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

Somatostatin (10(-10)-10(-7) mol/l) caused a concentration-dependent increase of the diameter of isolated crypts from the rat distal colon. Cell swelling was restricted to the upper one-third of the crypt and was dependent on the presence of Na+ and Cl- ions, indicating that it was caused by the stimulation of NaCl absorption by the hormone. Swelling was followed by a regulatory volume decrease, which could be inhibited by K+ and Cl- channel blockers. Also a lipoxygenase inhibitor and a leukotriene D4 receptor blocker inhibited volume regulation. Whole cell recordings performed in parallel revealed that somatostatin induced a depolarization of the cells at the upper one-third of the crypt but had no effect in the deeper parts of the crypt. This depolarization was concomitant with an increase in Cl- (and partially also HCO3-) conductance and was suppressed by a leukotriene D4 receptor blocker. In contrast, when Cl- secretion was stimulated by vasoactive intestinal peptide, a secretagogue acting on the adenosine 3',5'-cyclic monophosphate (cAMP) pathway, the effect of somatostatin was reversed from a depolarization into a hyperpolarization, an effect that was also observed in deeper parts of the crypt. Consequently, in crypts stimulated via the cAMP pathway, somatostatin inhibits the activation of apical Cl- channels. Somatostatin also partially inhibited the increase of K+ conductance induced by carbachol, a secretagogue acting on the Ca2+ pathway. Ussing chamber experiments showed that somatostatin caused a concentration-dependent decrease of short-circuit current. This decrease was dependent on the presence of Cl- and HCO3- ions. Measurements of unidirectional ion fluxes indicated that somatostatin stimulated Cl- absorption by an increase of the mucosa-to-serosa flux of this ion. The stimulation of Cl- absorption was completely suppressed by a Cl- channel blocker and by a lipoxygenase inhibitor. Consequently, the activation of a volume/leukotriene-sensitive basolateral Cl- conductance seems to be involved in the stimulation of Cl- absorption by somatostatin.
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PMID:Effect of somatostatin on cell volume, Cl- currents, and transepithelial Cl- transport in rat distal colon. 791 93

We used electrophysiological methods in a slice preparation to study the mechanisms of somatostatin (SS) effects on hippocampal pyramidal neurons. SS hyperpolarizes hippocampal pyramidal neurons in part by augmenting the time- and voltage-dependent M-current (IM), which has been shown to be reduced by muscarinic agonists. The SS effects are abolished by the phospholipase A2 inhibitors 4-bromophenacyl bromide and quinacrine. Arachidonic acid (AA) mimics all the effects of SS on hippocampal pyramidal neurons. The effects of AA and SS on IM are blocked by the lipoxygenase inhibitor nordihydroguaiaretic acid but not by the cyclooxygenase inhibitor indomethacin. Prostaglandins E2, F2 alpha, and I2 do not increase IM. However, the specific 5-lipoxygenase inhibitors 5,6-methanoleukotriene A4 methylester and 5,6-dehydroarachidonic acid both blocked the IM-augmenting action of either SS or AA. Leukotriene C4 (but not leukotriene B4) increases IM to the same extent as AA. IM was not altered by the 12-lipoxygenase product 12-hydroperoxyeicosatetraenoic acid, and SS effects were not altered by the 12-lipoxygenase inhibitor baicalein. These data implicate 5-lipoxygenase metabolite(s) (probably leukotriene C4) as a mediator for the IM-augmenting effect of SS. In addition, when the IM effect is blocked by lipoxygenase inhibitors, both SS and AA elicit another outward current that is not blocked by either lipoxygenase or cyclooxygenase inhibitors, suggesting a direct role of AA itself distinct from the IM effect. SS did not alter significantly Ca(2+)-dependent action potentials or, in whole-cell recordings, inward currents likely to represent high-threshold Ca2+ currents. The combined results of these studies suggest that SS hyperpolarizes hippocampal neurons by two mechanisms, both mediated through the AA system. However, one mechanism (IM) involves a metabolite of AA and is most effective at slightly depolarized potentials, whereas the other may involve AA itself and be more effective at membrane potentials near rest.
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PMID:Somatostatin inhibition of hippocampal CA1 pyramidal neurons: mediation by arachidonic acid and its metabolites. 809 29

The stimulation of large-conductance, calcium-activated (BK) potassium channels by somatostatin through protein dephosphorylation in rat pituitary tumor cells (White et al., Nature 351, 570-573, 1991) is blocked by drugs that interfere with arachidonic acid release by phospholipase A2 and metabolism by 5-lip-oxygenase. In contrast, higher concentrations of the same drugs had no effect on BK channel gating in cell-free patches, on the inhibition of adenylyl cyclase by somatostatin, or on the stimulation of BK channels by protein dephosphorylation through a cGMP-dependent pathway (White et al., Nature 361, 263-266, 1993). Exogenous arachidonic acid (1-20 muM) stimulated BK channel activity through protein dephosphorylation as effectively as somatostatin and was also blocked by inhibitors of lipoxygenases but not by inhibitors of phospholipase A2. These results support the hypothesis that lipoxygenase metabolites of arachidonic acid are second messengers linking pertussis toxin sensitive G-proteins to protein phosphatases regulating potassium channel activity (Armstrong and White, Trends Neurosci. 15, 403-408, 1992).
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PMID:Somatostatin stimulates BKCa channels in rat pituitary tumor cells through lipoxygenase metabolites of arachidonic acid. 893 25

Neurons containing neural nitric oxide synthase (nNOS) are found in various locations in the hypothalamus and, in particular, in the paraventricular and supraoptic nuclei with axons which project to the median eminence and extend into the neural lobe where the highest concentrations of NOS are found in the rat. Furthermore, nNOS is also located in folliculostellate cells and LH gonadotropes in the anterior pituitary gland. To define the role of NO in the release of hypothalamic peptides and pituitary hormones, we injected an inhibitor of NOS, Ng-monomethyl-L-arginine (NMMA) or a releasor of NO, nitroprusside (NP) into the third ventricle (3V) of conscious castrate rats and determined the effect on the release of various pituitary hormones. In vitro, we incubated medial basal hypothalamic (MBH) fragments and studied inhibitors of NO synthase and also releasors of NO. The results indicate that NOergic neurons play an important role in stimulating the release of corticotrophin-releasing hormone (CRH), luteinizing hormone releasing-hormone (LHRH), prolactin-RH's, particularly oxytocin, growth hormone-RH (GHRH) and somatostatin, but not FSH-releasing factor from the hypothalamus. NO stimulates the release of LHRH, which induces sexual behavior, and causes release of LH from the pituitary gland. The intrahypothalamic pathway by which NO controls LHRH release is as follows: glutamergic neurons synapse with noradrenergic terminals in the MBH which release nonepinephrine (NE) that acts on alpha 1 receptors on the NOergic neuron to increase intracellular free Ca++ which combines with calmodulin to activate NOS. The NOS diffuses to the LHRH terminal and activates guanylate cyclase (GC), cyclooxygenase and lipoxygenase causing release of LHRH via release of cyclic GMP, PGE2 and leukotrienes, respectively. Alcohol and cytokines can block LHRH release by blocking the activation of cyclooxygenase and lipoxygenase without interfering with the activation of GC. GABA also blocks the response of the LHRH neurons to NO and recent experiments indicate that granulocyte macrophage colony-stimulating factor (GMCSF) blocks the response of the LHRH neuron to NP by activation of GABA neurons since the blockade can be reversed by the competitive inhibitor of GABAa receptors, bicuculine.
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PMID:The role of nitric oxide (NO) in control of hypothalamic-pituitary function. 939 93

During infection, bacterial products, such as lipopolysaccharide (LPS), and viral products release cytokines from immune cells. These cytokines reach the brain by several routes. Furthermore, cytokines such as interleukin-1 (IL-1) are induced in central nervous system neurons by systemic injection of LPS. These cytokines determine the pattern of hypothalamic-pituitary secretion which occurs in infection. IL-2, by stimulation of cholinergic neurons, activates neural nitric oxide synthase (NOS). The nitric oxide (NO) released diffuses into corticotropin-releasing hormone (CRH)-secreting neurons and releases CRH. IL-2 also acts in the pituitary to stimulate adrenocorticotropic hormone secretion. On the other hand, IL-1 alpha blocks the NO-induced release of luteinizing-hormone-releasing hormone (LHRH) from neurons, thereby blocking pulsatile luteinizing hormone (LH), but not follicle-stimulating hormone release, and also inhibiting sexual behavior which is induced by LHRH. IL-1 alpha and granulocyte-macrophage colony-stimulating factor (GM-CSF) block the response of the LHRH terminals to NO. GM-CSF inhibits LHRH release by acting on its receptors on gamma-aminobutyric acid (GABA)ergic neurons to stimulate GABA release. GABA acts on GABA-A receptors on the LHRH neuronal terminal to block NOergic stimulation of LHRH release. This concept is supported by a blockade of GM-CSF-induced suppression of LHRH release from medial basal hypothalamic explants by the GABA-A receptor blocker, bicuculline. IL-1 alpha inhibits growth hormone (GH) release by inhibiting GH-releasing hormone release mediated by NO and stimulating somatostatin release, also mediated by NO. IL-1 alpha-induced stimulation of prolactin release is also mediated by intrahypothalamic action of NO which inhibits release of the prolactin-inhibiting hormone, dopamine. The actions of NO are brought about by its combined activation of guanylate cyclase liberating cyclic guanosine monophosphate and activation of cyclooxygenase and lipoxygenase, with liberation of prostaglandin E2 and leukotrienes, respectively. Thus, NO plays a key role in inducing the changes in the release of hypothalamic peptides induced in infection by cytokines. Cytokines, such as IL-1 beta, also act in the anterior pituitary gland, at least in part, via induction of inducible NOS. The NO produced alters the release of anterior pituitary hormones.
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PMID:Nitric oxide controls the hypothalamic-pituitary response to cytokines. 948 1

During infection, bacterial and viral products, such as bacterial lipopolysaccharide (LPS), cause the release of cytokines from immune cells. These cytokines can reach the brain by several routes. Furthermore, cytokines, such as interleukin-1 (IL-1), are induced in neurons within the brain by systemic injection of LPS. These cytokines determine the pattern of hypothalamic-pituitary secretion which characterizes infection. IL-2, by stimulation of cholinergic neurons, activates neural nitric oxide synthase (nNOS). The nitric oxide (NO) released diffuses into corticotropin-releasing hormone (CRH)-secreting neurons and releases CRH. IL-2 also acts in the pituitary to stimulate adrenocorticotropic hormone (ACTH) secretion. On the other hand, IL-1 alpha blocks the NO-induced release of luteinizing hormone-releasing hormone (LHRH) from LHRH neurons, thereby blocking pulsatile LH but not follicle-stimulating hormone (FSH) release and also inhibiting sex behavior that is induced by LHRH. IL-1 alpha and granulocyte macrophage colony-stimulating factor (GMCSF) block the response of the LHRH terminals to NO. The mechanism of action of GMCSF to inhibit LHRH release is as follows. It acts on its receptors on gamma-aminobutyric acid (GABA)ergic neurons to stimulate GABA release. GABA acts on GABAa receptors on the LHRH neuronal terminal to block NOergic stimulation of LHRH release. This concept is supported by blockade of GMCSF-induced suppression of LHRH release from medial basal hypothalamic explants by the GABAa receptor blocker, bicuculline. IL-1 alpha inhibits growth hormone (GH) release by inhibiting GH-releasing hormone (GHRH) release, which is mediated by NO, and stimulating somatostatin release, also mediated by NO. IL-1 alpha-induced stimulation of prolactin release is also mediated by intrahypothalamic action of NO, which inhibits release of the prolactin-inhibiting hormone dopamine. The actions of NO are brought about by its combined activation of guanylate cyclase-liberating cyclic guanosine monophosphate (cGMP) and activation of cyclooxygenase and lipoxygenase with liberation of prostaglandin E2 and leukotrienes, respectively. Thus, NO plays a key role in inducing the changes in release of hypothalamic peptides induced in infection by cytokines. Cytokines, such as IL-1 beta, also act in the anterior pituitary gland, at least in part via induction of inducible NOS. The NO produced inhibits release of anterior pituitary hormones.
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PMID:Role of nitric oxide in the neuroendocrine responses to cytokines. 962 49

During infection, bacterial and viral products, such as bacterial lipopolysaccharide (LPS), cause the release of cytokines from immune cells. These cytokines can reach the brain by several routes. Furthermore, cytokines, such as interleukin-1 (IL-1), are induced in neurons within the brain by systemic injection of LPS. These cytokines determine the pattern of hypothalamic-pituitary secretion that characterizes infection. IL-2, by stimulation of cholinergic neurons, activates neural nitric oxide synthase (nNOS). The nitric oxide (NO) released diffuses into corticotropin-releasing hormone (CRH)-secreting neurons and releases CRH. IL-2 also acts in the pituitary to stimulate adrenocorticotropic hormone (ACTH) secretion. On the other hand, IL-1 alpha blocks the NO-induced release of luteinizing hormone-releasing hormone (LHRH) from LHRH neurons, thereby blocking pulsatile LH but not follicle-stimulating hormone (FSH) release and also inhibiting sex behavior that is induced by LHRH. IL-1 alpha and granulocyte macrophage colony-stimulating factor (GMCSF) block the response of the LHRH terminals to NO. The mechanism of action of GMCSF to inhibit LHRH release is as follows. It acts on its receptors on gamma-aminobutyric acid (GABA)ergic neurons to stimulate GABA release. GABA acts on GABAa receptors on the LHRH neuronal terminal to block NOergic stimulation of LHRH release. IL-1 alpha inhibits growth hormone (GH) release by inhibiting GH-releasing hormone (GHRH) release, which is mediated by NO, and stimulating somatostatin release, also mediated by NO. IL-1 alpha-induced stimulation of PRL release is also mediated by intrahypothlamic action of NO, which inhibits release of the PRL-inhibiting hormone dopamine. The actions of NO are brought about by its combined activation of guanylate cyclase-liberating cyclic guanosine monophosphate (cGMP) and activation of cyclooxygenase (COX) and lipoxygenase (LOX) with liberation of prostaglandin E2 and leukotrienes, respectively. Thus, NO plays a key role in inducing the changes in release of hypothalamic peptides induced in infection by cytokines. Cytokines, such as IL-1 beta, also act in the anterior pituitary gland, at least in part via induction of inducible NOS. The NO produced inhibits release of ACTH. The adipocyte hormone leptin, a member of the cytokine family, has largely opposite actions to those of the proinflammatory cytokines, stimulating the release of FSHRF and LHRH from the hypothalamus and FSH and LH from the pituitary directly by NO.
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PMID:The mechanism of action of cytokines to control the release of hypothalamic and pituitary hormones in infection. 1126 67

Capsaicin, the pungent ingredient of chilli peppers has become a "hot" topic in neuroscience with yearly publications over half thousand papers. It is outlined in this survey how this exciting Hungarian research field emerged from almost complete ignorance. From the initial observation of the phenomenon of "capsaicin desensitization", a long-lasting chemoanalgesia and impairment in thermoregulation against heat, the chain of new discoveries which led to the formulation of the existence of a "capsaicin receptor" on C-polymodal nociceptors is briefly summarized. Neurogenic inflammation is mediated by these C-afferents which are supplied by the putative capsaicin receptor and were termed as "capsaicin sensitive" chemoceptive afferents. They opened new avenues in local peptidergic regulation in peripheral tissues. It has been suggested that in contrast to the classical axon reflex theory, the capsaicin-sensitive sensory system subserves a "dual sensory-efferent" function whereby initiation of afferent signals and neuropeptide release are coupled at the same nerve endings. Furthermore, in the skin at threshold stimuli which do not evoke sensation elicit already maximum efferent response as enhanced microcirculation. In isolated organ preparations large scale of new type of peptidergic capsaicin-sensitive neurogenic smooth muscle responses were revealed after the first one was described by ourselves on the guinea-pig ileum in 1978. Recently the "capsaicin receptor" has been cloned and it is now named as the "transient receptor potential vanilloid 1" (TRPV1). Hence, capsaicin research led to the discovery of the first temperature-gated ion channel gated by noxious heat, protons, vanilloids and endogenous ligands as anandamide, N-oleoyldopamine and lipoxygenase products. Another recent achievement is the discovery of a novel "unorthodox" neurohumoral regulatory mechanism mediated by somatostatin. Somatostatin released from the TRPV1-expressing nerve endings reaches the circulation and elicits systemic antiinflammatory and analgesic "sensocrine" functions with counter-regulatory influence e.g. in Freund's adjuvant-induced chronic arthritis. Nociceptors supplied by TRPV1 and sst4 somatostatin receptors has become nowadays promising targets for drug development.
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PMID:Forty years in capsaicin research for sensory pharmacology and physiology. 1556 73

The present review focuses on promising new opportunities for anti-inflammatory and analgesic therapy. The theoretical background is an original observation based on our own experimental results. These data demonstrate that somatostatin is released from capsaicin-sensitive, peptidergic sensory nerve endings in response to noxious heat and chemical stimuli such as vanilloids, protons or lipoxygenase products. It reaches distant parts of the body via the circulation and exerts systemic anti-inflammatory and analgesic effects. Somatostatin binds to G-protein-coupled membrane receptors (sst(1)-sst(5)) and diminishes neurogenic inflammation by prejunctional action on sensory-efferent nerve terminals, as well as by postjunctional mechanisms on target cells. It decreases the release of pro-inflammatory neuropeptides from sensory nerve endings and also acts on receptors of vascular endothelial, inflammatory and immune cells. Analgesic effect is mediated by an inhibitory action on peripheral terminals of nociceptive neurons, since circulating somatostatin cannot exert central action. Somatostatin itself is not suitable for drug development because of its broad spectrum and short elimination half life, stable, receptor-selective agonists have been synthesized and investigated. The present overview is aimed at summarizing the physiological importance of somatostatin and sst receptors, pharmacological significance of synthetic agonists and their potential in the development of novel anti-inflammatory and analgesic drugs. These compounds might provide novel perspectives in the pharmacotherapy of acute and chronic painful inflammatory diseases, as well as neuropathic conditions.
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PMID:Inhibitory effect of somatostatin on inflammation and nociception. 1676 34

Abstract We have recently shown that glutamate primarily induces somatostatin release in hypothalamic neurons through N-methyl-D-aspartate (NMDA)-type receptor sites. Here we report that glutamate and NMDA also stimulate the release of [(3)H]arachidonic acid in a dose-dependent manner. The NMDA-induced effects (arachidonic acid release and somatostatin secretion) were both inhibited by MK-801, an NMDA receptor-type antagonist, or mepacrine, a phospholipase A(2) inhibitor. In addition, mepacrine was able to inhibit A23187-stimulated arachidonic acid release and somatostatin secretion. p-Bromophenacylbromide, another phospholipase A(2) inhibitor, also blocked NMDA-induced secretion of somatostatin. However, responses to NMDA were unaffected by H7 (inhibitor of protein kinase C), nordihydroguaiaretic acid or indomethacin (inhibitors of lipoxygenase and cyclooxygenase). Melittin, a phospholipase A(2) activator, was found to stimulate both responses, but omission of extracellular Ca(2+) from the incubation media strongly reduced melittin-induced somatostatin release. Six-h pertussis toxin pretreatment did not significantly reduce the action of NMDA on either of the two parameters studied. High-performance liquid chromatography analysis of [(3)H]metabolites released in the medium after NMDA stimulation revealed that [(3)H]arachidonic acid was the only detectable metabolite. External addition of arachidonic acid increased the release of somatostatin, whereas E(2) and F(2)alpha prostaglandins had no effect. Our results show a close correlation between arachidonic acid release and somatostatin secretion, the two parameters we investigated.
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PMID:Phospholipase A and Somatostatin Release are Activated in Response to N-Methyl-D-Aspartate Receptor Stimulation in Hypothalamic Neurons in Primary Culture. 1921 1


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