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Query: UMLS:C0043167 (
pertussis
)
19,595
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Mitogen-activated protein kinase (MAPK) is activated in response to both receptor tyrosine kinases and G-protein-coupled receptors. Recently, Gi-coupled receptors, such as the
alpha 2A adrenergic receptor
, were shown to mediate Ras-dependent MAPK activation via a pathway requiring G-protein beta gamma subunits (G beta gamma) and many of the same intermediates involved in receptor tyrosine kinase signaling. In contrast, Gq-coupled receptors, such as the M1 muscarinic acetylcholine receptor (M1AChR), activate MAPK via a pathway that is Ras-independent but requires the activity of protein kinase C (PKC). Here we show that, in Chinese hamster ovary cells, the M1AChR and platelet-activating factor receptor (PAFR) mediate MAPK activation via the alpha-subunit of the G(o) protein. G(o)-mediated MAPK activation was sensitive to treatment with
pertussis
toxin but insensitive to inhibition by a G beta gamma-sequestering peptide (beta ARK1ct). M1AChR and PAFR catalyzed G(o) alpha-subunit GTP exchange, and MAPK activation could be partially rescued by a
pertussis
toxin-insensitive mutant of G(o) alpha but not by similar mutants of Gi. G(o)-mediated MAPK activation was insensitive to inhibition by a dominant negative mutant of Ras (N17Ras) but was completely blocked by cellular depletion of PKC. Thus, M1AChR and PAFR, which have previously been shown to couple to Gq, are also coupled to G(o) to activate a novel PKC-dependent mitogenic signaling pathway.
...
PMID:G(o)-protein alpha-subunits activate mitogen-activated protein kinase via a novel protein kinase C-dependent mechanism. 857 9
It is now clearly established that alpha-2 adrenergic receptors can be subdivided in three pharmacological subtypes (alpha-2A, alpha-2B and alpha-2C) encoded by distinct genes (alpha 2C10, alpha 2C2 and alpha 2C4, respectively, in humans). Whereas the study of the regulation of the human
alpha-2A adrenergic receptor
and of the promoter region of the alpha 2C10 gene has being greatly helped by the availability of the colon carcinoma cell line HT29, the study of the other human receptor subtypes has thus far been limited to homologous desensitization/down-regulation in transfected cells, because of the lack of human cellular models constitutively-expressing alpha-2B or alpha-2C adrenergic receptors. Several human cell lines were thus screened, in an attempt to find such models. Radioligand binding studies with [3H]RX821002 and [3H]MK912, reverse transcription-polymerase chain reactions and RNase mapping experiments with pairs of primers and riboprobes specific for each subtype demonstrated that the hepatoma cell line HepG2 and the neuroblastoma cell line SK-N-MC possess alpha-2 adrenergic receptors of the alpha-2C subtype. However, whereas HepG2 expresses exclusively alpha-2C receptors (55 +/- 7 fmol of [3H]MK912 binding sites/mg of protein), SK-N-MC expresses both alpha-2A and alpha-2C subtypes in fairly similar amounts (20 +/- 8 and 23 +/- 3 fmol of [3H]MK912 binding sites/mg of protein, respectively). The study of the inhibition of 3H-labeled antagonist binding by UK14304 demonstrated that a fraction of the receptor population was coupled to
pertussis
toxin-sensitive G-proteins, which were identified as Gi2 and Gi3 by immunoblotting. The alpha-2 agonist was, moreover, able to decrease forskolin-stimulated cAMP production by 47% in HepG2 and 23% in SK-N-MC, demonstrating that inhibition of adenylyl cyclase is one of the primary mechanisms of signal transduction in both cell lines. HepG2 and SK-N-MC are the first human cell lines unquestionably shown to natively express alpha-2C adrenergic receptors. The discovery of these two models may be useful for future study of the regulation of alpha 2C4 gene expression in cells of different origins and investigation of the reciprocal regulation of alpha-2A and alpha-2C subtype in single cells.
...
PMID:HepG2 and SK-N-MC: two human models to study alpha-2 adrenergic receptors of the alpha-2C subtype. 915 9
Evidence from use of
pertussis
and cholera toxins and from NaF suggested the involvement of G proteins in GnRH regulation of gonadotrope function. We have used three different methods to assess GnRH receptor regulation of G(q/11)alpha subunits (G(q/11)alpha). First, we used GnRH-stimulated palmitoylation of G(q/11)alpha to identify their involvement in GnRH receptor-mediated signal transduction. Dispersed rat pituitary cell cultures were labeled with [9,10-(3)H(N)]-palmitic acid and immunoprecipitated with rabbit polyclonal antiserum made against the C-terminal sequence of G(q/11)alpha. The immunoprecipitates were resolved by 10% SDS-PAGE and quantified. Treatment with GnRH resulted in time-dependent (0-120 min) labeling of G(q/11)alpha. GnRH (10(-12), 10(-10), 10(-8), or 10(-6) g/ml) for 40 min resulted in dose-dependent labeling of G(q/11)alpha compared with controls. Cholera toxin (5 microg/ml; activator of G(i)alpha),
pertussis
toxin (100 ng/ml; inhibitor of G(i)alpha actions) and Antide (50 nM; GnRH antagonist) did not stimulate palmitoylation of G(q/11)alpha above basal levels. However, phorbol myristic acid (100 ng/ml; protein kinase C activator) stimulated the palmitoylation of G(q/11)alpha above basal levels, but not to the same extent as 10(-6) g/ml GnRH. Second, we used the ability of the third intracellular loop (3i) of other seven-transmembrane segment receptors that couple to specific G proteins to antagonize GnRH receptor-stimulated signal transduction and therefore act as an intracellular inhibitor. Because the third intracellular loop of alpha1B-adrenergic receptor (alpha1B 3i) couples to G(q/11)alpha, it can inhibit G(q/11)alpha-mediated stimulation of inositol phosphate (IP) turnover by interfering with receptor coupling to G(q/11)alpha. Transfection (efficiency 5-7%) with alpha1B 3i cDNA, but not the third intracellular loop of M1-acetylcholine receptor (which also couples to G(q/11)alpha), resulted in 10-12% inhibition of maximal GnRH-evoked IP turnover, as compared with vector-transfected GnRH-stimulated IP turnover. The third intracellular loop of
alpha2A adrenergic receptor
, M2-acetylcholine receptor (both couple to G(i)alpha), and D1A-receptor (couples to G(s)alpha) did not inhibit IP turnover significantly compared with control values. GnRH-stimulated LH release was not affected by the expression of these peptides. Third, we assessed GnRH receptor regulation of G(q/11)alpha in a PRL-secreting adenoma cell line (GGH(3)1') expressing the GnRH receptor. Stimulation of GGH(3)1' cells with 0.1 microg/ml Buserelin (a metabolically stable GnRH agonist) resulted in a 15-20% decrease in total G(q/11)alpha at 24 h following agonist treatment compared with control levels; this action of the agonist was blocked by GnRH antagonist, Antide (10(-6) g/ml). Neither Antide (10(-6) g/ml, 24 h) alone nor phorbol myristic acid (0.33-100 ng/ml, 24 h) mimicked the action of GnRH agonist on the loss of G(q/11)alpha immunoreactivity. The loss of G(q/11)alpha immunoreactivity was not due to an effect of Buserelin on cell-doubling times. These studies provide the first direct evidence for regulation of G(q/11)alpha by the GnRH receptor in primary pituitary cultures and in GGH3 cells.
...
PMID:Regulation of G(q/11)alpha by the gonadotropin-releasing hormone receptor. 917 Dec 37
