Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0043167 (pertussis)
 19,595 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Angiotensin II (AII)-like immunoreactivity (LIR) was detected by immunostaining in 7.5 +/- 1.1% of cells obtained by redispersion of pituitary cell aggregates from 15- to 20-day-old female rats, cultured for 5-7 days in serum-free medium supplemented with thyroid hormone and dexamethasone. Also, renin-LIR was retained in these cultures. As shown by double immunostaining of paraffin-embedded sections of the aggregates, this AII-LIR was localized only in gonadotrophs. AII-LIR was detected at least up to 5 weeks in culture. On reversed-phase, high-performance liquid chromatography (HPLC), this AII-LIR co-migrated with authentic AII. In perifused aggregate cell cultures of 15- to 20-day-old female rat pituitary maintained in serum-free medium supplemented with dexamethasone (DEX) and triiodothyronine (T3), AII stimulated GH release. AI and AIII had a similar effect. To evaluate the possible involvement of endogenous AII in the local regulation of GH release, gonadotrophs were stimulated with luteinizing hormone-releasing hormone (LHRH). LHRH displayed a transient inhibitory effect on GH release, which was followed by a rebound of GH release after withdrawal of the peptide. Treatment of aggregates with pertussis toxin reversed this inhibitory effect into a significant stimulation of GH release. In aggregates cultured in serum-supplemented medium, LHRH provoked a significant stimulation of GH release which was still followed by a post-stimulus rebound release. In hemipituitaries from 5-day-old rats, a significant stimulatory effect of LHRH on GH release was found without rebound secretion. To evaluate the possible involvement of endogenous AII in the effects of LHRH on GH release, the influence of (Sar1,Ala8)AII, a peptide AII receptor antagonist, and of DUP753, a non-peptide AII receptor blocker was tested in various in vitro conditions. The effect of LHRH on GH release in aggregates cultured either in serum-free medium supplemented with DEX and T3 or in serum-supplemented medium was not affected by (Sar1,Ala8)AII, not even after enhancing the LHRH-induced GH release by treatment of the aggregates with pertussis toxin. A hundred times lower concentration of (Sar1,Ala8)AII, however, abolished the AII-induced changes in GH release. Also DUP753 (10 microM) failed to block LHRH-induced GH release in aggregates. (Sar1,Ala8)AII also failed to block the effect of LHRH on GH release from hemipituitaries. It is concluded that LHRH has inhibitory and stimulatory effects on GH release in cultured pituitary cell aggregates.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Angiotensin II is retained in gonadotrophs of pituitary cell aggregates cultured in serum-free medium but does not mimic the effects of exogenous angiotensins and luteinizing-hormone-releasing hormone on growth hormone release. 147 13

FRTL-5 thyroid cells express a muscarinic receptor which inhibits the phospholipase C activity in a pirenzepine-insensitive manner. We here report that the cholinergic agonist carbachol decreases in these cells the steady-state iodide content, an effect correlated with the iodination of thyroglobulin and with thyroid hormone formation. Several signal pathways may be involved in this phenomenon since carbachol in addition to inhibiting phospholipase C, increased the arachidonic acid release and modified the adenylyl cyclase activity. In FRTL-5 cells, arachidonic acid is released via the direct stimulation of phospholipase A2 by a pirenzepine-sensitive muscarinic receptor coupled to a GTP binding protein sensitive to pertussis toxin. Regarding adenylyl cyclase, carbachol potentiated the thyrotropin-induced stimulation of the enzyme, whereas it did not affect the basal levels of cAMP. In vitro binding studies revealed the presence of two muscarinic binding sites. To summarize, the analysis of signal pathways and of in vitro binding sites indicates a complex muscarinic regulation of thyroid function, which includes the modulation of iodide fluxes.
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PMID:Muscarinic regulation of phospholipase A2 and iodide fluxes in FRTL-5 thyroid cells. 165 22

We recently reported that dexamethasone (DEX) enhances acetylcholine (ACh) release from pituitary cell aggregates. In the present study, the effect of DEX on the GH-releasing properties of the cholinergic agonist carbachol (CCh) was investigated. Perifusion of hemipituitaries from 14-day-old rats with CCh stimulated basal GH release. CCh also increased basal GH release from organ-cultured pituitaries and from pituitary cells cultured as reaggregates, but only when the thyroid hormone T3 was supplemented to the culture medium. Pretreatment of the animals in vivo with DEX abolished the CCh-induced increase in basal GH release from hemipituitaries tested in vitro. Treatment of pituitary organ cultures and reaggregate cell cultures with DEX reversed the stimulation of basal GH release by CCh into an inhibition. CCh also inhibited isoproterenol- and GRF-stimulated GH release from DEX-treated pituitary cell reaggregates. In contrast, the responsiveness of tumoral GH3 cell aggregates to CCh was not dependent on T3 or DEX during culture. The half-maximal concentration of CCh for inhibition was significantly lower than that for stimulation (1 and 10 microM, respectively). Perifusion with CCh of DEX-treated cell reaggregates consisting of a highly enriched somatotroph population (greater than 90% GH immunoreactive cells), obtained by sequential velocity and buoyant density sedimentation of dispersed cells, also inhibited basal GH release. Pretreatment of pituitary cell reaggregates cultured in DEX-supplemented medium with pertussis toxin completely abolished the inhibition by CCh. The inhibition of GH release by CCh was not affected by the Na+ conductance blocker tetrodotoxin, the Cl- channel blocker picrotoxin, or the K+ channel blocker caesium, but was abolished by the Ca2+ channel blockers cadmium and verapamil. In conclusion, CCh is capable of both stimulating and inhibiting GH release in different pituitary in vitro assay systems; the inhibition is dependent on glucocorticoids and the stimulation on the thyroid hormone T3. The mechanism of action of the inhibition seems to involve a GTP-binding protein and most probably a decrease in calcium conductance in the somatotroph.
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PMID:The glucocorticoid hormone dexamethasone reverses the growth hormone-releasing properties of the cholinomimetic carbachol. 270 69

The regulation of thyroid hormone formation by thyrotropin and norepinephrine involves the activation of both phospholipases C and A2. When FRTL-5 cells are incubated with 10(-10)M pertussis toxin for 4 to 20 h, the stimulation of iodide efflux by norepinephrine is inhibited by 50 to 70%. At the same toxin concentration the norepinephrine induced increase in cytosolic Ca2+ is unaffected; however upon 20 h pretreatment with 10(-9)M pertussis toxin a 30% inhibition is observed. By contrast, the pertussis toxin treatment had no effect on the increase in iodide efflux or in cytosolic Ca2+ levels induced by thyrotropin. Our data suggest that two GTP binding proteins sensitive to pertussis toxin are involved in the alpha 1 adrenergic but not in the thyrotropin induced activation of the signal transduction mechanisms leading to iodide efflux in FRTL-5 cells.
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PMID:Role of pertussis toxin sensitive G proteins in the alpha 1 adrenergic receptor but not in the thyrotropin receptor mediated activation of membrane phospholipases and iodide fluxes in FRTL-5 thyroid cells. 302 81

The production of hydrogen peroxide (H2O2) as an essential process for iodide organification is a key reaction in TSH-induced thyroid hormone synthesis. Here we characterize the signal transduction pathway involved in TSH-induced H2O2 production in FRTL-5 thyroid cells. At higher than 1 nM TSH, N6-(L-2-phenylisopropyl)adenosine (PIA), an adenosine receptor agonist having, by itself, no influence on H2O2 generation, potentiated this TSH action, whereas the TSH increase and PIA addition reduced cAMP accumulation. RO 20-1724, a phosphodiesterase inhibitor, amplified the TSH-induced cAMP accumulation, but did not change H2O2 generation in the whole range of TSH used. Ca(2+)-mobilizing agonists, GTP and ATP, also induced H2O2 production without stimulating cAMP accumulation. Chelation of intracellular Ca2+ markedly inhibited the TSH action, but intracellular Ca2+ increases by either thapsigargin or ionomycin mimicking it. All of the findings show the participation of Ca2+, but not cAMP, in the action of TSH. Desensitization of protein kinase-C (PKC) did not influence the receptor-mediated H2O2 production, suggesting the reduced importance of PKC activation compared to Ca2+ signaling to the reaction. A rise in intracellular Ca2+ independent of receptor activation also induced H2O2 production as well as arachidonate release, and both were potentiated by PIA. In addition, inhibitors of phospholipase-A2 and the arachidonate metabolic pathway depressed H2O2 generation, suggesting the participation of an arachidonate cascade in the Ca(2+)-dependent H2O2 production. Lipoxygenase inhibitors depressed the Ca2+ action without influencing arachidonate release, suggesting the involvement of a lipoxygenase product(s) of arachidonate in the Ca(2+)-signaling mechanism. In conclusion, in FRTL-5 cells, TSH-induced H2O2 production is mediated not by cAMP, but by the phospholipase-C/Ca2+ cascade, possibly followed by the Ca(2+)-dependent phospholipase-A2/arachidonate cascade. PIA amplifies TSH-induced H2O2 production at the steps of phospholipase-C and phospholipase-A2 activation in a pertussis toxin-sensitive manner.
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PMID:Thyrotropin-induced hydrogen peroxide production in FRTL-5 thyroid cells is mediated not by adenosine 3',5'-monophosphate, but by Ca2+ signaling followed by phospholipase-A2 activation and potentiated by an adenosine derivative. 782 20

K(+)-evoked acetyl[3H]choline ([3H]ACh) release was inhibited in a concentration-dependent manner by apomorphine and the D2 agonist quinpirole in striatal slices prepared from euthyroid and hypothyroid rats. However, there was a significant increase in the maximum inhibition observed with both agonists in the hypothyroid compared with the euthyroid group, which paralleled the increased D2 agonist sensitivity reported for stereotyped behavior. The D2 antagonist raclopride decreased, and the D1 antagonist SCH 23390 increased, the inhibition of [3H]ACh release by apomorphine, confirming an inhibitory role for D2 receptors and an opposing role for D1 receptors. Because there is no difference in D1 or D2 receptor concentration between the euthyroid and hypothyroid groups, it is suggested that thyroid hormone modulation of D2 receptor sensitivity affects a receptor-mediated event. Following intrastriatal injection of pertussis toxin (PTX), apomorphine no longer inhibited [3H]ACh release. In fact, increased [3H]-ACh release was observed, an effect reduced by SCH 23390, providing evidence that D1 receptors enhance [3H]-ACh release, and confirming that a PTX-sensitive G protein mediates the D2 response. As it has been reported that thyroid hormones modulate G protein expression, this mechanism may underlie their effect on dopamine agonist-mediated inhibition of ACh.
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PMID:Dopamine agonist-mediated inhibition of acetylcholine release in rat striatum is modified by thyroid hormone status. 810 83

Thyroid hormone status has profound effects on signal transduction in various tissues throughout the body. Therefore, we quantified the signal transducing G-proteins in the rat heart, cerebral cortex, vas deferens and liver by immunoblotting and pertussis toxin labeling in response to chemically induced hypothyroidism (treatment with propylthiouracil) and hyperthyroidism (treatment with triiodothyronine). Levels of the pertussis toxin (PTX) substrates Gi alpha and Go alpha in the heart and vas deferens were inversely correlated with thyroid hormone levels, i.e. Gi alpha and Go alpha were decreased or unchanged in hyperthyroid rats and increased in hypothyroid rats compared to control animals. The cerebral cortex and liver expression of PTX substrates Gi alpha and Go alpha was not affected by changes in thyroid hormone. Regulation of Gs alpha protein was more complex in that Gs alpha was unaffected in the other tissues tested. Expression of G-protein beta-subunits was not affected by thyroid status in the heart, liver, or cerebral cortex. Our results suggest that tissue- and G-protein-specific factors are involved in the regulation of G-protein subunits by thyroid hormone. Moreover, cardiac expression of Gs alpha is upregulated by increases or decreases in the normal level of thyroid hormone.
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PMID:Tissue- and subunit-specific regulation of G-protein expression by hypo- and hyperthyroidism. 847 Oct 65

Hypothyroidism profoundly reduces the capacity of brown adipose tissue (BAT) to generate cAMP in response to adrenergic stimulation. Evidence obtained with isolated brown adipocytes suggests a postreceptor defect that offsets the hypothyroidism-induced increase in beta3-adrenergic receptors. The goal of the present studies was to identify the defect in the cAMP generation pathway for which we studied cAMP generation in isolated cells and purified BAT membranes from normal and hypothyroid rats. Studies with adenosine deaminase and the adenosine receptor-1 agonist r-phenyl isopropyl adenosine (R-PIA) show that hypothyroid cells are not more sensitive to adenosine (same EC50) but more inhibited by high concentrations of R-PIA. Pretreatment with pertussis toxin reduced the gap in cAMP generation between eu- and hypothyroid cells and the inhibition mediated by R-PIA, but did not normalize the cAMP response to forskolin in hypothyroid cells. Although purified euthyroid BAT membranes increased cAMP production with GTP concentrations up to submillimolar range, to plateau or slightly decrease at higher levels, hypothyroid membranes were weakly stimulated by low concentrations of GTP and markedly inhibited (>50%) at concentrations > or = 10(-4) M. When assayed at 0.3 mM ATP and 1 microM GTP, hypothyroid membranes actually generated more cAMP in response to forskolin, but this was reversed when GTP concentration was 1 mM. Immunoblotting studies showed no significant effects of hypothyroidism on the abundance of G(alpha)i or Gbeta subunits, and ADP ribosylation of G(alpha)i was only 45% increased in hypothyroidism in contrast to a 2.5-fold increase in hypothyroid white adipose tissue membranes from the same rats. Hypothyroid membranes also exhibited different kinetics regarding ATP, with higher cAMP generation at submillimolar concentrations but less at >1 mM ATP. Actually, at ATP concentrations >0.6 mM, cAMP generation was markedly inhibited in hypothyroid membranes. Fixing the concentration of free Mg++ in these experiments indicates that most of the inhibition seen in hypothyroid membranes is caused by ATP, whereas euthyroid membranes are more sensitive to changes in free Mg++. Ca++ +/- calmodulin did not stimulate adenylyl cyclase (AC) activity. On the contrary, AC activity was inhibited by Ca++ in a concentration-dependent manner, by as low as 100 nM free Ca++, and to greater extent in hypo- than in euthyroid membranes (maximal inhibition 60 vs. 25-30%). Our results suggest that, functionally, hypothyroidism causes a change in the AC of BAT membranes consistent with a relative or absolute increase in the type VI AC (AC-VI). The effects on this AC of nucleotides, Ca++, and Mg++ at concentrations prevailing in the hypothyroid brown adipocyte are probably the major factor in the reduced capacity of these cells to generate cAMP. These results also open the possibility of a novel, differential effect of thyroid hormone on AC expression, and support the concept that thyroid hormone affects the adrenergic signal transduction pathways in a tissue-selective manner.
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PMID:Effects of hypothyroidism on brown adipose tissue adenylyl cyclase activity. 894 Mar 79

In order to replicate a recently described murine model of Graves' disease, we immunized AKR/N (H-2k) mice i.p., every 2 weeks, with either a clone of fibroblasts expressing both the human TSH receptor (hTSHR) and murine major histocompatibility complex (MHC) class II molecules or with fibroblasts expressing the MHC class II molecules alone. Mice were bled, and their thyroid hormone levels measured, at 6, 12, and up to 18 weeks after the first immunization. Between 11-12 weeks after immunization, a significant number of mice began to die spontaneously and were found to have developed large goiters. Thirty to 40% of mice immunized with hTSHR transfected fibroblasts showed markedly increased serum T3 and T4 hormone levels by 12 weeks compared with controls, with the highest thyroid hormone levels being T3: 420 ng/dl (normal < 70) and T4: 16.5 microg/dl (normal < 5). The murine serum demonstrated the presence of antibodies to the TSHR, as evidenced by inhibition of labeled TSH binding to the hTSHR, and these sera had in vitro thyroid stimulating activity. Many of the hyperthyroid mouse exhibited weight loss and hyperactivity and, on examination, their thyroids had the histological features of thyroid hyperactivity including thyroid enlargement, thyroid cell hypertrophy, and colloid droplet formation--all consistent with Graves' disease. In contrast, a small number of mice (< 5%) developed hypothyroidism with low serum T4 levels and markedly increased TSH concentrations and evidence of thyroid hypoplasia. Both hyperthyroidism and hypothyroidism were successfully transferred to naive mice using ip cells of immunized mice. Surprisingly, hypothyroidism occurred in many recipient mice even after transfer from hyperthyroid donors. These results confirmed that immunization with naturally expressed hTSHR in mammalian cells was able to induce functional TSHR autoantibodies that either stimulated or blocked the mouse thyroid gland and induced hyperthyroidism or thyroid failure. Furthermore, both blocking and stimulating antibodies coexisted in the same mice as evidenced so clearly by the transfer of hypothyroidism from hyperthyroid mice. The addition of a Th2 adjuvant (pertussis toxin) caused approximately 50% of the animals to become hyperthyroid beginning early at 9 weeks, whereas a Th1 adjuvant (CFA) delayed the disease onset such that only 10% were hyperthyroid by 12 weeks. As with human autoimmune thyroid disease, the T cell control of this murine model may be critical and requires more extensive investigation.
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PMID:Regulation and transfer of a murine model of thyrotropin receptor antibody mediated Graves' disease. 1006 67

The involvement of atrial natriuretic peptide (ANP) in the regulation of thyroid gland is supported by the presence of high-affinity ANP receptors and the identification of the peptide in thyroid follicular cells. The aim of this work was to study the action of ANP on parameters of thyroid hormone biosynthesis and analyze the intracellular mechanism of the ANP action in cultured bovine thyroid follicles. The addition of ANP (0.1-10 nM) to the culture medium for 24 h inhibited the TSH (thyroid-stimulating hormone)-stimulated iodide uptake with a maximal inhibition at 1 nM ANP. When thyrocytes were incubated with 10 nM ANP the inhibitory effect slightly increased from 24 to 72 h. Thyroglobulin (Tg) mRNA expression was reduced by 1 and 10 nM ANP. After 24 h of treatment with the cGMP analogue, N(2),2'-O-dibutyrylguanosine 3':5'-cyclic monophosphate [(Bu)(2)cGMP] (0.1 and 1 mM), an inhibition of iodide uptake and Tg mRNA expression was obtained, evidencing a cGMP-mediated inhibitory signal in the thyroid cell. A reduction of the cAMP production was induced by incubation of thyroid follicles with 1 and 10 nM ANP for 24 h. Under a similar treatment the cGMP accumulation was increased only by 10 nM ANP. The inhibitory effect of ANP on Tg mRNA level was reverted in the presence of pertussis toxin, an inhibitor of the G(i)-protein-mediated reduction of the adenylate cyclase activity. These results indicate an inhibitory action of ANP on parameters of thyroid hormone biosynthesis. A G(i)-protein-mediated reduction of the cAMP production seems to be the main factor involved in the ANP action although a role of the cGMP pathway should not be discarded specially at high ANP levels.
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PMID:Atrial natriuretic peptide inhibits iodide uptake and thyroglobulin messenger ribonucleic acid expression in cultured bovine thyroid follicles. 1204 6


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