only show some of the problems in the treatment of elderly diabetic patients.
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PMID:[Iatrogenic diabetes mellitus (side effects and interactions of drugs during clinical diabetes mellitus (author's transl)]. 612 38

The effects of somatostatin (SRIF) on the production and release of TSH and its subunits have been investigated in bovine anterior pituitary monolayer cultures. SRIF caused a dose-dependent inhibition of TSH and subunit release by TRH, with a half-maximal effective dose of 3 X 10(-8) M. This effect was time dependent and was greater for TSH than for its subunits. However, the basal release and total production of TSH and its subunits over a 24-h period were not affected by SRIF. The effect of SRIF was additive to that of thyroid hormones in suppressing the release of TSH and its subunits by TRH. A combination of SRIF and thyroid hormone completely suppressed the release of TSH and its subunits by TRH. In contrast, thyroid hormones caused a dose-dependent inhibition of the total production, as well as the release, of TSH and its subunits induced by TRH. Furthermore, thyroid hormones produced a dose-dependent increase (r = 0.81; P less than 0.001) in the effectiveness of a single dose of SRIF in suppressing TSH release by TRH. Analysis of these data revealed that thyroid hormones interacted synergistically with the SRIF effect to suppress TRH-mediated TSH and subunit release.
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PMID:The effect of somatostatin on the release of thyrotropin and its subunits from bovine anterior pituitary cells in vitro. 613 40

The addition of thyroid hormone to cultures of GH3 or GH4C1 pituitary tumor cells maintained in medium with hypothyroid serum decreased the concentration of specific receptors for TRH. The relationship between thyroid hormone effects on TRH receptors and TRH responses was examined by testing the concentration dependence, time course, and specificity of these changes. The concentrations of T3 giving half-maximal decreases in [3H]TRH binding and inhibition of the PRL response to TRH were 0.20 and 0.24 nM, respectively. TRH stimulated the rate of [3H]uridine uptake by 50% in cultures incubated without added T3 but did not increase [3H]uridine uptake in cells incubated with thyroid hormone. The PRL response to TRH was substantially inhibited 12 h after the addition of T3, and the uridine uptake response was completely blocked in 8 h. Two other stimuli of PRL secretion, sodium butyrate and isobutylmethylxanthine, were effective in the presence or absence of T3. Thyroid hormone did not reduce the specific binding of either [125I-Tyr1]somatostatin or [125I]iodoepidermal growth factor. Somatostatin decreased the secretion of GH and PRL by pituitary tumor cells grown with or without T3. The data show that the effects of thyroid hormones on TRH receptors are specific and suggest that regulation of receptor concentrations may be the direct cause of thyroid hormone regulation of pituitary responsiveness to TRH.
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PMID:Mechanism of thyroid hormone inhibition of thyrotropin-releasing hormone action. 625 85

There is extensive deiodinative metabolism of thyroxine (T4) in thyroid hormone target organs, including the pituitary and brain. In both rat and man, most of the 3,3',5-triiodothyronine (T3) in the body is produced outside the thyroid gland by deiodination of T4. T3 is the principal active form of thyroid hormone within cells. In the rat, there are at least three enzymatic iodothyronine-deiodinating pathways which can be distinguished by kinetics and substrate and inhibitor specificities. Two of these (types I and II) can convert T4 to T3. The third pathway (type III) converts T4 to the inactive reverse-T3 and T3 to an inactive diiodothyronine. Both the anterior pituitary and the brain produce most of their intracellular T3 locally, by the type-II pathway. Type-III activity is present throughout the brain, but not in the anterior pituitary. Studies in the rat, using the deiodination inhibitor iopanoic acid, show that the capacities of T4 to inhibit thyrotropin release and stimulate growth hormone synthesis require conversion of T4 to T3 in the pituitary. Studies in man strongly suggest that the same is true in the human adenohypophysis, and a syndrome in man of a deficiency in this process possibly exists. The hypothalamus exhibits some responses to thyroid hormone, including changes in somatostatin and substance P content and changes in activities of type-II and III deiodination. The mechanism(s) of action of thyroid hormone in the hypothalamus, and in the brain in general, are not yet well understood.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The role of thyroid hormone deiodination in the regulation of hypothalamo-pituitary function. 637 72

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