Stanislaus D, Janovick J A, Brothers S, Conn P M
Department of Physiology and Pharmacology, Oregon Health Sciences University, Portland 97201, USA.
Mol Endocrinol. 1997 Jun;11(6):738-46. doi: 10.1210/mend.11.6.0005.
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.
百日咳毒素和霍乱毒素的使用证据以及氟化钠的相关证据表明,G蛋白参与了促性腺激素释放激素(GnRH)对促性腺细胞功能的调节。我们采用了三种不同方法来评估GnRH受体对G(q/11)α亚基(G(q/11)α)的调节作用。首先,我们利用GnRH刺激的G(q/11)α棕榈酰化来确定其参与GnRH受体介导的信号转导。将分散的大鼠垂体细胞培养物用[9,10-(3)H(N)] - 棕榈酸标记,并用针对G(q/11)α C末端序列制备的兔多克隆抗血清进行免疫沉淀。免疫沉淀物通过10% SDS - PAGE分离并定量。用GnRH处理导致G(q/11)α出现时间依赖性(0 - 120分钟)标记。与对照组相比,GnRH(10^(-12)、10^(-10)、10^(-8)或10^(-6) g/ml)处理40分钟导致G(q/11)α出现剂量依赖性标记。霍乱毒素(5μg/ml;G(i)α激活剂)、百日咳毒素(100 ng/ml;G(i)α作用抑制剂)和Antide(50 nM;GnRH拮抗剂)并未刺激G(q/11)α棕榈酰化超过基础水平。然而,佛波醇肉豆蔻酸(100 ng/ml;蛋白激酶C激活剂)刺激G(q/11)α棕榈酰化超过基础水平,但程度不如10^(-6) g/ml GnRH。其次,我们利用其他与特定G蛋白偶联的七跨膜片段受体的第三细胞内环(3i)拮抗GnRH受体刺激的信号转导并因此作为细胞内抑制剂的能力。因为α1B - 肾上腺素能受体的第三细胞内环(α1B 3i)与G(q/11)α偶联,它可以通过干扰受体与G(q/11)α的偶联来抑制G(q/11)α介导的肌醇磷酸(IP)周转刺激。用α1B 3i cDNA转染(效率5 - 7%),而不是M1 - 乙酰胆碱受体的第三细胞内环(其也与G(q/11)α偶联),与载体转染的GnRH刺激的IP周转相比,导致最大GnRH诱发的IP周转抑制10 - 12%。α2A肾上腺素能受体、M2 - 乙酰胆碱受体(两者均与G(i)α偶联)和D1A - 受体(与G(s)α偶联)的第三细胞内环与对照值相比未显著抑制IP周转。GnRH刺激的促黄体生成素(LH)释放不受这些肽表达的影响。第三,我们在表达GnRH受体的催乳素分泌性腺瘤细胞系(GGH(3)1')中评估GnRH受体对G(q/11)α的调节。用0.1μg/ml布舍瑞林(一种代谢稳定的GnRH激动剂)刺激GGH(3)1'细胞,与对照水平相比,激动剂处理后24小时总G(q/11)α减少15 - 20%;激动剂的这种作用被GnRH拮抗剂Antide(10^(-6) g/ml)阻断。单独的Antide(10^(-6) g/ml,24小时)或佛波醇肉豆蔻酸(0.33 - 100 ng/ml,24小时)均未模拟GnRH激动剂对G(q/11)α免疫反应性丧失的作用。G(q/11)α免疫反应性的丧失不是由于布舍瑞林对细胞倍增时间的影响。这些研究为原代垂体培养物和GGH3细胞中GnRH受体对G(q/11)α的调节提供了首个直接证据。
